Silverstone Classic is one of those events which goes into my diary just as soon as the dates are announced. It is, in my opinion, unmissable, and indeed I’ve not missed it since first discovering just how amazing it was with an attendance in 2007. What I had not appreciated was just how big an event it is. I understand that it has not always been like this, but that would be to wind the clock back to its origins in 1990. Ever since then, the Classic has grown in scale and prominence in the world such that these days it can justifiably claim to be the world’s largest historic motoring racing event. As such it attracts a crowd of over 100,000 fans, not all of whom are UK residents, who help to fill the site over the three days of the event. The racing is at the core of the event, with 22 races featuring more than 1000 cars , but taking advantage of the 760 acres of space available, this is also a popular event for Car Clubs, who between them bring an ever-growing number of their cars for display, and other attractions include a sizeable trade area, a Silverstone Auction, live bands on the Friday and Saturday evening, an array of fairground attractions and other entertainments for the younger attendee, along with plenty of outlets for food and drink, something which has improved markedly over the years. After attending a couple of times and being frustrated at how much I missed by only attending for one day, I soon realised that I needed to make a weekend of it, arriving early, and walking literally miles. And even, it is really not possible to take everything in, as the racing alone could keep you diverted the whole day, so for 2017 I decided to add on the third day and see if that helped me to do better at taking everything in. It certainly did, and the result is that I walked even more miles, but still there was plenty that I missed. You just can’t avoid that at an event the size of this one. But there was much that I did see, and the 1940 photos in this report will evidence that. Read on!

CAR CLUB DISPLAYS

Even if you were not interested in the racing, there’s an event, indeed a very big event, just provided by the Car Club displays. In excess of 10,000 cars are booked in, representing no fewer than 125 Car Clubs, and large areas of the infield are filled with lines of cars which range from familiar classics to those which you see rarely or almost never. Although a few of the cars here are left in position overnight, the majority move off site, some because they are only present on one day, others do stage a return, but inevitably are parked up in a different order when they do come back. So it’s not a case of doing a tour of all the represented Clubs and thinking you’ve seen it all, as you won’t have done. Saturday has always been the busier day than Sunday, so I was interested to see how the Friday would compare, and the answer is that it was very much like a Sunday. Clearly a lot of people do come for the three days! The event does try to help Clubs celebrate notable anniversaries, with the offer of Parade Laps for as many Clubs as can be fitted into the available time slots over the three days. In 2017 this meant McLaren celebrating the 80th birthday of marque founder Bruce, an amazing assembly of Jaguar XJ220s to mark the 25th anniversary, an array of cute little Fiat 500s on the 60th anniversary of Dante Giacosa’s much loved baby as well as 60 years of the Lotus Seven and Russia’s Gaz 21, 50 years of the Ferrari Owners’ Club and MG Car Club, 40 years of the Triumph Six Sports Club and 30 years of the Lamborghini Club UK and Ford Sierra RS Cosworth. As well as all the individual Clubs, there is also an area reserved for those cars which have been out on a pre-organised drive, so you get a collection of all sorts of generally rare cars in this section, too. And the BRDC have their own parking area, behind the Club, and a wander into this part of the site often yields something unexpected.

ABARTH

Interest from Abarth Owners club members is steadily increasing, so we had more cars here than in 2016, but still not as many as we get at many other events. Among those present was the yellow 595 from Dutchman Ton Kerdijk, who had planned a UK trip to coincide with this event, and it was good to meet him in person. His was one of a number of the 500 and 595-based models that were on the Abarth stand on each of the three days.

A little variety was provided when Jerry and Carla Rigden arrived in their 695 Biposto. These remain rare, with just 33 registered in the UK, so you are not going to see one very often, even when Abarths are gathered together en masse. First shown at the 2014 Geneva Show, this 2 seater (that’s what Biposto means in Italian) is nothing other than a road legal version of the 695 Assetto Corse Racing car, a vehicle which has its own race series in Europe. Although the car is road legal, it was envisaged that the majority of people who buy one of these cars will use it on the track and quite frequently. So it was conceived accordingly. That means upgrades to all the important bits – engine, brakes, suspension, gearbox – and some fairly drastic measures to save weight which resulted in a car which generates 190 bhp and 199 lb/ft or 250 Nm of torque with a kerb weight of just 997kg. That’s enough to give a 0 – 60 time that is under 6 seconds, and a top speed of 143 mph. Those are supercar figures produced by a city car. There’s more to it than that, though, as the changes that go to make a Biposto are extensive, and they have been well thought through, so this is a long-way from being a hastily conceived or tuned up special. Ignoring the limited edition cars which arrived during 2015, the “regular” Biposto is only offered in Matt Performance Grey paint, and the car is visually distinctive, with a new front bumper, rear diffuser, wider arches, new skirts and bigger roof spoiler. Although the engine is still the same 1.4 T-jet that features in the lesser 500 and 595 cars, it has been reworked here, with a new Garrett turbocharger, larger intercooler, altered fuel rail and an Akrapovic exhaust system. Buyers can choose between the standard five speed gearbox or an optional race-bred dog-ring unit mated to a mechanical limited slip diff. The standard car’s MacPherson strut and torsion beam suspension has been reworked, too, with altered springs, wider tracks adjustable ride height and dampers with more resilient bushings, using Extreme Shox technology shock absorbers. The brakes are upgraded in line with the extra power, featuring 305mm Brembo discs and four pot calipers up front and 240mm discs with single pot calipers at the rear. The wheels are lightened 18″ OZ and attached via a titanium hub, shod with bespoke 215/35 Goodyear tyres. In the interest of weight saving, a number of standard trim items are removed, including the regular door trims, air conditioning, the rear seats and some of the sound deadening material. Even the standard air vents have been changed so they are covered by a simple mesh. In their place is plenty of polished carbon fibre, a titanium strut brace, racing seats and harness, as well as special trim features such as new pedals, tread plates and a race inspired digital display on the dash where the radio usually sits.

Just one Punto was to be seen during the event, Olaf Svenden’s Punto Evo SuperSport. Just 199 of these SuperSport versions were built, of which around 120 are registered on UK roads. These cars had many of the options from the Punto Evo included as standard. Power came from the the 1.4-litre MultiAir turbo engine, tuned to produce 178bhp and 199lb ft of torque, up from 165 of the standard Punto Evo, giving the SuperSport a 0-62 time of 7.5 seconds and a top speed of over 132mph. To help put the power down, the SuperSport was fitted with wider 18″ wheels and optional Koni FSD dampers. Standard equipment included the Blue&Me infotainment system with steering wheel controls, automatic climate control and a popular option was the ‘Abarth Corsa by Sabelt’ sports leather seats. The SuperSport was available in the same colours as the regular Punto Evo, which means white, grey, black and red.

Eagerly awaited, the 124 Spider went on sale in September 2016. A quick reminder as to what this car is: The Abarth 124 Spider was developed in parallel with the Fiat model. It does cost a lot more, and there are those who think you don’t get enough extra for your money, but those who have driven it will tell you otherwise. You certainly get more power. The 1.4 MultiAir turbo unit jumps up from 138bhp to 168bhp, while torque also increases by a modest 10Nm to 250Nm, which gives it a 0-62mph time of 6.8 seconds, which is half a second quicker than the 2.0-litre Mazda MX-5. The top speed is 143mph. It weighs just 1060kg meaning a power-to-weight ratio of 158bhp-per-tonne, and with the new Record Monza exhaust system it sounds great even at idle. The Abarth version gets a stiffer suspension setup than the regular Fiat 124 Spider, with Bilstein dampers and beefed-up anti-roll bars. Bigger Brembo brakes also feature, with aluminium calipers. It can be had with a six-speed manual or six-speed automatic transmission with paddles, and the latter gets a Sport mode for quicker shifts. Many of the UK cars sport the ‘Heritage Look’ pack, which is a no-cost option. It brings a matt black bonnet and bootlid, plus red exterior trim detailing and has proved popular. The £29,565 starting price gets you standard equipment such as cruise control, climate control, Bluetooth, a DAB radio and satnav, plus Alcantara black and red (or pure black) seat trim. The automatic gearbox is a £2,035 extra, while an optional visibility pack brings LED DRLs, auto lights and wipers and rear parking sensors.

AC

AC came back to the market after the Second World War with the staid 2-Litre range of cars in 1947, but it was with the Ace sports car of 1953 that the company really made its reputation in the post war years. Casting around for a replacement for the ageing 2-Litre, AC took up a design by John Tojeiro that used a light ladder type tubular frame, all independent transverse leaf spring suspension, and an open two seater alloy body made using English wheeling machines, possibly inspired by the Ferrari Barchetta of the day. Early cars used AC’s elderly 100 bhp two-litre overhead cam straight-six engine (first seen soon after the end of the First World War), which, according to a 1954 road test by Motor magazine, gave a top speed of 103 mph and 0–60 mph in 11.4 seconds and a fuel consumption of 25.2 mpg. It was hardly a sporting engine, however, and it was felt that something more modern and powerful was required to put the modern chassis to good use. Joining the Ace in 1954 was the Aceca hard top coupé, which had an early form of hatchback rear door but used the same basic timber framed alloy body. From 1956, there was the option of Bristol Cars’ two-litre 120 bhp straight-six with 3 downdraught carburettors and slick four-speed gearbox. Top speed leapt to 116 mph with 0–60 mph in the nine second bracket. Overdrive was available from 1956 and front disc brakes were an option from 1957, although they were later standardised. In 1961 a new 2.6-litre straight-six ‘Ruddspeed’ option was available, adapted by Ken Rudd from the unit used in the Ford Zephyr. It used three Weber or SU carburettors and either a ‘Mays’ or an iron cast head. This setup boosted the car’s performance further, with some versions tuned to 170 bhp, providing a top speed of 130 mph and 0–60 mph in 8.1 seconds. However, it was not long before Carroll Shelby drew AC’s attention to the Cobra, so only 37 of the 2.6 models were made. These Ford engined models had a smaller grille which was carried over to the Cobra. The car raced at Le Mans in 1957 and 1958. In 1959 at Le Mans, Ted Whiteaway and John Turner drove their AC-Bristol, registration 650BPK, to the finish, claiming top honours for the 2,000cc class and seventh overall behind six 3 litre cars. Few cars with this provenance have survived and are extremely valuable. They can range from $100,000 or more for an unrestored car, even one in pieces, to in excess of $400,000 for a restored AC Ace.

This is a Greyhound, effectively a 2+2 version of the better known Ace and Aceca. It was announced for the opening of the Motor Show in October 1959. The car had a two-door, four-seater aluminium body, and inherited most of the technical components of the Ace and Aceca but it had a wheelbase 10 inches or 250mm longer and coil springs in place of a transverse leaf spring at the front. A variety of engines were used, including the AC 4 cylinder, Bristol 4 cylinder and Ford 6 cylinder units as featured in the Ace. Just 83 cars were made before production ceased in 1963.

Genuine AC Cobra are rare beasts, as not that many were produced, but for the last as long as anyone can remember, there have all manner of replica and officially sanctioned continuation type cars produced, so there are pretty decent numbers of cars around that bear the legendary shape of this raw sports car. These are largely what featured on this stand, with a number of continuation and recreation cars.

There was also an ME3000 here. First seen at the 1973 London Motor Show, it took until late 1979 before the car was available to customers. Prior to its launch, AC had been producing the large and costly 428 Coupe and Convertible, and the Managing Director, W Derek Hurlock, decided that a new and smaller car was needed. Mid-engined designs were in fashion at the time and in 1972 the prototype Diabolo was built with an Austin Maxi engine and transaxle. However, following considerable investment in development using the BLMC power unit and transmission, the engine manufacturers decided that they needed all the E series engines they could make to power their own Maxi and Allegro models, so the Diabolo project appeared likely to collapse for lack of an engine. In much the same way as they had taken up the Tojeiro prototype and turned it into the Ace, AC acquired the rights and at the 1973 London Motor Show showed their own version, the mid-engined ME3000 with the 3.0-litre Ford Essex V6 engine installed transversely over a custom AC-designed gearbox. The car featured a steel chassis making extensive use of square-section steel tube, with a strong monocoque for the central portion of the body. This framework supported a glass fibre body. Press releases of the time indicated that the company hoped to be able to build and sell the car at the rate of 10 – 20 cars per week, although it was at this stage apparent that the model was in many ways not yet ready for serial production. Development was complete in 1976 when new Type Approval regulations were introduced. A prototype failed the 30 mph crash test, and the chassis had to be redesigned. On the second attempt, the car passed. The design changes meant the AC 3000 ME was out of date by the time it reached production. The first cars (now renamed 3000ME) were delivered in 1979, by which time they were in direct competition with the Lotus Esprit. The goal of 250 cars per year did not seem possible. After 71 cars were sold, Hurlock called a halt to production in 1984.

ALFA ROMEO

First of the all-new Giulia models to appear was the Berlina, launched in 1962. The styling was quite straight forward, but great attention was paid to detail. The engine bay, cabin and boot were all square shaped. But the grille, the rooflines and details on the bonnet and boot made for an integrated design from bumper to bumper. Thanks to Alfa Romeo using a wind tunnel during its development, the Giulia was very aerodynamic with a drag coefficient of Cd=0.34, which was particularly low for a saloon of the era and not a bad figure even for cars of today. Couple that with the fact that Alfa Romeo was one of the first manufacturers to put a powerful engine in a light-weight car (it weighed about 1,000 kilograms) and thanks to an array of light alloy twin overhead camshaft four-cylinder engine, similar to that of the earlier Giulietta models range, the car had a lively performance which bettered that of many sports cars of the day. The Tipo 105.14 was the first model, with a 1,570 cc Twin Cam engine with single down-draft carburettor generating 91 hp at 6500 rpm. The “TI” nomenclature referred to a class of Italian saloon car racing known as “Turismo Internazionale”, and had previously been applied to higher-performance versions of the 1900 and Giulietta saloons in the 1950s. However, for the Giulia saloon, the Ti was at first the only version available, and later, with the introduction of the TI Super and Super, the TI became the base version for the 1,600 cc engine class. The steering column gearchange (the only one in the Giulia range) was replaced with a floor change for 1964 (Tipo 105.08). Right hand drive cars, available from 1964, only ever had a floor change (Tipo 105.09). Brakes were by drums all around at first. Discs were introduced later, first at the front, and later all around. A brake servo was not fitted at first, but was introduced in later cars. The steering wheel featured the only horn ring ever in the Giulia range. The dashboard with a strip speedo is a notable feature, as is the steering wheel with a horn ring. The Giulia TI was phased out in 1968 and re-introduced as the austerity model 1600 S. Tipo 105.16 was a special racing model introduced in 1963. Quadrifoglio Verde stickers on the front wings were a distinguishing feature. Only 501 were made for homologation and today it is very rare and desirable. The 1,570 cc engine was fitted with two double-choke horizontal Weber 45DCOE carburettors for 110 hp at 6500 rpm. The body was lightened and a floor gearchange was fitted as standard, as were alloy wheels of very similar appearance to the standard steel ones of the TI. The TI’s instrument cluster with its strip speedometer was replaced with a three-instrument binnacle comprising speedometer, tachometer and a multi-gauge instrument (fuel, water temperature, oil temperature and pressure) – these instruments were similar to those fitted to the contemporary Giulia Sprint and Sprint Speciale coupes and Spider convertibles. The steering wheel was a three-spoke item with centre hornpush, also similar to that of the more sporting models. Braking was by discs all around, although the first cars used drums and early disc models lacked a servo which was introduced later. The police cars seen in The Italian Job were of this type. Tipo 105.06 was an austerity model made from 1964 to 1970 with a 1,290 cc single-carburettor engine for 77 hp at 6000 rpm. Four-speed gearbox with floor change fitted as standard (the 1300 was the only Giulia model not fitted with a five-speed gearbox). Though the engine was given a 105 series type number, it was basically the engine from the 101 series Giulietta Ti. This model appears not to have been exported to many markets outside Italy, if at all. Braking was by discs all around, without a servo at first, later with a servo. Tipo 105.26 was introduced in 1965. It transferred the technology from the racing TI Super to a road car, to make the most successful Giulia saloon. 1,570 cc engine with two double-choke Weber 40DCOE carburettors for a milder, but torquier tune than the TI Super – 97 hp at 5500 rpm. There was a new dashboard with two large round instruments (speedo and tacho) and clock, a sportier steering wheel with three aluminium spokes and centre horn push, similar to that of the Ti Super, later changed for one with the horn pushes in the spokes. All-around disc brakes with servo were fitted as standard from the outset. The serpent crest of the Sforza family appears in a badge on the C-pillar and is a distinguishing feature of the Super. For 1968, there was a suspension update, including revised geometry and a rear anti-roll bar. The wheels were changed in size from 5J x 15 to 5J x 14, and tyres from 155/15 to 165/14. For 1970, updates included dual-circuit brakes, centre-mounted handbrake lever to replace under-dash “umbrella handle”, larger external doorhandles, and top-hinged pedals (the latter in left hand drive models only; right hand drive continued with bottom-hinged pedals to the end of production). In 1972, Tipo 105.26 was rationalised into the Giulia 1.3 – Giulia 1.6 range. Tipo 105.39 built from 1965 to 1972. Right hand drive model replaced in 1970 by the 1300 Super. 1,290 cc engine with single down-draft carburettor for 81 hp at 6000 rpm. Unlike the re-deployed 101-series Giulietta engine of the austerity-model 1300, the 1300 ti motor was a 105 series engine, basically that of the sportier GT1300 Junior coupe with different camshaft timing (but the same camshafts) and induction system. Five-speed gearbox. Three-spoke bakelite steering wheel with plastic horn push covering the centre and spokes. Dashboard initially with strip speedo like that of the TI. For 1968, updates included a dashboard based on that of the Super, but with a simpler instrument binnacle, still featuring two large round instruments (speedo and tacho) and a separate fuel gauge, and the same suspension, wheel and tire updates applied to the Giulia Super in the same year. For 1970, updates included dual-circuit brakes, centre handbrake, larger external doorhandles and top-hinged pedals (on left hand drive cars only), again as applied to the Super for that year. Tipo 105.85 was basically a Giulia TI re-introduced in 1968 as a lower-level model to come between the 1300 and 1300 ti on one hand, and the Super on the other. It had a re-interpretation of the 1,570 cc single-carburettor engine for 94 hp at 5500 rpm and similar trim to the 1300 ti. Replaced in 1970 by the 1300 Super which offered similar performance in a lower tax bracket. The last cars from 1970 featured the top-hinged pedals, centre handbrake and dual-circuit brakes as for the Super and 1300 ti. Tipo 115.09 was introduced in 1970. It was basically a 1300 ti fitted with the engine from the GT 1300 Junior coupe that featured two double-choke horizontal carburettors; the engine actually had the GT 1300 Junior type number. This model was rationalised into the Giulia Super 1.3 – Giulia Super 1.6 range in 1972. In 1972 a rationalisation of the Giulia range saw the Super 1300 (Tipo 115.09) and the Super (Tipo 105.26) re-released as the Super 1.3 and Super 1.6. The two models featured the same equipment, interior and exterior trim, differing only in engine size and final drive ratio. The 1300 ti was dropped. A small Alfa Romeo badge on the C-pillar is a distinguishing feature, as are hubcaps with exposed wheel nuts. In December 1972 Alfa-Romeo South Africa released the 1600 Rallye. This locally developed more powerful 1600 cc version of the 1300 Super used the 1300’s single-headlight body shell. The car was largely ready for competition and was only planned to be built in limited numbers, and was fitted with racing-style rear-view mirrors, rally lamps, fully adjustable seats, and a limited-slip differential. Claimed power was 125 hp. The Giulia Super range was re-released in 1974 as the Nuova Super range, including the Giulia Nuova Super 1300 and 1600 This featured a new black plastic front grille and a flat boot lid without the characteristic centre spine. Otherwise the cars differed little from their Giulia Super predecessors and bore the same Tipo numbers with an S suffix. A Nuova Super fitted with a Perkins 1,760 cc diesel with 54 hp at 4000 rpm, was the firm’s first attempt at diesel power. The same Perkins diesel was used also in Alfa Romeo F12 van. The diesel version was slow, 138 km/h (86 mph), and the engine somehow unsuitable for a sport sedan so it was not big seller, only around 6500 examples were made in 1976 and the car was not sold in the UK. Production of the Giulia ceased in 1977. There are relatively few of these cars in the UK, and many of these are left hand drive models which have been re-imported relatively recently, or have been converted for historic racing, so it was good to see a nice road-going Berlina Super model here.

The 105 Series Coupe was well represented, as you might expect. There’s a complex history to this much-loved classic. The first car was called the Alfa Romeo Giulia Sprint GT, and was revealed at a press event held at the then newly opened Arese plant on 9 September 1963, and displayed later the same month at the Frankfurt Motor Show. In its original form the Bertone body is known as scalino (step) or “step front”, because of the leading edge of the engine compartment lid which sat 1/4 an inch above the nose of the car. The Giulia Sprint GT can be distinguished from the later models by a number of features including: Exterior badging: Alfa Romeo logo on the front grille, a chrome script reading “Giulia Sprint GT” on the boot lid, and rectangular “Disegno di Bertone” badges aft of the front wheel arches; flat, chrome grille in plain, wide rectangular mesh without additional chrome bars; single-piece chrome bumpers; no overriders. Inside the cabin the padded vinyl dashboard was characterised by a concave horizontal fascia, finished in grey anti-glare crackle-effect paint. Four round instruments were inset in the fascia in front of the driver. The steering wheel was non-dished, with three aluminium spokes, a thin bakelite rim and a centre horn button. Vinyl-covered seats with cloth centres and a fully carpeted floor were standard, while leather upholstery was an extra-cost option. After initially marketing it as a four-seater, Alfa Romeo soon changed its definition of the car to a more realistic 2+2. The Giulia Sprint GT was fitted with the 1,570 cc version of Alfa Romeo’s all-aluminium twin cam inline four (78 mm bore × 82 mm stroke), which had first debuted on the 1962 Giulia Berlina. Breathing through two twin-choke Weber 40 DCOE 4 carburettors, on the Sprint GT this engine produced 105 hp at 6,000 rpm. Like all subsequent models, the Sprint GT was equipped with an all-synchromesh 5-speed manual transmission. The braking system comprised four Dunlop disc brakes and a vacuum servo. The rear brakes featured an unusual arrangement with the slave cylinders mounted on the axle tubes, operating the calipers by a system of levers and cranks. According to Alfa Romeo the car could reach a top speed of “over 180 km/h (112 mph)”. In total 21,902 Giulia Sprint GT were produced from 1963 to 1965, when the model was superceded by the Giulia Sprint GT Veloce. Of these 2,274 were right hand drive: 1,354 cars fully finished in Arese, and 920 shipped in complete knock-down kit form for foreign assembly. For 1966, the Giulia Sprint GT was replaced by the Alfa Romeo Giulia Sprint GT Veloce, which was very similar but featuring a number of improvements: a revised engine—slightly more powerful and with more torque—better interior fittings and changes to the exterior trim. Alongside the brand new 1750 Spider Veloce which shared its updated engine the Sprint GT Veloce was introduced at the 36th Geneva Motor Show in March 1966, and then tested by the international specialist press in Gardone on the Garda Lake. Production had began in 1965 and ended in 1968. The Giulia Sprint GT Veloce can be most easily distinguished from other models by the following features: badging as per Giulia Sprint GT, with the addition of round enamel badges on the C-pillar—a green Quadrifoglio (four-leaf clover) on an ivory background—and a chrome “Veloce” script on the tail panel; black mesh grille with three horizontal chrome bars; the grille heart has 7 bars instead of 6; stainless steel bumpers, as opposed to the chromed mild steel bumpers on the Giulia Sprint GT. The bumpers are the same shape, but are made in two pieces (front) and three pieces (rear) with small covers hiding the joining rivets. Inside the main changes from the Giulia Sprint GT were imitation wood dashboard fascia instead of the previous anti-glare grey finish, front seats revised to a mild “bucket” design, and a dished three aluminium spoke steering wheel, with a black rim and horn buttons through the spokes. The Veloce’s type 00536 engine, identical to the Spider 1600 Duetto’s, featured modifications compared to the Giulia Sprint GT’s type 00502—such as larger diameter exhaust valves. As a result it produced 108 hp at 6,000 rpm, an increase of 3 hp over the previous model, and significantly more torque. The top speed now exceeded 185 km/h (115 mph). Early Giulia Sprint GT Veloces featured the same Dunlop disc brake system as the Giulia Sprint GT, while later cars substituted ATE disc brakes as pioneered on the GT 1300 Junior in 1966. The ATE brakes featured an handbrake system entirely separate from the pedal brakes, using drum brakes incorporated in the rear disc castings. Though the Sprint GT Veloce’s replacement—the 1750 GT Veloce—was introduced in 1967, production continued throughout the year and thirty final cars were completed in 1968. By then total Giulia Sprint GT Veloce production amounted to 14,240 examples. 1,407 of these were right hand drive cars, and 332 right hand drive complete knock-down kits. The Alfa Romeo 1750 GT Veloce (also known as 1750 GTV) appeared in 1967 along with the 1750 Berlina sedan and 1750 Spider. The same type of engine was used to power all three versions; this rationalisation was a first for Alfa Romeo. The 1750 GTV replaced the Giulia Sprint GT Veloce and introduced many updates and modifications. Most significantly, the engine capacity was increased to 1779 cc displacement. Peak power from the engine was increased to 120 hp at 5500 rpm. The stroke was lengthened from 82 to 88.5 mm over the 1600 engine, and a reduced rev limit from 7000 rpm to 6000 rpm. Maximum torque was increased to 137 lb·ft at 3000 rpm. A higher ratio final drive was fitted (10/41 instead of 9/41) but the same gearbox ratios were retained. The result was that, on paper, the car had only slightly improved performance compared to the Giulia Sprint GT Veloce, but on the road it was much more flexible to drive and it was easier to maintain higher average speeds for fast touring. For the United States market, the 1779 cc engine was fitted with a fuel injection system made by Alfa Romeo subsidiary SPICA, to meet emission control laws that were coming into effect at the time. Fuel injection was also featured on Canadian market cars after 1971. Carburettors were retained for other markets. The chassis was also significantly modified. Tyre size went to 165/14 from 155/15 and wheel size to 5 1/2J x 14 instead of 5J x 15, giving a wider section and slightly smaller rolling diameter. The suspension geometry was also revised, and an anti-roll bar was fitted to the rear suspension. ATE disc brakes were fitted from the outset, but with bigger front discs and calipers than the ones fitted to GT 1300 Juniors and late Giulia Sprint GT Veloces. The changes resulted in significant improvements to the handling and braking, which once again made it easier for the driver to maintain high average speeds for fast touring. The 1750 GTV also departed significantly from the earlier cars externally. New nose styling eliminated the “stepped” bonnet of the Giulia Sprint GT, GTC, GTA and early GT 1300 Juniors and incorporated four headlamps. For the 1971 model year, United States market 1750 GTV’s also featured larger rear light clusters (there were no 1970 model year Alfas on the US market). Besides the chrome “1750” badge on the bootlid, there was also a round Alfa Romeo badge. Similar Quadrofoglio badges to those on the Giulia Sprint GT Veloce were fitted on C pillars, but the Quadrofoglio was coloured gold instead of green. The car also adopted the higher rear wheelarches first seen on the GT 1300 Junior. The interior was also much modified over that of earlier cars. There was a new dashboard with large speedometer and tachometer instruments in twin binnacles closer to the driver’s line of sight. The instruments were mounted at a more conventional angle, avoiding the reflections caused by the upward angled flat dash of earlier cars. Conversely, auxiliary instruments were moved to angled bezels in the centre console, further from the driver’s line of sight than before. The new seats introduced adjustable headrests which merged with the top of the seat when fully down. The window winder levers, the door release levers and the quarterlight vent knobs were also restyled. The remote release for the boot lid, located on the inside of the door opening on the B-post just under the door lock striker, was moved from the right hand side of the car to the left hand side. The location of this item was always independent of whether the car was left hand drive or right hand drive. Early (Series 1) 1750 GTV’s featured the same bumpers as the Giulia Sprint GT Veloce, with the front bumper modified to mount the indicator / sidelight units on the top of its corners, or under the bumper on US market cars. The Series 2 1750 GTV of 1970 introduced other mechanical changes, including a dual circuit braking system (split front and rear, with separate servos). The brake and clutch pedals on left hand drive cars were also of an improved pendant design, instead of the earlier floor-hinged type. On right hand drive cars the floor-hinged pedals were retained, as there was no space for the pedal box behind the carburettors. Externally, the series 2 1750 GTV is identified by new, slimmer bumpers with front and rear overriders. The combined front indicator and sidelight units were now mounted to the front panel instead of the front bumper, except again on the 1971-72 US/Canadian market cars. The interior was slightly modified, with the seats retaining the same basic outline but following a simpler design. 44,269 1750 GTVs were made before their replacement came along. That car was the 2000GTV. Introduced in 1971, together with the 2000 Berlina sedan and 2000 Spider, the 2 litre cars were replacements for the 1750 range. The engine displacement was increased to 1962 cc. The North American market cars had fuel injection, but everyone else retained carburettors. Officially, both versions generated the same power, 130 hp at 5500 rpm. The interior trim was changed, with the most notable differences being the introduction of a separate instrument cluster, instead of the gauges installed in the dash panel in earlier cars. Externally the 2000 GTV is most easily distinguished by its grille with horizontal chrome bars, featuring protruding blocks forming the familiar Alfa heart in outline, smaller hubcaps with exposed wheel nuts, optional aluminium alloy wheels of the same size as the standard 5. 1/2J × 14 steel items, styled to the “turbina” design first seen on the alloy wheels of the Alfa Romeo Montreal, and the larger rear light clusters first fitted to United States market 1750 GTV’s were standard for all markets. From 1974 on, the 105 Series coupé models were rationalised and these external features became common to post-1974 GT 1300 Junior and GT 1600 Junior models, with only few distinguishing features marking the difference between models. 37,459 2000 GTVs were made before production ended and these days they are very sought after with prices having sky-rocketed in recent years.

Based on the Coupe, but with a model designation of its own, was the GTC, a stunningly pretty open topped model which was only produced for a year in 1965, in very limited numbers making them rare today with a total production of just 1000 cars in right and left hand drive versions. Only 99 were made for the British and South African market. It was based on the Giulia Sprint GT, with the cabriolet modification carried out by Touring of Milan. Besides the cabriolet top, a distinguishing feature is the dashboard finished in black instead of grey crackle. The model was badged with a script reading “Giulia Sprint GTC” on the bootlid. To restore some of the bodyshell rigidity lost by removing the fixed roof and pillars, Carrozzeria Touring added reinforcement to several areas of the bodyshell. Through the production life of the model, several modifications to the reinforcement applied were made by Touring, apparently in an effort to improve the stiffening achieved. Carrozzeria Touring was in financial trouble when the Giulia Sprint GTC went into production. The company went out of business shortly after production of this model ended.

This was the Giulia Sprint Speciale, the earlier version of a car which was produced between 1957 and 1965, latterly with Giulia badging. Just 1,366 examples were made. The first cars were fitted with the 1,290cc Giulietta engine and then in 1963 this was replaced by the more powerful 1,570cc Giulia unit. The SS, or Sprint Speciale series was never intended to be a volume car and it was considerably more expensive than the other models in the Giulietta and Giulia ranges. It certainly looked special, with streamlined bodywork which bore a marked resemblance to some of the marque’s earlier competition designs, particularly the famous Disco Volante sports-racer, not to mention the BAT 9 show car. With an all-up weight of under 950kgs, a five-speed gearbox and an output of 112bhp (in Giulia form) these were excellent road cars and were equally used in competition. They don’t come up for sale very often, and needless to say, the price tag is not small when they do.

The S4, the final major change to the long running Spider came in 1990, and mechanically, the biggest different was the use of Bosch Motronic electronic fuel injection with an electric fan. Externally, the Spider lost its front under-bumper spoiler and the rather ungainly rear boot spoiler of the S3, and picked up 164-style rear lights stretching across the width of the car as well as plastic bumpers the same colour as the car. This also marked the first generation of the car with automatic transmission, as well as on-board diagnostics capabilities. The car had remained in production largely thanks to continued demand in North America, though this market had to wait until 1991 for the changes to appear on their cars. European markets were offered a car with a 1600cc engine and carburettors as well as the 2 litre injected unit. Production finally ended in 1993, with an all new model, the 916 Series Spider appearing a year later. The S4 car was not officially sold in the UK, but plenty have found their way to our shores since then.

As was still the practice in the 1970s, Alfa followed up the launch of the Alfetta Berlina with a very pretty coupe. Styled by Giugiaro, this car, initially called the GT, and premiered in the autumn of 1974, looked completely unlike the saloon on which it was based. The first cars had 1.8 litre four cylinder engines and there was one of those on show. In 1976 the range was expanded both up and down with a 1.6 and a 2.0 model, the latter adopting the legendary GTV name. A rare SE model from this period was part of the display, complete with period vinyl roof (look closely), and although the pain does appear a bit like a lot of older Alfa reds, having gone rather pink, this was the actual shade when the car was new. In 1981, with the 2.5 litre V6 engine that had been developed for the ill-fated Alfa 6 luxury saloon available, Alfa was able to create a true rival for the 2.8 litre Capri with the GTV6. A facelift modernised the look of the car with plastic bumpers front and rear and a new interior looked rather better as well as being more ergonomically logical. There was a good mix of the earlier chrome bumpered and later plastic bumpered models, the last with 2.0 and 2.5 GTV6 versions both represented. There was also a car sporting 3.0 badging and right hand drive. This is a South African car. From 1974 South African Alfetta’s were manufactured at Alfa Romeo’s own Brits plant. South Africa was one of two markets to have a turbocharged GTV6, with a Garrett turbocharger and a NACA intake. An estimated 750 were assembled before all production ceased in 1986. The South African range included a 3.0 litre GTV-6, predating the international debut of the factory’s 3.0 litre engine in 1987 (for the Alfa 75). and 212 of these were built in South Africa for racing homologation. The last 6 GTV-6 3.0’s were fuel injected. To this day, the GTV-6 remains the quintessential Alfa Romeo for South Africans.

Follow on to the much-loved AlfaSud was the Alfa 33. Despite the low survival rate, believe it or not, the 33 is actually the best selling Alfa in history, with just under a million of them sold between 1983 and 1994. One reason why precious few seem to have survived is that the 33 struggled even new to gain the affections of the enthusiasts in the way that the model’s predecessor, the AlfaSud, did, so when rust and old age came on, the vast majority of the cars were simply scrapped. There were two distinct generations of the 33. The first ran from 1983 until 1990 and then a major facelift was applied with new front and rear styling to bring the looks more into line with the new 164. A mild facelift was applied to the first 905 series cars in late 1986. Exterior alterations were limited to clear indicator lens, wheel covers and alloy wheels of new design, the adoption of side skirts on all models, and a new front grille. Two-tone paint schemes were discontinued. There were more significant changes inside, with a more conventionally designed dashboard and steering wheel, which superseded the innovative moveable instrument binnacle. All 1.5 variants now had the 105 PS engine from the now discontinued 1.5 QV; a TI (Turismo Internazionale) trim level was exclusive to the front-wheel drive 1.5 hatchback. Changes were made to the suspension, brakes and gearbox, with closer-spaced ratios. A new 1,712 cc 116 bhp engine was introduced on the 1.7 Quadrifoglio Verde, which replaced the 1.5 QV. The 1.7 engine was developed from the 1.5 by enlarging bore and stroke; it also used new cylinder heads, incorporating hydraulic tappets. To cope with the increased power the new QV was equipped with vented front brake discs. The 1.7 QV looked close to its predecessor, but had lost the grey mid-body stripe and gained new alloy wheels, wind deflectors on the front windows, more pronounced side skirts and a rear body-colour spoiler on the boot lid. Inside it featured a leather-covered steering wheel, red carpets, and leatherette-backed sport seats upholstered in a grey/black/red chequered cloth. Diesel models were offered in some continental markets, but these were not sold in the UK, where only 1.5 and 1.7 Green Cloverleaf hatchback models were sold, as well as a market-specific 1.7 Sportwagon estate; all three were also available in “Veloce” versions, outfitted by Alfa Romeo GB with a colour-matching Zender body kit.

The 155 was one of a series of cars built by the Fiat Group on a shared platform, the so called Tipo 3 or Tipo Tre, which sat under the Fiat Tipo, and Lancia Delta 2, as well as the Fiat Coupe. Built to replace the rear wheel drive 75, the 155 was somewhat larger in dimension than its predecessor. The 155 was designed by Italian design house I.DE.A Institute which achieved an exceptional drag coefficient of 0.29, and the rather boxy design gave the car a sizeable boot, as well. The single most significant technical change from the 75 was the change to a front-wheel drive layout. This new configuration gave cost and packaging benefits but many Alfa die-hards and the automotive press lamented the passing of the “purer” rear-wheel drive layout on a car from this sporting marque. Not even the availability of the 155 Q4, which had a 2.0-litre turbocharged engine and a permanent four-wheel drive powertrain, both derived from the Lancia Delta Integrale; making the car essentially a Lancia Delta Integrale with a different body was enough to win the sceptics over. Reception of the model was generally lukewarm. The 75 had been conceived prior to Fiat’s acquisition of the Alfa brand, so as “the last real Alfa” it cast rather a shadow over the 155; the loss of rear-wheel drive was frequently cited as the main cause of the disappointment. Nevertheless, the 155 was entered in Touring Car racing and was successful in every major championship it entered, which gradually improved its image. Belatedly, the factory introduced a wider version in 1995 (the “wide-body”) which as well as a wider track and revised steering based on racing experience or requirements, also brought in new 16-valve engines for the 1.8 and 2.0-litre whilst retaining the 2.5 V6 and making some improvements to cabin materials and build quality. There were several Sport Packs available, including a race-inspired body kit (spoiler and side skirts) and black or graphite-coloured 16-inch Speedline wheels. The more genteel could opt for the Super which came with wood inserts in the cabin and silver-painted alloy wheels. With this version, the 155 really came good. When production ceased in 1998, following the launch of the 156, 192,618 examples had been built.

The 916 Series GTV and Spider were conceived to replace two very different models in the Alfa range. First of these was the open topped 105 Series Spider which had been in production since 1966 and by the 1990s was long overdue a replacement. Alfa decided to combine a follow on to the Alfetta GTV, long out of production, with a new Spider model, and first work started in the late 1980s. The task was handed to Pininfarina, and Enrico Fumia’s initial renderings were produced in September 1987, with the first clay models to complete 1:1 scale model made in July 1988. Fumia produced something rather special. Clearly an Italian design, with the Alfa Romeo grille with dual round headlights, recalling the Audi-based Pininfarina Quartz, another design produced by Enrico Fumia back in 1981, the proposal was for a car that was low-slung, wedge-shaped with a low nose and high kicked up tail. The back of the car is “cut-off” with a “Kamm tail” giving improved aerodynamics. The Spider would share these traits with the GTV except that the rear is rounded, and would feature a folding soft-top with five hoop frame, which would completely disappear from sight under a flush fitting cover. An electric folding mechanism would be fitted as an option. Details included a one-piece rear lamp/foglamp/indicator strip across the rear of the body, the minor instruments in the centre console angled towards the driver. The exterior design was finished in July 1988. After Vittorio Ghidella, Fiat’s CEO, accepted the design, Alfa Romeo Centro Stile under Walter de Silva was made responsible for the completion of the detail work and also for the design of the interiors, as Pininfarina’s proposal was not accepted. The Spider and GTV were to be based on the then-current Fiat Group platform, called Tipo Due, in this case a heavily modified version with an all new multilink rear suspension. The front suspension and drivetrain was based on the 1992 Alfa Romeo 155 saloon. Chief engineer at that time was Bruno Cena. Drag coefficient was 0.33 for the GTV and 0.38 for the Spider. Production began in late 1993 with four cars, all 3.0 V6 Spiders, assembled at the Alfa Romeo Arese Plant in Milan. In early 1994 the first GTV was produced, with 2.0 Twin Spark engine. The first premiere was then held at the Paris Motor Show in 1994. The GTV and Spider were officially launched at the Geneva Motor Show in March 1995 and sales began the same year. The cars were well received. At launch, many journalists commented that Alfa had improved overall build quality considerably and that it came very close to equalling its German rivals. I can vouch for that, as I owned an early GTV for eighteen months, and it was a well built and reliable car. In 1997 a new engine, a 24-valve 3.0 litre V6, was available for the GTV along with bigger, 12.0 inch brakes and red four-pot calipers from Brembo. The console knobs were changed from round central to rectangle ones and to a three-spoke steering wheel. Some versions were upgraded with different front bumper mesh to bring the wind noise down to 74 dBA. In May 1998 the cars were revamped for the first time, creating the Phase 2 models. Most of the alterations were inside. The interior was changed with new centre console, painted letters on skirt seals, changed controls and switches arrangement and different instrument cluster. Outside, the main changes included chrome frame around the grille and colour-coded side skirts and bumpers. A new engine was introduced, the 142 hp 1.8 Twin Spark, and others were changed: the 2.0 Twin Spark was updated with a modular intake manifold with different length intakes and a different plastic cover. Power output of the 2.0 TS was raised to 153 hp. Engines changed engine management units and have a nomenclature of CF2. The dashboard was available in two new colours in addition to the standard black: Red Style and Blue Style, and with it new colour-coded upholstery and carpets. The 3.0 24V got a six-speed manual gearbox as standard and the 2.0 V6 TB engine was now also available for the Spider. August 2000 saw the revamp of engines to comply with new emission regulations, Euro3. The new engines were slightly detuned, and have a new identification code: CF3. 3.0 V6 12V was discontinued for the Spider and replaced with 24V Euro3 version from the GTV. 2.0 V6 Turbo and 1.8 T.Spark were discontinued as they did not comply with Euro3 emissions. By the 2001-2002 model year, only 2 engines were left, the 2.0 Twin.Spark and 3.0 V6 24V, until the Phase 3 engine range arrived. The Arese plant, where the cars had been built, was closing and, in October 2000, the production of GTV/Spider was transferred to Pininfarina Plant in San Giorgio Canavese in Turin. In 2003 there was another and final revamp, creating the Phase 3, also designed in Pininfarina but not by Enrico Fumia. The main changes were focused on the front with new 147-style grille and different front bumpers with offset numberplate holder. Change to the interior was minimal with different centre console and upholstery pattern and colours available. Instrument illumination colour was changed from green to red. Main specification change is an ASR traction control, not available for 2.0 TS Base model. New engines were introduced: 163 hp 2.0 JTS with direct petrol injection and 237 hp 3.2 V6 24V allowing a 158 mph top speed. Production ceased in late 2004, though some cars were still available for purchase till 2006. A total of 80,747 cars were made, and sales of the GTV and Spider were roughly equal. More V6 engined GTVs than Spiders were made, but in 2.0 guise, it was the other way round with the open model proving marginally more popular.

Rather than replacing the 916 Series GTV with a single model, Alfa elected to produce two successors., The more commodious of the two, the GT, was the first to appear, making its debut in March 2003 at the Geneva Motor Show, finally going on sale in early 2004. It was built at the Pomigliano plant, alongside the 147 and 159. The GT was based on the Alfa 156 platform, which was also used for the 147, providing the 2-door coupé with genuine five-passenger capacity. It was styled by Bertone. Most mechanicals were taken directly from the 156/147 using the same double wishbone front suspension and MacPherson rear setup. The interior was derived form the smaller hatchback 147 and shared many common parts. The GT shared the same dash layout and functions, the climate control system as well as having a similar electrical system. Some exterior parts were taken from 147 with the same bonnet, wing mirrors and front wings (from 147 GTA). The engine range included both a 1.8 TS, and 2.0 JTS petrol engine, a 1.9 MultiJet turbodiesel, and a top-of-the-range 240 bhp 3.2 V6 petrol. There were few changes during the GT’s production life. In 2006 Alfa introduced a 1.9 JTD Q2 version with a limited slip differential, and also added a new trim level called Black Line. In 2008 Alfa introduced the cloverleaf model as a limited edition complete with new trim levels, lowered suspension, body kit, 18 inch alloy wheels and was only available in the colours black, Alfa red, or blue. with 1.8 and 2.0 litre petrol engines as well as the 1.9 litre Multijet turbo diesel. The GT was acclaimed for its attractive styling and purposeful good looks, in 2004 being voted the world’s most beautiful coupe in the annual ‘World’s Most Beautiful Automobile’ (L’Automobile più Bella del Mondo) awards. The car sold reasonably well, with 80,832 units being produced before the model was deleted in 2010.

The other 916 series replacement cars were the Brera and Spider models, and there were a lot of them here. Visually similar to the 159 models at the front, the Brera and Spider boasted unique styling from the A pillars rearwards. They were offered with the same range of engines as the 159, and thanks to that strong, but rather heavy platform on which they were built, even the 3.2 litre V6 cars were more Grand Tourer than rapid sports car. Pininfarina was responsible for both models. The Brera was first to market, in 2005, with the Spider following in 2006. Production of both ceased in late 2010, by which time 12,488 units of the Spider and 21,786 units of the Brera had been built. It will be very surprising if these do not attain classic status, and the consequent rise in values, though that has not happened yet.

First seen as a concept at the 2011 Geneva Show, the production 4C Competizione model did not debut for a further 2 years. Production got underway later that year at the Maserati plant in Modena, and the first deliveries were late in 2013. Production was originally pegged at 1000 cars a year and a total of just 3500, which encouraged many speculators to put their name down in the hope of making a sizeable profit on selling their cars on. That plan backfired, and in the early months, there were lots of cars for sale for greater than list price. Press reaction to the car has been mixed, with everyone loving the looks, but most of them feeling that the driving experience is not as they would want. Owners generally disagree – as is so often the case! For sure, it has no radio, and no carpets and no luggage space to speak of, but you know that when you buy it. It won’t be the car everyone, but if you can live with these limitations, you are sure to enjoy it. Indeed, all owners I have ever spoke to do love their car. I know I would if I could find space (and funds!) for one in my garage!

Also here was the new Giulia saloon.

ALLARD

This is an L Type, a 4-seat roadster, produced from 1946 to 1950. It sat on a 112-inch wheelbase and was available with a choice of 3622 cc Ford V8 or 4375 cc Mercury engines. The top speed is estimated to be 85 mph. Priced at a little more than £1000, 191 were produced

ALPINA

The Alpina Owners Club always seem to have a strong showing here with lots of different models on here, reminding us that there have been Alpina versions of most BMWs for longer than we perhaps realise.

Not seen very often are Alpina versions of the E24 6 series. A number of different versions were produced, in B7, B9 and B10 versions. Only small numbers of each were produced.

This one was based on the E36. During the lifetime of this generation of 3 Series, Alpina produced quite an array of different versions: the B6 2.8, B3 3.0, B3 3.2, B8 4.0 and B8 4.6. The B3 and B6 models were powered by straight-six engines, while the B8 models were powered by V8 engines. A full range of bodystyles was available.

The B3 3.3 version of the E46 3 Series was launched in saloon form at the 1999 Geneva Show, with the coupe following at Frankfurt later in the year., the Touring at Geneva in 2000 and finally a convertible at the 2000 Birmingham Show It had an engine which was based on that of the US spec M3 unit. but enlarged with longer bore and stroke, as well as a different cylinder head and lighter pistons, giving it an output of 280 bhp. A six speed Getrag manual box was standard with a five speed Switchtronic unit an option. The suspension was uprated with stiffer dampers. Outside the changes were subtle with larger spoilers front and rear the only clue if the customer opted not to have the marque’s distinctive pin-striping. Inside there were the usual Alpina touches including sports seats in Alpina stitched leather and bespoke instruments. In 2002, Alpina updated the car to the 3.3S, with a more powerful 305 bhp of the same engine. Most of these cars were based on the post-facelift E46.

The BMW E60 and the 4.4-litre BMW N62 engine from the 545i serve as the basis for the Alpina B5. Compared to the E60, the B5 has larger brakes, a new suspension with Electronic Damper Control, a stainless steel silencing system with polished double tailpipes and the typical Alpina changes to the interior and exterior. An uprated B5S followed after a couple of years.

More recent models were this E92 B3 coupe and a D3 Touring from the current F31 generation.

ALVIS

The Alvis Fourteen also known as TA 14 was the first car to be produced by major defence contractor Alvis cars after World War II. The entire car factory had been destroyed on the night of Thursday 14 November 1940. Announced in November 1946 it was made until 1950 when its postwar austerity 1900 cc engine was replaced by the 2993 cc Alvis Three Litre or TA 21. The Fourteen was available as a four-door sports saloon built for Alvis by Mulliners of Birmingham but there were also Tickford and Carbodies drophead versions. When compared with the 12/70 car it replaced the interior is 4 inches wider and the distance between rear-seat armrests is increased almost 5 inches. The 1892 cc engine is a slightly larger-bore version of the one used in the 12/70 and produced 65 bhp. It is fitted with a single SU type H4 -inch side-draught carburettor. Inlet valves have been enlarged. The triplex chain drive has been given an automatic tensioner. The engine’s exhaust system has been extensively revised and the direction of flow of cooling water around the engine has been substantially changed. The bodies were mounted on an updated pre-war Alvis 12/70 chassis that was widened and lengthened but retained the rigid-axle leaf spring suspension. Employing Silentbloc bushes (except at the front of the front springs to maintain steering precision) it is controlled by double acting Armstrong hydraulic dampers. Hypoid bevel final drive was fitted for the first time and greatly reduced the height of the transmission tunnel. Steering is by Marles with a spring spoked steering wheel. Mechanically operated brakes are two-leading-shoe type by Girling. Disc wheels replaced the 12/70’s wire wheels and are fitted with larger tyres. The top speed is around 74 mph and acceleration from 0 to 60 mph in 22.2 seconds. This is one of a handful of cars which were built with a “woodie” style body.

ASTON MARTIN

The Aston Martin Le Mans was a two or four seat sports car made by Aston Martin between 1932 and 1934. Aston Martin’s single-overhead-cam engine with a Bore/Stroke of 69.3 mm x 99 mm, had first been seen in the 1927 models, was highly efficient and now had an output of 70 brake horsepower (52 kW) at 4750 rpm from 1.5 litres, an outstanding development by early 1930s standards. Twin Horizontal SU carburettors were fitted. The aluminium body was mounted on a separate steel chassis which had beam axles front and rear with semi-elliptic leaf springs. 4-Wheel drum brakes, mechanically operated at the rear, and by cable at the front were used. During 1932 the Aston Martin International Le Mans had slowly sold at £650; the 1933 Aston Martin Le Mans model retailed at £595, thereby increasing the chance of the car selling faster. Aston Martin, encouraged by the car’s reception, began to offer alternative wheelbase lengths: 102 inches/2591 mm or 120 inches/3048 mm and a choice of open two-seater or four-seater bodywork. The cars were long, low and immediately recognisable by their unique radiator style and had great character making all the appropriate mechanical noises that characterised Aston Martin. Aston Martin made the cars exclusive; between 1932 and 1933, only 130 were produced.

The DB2/4 was the first new post-war Aston, and the first car to adopt the now legendary DB naming convention, reflecting the fact that in 1947 David Brown had bought the Aston Martin and Lagonda companies and incorporated them as Aston Martin Lagonda Ltd. Lagonda’s 2.6 litre dual overhead cam, straight-six engine, more powerful than the pushrod 1.9 litre unit in the Aston Martin 2-Litre Sports, was the main objective in Brown’s acquisition of the company. W. O. Bentley had supervised the engine’s design, which was largely by William (Willie) Watson, an engineer with the pre-war Invicta company who had collaborated on Lagonda’s pre-war V12 and also designed the short-lived post-war version. Work then started on producing a new car, which was called the DB2. This new model would utilise a version of the Lagonda engine in a shortened version of the tube-frame chassis designed by Claude Hill for the Aston Martin 2-Litre Sports, with a fastback coupé body designed by Frank Feeley. Three pre-production cars were entered for the 1949 24 Hours of Le Mans. One, which would become the development car for the production DB2, had the Lagonda straight-6, while the four-cylinder Aston Martin 2-litre unit powered the other two. After six laps the Lagonda-powered car, driven by Leslie Johnson, retired with overheating caused by failure of the water pump. One of the 2-litre cars was in 4th place and running without brakes when it crashed two hours short of the finish, fatally injuring driver Pierre Maréchal. The other finished 7th, crewed by Arthur Jones and Nick Haines. A month later, the larger-engined car, driven by Leslie Johnson and Charles Brackenbury, finished 3rd in the Spa 24-hour race, where one of the 2-litre cars was driven to 5th by Nick Haines and Lance Macklin. For 1950 all three factory team cars were equipped with the Lagonda engine. At the 1950 Le Mans race the one driven by George Abecassis and Lance Macklin finished 5th, with Brackenbury and Reg Parnell bringing another home 6th, which won Aston Martin 1st and 2nd in the 3-litre class. Across the Atlantic, Briggs Cunningham drove his DB2 to 2nd in its class at the inaugural Sebring race meeting in December 1950. The factory team cars continued racing in Europe throughout 1951, including at Le Mans, where Macklin and Eric Thompson took 3rd overall, with Abecassis and Brian Shawe-Taylor 5th. David Brown soon embarked on a series of Aston Martins designed specifically for competition use, starting with the DB3. Meanwhile, the production DB2 debuted at the New York Auto Show in April 1950 and continued in production until April 1953, by which time 411 had been made. The first 49 had a chrome-framed front grille in three separate parts, and large rectangular cooling vents in the front wings. Subsequent cars had a one-piece grille with horizontal chrome slats, and no side vents. The single-piece bonnet was hinged at the front. At the rear of the fixed-head coupé (FHC) a small top-hinged lid gave access to the spare wheel, and luggage space was behind the front seats, accessible only from inside the car. Later in 1950, a Drophead Coupé (DHC) variant was introduced. At least 102 were built. In April 1950, an engine with larger carburettors, inlet camshaft the same as the exhaust (for increased duration), and higher compression ratio pistons (8.16:1) was made available. Aston Martin’s first Vantage upgrade option offered 125 hp. Initially the higher compression ratio made the engine unsuitable for the British market, as the postwar austerity measures of the early 1950s restricted UK vehicles to 72 octane “Pool petrol”. The first DB2 Vantage, LML 50/21, was delivered to, and raced by, Briggs Cunningham in the United States. A revised version of the DB2 was launched in 1953, called the DB2/4. It was available as a 2+2 hatchback, marketed as a Saloon, as a Drophead Coupé (DHC) and as a 2-seat Fixed Head Coupe. A small number of Bertone bodied spiders were commissioned by private buyers. A further update in 1957 created the Mark III, and this was produced until the launch of the DB4 in 1958.

This is a DBR1. The race rules for sports cars were changed in 1956 so that they no longer had to be road legal to qualify for entry to the track. This meant that Aston Martin (and others) had a free hand in the future design of racers, and so work could begin on the creation of the DBR1. Using the DB3S as a basis, a new lightweight space frame chassis was created, and to it was added the suspension and disc brakes from the DB3S. Designated the DBR1/1, it was powered by a new all-aluminium 2.5 litre, straight six, racing engine, based on the 2.6 litre Lagonda straight six used in the DB2. The car made its debut at Le Mans in 1956, where is was forced to retire due to gearbox failure. However, following various changes, it took second place in two events as part of the 1957 World Sports Car Championship. Later in 1957, DBR1/1 and the identical DBR1/2 were fitted with a 3 litre updated version of the 2.9 litre engine from the DB3S, which developed 255 bhp at 6250 rpm, and was capable of 165 mph. With a compression of 9.3:1, it was fitted with three Weber twin choke carburettors, an aluminium block and head, Girling disc brakes all round, and a five speed manual David Brown gearbox. Using magnesium body panels on a chrome-molybdenum multi-tubular chassis, the car weighed only 800 kg. In 1957, both DBR1/1 and DBR1/2 were victorious in the Spa Three Hour race and the Nurburgring 1000 km race, but the two failed to finish in that years Le Mans. One noticeable weakness of the DBR1 was its own DB gearbox which was known to be extremely fragile. Subsequently, in 1959, Stirling Moss was impressed when driving a DBR1, in practice, fitted with a Maserati five speed unit, which overcame the fragility problem. In 1958, in order to counter competition fitted with more powerful engines during sprint events, Aston Martin developed the DBR2 sports car, which was powered by a newly designed 3.7 litre, straight six unit from the Aston Martin DB4, and used in non-championship races. With the addition of the variant DBR1/3, this car won the 1958 Nurburgring 1000 km race at the hands of Stirling Moss. However, once again, the three DBR1’s were unable to finish in that years Le Mans. In the Tourist Trophy race at the end of 1957, the three DBR1’s finished in first, second, and third positions, allowing Aston Martin to finish second in the Constructor’s Championship, behind Ferrari. In 1959, DBR1/4 and DBR1/5 were completed, and one of the DBR1’s, driven by Stirling Moss, again won the Nurburgring 1000 km race. Ultimately, the DBR1’s zenith was when DBR1/2, driven by Carroll Shelby and Roy Salvadori, won the 1959 Le Mans 24 Hour race, with DBR1/4 taking second position. Later that year, DBR1/2 won the Tourist Trophy, with DBR1/4 taking fourth place, which was sufficient for Aston Martin to pass Ferrari and win the 1959 Constructor’s World Championship. This was the only time Aston Martin ever won this accolade. By the end of 1959, when production of the DBR1 ended, just five of these cars had been built, designated DBR1/1-5.

The DB4 was a development of the DB Mark III it replaced but with a completely new body. The DB4’s design formed the basis for later Aston Martin classics, such as the DB4 GT Zagato, the Lagonda Rapide 4-door saloon. It was eventually replaced by the Aston Martin DB5. The lightweight superleggera (tube-frame) body was designed by Carrozzeria Touring in Milan, and its Continental looks caused a sensation on its unveiling at the 1958 London Motor Show. Although the design and construction techniques were Italian, the DB4 was the first Aston to be built at the company’s Newport Pagnell works. The 3670 cc engine, designed by Tadek Marek, was a double overhead cam straight-6, with cylinder head and block of cast R.R.50 aluminium alloy, a further development of the earlier engine. The engine was prone to overheating initially, but the 240 hp produced by the twin-SU carburettor version made buyers forgive this unfortunate trait[citation needed]. Servo-assisted disc brakes were fitted all round: early 11.5 in Dunlops were replaced by Girlings. The independent front suspension used ball-jointed wishbones, coil springs and rack-and-pinion steering. The live rear axle also used coil springs and was located by a Watt’s linkage. The normal final-drive ratio for British and European use was 3.54:1: in the United States the ratio was usually 3.77. Customers wanting a car with an especially high top speed could choose a 3.31:1 ratio. A car with the British standard 3.54 final drive ratio tested by The Motor magazine in 1960 had a top speed of 139.3 mph and could accelerate from 0-60 mph in 9.3 seconds. A fuel consumption of 17.7 mpg. The test car cost £3967 including taxes. There were five “series” of DB4. The most visible changes were the addition of window frames in Series II and the adoption of a barred (rather than eggcrate) grille in Series IV. The Series III cars differed from the earlier ones in having taillights consisting of three small lamps mounted on a chrome backing plate. Earlier cars have single-piece units and the last Series V cars of September 1962 have similar taillights but recessed. The Series V also has a taller and longer body to provide more interior space, though the diameter of the wheels was reduced to keep the overall height the same. The front of the Series V usually was of the more aerodynamic style as already used on the Vantage and GT models, a style that was later carried over to the DB5 cars. A convertible was introduced in October 1961. It featured in-house styling similar to the Touring saloon, and an extremely rare factory hardtop was also available. In total, 70 DB4 convertibles were made from a total DB4 production run of 1,110 cars. 30 of these were Series IV, with the remaining 40 belonging to the Series V. 32 of the total convertibles built (11 and 21 of the different series respectively) were equipped with the more powerful Vantage engine. Top speed for the regular version is about 136 mph.

There were a number of DB6 cars, a model which was launched in 1965 as a replacement for the DB5 which had run since 1963. The wheelbase was now 4″ longer than before, resulting in an extensive restyle with a more raked windscreen, raised roofline and reshaped rear quarter windows. Opening front quarter lights made a reappearance, but the major change was at the rear where a Kamm tail with spoiler improved the aerodynamics, greatly enhancing stability at high speeds. “The tail lip halves the aerodynamic lift around maximum speed and brings in its train greater headroom and more luggage space”, declared Motor magazine, concluding that the DB6 was one of the finest sports cars it had tested. Famed employee, Tadek Marek, designed the six cylinder engine, which had been enlarged to 3,995cc for the preceding DB5 and remained unchanged. Power output on triple SU carburettors was 282bhp, rising to 325bhp in Vantage specification. Premiered at the 1965 London Motor Show, the DB6 Volante marked the first occasion the evocative ‘Volante’ name had been applied to a soft-top Aston Martin. After 37 Volante convertibles had been completed on the DB5 short wheelbase chassis, the model adopted the longer DB6 chassis in October 1966. A mere 140 DB6 based Volantes were manufactured, and of these only 29 were specified with the more powerful Vantage engine.

Representing the longest lived design in Aston Martin’s history were a number of DBS and V8 cars. By the mid 1960s, Aston Martin’s customers had been clamouring for an eight-cylinder car, so Aston Martin designed a larger car. The engine was not ready, however, so in 1967 the company released the DBS with the straight-six Vantage engine from the DB6. Two years later, Tadek Marek’s V8 was ready, and Aston released the DBS V8. Though the body and name was shared with the six-cylinder DBS, the V8 sold for much more. The body was a modern reinterpretation of the traditional Aston Martin look, with a squared-off grille and four headlights (though some consider the styling derivative of the early Ford Mustang). Distinguishing features of the V8 model are the larger front air dam and lack of wire wheels, though some six-cylinder DBS cars also used the V8’s alloy wheels. The tail lights were taken from the Hillman Hunter. A road test report of the time noted that the car had gained 250 lb in weight with the fitting of the V8 in place of the previously used six-cylinder unit, despite the manufacturer’s assurance that the engine weighed only 30 lb more than the older straight-six. Other contributions to the weight gain included heavier ventilated brake discs, air conditioning, fatter tyres, a new and stronger ZF gearbox as well as some extra bodywork beneath the front bumper. Marek’s V8 engine displaced 5,340 cc and used Bosch fuel injection. Output was not officially released, but estimates centre around 315 hp. The DBS V8 could hit 60 mph in 5.9 seconds and had a top speed of nearly 160 mph. 402 DBS V8s were built. In April 1972, the DBS V8 became just the Aston Martin V8 as the six-cylinder DBS was dropped, leaving just this car and the six-cylinder Vantage in production. The V8 became known as the AM V8, a model retroactively referred to as the Series 2 V8 to separate it from later models. Visual differences included twin quartz headlights and a mesh grille, a front design which was to last until the end of production in 1989. AM V8 cars, produced from May 1972 through July 1973, used a similar engine to the DBS V8, albeit with Bosch fuel injection rather than the earlier carburettors. Just 288 Series 2 cars were built. Although David Brown had left the company, he had overseen development of this model. The first 34 cars still carried leftover “DBS V8” badging. The car switched back to Weber carburettors for the Series 3 in 1973, ostensibly to help the car pass new stricter emissions standards in California but most likely because Aston Martin was unable to make the Bosch fuel injection system work correctly. These cars are distinguished by a taller bonnet scoop to accommodate four twin-choke (two-barrel) Weber carbs. The car produced 310 hp and could reach 60 mph in 6.1 seconds with an automatic transmission or 5.7 with a manual. Performance suffered with emissions regulations, falling to 288 hp in 1976. The next year, a more powerful “Stage 1” engine with new camshafts and exhaust brought it up to 305 hp. Production of Series 3 cars lasted from 1973 through October 1978, but was halted for all of 1975. 967 examples were produced in this time. While earlier V8 cars have louvers cut into the little panel mounted beneath the rear windshield, the Series 3 and later cars instead have a small lip at the bottom of this panel, just ahead of the leading edge of the bootlid. The “Oscar India” specification was introduced in October 1978 at the Birmingham International Motor Show. Visually, the former scoop on the bonnet gave way to a closed “power bulge”, while a spoiler was integrated into the tail. Most Oscar India cars were equipped with a Chrysler “Torqueflite” three-speed automatic transmission, with wood trim fitted for the first time since the DB2/4 of the 1950s. Just 352 Oscar India models were built from 1978 through 1985. The power of the now de-smogged engines kept dropping on American market cars, down to a low of 245 hp in the early eighties. The convertible “Volante” was introduced in June 1978, but featured the Series 4 bonnet a few months before the coupé received the Oscar India update. The Volante Series 1 weighs 70 kg (155 lb) more than the coupé, due to the necessity of reinforcing the frame. US market cars received much larger bumpers beginning with the 1980 model year, adding weight and somewhat marring the car’s lines. Owners of US-specified cars often modify them to have the slimmer European bumpers. By 1981, the success of the Volante meant that the coupé model was only built on individual demand. The fuel-injected Series 5 cars were introduced in January 1986 at the New York International Auto Show. The compact Weber/Marelli system no longer needed the space of the previous carburettors, so the bonnet bulge was virtually eliminated. 405 Series 5 cars were built before production ceased in 1989. The Volante Series 2 received the same changes; 216 were built.

After a production run of over 20 years, Aston came up with a new body shape for the 1988 Birmingham Motor Show, and called the new car the Virage. Initially announced solely as a close coupe, it was not long before an open-topped model was added to the range and then in 1993, these were joined by the high-performance Vantage. The name of the base model was changed to V8 Coupé in 1996. The V8-powered model was intended as the company’s flagship model, with the 6-cylinder DB7, introduced in 1994, positioned below it as an entry-level model. Although the DB7 became available with a V12 engine and claimed a performance advantage, the Virage remained the exclusive, expensive and hand-built flagship of the Aston Martin range. It was replaced in 2000 with the Vanquish. By the end of the 2000 model year, 1,050 cars in total had been produced

With the DB7, produced from September 1994 to December 2004, Aston Martin made more cars from a single model than all Astons previously made, with over 7000 built. Known internally as the NPX project, the DB7 was made mostly with resources from Jaguar and had the financial backing of the Ford Motor Company, owner of Aston Martin from 1988 to 2007. The DB7’s platform was an evolution of the Jaguar XJS’s, though with many changes. The styling started life as the still-born Jaguar F type (XJ41 – coupe / XJ42 – convertible) designed by Keith Helfet. Ford cancelled this car and the general design was grafted onto an XJS platform. The styling received modest changes by Ian Callum so that it looked like an Aston Martin. The first generation Jaguar XK-8 also uses an evolution of the XJ-S/DB7 platform and the cars share a family resemblance, though the Aston Martin was significantly more expensive and rare. The prototype was complete by November 1992, and debuted at the Geneva Motor Show in March, 1993, with the car positioned as an “entry-level” model below the hand-built V8 Virage introduced a few years earlier. With production of the Virage (soon rechristened “V8” following Vantage styling revisions) continuing at Newport Pagnell, a new factory was acquired at Bloxham, Oxfordshire that had previously been used to produce the Jaguar XJ220, where every DB7 would be built throughout its production run. The DB7 and its relatives were the only Aston Martins produced in Bloxham and the only ones with a steel unit construction inherited from Jaguar . Aston Martin had traditionally used aluminium for the bodies of their cars, and models introduced after the DB7 use aluminium for the chassis as well as for many major body parts. The convertible Volante version was unveiled at the North American International Auto Show in Detroit in 1996. Both versions have a supercharged straight-six engine that produced 335 bhp and 361 lb·ft of torque. The Works Service provided a special Driving Dynamics package, which greatly enhanced performance and handling for drivers who wanted more than what the standard configuration offered. In 1999, the more powerful DB7 V12 Vantage was introduced at the Geneva Motor Show. Its 5.9 litre, 48-valve, V12 engine produced 420 bhp and 400 lb·ft of torque. It has a compression ratio of 10.3:1. Transmissions were available with either a TREMEC T-56 six speed manual or a ZF 5HP30 five speed automatic gearbox. Aston Martin claimed it had a top speed of either 186 mph with the manual gearbox or 165 mph with the automatic gearbox, and would accelerate from 0–60 mph in 4.9 seconds. It is 4,692 mm long, 1,830 mm (72.0 in) wide, 1,243 mm (48.9 in) high, with a weight of 1,800 kg (3,968.3 lb). After the launch of the Vantage, sales of the supercharged straight-6 engine DB7 had reduced considerably and so production was ended by mid-1999. In 2002, a new variant was launched, named V12 GT or V12 GTA when equipped with an automatic transmission. It was essentially an improved version of the Vantage, its V12 engine producing 435 bhp and 410 lb·ft of torque for the manual GT, although the automatic GTA retained the 420 bhp and 400 lb·ft of torque of the standard DB7 Vantage. Additionally, the GT and GTA chassis had substantially updated suspension from the DB7 Vantage models. Aesthetically, compared to the Vantage it has a mesh front grille, vents in the bonnet, a boot spoiler, an aluminium gear lever, optional carbon fibre trim and new wheels. It also has 14.0 in front and 13.0 in rear vented disc brakes made by Brembo. When being tested by Jeremy Clarkson on Top Gear in 2003, he demonstrated the car’s ability to pull away in fourth gear and continue until it hit the rev limiter: the speedometer indicated 135 mph. Production of the GT and GTA was extremely limited, as only 190 GT’s and 112 GTA’s were produced worldwide with 17 of them shipped to the US market, for a total of 302 cars

The Aston Martin V12 Vanquish was designed by Ian Callum and bore a large resemblance to the production DB7 Vantage. However, the car had a strong influence from the Project Vantage Concept prototype which debuted with a V12 engine at the North American International Auto Show in January 1998. As underneath the car featured a strong aluminium/carbon composite construction, bonded chassis with a 5,935 cc V12 engine. It was available in 2+0 and 2+2 seating configurations. The 48-valve 60° engine produces 460 bhp and 400 lb⋅ft of torque. It is controlled by a drive-by-wire throttle and a six-speed Electrohydraulic manual transmission. The standard Vanquish model had 14.0 inch drilled and ventilated disc brakes with four-pot calipers, ABS, with electronic brake distribution. Its appearance in the 2002 James Bond film Die Another Day earned the V12 Vanquish the number three spot on the list of Best Film Cars Ever, behind the Minis from The Italian Job, and DB5 from Goldfinger & Thunderball. The car also appears in the video games Need For Speed: Hot Pursuit 2, James Bond 007: Nightfire, and James Bond 007: Everything or Nothing. The Vanquish S debuted at the 2004 Paris Auto Show, with increased horsepower and performance and slight styling revisions. The engine displacement remained at 5,935 cc with power increased from 460 to 520 bhp. Visual changes included new wheels, a slightly different nose shape, a new raised bootlid with a larger integrated spoiler incorporating the third high level brake light (in the rear window on the original Vanquish), a Vanquish S badge on the bootlid (the original Vanquish had no rear model designation) and the addition of a small front splitter (although this was mainly done for aerodynamic reasons). As part of its improvements, the Vanquish S featured a slightly improved coefficient of drag of 0.32 (from 0.33), with help from a redesigned splitter and boot lid. Its front and rear track were 1,524 mm (60.0 inches) and 1,529 mm (60.2 inches), respectively. It also incorporated the features of a 2004 option package, the Sports Dynamic Pack, which incorporated sportier suspension, steering, and brake features. This model was sold for the 2005 (alongside the base Vanquish) and 2006 (as a stand-alone) model years in the United States with only minor running changes; it was not sold in the United States for 2007. The Vanquish S featured larger brakes than the V12 Vanquish; 14.9 in front discs with six-pot calipers and 13.0 inches rear discs. The end of the Vanquish’s production run was celebrated with the Vanquish S Ultimate Edition. Aston Martin announced that the last 50 cars built would have a new ‘Ultimate Black’ exterior colour, upgraded interior, and personalised sill plaques. 1086 Vanquish S were built. With a 200+ MPH top speed, the Vanquish S was (as measured by top speed capability) the fastest Aston Martin ever until the Vantage V12 S was introduced in May 2013. Vanquish production ended on 19 July 2007, coinciding with the closing of the company’s Newport Pagnell factory after 49 years of operation.

This is a DBS. Aston Martin had used the DBS name once before on their 1967–72 grand tourer coupe. The modern car replaced the 2004 Vanquish S as the flagship of the marque, and was a V12-engined super grand tourer based on the DB9. The DBS was officially unveiled at the 2007 Pebble Beach Concours d’Elegance on 16 August 2007, which featured a brand new exterior colour (graphite grey with a blue tint) which has been dubbed “Lightning Silver”, followed by an appearance at the 2007 Frankfurt motor show. Deliveries of the DBS began in Q1 2008. The convertible version of the DBS dubbed the DBS Volante was unveiled at the 2009 Geneva Motor Show on 3 March 2009. The DBS Volante includes a motorized retractable fabric roof controlled by a button in the centre console and can fold into the compartment located behind the seats in 14 seconds after the press of the button. The roof can be opened or closed while at speeds up to 48 km/h (30 mph). Apart from the roof, changes include a new wheel design available for both the coupé and volante versions and a 2+2 seating configuration also available for both versions. Other features include rear-mounted six-speed manual or optional six-speed ‘Touchtronic 2’ automatic gearbox, Bang & Olufsen BeoSound DBS in-car entertainment system with 13 speakers. Deliveries of the DBS Volante began in Q3 2009. The model was replaced by a new generation Vanquish in 2012.

Several of the current generation Vantage model were here. Following the unveiling of the AMV8 Vantage concept car in 2003 at the North American International Auto Show designed by Henrik Fisker, the production version, known as the V8 Vantage was introduced at the Geneva Motor Show in 2005. The two seat, two-door coupé had a bonded aluminium structure for strength and lightness. The 172.5 inch (4.38 m) long car featured a hatchback-style tailgate for practicality, with a large luggage shelf behind the seats. In addition to the coupé, a convertible, known as the V8 Vantage Roadster, was introduced later in that year. The V8 Vantage was initially powered by a 4.3 litre quad-cam 32-valve V8 which produced 380 bhp at 7,300 rpm and 409 Nm (302 lb/ft) at 5,000 rpm. However, models produced after 2008 had a 4.7-litre V8 with 420 bhp and 470 Nm (347 lbft) of torque. Though based loosely on Jaguar’s AJ-V8 engine architecture, this engine was unique to Aston Martin and featured race-style dry-sump lubrication, which enabled it to be mounted low in the chassis for an improved centre of gravity. The cylinder block and heads, crankshaft, connecting rods, pistons, camshafts, inlet and exhaust manifolds, lubrication system and engine management were all designed in house by Aston Martin and the engine was assembled by hand at the AM facility in Cologne, Germany, which also built the V12 engine for the DB9 and Vanquish. The engine was front mid-mounted with a rear-mounted transaxle, giving a 49/51 front/rear weight distribution. Slotted Brembo brakes were also standard. The original V8 Vantage could accelerate from 0 to 60 mph in 4.8 seconds before topping out at 175 mph. In 2008, Aston Martin introduced an aftermarket dealer approved upgrade package for power and handling of the 4.3-litre variants that maintained the warranty with the company. The power upgrade was called the V8 Vantage Power Upgrade, creating a more potent version of the Aston Martin 4.3-litre V8 engine with an increase in peak power of 20 bhp to 400 bhp while peak torque increased by 10 Nm to 420 Nm (310 lb/ft). This consists of the fitting of the following revised components; manifold assembly (painted Crackle Black), valved air box, right and left hand side vacuum hose assemblies, engine bay fuse box link lead (ECU to fuse box), throttle body to manifold gasket, intake manifold gasket, fuel injector to manifold seal and a manifold badge. The V8 Vantage had a retail price of GB£79,000, US$110,000, or €104,000 in 2006, Aston Martin planned to build up to 3,000 per year. Included was a 6-speed manual transmission and leather-upholstery for the seats, dash board, steering-wheel, and shift-knob. A new 6-speed sequential manual transmission, similar to those produced by Ferrari and Lamborghini, called Sportshift was introduced later as an option. An open-topped model was added to the range in 2006 and then in the quest for more power a V12 Vantage joined the range not long after.

Follow on to the DB7 was the DB9 (there has never been a car called DB8 – supposedly because people might have assumed this meant a V8 engine), and there was a nice example here. Designed by Marek Reichmann and Hendrik Fisker, the DB9 was first shown at the 2003 Frankfurt Auto Show, in coupe form. It was widely praised for the beauty of its lines. This was the first model to be built at Aston Martin’s Gaydon facility. It was built on the VH platform, which would become the basis for all subsequent Aston models. The Aston Martin DB9 was initially launched equipped with a 6.0 litre V12 engine, originally taken from the V12 Vanquish. The engine produced 420 lbf·ft of torque at 5,000 rpm and a maximum power of 444 hp at 6,000 rpm, allowing the DB9 to accelerate from 0 to 60 mph in 4.7 seconds and a top speed of 299 km/h (186 mph). The engine largely sits behind the front-axle line to improve weight distribution. Changes to the engine for the 2013 model year increased the power to 503 hp and torque to 457 lb-ft, decreasing the 0 to 60 mph time to 4.50 seconds and with a new top speed is 295 km/h (183 mph). The DB9 was available with either a six-speed conventional manual gearbox from Graziano or a six-speed ZF automatic gearbox featuring paddle-operated semi-automatic mode. The gearbox is rear-mounted and is driven by a carbon-fibre tail shaft inside a cast aluminium torque tube. The DB9 was the first Aston Martin model to be designed and developed on Ford’s aluminium VH (vertical/horizontal) platform. The body structure is composed of aluminium and composites melded together by mechanically fixed self-piercing rivets and robotic assisted adhesive bonding techniques. The bonded aluminium structure is claimed to possess more than double the torsional rigidity of its predecessor’s, despite being 25 percent lighter. The DB9 also contains anti-roll bars and double wishbone suspension, supported by coil springs. To keep the back-end in control under heavy acceleration or braking, the rear suspension has additional anti-squat and anti-lift technology. Later versions of the car also features three modes for the tuning: normal, for every-day use, sport, for more precise movement at the cost of ride comfort, and track, which furthers the effects of the sport setting. The Aston Martin DB9 Volante, the convertible version of the DB9 coupe, followed a few months later. The chassis, though stiffer, uses the same base VH platform. To protect occupants from rollovers, the Volante has strengthened windscreen pillars and added two pop-up hoops behind the rear seats. The hoops cannot be disabled and will break the car’s rear window if deployed. In an effort to improve the Volante’s ride while cruising, Aston Martin have softened the springs and lightened the anti-roll bars in the Volante, leading to a gentler suspension. The retractable roof of the Volante is made of folding fabric and takes 17 seconds to be put up or down. The Volante weighs 59 kilograms (130 pounds) more than the coupe. The coupe and Volante both share the same semi-automatic and automatic gearboxes and engine. The car was limited to 266 km/h (165 mph) to retain the integrity of the roof. Like the coupe, the original Volante has 420 lb·ft of torque at 5,000 rpm and a maximum power of 450 hp at 6,000 rpm. The 0 to 60 mph slowed to 4.9 seconds due to the additional weight. The DB9 was facelifted in July 2008, which mainly amounted to an increase in engine power, to 476 hp and a redesigned centre console. Externally, the DB9 remained virtually unchanged. For the 2013 model year revision, Aston made minor changes to the bodywork by adapting designs from the Virage, including enlarging the recessed headlight clusters with bi-xenon lights and LED daytime strips, widening the front splitter, updating the grille and side heat extractors, updating the LED rear lights with clear lenses and integrating a new rear spoiler with the boot lid. .On newer models, like the coupe’s, the Volante’s horsepower and torque increased to 517 PS (510 hp) and 457 lb·ft respectively. As a finale for the model, a more powerful DB9 was released in 2015, called the DB9 GT. This had 540 bhp and 457 lb-ft of torque at 5500 rpm, giving a 0 to 60mph time of 4.4 seconds and 0 to 100mph in 10.2 seconds, with the standing quarter mile dispatched in 12.8 to 12.9 seconds and a top speed of 183mph.

A new generation of the Virage was introduced at the 2011 Geneva Motor Show by Aston Martin. The Virage capitalised on the technology from the DBS and united it with the comfort and refinement found in the DB9 and Rapide. The Virage was intended to sit in the narrow slot between the basic DB9 and the flagship DBS. Aston Martin announced that the second generation of the Virage would be discontinued after 18 months of production, as the distinctions between it, the DB9, and the DBS were simply too slim. The car has a 2-seat or 2+2 seating configuration. The Virage’s 5.9-litre AM11 V12 engine has a power output of 497 PS and 570 Nm (420 lb/ft) of torque. It is capable of accelerating from 0 to 100 km/h (62 mph) in 4.6 seconds, and has a top speed of 300 km/h (186 mph), while the Virage Volante is limited to 295 km/h (183 mph). The Virage was available in two bodystyles: Coupé or Volante (convertible).

This version of the Vanquish started life as the Project AM310 Concept that was unveiled at the 2012 Concorso D’Eleganza at Villa D’Este on the shores of Lake Como, Italy. The concept car was based on the fourth generation VH platform. It included a tweaked version of Aston Martin’s familiar grille and headlight design and a more pronounced bulge in the bonnet – with the real One-77-inspired flourishes saved for the sides and the rear, the side vents run almost to the door handles (from One-77), new rear light design from One-77, and a 5.9-litre V12 engine that produced 550 PS. Aston Martin later announced that the concept would be put into production as the all new Aston Martin Vanquish. The exterior styling of the Vanquish is an evolution of the DBS with many styling cues such as the elongated side strakes being inspired by the Aston Martin One-77. The boot lid included an integrated rear spoiler designed to look as if it is impossible to make; this was done on the orders of Aston Martin Chief Executive, Dr. Ulrich Bez. The car has an exposed carbon fibre side skirt showing its all carbon fibre body. The Vanquish uses the new VH Generation IV platform which is lighter and uses more carbon fibre components than the VH Generation II platform used in the DBS. The car featured an all new interior based on the one found in the exclusive One-77. The standard interior was trimmed in hand stitched leather and alcantara and was available in a range of colours. The centre console features an revised infotainment system over the one found in the DBS. The car was available as either a 2-seater or 2+2. The Vanquish used an upgraded version of Aston Martin’s flagship 5.9-litre AM11 V12 engine called the AM28 with a power output of 565 bhp at 6,750 rpm and torque of 457 lb/ft at 5,500 rpm. The Vanquish can accelerate from 0 to 100 km/h (62 mph) in 4.1 seconds, and has a top speed of 295 km/h (183 mph). Like most Aston Martins, the engine is front mid-mounted for better weight distribution, with the power going to the rear wheels. The Vanquish has 51/49 front/rear weight distribution, and a kerb weight of 1,739 kg (3,834 lb). It uses a fully catalysed stainless steel exhaust system with active bypass valves. The Vanquish uses an updated Touchtronic II six-speed automatic gearbox. It was the first Aston Martin model to be available with launch control. The combined space of cabin and a boot that, at 368 litres, is more than 60% larger than that of the DBS. The brakes are ventilated carbon ceramic discs, 398 mm (15.7 in) six-piston callipers in the front and 360 mm (14.2 in) four-piston callipers in the rear. The suspension is a lightweight aluminium front subframe with hollow castings with independent double wishbones incorporating anti-dive geometry, coil springs, anti-roll bar, and monotube adaptive dampers in the front and independent double wishbones with anti-squat and anti-lift geometry, coil springs, anti-roll bar, and monotube adaptive dampers in the rear. It has a three-stage adjustable adaptive damping system including normal, sport and track modes. The tyres are Pirelli P Zeros, 255/ZR20 in the front and 305/30 ZR20 in the rear. The vehicle was unveiled in the London Film Museum, Covent Garden, followed by 2012 Monterey Car Week. Deliveries to UK and Continental Europe began in late 2012. In August 2014, Aston Martin revealed technical modifications to the Vanquish. The changes include a new eight-speed Touchtronic III gearbox and upgraded AM29 V12 engine that produces 568 bhp and torque of 465 lb/ft. The changes greatly enhanced performance, with an acceleration of 0 to 100 km/h (62 mph) in 3.6 seconds, and a top speed of 324 km/h (201 mph). In 2013, Aston Martin unveiled a convertible version of the Vanquish, called Volante. The Volante includes a full carbon fibre body, triple-skin lightweight fabric roof, 50% larger boot than its predecessor and the third generation Brembo 398 mm × 36 mm front and 360 mm × 32 mm CCM rear Carbon Ceramic Matrix (CCM) brake discs with six-piston front and four-piston rear brake callipers (from the One-77). The Vanquish Volante is 13% torsionally stiffer than the outgoing DBS Volante. The carbon fibre-skin of the Vanquish Volante was created by the engineering team at Aston Martin. The vehicle was unveiled at the 2013 Pebble Beach Concours d’Elegance. Deliveries to Europe began in late 2013. On 16 November 2016, Aston Martin announced the new Vanquish S model. The Vanquish S features the same AM29 V12 engine, with power now increased to 595 bhp, and a new aerodynamic package. The Vanquish S can accelerate from 0 to 100 km/h (62 mph) in 3.5 seconds, and the top speed remains unchanged at 201 mph (324 km/h). The starting price at launch was £199,950 and deliveries started in December 2016. Aston Martin also unveiled a convertible version of the Vanquish S called the Vanquish S Volante in 2017.

Also from the current range was this Rapide.

AUDI

Still well-regarded over 35 years since its launch is the Quattro, a legend which transformed rallying and brought the idea of four wheel drive as a performance benefit to the market. The idea for a high-performance four-wheel-drive car was proposed by Audi’s chassis engineer, Jörg Bensinger, in 1977, when he found that the Volkswagen Iltis could outperform any other vehicle in snow, no matter how powerful. Bensinger’s idea was to start developing an Audi 80 variant in co-operation with Walter Treser, Director of Pre-Development.. Following an unveiling on 1st March 1980, Audi released the original Quattro to European customers in late 1980, with the car featuring Audi’s quattro permanent four-wheel drive system (hence its name), and the first to mate four-wheel drive with a turbocharged engine. The original engine was the 2,144 cc in-line-5-cylinder 10 valve SOHC, with a turbocharger and intercooler. It produced 197 bhp propelling the Quattro from 0 to 100 km/h in 7.1 seconds, and reaching a top speed of over 220 km/h (137 mph). The engine was eventually modified to a 2,226 cc inline-5 10 valve, still producing 197 bhp, but with peak torque lower in the rev-range. In 1989, it was then changed to a 2,226 cc inline-5 20v DOHC setup producing 217 bhp, now with a top speed of 230 km/h (143 mph) Audi Quattros are referred to among owners and enthusiasts by their engine codes, to differentiate between the earlier and later versions: the earliest 2144 cc 10v being the “WR” engine, the 2226 cc 10v being the “MB” engine, and the later 20v being the “RR” engine. Hence, Quattro models may be referred to as either the WR Quattro, MB Quattro, and RR or “20v” Quattro, respectively. Quattro car production was 11,452 vehicles over the period 1980–1991, and through this 11 year production span, despite some touch-ups, there were no major changes in the visual design of the vehicle. For the 1983 model year, the dash was switched from an analogue instrument cluster, to a green digital LCD electronic instrument cluster. This was later changed in 1988 to an orange LCD electronic instrument cluster. The interior was redesigned in 1984, and featured a whole new dash layout, new steering wheel design, and new centre console design, the switches around the instrument panel were also redesigned at this time. In 1985 the dash changed slightly with harder foam and lost a diagonal stripe, the dash switches were varied slightly and the diff lock pull knob gave way to a two-position turning knob with volt and oil temp digital readouts. External styling received very little modification during its production run. Originally, the car had a flat fronted grille featuring four separate headlamp lenses, one for each of the low and high beam units. This was altered for the 1983 model year, and replaced with combined units featuring a single lens, but housing twin reflectors. This was changed again, for the 1985 model year, in what has become known as the ‘facelift model’ and included such alterations as a new sloping front grille, headlights, and trim and badging changes. Max speed was 124 mph. The RR 20v Quattro also featured a new three spoke steering wheel design, leather covering for door arm rests, gloveboxes, centre console and door pockets. There was also a full length leather-wrapped centre console running all the way to the rear seats. The 20v was also the first Ur-Q to have “quattro” script interior with partial leather seats. The floor on the drivers side had a bulge due to dual catalytic exhaust setup. The different models may be distinguished by the emblems on their boot lids: the WR had a vinyl ‘quattro’ decal or a brushed aluminium effect plastic emblem, the MB had chrome plated ‘audi’, ‘audi rings’ and ‘quattro’ emblems, whilst the RR had only chrome plated ‘audi rings’. The rear suspension was altered early on with geometry changes and removal of the rear anti-roll bar to reduce a tendency for lift-off oversteer. For the 1984 facelift, the wheel size went from 6×15-inch with 205/60-15 tyres to 8×15-inch wheels with 215/50-15 tyres. At the same time the suspension was lowered 20 mm with slightly stiffer springs for improved handling. For 1987, the Torsen centre differential was used for the first time, replacing the manual centre differential lock. The last original Audi Quattro was produced on 17 May 1991, more than two years after the first models of the new Audi Coupe range (based on the 1986 Audi 80) had been produced.

Audi introduced the S8 4.2 quattro into the European market in 1996. The S8 followed the naming convention of other high-performance Audi “S” models such as the Audi A6-derived S6 and was similar in vein of Mercedes-Benz AMG models. In some markets such as the UK, the S8 was only available with the automatic transmission. Cosmetically, Audi differentiated the S8 from the A8 with solid aluminium alloy door mirror housings, chrome-effect beltline and lower front grille trim, and polished twin exhaust pipes, along with subtle “S8” badging. 14-way power adjustable and heated sports front seats with memory function were fitted as were heated rear seats. Standard alloy wheels were 18-inch cast aluminium alloy “Avus” six-spoke style. After the 1999 facelift, 20-inch polished nine-spoke RS wheels became an option. In 2002, 18-inch nine-spoke RS wheels became a no-cost option. At the same time of the A8’s facelift in late 1999, the S8 received the same cosmetic upgrades. This update marked the release of the S8 to the North American market. Production of the D2 series S8 ended in September 2002. The D2 series S8 featured an uprated, 335 bhp version of the 4.2-litre V8 with four valves per cylinder. From late 1999, Audi increased this to five valves per cylinder with power increased to 355 bhp and 430 Nm (317 lb⋅ft). From launch in 1996, European-market models came standard with a six-speed manual transmission. A sports-recalibrated version of the ZF 5HP24 five-speed tiptronic automatic, featuring “Dynamic Shift Programme” (DSP) was released a year later and was the only transmission available in most other markets. A retuned, 20-millimetre (0.8 in) lowered sports suspension included a 30 percent stiffer spring rate and 40 percent more compression damping in the shock absorbers. Speed-sensitive “servotronic” power assisted steering was also standard. The brakes featured Bosch 5.3 anti-lock braking system (ABS), with electronic brakeforce distribution (EBD), and worked radially ventilated front discs. From 2002, an upgraded Bosch 5.7 electronic stability programme became standard fitment. Production ceased when the next generation A8 family was launched in late 2002.

Also with the four rings on the front was this RS7, the most potent of the RS range, with its 4.0 TFSI twin scroll twin turbo V8 engine rated at 553 bhp and 516 lb·ft. The RS7 is full of advanced technology, with a cylinder on demand system which deactivates intake and exhaust valves of 4 cylinders (2, 3, 5 and 8), eight-speed tiptronic transmission with D and S driving modes, quattro with torque vectoring with self-locking centre differential with a high locking rate and oil cooler, polished 20-inch forged wheels in a seven twin-spoke design (with optional 21-inch cast wheels in a choice of three designs), four internally vented diameter brake discs with 15.35 in diameter front discs and black (optional red) painted six-piston calipers (optional 420 mm (16.54 in) carbon fiber ceramic discs with anthracite gray calipers), electronic stabilisation control with Sport and off modes, adaptive air suspension lowering body by 20 mm (optional tauter sport suspension plus with Dynamic Ride Control), optional Dynamic all-wheel steering with continuously variable steering boost and ratio. The RS7 is easy to identify from lesser models in the range with its high-gloss black protective grille with honeycomb structure at the front of the car, add-on parts in matt aluminium, power extending spoiler, two elliptical tailpipe trims, a choice of 10 body colours (including Nardo gray, exclusive finish Daytona gray, matt effect), optional matt aluminium and carbon styling packages. It was unveiled at the 2013 North American Show in Detroit, and probably sells more strongly in the US than in Europe, as that thunderous engine does have a CO2 penalty, efficient though it maybe given the performance on offer. That was no deterrent to Audi from introducing an even more potent version, though, with the RS7 Performance, along with the RS6 Performance being released in October 2015. This is powered by the same 4.0-litre twin-turbo V8 engine as the standard RS7, but now with 597 bhp and 553 lb·ft. The top speed remains limited to 250 km/h (155.3 mph) as standard, and there are optional Dynamic and Dynamic Plus packages that raise the top speed to 174.0 and 189.5 mph respectively. The RS7 performance will accelerate from 0 to 100 km/h (62.1 mph) in 3.7 seconds and 0 to 200 km/h (124.3 mph) in 12.1 seconds. Despite the improved performance, the fuel economy and CO2 are unchanged from the standard RS6 Avant. A very desirable car

AUSTIN

The Morris Minor was already well established when rival Austin launched their competitor, the A30 Saloon of 1952. That was also the year that Austin and Morris merged to become the British Motor Corporation, so suddenly the two cars that had been conceived to compete against each other were stablemates. Except BMC did not work like that. Separate dealer chains remained in place, as they would do for a further 30 years, and whilst this may sound inefficient now, it has to be noted that brand loyalty was such that there were plenty of people would only consider an Austin say, and not a Morris, or vice versa. The A30 was smaller than the Minor and at £507, at launch, it was also £60 cheaper. The body structure was designed by T.K. Garrett, who had been an aeronautical engineer before joining Austin. It was of fully stressed monocoque chassis-less construction, which made it lighter and stiffer than most contemporary vehicles, the first Austin to be made in this way. Inside there were individual seats at the front and a bench at the rear covered in PVC with an option of leather facings on the seats. Evidence of economy was seen in only having a single windscreen wiper, central combined stop/tail/numberplate lamp and a sun visor in front of the driver only. A passenger-side wiper and sun visor, and a heater were available as optional extras. Even so, it sold well, and 223,264 examples were built. The A30 was replaced by the Austin A35 in 1956 with the new name reflecting the larger and more powerful 34 hp A-Series engine, which gave the car a slightly higher top speed and better acceleration, though much of this came as a result of different gearbox ratios. The A30 had the first three ratios close together then a big gap to top, whereas in the A35, the ratios were better spaced and gave a higher speed in third gear. That top speed was 72 mph and 0 – 60 acceleration times are just over 30 seconds, so this remains a very slow car by modern standards. The A35 was very similar in appearance to the A30, and is best recognised by its larger rear window aperture and a painted front grille, with chrome horse-shoe surround, instead of the chrome grille featured on the A30. The semaphore trafficators were replaced with present-day front- and rear-mounted flashing light indicators. A slightly easier to operate remote-control gear-change was provided. Like the A30, the A35 was offered as a two- or four-door saloon or two-door “Countryman” estate and also as a van. The latter model continued in production through to 1968. A rare coupe utility (pickup) version was also produced in 1956, with just 477 sold. Drawings were made for a sports tourer, but no prototype was actually built. The A35 passenger cars were replaced by the new body shape A40 Farina models in 1959 but the estate car version continued until 1962 and van until 1968. These days they are popular as an affordable classic. Their simple mechanicals, good availability of some parts (not bodywork, though) and pert looks give them widespread appeal. There was a van version here as well as the regular saloons.

AUSTIN HEALEY

There were numerous examples of the “Big Healey” here, one of Britain’s most popular classics. Donald Healey had been producing a range of expensive sports cars from the 1940s, cars such as the Silverstone, the Abbott and the Farnham. For the 1952 London Motor Show, he produced a new design, which was called the Healey Hundred, based on Austin A90 mechanicals, which he intended to produce in-house at his small car company in Warwick. It was one of the stars of the 1952 Show, and it so impressed Leonard Lord, the Managing Director of Austin, who was looking for a replacement to the unsuccessful A90. that Lord struck a deal with Healey on the spot, to build it in quantity. Bodies made by Jensen Motors would be given Austin mechanical components at Austin’s Longbridge factory. The car was renamed the Austin-Healey 100, in reference to the fact that the car had a top speed of 100 mph. Production got under way in 1953, with Austin-Healey 100s being finished at Austin’s Longbridge plant alongside the A90 and based on fully trimmed and painted body/chassis units produced by Jensen in West Bromwich—in an arrangement the two companies previously had explored with the Austin A40 Sports. By early 1956, production was running at 200 cars a month, 150 of which were being sold in California. Between 1953 and 1956, 14,634 Austin-Healey 100s were produced, the vast majority of them, as was the case for most cars in this post war era, going for export. The car was replaced by an updated model in 1956, called the 100-6. It had a longer wheelbase, redesigned bodywork with an oval shaped grille, a fixed windscreen and two occasional seats added (which in 1958 became an option with the introduction of the two-seat BN6 produced in parallel with the 2+2 BN4), and the engine was replaced by one based on the six-cylinder BMC C-Series engine. In 1959, the engine capacity was increased from 2.6 to 2.9 litres and the car renamed the Austin-Healey 3000. Both 2-seat and 2+2 variants were offered. It continued in this form until production ceased in late 1967. The Big Healey, as the car became known after the 1958 launch of the much smaller Austin-Healey Sprite, is a popular classic now. You come across the 3000 models more frequently than the 100s, as they accounted for more than 60% of all Big Healey production.

There was also a number of the smaller stablemate, the “Frog Eye”. Known officially as the Sprite, it was announced to the press in Monte Carlo by the British Motor Corporation on 20 May 1958, just before that year’s Monaco Grand Prix. It was intended to be a low-cost model that “a chap could keep in his bike shed”, yet be the successor to the sporting versions of the pre-war Austin Seven. The Sprite was designed by the Donald Healey Motor Company, with production being undertaken at the MG factory at Abingdon. It first went on sale at a price of £669, using a tuned version of the Austin A-Series engine and as many other components from existing cars as possible to keep costs down. It was produced for a little over 3 years before being replaced by a Mark 2 version, which was then joined by a badge-engineered MG version, the Midget, reviving a model name used by MG from the late 1920s through to the mid 1950s. Enthusiasts often refer to Sprites and the later Midgets collectively as “Spridgets.” The first Sprite quickly became affectionately known as the “frogeye” in the UK and the “bugeye” in the US, because its headlights were prominently mounted on top of the bonnet, inboard of the front wings. The car’s designers had intended that the headlights could be retracted, with the lenses facing skyward when not in use; a similar arrangement was used many years later on the Porsche 928. But cost cutting by BMC led to the flip-up mechanism being deleted, therefore the headlights were simply fixed in a permanently upright position, giving the car its most distinctive feature. The body was styled by Gerry Coker, with subsequent alterations by Les Ireland following Coker’s emigration to the US in 1957. The car’s distinctive frontal styling bore a strong resemblance to the defunct American 1951 Crosley Super Sport. The problem of providing a rigid structure to an open-topped sports car was resolved by Barry Bilbie, Healey’s chassis designer, who adapted the idea provided by the Jaguar D-type, with rear suspension forces routed through the bodyshell’s floor pan. The Sprite’s chassis design was the world’s first volume-production sports car to use unitary construction, where the sheet metal body panels (apart from the bonnet) take many of the structural stresses. The original metal gauge (thickness of steel) of the rear structure specified by Bilbie was reduced by the Austin Design Office during prototype build, however during testing at MIRA (Motor Industry Research Association) distortion and deformation of the rear structure occurred and the original specification was reinstated. The two front chassis legs projecting forward from the passenger compartment mean the shell is not a full monocoque. The front sheet-metal assembly, including the bonnet (hood) and wings, was a one-piece unit, hinged from the back, that swung up to allow access to the engine compartment. The 43 bhp, 948 cc OHV engine (coded 9CC) was derived from the Austin A35 and Morris Minor 1000 models, also BMC products, but upgraded with twin 11⁄8 inch SU carburettors which gave it 43 hp at 5200 rpm and 52 lb/ft at 3300 rpm. When tested by “The Motor” magazine in 1958. It had a top speed of 82.9 mph and could accelerate from 0-60 mph in 20.5 seconds. Fuel consumption of 43 mpg was recorded. The rack and pinion steering was derived from the Morris Minor 1000 and the front suspension from the Austin A35. The front suspension was a coil spring and wishbone arrangement, with the arm of the Armstrong lever shock absorber serving as the top suspension link. The rear axle was both located and sprung by quarter-elliptic leaf springs, again with lever-arm shock absorbers and top links. There were no exterior door handles; the driver and passenger were required to reach inside to open the door. There was also no boot lid, owing to the need to retain as much structural integrity as possible, and access to the spare wheel and luggage compartment was achieved by tilting the seat-backs forward and reaching under the rear deck, a process likened to potholing by many owners, but which resulted in a large space available to store soft baggage. The BMC Competition Department entered Austin Healey Sprites in major international races and rallies, their first major success coming when John Sprinzel and Willy Cave won their class on the 1958 Alpine Rally. Private competitors also competed with much success in Sprites. Because of its affordability and practicality, the Austin Healey Sprite was developed into a formidable competition car, assuming many variants by John Sprinzel, Speedwell and WSM. The Sebring Sprite became the most iconic of the racing breed of Austin Healey Sprites. Many owners use their Austin Healey Sprites in competition today, fifty years after its introduction. 48,987 “frogeye” Sprites were made and the car remains popular to this day.

This is a Speedwell Sprite. John Sprinzel, George Hulbert and Len Adams established Speedwell Tuning Conversions in June 1957, following John’s success with an Austin A35. With the introduction of the Sprite the following year it was not long before they turned their attentions to tuning, modifying, racing and rallying these little sportscars. Towards the end of 1958 they decided to try and improve the aerodynamics of the Frogeye/Bugeye bonnet. They approached Frank Costin, then chief designer at Lister, with the idea of re-designing the front end, a project which luckily “took his fancy”. A prototype bonnet was made in aluminium – as were 5 or so more before production was changed to fibreglass, and this subsequently became known as the Speedwell Monza bonnet. To quote from John Baggott’s recently published book “Frogeye Sprite – the complete story”: “Frank also designed the coupé roof section with a windscreen that had a greater rake than a standard Sprite and was more curved. Like the bonnet, the prototype was formed in aluminium alloy and would later be used to make moulds (I presume this never happened) to enable them to be produced in fibreglass. Many regarded the finished article as a smaller version of the Costin-designed Lotus Elite. The Speedwell GT sales brochure highlighted the car’s aerodynamic styling, all-round visibility, luxurious interior, perfect braking and 60 bhp engine. It was described as a true Grand Touring car designed to incorporate all the requirements of the fastidious motorist’. A particular feature was the curved side windows, which were handmade from Perspex sheet.” John’s research has revealed that a total of around 25 Speedwell GTs were produced. Aluminium fabrication for the prototype which initially carried Sprinzel’s personal number PMO 200, and two or 3 more cars was by Williams & Pritchard. However, the later cars all came from Classic Motor Crafts who were able to give the cars more time at a cheaper price. With business continuing to grow, the idea was hatched of getting a special body for the Sprite, which – back in those days – received a great deal of scorn for those ridiculous headlamps. Even Gerry Coker, who had designed the Sprite with retractable lights, refused to take any credit back then, although he nowadays jokes that as the “Frogeyes” have become so popular, he is happy to do so today. Graham’s [Hill] presence caused Mike Costin to drop in most mornings to our works in the Finchley Road with the prototype Elite that Lotus were about to release, and that is how we got to know his half-brother Frank, who was a serious aerodynamicist with many race car shapes for Lotus, Vanwall and others to his credit. Frank first designed a new streamlined front with a small Jaguar-like air intake, and Stuart Turner and I debuted this on the Liege-Rome-Liege four day and night road race, with a Class win, so obviously the airflow improvements were working”.

The Mark II to Mark IV were all very similar and represented the evolution of the model throughout the 1960s, The Mark II was announced at the end of May 1961. It used the same 948 cc engine with larger twin 1 1⁄4 inch SU carburettors, increasing power to 46.5 bhp. A close-ratio gearbox was fitted. The bodywork was completely revamped, with the headlights migrating to a more conventional position in the wings, either side of a full-width grille. At the rear, styling borrowed from the soon-to-be-announced MGB gave a similarly more modern look, with the added advantages of an opening boot lid and conventional rear bumper bar. The result was a much less eccentric-looking sports car, though at the expense of some 100 lbs extra weight. It followed the MG version of the car which was introduced a couple of weeks earlier as ‘the new Midget,’ reviving a model name which had been a great success for the MG Car Company in the 1930s. The Midget was to prove more popular with the public than the Sprite and by 1972 had completely supplanted it within the BMC range. In October 1962, both Sprites and Midgets were given a long-stroke 1098 cc engine. A strengthened gearbox with Porsche (baulk-ring) synchromesh was introduced to cope with the extra power – 56 bhp. Front disc brakes were also introduced at the same time and wire wheels became an option. 31,665 Mark II Sprites were made. The Mark III Sprite was also marketed as the Mark II MG Midget – differences between the two were again restricted to minor trim detailing. Although still 1098 cc, the engine had a stronger block casting, and the size of the crankshaft main bearings was increased to two inches. A new (slightly) curved-glass windscreen was introduced with hinged quarterlights and wind-up side windows. Exterior door handles were provided for the first time, with separate door locks. Though the car could now be secured, with a soft-top roof the added protection was limited. The rear suspension was modified from quarter-elliptic to semi-elliptic leaf springs, which gave a more comfortable ride for a near-negligible weight penalty as well as providing additional axle location, the upper links fitted to the quarter-elliptic models being deleted. Though scarcely sybaritic, these changes helped the Sprite and Midget compete with the recently released Triumph Spitfire. 25,905 Mark III Sprites were made. The next upgrade was presented at the London Motor Show in October 1966. Besides receiving the larger 1275 cc engine (which disappointed enthusiasts by being in a lower state of tune than that of the Mini-Cooper ‘S’), the Mark IV and its cousin the Mark III MG Midget had several changes which were more than cosmetic. Most notable is the change from a removable convertible top, which had to be stowed in the boot, to a permanently affixed, folding top of greatly improved design, which was much easier to use. Separate brake and clutch master cylinders were fitted, as car manufacturers’ thoughts began to turn to making their products safer. For the 1970 model year cast-alloy wheels were fitted and the grille was changed to resemble that fitted to the MG Midget. 22,790 Mark IV Sprites were made. The Healey connection was discontinued in 1971, so the final 1,022 Sprites built were simply Austin Sprites.

BEDFORD

One of the “O” Series Bedfords, that shared its distinctive front end with the well known OB Bus that first appeared in 1939, and produced in small numbers before the War intervened and then again unchanged post War until 1951, the O Series trucks were one of three series of that the Luton manufacturer introduced to meet the haulage needs of its customers. Each was a 2-axle vehicles with a separate bonnet, and they were called “K”, “M” and “O”. The K Series had a carrying capacity of 1.5-2.0 tons, and had a a standard wheelbase of 3050mm, while the “M” Series could carry 2 – 3 tons and were offered with two wheelbases of 3050 mm and 3630., and the largest, the “‘O” could haul 3 – 5 tons and came in 13 different designs, also with two wheelbase lengths. They all used the same 6-cylinder engine which generated a heady 72 hp, coupled to a 4-speed transmission, and had leaf-spring suspension and hydraulic brakes. Models with a carrying capacity of 3 tons used a vacuum brake booster. The vehicles were adapted for military use during the War and then production resumed after the cessation of hostilities, with the “O” Series now offered in OLA and OLB versions, differing in haulage capacity. The design was finally retired in 1953.

BENTLEY

Bentley replaced the 3 Litre with a more powerful car by increasing its engine displacement to 4.5 litres. As before, Bentley supplied an engine and chassis and it was up to the buyer to arrange for their new chassis to be fitted with one of a number of body styles, most of which were saloons or tourers. Very few have survived with their four-seater coachwork intact. WO Bentley had found that success in motorsport was great publicity for the brand, and he was particularly attracted to the 2 Hours of Le Mans endurance race, the inaugural running of which took place 26–27 May 1923, attracting many drivers, mostly French. There were two foreign competitors in the first race, Frank Clement and Canadian John Duff, the latter winning the 1924 competition in his personal car, a Bentley 3 Litre. This success helped Bentley sell cars, but was not repeated, so ater two years without success, Bentley convened a group of wealthy British men, “united by their love of insouciance, elegant tailoring, and a need for speed,” to renew Bentley’s success. Both drivers and mechanics, these men, later nicknamed the “Bentley Boys”, drove Bentley automobiles to victory in several races between 1927 and 1931, including four consecutive wins at the 24 Hours of Le Mans, and forged the brands reputation. It was within this context that, in 1927, Bentley developed the Bentley 4½ Litre. Two cylinders were removed from the 6½ Litre model, reducing the displacement to 4.4 litres. At the time, the 3 Litre and the 6½ Litre were already available, but the 3 Litre was an outdated, under-powered model and the 6½ Litre’s image was tarnished by poor tyre performance. Sir Henry “Tim” Birkin, described as “the greatest British driver of his day” by W. O. Bentley, was one of the Bentley Boys. He refused to adhere strictly to Bentley’s assertion that increasing displacement is always preferable to forced induction. Birkin, aided by a former Bentley mechanic, decided to produce a series of five supercharged models for the competition at the 24 Hours of Le Mans; thus the 4½ litre Blower Bentley was born. The first supercharged Bentley had been a 3-litre FR5189 which had been supercharged at the Cricklewood factory in the winter of 1926/7. The Bentley Blower No.1 was officially presented in 1929 at the British International Motor Show at Olympia, London. The 55 copies were built to comply with 24 Hours of Le Mans regulations. Birkin arranged for the construction of the supercharged cars having received approval from Bentley chairman and majority shareholder Woolf Barnato and financing from wealthy horse racing enthusiast Dorothy Paget. Development and construction of the supercharged Bentleys was done in a workshop in Welwyn by Amherst Villiers, who also provided the superchargers. W.O. Bentley was hostile to forced induction and believed that “to supercharge a Bentley engine was to pervert its design and corrupt its performance.” However, having lost control of the company he founded to Barnato, he could not halt Birkin’s project. Although the Bentley 4½ Litre was heavy, weighing 1,625 kg (3,583 lb), and spacious, with a length of 172 in and a wheelbase of 130.0 in, it remained well-balanced and steered nimbly. The manual transmission, however, required skill, as its four gears were unsynchronised. The robustness of the 4½ Litre’s latticed chassis, made of steel and reinforced with ties, was needed to support the heavy cast iron inline-four engine. The engine was “resolutely modern” for the time. The displacement was 4,398 cc. Two SU carburettors and dual ignition with Bosch magnetos were fitted. The engine produced 110 hp for the touring model and 130 hp for the racing model. The engine speed was limited to 4,000 rpm. A single overhead camshaft actuated four valves per cylinder, inclined at 30 degrees. This was a technically advanced design at a time where most cars used only two valves per cylinder. The camshaft was driven by bevel gears on a vertical shaft at the front of the engine, as on the 3 Litre engine. The essential difference between the Bentley 4½ Litre and the Blower was the addition of a Roots-type supercharger to the Blower engine by engineer Amherst Villiers, who had also produced the supercharger. W. O. Bentley, as chief engineer of the company he had founded, refused to allow the engine to be modified to incorporate the supercharger. As a result, the supercharger was placed at the end of the crankshaft, in front of the radiator. This gave the Blower Bentley an easily recognisable appearance and also increased the car’s understeer due to the additional weight at the front. A guard protected the two carburettors located at the compressor intake. Similar protection was used, both in the 4½ Litre and the Blower, for the fuel tank at the rear, because a flying stone punctured the 3 Litre of Frank Clement and John Duff during the first 24 Hours of Le Mans, which contributed to their defeat. The crankshaft, pistons and lubrication system were special to the Blower engine. It produced 175 hp at 3,500 rpm for the touring model and 240 hp at 4,200 rpm for the racing version, which was more power than the Bentley 6½ Litre developed. Between 1927 and 1931 the Bentley 4½ Litre competed in several competitions, primarily the 24 Hours of Le Mans. The first was the Old Mother Gun at the 1927 24 Hours of Le Mans, driven as a prototype before production. Favoured to win, it instead crashed and did not finish. Its performance was sufficient for Bentley to decide to start production and deliver the first models the same year. Far from being the most powerful in the competitions, the 4½ Litre of Woolf Barnato and Bernard Rubin, raced neck and neck against Charles Weymann’s Stutz Blackhawk DV16, setting a new record average speed of 69 mph; Tim Birkin and Jean Chassagne finished fifth. The next year, three 4½ Litres finished second, third, and fourth behind another Bentley, the Speed Six, which possessed two more cylinders.The naturally aspirated 4½ Litre was noted for its good reliability. The supercharged models were not; the two Blower models entered in the 1930 24 Hours of Le Mans by Dorothy Paget, one of which was co-driven by Tim Birkin, did not complete the race. In 1930, Birkin finished second in the French Grand Prix at the Circuit de Pau behind a Bugatti Type 35. Ettore Bugatti, annoyed by the performance of Bentley, called the 4½ Litre the “fastest lorry in the world.” The Type 35 is much lighter and consumes much less petrol. Blower Bentleys consume 4 litres per minute at full speed. In November 1931, after selling 720 copies of the 4½ Litre – 655 naturally aspirated and 55 supercharged – in three different models (Tourer, Drophead Coupé and Sporting Four Seater, Bentley was forced to sell his company to Rolls-Royce for £125,175, a victim of the recession that hit Europe following the Wall Street Crash of 1929.

Also present here was what are sometimes referred to as the “Derby” Bentley. These were produced after the acquisition of Bentley by Rolls-Royce, in 1934, at which point the focus of the brand shifted to the production of large and elegant tourers. The cars retained the famous curved radiator shape based on earlier Bentley models, but in all meaningful respects they were clearly Rolls-Royces. Although disappointing some traditional customers, they were well received by many others and even W.O. Bentley himself was reported as saying that he would “rather own this Bentley than any other car produced under that name.” The Rolls-Royce Engineer in charge of the development project, Ernest Hives (later Lord Hives), underlined the Rolls-Royce modus operandi in a memo addressed to company staff “our recommendation is that we should make the car as good as we know how and then charge accordingly.” At a time when the Ford 8 could be purchased new for £100, an early Bentley 3½ Litre cost around £1,500 (equivalent to £6400 vs. £96,000 today), putting it beyond the reach of all but the wealthiest consumers. Despite not being a car of remarkable outright performance, the car’s unique blend of style and grace proved popular with the inter-war elite and it was advertised under the legend the silent sports car. Over 70% of the cars built between 1933 and 1939 were said to have still been in existence 70 years later. Although chassis production ceased in 1939, a number of cars were still being bodied and delivered during 1940. The last few were delivered and first registered in 1941. The 3.5 litre came first. Based on an experimental Rolls-Royce project “Peregrine” which was to have had a supercharged 2¾ litre engine, the 3½ Litre was finally fitted with a less adventurous engine developed from Rolls’ straight-6 fitted to the Rolls-Royce 20/25. The Bentley variant featured a higher compression ratio, sportier camshaft profile and two SU carburettors on a crossflow cylinder head. Actual power output was roughly 110 bhp at 4500 rpm, allowing the car to reach 90 mph. The engine displaced 3669 cc with a 3¼ in (82.5 mm) bore and 4½ in (114.3 mm) stroke. A 4-speed manual transmission with synchromesh on 3rd and 4th, 4-wheel leaf spring suspension, and 4-wheel servo-assisted mechanical brakes were all common with other Rolls-Royce models. The chassis was manufactured from nickel steel, and featured a “double-dropped” layout to gain vertical space for the axles and thus keep the profiles of the cars low. The strong chassis needed no diagonal cross-bracing, and was very light in comparison to the chassis built by its contemporary competitors, weighing in at 2,510 pounds (1,140 kg) in driveable form ready for delivery to the customer’s chosen coachbuilder. 1177 of the 3½ Litre cars were built, with about half of them being bodied by Park Ward, with the remainder “dressed” by other coachbuilders like Barker, Carlton, Freestone & Webb, Gurney Nutting, Hooper, Mann Egerton, Mulliner (both Arthur and H J), Rippon, Thrupp & Maberly, James Young, Vanden Plas and Windovers in England; Figoni et Falaschi, Kellner, Saoutchik and Vanvooren in Paris; and smaller concerns elsewhere in UK and Europe. Beginning in March, 1936, a 4¼ Litre version of the car was offered as replacement for the 3½ Litre, in order to offset the increasing weight of coachwork and maintain the car’s sporting image in the face of stiff competition. The engine was bored to 3½ in (88.9 mm) for a total of 4257cc. From 1938 the MR and MX series cars featured Marles steering and an overdrive gearbox. The model was replaced in 1939 by the MkV, but some cars were still finished and delivered during 1940-1941. 1234 4¼ Litre cars were built, with Park Ward remaining the most popular coachbuilder. Many cars were bodied in steel rather than the previous, more expensive, aluminium over ash frame construction.

Oldest of the post cars was this R Type. Announced in May 1946, as the mark VI nd produced from 1946 to 1952 it was also both the first car from Rolls-Royce with all-steel coachwork and the first complete car assembled and finished at their factory. These very expensive cars were a genuine success, long-term their weakness lay in the inferior steels forced on them by government’s post-war controls. The chassis continued to be supplied to independent coachbuilders. Four-door Saloon, two-door saloon and drophead coupe models with bodies by external companies were listed by Bentley along with the Bentley-bodied saloon. This shorter wheelbase chassis and engine was a variant of the Rolls-Royce Silver Wraith of 1946 and, with the same standard steel body and a larger boot became the cautiously introduced Silver Dawn of 1949. The same extended-boot modification was made to the Mark VI body in 1952 and the result became known as the R type Bentley. Among the cars here was one of the revered Continental versions.

Sadly, many of the factory bodied cars rusted quite badly, but rather than scrap the entire car, a number of them got a second chance as the chassis was retained and clothed with a new body, many of them with a resemblance to the pre-war designs. These are generally known as “Specials” and there were a couple of them here.

A close relative of the Rolls Royce Silver Cloud, the S Type was first revealed in April 1955. It represented a complete redesign of the standard production car, the R Type. It was a more generously sized five- or six-seater saloon with the body manufactured in pressed steel with stressed skin construction, with the doors, bonnet and boot lid made of aluminium. The external appearance was very different, although the car still had the traditional radiator grille. Compared to the outgoing R Type, the new model had a three inch longer wheelbase, was lower of build without reducing headroom and with an enlarged luggage boot, softer suspension with electrically operated control of rear dampers, lighter steering and improved braking. The engine, still a clear descendants of the one originally used in the Rolls-Royce Twenty from 1922 to 1929, had its capacity increased to 4887cc, and a four-speed automatic gearbox was standard, with the ability to select individual ratios if desired, which was enough to give the Bentley a top speed of just over 100 mph and 0 – 60 acceleration times of around 13 seconds. Standard and from 1957, long wheelbase saloons were offered and some were sent to the coachbuilders for alternative bodies to be fitted. An upgrade in 1959, creating the S2, saw the installation of a new V8 engine, and in 1962, the S3 cars gained four round headlights. 3072 S Types were made, 145 of them with coachbuilt bodies as well as 35 of the long wheelbase cars, before the model was replaced by the new T Type in 1965.

Although the Turbo models claimed the limelight of the 1980s and 1990s, the lesser versions of the car sold well, too. Several different version of what started out simply as the Mulsanne, a badge-engineered version of the Rolls-Royce Silver Spirit were offered. The Eight was Bentley’s “entry-level” offering from 1984 until 1992. Distinguished mainly by a wire-mesh grille radiator instead of vertical slats, the Eight also had somewhat less equipment than the similar Mulsanne on which it was based. This brought the introductory price to under the psychologically important £50,000 mark at the time of introduction, £6,000 less than the Mulsannne. A firmer suspension offered slight handling improvements. The Eight was so popular that sales expanded from the original UK market to Europe and the United States. The Eight was introduced with cloth upholstery, steel wheels, and a mesh grille that was simpler than the slatted grille of the Mulsanne. Fuel injection and anti-lock brakes were added in 1986, leather upholstery and power memory seats were added in 1987, and automatic ride height adjustment was added in 1990. In Britain, catalytic converters became optional in 1990 – although they had been available long before in markets where such were required. The three-speed automatic transmission was replaced by a four-speed transmission in August 1992. The Bentley Brooklands was introduced in 1992 as a replacement for the Bentley Mulsanne S and Bentley Eight models. It was intended as a slightly cheaper alternative to the Bentley Turbo R, featuring the same styling, underpinnings and the Rolls-Royce 6.75-litre V8 engine, but without the more powerful model’s turbocharger. The Brooklands continued Bentley’s relatively angular design theme, which was also used on contemporary Rolls-Royce vehicles, throughout the 1980s and early 1990s. The exterior design featured the classic Bentley waterfall grille as well as dual headlights with wraparound parking lights. As in many Bentley and Rolls-Royce vehicles, the Brooklands also featured the trademark descending bootlid and chrome B-pillars. The interior remained relatively unchanged from previous Bentley models, with more curvaceous design elements surrounding the leather-wrapped centre console. The steering wheel and interior door panels remained largely unchanged; the major change arrived in the form of relocating the gear selector to the centre console – for decades the standard practice among R-R and Bentley models utilised a steering column mounted selector. The interior continued to be surrounded by ample woodgrain which featured engraved, lighter-coloured outlines on the door panels.

The success of the Mulsanne Turbo and Turbo R brought new life to Bentley, changing the position of the preceding 15 years where sales of the marque’s badge-engineered Rolls Royce cars had been only a very small percentage of the company’s sales. The obvious next step would be further to enhance the distinctive sporting nature of the Bentley brand and move away from a Bentley that was merely a re-badged Rolls Royce. Bentley appointed stylists John Heffernan and Ken Greenley to come up with ideas for a new, distinctive, Bentley coupé. The fibreglass mock up was displayed at the 1984 Geneva Motor Show in Rolls-Royce’s “Project 90″ concept of a future Bentley coupé. The concept was met with an enthusiastic reception, but the Project 90 design was largely shelved as the company began to work towards a replacement for the Rolls-Royce Corniche. During this process, Graham Hull, chief stylist in house at Rolls Royce, suggested the designs before the board for the Corniche, would suit a Bentley coupé better. From this point it was decided the Corniche could continue as it was, and efforts would once again be channelled into a new Bentley coupé. In 1986 Graham Hull produced a design rendering of a new Bentley coupé which became the Continental R. Based on the Rolls Royce SZ platform (which was an evolution of the SY platform), an aerodynamically shaped coupé body had been styled. John Heffernan and Ken Greenley were officially retained to complete the design of the Continental R. They had run the Automotive Design School at the Royal College of Art and headed up their own consultancy, International Automotive Design, based in Worthing, Southern England. Greenley and Heffernan liaised constantly throughout the styling process with Graham Hull. The interior was entirely the work of Graham Hull and the small in house styling team at Rolls Royce. The shape of the car was very different from the somewhat slab sided four door SZ Rolls-Royce and Bentley vehicles of the time and offered a much improved 0.37 coefficient of drag. The Continental R also featured roof-cut door frames, a necessity to allow easier access into the car which had a lower roof line than its 4-door contemporaries. A subtle spoiler effect was also a feature of the rear. The finished car is widely acknowledged as a very cleverly styled vehicle, disguising its huge dimensions (The Continental R is around 4” longer than a 2013 long wheelbase Mercedes S Class) and a very well proportioned, extremely attractive, car. The “Continental” designation recalls the Bentley Continental of the post-war period. The “R” was meant to recall the R Type Bentleys from the 1950s as well as the Turbo R of the 1980s and 90’s where the “R” refers to “roadholding”. 1504 Continental R and 350 Continental T models were made before production finally ceased in 2003. The revival of the Bentley marque following the introduction of the Bentley Mulsanne Turbo, and then the Continental R, is widely acknowledged to have saved Rolls Royce Motor cars and formed the groundwork which led to the buyout and parting of the Rolls Royce and Bentley brands in 1998. Bentley was once again capable of standing alone as a marque in its own right.

The Arnage, a twin of the Rolls-Royce-branded sibling, the Silver Seraph, was introduced in the Spring of 1998, the first entirely new designs for the two marques since 1980. This is a large car: over 5.4 metres (212 in) long, 1.9 metres (75 in) wide, and has a kerb weight of more than 2.5 metric tonnes. For a brief period it was the most powerful and fastest four-door saloon on the market. In a complete switch from tradition, whilst these cars had bodies built at the Crewe factory, the then owner, Vickers, decided that the car would be powered by engines built elsewhere. A number of potential engines were examined, including the GM Premium V engine, and a Mercedes-Benz V8 engine, before, in late 1994, Vickers selected a pair of BMW power plants. It was decided that the Rolls-Royce model would use BMW’s naturally aspirated V12 engine while the more-sporting Bentley model would use a special twin-turbo version of the 4.4-litre BMW V8, which was developed by Vickers subsidiary, Cosworth Engineering. On its introduction in the spring of 1998, the Arnage was available as a single model with the this 4,398cc twin turbo developing some 354 PS (349 bhp) and 420 lb·ft. During the takeover battle in 1998 between BMW and Volkswagen Group for ownership of Rolls Royce and Bentley Motors, BMW had threatened to stop supply of their engines if Volkswagen Group won. While the threat was later withdrawn in conjunction with BMW acquiring the right to manufacture the Rolls Royce marque at a new location, it was clear that Volkswagen could not accept the business and reputation risks associated with having their rival as a long-term business partner. Furthermore, customers were nervous about engine and part availability (of which there turned out to be no issue) and orders for new cars dropped precipitously. Volkswagen’s response was to prepare the old pushrod 6.75-litre 16-valve engine from the Turbo R for the Arnage, designed for the lighter and smaller BMW 32-valve V8 unit. Coupled with an outdated 4-speed automatic, the engine was extremely thirsty, and would not meet government-imposed emissions standards without hasty modifications. The revised version of the car was launched as the Arnage Red Label in October 1999. At the same time, but without the fanfare, Bentley made several minor modifications to the original BMW engined cars, and designated them as the “Arnage Green Label” for the 2000 model year. As part of the modification process, both Red and Green Label cars received stiffer body shells and larger wheels and brakes. The stiffer body shell was needed because of the extra weight of the British engine. The larger brakes were needed for the same reason. Despite the larger brakes, braking performance worsened with the extra weight of the 6.75 engine. The braking performance of the ’99 Green Label from 70–0 was 172 feet while the later Arnage T’s performance was 182 feet from the same speed. The PR department at Bentley pointed to customer demand as the driving force behind the reversion to the old two valve per cylinder 6.75-litre unit for the Red Label. This explanation appears to have been acceptable to all but a few of the motoring press who welcomed the return of the old unit after criticising the BMW motor as at best insipid and, at worst, underpowered. In reality, the outgoing BMW-powered Arnage was technically more modern, considerably more fuel efficient, and had 32 valves with double overhead camshafts, twin-turbo and Bosch engine management technology – as opposed to 16-valve, single turbo and a pushrod motor with less advanced engine management. The Red Label’s increase in motive power shaved less than a second of the zero to 60 mph time. However, the BMW twin turbo unit remained noticeably more agile and responsive from a driver’s perspective, due to its more responsive DOHC engine, better weight balance(maintaining a 51.1/48.9 weight distribution) and almost 600 lb (270 kg) lower curb weight. Ultimately the Green Label was more reliable and significantly less expensive to service in the long term. The key limiting factor of the BMW engine’s output was the ZF 5HP30 transmission which was not rated to handle more than the 413 lb·ft torque that the twin turbo engine was tuned to produce. In total only seven Arnage Green Label units were built, all of which were left-hand-drive versions. There was a final series of vehicles built in 2000 with the 4.4-litre BMW engine designated the Arnage Birkin, of which 52 units were produced and are distinguishable by their three-dial as opposed to five-dial instrument centre dashboard configuration. A long-wheelbase version of the Red Label was launched at the North American International Auto Show in 2001. The Green Label ended production in 2000. The Red Label models were replaced in 2002. In 2001, the Arnage RL, a long-wheelbase model, 9.8 in longer than the Arnage, was launched, the extra length added to the car at its rear doors and its C-pillar. With the standard Arnage model, the rear wheel wells butt up against the rear door frames, but with the RL they are a few inches further back. The overall effect is a larger rear area inside the car. Available only as a bespoke “Mulliner” model, each RL was customised to the desires of the buyer. The RL, however, was also the first of a new series of Arnages which would finally cure the Bentley Arnage of the reliability and performance deficiencies experienced following its forced deprivation of the modern BMW engines it was designed to use. The RL would also present a credible challenge to BMW’s attempts to revive the Rolls-Royce brand with its planned new model, the Phantom. The RL’s introduction saw the introduction of an entirely reworked version of the 6.75-litre V8 engine. Where the engine used in the Red Label was a quickly and less-than-completely-satisfactorily modified version of the Turbo RT’s unit, the RL featured an entirely reworked version of the old 6.75-litre V8. More than half of the engine’s parts were completely new, with Bosch Motronic ME7.1.1 engine management replacing the old Zytek system, and two small Garrett T3 turbochargers replacing the single large T4. This new engine developed 405 PS (399 bhp) and 616 lb·ft, and was said to be capable of meeting all future emissions requirements. Finally, the Arnage was powered by a modern twin-turbo unit with state-of-the-art electronic management system similar to the originally Cosworth-BMW unit developed for the Arnage in 1998. Perhaps ironically, what was essentially a new engine developed by Volkswagen Group engineers for the RL in 2001, was now producing the same sort of power as the original BMW V8 4.4 engine used in the first Arnage in 1998. Unfortunately, the development and testing of the revisions to the new engine were rushed by VW to meet regulatory requirements. As a result, the camshafts are prone to failure requiring extensive repair work to remedy In 2002, Bentley updated the Red Label as the series two Arnage R. This model was launched to contrast the Arnage T, which was developed to be more sporting. The Arnage R features two Garrett T3 turbochargers, as with the RL.The Arnage T, also from 2002, was claimed to be the most powerful roadgoing Bentley at its launch at the Detroit Motor Show. As with the Arnage R, there were twin-turbochargers, but tuned to develop 465 PS (459 bhp) and 645 lbf·ft. The Arnage T’s 0–60 mph time is 5.5 seconds; a top speed of 170 mph was claimed. The Arnage range was facelifted in 2005, with a front end resembling that of the new Continental GT. Production of the Arnage ceased in 2009.

Completing the lineup of Bentley cars were examples of the Continental GT Coupe, a car produced in far greater quantities than any Bentley model preceding it, and the latest Mulsanne.

BMC

Competitions Transporter.

BMW

There was a big BMW presence here, with a large hospitality unit housing some interesting cars. Oldest of these was this 328, a sports car made between 1936 and 1940, with the body design credited to Peter Szymanowski, who became BMW chief of design after World War II (although technically the car was designed by Fritz Fiedler). It had a 1971cc straight 6 OHV engine and 3 solec carburettors which gave it an output of 79 bhp at 5000 rpm, and a top speed of 150 km/h, making this relatively light car ideal for motorsport. The 328 was introduced at the Eifelrennen race at the Nürburgring in 1936, where Ernst Henne drove it to win the 2.0 litre class. The 328 had more than 100 class wins in 1937, including the RAC Tourist Trophy, the Österreichische Alpenfahrt, and the La Turbie hillclimb. In 1938, the 328 won its class at Le Mans, the RAC Tourist Trophy, the Alpine Rally, and the Mille Miglia. The 328 won the RAC Rally in 1939 and came in fifth overall and first in class in the 1939 24 Hours of Le Mans. The car continued its competition career after the war, with Frank Pratt winning the 1948 Australian Grand Prix driving a 328.

BMW introduced the M4 GTS concept in August 2015 at the Pebble Beach Concours d’Elegance, and then in 2016, released this “production” track-focused version of the standard M4 coupe, limited to 700 units with a US price tag of $133,205 (and about the same in £ sterling!0 It is powered by the same 3.0-litre twin-turbo straight-six engine as in the normal M4, but the power has been raised to 500 PS (493 bhp), largely due to a novel water injection system that is the first to be used on a production car in almost twenty years. In addition to the increased engine power, the M4 GTS is 27 kg (60 lb) lighter than the standard M4 Coupé with the DCT transmission, so the weight now stands at 1,585 kg (3,494 lb). The 0 to 100 km/h (62 mph) is reduced to just 3.8 seconds, while the top speed is 305 km/h (190 mph). The M4 GTS has, according to BMW, lapped the Nürburgring Nordschleife in 7min 28sec, 24 seconds faster than the base M4, 20 seconds faster than the M3 GTS and the same time as a Porsche Carrera GT.

Shown alongside it was the M4 DTM car.

Several example of the E9 coupe models were to be found here. These two-door coupés were built for BMW by Karmann from 1968 to 1975 and were developed from the New Class-based BMW 2000 CS coupé. The first of the E9 coupés, the 2800 CS, replaced the 2000 C and 2000 CS in 1968. The wheelbase and length were increased to allow the engine bay to be long enough to accommodate the new straight-six engine code-named M30, and the front of the car was restyled to resemble the E3 saloon. The rear axle, however, remained the same as that used in the lesser “Neue Klasse” models and the rear brakes were initially drums – meaning that the 2800 saloon was a better performing car, as it was also lighter. The CS’ advantages were thus strictly optical to begin with The 2800 CS used the 2,788 cc version of the engine used in the E3 2800 ssaloon. The engine produced 170 hp.The 2800CS was replaced by the 3.0 CS and 3.0 CSi in 1971. The engine had been bored out to give a displacement of 2,986 cc, and was offered with a 9.0:1 compression ratio, twin carburettors, and 180 hp in the 3.0 CS or a 9.5:1 compression ratio, Bosch D-Jetronic fuel injection, and 200 hp in the 3.0 CSi. There was a 4 speed manual and an automatic transmission variant. Introduced in May 1972, the 3.0 CSL was a homologation special built to make the car eligible for racing in the European Touring Car Championship. 1,265 were built. The “L” in the designation meant leicht (light), unlike in other BMW designations, where it meant lang (long). The lightness was achieved by using thinner steel to build the unit body, deleting the trim and soundproofing, using aluminium alloy doors, bonnet, and boot lid, and using Perspex side windows. The five hundred 3.0 CSLs exported to the United Kingdom were not quite as light as the others, as the importer had insisted on retaining the soundproofing, electric windows, and stock E9 bumpers on these cars. Initially using the same engine as the 3.0 CS, the 3.0 CSL was given a very small increase in displacement to 3,003 cc by increasing the engine bore by one quarter of a millimetre. This was done in August 1972 to allow the CSL to be raced in the “over three litre” racing category, allowing for some increase in displacement in the racing cars. In 1973,the engine in the 3.0 CSL was given another, more substantial increase in displacement to 3,153 cc by increasing the stroke to 84 mm. This final version of the 3.0 CSL was homologated in July 1973 along with an aerodynamic package including a large air dam, short fins running along the front fenders, a spoiler above and behind the trailing edge of the roof, and a tall rear wing. The rear wings were not installed at the factory, but were left in the boot for installation after purchase. This was done because the wings were illegal for use on German roads. The full aero package earned the racing CSLs the nickname “Batmobile”. In 1973, Toine Hezemans won the European Touring Car Championship in a 3.0 CSL and co-drove a 3.0 CSL with Dieter Quester to a class victory at Le Mans. Hezemans and Quester had driven to second place at the 1973 German Touring Car Grand Prix at Nürburgring, being beaten only by Chris Amon and Hans-Joachim Stuck in another 3.0 CSL 3.0 CSLs would win the European Touring Car Championship again in every year from 1975 to 1979. The 3.0 CSL was raced in the IMSA GT Championship in 1975, with Sam Posey, Brian Redman, and Ronnie Peterson winning races during the season. The first two BMW Art Cars were 3.0 CSLs; the first was painted by Alexander Calder and the second by Frank Stella.

From the same time period were a number of 02 Series cars. The 1600-2, as the first “02 Series” BMW was designated, was an entry-level BMW, and was smaller, less expensive, and less well-appointed than the New Class Sedan on which it was based. BMW’s design director Wilhelm Hofmeister assigned the two-door project to staff designers Georg Bertram and Manfred Rennen. The 9.1 in shorter length and wheelbase and lighter weight of the two-door sedan made it more suitable than the original New Class sedan for sporting applications. As a result, the two door sedan became the basis of the sporting 02 Series. The 1600-2 (the “-2” meaning “2-door”) made its debut at the Geneva Show in March 1966 and was sold until 1975, with the designation being simplified to “1602” in 1971. The 1.6 litre M10 engine produced 84 hp at 5,700 rpm and 96 lb·ft. A high performance version, the 1600 TI, was introduced in September 1967. With a compression ratio of 9.5:1 and the dual Solex PHH side-draft carburettor system from the 1800 TI, the 1600 TI produced 110 hp at 6,000 rpm. Also introduced in September 1967 was a limited-production cabriolet, which would be produced by Baur from 1967 through 1971. A hatchback 1600 Touring model was introduced in 1971 but was discontinued in 1972. It was what came next which was more significant. Helmut Werner Bönsch, BMW’s director of product planning, and Alex von Falkenhausen, designer of the M10 engine, each had a two litre engine installed in a 1600-2 for their respective personal use. When they realised they had both made the same modification to their own cars, they prepared a joint proposal to BMW’s board to manufacture a two litre version of the 1600-2. At the same time, American importer Max Hoffman was asking BMW for a sporting version of the 02 series that could be sold in the United States. As per the larger coupe and 4-door saloon models, the 2.0 engine was sold in two states of tune: the base single-carburettor 2002 producing 101 hp and the dual-carburettor high compression 2002 ti producing 119 hp.In 1971, the Baur cabriolet was switched from the 1.6 litre engine to the 2.0 litre engine to become the 2002 cabriolet, the Touring hatchback version of the 02 Series became available with all engine sizes available in the 02 Series at the time and the 2002 tii was introduced as the replacement for the 2002 ti. The 2002 tii used the fuel-injected 130 hp engine from the 2000 tii, which resulted in a top speed of 185 km/h (115 mph). A 2002 tii Touring model was available throughout the run of the tii engine and the Touring body, both of which ended production in 1974. The 2002 Turbo was launched at the 1973 Frankfurt Motor Show. This was BMW’s first turbocharged production car and the first turbocharged car since General Motors’ brief offerings in the early 1960s. It produced 170 hp. The 2002 Turbo used the 2002 tii engine with a KKK turbocharger and a compression ratio of 6.9:1 in order to prevent engine knocking. Kugelfischer mechanical fuel injection was used, with a sliding throttle plate instead of the usual throttle butterfly. The 2002 Turbo was introduced just before the 1973 oil crisis, therefore only 1,672 were built. The 1802 was introduced in 1971 and was available with either the original 2-door sedan body or the 3-door Touring hatchback introduced that year. Production of the Touring model continued until 1974, with the 1802 sedan ending production the following year. The 1502, an economy model with an engine displacement of 1573 cc was introduced in 1975. This engine had a lower compression ratio of 8.0:1, therefore standard-octane petrol could be used. While the rest of the 02 Series was replaced in 1975 by the E21 3 Series, the 1502 was continued until 1977.

The first car to bear the 6 Series nomenclature was the E24, which was launched in 1976, as a replacement for the E9 model 3.0 CS and CSL coupés first produced in 1965. The 3.0 CS was almost changed by adding a few centimeters in height to make it easier for customers to get into the car. However, Bob Lutz rebelled against the decision and rough drafted an alternative version that soon became the 6 series. Production started in March 1976 with two models: the 630 CS and 633 CSi. Originally the bodies were manufactured by Karmann, but production was later taken in-house to BMW. In July 1978 a more powerful variant, the 635 CSi, was introduced that featured as standard a special close-ratio 5-speed gearbox and a single piece black rear spoiler. The bigger bore and shorter stroke facilitated max 218 hp at 5200rpm and a better torque curve. For the first year, the 635 CSi was offered in three colours (Polaris, Henna Red, Graphite), and could also be spotted by the front air dam that did not have attached fog lights. These simple cosmetic changes reportedly worked to reduce uplift on the car at high speeds by almost 15% over the non-spoiler body shape. This early model shared suspension components with the inaugural BMW 5-series, the E12. In 1979 the carburettor 630 CS was replaced with the 628 CSi with its fuel injected 2.8 litre engine taken from the BMW 528i. In 1980 the 635 CSi gained the central locking system that is also controlled from the boot. Also, the E24 body style converted from L-jetronic injection to a Bosch Motronic DME. In 1982 (Europe) and 1983 (US), the E24 changed slightly in appearance, with an improved interior and slightly modified exterior. At the same time, the 635 CSi received a new engine, a slightly smaller-bored and longer-stroked 3430 cc six to replace the former 3453 cc engine and became available with a wide-ratio 5-speed manual or an automatic. This slight change was in fact a major change as pre-1982 cars were based on the E12 5-series chassis; after mid-1982, E24s shared the improved E28 5-series chassis. The only parts that remained the same were some of the exterior body panels. E24s produced after June 1987 came with new, ellipsoid headlamps which projects beam more directly onto road surface (newly introduced E32 7-series also sporting them). The sleeker European bumpers were also discontinued. Previous cars had either a European-standard bumper or a larger, reinforced bumper to meet the US standard requiring bumpers to withstand impact at 5 mph without damage to safety-related components. 1989 was the last year for the E24 with production stopping in April. The E24 was supplanted by the considerably heavier, more complex, and more exclusive 8 Series. BMW Motorsport introduced the M 635 CSi in Europe at the Frankfurt Motor Show in 1983. It is essentially an E24 powered by the powerplant of the BMW M1 – the M88 with 286 PS). Most of the cars were equipped with special metric 415 mm diameter wheels requiring Michelin TRX tyres. A catalysed, lower compression ratio version of the car with the S38 engine (260 PS ) was introduced in the U.S. in 1987. All M6 cars came standard with a 25% rear limited slip differential. U.S. models included additional comforts that were usually optional on models sold in Europe such as Nappa leather power seats and a dedicated rear A/C unit with a centre beverage chiller. 4,088 M635CSi cars were built between 1983 and 1988 with 1,767 U.S.

In the late 1970s, Italian manufacturer Lamborghini had entered into an agreement with BMW to build a production racing car in sufficient quantity for homologation, but conflicts arose and Lamborghini’s increasingly tenuous financial position at the time meant that BMW reasserted control over the project and ended up producing the car themselves after 7 prototypes had been built. The result was the BMW M1 a hand-built car that was sold to the public between 1978 and 1981 under the Motorsport division of BMW. The body was designed by Giugiaro, taking inspiration from the 1972 BMW Turbo show car. The only mid-engined BMW to be “mass”produced, it employed a twin-cam M88/1 3.5 litre 6-cylinder petrol engine with Kugelfischer mechanical fuel injection, a version of which was later used in the South African version of the BMW 745i, as well as the E24 BMW M6/M635CSi and E28 BMW M5. The engine had six separate throttle bodies, four valves per cylinder and produced 273 hp, giving it a top speed of 162 mph. Turbocharged racing versions were capable of producing around 850 hp. Only 453 production M1s were built, making it one of BMW’s rarest models. Of these, 20 were race versions created for the BMW M1 Procar Championship.

It was nice to see an E28 M5, the first model to bear the now legendary name. This M5 made its debut at Amsterdam Motor Show in February 1984. It was the product of demand for an automobile with the carrying capacity of a saloon, but the overall appearance of a sports car. It utilised the 535xi chassis and an evolution of the bodykit from the M535i. At its launch, the E28 M5 was the fastest production sedan in the world. The first generation M5 was hand-built in Preussenstrasse/Munich prior to the 1986 Motorsport factory summer vacation. Thereafter, M5 production was moved to Daimlerstrasse in Garching where the remainder were built by hand. Production of the M5 continued until November 1988, well after production of the E28 chassis ended in Germany in December 1987. The M5 was produced in four different versions based on intended export locations. These were the left-hand drive Euro spec, the right-hand drive UK spec, the LHD North American spec for the United States and Canada, and the RHD South African spec. The European and South African M5s used the M88/3 engine which produced 286 PS. North American 1988 models used the S38B35 engine which was equipped with a catalytic converter and produced 256 hp. With a total production of 2,191 units, the E28 M5 remains among the rarest regular production BMW Motorsport cars – after the BMW M1 (456 units), BMW E34 M5 Touring (891 units), and the BMW 850CSi (1510 units).

The BMW E30 is the second generation of BMW 3 Series, which was produced from 1982 to 1994 and replaced the E21 3 Series, and was the car which really saw the popularity of the 3 Series increase dramatically. . Development of the E30 3 Series began in July 1976, with styling being developed under chief designer Claus Luthe with exterior styling led by Boyke Boyer. In 1978, the final design was approved, with design freeze (cubing process) being completed in 1979. BMW’s launch film for the E30 shows the design process including Computer-aided design (CAD), crash testing and wind-tunnel testing. The car was released at the end of November 1982. Externally, the E30’s appearance is very similar to twin headlight versions of its E21 predecessor, however there are various detail changes in styling to the E30. Major differences to the E21 include the interior and a revised suspension, the latter to reduce the oversteer for which the E21 was criticised. At launch, the car had a 2 door style like its predecessor and just four engines, all of them petrol: the 316 and 318 four cylinder units and the 320 and 323i 6 cylinders. This last was soon upgraded to a 2.5 litre unit. Diesel models were added during the 80s and there was an all-wheel drive 325iX option for continental European markets. In addition to the 2 door saloon and Baur convertible body styles of its E21 predecessors, the E30 became available by early 1984 as a four-door sedan and later a five-door station wagon (marketed as “Touring”). The Touring body style began life as a prototype built by BMW engineer Max Reisböck in his friend’s garage in 1984 and began production in 1987. The factory convertible version began production in 1985, with the Baur convertible conversions remaining available alongside it. Following the launch of the E36 3 Series in 1990, the E30 began to be phased out.

Oldest of the legendary M3 cars was this fabulous E30 M3. Produced initially purely as a homologation special, the car achieved far greater levels of interest than ever imagined, and the rest, as they say, is history. Based on the 1986 model year E30 3 Series, the car was initially available with the 2 door body and was later offered as a convertible bodies. The E30 M3 used the BMW S14 engine. The first iteration of the road car engine produced 195 PS with a catalytic converter and 200 PS without a catalytic converter in September 1989 power was increased to 215 PS with a catalytic converter. The “Evolution” model (also called “EVO2”) produced 220 PS. Other Evolution model changes included larger wheels (16 X 7.5 inches), thinner rear and side window glass, a lighter bootlid, a deeper front splitter and additional rear spoiler. Later the “Sport Evolution” model production run of 600 (sometimes referred as “EVO3”) increased engine displacement to 2.5 litres and produced 238 PS. Sport Evolution models have enlarged front bumper openings and an adjustable multi-position front splitter and rear wing. Brake cooling ducts were installed in place of front foglights. An additional 786 convertibles were also produced. The E30 M3 differed from the rest of the E30 line-up in many other ways. Although using the same basic unit-body shell as the standard E30, the M3 was equipped with 12 different and unique body panels for the purposes of improving aerodynamics, as well as “box flared” wheel-arches in the front and rear to accommodate a wider track with wider and taller wheels and tyres. The only exterior body panels the standard model 3 Series and the M3 shared were the bonnet, roof panel, sunroof, and door panels. The E30 M3 differed from the standard E30 by having a 5×120 wheel bolt pattern. The E30 M3 had increased caster angle through major front suspension changes. The M3 had specific solid rubber offset control arm bushings. It used aluminium control arms and the front strut tubes were changed to a design similar (bolt on kingpins and swaybar mounted to strut tube) to the E28 5 Series. This included carrying over the 5 series front wheel bearings and brake caliper bolt spacing. The rear suspension was a carry over from the E30. The E30 M3 had special front and rear brake calipers and rotors. It also has a special brake master cylinder. The E30 M3 had one of two Getrag 265 5-speed gearboxes. US models received an overdrive transmission while European models were outfitted with a dogleg version, with first gear being down and to the left, and fifth gear being a direct 1:1 ratio. Rear differentials installed included a 4.10:1 final-drive ratio for US models. European versions were equipped with a 3.15:1 final drive ratio. All versions were clutch-type limited-slip differentials with 25% lockup. To keep the car competitive in racing following year-to-year homologation rules changes, homologation specials were produced. These include the Evo 1, Evo 2, and Sport Evolution, some of which featured less weight, improved aerodynamics, taller front wheel arches (Sport Evolution; to further facilitate 18-inch wheels in DTM), brake ducting, and more power. Other limited-production models (based on evolution models but featuring special paintwork and/or unique interior schemes commemorating championship wins) include the Europa, Ravaglia, Cecotto, and Europameister. Production of the original E30 M3 ended in early 1992.

The first example of the Z1 was released by BMW to the press in 1986 and later officially presented at the 1987 Frankfurt Motor Show. Initial demand was so fierce that BMW had 5,000 orders before production began. The Z1 was designed over a three-year period by an in-house division of BMW Forschung und Technik GmbH. The development of the Z1 is attributed to Ulrich Bez and his team at BMW Technik GmbH. The BMW Z1 was used to develop and debut several technologies. Z1 designer Harm Lagaay mentioned that Z1 production helped generate patents for BMW’s high-intensity discharge lamp, integrated roll-bar, door mechanism, and underbody tray. Both the engine and the five-speed manual transmission were sourced from the E30 325i. The 2.5 litre 12-valve SOHC straight-six engine sits tilted 20 degrees to the right to accommodate the low bonnet line. The engine produces 168 hp at 5,800 rpm and 164 lb·ft of torque in its original form. The rear suspension, called the Z Axle, was specially designed for the Z1 and this was one of the first BMWs to feature a multi-link design. In the 1990s, the Z Axle would be used on a variety of BMW Group vehicles, including the E36, 3 series, and the R40 Rover 75. The chassis was specially designed for the Z1 and featured a number of innovative features: removable body panels, continuously zinc welded seams, a composite undertray, and the unusual dropped doors. Parts of the car (including the engine, gearbox, and front suspension) were borrowed from the BMW E30 325i and 325Ix, but most of the Z1’s components are unique to the model, and that had the consequence of making it expensive. The body was made from plastic and could be removed completely from the chassis. The side panels and doors are made of General Electric’s XENOY thermoplastic. The hood, trunk, and roof cover are GRP components made by Seger + Hoffman AG. The car is painted in a special flexible lacquer finish developed jointly by AKZO Coatings and BMW Technik GmbH. During the Z1s launch, BMW suggested that owners purchase an additional set of body panels and change the colour of the car from time to time. The car could actually be driven with all of the panels completely removed, similar to the Pontiac Fiero. BMW noted that the body could be completely replaced in 40 minutes, although Z1 owners have reported that this may be optimistic. The entire vehicle was designed with aerodynamics in mind. Specifically, the entire undertray is completely flat and the exhaust and rear valance were designed as integral aerodynamic components to decrease turbulence and rear lift. The front end reportedly induces a high-pressure zone just forward of the front wheels to increase front-wheel traction. The Z1 has a drag coefficient of 0.36 Cd with the top up or 0.43 Cd with it down. The doors retract vertically down into the car’s body instead of swinging outward or upward. The Kaiser Darrin was the first car to have retractable doors; they slid forward into the front wings. The inspiration for these doors came from more traditional roadsters which often feature removable metal or cloth doors. Because removable doors did not fit within BMW’s design goals, the retractable doors were installed instead. The body with its high sills, offers crash protection independent of the doors, the vehicle may be legally and safely driven with the doors up or down, although this is not legal in the U.S. The windows may be operated independently of the doors, although they do retract automatically if the door is lowered. Both the window and door are driven by electric motors through toothed rubber belts and may be moved manually in an emergency. It took a while to get the Z1 into production, by which time demand had dropped considerably, perhaps due to reduced demand from speculators. In the end, BMW only produced 8,000 Z1 models. 6,443 of these were sold in BMW’s native German market. The country to receive the second-greatest number of Z1s, Italy, received less than 7% of the total sold domestically. BMW was reportedly unable to build more than 10 to 20 Z1 vehicles each day. None were initially sold in North America, although examples have been independently imported since the car’s launch. More than half of all Z1 vehicles (specifically, 4,091) were produced for the 1990 model year. Seventy-eight Z1 vehicles were reportedly used as test mules, although most were later sold without a warranty and, presumably, at a lower price. The Z1 was available in six exterior colours and four interior colours. Most (6,177) were red, black, or green with a dark grey interior. Light yellow exterior (fun-gelb in German or fun yellow in English, with 33 examples made and cars with a red interior (38 examples made) are the rarest Z1 colours. The colours swimming pool blue and oh-so-orange were reserved for the car’s designers, Bez and Lagaay. Reportedly, some 1,101 Z1 vehicles were delivered without a factory radio installed. In these vehicles, BMW AG installed an aftermarket Sony radio in its place. None of the Z1 vehicles were sold with air conditioning. The vehicle’s dashboard is very small and there was no room for both heat and cooling units. Some Z1 vehicles were converted using BMW E30 parts to have air conditioning, but reportedly the heater elements had to be removed. Although prices did drop from the new car cost of around £40,000, these have never been cheap cars to buy, and these days values are increasing again.

In 1994, BMW produced the limited-edition M3 GT as a racing homologation special for Europe, in order to compete in the FIA-GT class II, IMSA GT and international long-distance races. A total of 356 cars were produced, all in left-hand drive for mainland Europe. The UK received a special GT trim limited to 50 cars with only the cosmetic upgrades of the homologation special. The engine was the European-specification S50B30, which was upgraded with larger camshafts and a higher compression ratio, resulting in peak power of 295 bhp at 7,100 rpm. All M3 GTs only came in one single colour, “British Racing Green”. Other changes include a deeper and adjustable front splitter, higher rear double wing, aluminium doors, wheels measuring 17 x 7.5 inches at the front and 17 x 8.5 inches at the rear, stiffer front suspension, a cross-brace and a strut brace. The M3 GT is approximately 30 kg (66 lb) lighter than the regular M3 and has a derestricted top speed of 275 km/h (171 mph).

The M3 version of the E46 3 Series was produced in coupé and convertible body styles. The E46 M3 is powered by the S54 straight-six engine and has a 0-100 km/h (62 mph) acceleration time of 5.1 seconds for the coupe, with either the manual or SMG-II transmission. The skid pad cornering results are 0.89 g for the coupe and 0.81 g for the convertible.The top speed is electronically limited to 250 km/h (155 mph). The available transmissions were a Getrag 420G 6-speed manual transmission or a SMG-II 6-speed automated manual transmission, which was based on the Getrag 420G. The SMG-II used an electrohydraulically actuated clutch and gearshifts could be selected via the gear knob or paddles mounted on the steering wheel. The SMG-II was praised for its fast shift times and racetrack performance, but some people found its shifts to be delayed and lurching in stop-start traffic. In 2005, a special edition was introduced which used several parts from the CSL. This model was called the M3 Competition Package (ZCP) in the United States and mainland Europe, and the M3 CS in the United Kingdom. Compared to the regular M3, the Competition Package includes: 19-inch BBS alloy wheels- 19″x 8″ at the front and 19″x 9.5″ at the rear; Stiffer springs (which were carried over to the regular M3 from 12/04); Faster ratio steering rack of 14.5:1 (compared with the regular M3’s ratio of 15.4:1) as per the CSL; Steering wheel from the CSL; M-track mode for the electronic stability control, as per the CSL; The CSL’s larger front brake discs (but with the regular M3 front calipers) and rear brake calipers with larger pistons; Alcantara steering wheel and handbrake covers; The engine, gearbox and other drivetrain components are the same as the standard M3. Total production of the E46 M3 was 56,133 coupes and 29,633 convertibles. The cars were assembled at the BMW Regensburg factory in Germany and production was from September 2000 until August 2006, production totalled 85,766.

Representing the E31 8 Series, a car which found less favour than everyone expected when it was new, as this 840Ci. While it did supplant the original E24 based 6 Series in 1991, a common misconception is that the 8 Series was developed as a successor. It was actually an entirely new class aimed at a different market, however, with a substantially higher price and better performance than the 6 series. Design of the 8 Series began in 1984, with the final design phase and production development starting in 1986. The 8 Series debuted at the Frankfurt Motor Show (IAA) in early September 1989. The 8 Series was designed to move beyond the market of the original 6 Series. The 8 Series had substantially improved performance, however, as well as a far higher purchase price. Over 1.5 billion Deutsche Mark was spent on total development. BMW used CAD tools, still unusual at the time, to design the car’s all-new body. Combined with wind tunnel testing, the resulting car had a drag coefficient of 0.29, a major improvement from the previous BMW M6/635CSi’s 0.39. The 8 Series supercar offered the first V-12 engine mated to a 6-speed manual gearbox on a road car. It was the first car to feature CAN bus—a form of multiplex wiring for cars that is now an industry standard. It was also one of the first vehicles to be fitted with an electronic drive-by-wire throttle. The 8 Series was one of BMW’s first cars, together with the Z1, to use a multi-link rear axle. While CAD modelling allowed the car’s unibody to be 8 lb (3 kg) lighter than that of its predecessor, the car was significantly heavier when completed due to the large engine and added luxury items—a source of criticism from those who wanted BMW to concentrate on the driving experience. Some of the car’s weight may have been due to its pillarless “hardtop” body style, which lacked a “B” post. Sales of the 8 Series were affected by the global recession of the early 1990s, the Persian Gulf War, and energy price spikes. As a result, plans for the M8 supercar were dropped in 1991. A cheaper 8 cylinder 840CI joined the range in 1993 in an effort to boost sales, and to an extent it, did but this was still not enough and BMW pulled the 8 Series from the North American market in 1997, having sold only 7,232 cars over seven years. BMW continued production for Europe until 1999. The ultimate worldwide production total was 31,062

There were several of the Z sports cars here, with both the Z3 and the later Z4 in both its generations here.

Displayed among the Z cars was this, a Bertini GT25, an original design, body panel replacement kit to fit all versions of the BMW Z3. The vision is a modern take on classic British / Italian styling coupled with the reliability and interior quality of the German car. The doors, screen and soft top of the Z3 are retained so only the bonnet, boot lid, bumpers, wings and lights need to be removed. They can be sold to to offset the cost of the kit. All the Z3 mechanical parts and interior are also retained.

BMW’s current supercar is the futuristic i8, and there were examples of both this and the recently added Roadster version here. The Roadster was launched at the 2017 Los Angeles Show in December, and it is only now that the first right hand drive cars are reaching the UK, three years after the first of the closed coupe models went on sale. For the Roadster, the basic parameters are the same as the Coupe: plug-in hybrid powertrain, housed an aluminium chassis with a carbon-fibre monotub. But the battery boasts a higher capacity, and the hybrid powertrain more muscle to take the i8 even further (and faster). The 1.5-litre turbocharged three-cylinder engine now produces 231 bhp (up from 228), and the electric motor 143 hp (up from 131 hp) for a combined output of 374 hp to rocket the i8 coupe from a standstill to 60 mph in 4.2 seconds, and the roadster in 4.4 as they rocket towards their electronically limited top speed of 155 mph. With a battery pack upgraded from 20 Ah to 34 Ah and from 7.1 kWh to 11.6, it’ll also travel on electric power alone at speeds of up to 65 mph (instead of just 43 mph) – or 75 mph in eDrive mode. All-electric range is up to 34 miles (for the coupe, 33 for the convertible) on the ambitious New European Driving Cycle. The key new thing in the Roadster is the folding soft-top. Aside from the slight performance penalty, it does mean sacrificing the rear seats, but with the inherent rigidity of the carbon cell, chopping the roof off nets only a 132-pound weight penalty for a curb weight quoted at 3,516 lbs. That roof, incidentally, can raise and lower in just 15 seconds at speeds of up to 31 mph, folding into a compact Z-shaped vertical stack. The suspension’s been retuned for the roadster too, and new wheels for both versions reduce unsprung weight. These changes have been applied to the Coupe as well.

The M2 was first revealed in Need for Speed: No Limits on November 2015, before later premiering at the North American International Auto Show in January 2016. Production commenced in October 2015 and is only available as a rear-wheel drive coupé. The M2 is powered by the turbocharged 3.0-litre N55B30T0 straight-six engine producing 365 bhp at 6,500 rpm and 465 Nm (343 lb/ft) between 1,450–4,750 rpm, while an overboost function temporarily increases torque to 500 N⋅m (369 lb⋅ft). The M2 features pistons from the F80 M3 and F82 M4, and has lighter aluminium front and rear suspension components resulting in a 5 kg (11 lb) weight reduction. The M2 is available with a 6-speed manual or with a 7-speed dual-clutch transmission which features a ‘Smokey Burnout’ mode. 0-100 km/h acceleration times are 4.5 seconds manual transmission models and 4.3 seconds for models equipped with the 7-speed dual clutch transmission. Top speed is limited to 250 km/h (155 mph) but can be extended to 270 km/h (168 mph) with the optional M Driver’s package. The M2 Competition was introduced at the 2018 Beijing Auto Show and succeeded the standard M2 Coupé. Production began in July 2018. The M2 Competition uses the high performance S55 engine which is a variant of the 3.0-litre twin turbocharged straight six engine found in the F80 M3 and F82 M4. The engine features a redesigned oil supply system and modified cooling system from the BMW M4 with the Competition Package, and also features a gasoline particulate filter in certain European Union countries to reduce emissions. Compared to the standard M2, the S55 produces an additional 30 kW (40 hp) and 85 Nm (63 lb/ft), resulting in a larger and more sustained power output of 405 bhp between 5,370–7,200 rpm, and 550 N⋅m (406 lb⋅ft) at 2,350–5,230 rpm. The 0-100 km/h acceleration time is 4.4 seconds for six-speed manual transmission models, and 4.2 seconds for models with the 7-speed dual clutch transmission. Top speed is electronically limited to 250 km/h (155 mph), but the M Driver’s package can extend the limit to 280 km/h (174 mph) which is 10 km/h (6 mph) further than in the M2. The M2 Competition also has a carbon-fibre reinforced plastic strut bar, enlarged kidney grilles, and larger brake discs of 400 mm (15.7 in) in the front axle and 380 mm (15.0 in) in the rear axle. Because of the new engine and cooling system, the M2 Competition is 55 kg (121 lb) heavier than the standard M2 at 1,550 kg (3,417 lb) for manual transmission models and 1,575 kg (3,472 lb) for dual-clutch transmission models. It remains in production.

Final BMW I spotted was this 6 Gran Coupe.

BRABUS

G wagen

BRISTOL

The 403 is an example of the second body design produced by Bristol Cars. First seen on the 401 model, which replaced the first ever Bristol model, the 400, a program of updates saw the car morph into the 403 (the 402 having been an open topped version of the 401) and this car was then produced between 1953 and 1955, the third of the eventual five series of Bristols powered by the BMW-derived pushrod straight-six engine. It replaced both the Bristol 401 and 402 in 1953 and whilst it retained much the same styling as the 401, the new 403 featured many mechanical improvements compared to its predecessor. The 1971 cc six-cylinder engine was modified through the use of bigger valves and larger main bearings with a diameter of 54 mm as against 51 mm on the 400 and 401, which increased the power output to 100 hp as against 85 hp in the 401. The acceleration was markedly improved: the 403 could reach 60 mph in 13.4 seconds as against 16.4 seconds for the 401. The 403 had a top speed of 104 mph. To cope with this increased power, an anti-roll bar was fitted on the front suspension and improved drum brakes known as “Alfins” (Aluminium finned) were fitted. Early models had them on all wheels, but Bristol thought the car was over-braked and they were thus restricted to the front wheels on later 403s. The 403 was the last Bristol to feature a BMW-style radiator grille. It is also noteworthy for having two extra headlamps at the side, almost pre-dating the adoption of the four-headlamp layout in larger cars (Bristol themselves adopted it with the 411 in the late 1960s).

This is a 406, the last Bristol to use the BMW-derived pushrod straight six engine that had powered all cars built by the company up to that point. In a stopgap measure for the 406 its torque was improved by a 245 cc increase in capacity because it was clearly unable to give a performance comparable to that of newer engines emerging at the time. A prototype with a body by Carrosserie Beutler AG of Thun in Switzerland was exhibited in 1957 in both Paris and London Motor Shows. The start of production at Filton was announced in late August 1958. Compared to the 405, the 406 saw several significant changes. The most important was that the six-cylinder engine itself was enlarged slightly in both bore and stroke to dimensions of 69 mm by 100 mm This gave an engine displacement of 2,216 cc but the actual power of the engine was no greater than that of the 405. However, the torque was higher than for the smaller engine, especially at low engine speeds. Manufacture of the 2-litre version continued for supply to AC Cars for their AC Ace and Aceca. The 406 also featured Dunlop-built disc brakes on all four wheels (making it one of the first cars with four-wheel disc brakes) and a two-door saloon body Bristol were to stick with for a long period after adopting Chrysler V8 engines with the 407. The styling made the 406 more of a luxury car than a true sports saloon. The rear suspension of the 406 also did away with the outdated A-bracket of all previous Bristols for a more modern Watt’s linkage. The 406 was the world’s first production car to be thus equipped. However, the outdated front suspension of previous Bristols was retained and not updated until the following model with its more powerful drivetrain. It was replaced by the similar looking 407 in 1961.

There were further evolutions culminating in the Bristol 411 which was built from 1969 to 1976. It was the fifth series of Chrysler-V8 engined Bristol models. The car was rated highly for its comfort, performance and handling by contemporary reviewers. With the 411, Bristol, for the first time since the 407 was introduced, made a change of engine. Although they were still using a Chrysler V8 engine, the old A type engine was gone. Replacing it was the much larger big-block B series engine of 6,277 cc – as compared to the 5,211 cc of the 410. This much larger engine gave the 411 an estimated 30 percent more power than had been found in the 410. The 411 was capable of 230 km/h (143 mph). To cope with this extra power, a limited slip differential was fitted. The interior showed a number of important changes from the Bristol 410. The traditional Blümel twin-spoke steering wheel was replaced by a more practical three-spoked leather-wrapped wheel, which as a result of the traditional Bristol badge being removed from the front of the car, was the only place where this badge was retained. Over its seven years in production, the 411 showed a number of changes. The 1971 Series 2 added self-levelling suspension and a metric odometer, while the Series 3 from a year later had a lower compression ratio and completely revised styling. This edition was the first Bristol to possess the four-headlamp layout that was oddly anticipated by some of the company’s earliest models, and to power this a bigger alternator was used. For the Series 4 of 1974, the compression ratio was reduced dramatically (from 9.5:1 to 8.2:1) but this was compensated by using a larger version of the B series engine with a capacity of 6,556 cc. The rear lights were also changed using vertically mounted rectangular Lucas clusters, that carried over to the early 603 models. The Series 5 made from 1975 to 1976 had the original Bristol badge restored and was the first Bristol to feature inertia reel seat belts. In the 2010s Bristol Cars offered a modernised version of the Bristol 411, the Series 6. This was a refurbished version based on existing 411s. The only engine is the fuel injected 5.9 litre V8 as used in the later Bristol Blenheim, allowing for up to 400 hp depending on the customer’s desires. 297 were made.

CATERHAM

CHEVROLET

The Corvette Owners Club had a strong showing, as they usually do at this event. The majority of the cars that I came across this time were relatively recent from the C5 to current C7 generations.

CITROEN

The SM, a glamorous Sports/GT Coupe still wows people over 45 years since its debut. The Citroën SM was first shown at the 1970 Geneva Motor Show, but work on the car had started way back in 1961, with ‘Project S’, which was envisaged to be a a sports variant of the revolutionary Citroen DS. For the next few years, many running concept vehicles were developed, and these became increasingly complex and upmarket from the DS. In 1968, Citroën purchased Maserati, with the intention of harnessing Maserati’s high-performance engine technology to produce a true Gran Turismo car, which would combine Citroen’s advanced suspension with a V6 Maserati engine. The car was a sensation when revealed, with its distinctive styling, an amazingly low drag coefficient of just 0.26, and as well as the advanced features from the DS such as lights that swivelled with the steering and the advanced hydropneumatic self-levelling suspension there were numerous technical innovations such as variable assistance for the power steering, rain sensitive wipers and the option of lightweight wheels of composite alloys. It was a further six months before customers could get behind the wheel, with the SM finally going on sale in France in September of that year. The origin of the model name ‘SM’ is not clear. The ‘S’ may derive from the Project ‘S’ designation, and the ‘M’ may refers to Maserati, hence SM is often assumed to stand for ‘Sports Maserati’. Another common hypothesis is that SM stood for Série Maserati and others have suggested it is short for ‘Sa Majesté’ (Her Majesty in French), which would aligns with the explanation that the DS model was so called as a contraction of the French word ‘Déesse’ (The Goddess). Regardless of the origins of the name, it attracted lots of attention, and came third in the 1971 Car of the Year competition (behind Citroen’s own revolutionary GS model). For a couple of years, sales were reasonable, but they fell off dramatically in 1973, not just because of the Oil Crisis that struck late that year, but largely because the SM’s technical complexity came with a price tag of some terrible reliability problems, something which owners of rival cars simply did not experience. To compound the owner’s misery, they needed to find and pay for Citroen specialists who understood the hydraulics and a Maserati specialist for the engine. Both categories were kept busy. Citroen declared bankruptcy in 1974 and the company was purchased in May 1975. Thanks to changes in US legislation, sales in that market, which had hitherto been the SM’s largest had ceased, and so with global sales of under 300 SMs in 1974, having divested itself of Maserati, new owner Peugeot took the obvious decision to cease production of the SM almost immediately. During the SM’s 5 year product life, a total of 12,920 cars were produced. With the exception of a handful of conversions for the Australian market, all SMs were made in left hand drive, which is perhaps one reason why UK sales amounted to just 325 cars from that total. Although this is often labelled as one of the 4 “nightmare cars of the apocalypse” (along with the Triumph Stag and Alfa Montreal), the reality is that the surviving cars have largely been “fixed” and they are now not the fearsome ownership proposition that many still assume.

This is an AX Sport. Development of this model started in 1983, and was initially also going to form the basis of a sister model from Talbot to replace the Samba; however, the falling popularity of the Talbot brand – coupled with the huge success of the new Peugeot 205 – had led to Peugeot deciding to axe it by the time the Citroën AX was launched, and so the Talbot version never made it into production. The car was available on the left-hand drive continental markets from its launch on 2 October 1986, as a three-door hatchback with 1.0, 1.1 and 1.4-litre TU-series belt driven OHC engines. A range of five-door models was added in 1987 and a 1.4 litre diesel engine was introduced in 1988. The latter was replaced by a 1.5 litre unit in September 1994. The right-hand drive version for the UK market was launched in August 1987, initially only as a three-door hatchback, with a five-door version joining the range a year later, effectively replacing the five-door Citroën Visa, which was discontinued that year. With the final demise of the classic Citroën 2CV in 1990, the AX became the smallest model in the Citroën range. The very earliest cars had an issue with gear shifters falling off; this was rectified by the time the AX reached export markets. It was initially backed by a memorable television advertising campaign filmed in China, starring actress Janet Mas and an elderly gentleman, whose character was simply known as Mr. Wong. The car was very economical, largely because of excellent aerodynamics for its class of car (drag coefficient of 0.31) and a very light weight of 640 kg (1,411 lb) for the basic version. This was due to the extensive use of plastic panels in non-load bearing areas and varying the thicknesses of steel in the bodyshell to be the minimum needed to take required loads. Another target for the engineers was lowering friction in the engines. The AX has fully independent suspension with unusually long wheel travel. It also optionally used self-coloured plastic bumpers. This technology came from the PSA Peugeot-Citroën / Renault / French government ECO 2000 project. The production version was much more conservative than the original ‘one box’ design prototype, that was closer to the Eco 2000 styling after negative reactions in focus groups. The “one-box” city car eventually came to market with the Renault Twingo, launched in 1992. In 1989, a naturally aspirated diesel AX, using the 1360 cc all aluminium alloy TUD engine, managed a figure of 2.7 litres/100 km (100 mpg), totalling over 1,000 miles from Dover to Barcelona. This was the longest ever distance travelled on 10 gallons of fuel and earned it a place in the Guinness Book of Records as the most economical production car. Also available was a 4×4 variant, but with limited success when compared to the rival Fiat Panda 4×4. The AX 4×4 was only available with five doors and was not sold in the United Kingdom. The first performance version was the limited-run AX Sport from 1987, with a 1.3 engine and twin carburettors producing 95 bhp, wearing iconic white steel wheels (5,5″ x 13″) which resembled those on its brother, the Peugeot 205 Rallye. The AX Sport used Solex ADDHE 40 carburettors until late 1988 and was then replaced with Weber DCOM 40s, just like the 205 Rallye 1,3. The AX Sport had a shorter inlet manifold than the 205 Rallye, to save room in the smaller engine compartment. In phase 2 guise the Sport was available in other colours and with optional GT wheels and rear spoiler. Later, the AX 14GT, with a single-carburettor 85 bhp 1.4 engine also found in the Peugeot 205 XS, was introduced. From 1991, this model utilised fuel injection to coincide with the revamp of the entire range and to coincide with tougher 1992 EU emission regulations that introduced exhaust catalytic converters. Late 1991 saw the range revised, with a heavily facelifted tailgate and interior being the most notable changes. The front turn signals were now clear, and the Citroën logo was moved to the center of the bonnet. The much maligned dashboard was replaced by a more conservative design. The following year saw the introduction of the most powerful AX variant, the 100 bhp GTi. The GT was sold alongside the GTi for a few months, but was eventually phased out. New models were also introduced, such as the Forte, Spree, Elation and Dimension. In January 1995, the Citroën AX Echo was launched, with a top speed of 110 mph (180 km/h). Its closest competitor, the Peugeot 106 Ski, (that shared components with the AX), was outsold by the Echo. From June 1996, following the introduction of the Saxo, the range was slimmed-down, with production of the AX ending in December 1998, after a 12-year production run. It had been withdrawn from the UK market during the first half of 1997, following the demise of right-hand drive production. A total of 2,425,138 AXs were produced.

The C6 was inspired by the Citroën C6 Lignage prototype which was first shown at the Geneva Motor Show in the spring of 1999. When shown, it was clear that this was a potential replacement for the XM, and Citroën was intent on launching it before the end of 2000. It took rather longer than that, though, with the production C6 not being launched until 2005, four years later than Citroen had originally planned and five years after the XM had ceased production. In appearance, it was not very different form the C6 Lignage concept, though it did lack the rear suicide doors. Intended to compete against the might of the German executive triumvirate of E Class, 5 Series and A6, as well as be a flagship French model, the C6 was launched with the choice of a 3.0 litre V6 petrol engine producing 208hp or a 2.7 litre V6 HDi diesel producing 201 hp (shared with the Jaguar models of the time. In October 2006 a 2.2 litre 4 cylinder HDi producing 168hp joined the range and in June 2009 the V6 diesel unit was enlarged to 3 litres and now producing 237 hp. Few other changes were made to the car during its product life. Despite the looks, the C6 was a conventional saloon, with a boot lid, as opposed to a hatchback (just as the earlier CX had been). Citroën hoped that as well as its undoubted elegance, the C6’s selling points would be its innovative technology, which included a head-up display, a lane departure warning system, xenon directional headlamps (also available on the Citroën C4 and Citroën C5), and the Hydractive 3+ suspension with electronically controlled springing and damping which gave the car a “magic carpet” like ride, and a rear spoiler which automatically adjusted to speed and braking. On launch, the press used phrases such as “spaceship that rides on air”, “charmingly idiosyncratic” and “refreshingly different”. Unsurprisingly, the C6 immediately became a prominent vehicle among the fleet of executive cars of the Élysée Palace. Former Presidents of France, Jacques Chirac & Nicolas Sarkozy, have chosen the Citroën C6 as their official car. Chirac, in particular, used a pre-series car before the model was introduced. But finding buyers among the general public proved more difficult. At launch sales expectations across the model’s lifespan were given as 20,000 per year, but when production ended on 19 December 2012, only 23,384 units built over a 7 year period.

DAIMLER

The SP250 “Dart” was quite unlike any previous Daimler model, the marque having a history of producing a series of luxurious saloon and open topped models. But by the mid 1950s, the once proud Coventry marque was in trouble, with a range of cars which were expensive and just not selling. New models were seen as a potential way of changing things around, so shortly after being appointed Managing Director of BSA’s Automotive Division in 1956, Edward Turner was asked to design a saloon car powered by a new V8 engine. The engine drawings were finalised by March 1958 but the saloon prototype, project number DN250, was not available for examination by the committee formed in 1958 to report on the feasibility of the V8 cars. The committee’s evaluation centred on the prototypes being tested at the time, which were for the SP250 sports car project. according to the feasibility study conducted by the committee, the SP250 would generate a profit of more than £700,000 based on a projection of 1,500 cars being sold in the first year of production and 3,000 cars per year for the second and third years of production. Two-thirds of the sales of the car were expected to be in the United States. The study also determined that the body should be made from fibreglass, with shorter time to the beginning of production, tooling costs of £16,000 as opposed to £120,000 for steel bodies, and lower cost to change the styling. That meant that the car was able to be launched at the 1959 New York Show, christened the Daimler Dart. Chrysler, whose Dodge division owned the trademark for the “Dart” model name, ordered Daimler to change the name under threat of legal action. With little time to come up with a new name, Daimler used the project number, SP250, as the model number. The car certainly looked quite unlike previous Daimlers, but whether that was a good thing is less clear as the SP250 won “The Ugliest Car” via vote at that 1959 show. That was not the only problem with the car, either. The original version, later called the A-spec, could reach a speed of 120 mph, but the chassis, a “14-gauge ladder frame with cruciform bracing” based on the Triumph TR3, flexed so much that doors occasionally came open, marring its reputation. The car featured the smaller of the two hemi-head V8 engines which Edward Turner had designed. 2547cc in capacity, it was a V8, iron block, OHV unit, with a single central camshaft operated valves through short pushrods with double heavy-duty valve springs, aluminium alloy hemispherical cylinder heads, and twin SU carburettors which meant it put out 140 bhp.The manual gearbox, the first of the type used by Daimler since they started using the pre-selector type across their range in the 1930s,, was reverse-engineered from the Standard gearbox used in the Triumph TR3A. Early examples of the car were not particularly reliable. Sales were slow, initially, and Daimlers problems were compounded when, not long after they had been acquired by Jaguar, an in-house rival in the form of the E Type arrived on the scene. New bosses at Jaguar did not kill off the SP250, though, but they were immediately concerned about the chassis flex. They brought out the B-spec. version with extra outriggers on the chassis and a strengthening hoop between the A-posts. There were also other detail improvements, including an adjustable steering column. Bumpers had originally been an optional extra. With the basic specification not including full bumpers, the A-spec. cars have two short, chromium-plated ‘whiskers’ on the body on either side of the front grille and two short, vertical bumpers, or “overriders” at the rear, which were not included if the rear bumper was optioned. B-spec. and the later C-spec. cars do not have the ‘whiskers’ that A-spec. have and some do not have the optional front bumper, so there is very little front protection for these cars. A planned Coupe version of the car, the DP250 never got beyond the prototype phase, and Ogle Design’s proposal for a Coupe version was not taken up, the styling for that concept ending up forming the Reliant Scimitar GT. The SP250 ended production in 1964. Just 2,654 SP250s were produced in five years of production, far short of the projection of 3,000 per year by the second year of production. Jaguar did built a prototype replacement under project number SP252 with a neater body style but decided not to proceed with production, as they figured that the cost to build the SP252 would have been greater than that of Jaguar’s popular and more expensive E-Type, thereby creating internal competition from a product with no practical profit margin and with uncertain market acceptance. These days, surviving SP250s are viewed rather more positively than they were when new, and a certain Quentin Willson, who has owned one for many years, is particularly positive about the car’s merits.

Now over 35 years old is the elegant Coupe version of the Jaguar XJ and Daimler Sovereign. First shown in September 1973, at the same time as the Series 2 versions of the Jaguar XJ6/12 and related Daimler models, it soon became clear that this version was not ready for production, with problems surrounding the window sealing. The economic troubles unfolding in the western world at this time seem to have reduced further any sense of urgency about producing and selling the cars, so it was a further two years before XJ Coupés finally started to appear in Jaguar showrooms. The Coupé was based on the short-wheelbase version of the XJ. The elongated doors were made out of a lengthened standard XJ front door, with the weld seams clearly visible under the interior panels where two front door shells were grafted together with a single outer skin. Even with the delay, these cars suffered from water leaks and wind noise. All coupes came with a vinyl roof as standard. Since the coupe lacked B-pillars, the roof flexed enough that the paint used by Jaguar at the time would develop cracks. More modern paints do not suffer such problems, so whenever a coupe is repainted it is viable to remove the vinyl. Today many XJ-Cs no longer have their vinyl roof, also removing the threat of roof rust. Some owners also modified their XJ-C by changing to Series III bumpers. This lifted the front indicators from under the bumper and provided built in rear fog lights. Both six and twelve-cylinder models were offered, along with Daimler badged versions. However, the delayed introduction, the labour-intensive work required by the modified saloon body, the higher price than the four-door car, and the focus on the new XJ-S all contributed to a short production run of just two years. 6,505 of the 4.2 and 1,873 of the V12 Jaguar models were made, along with 1677 Daimler Sovereign and 477 Double Six models, making a total of 10,426. Nowadays, the cars are much respected for their elegant design.

De TOMASO

Designed by American Tom Tjaarda, and unlike the Mangusta, which employed a steel backbone chassis, the Pantera was a steel monocoque design, the first instance of De Tomaso using this construction technique. The Pantera logo included a version of Argentina’s flag turned on its side with a T-shaped symbol that was the brand used by De Tomaso’s Argentinian cattle ranching ancestors. The car made its public debut in Modena in March 1970 and was presented at the 1970 New York Motor Show a few weeks later. Approximately a year later the first production Panteras were sold, and production was increased to three per day. The curious slat-backed seats which had attracted comment at the New York Show were replaced by more conventional body-hugging sports-car seats in the production cars: leg-room was generous but the pedals were off-set and headroom was insufficient for drivers above approximately 6 ft. Reflecting its makers’ transatlantic ambitions, the Pantera came with an abundance of standard features which appeared exotic in Europe, such as electric windows, air conditioning and even “doors that buzz when … open”. By the time the Pantera reached production, the interior was in most respects well sorted, although resting an arm on the central console could lead to inadvertently activating the poorly located cigarette lighter. The first 1971 Panteras were powered by a Ford 351 cu in (5.8 litre) V8 engine that produced a severely underrated 330 hp. Stock dynos over the years proved that power was more along the lines of about 380 hp. The high torque provided by the Ford engine reduced the need for excessive gear changing at low speeds: this made the car much less demanding to drive in urban conditions than many of the locally built competitor products. The ZF transaxle used in the Mangusta was also used for the Pantera: a passenger in an early Pantera recorded that the mechanical noises emanating from the transaxle were more intrusive than the well restrained engine noise. Power-assisted four-wheel disc brakes and rack and pinion steering were all standard equipment on the Pantera. The 1971 Pantera could accelerate to 60 mph in 5.5 seconds. In the summer of 1971, a visitor to the De Tomaso plant at Modena identified two different types of Pantera awaiting shipment, being respectively the European and American versions. From outside, the principal differences were the larger tail lamps on the cars destined for America, along with addition of corner marker lamps. The visitor was impressed by the large number of cars awaiting shipment; but in reality, spending the best part of a year under dust covers in a series of large hangars probably did nothing for the cash-flow of the business or the condition of some of the cars by the time they crossed the Atlantic. Late in 1971, Ford began importing Panteras for the American market to be sold through its Lincoln Mercury dealers. The first 75 cars were simply European imports and are known for their “push-button” door handles and hand-built Carrozzeria Vignale bodies. A total of 1,007 Panteras reached the United States that first year. These cars were poorly built, and several Panteras broke down during testing on Ford’s test track. Early crash testing at UCLA showed that safety cage engineering was not very well understood in the 1970s. Rust-proofing was minimal on these early cars, and the quality of fit and finish was poor, with large amounts of body solder being used to cover body panel flaws. Notably, Elvis Presley once fired a gun at his Pantera after it would not start. An L model (“Lusso”) was added in 1972 and a GTS version in 1974, but it was not enough and Ford ended their importation to the US in 1975, having sold around 5,500 cars. De Tomaso continued to build the car in ever-escalating forms of performance and luxury for almost two decades for sale in the rest of the world. A small number of Panteras were imported to the US by grey market importers in the 1980s, notably Panteramerica and AmeriSport. After 1974, Ford US discontinued the Cleveland 351 engine, but production continued in Australia until 1982. De Tomaso started sourcing their V8s from Australia once the American supplies dried up. These engines were tuned in Switzerland and were available with a range of outputs up to 360 PS. The chassis was completely revised in 1980, beginning with chassis number 9000. From May 1980 the lineup included the GT5, which had bonded and riveted-on fibreglass wheelarch extensions and from November 1984 the GT5S model which had blended arches and a distinctive wide-body look. The GT5 also incorporated better brakes, a more luxurious interior, much larger wheels and tires and the fibreglass body kit also included an air dam and side skirts. Production of the wide body GT5 (and similarly equipped narrow body GTS models) continued until 1985, when the GT5-S replaced the GT5. Although the factory has not made its records available, an analysis based on Vehicle Identification Numbers by the Pantera Owners Club of America (POCA) late model (9000 series) registrar has shown that fewer than 252 GT5 Panteras were likely to have been built. The GT5-S featured single piece flared steel fenders instead of the GT5’s riveted-on fibreglass flares, and a smaller steel front air dam. The ‘S’ in the GT5-S name stood for “steel”. Otherwise the GT5-S was largely identical to the GT5. The POCA 9000 series registrar’s VIN analysis indicates that fewer than 183 GT5-S Panteras were built. Concurrent GTS production continued, on a custom order and very limited basis, until the late 1980s. The car continued to use a Ford V8 engine, although in 1988, when the supply of Ford 351 Cleveland engines from Australia ran out, De Tomaso began installing Ford 351 Windsor engines in the Pantera instead. For 1990 the 351 was changed to the Ford 302 cu in (4942 cc, commonly called a “5.0”). Incorporating a Marcello Gandini facelift, suspension redesign, partial chassis redesign and the new, smaller engine, the Pantera 90 Si model was introduced in 1990. Only 38 90 Si models were sold before the Pantera was finally phased out in 1993 to make way for the radical, carbon-fibre-bodied Guarà. Some say 41 were built (with the last one not finished until 1996), of which four were targa models. The targas were converted by Pavesi directly off the production lines. In all, about 7,200 Panteras were built. The duo here were from the later production, with the much wider body and extended wheelarches.

The De Tomaso Deauville was a luxury four-door saloon first exhibited at Turin Motor Show 1970. The Deauville was powered by the same 351 in³ (5763 cc) Ford Cleveland V8 as the De Tomaso Pantera, rated at 330 hp. The car had a top speed of 230 km/h (143 mph) and featured styling similar to that of the Jaguar XJ. The Deauville had an independent rear suspension very similar to that used by Jaguar, and ventilated discs front and aft. It shares its chassis with the Maserati Quattroporte III. There were three Deauville variants: the early series 1 (1970–1974: serial number 10##, 11## and 12##), late series 1 (1975–1977: serial numbers 14##) and the series 2 (1978–1985: serial numbers 20## and 21##). A total of 244 cars were produced.

EVANTE

The Evante, designed and invented by George Walter Robinson, is an English automobile which began production in 1987 in Spalding, Lincolnshire, England. Engine tuning company Vegantune had been restoring Lotus Elan cars and making some improvements to them. They decided to build a complete new car and set up a separate company, Evante Cars Ltd, to make them. The car’s looks were heavily inspired by the Lotus Elan and it was powered by the Ford Kent based Vegantune VTA 1.6 and later 1.7-litre twin overhead cam engine driving the rear wheels through a gearbox originally from a Ford Sierra. The fibreglass body and carbon-fibre was mounted onto a space frame chassis with independent suspension all round. Disc brakes were fitted front and rear. The cars were intended to be available as either complete or in kit form but all cars were supplied fully built and were produced at a rate of about one a week. The bodies were fitted out with leather seats, walnut dashboard and electric windows. Production stopped in 1991 when the original company failed, but the design was bought by Fleur de Lys who specialised in making retro styled vans. They redeveloped the car to take a Ford Zetec 1.8 Litre engine, but only nine more cars were made. An attempt was made to revive the car in 2001, but this was unsuccessful. Spydercars Whittlesey now own the rights to the name and the fibre glass moulds.

FERRARI

The Ferrari Owners Club always put on a massive display of cars, with pretty much every model type from the last 50 years represented, and this year was no exception.

Still seen by many as the most beautiful Ferrari ever built was the 246 GT Dino and this time there was just one example here. The Ferrari Dino was created to honour Alfredo ‘Dino’ Ferrari, Enzo Ferrari’s only legitimate son, who sadly died of muscular dystrophy in 1956. Unlike any previous road-going Ferrari, the Dino utilised a V6 engine, the Tipo 156, which Alfredo himself had helped develop and strongly advocated during his working life. Following continued motor racing success and in order to homologate Ferrari’s 1966 Formula Two campaign, a new line of mid-engined production V6 coupés with Fiat running gear went on sale in 1967 in two litre 206 GT form. However, in 1969 a larger 2.4 litre Dino was introduced, named the 246 GT or GTS in the case of the Spider. Only 3,913 definitive Dinos were built before the introduction of the completely restyled V8 engined 308 in 1973. The voluptuous bodywork of the 246, which many regard as the prettiest ever to grace a road-going Ferrari, was designed by Pininfarina and built by Scaglietti. It clothed a tubular chassis which carried wishbone independent suspension at each corner. The compact four-cam, 190bhp. engine was mounted transversely above the five-speed gearbox and just ahead of the rear axle, allowing for both a comfortable cockpit and some usable boot space

The Ferrari 365 GTC/4, a 2+2 grand tourer, was only produced by Ferrari from 1971 to 1972. It was based on the chassis of the Ferrari 365 GTB/4 “Daytona”. In the very short two-year production run 505 examples of the GTC/4 were produced. Its chassis and drivetrain, however, were carried over mostly unaltered (apart from a wheelbase stretch to provide more satisfying rear seat room) on its successor, the 1972 365 GT4 2+2. The GTC/4’s coupé bodywork by Pininfarina enclosed two front and two rear seats, as on the 365 GT 2+2 it replaced directly. However, the rear seats were small and the slanting rear window limited rear headroom, so it can also be seen to trace to the two-seat 365 GTC that had been discontinued in 1970. With its wedge shape, fastback silhouette, sharp creases and hidden headlamps the GTC/4’s styling clearly reflects the 365 GTB/4 “Daytona” it was based on. Power steering, electric windows and air conditioning were standard. The cabin was upholstered in mixed leather and tartan fabric, unique to this model and unusual for a Ferrari, with full leather upholstery an option. The 365 GTC/4 shared the chassis and engine block as the 365 GTB/4 Daytona, riding on the same wheelbase and suspension. Many changes were made to make it a more comfortable grand tourer than its two-seat predecessor and sibling. These included softer spring rate and a hydraulic power steering. The chassis was a tubular spaceframe, mated to a steel body with aluminium doors and bonnets; as was customary in this period, the bodies were made and finished by Pininfarina in Turin, then sent to Ferrari in Modena for the assembly. The suspension system used transverse A-arms, coil springs coaxial with the shock absorbers (double at the rear), and anti-roll bars on all four corners. Wheels were cast magnesium on Rudge knock-off hubs, while Borrani wire wheels were optional; the braking system used vented discs front and rear. The engine was a Tipo F 101 AC 000 Colombo V12, displacing 4,390 cc. Engine block and cylinder heads were aluminium alloy, with cast iron pressed-in sleeves; chain-driven two overhead camshafts per bank (four in total, as noted by the “4” in the model designation) commanded two valves per cylinder. The V12 was detuned to 340 PS (335 bhp) from the Daytona, to provide a more tractable response suited to a GT-oriented Ferrari. In place of the Daytona’s downdraft setup, six twin-choke side-draft Weber carburetors were used, whose lower profile made possible the car’s lower and sloping bonnet line. The 5-speed all-synchronised manual transmission was bolted to the engine, another difference from the Daytona which used a transaxle. However the set back placement of the engine and transmission still allowed the car to achieve a near perfect 51:49 weight distribution. The gearbox was rigidly connected to the alloy housing of the rear differential through a torque tube. There are a handful of them in the UK.

Among the older four seater models was this 400GT, an elegant model that has languished in the doldrums of affection for far too long, but which is gradually gaining new fans, as people realise that it is not just worthy of the Ferrari badge on the front, but also an elegant and surprisingly practical Grand Tourer. The 400 was an evolution of the 365 GT4 2+2, which was first seen at the 1976 Paris Motor Show. It proved quite controversial, as this was the first Ferrari to be offered with an automatic gearbox, a Borg Warner 3-speed unit, though a five speed manual was also offered. The 365’s V12 engine had been stroked to a displacement of 4.8 litres and given six 38 DCOE 110-111 Webers, and now produced 340 PS. 0-60 mph took 7.1 seconds. Other changes compared to the 365 GT4 included five-stud wheels to replace the knock-off hubs (Borrani wheels weren’t offered anymore), a revised interior, the addition of a lip to the front spoiler, and double circular tail light assemblies instead of triple. A total of 502 examples were produced, 355 of which were Automatics and 147 GTs before a further upgrade in 1979 which saw the addition of fuel injection. It was replaced by the visually similar 412i in 1985. which had a larger 5 litre engine. Production of this version ran for 4 years, meaning that by the time the model was deleted from the range, this elegant Pininfarina design had been produced for 17 years, the longest run of any Ferrari bodystyle ever. It was some years before another 4 seater V12 Ferrari would join the range, the 456 GT in 1994.

Top of the Ferrari range from the mid 70s for 10 years was the Berlinetta Boxer,object of many a small child’s intense desire, as I can attest from my own childhood! Production of the Berlinetta Boxer was a major step for Enzo Ferrari. He felt that a mid-engined road car would be too difficult for his buyers to handle, and it took many years for his engineers to convince him to adopt the layout. This attitude began to change as the marque lost its racing dominance in the late 1950s to mid-engined competitors. The mid-engined 6- and 8-cylinder Dino racing cars were the result, and Ferrari later allowed for the production Dino road cars to use the layout as well. The company also moved its V12 engines to the rear with its P and LM racing cars, but the Daytona was launched with its engine in front. It was not until 1970 that a mid-engined 12-cylinder road car would appear. The first “Boxer” was the 365 GT4 BB shown at the 1971 Turin Motor Show. Designed to rival the Lamborghini Miura and the newly developed Lamborghini Countach, it was finally released for sale in 1973 at the Paris Motor Show. 387 were built, of which 88 were right-hand drive (of which 58 were for the UK market), making it the rarest of all Berlinetta Boxers. The Pininfarina-designed body followed the P6 show car with popup headlights. Though it shared its numerical designation with the Daytona, the Boxer was radically different. It was a mid-engined car like the Dino, and the now flat-12 engine was mounted longitudinally rather than transversely. Although referred to as a Boxer, the 180° V12 was not a true boxer engine, but rather a flat engine. It had 380 hp, slightly more than the Daytona. The 365 GT4 BB was updated as the BB 512 in 1976, resurrecting the name of the earlier Ferrari 512 racer. The name 512 referred to the car’s 5 litre, 12 cylinder engine; a deviation from Ferrari’s established practice of naming 12-cylinder road cars (as the 365 BB) after their cylinder displacement. The engine was enlarged to 4943.04 cc, with an increased compression ratio of 9.2:1. Power was slightly down to 360 hp, while a dual plate clutch handled the added torque and eased the pedal effort. Dry sump lubrication prevented oil starvation in hard cornering. The chassis remained unaltered, but wider rear tyres (in place of the 365’s equally sized on all four corners) meant the rear track grew 63 mm. External differentiators included a new chin spoiler upfront, incorporated in the bumper. A NACA duct on the side provided cooling for the exhaust system. At the rear there were now twin tail lights and exhaust pipes each side, instead of triple units as on the 365 GT4 BB. 929 BB 512 models were produced. The Bosch K-Jetronic CIS fuel injected BB 512i introduced in 1981 was the last of the series. The fuel injected motor produced cleaner emissions and offered a better balance of performance and daily-driver temperament. External differentiators from the BB 512 besides badging include a change to metric sized wheels and the Michelin TRX metric tyre system, small white running lights in the nose, and red rear fog lamps outboard of the exhaust pipes in the rear valance. 1,007 BB 512i models were produced.

The Dino 308 GT4 was introduced at the Paris Motor Show in 1973. It only gained the “Prancing Horse” badge in May 1976, which replaced the Dino badges on the front, wheels, rear panel and the steering wheel. This has caused major confusion over the years by owners, enthusiasts and judges. During the energy crisis at that time many prospective owners were hesitant to buy such an expensive automobile not badged “Ferrari” being confused at the significance of the Dino name. The GT4 was a groundbreaking model for Ferrari in several ways: it was the first production Ferrari to feature the mid-engined V8 layout that would become the bulk of the company’s business in the succeeding decades, and was the first production Ferrari with Bertone (rather than Pininfarina) designed bodywork. Pininfarina was upset by the decision to give cross-town rival Bertone the design, considering all they had done for Ferrari. The styling featured angular lines entirely different from its curvaceous 2-seater brother, the Dino 246, and was controversial at the time. Some journalists compared it to the Bertone-designed Lancia Stratos and Lamborghini Urraco, also penned by Marcello Gandini. From the cockpit the driver sees only the road. It has perfect 360 degree visibility, no blind spots, upright and comfortable seating position, a real boot, a back seat for soft luggage, and very easy engine access. Enzo Ferrari himself took a major role in its design, even having a mock-up made where he could sit in the car to test different steering, pedals and cockpit seating positioning. The chassis was a tubular spaceframe based on the Dino 246, but was stretched for a 115.2 in wheelbase to make room for the second row of seats. The suspension was fully independent, with double wishbones, anti-roll bars, coaxial telescopic shock absorbers and coil springs on both axles. Niki Lauda helped set up the chassis. The 2927 cc V8 was mounted transversally integrally joined with the 5-speed transaxle gearbox. The engine had an aluminium alloy block and heads, 16-valves and dual overhead camshafts driven by toothed belts; it produced 255 hp in the European version and 240 hp in the American. The induction system used four Weber 40 DCNF carburettors. The GT4 was replaced by the Mondial 8 in 1980 after a production run of 2,826 308s and 840 208s.

The 308 GTB was launched at the Paris Motor Show in 1975 as a direct replacement for the Dino 246. Designed by Pininfarina with sweeping curves and aggressive lines, the 308 has gone on to become one of the most recognised Ferraris of all time. Fitted with a 2.9 litre DOHC V8 engine fed by four Webber 40DCNF Carburettors, the power output of 255bhp was sufficient to propel the 308 from 0 to 60mph in 6.5 seconds and on to a top speed of 159 mph. Tougher emissions standards in the 1980s challenged Ferrari more than many other marques. In 1980, fuel injection was adopted for the first time on the 308 GTB and GTS models, and power dropped quite noticeably fro 240 bhp to 214bhp. Two years later, at the 1982 Paris Motor Show, Ferrari launched the 308 quattrovalvole, in GTB and GTS form. The main change from the 308 GTBi/GTSi it succeeded were the 4-valves per cylinder—hence its name, which pushed output back up to 240 hp restoring some of the performance lost to the emission control equipment. The new model could be recognised by the addition of a slim louvred panel in the front lid to aid radiator exhaust air exit, power operated mirrors carrying a small enamel Ferrari badge, a redesigned radiator grille with rectangular driving lights on each side, and rectangular (in place of round) side repeaters. The interior also received some minor updates, such as a satin black three spoke steering wheel with triangular centre; cloth seat centres became available as an option to the standard full leather. Available included metallic paint, a deep front spoiler, air conditioning, wider wheels, 16-inch Speedline wheels with Pirelli P7 tyres, and a satin black roof aerofoil (standard on Japanese market models). Apart from the 32-valve cylinder heads, the V8 engine was essentially of the same design as that used in the 308 GTSi model. The gear and final drive ratios were altered to suit the revised characteristics of the four valves per cylinder engine. One other significant benefit of the QV four valve heads was the replacement of the non-QV models sodium valves which have been known to fail at the joint between the head and the stem. Bosch K-Jetronic fuel injection and Marelli Digiplex electronic ignition were carried over from the GTBi/GTSi. The car was produced in this form until the launch of the 328 models in the autumn of 1985 which had larger 3.2 litre engines and a number of styling changes. 308 GTB models are becoming increasingly sought after, with prices rising steadily and quite steeply.

Introduced at the 1985 Frankfurt Show alongside the Mondial 3.2 series, the Ferrari 328 GTB and GTS (Type F106) were the successors to the Ferrari 308 GTB and GTS which had first been seen in October 1975. While mechanically still based on the 308 GTB and GTS respectively, small modifications were made to the body style and engine, most notably an increase in engine displacement to 3185 cc for increased power and torque output. As had been the case for a generation of the smaller Ferraris, the model name referred to the total cubic capacity of the engine, 3.2 litres, and 8 for the number of cylinders. Essentially the new model was a revised and updated version of the 308 GTS, which had survived for eight years without any radical change to the overall shape, albeit with various changes to the 3-litre engine. The 328 model presented a softening of the wedge profile of its predecessor, with a redesigned nose that had a more rounded shape, which was complemented by similar treatment to the tail valance panel. The revised nose and tail sections featured body colour bumpers integral with the valance panels, which reflected the work done concurrently to present the Mondial 3.2 models, with which they also shared a similar radiator grille and front light assembly layout. Thus all the eight-cylinder cars in the range shared fairly unified front and rear aspects, providing a homogeneous family image. The exhaust air louvres behind the retractable headlight pods on the 308 series disappeared, coupled with an increase in the size of the front lid radiator exhaust air louvre, which had been introduced on the 308 Quattrovalvole models, whilst a new style and position of exterior door catch was also provided. The interior trim also had a thorough overhaul, with new designs for the seat panel upholstery and stitching, revised door panels and pulls, together with more modern switchgear, which complemented the external updating details. Optional equipment available was air conditioning, metallic paint, Pirelli P7 tyres, a leather dashboard, leather headlining to the removable roof panel plus rear window surround, and a rear aerofoil (standard on Japanese market models). In the middle of 1988 ABS brakes were made available as an option, which necessitated a redesign of the suspension geometry to provide negative offset. This in turn meant that the road wheel design was changed to accommodate this feature. The original flat spoke “star” wheels became a convex design, in the style as fitted to the 3.2 Mondial models, whether ABS was fitted or not. The main European market 328 GTS models had a tubular chassis with a factory type reference F 106 MS 100. Disc brakes, with independent suspension via wishbones, coil springs, and hydraulic shock absorbers, were provided all round, with front and rear anti roll bars. There were various world market models, each having slight differences, with right and left hand drive available. The V8 engine was essentially of the same design as that used in the 308 Quattrovalvole model, with an increase in capacity to 3185 cc. The engine retained the Bosch K-Jetronic fuel injection system of its predecessor, but was fitted with a Marelli MED 806 A electronic ignition system, to produce a claimed power output of 270 bhp at 7000 rpm. As with the preceding 308 models the engine was mounted in unit with the all synchromesh five-speed manual transmission assembly, which was below, and to the rear of the engine’s sump. The 328 GTS continued in production for four years, until replaced by the 348 ts model in the autumn of 1989, during which time 6068 examples were produced, GTS production outnumbering the GTB (1344 produced) version almost five to one.

Produced alongside the 308/328 GTB and GTS models was the Mondial, and there were a couple of examples of the car on show. Produced by Ferrari from 1980 through 1993, it replaced the 208/308 GT4. The “Mondial” name came from Ferrari’s history — the 500 Mondial race car of the early 1950s. Despite its predecessor being Bertone styled, the Mondial saw Ferrari return to Pininfarina for styling. Sold as a mid-sized coupe and, eventually a cabriolet, it was conceived as a ‘usable’ model, offering the practicality of four seats and the performance of a Ferrari. The car had a slightly higher roofline than its stablemates, with a single long door either side, offering easy access and good interior space, reasonable rear legroom while all-round visibility was excellent. The cabriolets also hold the distinction of being the only production automobile in history that has four seats, is rear mid-engined, and is a full convertible. The car body was not built as a monocoque in the same way as a conventional car. The steel outer body produced by the famous Italian coachbuilder Carrozzeria Scaglietti, in nearby Modena, was built over a lightweight steel box-section space frame. The engine cover and rear luggage compartment lids are in light alloy. The seats and interior were trimmed in Connolly hide, contrasting with the body colour. Most cars were painted rosso red, but some were black or silver, and a few were dark blue. The Mondial was the first Ferrari car where the entire engine/gearbox/rear suspension assembly is on a detachable steel subframe. This design made engine removal for a major rebuild or cylinder head removal much easier than it was on previous models. Unusually, the handbrake is situated between the driver’s seat and the inner sill. Once the handbrake is set it drops down so as, not to impede egress and ingress. Instead of the conventional “H” shift pattern, the gearbox has 1st gear situated in a “dog leg” to the left and back, behind reverse. This pattern, otherwise known as a “reverse h-gate”, allows quicker gear shifts between 2nd and 3rd gear, and also between 4th and 5th. The Mondial underwent many updates throughout production. There were four distinct iterations (8, QV, 3.2, and t), with the latter 3 having two variations each. (coupe and cabriolet). The first car was introduced as the Mondial 8 at the 1980 Geneva Auto Salon. It was the first Ferrari to depart from the company’s simple 3-digit naming scheme, and some reviews found it relatively mild, compared to other Ferraris, regarding performance, drawing criticism from some in the motoring press. It used a mid/rear-mounted Bosch K-Jetronic fuel injection V8, shared with the 308 GTBi/GTSi, mounted transversely. The engine used in the 1973 Dino 308 GT4. The K-Jetronic system is mechanical, with a high-pressure pump which streams fuel continuously to the injectors; it does not have a computer, just a few relays to handle the cold start sequence etc. The chassis was also based on the 308 GT4, but with a 3.9 inch longer wheelbase at 104.3 in. The suspension was the classic layout of unequal-length double wishbones and Koni dampers all around. Today, the Mondial 8 is considered one of the marque’s most “practical” vehicles, due to its 214 hp, proven drivetrain, four seats, and relatively low cost of maintenance (major services can be performed without removing the entire engine/transmission subframe). 703 examples were made. The first Mondial engine, although a DOHC design, used just two valves per cylinder. The 1982 Quattrovalvole or QV introduced a new four-valve head; the combustion chamber design purportedly based on the early eighties Formula 1 engine. Again, the engine was shared with the contemporary 308 GTB/GTS QV, and produced a much more respectable 240 hp. Appearance was largely as per the Mondial 8, although with red engine heads and prominent “quattrovalvole” script at the rear. 1,145 coupés built between 1982 and 1985. A new Cabriolet body style added for 1983. Body styling remained the same as the coupé variant, with the roof maintaining the ‘buttress’ design of the roof, though the Cabriolet required the rear seats to be mounted closer together laterally. The introduction of the Cabriolet saw the popularity of the Mondial rise, particularly in the American market, where the convertible body style was highly desirable. The Cabriolet has the added distinction of being the only four-seat, mid-rear engine, convertible automobile ever manufactured in regular production. 629 units were produced between 1983 and 1985, making this the rarest version of the Mondial. Like the Ferrari 328, the Mondial’s engine grew in both bore and stroke to 3,185 cc in 1985. Output was now 270 PS. The Mondial 3.2 was first presented at the 1985 Frankfurt Auto Show in September that year. Available in both Coupé and Cabriolet forms, styling refreshed with restyled and body-coloured bumpers, similar to the 328 with more integrated indicators and driving lamps, and new alloy wheels with a more rounded face. The 3.2 also boasted a major interior update, with a more ergonomic layout and a more rounded instrument binnacle. Later cars, from 1987 onwards, also sported ABS brakes. Fuel injection remained the primarily mechanical Bosch K-Jetronic (CIS) with an O2 sensor in the exhaust providing feedback to a simple computer for mixture trimming via a pulse modulated frequency valve that regulated control fuel pressure. The ignition system was Marelli Microplex, with electronic advance control and one distributor per bank of the V8. The 1988 Mondial 3.2 would be the final model year that retained the relatively low maintenance costs of the 308/328 drivetrain, allowing major service items like timing belt and clutch replacement performed with the engine/transmission package still in the car. The final Mondial evolution was 1989’s Mondial t, which was a substantially changed model. It was visually different from preceding Mondial models, the most recognizable being the redesign of the air intakes to a smaller rectangular shape. Additionally, the door-handles were of a visually different design, as were the front and rear bumpers which became body coloured. New front and rear wings cover wider tracks and are re-profiled to a fuller shape compared to previous models, which feature a rolled lip. The ‘t’ called attention to the car’s new engine/transmission layout: the previously-transverse engine mounted longitudinally while the gearbox remained transverse, thus forming a ‘t’. By adopting this layout, a longer engine could be mounted lower in the chassis, improving handling dramatically. The ‘t’ configuration was used by Ferrari’s Formula One cars of the 1980s, and would be the standard for the marque’s future mid-engined V8 cars, beginning with the 348, introduced later in the year. The transverse manual gearbox fitted with a Limited Slip Differential with a twin-plate clutch design with bevel gears driving the wheels. Later in production, a Semi-automatic transmission termed “Valeo” was available as an option; while shifting was using a traditional gear lever, the clutch was actuated automatically without a clutch pedal. The engine was up to 3405 cc and 300 hp, controlled by Bosch Motronic DME 2.5 (later DME 2.7) electronic engine management that integrated EFI and ignition control into a single computer unit. Two of these used in the car: one for each bank of the engine. Engine lubrication upgraded to a dry-sump system. The Mondial’s chassis would underpin a new generation of 2-seat Ferraris, right up to the 360, but the 2+2 Mondial would end production just four and a half years later in 1993. However, the “t” layout of the engine and transaxle, adapted from Ferrari’s Formula One cars, continues to be used in mid-engined V8 model Ferraris to date, albeit with a more sophisticated chassis. The new layout saw the engine and transmission mounted on a removable subframe; the assembly removed from the underside of the vehicle for maintenance. This process is necessary for timing belt replacement, making this a costly procedure for the owner who does not have a lift. On the other hand, the clutch was now located at the very rear of the drive train. This arrangement makes clutch replacement and service a simple, inexpensive, and readily owner-do-able proposition. The “t” was home to other Ferrari firsts: It used power assisted steering for the first time and had a 3-position electronically controlled suspension for a variable trade-off between ride quality and road holding. It also had standard ABS. Total production of the t Coupe was 858 (45 Right Hand Drive), and the t Cabriolet of 1,017 (51 Right Hand Drive, meaning that around 6000 Mondial cars were produced over those 13 years, making it one of the most commercially significant Ferraris to date.

Object of many a poster on a young enthusiast’s bedroom wall when the car was new was the Testarossa and there was a nice example of the slightly later version, the 512TR here. A replacement for the BB512i, the final iteration of Ferrari’s first ever mid-engined road car, the Testarossa was launched at the Paris Show in October 1984. The Pininfarina-designed car was produced until 1991, with the same basic design then going through two model revisions, with the 512 TR and later F512 M which were produced from 1992 to 1996 before the model was replaced by the front-engined 550 Maranello. Almost 10,000 Testarossas, 512 TRs, and F512 Ms were produced, making it one of the most-produced Ferrari models, despite its high price and exotic design. The Testarossa followed the same concept as the BB512, but was intended to fix some of the criticisms of the earlier car, such as a cabin that got increasingly hot from the indoor plumbing that ran between the front-mounted radiator and the midships-mounted engine and a lack of luggage space. This resulted in a car that was larger, and at 1,976 millimetres (78 in) wide the Testarossa was half a foot wider than the Boxer and immediately condemned for being too wide, though these days it does not appear anything like as wide as it did when new. This resulted in an increased wheelbase that stretched about 2.5 in to 100 in which was used to accommodate luggage in a carpeted storage space under the front forward-opening lid. The increase in length created extra storage space behind the seats in the cabin. Headroom was also increased with a roofline half an inch taller than the Boxer. The design came from Pininfarina with a team of designers led by design chief Leonardo Fioravanti, the designer of many contemporary Ferraris. The design was originated by Nicosia, but the guidance of Fioravanti was equally important. Being a trained aerodynamicist, Fioravanti applied his know-how to set the aerodynamics layout of the car. This meant the large side intakes were not only a statement of style but actually functional – they drew clean air to cool the side radiators and then went upward and left the car through the ventilation holes located at the engine lid and the tail. As a result, the Testarossa did not need a rear spoiler like Lamborghini’s Countach yet produced zero lift at its rear axle. The aerodynamic drag coefficient of 0.36 was also significantly better than the Lamborghini’s 0.42. Pininfarina’s body was a departure from the curvaceous boxer—one which caused some controversy. The side strakes sometimes referred to as “cheese graters” or “egg slicers,” that spanned from the doors to the rear wings were needed for rules in several countries outlawing large openings on cars. The Testarossa had twin radiators in the back with the engine instead of a single radiator up-front. In conjunction the strakes provided cool air to the rear-mounted side radiators, thus keeping the engine from overheating. The strakes also made the Testarossa wider at the rear than in the front, thus increasing stability and handling. One last unique addition to the new design was a single high mounted rear view mirror on the driver’s side. On US based cars, the mirror was lowered to a more normal placement in 1987 and quickly joined by a passenger side rear view mirror for the driver to be able to make safe easy lane changes. Like its predecessor, the Testarossa used double wishbone front and rear suspension systems. Ferrari improved traction by adding 10-inch-wide alloy rear wheels. The Testarossa drivetrain was also an evolution of the BB 512i. Its engine used near identical displacement and compression ratio, but unlike the BB 512i had four-valve cylinder heads that were finished in red. The capacity was 4,943 cc, in a flat-12 engine mid mounted. Each cylinder had four valves, lubricated via a dry sump system, and a compression ratio of 9.20:1. These combined to provide a maximum torque of 361 lb/ft at 4500 rpm and a maximum power of 390 hp at 6300 rpm. That was enough to allow the Testarossa to accelerate from 0–60 mph in 5.2 seconds and on to 100 mph. The original Testarossa was re-engineered for 1992 and released as the 512 TR, at the Los Angeles Auto Show, effectively as a completely new car, with an improved weight distribution of 41% front: 59% rear.

Launched in 1987, the F40 was the successor to the 288 GTO. It was designed to celebrate Ferrari’s 40th anniversary and was the last Ferrari automobile personally approved by Enzo Ferrari. At the time it was Ferrari’s fastest, most powerful, and most expensive car for sale. As soon as the 288 GTO was launched, Ferrari started the development of an evolution model, intended to compete against the Porsche 959 in FIA Group B. However, when the FIA brought an end to the Group B category for the 1986 season, Enzo Ferrari was left with five 288 GTO Evoluzione development cars, and no series in which to campaign them. Enzo’s desire to leave a legacy in his final supercar allowed the Evoluzione program to be further developed to produce a car exclusively for road use. In response to the quite simple, but very expensive car with relatively little out of the ordinary being called a “cynical money-making exercise” aimed at speculators, a figure from the Ferrari marketing department was quoted as saying “We wanted it to be very fast, sporting in the extreme and Spartan,” “Customers had been saying our cars were becoming too plush and comfortable.” “The F40 is for the most enthusiastic of our owners who want nothing but sheer performance. It isn’t a laboratory for the future, as the 959 is. It is not Star Wars. And it wasn’t created because Porsche built the 959. It would have happened anyway.” Power came from an enlarged, 2936 cc version of the GTO’s twin IHI turbocharged V8 developing 478 bhp. The F40 did without a catalytic converter until 1990 when US regulations made them a requirement for emissions control reasons. The flanking exhaust pipes guide exhaust gases from each bank of cylinders while the central pipe guides gases released from the wastegate of the turbochargers. Engines with catalytic converters bear F120D code. The suspension was similar to the GTO’s double wishbone setup, though many parts were upgraded and settings were changed; the unusually low ground clearance prompted Ferrari to include the ability to raise the vehicle’s ground clearance when necessary. The body was an entirely new design by Pininfarina featuring panels made of Kevlar, carbon fibre, and aluminium for strength and low weight, and intense aerodynamic testing was employed. Weight was further minimised through the use of a plastic windscreen and windows. The cars did have air conditioning, but had no sound system, door handles, glove box, leather trim, carpets, or door panels. The first 50 cars produced had sliding Lexan windows, while later cars were fitted with wind down windows. The F40 was designed with aerodynamics in mind. For speed the car relied more on its shape than its power. Frontal area was reduced, and airflow greatly smoothed, but stability rather than terminal velocity was a primary concern. So too was cooling as the forced induction engine generated a great deal of heat. In consequence, the car was somewhat like an open-wheel racing car with a body. It had a partial undertray to smooth airflow beneath the radiator, front section, and the cabin, and a second one with diffusers behind the motor, but the engine bay was not sealed. Nonetheless, the F40 had an impressively low Cd of 0.34 with lift controlled by its spoilers and wing. The factory never intended to race the F40, but the car saw competition as early as 1989 when it debuted in the Laguna Seca Raceway round of the IMSA, appearing in the GTO category, with a LM evolution model driven by Jean Alesi, finishing third to the two faster space-framed four wheel drive Audi 90 and beating a host of other factory backed spaceframe specials that dominated the races. Despite lack of factory backing, the car would soon have another successful season there under a host of guest drivers such as Jean-Pierre Jabouille, Jacques Laffite and Hurley Haywood taking a total of three second places and one third. It would later be a popular choice by privateers to compete in numerous domestic GT series. Although the original plan was to build just 400 cars, such was the demand that in the end, 1311 were built over a 4 year period.

With styling that had a close link to the Testarossa, the next V8 Ferrari to be launched, in 1989, was the 348, as a replacement for the 328 GTB/GTS models, and there were several examples of this model here. At launch, the 348 series were not that enthusiastically received by the press who found much to complain about. The 348’s styling differed from previous models with straked side air intakes and rectangular taillights resembling the Testarossa. Launched in two models, a coupe badged 348 tb (Trasversale Berlinetta) and targa roofed 348 ts (Targa), these were soon joined by a fully open car, the 348 Spider. All featured a normally aspirated 3.4-litre version of the quad-cam, four-valve-per-cylinder V8 engine. As with its predecessors, the model number was derived from this configuration, with the first two digits being the displacement and the third being the number of cylinders. The engine, which produced 300 hp was mounted longitudinally and coupled to a transverse manual gearbox, like the Mondial t with which the 348 shared many components. This was a significant change for Ferrari, with most previous small Ferraris using a transverse engine with longitudinal transmission. The “T” in the model name 348 tb and ts refers to the transverse position of the gearbox. The 348 was fitted with dual-computer engine management using twin Bosch Motronic ECUs, double-redundant anti-lock brakes, and self-diagnosing air conditioning and heating systems. Late versions (1993 and beyond) have Japanese-made starter motors and Nippondenso power generators to improve reliability, as well as the battery located within the front left fender for better weight distribution. Similar to the Testarossa but departing from the BB 512 and 308/328, the oil and coolant radiators were relocated from the nose to the sides, widening the waist of the car substantially, but making the cabin much easier to cool since hoses routing warm water no longer ran underneath the cabin as in the older front-radiator cars. This also had the side effect of making the doors very wide. The 348 was equipped with a dry-sump oil system to prevent oil starvation at high speeds and during hard cornering. The oil level can only be accurately checked on the dipstick when the motor is running due to this setup. The 348 was fitted with adjustable ride-height suspension and a removable rear sub-frame to speed up the removal of the engine for maintenance. Despite trenchant criticism of the car, especially its handling, 2,895 examples of the 348 tb and 4,230 of the 348 ts were produced.

Stung by the criticism of the 348, Ferrari undertook a comprehensive revision, creating the F355 model which they launched in May 1994. An evolution of the Ferrari 348, just about everything was changed, and improved. Design emphasis for the F355 was placed on significantly improved performance, but driveability across a wider range of speeds and in different environments such as low-speed city traffic was also addressed, as the Honda NS-X had proved that you could make a supercar that could be lived with every day. Apart from the displacement increase from 3.4 to 3.5 litres, the major difference between the V8 engine in the 348 and F355 was the introduction of a 5-valve cylinder head. This new head design allowed for better intake permeability and resulted in an engine that was considerably more powerful, producing 375 hp. The longitudinal 90° V8 engine was bored 2mm over the 348’s engine, resulting in the small increase in displacement. The F355 had a Motronic system controlling the electronic fuel injection and ignition systems, with a single spark plug per cylinder, resulting in an unusual 5 valves per cylinder configuration. This was reflected in the name, which did not follow the formula from the previous decades of engine capacity in litres followed by number of cylinders such as the 246 = 2.4 litres and 6 cylinders and the 308 of 3.0 litres and 8 cylinders. For the F355, Ferrari used engine capacity followed by the number of valves per cylinder (355 = 3.5 litres engine capacity and 5 valves per cylinder) to bring the performance advances introduced by a 5 valve per cylinder configuration into the forefront. 5. The frame was a steel monocoque with tubular steel rear sub-frame with front and rear suspensions using independent, unequal-length wishbones, coil springs over gas-filled telescopic shock absorbers with electronic control servos and anti-roll bars. The car allows selection between two damper settings, “Comfort” and “Sport”. Ferrari fitted all road-going F355 models with Pirelli tires, size 225/40ZR 18 in front and 265/40 ZR 18 in the rear. Although the F355 was equipped with power-assisted steering (intended to improve low-speed driveability relative to the outgoing 348), this could optionally be replaced with a manual steering rack setup by special order. Aerodynamic designs for the car included over 1,300 hours of wind tunnel analysis. The car incorporates a Nolder profile on the upper portion of the tail, and a fairing on the underbody that generates downforce when the car is at speed. These changes not only made the car faster but also much better to drive,m restoring Ferrari to the top of the tree among its rivals. At launch, two models were available: the coupe Berlinetta and the targa topped GTS, which was identical to the Berlinetta apart from the fact that the removable “targa-style” hard top roof could be stored behind the seats. The F355 would prove to be last in the series of mid-engined Ferraris with the Flying Buttress rear window, a lineage going back to the 1965 Dino 206 GT, unveiled at the Paris Auto Show. The Spider (convertible) version came later in the year. In 1997 the Formula One style paddle gear shift electrohydraulic manual transmission was introduced with the Ferrari 355 F1 adding £6,000 to the dealer asking price. This system promised faster gearchanges and allowed the driver to keep both hands on the steering wheel, It proved to be very popular and was the beginning of the end for the manual-transmission Ferrari. Ferrari produced 4,871 road-going Berlinetta models, of which 3,829 were 6-speed and 1,042 were F1 transmissions. The Spider proved to be the second-most popular F355 model, with a total production of 3,717 units, of which 2,664 were produced with the 6-speed transmission and another 1,053 produced with the F1 transmission. A total of 2,577 GTS models were produced, with 2,048 delivered with the 6-speed transmission and another 529 with the F1 transmission. This was the last GTS targa style model produced by Ferrari. This made a total production run of 11,273 units making the F355 the most-produced Ferrari at the time, though this sales record would be surpassed by the next generation 360 and later, the F430.

A front-engined grand tourer, the 456 was produced from 1992 until 2003, as an overdue replacement for the long-defunct front-engined 412 as the company’s V12 four seater. Pietro Camardella and Lorenzo Ramaciotti at Pininfarina designed the original 456 which was available in GT and from 1996 in GTA forms. The difference in name signifies the transmission: the former has a six-speed manual and the latter has a four-speed automatic developed in partnership with FF Developments, in Livonia, MI (which was later purchased by Ricardo Engineering in the UK). This was only the fourth automatic transmission ever offered by Ferrari. The 5473 cc 65° V12 engine was derived from the Dino V6 rather than the more conventional 60° V12s used in the 412 and Daytona. It produced 442 PS with 4 valves per cylinder and Bosch Motronic M2.7 engine management. It could push the 1690 kg car and four passengers to 302 km/h (188 mph) making it the world’s fastest production four-seater. Acceleration to 100 km/h was just 5.2 seconds, with a 13.4 second quarter-mile time. At the time of its development it was the most powerful road car ever developed by Ferrari (aside from the F40). In 1996 engine was changed with Motronic M5.2 management and typed as F116C. The name 456, as was Ferrari practice, came from the fact that each cylinder displaces 456 cubic centimeters. This was the last Ferrari to use this naming convention. Despite its supercar performance, the 456 has a relatively unstressed engine, which has proven to be a very reliable unit. The chassis is a tubular steel spaceframe construction with a one-piece composite bonnet and body panels of aluminium. The body panels are welded to the chassis by using a special “sandwich filler” called feran that, when laid between, allows steel and aluminium to be welded. The Modificata 456M appeared in 1998, starting with chassis number 109589. Many changes were made to improve aerodynamics and cooling, and the interior – still featuring Connolly Leather – was freshened with new seats and other conveniences (fewer gauges on dash, and a new Becker stereo fitted in front of gear stick rather than behind as in the very shallow and special Sony head unit in the 456 GT). The 456 has a smaller grille with fog lights outside the grille, and lacked the bonnet-mounted air scoops. The undercarriage spoiler on the 456M is fixed, where the older 456 had a motorised spoiler that began its deployment above 105 km/h (65 mph). Power remained unchanged on the Modificata using Bosch Motronic M5.2 engine management at 442 PS; the cylinder firing order was changed for smoother running, and the torque remained the same for later versions of the 456 GT. The Tour de France Blue with Daytona Seats was the most desirable colour and leather combination. Approximately 3,289 of all versions were built, consisting of: 456 GT: 1,548; 456 GTA: 403; 456M GT: 688; 456M GTA: 650.

The F50 was Ferrari’s “extreme machine” of the 1990s. It was presented at the 1995 Geneva Show, and was effectively the replacement for the F40. This could almost be seen as a Formula 1 car for the road, as this mid-engined two seat roadster with a removable hardtop had a 4.7 litre naturally aspirated 60-valve V12 engine that was developed from the 3.5 litre V12 used in the 1990 Ferrari 641 Formula One car. Only 349 cars were made, of which 301 were red. Just 4 of them were black, making it, along with silver the least produced colour of the limited palate offered. The last F50 was produced in July 1997.

It was with the 360 Modena that sales of Ferrari models really took off, with unprecedented volumes of the car being sold. The 360 Modena was launched in 1999, named after the town of Modena, the birthplace of Enzo Ferrari. A major innovation in this all new model came from Ferrari’s partnership with Alcoa which resulted in an entirely new all-aluminium space-frame chassis that was 40% stiffer than the F355 which had utilised steel. The design was 28% lighter despite a 10% increase in overall dimensions. Along with a lightweight frame the new Pininfarina body styling deviated from traditions of the previous decade’s sharp angles and flip-up headlights. The new V8 engine, common to all versions, was of 3.6 litre capacity with a flat plane crankshaft, titanium connecting rods and generates 400 bhp Despite what looks like on paper modest gains in reality the power to weight ratio was significantly improved on over the F355, this was due to the combination of both a lighter car and more power. The 0 to 100 km/h acceleration performance improved from 4.6 to 4.3 seconds. The first model to be rolled out was the 360 Modena, available as a manual, or an F1 electrohydraulic manual. Next up was an open car. The 360 was designed with a Spider variant in mind; since removing the roof of a coupe reduces the torsional rigidity, the 360 was built for strength in other areas. Ferrari designers strengthened the sills, stiffened the front of the floorpan and redesigned the windscreen frame. The rear bulkhead had to be stiffened to cut out engine noise from the cabin. The convertible’s necessary dynamic rigidity is provided by additional side reinforcements and a cross brace in front of the engine. Passenger safety is ensured by a strengthened windscreen frame and roll bars. The 360 Spider displays a curvilinear waistline. The fairings imply the start of a roof, and stable roll bars are embedded in these elevations. Due to use of light aluminium construction throughout, the Spider weighs in only 60 kg heavier than the coupé. As with the Modena version, its 3.6 litre V8 with 400 bhp is on display under a glass cover. The engine — confined in space by the convertible’s top’s storage area — acquires additional air supply through especially large side grills. The intake manifolds were moved toward the center of the engine between the air supply conduits in the Spider engine compartment, as opposed to lying apart as with the Modena. In terms of performance, the 0-60 mph time was slightly slower at 4.4 seconds due to the slight weight increase, and the top speed was reduced from 189 to 180 mph. Despite the car’s mid-mounted V8 engine, the electrically operated top is able to stow into the compartment when not in use. The convertible top was available in black, blue, grey and beige. The transformation from a closed top to an open-air convertible is a two-stage folding-action that has been dubbed “a stunning 20 second mechanical symphony”. The interior of the Spider is identical to that of the coupé.

Firmly placed in Ferrari’s history as one of their finest big GTs, the 550 Maranello’s combination of stylish Pininfarina lines and front mounted 12-cylinder engine meant this car had the potential to become an instant classic, following in the footsteps of its forebear, the 365 GTB/4 ‘Daytona’, and if you look at the way the prices are steading to go, it’s clear that the potential is being realised. Launched in 1996, and with modern styling cues, a 5.5 litre V12 engine producing around 485bhp and a reported top speed of 199mph, the 550 Maranello was a serious motor car. A less frenetic power delivery, the six speed manual box and excellent weight distribution were all factors in the 550 becoming the perfect European Grand Tourer. Ferrari updated the car to create the 575M.

There were several examples of the F430 here, of course, as this car sold in what were large quantities, by Ferrari standards. Effectively a mid-life update to the 360 Modena, the F430 debuted at the 2004 Paris Motor Show. Designed by Pininfarina, under the guidance of Frank Stephenson, the body styling of the F430 was revised from the 360 Modena, to improve its aerodynamic efficiency. Although the drag coefficient remained the same, downforce was greatly enhanced. Despite sharing the same basic Alcoa Aluminium chassis, roof line, doors and glass, the car looked significantly different from the 360. A great deal of Ferrari heritage was included in the exterior design. At the rear, the Enzo’s tail lights and interior vents were added. The car’s name was etched into the Testarossa-styled driver’s side mirror. The large oval openings in the front bumper are reminiscent of Ferrari racing models from the 60s, specifically the 156 “sharknose” Formula One car and 250 TR61 Le Mans cars of Phil Hill. Designed with soft-top-convertible. The F430 featured a 4.3 litre V8 petrol engine of the “Ferrari-Maserati” F136 family. This new power plant was a significant departure for Ferrari, as all previous Ferrari V8’s were descendants of the Dino racing program of the 1950s. This fifty-year development cycle came to an end with the entirely new unit. The engine’s output was 490 hp at 8500 rpm and 343 lb/ft of torque at 5250 rpm, 80% of which was available below 3500rpm. Despite a 20% increase in displacement, engine weight grew by only 4 kg and engine dimensions were decreased, for easier packaging. The connecting rods, pistons and crankshaft were all entirely new, while the four-valve cylinder head, valves and intake trumpets were copied directly from Formula 1 engines, for ideal volumetric efficiency. The F430 has a top speed in excess of 196 mph and could accelerate from 0 to 100 km/h in 3.9 seconds, 0.6 seconds quicker than the old model. The brakes on the F430 were designed in close cooperation with Brembo (who did the calipers and discs) and Bosch (who did the electronics package),resulting in a new cast-iron alloy for the discs. The new alloy includes molybdenum which has better heat dissipation performance. The F430 was also available with the optional Carbon fibre-reinforced Silicon Carbide (C/SiC) ceramic composite brake package. Ferrari claims the carbon ceramic brakes will not fade even after 300-360 laps at their test track. The F430 featured the E-Diff, a computer-controlled limited slip active differential which can vary the distribution of torque based on inputs such as steering angle and lateral acceleration. Other notable features include the first application of Ferrari’s manettino steering wheel-mounted control knob. Drivers can select from five different settings which modify the vehicle’s ESC system, “Skyhook” electronic suspension, transmission behaviour, throttle response, and E-Diff. The feature is similar to Land Rover’s “Terrain Response” system. The Ferrari F430 was also released with exclusive Goodyear Eagle F1 GSD3 EMT tyres, which have a V-shaped tread design, run-flat capability, and OneTRED technology. The F430 Spider, Ferrari’s 21st road going convertible, made its world premiere at the 2005 Geneva Motor Show. The car was designed by Pininfarina with aerodynamic simulation programs also used for Formula 1 cars. The roof panel automatically folds away inside a space above the engine bay. The conversion from a closed top to an open-air convertible is a two-stage folding-action. The interior of the Spider is identical to that of the coupé. Serving as the successor to the Challenge Stradale, the 430 Scuderia was unveiled by Michael Schumacher at the 2007 Frankfurt Auto Show. Aimed to compete with cars like the Porsche RS-models and the Lamborghini Gallardo Superleggera it was lighter by 100 kg/220 lb and more powerful (510 PS) than the standard F430. Increased power came from a revised intake, exhaust, and an ion-sensing knock-detection system that allows for a higher compression ratio. Thus the weight-to-power ratio was reduced from 2.96 kg/hp to 2.5 kg/hp. In addition to the weight saving measures, the Scuderia semi-automatic transmission gained improved “Superfast”, known as “Superfast2”, software for faster 60 millisecond shift-times. A new traction control system combined the F1-Trac traction and stability control with the E-Diff electronic differential. The Ferrari 430 Scuderia accelerates from 0-100 km/h in 3.6 seconds, with a top speed of 202 miles per hour. Ferrari claimed that around their test track, Fiorano Circuit, it matched the Ferrari Enzo, and the Ferrari F430’s successor, the Ferrari 458. To commemorate Ferrari’s 16th victory in the Formula 1 Constructor’s World Championship in 2008, Ferrari unveiled the Scuderia Spider 16M at World Finals in Mugello. It is effectively a convertible version of the 430 Scuderia. The engine produces 510 PS at 8500 rpm. The car has a dry weight of 1,340 kg, making it 80 kg lighter than the F430 Spider, at a curb weight of 1,440 kg (3,175 lb). The chassis was stiffened to cope with the extra performance available and the car featured many carbon fibre parts as standard. Specially lightened front and rear bumpers (compared to the 430 Scuderia) were a further sign of the efforts Ferrari was putting into this convertible track car for the road. Unique 5-spoke forged wheels were produced for the 16M’s launch and helped to considerably reduce unsprung weight with larger front brakes and callipers added for extra stopping power (also featured on 430 Scuderia). It accelerates from 0-100 km/h in 3.7 seconds, with a top speed of 315 km/h (196 mph). 499 vehicles were released beginning early 2009 and all were pre-sold to select clients. Seen here were the Coupe. Spider and the Scuderia.

Widely rumoured to be called the F60, Ferrari surprised everyone at its 2002 unveiling by giving it the name Enzo. This car was built using even more Formula One technology, such as a carbon-fibre body, F1-style electrohydraulic shift transmission, and carbon fibre-reinforced silicon carbide (C/SiC) ceramic composite disc brakes. Also used were technologies not allowed in F1 such as active aerodynamics and traction control. After a downforce of 7600 N (1700 lb/ft) is reached at 300 km/h (186 mph) the rear wing is actuated by computer to maintain that downforce. The Enzo’s F140 B V12 engine was the first of a new generation for Ferrari. It was based on the design of the V8 found in Maserati’s Quattroporte, using the same basic design and 104 mm (4.1 in) bore spacing. The Enzo formed the basis for a whole array of other very special cars, including the FXX and FXX Evoluzione cars and the Maserati MC12 and MC12 Evoluzione as well as the Ferrari P4/5 and the Millechilli. Originally, 349 of these were going to be produced, but Ferrari decided to add another 50 to the total, meaning 400 in total were produced up until 2004.

The next V12 engined Ferrari was the 599 GTB (internal code F141) a new flagship, replacing the 575M Maranello. Styled by Pininfarina under the direction of Ferrari’s Frank Stephenson, the 599 GTB debuted at the Geneva Motor Show in February 2006. It is named for its total engine displacement (5999 cc), Gran Turismo Berlinetta nature, and the Fiorano Circuit test track used by Ferrari. The Tipo F140 C 5999 cc V12 engine produced a maximum 620 PS (612 hp), making it the most powerful series production Ferrari road car of the time. At the time of its introduction, this was one of the few engines whose output exceeded 100 hp per litre of displacement without any sort of forced-induction mechanism such as supercharging or turbocharging. Its 448 ft·lb of torque was also a record for Ferrari’s GT cars. Most of the modifications to the engine were done to allow it to fit in the Fiorano’s engine bay (the original Enzo version could be taller as it would not block forward vision due to its mid-mounted position). A traditional 6-speed manual transmission as well as Ferrari’s 6-speed called “F1 SuperFast” was offered. The Fiorano also saw the debut of Ferrari’s new traction control system, F1-Trac. The vast majority of the 599 GTB’s were equipped with the semi-automatic gearbox, with just 30 examples produced with a manual gearbox of which 20 were destined for the United States and 10 remained in Europe. The car changed little during its 6 year production, though the range did gain additional versions, with the HGTE model being the first, with a number of chassis and suspension changes aimed at making the car even sharper to drive, and then the more potent 599GTO came in 2010. With 670 bhp, this was the fastest road-going Ferrari ever made. Just 599 were made. The model was superceded by the F12 Berlinetta in 2012. GTB and GTO versions were on show here.

The Ferrari 612 Scaglietti, a 2+2 coupé grand tourer, was produced between 2004 and 2010. The 612 Scaglietti was designed to replace the smaller 456 M; its larger size makes it a true 4 seater with adequate space in the rear seats for adults. The 612 was Ferrari’s second all-aluminium vehicle, the first being the 360 Modena. Its space frame, developed with Alcoa, was made from extrusions and castings of the material, and the aluminium body is welded on. The chassis of the 612 forms the basis of the later 599 GTB model. The 612 Scaglietti shared its engine with the Ferrari 575 Superamerica. The Scaglietti had a top speed of 320 km/h (198.8 mph) and a 0–100 km/h acceleration time of 4.2 seconds. It came with a either a 6-speed manual or the 6-speed F1A semi-automatic paddle shift system, a much refined version of the F1 system in the 360. The model was replaced by the Ferrari FF in 2011.

After a gap of some years, Ferrari added a 4 seater V8 model to the range at the 2008 Paris Motor Show, with the California. According to industry rumours, the California originally started as a concept for a new Maserati, but the resulting expense to produce the car led the Fiat Group to badge it as a Ferrari in order to justify the high cost of purchase; the company denies this, however. The California heralded a number of firsts for Ferrari: the first front engined Ferrari with a V8; te first to feature a 7-speed dual-clutch transmission; the first with a folding metal roof; the first with multi-link rear suspension; and the first with direct petrol injection. Bosch produced the direct injection system. The engine displaces 4,297 cc, and used direct injection. It delivered 453 bhp at 7,750 rpm; its maximum torque produced was 358 lbf·ft at 5,000 rpm. The resulting 106 bhp per litre of engine displacement is one of the highest for a naturally aspirated engine, as other manufacturers have used supercharging or turbocharging to reach similar power levels. Ferrari spent over 1,000 hours in the wind tunnel with a one-third-scale model of the California perfecting its aerodynamics. With the top up, the California has a drag coefficient of Cd=0.32, making it the most aerodynamic Ferrari ever made until the introduction of the Ferrari F12 Berlinetta. Throughout the California’s production, only 3 cars were built with manual transmission, including one order from the UK. On 15 February 2012, Ferrari announced an upgrade, which was lighter and more powerful. Changes include reducing body weight by 30 kg (66 lb), increased power by output of 30 PS and 11 lbf·ft, acceleration from 0–100 km/h (62 mph) time reduced to 3.8 seconds, introduction of Handling Speciale package and elimination of the manual transmission option. The car was released at the 2012 Geneva Motor Show as a 2012 model in Europe. To give the clients a more dynamic driving experience, an optional HS (Handling Speciale) package was developed as part of the update. It can be recognised by a silver coloured grille and ventilation blisters behind the front wheel wells. The HS package includes Delphi MagneRide magnetorheological dampers controlled by an ECU with 50% faster response time running patented Ferrari software, stiffer springs for more precise body control and a steering rack with a 9 per cent quicker steering ratio (2.3 turns lock to lock as opposed to the standard rack’s 2.5). A more substantive update came in 2014, with the launch of the California T, which remains in production. It featured new sheetmetal, a new interior, a revised chassis and a new turbocharged powertrain.

Next up was the 458, of which there were examples of both the closed Coupe and the later Spider model. An all new design, the 458 Italia was first officially unveiled at the 2009 Frankfurt Motor Show. Once more, Ferrari advised that the model incorporated technologies developed from the company’s experience in Formula 1. The body computer system was developed by Magneti Marelli Automotive Lighting. The 458 came with a 4,499 cc V8 engine of the “Ferrari/Maserati” F136 engine family, producing 570 PS ( 562 hp) at 9,000 rpm and 540 N·m (398 lb/ft) at 6,000 rpm with 80% torque available at 3,250 rpm. The engine featured direct fuel injection, a first for Ferrari mid-engine setups in its road cars. The only transmission available was a dual-clutch 7-speed Getrag gearbox, in a different state of tune shared with the Mercedes-Benz SLS AMG. There was no traditional manual option, making this the fourth road-car after the Enzo, Challenge Stradale and 430 Scuderia not to be offered with Ferrari’s classic gated manual. The car’s suspension featured double wishbones at the front and a multi-link setup at the rear, coupled with E-Diff and F1-Trac traction control systems, designed to improve the car’s cornering and longitudinal acceleration by 32% when compared with its predecessors.The brakes included a prefill function whereby the pistons in the calipers move the pads into contact with the discs on lift off to minimise delay in the brakes being applied. This combined with the ABS and standard Carbon Ceramic brakes caused a reduction in stopping distance from 100–0 km/h (62-0 mph) to 32.5 metres. Ferrari’s official 0–100 km/h (62 mph) acceleration time was quoted as 2.9–3.0 seconds with a top speed of 340 km/h (210 mph). In keeping with Ferrari tradition the body was designed by Pininfarina under the leadership of Donato Coco, the Ferrari design director. The interior design of Ferrari 458 Italia was designed by Bertrand Rapatel, a French automobile designer. The car’s exterior styling and features were designed for aerodynamic efficiency, producing a downforce of 140 kg (309 lb) at 200 km/h. In particular, the front grille features deformable winglets that lower at high speeds, in order to offer reduced drag. The car’s interior was designed using input from former Ferrari Formula 1 driver Michael Schumacher; in a layout common to racing cars, the new steering wheel incorporates many controls normally located on the dashboard or on stalks, such as turning signals or high beams. At launch the car was widely praised as being pretty much near perfect in every regard. It did lack a fresh air version, though, but that was addressed with the launch of the 458 Spider at the 2011 Frankfurt Motor Show. This convertible variant of the 458 Italia featured an aluminium retractable hardtop which, according to Ferrari, weighs 25 kilograms (55 lb) less than a soft roof such as the one found on the Ferrari F430 Spider, and can be opened in 14 seconds The engine cover was redesigned to accommodate the retractable roof system. It had the same 0–100 km/h time as the hard-top but a lower top speed of 199 mph. It quickly became the better seller of the two versions.

The 458 Speciale is part of a now long line of specially engineered cars added to complement the “regular” V8 models that started with the 100 units of the 348 Speciale produced in 1992, and followed up by the 360 Challenge Stradale, the 430 Scuderia and the 16M. In essence they are all about adding power and shedding weight. In simplistic terms, the road to the Speciale can be summed up in four words: more power, less weight. There are other, more detailed changes, too, obviously, but those are the cornerstones around which everything else is shaped. The normally aspirated, flat-plane crank V8 retains its 4497cc swept capacity but receives new cam geometry with higher valve lift, shorter inlet manifolds and different pistons providing a higher compression ratio. Internal friction is reduced, through the use of uprated materials and the upshot is 597bhp (up from 562bhp) generated at the engine’s 9000rpm limit. Torque is the same, at 398lb ft, still delivered at 6000rpm. The engine is mated to a seven-speed, dual-clutch gearbox whose upshifts, we were told at the launch of such gearboxes, are all but instant. That’s still true, but Ferrari has improved the response time to a pull on the lever and made the engine rev-match more quickly on downshifts to reduce the time that those take. The engine’s changes shave 8kg from the car’s overall weight – the exhaust is all aluminium and the intake is carbonfibre. Those 8kg form part of a claimed 90kg total saving at 1395kg now, versus 1485kg for a 458 Italia. Of this 90kg, 12kg is contributed by lighter, forged wheels, 13kg comes from bodywork and window changes (lighter glass all round and Lexan for the engine cover), and 20kg comes from the cabin. There are two flaps on the Speciale’s front valance, one either side of the prancing horse badge in its centre. Below 106mph these flaps remain closed, which diverts air towards the radiators. Above that speed, the radiators get quite enough cool air, thanks very much, so the flaps open, which reduces drag. Then, above 137mph, they move again, lowering to shift downforce to the rear of the car, in turn adjusting the balance 20 per cent rearward in order to promote high-speed cornering stability. At the rear, meanwhile, there is a new diffuser (the exhausts have been rerouted to make the most of its central section). Movable flaps in the diffuser adjust, but this time they are dependent not only on speed but also on steering angle and throttle or brake position. When lowered, the flaps stall the path of air into the diffuser and improve the Cd by 0.03. When raised, the diffuser adds downforce as it should. Bodywork changes, though, also bring some aerodynamic improvements, you’ll not be surprised to hear, with lessons applied from the LaFerrari and FXX programmes. In the front valance and under the rear diffuser, there are flaps that open at speed to reduce drag and improve downforce. Finally, there are new Michelin Pilot Sport Cup 2 tyres in a unique compound – rather a sticky one, we suspect – plus new calibration for the adaptive dampers. The carbon-ceramic brake discs also use a new compound. 499 of them were built and they sold out very quickly.

The Ferrari FF (FF meaning “Ferrari Four”, for four seats and four-wheel drive, the Type F151) is a grand tourer presented by Ferrari on March 1, 2011 at the Geneva Motor Show as a successor to the 612 Scaglietti and is Ferrari’s first production four-wheel drive model. The body style has been described as a shooting-brake, a type of sporting hatchback/estate car with two doors. With a top speed of f 335 km/h (208 mph) and it accelerates from 0 to 100 km/h (62 mph) in 3.7 seconds, Ferrari stated that the FF was the world’s fastest four-seat automobile upon its release to the public. At the time of its reveal, the Ferrari FF had the largest road-going Ferrari engine ever produced: an F140 EB 6,262 cc naturally aspirated direct injected 65° V12, which produced 660 PS (485 kW; 651 hp) at 8,000 rpm and 683 N⋅m (504 lb⋅ft) of torque at 6000 rpm. The FF is equipped with a 7-speed dual-clutch transmission and paddle shift system similar to the California, the 458 Italia, and the Ferrari F12berlinetta. The new four-wheel drive system, engineered and patented by Ferrari, is called 4RM: it is around 50% lighter than a conventional system, and provides power intelligently to each of the four wheels as needed. It functions only when the manettino dial on the steering wheel is in the “comfort” or “snow” positions, leaving the car most often in the traditional rear wheel drive layout. Ferrari’s first use of 4RM was in a prototype created in the end of the 80s, called 408 4RM (abbreviation of “4.0 litre, 8 cylinder, 4 Ruote Motrici”, meaning “four-wheel drive”). This system is based around a second, simple, gearbox (gears and other components built by Carraro Engineering), taking power from the front of the engine. This gearbox (designated “power take off unit”, or PTU) has only two forward gears (2nd and 4th) plus reverse (with gear ratios 6% taller than the corresponding ratios in the main gearbox), so the system is only active in 1st to 4th gears. The connection between this gearbox and each front wheel is via independent Haldex-type clutches, without a differential. Due to the difference in ratios “the clutches continually slip” and only transmit, at most, 20% of the engine’s torque. A detailed description of the system (based on a conversation with Roberto Fedeli, Ferrari’s technical director) has been published. The FF shares the design language of contemporary Ferraris, including the pulled-back headlights of the 458 Italia, and the twin circular taillights seen on the 458 as well as the 599 GTB Fiorano. Designed under the direction of Lowie Vermeersch, former Design Director at Pininfarina, and Flavio Manzoni, Ferrari’s Styling Centre, work on the shooting brake concept initially started following the creation of the Sintesi show car of 2007. Distinctive styling elements include a large egg-crate grille, defined side skirts, and four exhaust tips. The shooting brake configuration is a departure from the conventional wedge shape of modern Ferraris, and the FF has been likened to the similarly-shaped 1962 Ferrari 250 GT SWB Drogo race car. The combination of hatchback-like shooting-brake design and collapsible rear seats gives the Ferrari FF a boot capacity of between 16 and 28 cu ft. Luxury is the main element of the interior and the use of Leather is incorporated throughout, just like the predecessors of the FF. Creature comforts like premium air conditioning, GPS navigation system, carpeting and sound system are also used. An updated version. called the GTC4 Lusso was launched in 2016 by which 2291 examples had been built.

The latest of the V8 line is the 488 GTB, and one of these was the “course car” for the day. Launched at the 2015 Geneva Show, the 488GTB followed the lead set by the California T in bringing turbocharging into a modern-day, mid-engined V8 Ferrari supercar for the first time. The engine is completely new when compared with its V8 stablemate, not only in components but also in feel and character. It is a twin-turbocharged 3902cc unit whilst that in the California T is 3855cc. In the 488 GTB, it produces 660bhp at 8000rpm and 560lb ft at 3000rpm. Both outputs are significant increases over the normally aspirated 4.5-litre V8 used in the 562 bhp 458 Italia and 597 bhp 458 Speciale, and also greater than the car’s biggest rival, the McLaren 650S. The torque figure of the 488 GTB is such that it also exceeds the 509lb ft at 6000rpm of the normally aspirated V12 used in the range-topping Ferrari F12 Berlinetta. The mighty new engine in the 488 GTB drives the rear wheels through a revised seven-speed dual-clutch automatic gearbox derived from the 458. It features a new ‘Variable Torque Management’ system which, Ferrari says, “unleashes the engine’s massive torque smoothly and powerfully right across the rev range”. The gear ratios are also tuned to “deliver incredibly progressive acceleration when the driver floors the throttle”. The 488 GTB can crack 0-62mph in just 3.0sec, 0-124mph in 8.4sec and reach a top speed of 205mph. Its 0-62mph and 0-124mph times match the McLaren 650S’s, but the Woking car’s top speed is slightly higher at 207mph. The engine also accounts for the ‘488’ element of the car’s name, because each of the engine’s eight cylinders is 488cc in capacity when rounded up. The GTB suffix, standing for Gran Turismo Berlinetta, is a hallmark of previous mid-engined V8 Ferraris such as the 308 GTB. Not only is the new turbo engine more potent than the 4.5-litre V8 from the 458 Italia, but it is also more economical. Combined fuel economy is rated at 24.8mpg, compared with 21.2mpg in the 458 Italia, and CO2 emissions are 260g/km – a 47g/km improvement. Ferrari’s HELE engine stop-start system features on the 488 GTB. Developments on the dynamic side include a second generation of the Side Slip Angle Control system, called SSC2. This allows the driver to oversteer without intruding, unless it detects a loss of control. The SSC2 now controls the active dampers, in addition to the F1-Trac traction control system and E-Diff electronic differential. Ferrari says the result is “more precise and less invasive, providing greater longitudinal acceleration out of corners” and flatter, more stable behaviour during “complex manoeuvres”. Learnings from the Ferrari XX programme have also been incorporated into the 488 GTB, something that Ferrari says allows all drivers and not just professionals, to make the most of its electronic and vehicle control systems. It also claims the 488 GTB is “the most responsive production model there is”, with responses comparable to a track car. The 488 GTB has lapped Ferrari’s Fiorano test track in 1min 23sec – two seconds faster than the 458 Italia, and half a second quicker than the 458 Speciale. The dimensions of the 488 GTB – it is 4568mm in length, 1952mm in width and 1213mm in height – closely match the 458 Italia from which it has evolved. Its dry weight is 1370kg when equipped with lightweight options – 40kg more than the McLaren 650S. The new look, styled at the Ferrari Styling Centre, features several new aerodynamic features that improve downforce and reduce drag. Most notable is the addition of active aerodynamics at the rear through a ‘blown’ rear spoiler, where air is channelled from the base of the glass engine cover under the spoiler. This contributes to the 50% increase in downforce over the 458 Italia. Also new is a double front spoiler, an aerodynamic underbody, a large air intake at the front that references the 308 GTB, a diffuser with active flaps, new positioning for the exhaust flaps and new-look lights. The interior has been redesigned to be made more usable, including new switchgear, air vents and instrument panel. The multi-function steering wheel remains, while the infotainment system gets a new interface and graphics. The Spider followed the closed coupe model six months later, and supplies of that car are now reaching the UK. It is expected that this will be bigger seller of the car, as was the case with the 458 models.

Final Ferrari model to be seen here were a couple of examples of the F12 Berlinetta, the current top of the range, with it is V12 engine and elegant 2-seater body.

FIAT

Celebrating the 60th anniversary of the Nuova 500 were a number of examples of this much-loved car. Known as project 110, the brief for the Nuova 500 was to create a micro-car that would not only carry on the tradition of the earlier Topolino, but which would also take sales away from the ever popular Lambretta and Vespa scooters of the day. It clearly needed to be smaller than the 600 which had been released with a conventional 4 cylinder engine. Not an easy task, but development started in 1953 and by August 1954, two designs were ready to be shown to Fiat management. They selected one, and serious development began. At first the car was referred to as the 400, as it was going to have a 400cc engine, but it was soon realised that this was just too small, so a larger 500cc air-cooled engine was developed. It was signed off in January 1956, with production starting in March 1957 in advance of a June launch. Fiat’s marketing department got busy, with hundreds of the new car taking to the streets of Turin, each with a pretty girl standing through the open sunroof that was a feature of all the early cars. The press loved it. 50 units were shipped to Britain, where the car made its debut at Brands Hatch, and again the reception was enthusiastic. But the orders just did not come in. Fiat went for a hasty rethink, relaunching the car at the Turin Show later that year. power was increased from 13 to 15 bhp, and the poverty spec was lessened a little, with headlight bezels, brightwork on the side and chrrome hubcaps, a Nuova500 badge on the engine cover, winding side windows (the launch cars just had opening quarterlights) and the option of a heater fan. It was enough to get sales moving. The original car was still offered, at a lower price, called the Economy. In the first year of production, 28,452 Fiat 500s were made. Over the next 19 years, the car changed little in overall appearance, but there were a number of updates with more power and equipment added. A 500 Sport was launched in August 1958, with a more powerful version of the 499cc engine. It lost the soft top, having a ridged steel roof, to increase strength of the body. It was only available in grey with a red side flash. The first major changes came in 1960 with the 500D. This looks very similar to the Nuova, but with two key differences. One is the engine size: the D features an uprated 499 cc engine producing 17 bhp as standard, an engine which would be used right through until the end of the L in 1973; and the other is the roof: the standard D roof does not fold back as far as the roof on the Nuova, though it was also available as the “Transformable” with the same roof as the Nuova. The D still featured “suicide doors”. There were larger rear light clusters, more space in the front boot thanks to a redesign of the fuel tank and new indicators under the headlights. A year later, Fiat added a light on the rear-view mirrors and a windscreen washer, but the car still lacked a fuel gauge. Sales increased from 20,900 in 1960 to 87.000 in 1961, 132,000 in 1962 and by 1964, the last year of production, they hit 194,000 units. The D was replaced in 1965 by the 500F, which finally moved the door hinges from back to the front, owing to changes in Italian safety laws. There was a deeper windscreen and thinner door pillars, which increased the height of the car by 10mm, improving visibility for the driver. The 500F ran through to 1975, from 1968 alongside the more luxurious 500L which was added to the range in 1968. The L is easy to tell apart, with its bumper overriders. The final updates created the 500R, which incorporated many changes from the 126 under the skin of the classic shape, and in this form production continued alongside the newer 126 until 1976.

Following the success of the 500 and 600 models, Fiat introduced a slightly larger and more expensive var, the 850 in 1964. The regular 2 door saloon was soon joined in the range by other models and they are the ones you see more often these days, not that they are exactly common now. The 850 Coupe, early and later versions of which were to be seen here was seen for the first time at the 1965 Geneva Show. As was generally the case at the time, the body looked completely different from the saloon on which it was based, but underneath it shared the same mechanicals including the the original 843 cc engine producing 47 hp, which gave it a maximum speed of 84 mph. A Spider model was launched at the same time. In order to separate the sportier variants, equipment levels were raised, with both models getting sport seats, a sport steering wheel and round speedometer; The Spider even received a completely rearranged instrument panel. The front drum brakes were replaced with disc brakes, although drum brakes remained on the rear wheels. In 1968, Fiat revised both the Spider and Coupé and gave them a stronger engine with 903 cc and 52 hp. They were called Sport Spider and Sport Coupé. The Sport Spider body stayed essentially the same, but with a restyled front, whereas the Coupe gained twin headlights at the front and a revised tail with a slight lip on the trailing edge of the engine cover. Despite its popularity, the Coupe was the first model to cease production, being deleted in 1971. Seen here was an early 850 Coupe.

The X1/9 followed a 1969 show concept car called the Autobianchi Runabout, with styling by Bertone under chief designer Marcello Gandini. The Runabout was powered by the same engine as the Autobianchi A112. Designed around the all-new 128 SOHC engine and with the gearbox (transmission) from the front wheel drive Fiat 128, the X1/9 relocated the transverse drive train and suspension assembly from the front of the 128 to the rear of the passenger cabin, directly in front of the rear axle, giving a mid-engined layout. The layout also located the fuel tank and spare wheel side by side ahead of the engine, directly behind the seats — optimising the proportion of the car’s weight falling within its wheelbase for more effective handling and also enabling cargo areas front and rear. Unlike Fiat’s marketing nomenclature at the time which used a numerical system (e.g., 127, 128, 124, 131) denoting relative position in the model range, the X1/9 retained its prototype code as its marketing name. Fiat’s prototype coding used X0 for engines, X1 for passenger vehicles and X2 for commercial vehicles. The X1/9 was thus the ninth passenger car developed using the nomenclature. The prototype car featured a distinctive wedge shape and took many styling cues from contemporary power-boat design. Though the more extreme features of the Runabout such as the C pillar mounted headlights and the small wind-deflector windscreen were lost for the production car, many aesthetic features of the Autobianchi Runabout are readily identifiable on the X1/9. The long flat bonnet with central indentation, the large front overhang, the wedge shape with prominent C pillar roll-over hoop and the car-length indented plimsoll-line all made the successful transition to the X1/9, giving it a highly distinctive appearance. Once developed for production, the two-seater featured sharp-edged styling with a wedge shape, pop-up headlights and a removable hard top roof panel (targa top). The removable hardtop stores in the front luggage compartment, below the front hood, only slightly reducing the space available for cargo. An aftermarket company offered a top made of lightweight clear-smoked polycarbonate. The car was developed for release for European sales in 1972 to replace the 850 spider by Bertone. It was not intended as a replacement for the 124 Sport spider and production of the 124 spider and X1/9 continued in parallel for much of the X1/9’s life. The car’s monocoque body was produced at the Bertone factory in Torino and then transported to the Fiat’s Lingotto factory for final assembly. In 1982, shortly after the introduction of the 1500 model, complete production was assumed by Bertone with models subsequently badged as the “Bertone” X1/9. Bertone models featured revised footwells redesigned to enhance legroom and sitting comfort for persons taller than the original design’s target. The first models featured a 75 bhp 1290 cc single overhead cam engine with an aluminium head. In 1978 the more powerful 85bhp 1500cc unit found its way into the engine bay which necessitated a raised engine cover to provide the clearance. Larger bumpers were fitted at this time. Fiat made few other changes for many years, as if they lost interest in the car. The last production models were named the Gran Finale and sold over the 1989/1990 period. They were a dealer modification of the special edition (commonly abbreviated to SE) of 1988/1989, with the addition of a rear spoiler and “gran finale” badges.

Final Fiat here was this 131 Rally replica.

FORD

In the late 1960s, Ford set about developing the third-generation Cortina,the Mark III, which would be produced in higher volumes than before, following the recent merger of Ford of Britain and Ford of Germany into the modern-day Ford of Europe. The car marked the convergence of the German Taunus and British Cortina platforms with only minor differences between the two, hence the car’s internal name TC1, standing for Taunus-Cortina. It was also the last European car engineered by Harley Copp as Vice President Engineering and head of Brentwood, before he returned to Detroit. Ford UK originally wanted to call it something other than Cortina, but the name stuck. Although the Mark III looked significantly larger than the boxier Mark II Cortina, it was actually the same overall length, but 4 inches wider. Within the overall length, a wheelbase lengthened by more than 3 inches (76 mm) also contributed to the slightly more spacious interior. The Mark III Cortina was inspired by the contemporary “coke bottle” design language which had emanated from Detroit – the car sported similar fluted bonnet and beltline design elements to the North American Mercury Montego and Ford LTD of the same era. It replaced both the Mark II Cortina and the larger, more expensive Ford Corsair, offering more trim levels and the option of larger engines than the Mark II Cortina. The Mark III’s continental European sister car – the Taunus TC – was subtly different in appearance, with longer front indicators, different door skins and rear wing pressings that toned down the drooping beltline in order to lose the “coke-bottle” appearance of the Cortina. The MacPherson strut front suspension was replaced with more conventional double A-arm suspension which gave the Mark III a much softer ride on the road’ but did give the larger engines distinct understeer. Trim levels for the Mark III Cortina were Base, L, XL , GT and GXL. The early Mark III Cortinas came with the same 1,300 and 1,600 cc engines as the Mark II Cortinas, except for the 1,600 cc GXL. These engines are known as the Kent, crossflow engine or OHV engine. There was also the introduction of the 2000 cc engine, the single overhead cam engine, now known as the pinto engine. SOHC. The OHV Kent unit was fitted with a single choke carburettor and was used for the early models up to GT trim, the SOHC twin choke carburettor Pinto unit was used for the GT and GXL models. The GXL was also offered in 1,600 in the later Cortina Mark IIIs. In left-hand drive markets, the 1,600 cc OHC was replaced by a twin-carb OHV (Kent) unit not offered in the home market, in order to distinguish it from the competing Taunus which only came with the OHC Pinto engine. 2.0 litre variants used a larger version of the 1,600 cc Pinto unit and were available in all trim levels except base. Base, L and XL versions were available as a five-door estate. Although no longer than its predecessor, the Mark III was a heavier car, reflecting a trend towards improving secondary safety by making car bodies more substantial. Weight was also increased by the stout cross-member incorporated into the new simplified front suspension set-up, and by the inclusion of far more sound deadening material which insulated the cabin from engine and exhaust noise, making the car usefully quieter than its predecessor, though on many cars the benefit was diminished by high levels of wind noise apparently resulting from poor door fit around the windows. Four-speed manual transmissions were by now almost universally offered in the UK for this class of car, and contemporary road tests commented on the rather large gap between second and third gear, and the resulting temptation to slip the clutch when accelerating through the gears in the smaller-engined cars: it was presumably in tacit acknowledgment of the car’s marginal power-to-weight ratio that Ford no longer offered the automatic transmission option with the smallest 1,298 cc-engined Cortina. Four headlights and Rostyle wheels marked out the GT and GXL versions, while the GXL also had bodyside rub strips, a vinyl roof and a brushed aluminium and black boot lid panel on the GXLs, while the GTs had a black painted section of the boot with a chrome trim at either site sloping dashboard with deeply recessed dials and all coil suspension all round. In general styling and technical make up, many observed that the Mark III Cortina aped the Vauxhall Victor FD of 1967. The Cortina went on sale on 23 October 1970, but sales got off to a particularly slow start because of production difficulties that culminated with a ten-week strike at Ford’s plant between April and June 1971, which was at the time reported to have cost production of 100,000 vehicles, equivalent to almost a quarter of the output for a full year. During 1971 the spring rates and damper settings were altered along with the front suspension bushes which reduced the bounciness of the ride and low speed ride harshness which had generated press criticism at the time of the Cortina Mark III’s launch. Volumes recovered, and with the ageing Austin/Morris 1100/1300 now losing out to various newer models, the Cortina was Britain’s top selling car in 1972, closely followed by the Escort. It remained the UK’s top selling car until 1976 when it overtaken by the Mk2 Escort. In late 1973 the Cortina Mark III was given a facelift. The main difference was the dashboard and clocks, no longer did it slope away from the driver’s line of sight. But shared the same dash and clocks as the later Mark IV and Mark V Cortinas, upgraded trim levels and revised grilles, rectangular headlights for the XL, GT and the new 2000E (the “E” standing for executive), which replaced the GXL. The 1.3 litre Kent engine was carried over but now, 1.6 litre models all used the more modern 1.6 litre SOHC engine. Whilst the TD Cortina still had double A-arm suspension with coils at the front and a four-link system at the rear, handling was improved. The 2000E reverted to the classy treatment offered by the 1600E and later Mark IV/V Ghia models instead of the faux wood-grain trim offered by the GXL. The 2000E was also available as an estate version. The cars were replaced by the Mark IV in the autumn of 1976.

The squarer-styled Mark II version appeared in January 1975. The first production models had rolled off the production lines on 2 December 1974. Unlike the first Escort (which was developed by Ford of Britain), the second generation was developed jointly between the UK and Ford of Germany. Codenamed “Brenda” during its development, it used the same mechanical components as the Mark I. The 940 cc engine was still offered in Italy where the smaller engine attracted tax advantages, but in the other larger European markets in Europe it was unavailable. The estate and van versions used the same panelwork as the Mark I, but with the Mark II front end and interior. The car used a revised underbody, which had been introduced as a running change during the last six months production of the Mark I. Rear suspension still sat on leaf springs though some contemporaries such as the Hillman Avenger had moved on to coil springs. The car came in for criticism for its lack of oddments space, with a glove compartment only available on higher end models, and its stalk-mounted horn. The “L” and “GL” models (2-door, 4-door, estate) were in the mainstream private sector, the “Sport”, “RS Mexico”, and “RS2000” in the performance market, the “Ghia” (2-door, 4-door) for a hitherto untapped small car luxury market, and “base / Popular” models for the bottom end. Panel-van versions catered to the commercial sector. The 1598 cc engine in the 1975 1.6 Ghia produced 84 hp with 92 ft·lbft torque and weighed 955 kg (2105 lb). A cosmetic update was given in 1978 with L models gaining the square headlights (previously exclusive to the GL and Ghia variants) and there was an upgrade in interior and exterior specification for some models. Underneath a wider front track was given. In 1979 and 1980 three special edition Escorts were launched: the Linnet, Harrier and Goldcrest. Production ended in Britain in August 1980, other countries following soon after.

The Capri Mk III was referred to internally as “Project Carla”, and although little more than a substantial update of the Capri II, it was often referred to as the Mk III. The first cars were available in March 1978, but failed to halt a terminal decline in sales. The concept of a heavily facelifted Capri II was shown at the 1976 Geneva show: a Capri II with a front very similar to the Escort RS2000 (with four headlamps and black slatted grille), and with a rear spoiler, essentially previewed the model some time before launch. The new styling cues, most notably the black “Aeroflow” grille (first used on the Mk I Fiesta) and the “sawtooth” rear lamp lenses echoed the new design language being introduced at that time by Ford of Europe’s chief stylist Uwe Bahnsen across the entire range. Similar styling elements were subsequently introduced in the 1979 Cortina 80, 1980 Escort Mk III and the 1981 Granada Mk IIb. In addition, the Mk III featured improved aerodynamics, leading to improved performance and economy over the Mk II and the trademark quad headlamps were introduced. At launch the existing engine and transmission combinations of the Capri II were carried over, with the 3.0 S model regarded as the most desirable model although the softer, more luxurious Ghia derivative with automatic, rather than manual transmission, was the bigger seller of the two V6-engined models. Ford began to focus their attention on the UK Capri market as sales declined, realising the car had something of a cult following there. Unlike sales of the contemporary 4-door Cortina, Capri sales in Britain were to private buyers who would demand less discounts than fleet buyers allowing higher margins with the coupé. Ford tried to maintain interest in 1977 with Ford Rallye Sport, Series X, “X Pack” options from the performance oriented RS parts range. Although expensive and slow selling these proved that the press would enthusiastically cover more developed Capris with higher performance. In early 1982, the Essex 3.0 V6 which had been the range topper since September 1969 was dropped, while a new sporty version debuted at the Geneva Motor Show, called the 2.8 Injection. The new model was the first regular model since the RS2600 to use fuel injection. Power rose to a claimed 160 PS, even though tests showed the real figure was closer to 150 PS, giving a top speed of 210 km/h (130 mph), but the car still had a standard four-speed gearbox. The Capri 2.8 Injection breathed new life into the range and kept the car in production 2–3 years longer than Ford had planned. The four-speed gearbox was replaced with a five-speed unit early on – at the same time Ford swapped the dated looking chequered seats for more luxurious looking velour trim. A more substantial upgrade was introduced in 1984 with the Capri Injection Special. This development used half leather seating and included a limited slip differential. Externally the car could be easily distinguished by seven spoke RS wheels (without the customary “RS” logo since this was not an RS vehicle) and colour-coded grille and headlamp surrounds. At the same time the 2.0 Capri was rationalised to one model, the 2.0 S, which simultaneously adopted a mildly modified suspension from the Capri Injection. The 1.6 model was also reduced to a single model, the 1.6 LS. The car was finally deleted at the end of 1986, 1.9 million cars having been made over 18 years, and having been sold only in the UK for the final months of production.

Also here was a Cortina 80, sometimes known as the Mark V. It was announced on 24 August 1979. Officially the programme was code named Teresa, although externally it was marketed as “Cortina 80”, but the Mark V tag was given to it immediately on release by the press, insiders and the general public. Largely an update to the Mark IV, it was really a step between a facelift and a rebody. The Mark V differentiated itself from the Mark IV by having revised headlights with larger turn indicators incorporated (which were now visible on the side too), a wider slatted grille said to be more aerodynamically efficient, a flattened roof, larger glass area, slimmer C-pillars with revised vent covers, larger slatted tail lights (on saloon models) and upgraded trim. Improvements were also made to the engine range, with slight improvements to both fuel economy and power output compared to the Mark IV. The 2.3 litre V6 engine was given electronic ignition and a slight boost in power output to 116 bhp, compared to the 108 bhp of the Mark IV. Ford also claimed improved corrosion protection on Mark V models; as a result, more Mark Vs have survived; however, corrosion was still quite a problem. The estate models combined the Mark IV’s bodyshell (which was initially from the 1970 Ford Taunus) with Mark V front body pressings. A pick-up (“bakkie”) version was also built in South Africa. These later received a longer bed and were then marketed as the P100. Variants included the Base, L, GL, and Ghia (all available in saloon and estate forms), together with Base and L spec 2-door sedan versions (this bodystyle was available up to Ghia V6 level on overseas markets). The replacement for the previous Mark IV S models was an S pack of optional extras which was available as an upgrade on most Mark V models from L trim level upwards. For the final model year of 1982 this consisted of front and rear bumper overriders, sports driving lamps, an S badge on the boot, tachometer, 4 spoke steering wheel, revised suspension settings, front gas shock absorbers,’Sports’ gear lever knob, sports road wheels, 185/70 SR x 13 tyres and Fishnet Recaro sports seats (optional). Various “special editions” were announced, including the Calypso and Carousel. The final production model was the Crusader special edition which was available as a 1.3 litre, 1.6 litre, and 2.0 litre saloons or 1.6 litre and 2.0 litre estates. The Crusader was a final run-out model in 1982, along with the newly introduced Sierra. It was the best-specified Cortina produced to date and 30,000 were sold, which also made it Ford’s best-selling special edition model. Another special edition model was the Cortina Huntsman, of which 150 were produced. By this time, the Cortina was starting to feel the competition from a rejuvenated Vauxhall, which with the 1981 release Cavalier J-Car, was starting to make inroads on the Cortina’s traditional fleet market, largely helped by the front wheel drive benefits of weight. Up to and including 1981, the Cortina was the best selling car in Britain. Even during its final production year, 1982, the Cortina was Britain’s second best selling car and most popular large family car. On the continent, the Taunus version was competing with more modern and practical designs like the Talbot Alpine, Volkswagen Passat, and Opel Ascona. The very last Cortina – a silver Crusader – rolled off the Dagenham production line on 22 July 1982 on the launch of the Sierra, though there were still a few leaving the forecourt as late as 1987, with one final unregistered Cortina GL leaving a Derbyshire dealership in 2005. The last Cortina built remains in the Ford Heritage Centre in Dagenham, Essex, not far from the factory where it was assembled.

The Sierra RS Cosworth model. a very sporting version of Ford’s upper-medium sized family car, was built by Ford Europe from 1986 to 1992, the result of a Ford Motorsport project with the purpose of producing an outright winner for Group A racing in Europe. The project was defined in the spring of 1983 by Stuart Turner, then recently appointed head of Ford Motorsport in Europe, who had realised right away that Ford was no longer competitive in this area. Turner got in touch with Walter Hayes, at the time the vice-president of public relations at Ford, to get support for the project. Hayes had earlier been the driving force behind the development of the Ford GT40 that won Le Mans in 1966, and the Cosworth DFV engine that brought Ford 154 victories and 12 world championships in Formula One during the 1960s and 1970s. Hayes found the project very appealing and promised his full support. Turner then invited Ken Kohrs, vice-president of development, to visit Ford’s longtime partner, the automotive company Cosworth, where they were presented a project developed on Cosworth’s own initiative, the YAA engine. This was a twin cam, 16-valve engine based on Ford’s own T88 engine block, better known as the Pinto. This prototype proved an almost ideal basis for the engine Turner needed to power his Group A winner. Therefore, an official request for a turbocharged version (designated Cosworth YBB) capable of 180 HP on the street and 300 HP in race trim, was placed. Cosworth answered positively, but they put up two conditions: the engine would produce not less than 204 HP in the street version, and Ford had to accept no fewer than 15,000 engines. Turner’s project would only need about 5,000 engines, but Ford nevertheless accepted the conditions. The extra 10,000 engines would later become one of the reasons Ford also chose to develop a four door, second generation Sierra RS Cosworth. To find a suitable gearbox proved more challenging. The Borg-Warner T5, also used in the Ford Mustang, was chosen, but the higher revving nature of the Sierra caused some problems. Eventually Borg-Warner had to set up a dedicated production line for the gearboxes to be used in the Sierra RS Cosworth. Many of the suspension differences between the standard Sierra and the Cosworth attributed their development to what was learned from racing the turbocharged Jack Roush IMSA Merkur XR4Ti in America and Andy Rouse’s successful campaign of the 1985 British Saloon Car Championship. Much of Ford’s external documentation for customer race preparation indicated “developed for the XR4Ti” when describing parts that were Sierra Cosworth specific. Roush’s suspension and aerodynamics engineering for the IMSA cars was excellent feedback for Ford. Some production parts from the XR4Ti made their way into the Cosworth such as the speedometer with integral boost gauge and the motorsport 909 chassis stiffening plates. In April 1983, Turner’s team decided on the recently launched Sierra as a basis for their project. The Sierra filled the requirements for rear wheel drive and decent aerodynamic drag. A racing version could also help to improve the unfortunate, and somewhat undeserved, reputation that Sierra had earned since the introduction in 1982. Lothar Pinske, responsible for the car’s bodywork, demanded carte blanche when it came to appearance in order to make the car stable at high speed. Experience had shown that the Sierra hatchback body generated significant aerodynamic lift even at relatively moderate speed. After extensive wind tunnel testing and test runs at the Nardò circuit in Italy, a prototype was presented to the project management. This was based on an XR4i body with provisional body modifications in fibreglass and aluminium. The car’s appearance raised little enthusiasm. The large rear wing caused particular reluctance. Pinske insisted however that the modifications were necessary to make the project successful. The rear wing was essential to retain ground contact at 300 km/h, the opening between the headlights was needed to feed air to the intercooler and the wheel arch extensions had to be there to house wheels 10” wide on the racing version. Eventually, the Ford designers agreed to try to make a production version based on the prototype. In 1984, Walter Hayes paid visits to many European Ford dealers in order to survey the sales potential for the Sierra RS Cosworth. A requirement for participation in Group A was that 5,000 cars were built and sold. The feedback was not encouraging. The dealers estimated they could sell approximately 1,500 cars. Hayes did not give up, however, and continued his passionate internal marketing of the project. As prototypes started to emerge, dealers were invited to test drive sessions, and this increased the enthusiasm for the new car. In addition, Ford took some radical measures to reduce the price on the car. As an example, the car was only offered in three exterior colours (black, white and moonstone blue) and one interior colour (grey). There were also just two equipment options: with or without central locking and electric window lifts. The Sierra RS Cosworth was first presented to the public at the Geneva Motor Show in March 1985, with plans to release it for sale in September and closing production of the 5,000 cars in the summer of 1986. In practice, it was launched in July 1986. 5545 were manufactured in total of which 500 were sent to Tickford for conversion to the Sierra three-door RS500 Cosworth. The vehicles were manufactured in right hand drive only, and were made in Ford’s Genk factory in Belgium. Exactly 500 RS500s were produced, all of them RHD for sale in the UK only – the biggest market for this kind of Ford car. It was originally intended that all 500 would be black, but in practice 56 white and 52 moonstone blue cars were produced.To broaden the sales appeal, the second generation model was based on the 4 door Sierra Sapphire body. It was launched in 1988, and was assembled in Genk, Belgium, with the UK-built Ford-Cosworth YBB engine. Cylinder heads on this car were early spec 2wd heads and also the “later” 2wd head which had some improvements which made their way to the 4X4 head. Suspension was essentially the same with some minor changes in geometry to suit a less aggressive driving style and favour ride over handling. Spindles, wheel offset and other changes were responsible for this effect. Approximately 13,140 examples were produced during 1988-1989 and were the most numerous and lightest of all Sierra Cosworth models. Specifically the LHD models which saved weight with a lesser trim level such as manual rear windows and no air conditioning. In the UK, the RHD 1988-1989 Sierra Sapphire RS Cosworth is badged as such with a small “Sapphire” badge on the rear door window trims. All 1988-1989 LHD models are badged and registered as a Sierra RS Cosworth with no Sapphire nomenclature at all. “Sapphire” being viewed as a Ghia trim level that saw power rear windows, air conditioning and other minor options. Enthusiasts of the marque are mindful of this and will describe the LHD cars by their body shell configuration, 3 door or 4 door. As the Sapphire Cosworth was based on a different shell to the original three-door Cosworth, along with its more discreet rear wing, recorded a drag co-efficient of 0.33, it registered slightly better performance figures, with a top speed of 150 mph and 0-60 of 6.1 seconds, compared to the original Cosworth. In January 1990, the third generation Sierra RS Cosworth was launched, this time with four wheel drive. As early as 1987, Mike Moreton and Ford Motorsport had been talking about a four wheel drive Sierra RS Cosworth that could make Ford competitive in the World Rally Championship. The Ferguson MT75 gearbox that was considered an essential part of the project wasn’t available until late 1989 however. Ford Motorsport’s desire for a 3-door “Motorsport Special” equivalent to the original Sierra RS Cosworth was not embraced. The more discreet 4-door version was considered to have a better market potential. It was therefore decided that the new car should be a natural development of the second generation, to be launched in conjunction with the face lift scheduled for the entire Sierra line in 1990. The waiting time gave Ford Motorsport a good opportunity to conduct extensive testing and demand improvements. One example was the return of the bonnet louvres. According to Ford’s own publicity material, 80% of the engine parts were also modified. The improved engine was designated YBJ for cars without a catalyst and YBG for cars with a catalyst. The latter had the red valve cover replaced by a green one, to emphasise the environmental friendliness. Four wheel drive and an increasing amount of equipment had raised the weight by 100 kg, and the power was therefore increased to just about compensate for this. The Sierra RS Cosworth 4×4 received, if possible, an even more flattering response than its predecessors and production continued until the end of 1992, when the Sierra was replaced by the Mondeo. The replacement for the Sierra RS Cosworth was not a Mondeo however, but the Escort RS Cosworth. This was to some extent a Sierra RS Cosworth clad in an “Escort-like” body. The car went on sale in May 1992, more than a year after the first pre-production examples were shown to the public, and was homologated for Group A rally in December, just as the Sierra RS Cosworth was retired. It continued in production until 1996. The Sierra and Sapphire Cosworths were undoubted performance bargains when new, but they also gained a reputation both for suffering a lot of accidents in the hands of the unskilled and also for being among the most frequently stole cars of their generation. These days, though, there are some lovely and treasured examples around and indeed you are far more likely to see a Cosworth version of the Sierra than one of the volume selling models, though in fact there was a late model hatch here as well.

A sporting version of Ford’s front wheel drive Escort was announced at the same time as the “cooking” 1.1, 1.,3 and 1,6 litre cars in October 1980. This was the XR3, and it came initially with a carb fed 1.6 litre engine generating 105 bhp and had a four speed gearbox. Fuel injection finally arrived in October 1982 (creating the XR3i), eight months behind the limited edition (8,659 examples), racetrack-influenced RS 1600i. The Cologne-developed RS received a more powerful engine with 115 PS, thanks to computerised ignition and a modified head as well as the fuel injection. For 1983, the XR3i was upgraded to 115bhp thanks to the use of fuel injection and a five speed transmission had been standardised. Both variants proved very popular, getting a significant percentage of Escort sales and also as a slightly more affordable alternative to a Golf GTi. For those for whom the performance was not quite enough, Ford had an answer, withe the RS Turbo. This 132 PS car was shown in October 1984, as a top of the range car, offering more power than the big-selling XR3i and the limited production RS1600i. Going on sale in the spring of 1985, it proved to be somewhat of a disappointment, with the chassis coming in for severe criticism. The RS Turbo Series 1 was only marketed in a few European nations as production was limited to 5,000 examples, all in white. They were well equipped, with the alloy wheels from the limited production RS 1600i, Recaro seats, and a limited slip differential. One car only was finished in black; it was built especially for Lady Diana. Ford facelifted the entire Escort range in January 1986, and a few months later, a revised Series 2 RS Turbo emerged, which adopted the styling changes of the less potent models, and the new dashboard, as well as undergoing a mechanical revision and the addition of more equipment including anti-lock brakes. The Series 2 cars were available in a wider range of colours.

A completely new Fiesta, codenamed BE-13 was unveiled at the end of 1988 and officially went on sale in February 1989. The car was based on a new platform ditching the old car’s rear beam axle for a semi-independent torsion beam arrangement and looked radically different, addressing the principal weakness of the previous generation – the lack of a 5-door derivative, something that was by then available in its major rivals such as the Fiat Uno, Peugeot 205 and 106 and Opel Corsa/Vauxhall Nova. The other main change was to the running gear – the improved HCS (High Compression Swirl) version of the Kent/Valencia powerplant. The CVH units from the second generation were carried over largely unmodified. The diesel engine was enlarged to a 1.8L capacity. As for sports models, the XR2i was launched in August 1989 with an eight-valve CVH (standing for “compound valve-angle hemispherical combustion chamber”) engine with 104 PS. This was the first Fiesta to have a fuel-injected engine. This was then replaced by a Zetec 16 valve version in 1992, which also saw the RS Turbo being supplanted by the RS1800 as the CVH engine was being phased out. The RS1800 shared its 1.8 litre Zetec fuel-injected engine with the 130 bhp version of the then current Ford Escort XR3i and had a top speed of 125 mph. The XR2i name was also dropped in early 1994, and the insurance-friendly “Si” badge appeared in its place on a slightly less sporty-looking model with either the 1.4 L PTE (a development of the CVH) or the 1.6 L Zetec engine. The sporting Fiesta models of this generation were not well regarded so survivors are relatively few, which means it was good to see this XR2i here.

After the universal panning received by the 1990 Escort, Ford worked hard to try to right the most serious of the wrongs. First signs of an improvement came in the autumn of 1991 when the RS2000 badge was dusted off. Using the three door body, this 150 PS car had a 16v version of the Sierra’s I4 2.0 L engine and also improved ride and handling meaning that this version of the Escort finally delivered on the road. It would be joined by less potent 1.8 litre cars with the new Zetec engine in 1992, further making the Escort if not exactly good then no longer actively unpleasant. Although the RS2000 was quite well thought of when new, few have survived.

The Ford Escort RS Cosworth is a sports derivative and rally homologation special of the fifth generation European Ford Escort. It was designed to qualify as a Group A car for the World Rally Championship, in which it competed between 1993 and 1998. It was available as a road car from 1992–96 in very limited numbers. Ford developed the car around the chassis and mechanicals of its spiritual predecessor, the Sierra Cosworth to accommodate the larger Cosworth engine and transmission, whilst clothing it in Escort body panels to make it resemble the standard car. Designed under the guidance of Rod Mansfield and John Wheeler of Ford’s SVO department, the styling was carried out during 1989, a year before the standard Escort was launched, by Stephen Harper at MGA Developments in Coventry. The spoiler was added by Frank Stephenson, who originally proposed a three-deck piece. The body tooling was created by coachbuilders Karmann at their facility in Rheine, Germany, where the cars were manufactured. Changes were made to the engine management system and a new turbocharger was fitted. Permanent four wheel drive with a 34/66% front/rear split came courtesy of an uprated five speed gearbox as used in the Sierra Cosworth. Recaro sports seats came as a standard fitment. Later production models were available without the oversize tail spoiler although by far the majority were still ordered with it. Like its Sierra predecessor, they are commonly nicknamed “Cossie” by enthusiasts. The car’s top speed was 150 mph, which rivalled lower-end supercars including the Audi Quattro, BMW M3, Nissan 300ZX and Toyota Supra, and comfortably outperformed traditional “hot hatchbacks” like the Volkswagen Golf GTI. It was much faster than the 126 mph which the Escort RS2000 and earlier Escort RS Turbo were capable of. Two versions were produced. The initial 2,500 units were “homologation specials” used to get the FIA accreditation for entry into the World Rally Championship. They were fitted with a Garrett T3/T04B turbocharger. Among these initial units, a handful were badged as Motorsport versions, these lacked certain refinements such as a sunroof and sound deadening. The initial cars included features that, although they made the Cosworth a more effective car, did not enhance it as a road vehicle, and once the rules were satisfied Ford attempted to make the car less temperamental and easier to drive under normal conditions. The second generation, starting production from late 1994, were fitted with a Garrett T25 turbocharger, a smaller unit which reduced turbo lag and increased usability in everyday driving situations. With these later models, the ‘whale tail’ spoiler became a delete option. . The Escort Cosworth was a rare car, with 7,145 vehicles produced from the start of production on 19 February 1992 until the last car rolled out of the factory on 12 January 1996.

The Ford Racing Puma was the name eventually given to Ford’s concept Puma, the Puma ST160 Concept, which was first unveiled to the public at the 1999 Geneva Motor Show. At the time, Ford were keen to stress that this was no mere styling job and the idea was to transfer the know-how and technology learned directly from Ford Puma race and rally programmes to a road car. It was created by the Ford Rally specialist team at Boreham. The strictly limited production run was initially pencilled to run for 1000 units, with 500 destined for the German market, and 500 for the UK. All conversions were carried out by Tickford, Daventry UK. In the end, only the 500 destined for the UK market were produced and sold. Less than half of the 500 cars were actually sold directly to customers, with the vehicle’s high price (£23,000 when new) often cited as a reason, as rival performance cars such as the Subaru Impreza (with an additional 50+ BHP/Turbo, four-wheel-drive and rallying pedigree) were being offered for a maximum of £21,000 with the optional Pro Drive pack. The lower than anticipated demand had Ford offering Racing Pumas to senior managers through their MRC scheme, which enabled cars to continue being registered and converted. The lack of demand when brand new has allowed it to maintain an increased value over the standard Puma due to its rarity.

Ford did not make the same mistake with the Focus as they had with its predecessor, so even the ordinary models were good to drive. There was a long wait for a truly sporting flagship, but when it arrived, in late 2002, the Focus RS proved to be rather special. Originally it was to be released as the Racing Focus, however after the poor selling Racing Puma, Ford decided to revive the RS badge. The car was largely built on its own assembly line in Ford’s Saarlouis plant, with some additional specialist off-line assembly performed by the ACÜ group at Überhern. The RS was offered all over Europe, with production limited to 4501 units. 2147 of these were sold in the United Kingdom, by far its largest of the 21 markets where it was available. The development of the Focus RS was undertaken by a mixed team of mainstream Ford engineers (not SVE or the TeamRS group which replaced it later on) and Tickford Engineering in Milton Keynes, United Kingdom. More bespoke than the prior Focus ST170, the Focus RS upgraded or replaced 70% of the standard Focus mechanicals. The turbocharged straight-4 engine produced a minimum of 212 bhp and 310 N·m (229 lb·ft) of torque, which was then mated to the 5-speed MTX-75 and not the Getrag transmission used in the ST 170. Mechanically, most notably, the car incorporated a Quaife automatic torque biasing differential to improve traction from the front-wheel drive setup. The steering used a similar quick-ratio rack as the ST170 while the brakes used fixed-caliper, four-piston Brembo units with 12.8 in discs at the front and single-piston floating calipers and 11.0 in discs at the back. Wheels were 18″ alloys specially developed by OZ Racing. The engine was heavily modified with forged aluminium pistons, hardened valve seats, sodium-filled exhaust valves, stainless steel exhaust system. The forced induction system comprised a Garrett turbocharger with a water-cooled charge air cooler and an electric water pump. To transmit the higher torque an upgraded AP clutch was used. It could generate a steady 0.98G in lateral acceleration due to racing parts such as Sachs dampers, lightweight O.Z Alloy Wheels and a Quaife ATB Differential. It would also allow 1.0G of braking force due to the standard Brembo braking system. The Focus RS was available in one metallic colour, Imperial Blue. The body looked similar to the standard Focus or to the ST170, although the RS featured unique front and rear bumper assemblies required for the wider wheel arches which accommodated the 65 mm (2.6 in) wider front track. Internally, the theme is blue and black with sections of blue leather trim on the door trim panels, the steering wheel and the Sparco seats which were trimmed in blue/black leather and Alcantara. A green starter button starts the engine. The instruments have a blue background and in place of the coolant temperature gauge, the RS was equipped with a boost pressure indicator (up to 1.5 bar). The gear lever knob, handbrake lever, and pedals were all custom made by Sparco. All-around performance was roughly equal or better to its other competitors, including hatchbacks such as the Honda Civic Type-R and some four-wheel drive cars in the same price field. Power was a diminished priority and the handling on a track, courtesy of the front differential, was considered by most observers to be its strongest characteristic. In a Top Gear review, Jeremy Clarkson noted that “it lacks the straightforward oomph of a Subaru Impreza. […] The reason it was quick round our track is simple: this car handles like it’s in a cartoon.” Clarkson and other motor journalists also commented on the car’s torque steer on bumpy British roads. Well preserved examples – and that’s not all of them, by any means, now – are worth decent money and will likely increase in value over time.

The regular second generation cars were released in late 2004. An ST version followed very quickly, and for a long time, Ford maintained that was the only sporty Focus there was going to be. Finally, on December 17, 2007 Ford of Europe confirmed that a Mk 2 Focus RS would be launched in 2009, with a concept version due in mid-2008. t with an upgraded Duratec ST engine with 305PS Duratec RS, gearbox, suspension, and LSD. In 2008, Ford revealed the new Focus RS in “concept” form at the British International Motor Show. Contrary to numerous rumours and speculation, the RS was announced by Ford to have a conventional FWD layout. The Duratec RS engine was upgraded to produce 301 bhp and 325 lb/ft of torque. 0 to 100 km/h (62 mph) acceleration was quoted to be under 6 seconds. The RS used a modified Volvo -engineered 2,522cc five-cylinder engine found in the Focus ST. A larger Borg Warner K16 turbo now delivers up to 20.3-psi of boost. A new air-to-air intercooler has been developed as a complement, while the forged crankshaft, silicon-aluminum pistons, graphite-coated cylinder bores, 8.5:1 compression ratio and variable valve timing also up the power output. The car remained front wheel drive, but to reduce torque steer used a Quaife Automatic Torque Biasing LSD, and a specially designed MacPherson strut suspension at the front called RevoKnuckle, which provided a lower scrub radius and kingpin offset than traditional designs while avoiding the increased weight and complexity of double wishbone and multi-link suspension setups. Ford UK claim: “It’s as close as you’ll come to driving a full-spec rally car (Ford Focus RS WRC). The production car was finally unveiled on 5 January 2009. It looked very distinctive, as at the rear a large venturi tunnel and a dramatic rear spoiler created a purposeful look. It was available in three expressive exterior colours: Ultimate Green, Performance Blue and Frozen White. The ‘Ultimate’ Green was a modern reinterpretation of the classic 1970s Ford Le Mans Green of the Ford Escort RS1600 era.

Ford played much the same guessing game about whether there would be an RS version of the third generation car as they had done with the earlier versions. Production of the regular cars started in late 2010, but it was not until the 2015 Geneva Motor Show before the production ready MKIII Ford Focus RS was unveiled. It came packing the turbocharged 2.3-litre inline-four engine found in the Mustang EcoBoost. In the Focus RS, the engine itself produces 350 hp. Power is sent to all four wheels via Ford’s all-new Torque-Vectoring All-Wheel-Drive system with a rear drive unit designed by GKN, as well as upgraded suspension and brakes. As well as that, the new Focus RS will be fitted with Drive Modes – including an industry-first Drift Mode that allows controlled oversteer drifts – and Launch Control. The RS will boast a model specific aerodynamic package that helps to differentiate it from other Focus models. The RS is capable of accelerating to 100 km/h (62 mph) in 4.7 seconds. Sales finally started in mid 2016, with long waiting lists having been created, though Ford did eventually catch up with expanded production levels allowing them to meet the demand. There were a number of them here, including one of the rare limited edition red-painted cars.

There were a number of examples of the first generation Mustang. Drawing on inspiration from the mid-engined Ford Mustang I concept vehicle, Lee Iacocca ordered development of a new “small car” to vice-president of design at Ford, Eugene Bordinat. Bordinat tasked Ford’s three design studios (Ford, Lincoln-Mercury, and Advanced Design) to create proposals for the new vehicle. The design teams had been given five goals for the design of the Mustang: It would seat four, have bucket seats and a floor mounted shifter, weigh no more than 2,500 pounds (1,100 kg) and be no more than 180 inches (4,572 mm) in length, sell for less than $2,500, and have multiple power, comfort, and luxury options. The Lincoln–Mercury design studio ultimately produced the winning design in the intramural contest, under Project Design Chief Joe Oros and his team of L. David Ash, Gale Halderman, and John Foster. Development of the Mustang was completed in a record 18 months from September 1962 to March 1964. and Iacocca himself championed the project as Ford Division general manager. The styling is often credited to one person, and that is not accurate, as this was very much a team effort, it has been reported by those involved. To decrease developmental costs, the Mustang used chassis, suspension, and drivetrain components derived from the Ford Falcon and Fairlane. It used a unitised platform-type frame from the 1964 Falcon, and welded box-section side rails, including welded crossmembers. Although hardtop Mustangs accounted for the highest sales, durability problems with the new frame led to the engineering of a convertible first, which ensured adequate stiffness. Overall length of the Mustang and Falcon was identical, although the Mustang’s wheelbase was slightly shorter. With an overall width of 68.2 in (1,732 mm), it was 2.4 in (61 mm) narrower, yet the wheel track was nearly identical. Shipping weight, approximately 2,570 lb (1,166 kg) with the straight six-cylinder engine, was also similar to the Falcon. A fully equipped V8 model weighed approximately 3,000 lb (1,361 kg). Although most of the mechanical parts were from the Falcon, the Mustang’s body was completely different; sporting a shorter wheelbase, wider track, lower seating position and lower overall height. An industry first, the “torque box” was an innovative structural system that greatly stiffened the Mustang’s construction and helped contribute to better handling. The car was launched in 17th April 1964, as a hardtop and a convertible, with the fastback version following in August. It was an instant sensation, with demand massively exceeding supply. Since it was introduced four months before the normal start of the 1965 production year and manufactured alongside 1964 Ford Falcons and 1964 Mercury Comets, the earliest Mustangs are widely referred to as the 1964½ model. Nevertheless, all “1964½” cars were given 1965 U.S. standard VINs at the time of production, and – with limited exception to the earliest of promotional materials – were marketed by Ford as 1965 models. The low-end model hardtop used a “U-code” 170 cu in (2.8 litre) straight-6 engine borrowed from the Falcon, as well as a three-speed manual transmission and retailed for US$2,368. Standard equipment for the early 1965 Mustangs included black front seat belts, a glove box light, and a padded dash board. Production began in March 1964 and official introduction following on April 17 at the 1964 World’s Fair. V8 models got a badge on the front fender that spelled out the engine’s cubic inch displacement (“260” or “289”) over a wide “V.” This emblem was identical to the one on the 1964 Fairlane. Several changes to the Mustang occurred at the start of the “normal” 1965 model year in August 1964, about four months after its introduction. These cars are known as “late 65’s”. The engine lineup was changed, with a 200 cu in (3.3 litre) “T-code” engine that produced 120 hp. Production of the Fairlane’s “F-code” 260 cu in (4.3 litre) engine ceased when the 1964 model year ended. It was replaced with a new 200 hp “C-code” 289 cu in (4.7 litre) engine with a two-barrel carburettor as the base V8. An “A-code” 225 hp four-barrel carburettor version was next in line, followed by the unchanged “Hi-Po” “K-code” 271 hp 289. The DC electrical generator was replaced by a new AC alternator on all Fords (a way to distinguish a 1964 from a 1965 is to see if the alternator light on the dash says “GEN” or “ALT”). The Mustang GT version was introduced as the “GT Equipment Package” and included a V8 engine (most often the 225 hp 289), grille-mounted fog lamps, rocker panel stripes, and disc brakes. In the interior the GT option added a different instrument panel that included a speedometer, fuel gauge, temp. gauge, oil pressure gauge and ammeter in five round dials (the gauges were not marked with numbers, however.) A four-barrel carburettor engine was now available with any body style. Additionally, reverse lights were an option added to the car from August 1964 production. In 1965, the Shelby Mustang was born, it was available only in newly introduced fastback body version with its swept-back rear glass and distinctive ventilation louvres. The standard interior features of the 1965 Mustang included adjustable driver and passenger bucket seats, an AM radio, and a floor mounted shifter in a variety of colour options. Ford added additional interior options during the 1965 model year. The Interior Decor Group was popularly known as “Pony Interior” due to the addition of embossed running ponies on the seat fronts, and also included integral armrests, woodgrain appliqué accents, and a round gauge cluster that would replace the standard Falcon instrumentation. Also available were sun visors, a (mechanical) remote-operated mirror, a floor console, and a bench seat. Ford later offered an under-dash air-conditioning unit, and discontinued the vinyl with cloth insert seat option, offered only in early 1965 models. One option designed strictly for fun was the Rally-Pac. Introduced in 1963 after Ford’s success at that year’s Monte Carlo Rally and available on other Ford and Mercury compacts and intermediates, the Rally-Pac was a combination clock and tachometer mounted to the steering column. It was available as a factory ordered item for US$69.30. Installed by a dealer, the Rally-Pac cost US$75.95.A 14″ rim option was available for Rally-pac and GT350R vehicles widening front and rear track to 57.5″. Reproductions are presently available from any number of Mustang restoration parts sources. A compass, rear seat belts, A/C, and back-up lights were also optional. The 1966 Mustang debuted with moderate trim changes including a new grille, side ornamentation, wheel covers and filler cap. Ford’s new C-4 “cruise-o-matic” three-speed auto transmission became available for the 225 hp V8. The 289 “HiPo” K-code engine was also offered with a c4 transmission, but it had stronger internals and can be identified by the outer casing of the servo which is marked with a ‘C’. The long duration solid-lifter camshaft that allowed the high revving 289 to make the horsepower it was known for, was not friendly for a low stall speed automatic torque converter. The “HiPo” could be spotted very easily by the 1-inch-thick vibration damper, (as compared to 1/2 inch on the 225-hp version) and the absence of a vacuum advance unit on the dual point distributor. With the valve covers off, there is a large letter “K” stamped between the valve springs, along with screw in studs (vs. a pressed in stud for other 289s) for the adjustable rocker arms. A large number of new paint and interior color options, an AM/eight-track sound system, and one of the first AM/FM mono automobile radios were also offered. It also removed the Falcon instrument cluster; the previously optional features, including the round gauges and padded sun visors, became standard equipment. The Mustang would be the best-selling convertible in 1966, with 72,119 sold, beating the number two Impala by almost 2:1. The 1965 and 1966 Mustangs are differentiated by variations in the exterior, despite similar design. These variations include the emblem on the quarter-panels behind the doors. From August 1964 production, the emblem was a single vertical piece of chrome, while for 1966 models the emblem was smaller in height and had three horizontal bars extending from the design, resembling an “E”. The front intake grilles and ornaments were also different. The 1965 front grille used a “honeycomb” pattern, while the 1966 version was a “slotted” style. While both model years used the “Horse and Corral” emblem on the grille, the 1965 had four bars extending from each side of the corral, while on the 1966, these bars were removed. The 1966 model year saw introduction of ‘High Country Special’ limited edition, 333 of them were sold in Colorado, Wyoming, and Nebraska. When Ford wanted to introduce the Mustang in Germany, they discovered that Krupp company had already registered the name for a truck. The German company offered to sell the rights for US$10,000. Ford refused and removed Mustang badges from exported units, instead naming the cars as T-5 (a pre-production Mustang project name) for the German market until 1979 when Krupp copyrights expired. In 1965, Harry Ferguson Research purchased 3 Mustang notchbacks and converted them to 4×4 in an attempt to sell potential clients on their FF AWD system. A similar system was used in the Ferguson P99 Formula One car, and would go on to be featured in the Jensen FF, widely considered the first AWD passenger car. As in the Jensen FF, the AWD Mustangs also featured an ABS braking system, long before such a feature was commonplace. Ford Australia organised the importation and conversion of 1966 Mustang to right-hand-drive for the Australian market. This coincided with the launch of new XR Falcon for 1966, which was marketed as “Mustang-bred Falcon”. To set the official conversion apart from the cottage industry, the RHD Mustangs were called “Ford Australia Delivered Mustang” and had compliance plates similar to XR Falcon. About 209 were imported to Australia with 48 units were converted in 1965 while the further 161 were done in 1966. The 1967 model year Mustang was the first redesign of the original model. Ford’s designers began drawing up a larger version even as the original was achieving sales success, and while “Iacocca later complained about the Mustang’s growth, he did oversee the redesign for 1967 .” The major mechanical feature was to allow the installation of a big-block V8 engine. The overall size, interior and cargo space were increased. Exterior trim changes included concave taillights, side scoop (1967 model) and chrome (1968 model) side ornamentation, square rear-view mirrors, and usual yearly wheel and gas cap changes. The high-performance 289 option was placed behind the newer 335 hp 6.4 litre FE engine from the Ford Thunderbird, which was equipped with a four-barrel carburettor. During the mid-1968 model year, a drag racer for the street could be ordered with the optional 428 cu in (7.0 litre) Cobra Jet engine which was officially rated at 335 hp. All of these Mustangs were issued R codes on their VIN’s. The 1967 Deluxe Interior was revised, discontinuing the embossed running horse motif on the seat backs (the source for the “pony interior” nickname) in favor of a new deluxe interior package, which included special colour options, brushed aluminium (from August 1966 production) or woodgrain dash trim, seat buttons, and special door panels. The hardtop also included upholstered quarter trim panels, a carryover from the 1965-66 deluxe interior. The 1967 hardtop also had the chrome quarter trim caps, carried over from 1965-66, but these were painted to match the interior in 1968 models. The 1967 deluxe interior included stainless steel-trimmed seat back shells, similar to those in the Thunderbird. These were dropped at the end of the 1967 model year, and were not included in the woodgrain-trimmed 1968 interior. The deluxe steering wheel, which had been included in the deluxe interior for the 1965-66, became optional, and could also be ordered with the standard interior. The 1968 models that were produced from January 1968 were also the first model year to incorporate three-point lap and shoulder belts (which had previously been optional, in 1967-68 models) as opposed to the standard lap belts. The air-conditioning option was fully integrated into the dash, the speakers and stereo were upgraded, and unique center and overhead consoles were options. The fastback model offered the option of a rear fold-down seat, and the convertible was available with folding glass windows. Gone was the Rally-Pac, since the new instrument cluster had provisions for an optional tachometer and clock. Its size and shape also precluded the installation of the accessory atop the steering column. The convenience group with four warning lights for low fuel, seat belt reminder, parking brake not released, and door ajar were added to the instrument panel, or, if one ordered the optional console and A/C, the lights were mounted on the console. Changes for the 1968 model increased safety with a two-spoke energy-absorbing steering wheel, along with newly introduced shoulder belts. Other changes included front and rear side markers, “FORD” lettering removed from hood, rearview mirror moved from frame to windscreen, a 302 cu in (4.9 litre) V8 engine was now available, and C-Stripe graphics were added. The California Special Mustang, or GT/CS, was visually based on the Shelby model and was only sold in Western states. Its sister, the ‘High Country Special’, was sold in Denver, Colorado. While the GT/CS was only available as a coupe, the ‘High Country Special’ model was available in fastback and convertible configurations during the 1966 and 1967 model years, and as a coupe for 1968. The 1968 Ford Mustang GT Fastback reached iconic status after it was featured in the 1968 film Bullitt, starring Steve McQueen. In the film, McQueen drove a modified 1968 Mustang GT 2+2 Fastback chasing a Dodge Charger through the streets of San Francisco. There were further annual updates until the model’s replacement in 1973, but with each the car got steadily bigger and less overtly sporty. Sales reduced, too, suggesting that Ford were losing their way. Mustang II did not fix that, of course, but gradually, the legendary nameplate has returned to delivering the same sort of promise as those early and much loved cars were able to do.

There were examples from all the subsequent generations of the Mustang here, too.

GINETTA

The G15 was launched in 1967. An good looking two-seater coupé, it had a glass fibre body bolted to a tube chassis with a rear mounted 875cc Imp engine, and it used Imp rear and Triumph front suspension. Over 800 were made up to 1974 and the car was fully type approved allowing, for the first time, complete Ginetta cars to be sold. Eight G15s were engineered for Volkswagen engines and called the “Super S”.

The G27, which was introduced in November 1985, was a two-seater sports car derived from the G4. It uses the front suspension from the Triumph Vitesse, a modified Jaguar independent rear suspension, and could be fitted with a wide range of engines up to the Rover V8. This design was then used for the G33’s bodywork as well.

In the early 1990s, Ginetta decided to re-enter the complete car business with the mid-engined G32 with a choice of 1.6- or 1.9-litre four-cylinder engine, available as a coupé or convertible and the G33 speedster which was equipped with a 3.9-litre Rover V8 capable of a top speed of 233 km/h (145 mph) and a 0-97 km/h acceleration time of 5 seconds. In 1990, the G32 coupé cost £13,700, the convertible £14,600, and the G33 £17,800. This is a G33.

GTM

You rarely see a GTM by itself, as these British produced kit cars only ever sold in small enough quantities that they rarely appear in normal everyday motoring. When they come to an event, such as this one, the enthusiastic Owners Club tends to bring several examples along, and that was definitely the case here. Like many low volume specialist producers, there’s quite a complex history around GTM. The firm started out creating small and relatively inexpensive kitcars in 1967, when they produced the Cox GTM, a mid-engined Mini-based machine with styling inspired by the Ferrari Dino (so it is said!). Production stopped after 5 years, and ownership of the company changed a few times over the next few years, with production of new cars, as opposed to spares, starting again in 1980, with an updated version of the GTM Coupe. The model continued to be developed and the company took advantage of the Austin-Rover K Series engine when it became available. In 1998 they launched a new car, the Libra. Three years in development, it was a collaboration between GTM Cars directors Peter Beck & Paddy Fitch, designer Richard Oakes and suspension designer Bryn Davies. Conceived as a lightweight sports car, it uses no subframes for its suspension with all the mountings being bolted straight to the GRP monocoque tub. At the front it uses unequal length wishbones of GTM design locating uprights from the Rover Metro/100 range and a forward mounted steering rack for extra legroom. The rear suspension is an unusual double trailing arm design, bolted to the rear bulkhead and using the same uprights as the front. The engine/transmission unit is held in a frame hanging off the rear bulkhead, a frame which also locates the rear hinging engine cover which incorporates a sizeable boot which can accommodate a full size set of golf clubs. The front ‘clamshell’ conceals the radiator, battery, master cylinders etc. and also manages to stow a full size spare wheel (either 16″ or 17″). A removable roof panel can be stowed behind the seats for an open top experience. Initially launched with the 1.4 litre Rover ‘K’-Series engine, the Libra has been fitted successfully with 1.6, 1.8, 1.8 VVC and KV6 2.5 litre Rover engines as well as some Honda units and the Audi 1.8 turbo engine. Production ceased in 2010, as supply of the necessary parts dried up.

HEALEY

The Donald Healey Motor Company completed its first car in 1945, going into production the following year with the Elliott sports saloon and Westland roadster, both 2.4-litre Riley powered and featuring Healey’s own trailing arm independent front suspension. For a time the Elliott was the world’s fastest closed four-seater production car, clocking 110mph at Jabbeke, Belgium in 1947. In 1950 the duo were superseded by the Tickford saloon and Abbott drophead coupe, both of which enjoyed an improved chassis incorporating Girling brakes. They were more refined and better equipped than their predecessors too and, although heavier, still good for the ‘ton’. Only 222 had been built before production ceased in 1954.

This is a Healey Silverstone, an open two-seater road / racing sports car, which had headlights behind the grille to make it more aerodynamic. It was designed to be a dual purpose “race and ride” car. It also had a 104-horsepower 2.5-litre Riley I-4 engine and four speed manual transmission. The Silverstone was hand-built at Healey’s Warwick factory and just 105 were produced. Healey was producing a range of expensive cars in small quantities at the time and when the British government doubled the purchase tax on (luxury) cars over £1000 from 33.33% to 66.66% in 1948, Healey realised his business would be in trouble, so he decided to make a high performance car that was under £1000. The result was the Healey Silverstone. The car had a very successful competition history when new. Production ended in September 1950 when it was replaced by the Nash-Healey.

HILLMAN

Sitting below the Hunter in the Hillman range of the 1970s was the Avenger, a conventionally engineered small saloon that competed with the Ford Escort and Vauxhall Viva. 1250 and 1500cc models from launch were upgraded to 1300 and 1600cc in the autumn of 1973 and these garnered the majority of sales, but they are not the cars that have survived in the greatest numbers. The ones that you most often see now are the Tiger models. Named to evoke memories of the Sunbeam Tiger, the Avenger Tiger concept began as a publicity exercise. Avenger Super (four-door) cars were modified by the Chrysler Competitions Centre under Des O’ Dell and the Tiger model was launched in March 1972. Modifications included the 1500 GT engine with an improved cylinder head with enlarged valves, twin Weber carburettors and a compression ratio of 9.4:1. The engine now developed 92.5 bhp at 6,100 rpm. The suspension was also uprated, whilst brakes, rear axle, and gearbox are directly from the GT. The cars were all painted in a distinctive yellow called Sundance and they featured a bonnet bulge, whilst a rear spoiler and side stripes were standard, set off with “Avenger Tiger” lettering on the rear quarters. They are also distinguished by the fact that have rectangular headlights. Road test figures demonstrated a 0–60 mph time of 8.9 seconds and a top speed of 108 mph, which beat the rival Ford Escort Mexico, but fuel consumption was heavy. All Avenger Tigers were assembled by the Chrysler Competitions Centre and production figures are vague but around 200 of the initial Mark 1 seems likely. In October 1972, Chrysler unveiled the more “productionised” Mark 2 Tiger. The Avenger GL bodyshell with four round headlights was used. Mechanically identical to the earlier cars, the bonnet bulge was lost although the bonnet turned matt black, and there were changes to wheels and seats. These cars went on sale at £1,350. Production was around 400. These were available in a bright red colour called Wardance as well as the earlier Sundance, both with black detailing.

HONDA

It is more than a quarter of a century since Honda stunned the world with a true Ferrari-beater. Its origins go back all the way to 1984, when Honda commissioned the Italian car designer Pininfarina to design the HP-X (Honda Pininfarina eXperimental), which had a mid-mounted C20A 2.0 L V6 configuration. After Honda committed to the project, management informed the engineers that the new car would have to be as fast as anything coming from Italy and Germany .The HP-X concept car evolved into a prototype called the NS-X, which stood for “New”, “Sportscar” and “eXperimental”. The NS-X prototype and eventual production model were designed by a team led by Chief Designer Ken Okuyama and Executive Chief Engineer Shigeru Uehara, who subsequently were placed in charge of the S2000 project. The original performance target for the NS-X was the Ferrari 328, and later the 348 as the design neared completion. Honda intended the NS-X to meet or exceed the performance of the Ferrari, while offering targeted reliability and a lower price point. For this reason, the 2.0L V6 of the HP-X was abandoned and replaced with a more powerful 3.0L VTEC V6 engine. The bodywork design had been specifically researched by Okuyama and Uehara after studying the 360 degree visibility inside an F-16 fighter jet cockpit. Thematically the F-16 came into play in the exterior design as well as establishing the conceptual goals of the NSX. In the F-16 and other high performance craft such as unlimited hydroplanes, single seat race cars etc. the cockpit is located far forward on the body and in front of the power plant. This “cab-forward” layout was chosen early in the NSX’s design to optimise visibility while the long tail design enhanced high speed directional stability. The NS-X was designed to showcase several Honda automotive technologies, many derived from its F1 motor-sports program. The NS-X was the first production car to feature an all-aluminium monocoque body, incorporating a revolutionary extruded aluminium alloy frame, and suspension. The use of aluminium in the body alone saved nearly 200 kg in weight over the steel equivalent, while the aluminium suspension saved an additional 20 kg; a suspension compliance pivot helped maintain wheel alignment changes at a near zero value. Other notable features included an independent, 4-channel anti-lock brake system; titanium connecting rods in the engine to permit reliable high-rpm operation; an electric power steering system; Honda’s proprietary VTEC variable valve timing system (a first in the US) and, in 1995, the first electronic throttle control fitted to a Honda. With a robust motorsports division, Honda had significant development resources at its disposal and made extensive use of them. Respected Japanese Formula One driver Satoru Nakajima, for example, was involved with Honda in the NS-X’s early on track development at Suzuka race circuit, where he performed many endurance distance duties related to chassis tuning. Brazilian Formula One World Champion Ayrton Senna, for whom Honda had powered all three of his world championship-winning Formula One race cars before his death in 1994, was considered Honda’s main innovator in convincing the company to stiffen the NSX chassis further after initially testing the car at Honda’s Suzuka GP circuit in Japan. Senna further helped refine the original NSX’s suspension tuning and handling spending a whole day test driving prototypes and reporting his findings to Honda engineers after each of the day’s five testing sessions. Senna also tested the NSX at the Nurburgring and other tracks. The suspension development program was far-ranging and took place at the Tochigi Proving Grounds, the Suzuka circuit, the 179-turn Nurburgring Course in Germany, HPCC, and Hondas newest test track in Takasu, Hokkaido. Honda automobile dealer Bobby Rahal (two-time CART PPG Cup and 1986 Indianapolis 500 champion) also participated in the car’s development. The production car made its first public appearances as the NS-X at the Chicago Auto Show in February 1989, and at the Tokyo Motor Show in October 1989 to positive reviews. Honda revised the vehicle’s name from NS-X to NSX before final production and sale. The NSX went on sale in Japan in 1990 at Honda Verno dealership sales channels, supplanting the Honda Prelude as the flagship model. The NSX was marketed under Honda’s flagship Acura luxury brand starting in 1991 in North America and Hong Kong. It sent shockwaves through the industry, as the car was considerably better than the Ferrari 348 in just about every respect. But that was not the end of the story, of course. While the NSX always was intended to be a world-class sports car, engineers had made some compromises in order to strike a suitable balance between raw performance and daily driveability. For those NSX customers seeking a no-compromise racing experience, Honda decided in 1992 to produce a version of the NSX specifically modified for superior on-track performance at the expense of customary creature comforts. Thus, the NSX Type R (or NSX-R) was born. Honda chose to use its moniker of Type R to designate the NSX-R’s race-oriented design. In 1995, a Targa model was released, the NSX-T, which allowed customers to experience fresh air thanks to two removable targa top panels. The original NSX body design received only minor modifications from Honda in the new millennium when in 2002 the original pop-up headlamps were replaced with fixed xenon HID headlamp units. There was a really impressive collection of the model here, with examples showing the evolution of the car from the original to the later ones with fixed lights.

Also here was a example of the second generation model.

There was also a large number of examples here of the S2000, the much missed sports car that Honda produced to mark their 50th anniversary. The S2000 was first alluded to at the 1995 Tokyo Motor Show, with the Honda Sport Study Model (SSM) concept car, a rear-wheel-drive roadster powered by a 2.0 litre inline 4-cylinder engine and featuring a rigid ‘high X-bone frame’ which Honda claimed improved the vehicle’s rigidity and collision safety. The concept car was constructed with aluminium body panels and featured a 50:50 weight distribution. The SSM appeared at many automotive shows for several years afterwards, hinting at the possibility of a production version, which Honda finally announced in 1999. It featured a front mid-engine, rear-wheel-drive layout with power being delivered by a 1,997 cc inline 4-cylinder DOHC-VTEC engine. The engine produced outputs of 237–247 hp, and 153–161 lb/ft depending on the target market., and it was mated to a six-speed manual transmission and Torsen limited slip differential. The S2000 achieved what Honda claimed as “the world’s top level, high performance 4-cylinder naturally aspirated engine”. Features included independent double wishbone suspension, electrically assisted steering and integrated roll hoops. The compact and lightweight engine, mounted entirely behind the front axle, allowed the S2000 to achieve a 50:50 front/rear weight distribution and lower rotational inertia. An electrically powered vinyl top with internal cloth lining was standard, with an aluminium hardtop available as an optional extra. Although the S2000 changed little visually during its production run, there were some alterations, especially in 2004, at which point production of the S2000 moved to Suzuka. The facelifted car introduced 17 in wheels and Bridgestone RE-050 tyres along with a retuned suspension to reduce oversteer. The spring rates and shock absorber damping were altered and the suspension geometry modified to improve stability by reducing toe-in changes under cornering loads. The subframe has also received a revision in design to achieve a high rigidity. In the gearbox the brass synchronisers were replaced with carbon fibre. In addition, cosmetic changes were made to the exterior with new front and rear bumpers, revised headlight assemblies, new LED tail-lights, and oval-tipped exhausts. Although all the cosmetic, suspension and most drivetrain upgrades were included on the Japanese and European S2000s, they retained the 2.0l F20C engine and remained designated as an AP1. A number of special editions were made, such as the more track-oriented Club Racer version offered in the US in 2007/8 and the Type S for Japan in 2008/9. The UK received a GT for 2009, which featured a removable hard-top and an outside temperature gauge. The S2000 Ultimate Edition (continental Europe) and GT Edition 100 (UK) were limited versions of the S2000 released to commemorate the end of production. Both included Grand Prix White body colour, removable hard top, graphite-coloured alloy wheels, red leather interior with red colouring for stitching on the gear lever gaiter. The Ultimate Edition was unveiled at the 2009 Geneva Motor Show and went on sale in March 2009. The GT Edition 100 was a limited run of 100 units released for the UK market. In addition to the Ultimate Edition’s specification, it featured a black S2000 badge and a numbered plaque on the kick-plate indicating which vehicle in the series it was. The car was never replaced, as Honda decided to head off in the same direction as Toyota, producing a series of very dull appliance-like cars that focused on low emissions and dependability but of no appeal to the sort of enthusiast who bought (and probably kept!) an S2000.

JAGUAR

Oldest Jaguar model type here was the SS100, along with a number of modern recreations. The first of William Lyons’ open two-seater sports cars came in March 1935 with the SS 90, so called because of its claimed 90 mph top speed. This car used the 2½-litre side-valve, six-cylinder engine in a short-chassis “cut and shut” SS 1 brought down to an SS 2’s wheelbase. Just 23 were made. It was the precursor to one of the finest pre-war sports car ever made, the SS100. That car benefitted from some significant engine development work that was led by Harry Westlake, who was asked to redesign the 2½-litre 70 bhp side-valve engine to achieve 90 bhp. His answer was an overhead-valve design that produced 102 bhp and it was this engine that launched the new SS Jaguar sports and saloon cars in 1936. Shown first in the SS Jaguar 2½-litre saloon, the new car caused a sensation when it was launched at a trade luncheon for dealers and press at London’s Mayfair Hotel on 21 September 1935. The show car was in fact a prototype. Luncheon guests were asked to write down the UK price for which they thought the car would be sold and the average of their answers was £765. Even in that deflationary period, the actual price at just £395 would have been a pleasant surprise for many customers, something which characterised Jaguars for many decades to come. Whilst the new Jaguar saloon could now compete with the brand new MG SA, it was the next application of the engine that stunned everyone even more, with the launch of the legendary SS100. Named because it was a genuine 100 mph car, this open topped sports car looked as good as it was to drive. Only 198 of the 2½-litre and 116 of the 3½-litre models were made and survivors are highly prized and priced on the rare occasions when they come on the market. Such is their desirability that a number of replica models have been made over the years, with those made by Suffolk Engineering being perhaps the best known, and which are indeed hard to tell apart from an original 1930s car at a glance.

The display included these C and D Type cars, all of which were actually recreations rather than examples of the real thing made in the 50s.

Jaguar stunned the world with the XK120 that was the star of the Earls Court Motor Show in 1948. Seen in open two seater form, the car was a testbed and show car for the new Jaguar XK engine. The display car was the first prototype, chassis number 670001. It looked almost identical to the production cars except that the straight outer pillars of its windscreen would be curved on the production version. The roadster caused a sensation, which persuaded Jaguar founder and design boss William Lyons to put it into production. Beginning in 1948, the first 242 cars wore wood-framed open 2-seater bodies with aluminium panels. Production switched to the 112 lb heavier all-steel in early 1950. The “120” in the name referred to the aluminium car’s 120 mph top speed, which was faster with the windscreen removed. This made it the world’s fastest production car at the time of its launch. Indeed, on 30 May 1949, on the empty Ostend-Jabbeke motorway in Belgium, a prototype XK120 timed by the officials of the Royal Automobile Club of Belgium achieved an average of runs in opposing directions of 132.6 mph with the windscreen replaced by just one small aeroscreen and a catalogued alternative top gear ratio, and 135 mph with a passenger-side tonneau cover in place. In 1950 and 1951, at a banked oval track in France, XK120 roadsters averaged over 100 mph for 24 hours and over 130 mph for an hour, and in 1952 a fixed-head coupé took numerous world records for speed and distance when it averaged 100 mph for a week. Roadsters were also successful in racing and rallying. The first production roadster, chassis number 670003, was delivered to Clark Gable in 1949. The XK120 was ultimately available in two open versions, first as an open 2-seater described in the US market as the roadster (and designated OTS, for open two-seater, in America), and from 1953 as a drophead coupé (DHC); as well as a closed, or fixed head coupé (FHC) from 1951. A smaller-engined version with 2-litres and 4 cylinders, intended for the UK market, was cancelled prior to production.

The XK140, was the successor to the XK120, with a number of useful changes and upgrades over the earlier car which included more interior space, improved brakes, rack and pinion steering, increased suspension travel, and telescopic shock absorbers instead of the older lever arm design. The XK140 was introduced in late 1954 and sold as a 1955 model. Exterior changes that distinguished it from the XK120 included more substantial front and rear bumpers with overriders, and flashing turn signals (operated by a switch on the dash) above the front bumper. The grille remained the same size but became a one-piece cast unit with fewer, and broader, vertical bar, making it easy to tell an XK140 apart from an XK120. The Jaguar badge was incorporated into the grille surround. A chrome trim strip ran along the centre of the bonnet and boot lid. An emblem on the boot lid contained the words “Winner Le Mans 1951–3”. The interior was made more comfortable for taller drivers by moving the engine, firewall and dash forward to give 3 inches more legroom. Two 6-volt batteries, one in each front wing were fitted to the Fixed Head Coupe, but Drop Heads and the Open Two Seater had a single 12-volt battery. This was installed in the front wing on the passenger side (e.g. In the left wing on right hand drive cars and in the right wing on left hand drive). The XK140 was powered by the Jaguar XK engine with the Special Equipment modifications from the XK120, which raised the specified power by 10 bhp to 190 bhp gross at 5500 rpm, as standard. The C-Type cylinder head, carried over from the XK120 catalogue, and producing 210 bhp ross at 5750 rpm, was optional equipment. When fitted with the C-type head, 2-inch sand-cast H8 carburettors, heavier torsion bars and twin exhaust pipes, the car was designated XK140 SE in the UK and XK140 MC in North America. In 1956 the XK140 became the first Jaguar sports car to be offered with automatic transmission. As with the XK120, wire wheels and dual exhausts were options, and most XK140s imported into the United States had wire wheels. Cars with the standard disc wheels had spats (fender skirts) over the rear wheel opening. When leaving the factory it originally fitted either 6.00 × 16 inch crossply tyres or you could specify 185VR16 Pirelli Cinturato CA67 as a radial option on either 16 × 5K½ solid wheels or 16 × 5K (special equipment) wire wheels. The Roadster (designated OTS – Open Two Seater – in America) had a light canvas top that folded out of sight behind the seats. The interior was trimmed in leather and leatherette, including the dash. Like the XK120 Roadster, the XK140 version had removable canvas and plastic side curtains on light alloy barchetta-type doors, and a tonneau cover. The door tops and scuttle panel were cut back by two inches compared to the XK120, to allow a more modern positioning of the steering wheel. The angle of the front face of the doors (A-Post) was changed from 45 degrees to 90 degrees, to make access easier. The Drophead Coupé (DHC) had a bulkier lined canvas top that lowered onto the body behind the seats, a fixed windscreen integral with the body (the Roadster’s screen was removable), wind-up side windows, and a small rear seat. It also had a walnut-veneered dashboard and door cappings. The Fixed Head Coupé (FHC) shared the DHC’s interior trim and rear seat. The prototype Fixed Head Coupe retained the XK120 Fixed Head roof-profile, with the front wings and doors the same as the Drophead. In production, the roof was lengthened with the screen being placed further forward, shorter front wings, and longer doors. This resulted in more interior space, and more legroom. The XK140 was replaced by the XK150 in March 1957.

Although bearing a family resemblance to the earlier XK120 and XK140, the XK150, launched in the spring of 1957, was radically revised. A one-piece windscreen replaced the split screen, and the wing line no longer dropped so deeply at the doors. The widened bonnet opened down to the wings, and on the Roadster the windscreen frame was moved back 4 inches to make the bonnet longer. The XK140’s walnut dashboard was replaced by one trimmed in leather. On the early Drophead Coupés, the aluminium centre dash panel, which was discontinued after June 1958, had an X pattern engraving similar to the early 3.8 E-Type. Thinner doors gave more interior space. On the front parking lights, which were located atop the wings, a little red light reminded the driver the lights were on. Suspension and chassis were very similar to the XK140, and steering was by rack and pinion; power steering was not offered. The standard engine, the similar to the XK140, but with an new “B” type cylinder head, was the 3.4 litre DOHC Jaguar straight-6 rated at 180 SAE bhp at 5750 rpm but most cars were fitted with the SE engine whose modified cylinder head (B type) and larger exhaust valves boosted the power to 210 SAE bhp at 5500 rpm. Twin 1.75-inch (44 mm) SU HD6 carburettors were fitted. While the first XK150s were slower than their predecessors, the deficit was corrected in the spring of 1958 with a 3.4-litre “S” engine whose three 2-inch SU HD8 carburettors and straight-port cylinder head increased power to a claimed 250 SAE bhp. For 1960, the 3.4 litre engine was bored to 3.8 litres, rating this option at 220 hp in standard tune or 265 hp in “S” form. A 3.8 litre 150S could top 135 mph and go from 0–60 mph in around 7.0 seconds. Fuel economy was 18mpg. Four-wheel Dunlop 12 in disc brakes appeared for the first time although it was theoretically possible to order a car with drums. When leaving the factory the car originally fitted either 6.00 × 16 inch Dunlop Road Speed tyres as standard, or you could specify 185VR16 Pirelli Cinturato CA67 as a radial option on either 16 × 5K½ solid wheels (basic models) or 16 × 5K wire wheels. Production ended in October 1960, and totalled 2265 Roadsters, 4445 Fixed Head Coupés and 2672 Drophead Coupés.

Replacement for the XK models came in 1961 with the E Type, and it stunned the world at its premier at the 1961 Geneva Show. Considered by many to be Sir William Lyons’ greatest achievement, not only did the car have stop-you-in-your-tracks gorgeous styling, but it had explosive performance (even if the 150 mph that was achieved in The Autocar’s Road Test is now known to have been with a little “help”), but it was the price that amazed people more than anything else. Whilst out of reach for most people, who could barely afford any new car, it was massively cheaper than contemporary Aston Martins and Ferraris, its market rivals. It was not perfect, though, and over the coming years, Jaguar made constant improvements. A 2+2 model joined the initial range of Roadster and Coupe, and more powerful and larger engines came when the 3.8 litre was enlarged to 4.2 litres, before more significant styling changes came with the 1967 Series 2 and the 1971 Series 3, where new front end treatments and lights were a consequence of legislative demands of the E Type’s most important market, America. There were examples of all three Series here.

One of the most loved Jaguars of all time, both when it was new, and still now, is the Mark 2 saloon. Many will tell you that it is not the 3 Series BMW that “invented” the “compact sports saloon” car class, but this model, which dates back to 1959. A thorough revision of the small Jaguar saloon that had joined the range in 1955, the Mark 2 was notable in that it was the first car to use the Arabic numeral in its name, as opposed to the Roman numerals of the larger Jaguar models. At launch, the earlier model which had hitherto been known by its engine size was christened the Mark 1. Although clearly based on that car, the updated car looked significantly different, with an increase of 18% in cabin glass area greatly improving visibility. The car was re-engineered above the waistline. Slender front pillars allowed a wider windscreen and the rear window almost wrapped around to the enlarged side windows now with the familiar Jaguar D-shape above the back door and fully chromed frames for all the side windows. The radiator grille was amended and larger side, tail and fog lamps repositioned. Inside a new heating system was fitted and ducted to the rear compartment (although still notoriously ineffective). There was an improved instrument layout that became standard for all Jaguar cars until the XJ Series II of 1973. As well as the familiar 2.4 and 3.4 litre engines, what made this car particularly special was that it was also offered with the potent 220 bhp 3.8 litre unit that was fitted to the XK150 and which would later see service in the E Type. This gave the car a 0 – 60 time of around 8.5 seconds and a top speed of 125 mph. No wonder that the Mark 2 became popular as a get-away car for the criminal fraternity, and to keep up with and catch them, many police forces bought the car as well. With revised suspension and standard four wheel disc brakes, the car was effective on the track, taking plenty of class wins when new, and it is still popular in historic racing circles today. The quickest and most successful private entries came from John Coombs, a man with significant race experience who operated a large Jaguar dealership in Guildford. Coombs would undertake modifications to meet the demands of his customers, so not all the cars that he worked on are the same. Jaguar replaced the Mark 2 with simplified and slightly more cheaply finished 240 and 340 models, as an interim measure until an all-new model was ready to take over from them. The 3.8 litre disappeared from the range at this time, but in the 7 years it had been in production, it had been the best seller of the range, with around 30,000 cars produced, as compared to 28,666 of the 3.4 litre and 25,741 of the 2.4 litre model.

When the time came to replace the Mark IX, Jaguar adopted a completely new look, with the resulting car, unsurprisingly called the Mark X, being notably larger. Indeed its bulk, especially the width, came to characterise the car, and constituted one of the obstacles to sales in Europe, though this was less of a handicap for the American market, for whom it had been designed. The first three years production used the familiar 3.8 litre XK engine, and this was enlarged to 4.2 litre in 1964 in line with the E Type. The Mark X was the first Jaguar to feature fully independent rear suspension and the last to feature an interior with abundant standard woodwork, including the dashboard, escutcheons, window trim, a pair of large bookmatched fold out rear picnic tables, and a front seat pull-out picnic table stowed beneath the instrument cluster. Later, air conditioning and a sound-proof glass division between the front and rear seats were added as options. For the London Motor Show in October 1966 the Mark X was renamed the Jaguar 420G (not to be confused with the smaller Jaguar 420, which was an update of the smaller S Type). The 420G differed visually from the Mark X only with the addition of a vertical central bar splitting the grille in two, side indicator repeaters on the front wings, and a chrome strip along the wing and door panels (two tone paint schemes were also available with the chrome strip omitted). Interior changes included perforations in the central sections of the leather seats, padded dashboard sections for safety, moving the clock to a central position, and the introduction of air conditioning as an option. A “limousine” version was available, on the standard wheelbase, with a dividing glass screen partition and front bench seat replacing the separate seats of standard cars. The wheelbase was extended by 21″ with the mechanical underpinnings of the car being subtly re-bodied for the 1968 Daimler DS420. Despite running for the same length of time as the Mark X (5 years) the 420G sold in less than a third of the numbers: this lack of popularity and the increasing production of the XJ6 resulted in the 420G being run out of production in 1970. Whilst over 18,500 of the Mark X were made, just 5,763 of the 420G were made

By the mid 60s, the Jaguar range was quite complicated, with several different models, all looking quite similar, and owing their origins to the Mark 2 of 1959. The situation was not eased with the launch of the 420 at the October 1966 London Motor Show. This was produced for two years, and was the ultimate expression of a series of “compact sporting saloons” which included the Mark 2 (which morphed into the 240 and 340) and the S Type, all of which shared the same wheelbase. Developed from the Jaguar S-Type, the 420 cost around £200 more than that model and effectively ended buyer interest in it, although the S-Type continued to be sold alongside the 420/Sovereign until both were supplanted by the Jaguar XJ6 late in 1968. 10,236 of the 420 were sold over that two year period.

Although some of the older cars lived for a few months more, whilst production ramped up, the Jaguar XJ6 and Daimler Sovereign cars that were launched in 1968 were intended to replace all the saloon cars. Offered initially with a choice of 2.8 and 4.2 litre XK engines, these cars wowed the press and the public just as much as many of their predecessors had done, both for their excellence and the fact that they were priced well below their competitors. It was not long before there was a long waiting list. As if this was not enough, the new V12 engine which had first been seen in the Series 3 Jaguar E Type was slotted under the bonnet of the cars in Spring 1972, creating one of the fastest and most refined saloons available in the world. At the time, the fact that it would only average around 11 mpg was not an issue, but within 18 months, and the onset of the Yom Kippur war and the resultant fuel crisis of late 1973, suddenly these cars – desirable as they were – became rather harder to sell. A Series 2 model was launched in the autumn of 1973, with new front end styling and bumper height set to meet the requirements of the critical US market.

Successor to the E Type was the XJ-S, launched in September 1975, and to a not universally approving public. This was a very different sort of sporting Jaguar, more boulevard cruiser than sports car, even though the car had plenty of appeal with its smooth V12 engine which gave it genuine 150 mph performance. Press reports were favourable, but a thirsty V12 and a car with inconsistent build quality and styling that not everyone warmed to meant that sales were slow, and they got slower as the decade passed, leading questions to be asked as to whether the car should continue. As well as sorting the saloon models, Jaguar’s Chairman, John Egan, put in place a program to improve the XJ-S as well, which also benefitted from the HE engine in early 1981. A Cabrio model and the option of the new 3.6 litre 6 cylinder engine from 1984 widened the sales appeal, and the volumes of cars being bought started to go up. A fully open Convertible, launched in 1988 was the model many had been waiting for, and by this time, although the design was over 10 years old, it was now brimming with appeal to many. 1991 saw an extensive facelift which changed the styling details as well as incorporating the latest mechanical changes from the Jaguar parts bin, making the XJS (the hyphen had been dropped from the name in 1990) a truly desirable car. Seen here were both pre- and post-facelift models as well as one of the rare TWR-converted XJR-S cars. These were made between 1988 and 1993 by the newly formed JaguarSport, a separate company owned in a ratio of 50:50 by Jaguar and TWR Group Limited specialising in developing high performance Jaguar sports cars. The car had a distinctive body kit, special alloy wheels, a unique suspension system utilising modified coil springs and Bilstein shocks, a luxurious interior with Connolly Autolux leather along with walnut wood trim, and handling improvements. The first 100 of these cars were named “Celebration Le Mans” to commemorate Jaguar’s 1988 win at the 24 Hours of Le Mans and were only sold in the UK. Between 1988 and 1989, a total of 326 XJR-S cars were produced with the 5.3 litres engine with a power output of 318 bhp. After September 1989, the displacement of the engine was increased to 5,993 cc and it was now equipped with Zytek fuel injection and engine management system. This was different from the standard 6.0-litre engine used in the late XJS models and was unique to this model. The power output was raised to 334 bhp at 5,250 rpm and 495 Nm (365 lb/ft) of torque at 3,650 rpm due to a higher compression ratio of 11.0:1, a new forgedsteel crankshaft, increased bore and forged alloy pistons. A modified air intake system and a low loss dual exhaust system was also standard on the model. The engine was mated to the 3-speed GM400 automatic transmission utilising a recalibrated valve body and had faster shift times. The car was equipped with Dunlop D40 M2 tyres for better grip. These modifications resulted in a top speed of 260 km/h (160 mph). A total of 787 coupés and 50 convertible XJR-S were built for the world market.

In 1986, a newly formed Lister Cars under the leadership of engineer Laurence Pearce began offering a high performance package for the Jaguar XJS. The cars were sold as Lister-Jaguar and 90 customer cars in total were converted. Lister teamed up with two manufacturers namely WP Automotive and BLE Automotive to carry out the conversion process. The standard package included increased engine displacement to 7.0-litres, a modified fuel injection system with four additional injectors and throttle bodies, larger engine valves along with connecting rods manufactured by Cosworth, a new crankshaft, new cylinder heads, new inlet and exhaust valves, new bearing caps, and a new body kit featuring a spoiler at the rear with a modified rear light clusters and flared wheel arches to accommodate the wide tyres. The modified suspension system featured Koni dampers having 30% stiffer rebound than the original and having a modified rear subframe arrangement with wishbones and radius arms relocated to provide greater triangulation and reduce axle tramp. The new shocks were 100% stiff at the front and 50% stiff at the rear. The braking system had ventilated brake discs and were moved outward for better cooling and stability. The interior was also modified and now had Recaro racing bucket seats and a new steering wheel with optimised feedback. The modified engine was rated at 496 hp and 678 Nm (500 lb⋅ft) of torque. The engine was mated to a 5-speed Getrag manual transmission. The cars were fitted with 17-inch wheels with wide Pirelli tyres measuring 10-inch at the front and 13-inch at the rear. Performance figures include a 0-60 mph acceleration time of 4.5 seconds and a top speed of 322 km/h (200 mph). Some customers further got their cars modified with the addition of the LeMans package. The package included a 6-speed Getrag manual transmission, a new exhaust system and twin-superchargers over the standard package applied in order to extract a power output of 603 bhp from the engine.

 

Throughout the 1970s Jaguar had been developing “Project XJ40”, which was an all-new model intended to replace the original XJ6. Scale models were being built as early as 1972. Due to the 1973 oil crisis and problems at parent company British Leyland, the car was continually delayed. Proposals from both Jaguar’s in-house designers and Pininfarina were received. Eventually, it was decided an internal design would be carried through to production and, in February 1981, the British Leyland board approved £80 million to produce the new car. Launch was originally scheduled for 1984, but following Jaguar’s de-merger from BL and privatisation that same year, the company’s CEO Sir John Egan took advantage of the resurgence in sales of the existing Series III XJ6 (particularly in the lucrative North American market) to delay the XJ40’s launch a further two years to allow for more development time. The XJ40 was at the time, the most extensively tested vehicle the company had ever developed. Designs for the XJ40 pioneered significant improvements to how Jaguar cars were designed, built, and assembled. Among these improvements was a 25% reduction in the number of bodywork panels required per car (e.g. three pressings needed for a Series 3 door compared with one for a XJ40 door), resulting in not only a more efficient assembly process, but also a weight saving and a stiffer structure. Initially, only two engines were offered across the XJ40 models: a 2.9 L and a 3.6 L version of the AJ6 inline-six. In 1990 the 3.6 L was replaced by a 4.0 L model and in 1991 the 2.9 L was replaced by a 3.2 L model. During the development of the XJ40, British Leyland had considered providing the Rover V8 engine for the car, which would have eliminated the need for future Jaguar engine production. The XJ40 bodyshell was allegedly engineered to prevent fitting V-configuration engines – in particular the Rover V8 – which British Leyland management had desired; this delayed the introduction of the V12-powered XJ12 until 1993 as the front structure of the XJ40 had to be extensively redesigned. As a consequence, the preceeding Series III XJ was kept in production in V12 form to cater for this market need until 1992. The automatic gearbox used in the 2.9 L, 3.2 L and 3.6 L six-cylinder cars was the four-speed ZF 4HP22. On the 4.0 L, the four-speed ZF 4HP24 was used. A stronger automatic gearbox was required for the V12-equipped cars, and the four-speed GM 4L80-E was selected. The manual gearbox fitted to early cars was the five-speed Getrag 265, while later cars received the Getrag 290. The automatic transmission selector was redesigned to allow the manual selection of forward gears without accidentally selecting neutral or reverse. This new feature was dubbed the “J-Gate” and remained a staple of all Jaguar models up until the 2008 Jaguar XF, when shift by wire technology rendered it redundant – all subsequent Jaguar models now use a rotary knob for transmission mode selection. The base XJ6 of the model range was modestly equipped; extra-cost options included alloy wheels, anti-lock brakes, air conditioning, leather upholstery, and an automatic transmission. The exterior featured two pairs of circular headlamps and black powder-coated window frames. The Sovereign model came equipped with significantly more features than the base XJ6. Included was air conditioning, headlamp washers, a six-speaker sound system, rear self-levelling suspension (SLS), anti-lock braking system, and inlaid burl walnut wood trim (pre-MY1991). The headlamps fitted were the rectangular single units. The window frames were made from stainless steel. Further variants would follow, before the car’s replacement in 1994.

The “X300” model was the first XJ produced entirely under Ford ownership, and can be considered an evolution of the outgoing XJ40 generation. Like all previous XJ generations, it featured the Jaguar independent rear suspension arrangement. The design of the X300 placed emphasis on improved build quality, improved reliability, and a return to traditional Jaguar styling elements. At the car’s launch in October 1994 at the Paris Motor Show, Jaguar marketing material made use of the phrase “New Series XJ” to describe the X300 models. The X300 series represented the result of a £200 million facilities renewal program by Ford. which included the introduction of state-of-the-art automated body welding robots manufactured by Nissan. Aesthetically, the X300 received several updates in the design refresh led by Geoff Lawson in 1991. The mostly flat bonnet of the XJ40 was replaced with a fluted, curvaceous design that accentuated the four separate round headlamps. Rear wings were reshaped to accommodate the new wrap-around rear light clusters. Also, the separate black-rubber bumper bar of the XJ40 were replaced with a fully integrated body-coloured bumper. The interior of the X300 was similar to that found in the XJ40, with some revisions. The seats were updated to have a more rounded profile, wood trim was updated with bevelled edges, and the steering wheel was redesigned. Jaguar’s V12 engine and AJ6 inline-six (AJ16) engine were both available in various X300 models, although they received significant updates. Both engines were fitted with distributorless electronic engine management systems. The Jaguar X308 first appeared in 1997 and was produced until 2003. It was an evolution of the outgoing X300 platform, and the exterior styling is nearly identical between the two generations, though there are quite a few detailed differences if you know what to look for. The major change was the under the bonnet. Having discontinued production of both the AJ16 inline-six and V12 engines, Jaguar offered only its newly designed V8 engine (named the AJ-V8.) It was available in either 3.2 or 4.0 litre forms, although certain markets, such as the United States, only received cars powered by the 4.0 litre version. The 4.0 litre version was also supercharged in certain models. Equipment levels were notably more generous than had previously been the case.

As is well known, the XJ220 was developed from a V12-engined 4-wheel drive concept car designed by an informal group of Jaguar employees working in their spare time. The group wished to create a modern version of the successful Jaguar 24 Hours of Le Mans racing cars of the 1950s and ’60s that could be entered into FIA Group B competitions. The XJ220 made use of engineering work undertaken for Jaguar’s then current racing car family. The initial XJ220 concept car was unveiled to the public at the 1988 British International Motor Show. Its positive reception prompted Jaguar to put the car into production; some 1500 deposits of £50,000 each were taken, and deliveries were planned for 1992. Engineering requirements resulted in significant changes to the specification of the XJ220, most notably replacement of the Jaguar V12 engine by a turbocharged V6 engine. The changes to the specification and a collapse in the price of collectible cars brought about by the early 1990s recession resulted in many buyers choosing not to exercise their purchase options. A total of just 271 cars were produced by the time production ended, each with a retail price of £470,000 in 1992. The production XJ220 used a 3.5-litre twin turbocharged engine, which was given the designation Jaguar/TWR JV6. This engine, which replaced the Jaguar V12 engine featured in the concept car, was a heavily redesigned and significantly altered version of the Austin Rover V64V V6 engine. The decision to change the engine was based on engine weight and dimensions, as well as to environmental emission considerations. Use of the shorter V6 engine design allowed the wheelbase of the XJ220 to be shortened and its weight to be reduced; the V12 engine was definitively ruled out when it was determined it would have difficulty in meeting emissions legislation whilst producing the required power and torque. TWR purchased the rights to the V64V engine from Austin Rover in 1989 and developed a completely new turbocharged engine, codenamed JV6, under the auspices of Allan Scott, with proportions roughly similar to the V64V, and suitable for Sportcar racing. TWR redesigned all parts of the engine, increasing the displacement to 3.5 litres, and adding two Garrett TO3 turbochargers. The JV6 engine would first be used in the JaguarSport XJR-10 and XJR-11 racing cars; its compact dimensions and low weight made it an ideal candidate for the XJ220. The engine had a 90° bank angle, four valves per cylinder and belt-driven double overhead camshafts. It shares a number of design features with the Cosworth DFV Formula One engine. The V64V engine chosen had a short but successful career as a purpose-designed racing car engine. It was designed by Cosworth engine designer David Wood for Austin Rover Group’s Metro derived Group B rally car, the MG Metro 6R4. The redesign work necessary to create the Jaguar/TWR JV6 engine was undertaken by Andrew Barnes, TWR’s Powertrain Manager, and also involved Swiss engine builder Max Heidegger who had designed and built the race engines used in the XJR-10 and XJR-11 racing cars. The XJ220’s engine had a bore and stroke of 94 mm × 84 mm, dry sump lubrication, Zytek multi point fuel injection with dual injectors and Zytek electronic engine management. The engine was manufactured with an aluminium cylinder block, aluminium cylinder heads with steel connecting rods and crankshaft, and in the standard state of tune, it produced a maximum power of 550 PS at 7200 rpm and torque of 475 lb·ft at 4500 rpm. The XJ220 can accelerate from 0–60 miles per hour in 3.6 seconds and reach a top speed of 213 miles per hour.The exhaust system had two catalytic converters, which reduced the power output of the engine. During testing at the Nardò Ring in Italy the XJ220, driven by 1990 Le Mans Winner Martin Brundle achieved a top speed of 217.1 miles per hour when the catalytic converters were disconnected and the rev limiter was increased to 7,900rpm; owing to the circular nature of the track, a speed of 217 mph is equivalent to 223 mph on a straight, level road. The V64V engine had the additional benefit of being very economical for such a powerful petrol engine, it was capable of achieving 32 mpg, in contrast, the smallest-engined Jaguar saloon of the time, the Jaguar XJ6 4.0 could only achieve around 24 mpg. Four-wheel drive was decided against early in the development process, for a number of reasons. It was thought rear-wheel drive would be adequate in the majority of situations, that the additional complexity of the four-wheel drive system would hinder the development process and potentially be problematic for the customer. FF Developments were contracted to provide the gearbox/transaxle assembly, modifying their four-wheel drive transaxle assembly from the XJ220 concept into a pure rear-wheel drive design for the production car. A five-speed gearbox is fitted; a six-speed gearbox was considered but deemed unnecessary, as the torque characteristics of the engine made a sixth gear redundant. The transaxle featured a viscous coupling limited slip differential to improve traction. The transmission system featured triple-cone synchromeshing on first and second gears to handle rapid starts, whilst remaining relatively easy for the driver to engage and providing positive feel. The exterior retained the aluminium body panels of the XJ220 concept, but for the production vehicles, Abbey Panels of Coventry were contracted to provide the exterior panels. The scissor doors were dropped for the production model, and significant redesign work was carried out on the design when the wheelbase and overall length of the car was altered. Geoff Lawson, Design Director at Jaguar took a greater interest in the car and insisted the design had to be seen to be a Jaguar if it was to be successful in promoting the company. Keith Helfet returned to undertake the necessary redesign work mandated by the change in the wheelbase, which was reduced by 200 mm. The turbocharged engine required larger air intakes to feed the two intercoolers. Situated between the doors and the rear wheels, the air intakes were larger on the production version of the XJ220 than on the concept car. A number of small design changes for the body were tested in the wind tunnel; the final version had a drag coefficient of 0.36 with downforce of 3,000 lb at 200 mph. The XJ220 was one of the first production cars to intentionally use underbody airflow and the venturi effect to generate downforce. The rear lights used on the production XJ220 were taken from the Rover 200. The production model utilised the same Alcan bonded honeycomb aluminium structure vehicle technology (ASVT) as the concept car for the chassis. The chassis design featured two box section rails which acted as the suspension mounting points and would provide an energy absorbing structure in the event of a frontal impact, these were successfully tested at speeds up to 30 mph, an integral roll cage formed part of the chassis and monocoque, providing additional structural rigidity for the car and allowing the XJ220 to easily pass stringent crash testing.The rear-wheel steering was dropped from the production car to save weight and reduce complexity, as was the height adjustable suspension and active aerodynamic technology. The suspension fitted to the production model consisted of front and rear independent suspension, double unequal length wishbones, inboard coil springs and anti-roll bars, with Bilstein gas-filled dampers. The suspension was designed in accordance with the FIA Group C specifications. The braking system was designed by AP Racing and featured ventilated and cross-drilled discs of 13 in diameter at the front and 11.8 in diameter at the rear. The calipers are four pot aluminium units. JaguarSport designed the handbrake, which are separate calipers acting on the rear brake discs. Feedback from enthusiasts and racing drivers resulted in the decision to drop the anti-lock braking system from the production car. The braking system was installed without a servo, but a number of owners found the brakes to be difficult to judge when cold and subsequently requested a servo to be fitted. Rack and pinion steering was fitted, with 2.5 turns lock to lock; no power assistance was fitted. The Bridgestone Expedia S.01 asymmetric uni-directional tyres were specially developed for the XJ220 and had to be rateable to a top speed in excess of 220 mph, carry a doubling of load with the exceptionally high downforce at speed and maintain a compliant and comfortable ride. Rally alloy wheel specialists Speedline Corse designed the alloy wheels, these are both wider and have a larger diameter on the rear wheels; 17 inches wheels are fitted to the front and 18 inches are fitted at the rear, with 255/55 ZR17 tyres at the front and 345/35 ZR18 tyres at the rear. The interior was designed for two passengers and trimmed in leather. Leather trimmed sports seats are fitted together with electric windows and electrically adjustable heated mirrors. The dashboard unusually curves round and carries onto the drivers door, with a secondary instrument binnacle containing four analogue gauges, including a clock and voltmeter fitted on the front of the drivers door. Air conditioning and green tinted glazing was also fitted.The luggage space consists of a small boot directly behind and above the rear portion of the engine, also trimmed in leather. The car was assembled in a purpose-built factory at Wykham Mill, Bloxham near Banbury. HRH The Princess of Wales officially opened the factory and unveiled the first production XJ220 in October 1991. The JV6 engines used in the Jaguar racing cars were produced by Swiss engineer Max Heidegger, but delivering the number of engines required for the XJ220 program was considered beyond his capacity. TWR formed a division, TWR Road Engines, to manage the design, development, construction and testing of the engines for the production cars. The JV6 engine used in the XJ220 featured little commonality with the engines Heidegger built for use in the XJR racing cars, being specifically engineered to meet performance and in particular, the European emissions requirements, which the race engines didn’t have to meet. FF Developments, in addition to their design work on the gearbox and rear axle assembly were given responsibility for their manufacture. The aluminium chassis components and body panels were manufactured and assembled at Abbey Panels factory in Coventry, before the body in white was delivered to the assembly plant at Bloxham. The car, including chassis and body components, consists of approximately 3000 unique parts. The first customer delivery occurred in June 1992, and production rates averaged one car per day. The last XJ220 rolled off the production line in April 1994; the factory was then transferred to Aston Martin and used for the assembly of the Aston Martin DB7 until 2004.

Few would have guessed that the XJS would run for over 20 years, but eventually it came time for its replacement, and the car charged with so doing was the XK8. Development began in 1992, with design work having starting earlier, in late 1991. By October 1992 a design was chosen and later frozen for production in 1993. Prototypes were built from December 1993 after the X100 was given formal approval and design patents were filed in June 1994. Development concluded in 1996, at which point the car was launched. The first-generation XK series shares its platform with the Aston Martin DB7, and both cars are derived from the Jaguar XJS, though the platform has been extensively changed. One of the revisions is the use of the second generation of Jaguar’s independent rear suspension unit, taken from the XJ40. The XK8 was available in coupé or convertible body styles and with the then new 4.0-litre Jaguar AJ-V8 engine. In 1998 the XKR was introduced with a supercharged version of the engine. 2003 the engines were replaced by the 4.2-litre AJ34 engines in both the normally aspirated and supercharged versions. Equipment levels were generous and there was a high standard of fit and finish. Both models came with all-leather interior, burl walnut trim, and side airbags. Jeremy Clarkson, during a Top Gear test-drive, likened the interior of the original XK8 to sitting inside Blenheim Palace. The model ran for 10 years before being replaced by the X150 model XK.

The second generation of the XK debuted in 2005 at the Frankfurt Motor Show in Germany, styled by Jaguar’s chief designer Ian Callum. The X150’s grille was designed to recall the 1961 E-Type. The XK is an evolution of the Advanced Lightweight Coupé (ALC) introduced at the 2005 North American International Auto Show. The XK features a bonded and riveted aluminium chassis shared with the XJ and body panels, both a first for a Jaguar grand tourer. Compared to the XK (X100), the XK (X150) is 61.0 mm (2.4 in) wider and is 162.6 mm (6.4 in) longer. It is also 91 kg (200 lb) lighter resulting in performance and fuel consumption improvements. Unlike the X100, the X150 has no wood trim on the interior offered as standard equipment. The interior featured steering column mounted shift paddles. A more powerful XKR version having a supercharged variant of the engine was introduced in 2007. The XK received a facelift in 2009,[10] with minor alterations to front and rear lights and bumper designs, together with the introduction of a new 5.0-litre V8 for both the naturally aspirated XK and the supercharged XKR. The interior also received some changes, in particular the introduction of the XF style rotary gear selector mated to the new ZF automatic transmission. The XK received a second and more minor facelift in 2011 with new front bumper and light design, which was presented at the New York Auto Show. A higher performance variant of the XKR, the XKR-S, was introduced at the Geneva Motor Show in 2012. The XKR-S gained an additional 40 bhp over the XKR bringing the 0-60 mph acceleration time down to 4.4 seconds and the top speed up to 300 km/h (186 mph). A convertible version of the XKR-S was introduced in 2012. Production of the XK ended in July 2014 without a replacement model.

Also here were a number of examples of Jaguar’s latest sports car, the F Type.

JENSEN

With the demise of the Austin-Healey 3000, Donald Healey opened discussions with Jensen Motors, who had built the bodies for Healey’s Austin-Healey cars. The largest Austin Healey Car Dealer in the US, Kjell Qvale was also keen to find a replacement to the Austin-Healey 3000 then became a major shareholder of Jensen, making Donald Healey the chairman. The Jensen-Healey was designed in a joint venture by Donald Healey, his son Geoffrey, and Jensen Motors. Hugo Poole did the styling of the body, the front and back of which were later modified by William Towns to take advantage of the low profile engine and to allow cars for the U.S. market to be fitted with bumpers to meet increasing US regulations. The unitary body understructure was designed by Barry Bilbie, who had been responsible for the Austin-Healey 100, 100-6 and 3000 as well as the Sprite. It was designed to be cheap to repair, with bolt-on panels, to reduce insurance premiums. Launched in 1972 as a fast luxurious and competent convertible sports car, it was positioned in the market between the Triumph TR6 and the Jaguar E-Type. The 50/50 weight balance due to the all alloy Lotus engine led to universal praise as having excellent handling. It all looked very promising, but it was the engine which was the car’s undoing. Various engines had been tried out in the prototype stage including Vauxhall, Ford and BMW units. The Vauxhall 2.3 litre engine met United States emission requirements but did not meet the power target of 130 hp. A German Ford V6 was considered but industrial action crippled supply. BMW could not supply an engine in the volumes needed. Colin Chapman of Lotus offered, and Jensen accepted his company’s new 1973 cc Lotus 907 engine, a two-litre, dual overhead cam, 16 valve all-alloy powerplant. This multi-valve engine is the first to be mass-produced on an assembly line. This setup put out approximately 144 bhp, topping out at 119 mph and accelerating from zero to 60 mph in 8.1 seconds. The problem was that it was a brand new engine, and Lotus were effectively using Jensen-Healey to complete the development. There were numerous issues early on, which meant that warranty claims rocketed and then sales stalled, so whilst this soon became the best selling Jensen of all time, it also helped seal the fate of the company. In total 10,503 (10 prototypes, 3,347 Mk.1 and 7,146 Mk.2) were produced by Jensen Motors Ltd. A related fastback, the Jensen GT, was introduced in 1975. Values are surprisingly low these days, which is a shame, as the problems are long since ironed out, and the resulting car looks good and goes well.

LAMBORGHINI

The first 400 GTs were essentially just the older 350GT featuring an enlarged, 3929 cc V12 engine, with a power output of 320 bhp and recognised by the change to twin circular headlights from rectangular units. Twenty-three of these cars were built, with three featuring aluminium bodywork, and then at the 1966 Geneva Show, Lamborghini presented a revised version, called the 400 GT 2+2, which had a different roofline, and minor sheetmetal changes compared to the earlier cars, still with the Carrozzeria Touring bodywork. The larger body shape enabled the +2 seating to be installed in the rear, where the 350GT only had room for luggage or +1 seating, without changing the wheelbase. The 400 GT 2+2 also had a Lamborghini designed gearbox, with Porsche style synchromesh on all gears, which greatly improved the drivetrain. 224 examples of the 400 GT 2+2 were built from 1966 to 1968, when it was replaced with the Islero.

The Espada, a 4-seat grand touring coupé, arrived in 1968. The car was designed by Marcello Gandini at Bertone. Gandini drew inspiration and cues from two of his Bertone show cars from 1967, the Lamborghini Marzal and the Jaguar Piraña. The name “Espada” means “sword” in Spanish, referring to the sword that the Torero uses to kill the bull in the Corrida. During its ten years in production the car underwent some changes, and three different series were produced. These were the S1 (1968–1970), the S2 (1970–1972) and the S3 (1972–1978). Each model featured interior redesigns, while only minor details were changed on the exterior. The Espada was launched at the 1968 Geneva Motor Show. The original design of the dashboard was inspired by the Marzal concept car, and featured octagonal housings for the main instruments, topped by an additional binnacle for the secondary gauges. Wheels were Campagnolo alloys on knock-off hubs, of the same design seen on the Miura. The tail lights were the same units mounted on the first series Fiat 124 Sport Coupé. 186 were made up until January 1970. At the 1970 Brussels Motor Show Lamborghini unveiled the Espada S2. Outside the only change was the deletion of the grille covering the vertical glass tail panel. Inside changes were more radical: all-new dashboard, centre console and steering wheel were installed. The instrument binnacle was of a more conventional rectangular shape, with round gauges. A wood-trimmed fascia extended along the entire width of the dashboard. Power output increased to 350 PS (345 bhp) due to a higher 10.7:1 compression ratio; the brakes were upgraded to vented Girling discs. Power steering was offered as an option. 575 Series II Espada were made, making it the most popular and desirable variant. The Espada S3 was launched in 1972. Its 3.9 litre V12 engine produced 325 PS (321 bhp) With the second redesign the dashboard changed to a aluminium-trimmed cockpit that kept all instruments and most controls (including the radio) within easy reach of the driver. Newly designed wheels on five-stud hubs replaces the earlier knock-off wider wheels fitted with Pirelli Cinturato 215/70WR15 CN12 tyres, making the Espada S3 instantly recognisable; other exterior changes included the square instead of hexagonal mesh grille and tail lights from the Alfa Romeo 2000 replacing the previous Fiat-sourced ones. In 1974 a Borg Warner automatic transmission became available. From 1975 large impact bumpers had to be installed to meet United States safety requirements; some people consider cars produced with them as a separate fourth series, but Lamborghini did not officially change the model designation. In total, 1217 Espadas were made, making it the most successful Lamborghini model until the expansion of Countach production in the mid-1980s.

Which small boy (and perhaps car loving girl) did not lust after a Countach back in the 1970s and 1980s. A dramatic looking car, this was the stuff of dreams that you would only ever see at the London or NEC Motor Shows. Countach first made an appearance, as a concept in 1971, but it was 1973 before the production car made its debut, and despite unfortunate timing with fuel shortages and a recession, and a number of financial problems for its maker, the car sold well throughout its production life. The Countach entered production as the LP400 with a 3929 cc engine delivering 370 hp. The first production Countach was delivered to an Australian in 1974. Externally, little had altered from the final form of the prototype except at the rear, where conventional lights replaced the futuristic light clusters of the prototype. The styling had become rather more aggressive than Gandini’s original conception, with the required large air scoops and vents to keep the car from overheating, but the overall shape was still very sleek. The original LP400 rode on the quite narrow tyres of the time, but their narrowness and the slick styling meant that this version had the lowest drag coefficient of any Countach model. The emblems at the rear simply read “Lamborghini” and “Countach”, with no engine displacement or valve arrangement markings as is found on later cars. By the end of 1977, the company had produced 158 Countach LP400s. In 1978, a new LP400 S model was introduced. Though the engine was slightly downgraded from the LP400 model (350 bhp), the most radical changes were in the exterior, where the tyres were replaced with 345/35R15 Pirelli P7 tyres; the widest tyres available on a production car at the time, and fibreglass wheel arch extensions were added, giving the car the fundamental look it kept until the end of its production run. An optional V-shaped spoiler was available over the rear deck, which, while improving high-speed stability, reduced the top speed by at least 16 km/h (10 mph). Most owners ordered the wing. The LP400 S handling was improved by the wider tyres, which made the car more stable in cornering. Aesthetically, some prefer the slick lines of the original, while others prefer the more aggressive lines of the later models, beginning with the LP400 S. The standard emblems (“Lamborghini” and “Countach”) were kept at the rear, but an angular “S” emblem was added after the “Countach” on the right side. 1982 saw another improvement, this time giving a bigger, more powerful 4754 cc engine. The bodywork was unaltered, however the interior was given a refresh. This version of the car is sometimes called the 5000 S, which may cause confusion with the later 5000 QV. 321 of these cars were built. Two prototypes of the 1984 Countach Turbo S were built by Lamborghini, of which one is known to exist. The Turbo S weighed 1,515 kg (3,340 lb), while its 4.8 litre twin-turbo V12 had a claimed maximum power output of 758 PS and a torque output of 876 N·m (646 lb·ft), giving the car an acceleration of 0–100 km/h (0–62 mph) in 3.7 seconds and a top speed of 335 km/h (208 mph). A turbo adjuster, located beneath the steering wheel, could be used to adjust the boost pressure from 0.7 bar to 1.5 bar at which the engine performed its maximum power output. The Turbo S has 15″ wheels with 255/45 tyres on the front and 345/35 on the rear. In 1985 the engine design evolved again, as it was bored and stroked to 5167 cc and given four valves per cylinder—quattrovalvole in Italian, hence the model’s name, Countach 5000 Quattrovalvole or 5000 QV in short. The carburettors were moved from the sides to the top of the engine for better breathing—unfortunately this created a hump on the engine deck, reducing the already poor rear visibility to almost nothing. Some body panels were also replaced by Kevlar. In later versions of the engine, the carburettors were replaced with fuel injection. Although this change was the most notable on the exterior, the most prominent change under the engine cover was the introduction of fuel injection, with the Bosch K-Jetronic fuel injection, providing 414 bhp, rather than the six Weber carburettors providing 455 bhp. As for other markets, 1987 and 1988 model Quattrovalvoles received straked sideskirts. 610 cars were built.

Lamborghini had been toying for some time with the idea of a smaller and cheaper car, powered by a V8 engine, to rival the smaller Ferraris, and the result, the Urraco, was first seen at the 1970 Turin Show. It was styled by Marcello Gandini, and engineered by Paolo Stanzani. It was launched with a 2.5 litre V8 engine, engineered to be cheaper to build, with belt-driven camshafts, situated within a steel monocoque structure suspended on McPherson struts. It reached the market before the rival Maserati Merak and Ferrari 308 GT4 Dino, which should have given it a big advantage. But it did not. For a start, it was deemed not powerful enough, so even before the difficulties of the late 1973 Fuel Crisis made things difficult, the car did not sell well at all. The solution was to add more power, and this came when the engine was enlarged to 3 litres, with four chain-driven cams, which took power from 220 bhp to 265 bhp. A roll-hoop across the back of the cabin improved rigidity, and more powerful brakes were fitted. It sold better, though never in the sort of volume that had been anticipated, and the addition of an Italian market tax special P200 did not help much, either. Just 66 of these were built, whereas 520 of the original P250 models found buyers, and 190 of the more powerful P300s added to the total before production ceased in 1979. The story did not quite end there, as in 1976 a heavily revised version, with removable targa roof panels, appeared, called the Silhouette, and both were replaced by the Jalpa in the 1980s, though neither of these sold as well as the Urraco.

At a time when the company was financed by the Swiss-based Mimran brothers, Lamborghini began development of what was codenamed Project 132 in June 1985 as a replacement for the Countach model. The brief stated that its top speed had to be at least 315 km/h (196 mph). The design of the car was contracted to Marcello Gandini, who had designed its two predecessors. When Chrysler bought the company in 1987, providing money to complete its development, its management was uncomfortable with Gandini’s designs and commissioned its design team in Detroit to execute a third extensive redesign, smoothing out the trademark’s sharp edges and corners of Gandini’s original design, and leaving him famously unimpressed. In fact, Gandini was so disappointed with the “softened” shape that he would later realise his original design in the Cizeta-Moroder V16T. The car became known as the Diablo, carrying on Lamborghini’s tradition of naming its cars after breeds of fighting bulls. The Diablo was named after a ferocious bull raised by the Duke of Veragua in the 19th century, famous for fighting an epic battle with ‘El Chicorro’ in Madrid on July 11, 1869 In the words of Top Gear presenter Jeremy Clarkson, the Diablo was designed “solely to be the biggest head-turner in the world.” The Diablo was presented to the public for sale on January 21, 1990. Its power came from a 5.7 litre 48-valve version of the existing Lamborghini V12 featuring dual overhead cams and computer-controlled multi-point fuel injection, producing a maximum output of 499 PS and 580 N·m (428 lb/ft) of torque. The vehicle could reach 100 km/h in about 4.5 seconds, with a top speed of 202 mph. The Diablo was rear-wheel drive and the engine was mid-mounted to aid its weight balance. The Diablo came better equipped than the Countach; standard features included fully adjustable seats and steering wheel, electric windows, an Alpine stereo system, and power steering from 1993 onwards. Anti-lock brakes were not initially available, although they would eventually be used. A few options were available, including a custom-moulded driver’s seat, remote CD changer and subwoofer, rear spoiler, factory fitted luggage set and an exclusive Breguet clock for the dash. The Diablo VT was introduced in 1993. Although the VT differed from the standard Diablo in a number of ways, by far the most notable change was the addition of all wheel drive, which made use of a viscous centre differential (a modified version of LM002’s 4WD system). This provided the new nomenclature for the car (VT stands for viscous traction). The new drivetrain could direct up to 25% of the torque to the front wheels to aid traction during rear wheel slip, thus significantly improving the handling characteristics of the car. Other improvements debuting on the VT included front air intakes below the driving lamps to improve brake cooling, larger intakes in the rear arches, a more ergonomic interior with a revised dashboard, electronically adjustable dampers, four-piston brake calipers, power steering, and minor engine refinements. Many of these improvements, save the four-wheel drive system, soon transferred to the base Diablo, making the cars visually nearly identical. Further updates would follow before the car gave way to the Murcielago in 2001. The Diablo sold in greater numbers than its predecessor with 2898 examples being made during its 11 year production life. There were several here, including the VT and the SV, a few of them were the late model cars with their faired-in headlights.

In its turn, the Diablo gave way to the Murcielago in 2001. Taking its name from the Spanish for “bat”, this was Lamborghini’s first new design in eleven years and more importantly, the brand’s first new model under the ownership of German parent company Audi, which was manifest in a much higher level of quality and reliability. The Murcielago was styled by Peruvian-born Belgian Luc Donckerwolke, Lamborghini’s head of design from 1998 to 2005. Initially it was only available as a Coupe. The Murciélago was an all-wheel drive, mid-engined supersports car. With an angular design and an exceptionally low slung body, the highest point of the roof is just under 4 feet above the ground. One of the vehicle’s most distinguishing features are its scissor doors. which lends to the extreme image. First-generation Murciélagos, produced between 2001 and 2006, were powered by a Lamborghini V12 that traces its roots back to the company’s beginnings in the 1960s. The rear differential is integrated with the engine itself, with a viscous coupling centre differential providing drive to the front wheels. Power is delivered through a 6-speed manual transmission. The Murciélago suspension uses an independent double-wishbone design, and bodywork features carbon fiber, steel and aluminium parts. The rear spoiler and the active air intakes integrated into the car’s shoulders are electromechanically controlled, deploying automatically only at high speeds in an effort to maximise both aerodynamic and cooling efficiency. The first generation cars were produced between 2001 and 2006, and known simply as Murciélago, sometimes Murciélago VT. Their V12 engines produced just under 580 PS (572 hp), and powered the car to 100 km/h (62 mph) in 3.8 seconds. Subsequent versions incorporated an alphanumeric designation to the name Murciélago, which indicated their engine configuration and output. However, the original cars are never referred to as “LP 580s”. The Murciélago Roadster was introduced in 2004. Primarily designed to be an open top car, it employed a manually attached soft roof as cover from adverse weather, but a warning on the windshield header advised the driver not to exceed 100 mph (160 km/h) with the top in place. The designer used the B-2 stealth bomber, the Wally 118 WallyPower yacht, and architect Santiago Calatrava’s Ciutat de les Arts i les Ciències in Valencia, Spain as his inspiration for the roadster’s revised rear pillars and engine cover. In March 2006, Lamborghini unveiled a new version of its halo car at the Geneva Motor Show: the Murciélago LP 640. The new title incorporated the car’s name, along with an alphanumeric designation which indicated the engine’s orientation (Longitudinale Posteriore), along with the newly updated power output. With displacement now increased to 6.5 litres, the new car made 640 PS ( 631 hp) at 8000 rpm. The Murciélago’s exterior received a minor facelift. Front and rear details were revised, and side air intakes were now asymmetrical with the left side feeding an oil cooler. A new single outlet exhaust system incorporated into the rear diffuser, modified suspension tuning, revised programming and upgraded clutch for the 6-speed “e-Gear” automated sequential transmission with launch control rounded out the performance modifications. Interior seating was also re-shaped to provide greater headroom, and a new stereo system formed part of the updated dashboard. Optional equipment included Carbon fibre-reinforced Silicon Carbide (C/SiC) ceramic composite brakes, chrome paddle shifters and a glass engine cover. At the 2006 Los Angeles Auto Show, Lamborghini announced that the roadster version of the Murciélago would also be updated to LP 640 status. At the 2009 Geneva Motor Show, Lamborghini unveiled the ultimate version of the Murciélago, the LP 670–4 SuperVeloce. The SV moniker had previously appeared on the Diablo SV, and Miura. SV variants are more extreme and track-oriented, and are released at the end of each model’s production run. The SuperVeloce’s V12 produced 670 PS (661 hp) at 8000 rpm and 660 N·m (490 lbf·ft) of torque at 6500 rpm, thanks to revised valve timing and upgraded intake system. The car’s weight was also reduced by 100 kg (220 lb) through extensive use of carbon fibre inside and out. A new lighter exhaust system was also used. As a result of the extensive weight loss, the SV had a power-to-weight ratio of 429 bhp/ton. Also standard were the LP 640’s optional 15-inch carbon-ceramic disc brakes with 6 piston calipers. The original production plan for the SV was limited to 350 cars, but in fact only 186 LP 670-4s were produced before the factory had to make room for the new Aventador production line. Numbered cars 1–350 do not represent the order in which cars were manufactured. Only 5-6 were made with manual transmission. Production of the Murciélago ended on November 5, 2010, with a total run of 4,099 cars. Its successor, the Aventador, was released at the 2011 Geneva Motor Show.

The Gallardo was launched in 2003, and stayed in production over 10 years, In excess of 10,000 were made, making it by some margin the most popular Lamborghini yet made. During the long life, lots of different variants were produced with a mixture of all wheel drive and rear wheel power only, open topped bodies, and lightened Superleggera models. Several different ones were on show here including the Superleggera, Balboni and Performante versions.

The Aventador has been a huge success for Lamborghini. It was first seen at the 2011 Geneva Show, with the full name of Aventador LP700-4 Coupe, the numbers denoting the output of 700 bhp from the all-new V12 engine and the 4 meaning four wheel drive, something which has featured on every Aventador since. The launch price was £250,000 but even so within a month, Lamborghini had a year’s worth of orders, and within a year, 1000 had been built. In November 2012 a Roadster version arrived, which was very similar to the Coupe, but with a lift-out roof panel. A suite of mechanical changes came at this point, with a cylinder deactiviation technology helping to improve fuel consumption and cut emissions. To mark half a century of car production, in April 2013, the LP720-4 50th Anniversary was launched, with 100 units available. As well as the extra 20 bhp, these had a mildly redesigned nose and tail, special paintwork and unique interior trim. A Roadster version followed in December 2014, the LP 700-4 Pirelli Edition. This did not have the extra power, but did feature two tone paint, unique wheels and a transparent engine cover, with the engine bay finished in carbon fibre. Lamborghini turned up the wick in march 2015 with the LP750-4 SuperVeloce, or SV for short, which featured and extra 50 bhp and a 50 kg weight reduction largely thanks to the use of more carbon fibre. A Roadster version followed a few months later.

Newest Lamborghini is the Huracan. Replacing Lamborghini’s sales leader and most produced car, the Gallardo, the Huracán made its auto show debut at the March 2014 Geneva Auto Show, and was released in the second quarter of 2014. The name of the Huracan LP 610-4 comes from the fact that this car has 610 metric horsepower and 4 wheel drive. Huracán (huracán being the Spanish word for hurricane) is inspired by a Spanish fighting bull. Continuing the tradition of using names from historical Spanish fighting bulls, Huracán was a bull known for its courage that fought in 1879. Also Huracan is the Mayan god of wind, storm and fire. Changes from the Gallardo included full LED illumination, a 12.3 inch full-colour TFT instrument panel, Fine Nappa leather and Alcantara interior upholstery, redesigned dashboard and central tunnel, Iniezione Diretta Stratificata (IDS, essentially an adapted version of parent Audi’s Fuel Stratified Injection) direct and indirect gasoline injections, engine Stop & Start technology, EU6 emissions regulation compliance, Lamborghini Doppia Frizione (LDF) 7-speed dual-clutch transmission with 3 modes (STRADA, SPORT and CORSA), 20 inch wheels, carbon-ceramic brake system, optional Lamborghini Dynamic Steering variable steering system and MagneRide electromagnetic damper control. In early 2015, the Huracán appeared on Top Gear. It got a neutral review from Richard Hammond who said that it was too tame to be a “proper Lamborghini.” However, it got around the Top Gear test track in 1:15.8 which is faster than any other Lamborghini to go around the track to date, including the Aventador. Now it has been available in the UK for some a couple of years, there are now quite a few on our roads, so it was no surprise to find the model here.

LANCIA

Replacement for the Aurelia was the Flaminia, which although superficially similar to its illustrious predecessor and materially “better” in just about every respect, never managed to capture buyers’ imaginations in the same way when new, and even now, it has to play second fiddle to the older car. The first model in the range was the Berlina, which was launched at the 1957 Geneva Show. It had a Pininfarina styled body which took much inspiration from the Florida concept car that had been shown in the previous year. Much was new under the skin. Its larger 2.5 litre 100 bhp V6 engine was new in detail, and was designed to allow for further increases in capacity, which would come in time. I was smoother than the Aurelia engines and had more torque, and with better cylinder head design and revised cooling, it was more robust, as well. There was synchromesh on all four gears. Lancia’s famous sliding pillar suspension was banished in favour of unequal length wishbones and coil springs which required less maintenance and were more refined. But the car was heavy, and complex, and exceedingly expensive. Lancia thought that their customers would pay a premium for “the best”, but tastes were changing, and the Berlina was never a strong seller, with fewer than 3000 of them being constructed, most of them being the first series cars. Just 549 of the later second series model with 110 bhp and disc brakes were made between 1961 and 1963, hardly surprising when the car cost more than a Rolls Royce Silver Cloud, as it did in the UK. The later cars had a 2.8 litre engine and 125 bhp, and just 599 of these were made between 1963 and 1968. There was more success with the coachbuilt two door variants which joined the range. The most successful of these, the Pininfarina Coupe, was the first to appear. This was made between 1959 and 1967, during which time 5284 of these mostly steel-bodied cars were constructed. In many ways they were very like the Berlina, just a bit smaller, though there was a floor mounted gear lever, and the cars had more power. The first 3200 of them had a 119 bhp single carb engine with a sport camshaft. Later 3Bs had a triple choke Solex from 1962 and the power went up to 136 bhp. It was only a year after the Pininfarina car’s debut when Touring of Milan announced their Flaminia models. These aluminium bodied cars were sold in three distinct variants between 1960 and 1965. The single carburettor GT was followed by a Convertible in 1960, both of them uprated to 140 bhp triple Weber 3C spec in 1961. The 2.8 litre 3C took over in 1963 and were supplemented by a new 2+2 version called the GTL, with a taller roofline, front-hinged bonnet, longer doors and more substantial seats. It is the rarest of all Flaminia models, with just 300 made. The styling house to offer a car was Zagato, with their Sports and SuperSports. Only 526 were made and there is a complicated production history which probably shows the sort of chaotic thinking that was going on at Lancia and which would lead to is bankruptcy and take over by Fiat in 1969. The first 99 Sports had faired-in headlights and the 119 bhp engine. From 1960 another 100 cars were built with expose lights until the introduction of the Sport 3C with the 140 bhp triple carb. Zagato made 174 of those in 1962 and 1963, still with the exposed lights. The faired-in lights returned in 1964 on the SuperSport, which also had a Kamm tail, and with DCN Webers this one put out 150 bhp. 150 of these were made between 1964 and 1967. Many of the earlier cars were upgraded early in their life, so if you see one now, you cannot be totally sure of is true origin. Production of the car ceased in 1970, with fewer than 13,000 Flaminia of all types having been built. These days, the cost to restore them properly – and it is a huge job – exceeds the value of most of them, by some margin, as Berlina and Coupe models tend not to sell for more than £30k. The Zagato cars are a different matter, and when they come up for sale, routinely go for over £300k. The Touring cars – considered by most to be the prettiest tend to be around £100k for the GT and another 50 – 80k for a convertible – a long way from the value of an Aston Martin DB4 Volante, which cost roughly the same when new. There’s believed to be only one Berlina on the road in the UK, so that is going to remain a rare sighting, and it was not here. It was the Farina Coupe, the Touring GT and the SuperSport that were represented here.

Lancia replaced the long-running Appia with a new model in 1963, the Fulvia. Like the larger Flavia which had been shown 3 years earlier, it came with front wheel drive, and a host of exquisite engineering which ensure that even though it was expensive, it was actually not profitable for its maker, and was a direct contribution to the marque’s bankruptcy and take over by Fiat in 1969. It was not long before the initial Berlina saloon model was joined by a Coupe. First seen in 1965. the Coupe proved to be the longest lived of all Fulvia variants, surviving until 1976 when it was effectively replaced by the 1300cc version of the Beta Coupe. Before that, it had undergone a steady program of updates, with more powerful engines, including a capacity increase from the initial 1200cc of the narrow angle V4 to 1300 and then later 1600cc, and the car was developed into a successful rally machine for the late 60s. The Sport Zagato version was designed by Ercole Spada at Zagato and was intended to be the more sporting model of the range. It was also considerably more expensive. Early cars had an unusual side hinged bonnet, but this was changed on the Series 2 models which were launched in 1970, and which also switched to all-steel bodies. Seen here was a nice Coupe in S2 guise.

This is a 2000 HF Coupe, last iteration of the Flavia range. Named after the Via Flavia, the Roman road leading from Trieste (Tergeste) to Dalmatia, and launched at the 1960 Turin Motor Show, the Flavia was initially available only as a four-door saloon, featuring a 1.5 litre aluminium boxer engine, Dunlop disc brakes on all four wheels, front-wheel drive and front suspension by unequal-length wishbones. This model was soon joined by a two-door coupé, designed by Pininfarina on a shortened platform. Vignale built 1,601 two-door convertibles, while Zagato designed an outlandish-looking light weight two-door sport version. The sport version has twin carburettors for extra power (just over 100 hp); however, this version of the engine was notoriously difficult to keep in tune. Even the single-carburettor engine suffered from the problem of timing chain stretch. Sprockets with vernier adjusters were fitted to allow for chain wear, and the cam timing was supposed to be checked every 6000 miles. Early cars also suffered from corrosion of the cylinder heads caused by using copper gaskets on aluminium heads; nevertheless, the car was quite lively for its day, considering the cubic capacity. Later development of the engine included an enlargement to 1.8 litres, a mechanical injection version using the Kugelfischer system, and a five-speed manual gearbox. Towards the end of the 1960s, when Fiat took control of the company, the Vignale and Zagato versions were discontinued. The coupé and saloon versions received new bodywork, first presented in March 1969 at the Geneva Motor Show. The engine increased to 2.0 litres, available with carburettor or injection, and four- or five-speed gearbox. The 2.0 litre models were only made with revised Pininfarina Coupe and revised Berlina bodies. The model was updated further in 1971, with squared off styling, becoming the 2000 in which guise it was produced for a further 4 years.

There were a number of Stratos replica cars. Although faithful to the original, the fact that they have right hand drive is the clue as none of the original factory cars did.

Representing the Beta family was this HPE. The Beta HPE was a three-door sporting estate or shooting-brake introduced in March 1975. HPE stood for High Performance Estate, and then later High Performance Executive. This model had Berlina’s longer wheelbase floorpan combined with the coupé’s front end and doors. The HPE was also styled in house at Lancia by Castagno’s team, with Castagnero as styling consultant. At launch it came with either 1600 or 1800 twin-cam engines, these being replaced in November of the same year by new 1.6 and 2.0 units. In 1978, like other Beta models automatic transmission became available along with power steering. It was renamed the Lancia HPE (without the Beta) from 1979 and in autumn 1981 gained the option of a fuel injected 2.0 engine. In 1984 a 2.0VX supercharged version became available. Like all other cars in the Beta range the HPE was discontinued in 1984.

Considered to be part of the Beta family, though there is an awful lot about the car that is very different from the front wheel drive models was the MonteCarlo, no fewer than eight examples of which were displayed. First conceived in 1969, with a a final design completed by 1971 by Paolo Martin at Pininfarina, what was initially known as the Fiat X1/8 Project, was originally designed as Pininfarina’s contender to replace Fiat’s 124 Coupe, but it lost out to Bertone’s cheaper design, which became the Fiat X1/9. Rather than scrap the proposal completely, it was developed further, when Fiat commissioned Pininfarina to build a 3.0 litre V6 mid-engined sports car. An X1/8 chassis was used as the start point, and developed for the first time in-house by Pininfarina and not based on any existing production car. Due to the 1973 Oil Crisis, the project was renamed X1/20 and updated to house a 2.0 litre engine. The first car to be made out of the X1/20 Project was the Abarth SE 030 in 1974. The project was passed to Lancia, and the road car was launched at the 1975 Geneva Motor Show as the Lancia Beta MonteCcarlo. It was the first car to be made completely in-house by Pininfarina. Lancia launched the MonteCarlo as a premium alternative to the X1/9, with the 2 litre twin cam engine rather than the X1/9’s single cam 1300. Both used a similar, based on the Fiat 128, MacPherson strut front suspension and disc brakes at both front and rear. Lancia Beta parts were limited to those from the existing Fiat/Lancia standard parts bin, the transverse mount version of the Fiat 124’s twin cam engine and the five speed gearbox and transaxle. MonteCarlos were available as fixed head “Coupés” and also as “Spiders” with solid A and B pillars, but a large flat folding canvas roof between them. Sales were slow to get started, and it soon became apparent that there were a number of problems with a reputation for premature locking of the front brakes causing particular alarm. Lancia suspended production in 1979 whilst seeking a solution, which meant that the car was not produced for nearly two years. The second generation model, known simply as MonteCarlo now, was first seen in late 1980. The braking issue was addressed by removing the servo, as well as few other careful mechanical tweaks. The revised cars also had glass panels in the rear buttresses, improving rear visibility somewhat, and there was a revised grille. In the cabin there was a new three spoke Momo steering wheel in place of the old two spoke one, as well as revamped trim and fabrics. The engine was revised, with a higher compression ratio, Marelli electronic ignition and new carburettors which produced more torque. It was not enough for sales to take off, and the model ceased production in 1982, although it took quite a while after that to shift all the stock. Just under 2000 of the Phase 2 cars were made, with 7798 MonteCarlos made in total.

Lancia launched the Delta in 1979, as what we would now think of as a “premium hatch”. Offered in 1300 and 1500cc engines, this car, which collected the prestigious “Car of the year” award a few months later, brought Italian style and an expensive feeling interior to a new and lower price point in the market than Lancia had occupied since the early days of the Fulvia some 15 years earlier. The range grew first when a model was offered using the 4 speed AP automatic transmission and then in late 1982, more powerful models started to appear, with first a 1600cc engine, and then one with fuel injection, before the introduction of the HF Turbo. All these cars kept the same appearance and were quite hard to tell apart. These were the volume models of the range, but now they are very definitely the rare ones, as it is the performance versions which have survived and are now much loved classics, even though relatively were sold when they were new, thanks to a combination of the fact that they were quite costly and that they only ever came with left hand drive. The Integrale evolved over several years, starting off as the HF Turbo 4WD that was launched in April 1986, to homologate a new rally car for Lancia who needed something to fill the void left by the cancellation of Group B from the end of 1986. The Delta HF 4X4 had a four-wheel drive system with an in-built torque-splitting action. Three differentials were used. Drive to the front wheels was linked through a free-floating differential; drive to the rear wheels was transmitted via a 56/44 front/rear torque-splitting Ferguson viscous-coupling-controlled epicyclic central differential. At the rear wheels was a Torsen (torque sensing) rear differential. It divided the torque between the wheels according to the available grip, with a maximum lockup of 70%. The basic suspension layout of the Delta 4WD remained the same as in the rest of the two-wheel drive Delta range: MacPherson strut–type independent suspension with dual-rate dampers and helicoidal springs, with the struts and springs set slightly off-centre. The suspension mounting provided more isolation by incorporating flexible rubber links. Progressive rebound bumpers were adopted, while the damper rates, front and rear toe-in and the relative angle between springs and dampers were all altered. The steering was power-assisted rack and pinion. The car looked little different from the front wheel drive models. In September 1987, Lancia showed a more sophisticated version of the car, the Lancia Delta HF Integrale 8V. This version incorporated some of the features of the Delta HF 4WD into a road car. The engine was an 8-valve 2 litre fuel injected 4-cylinder, with balancing shafts. The HF version featured new valves, valve seats and water pump, larger water and oil radiators, more powerful cooling fan and bigger air cleaner. A larger capacity Garrett T3 turbocharger with improved air flow and bigger inter-cooler, revised settings for the electronic injection/ignition control unit and a knock sensor, boosting power output to 185 bhp at 5300 rpm and maximum torque of 224 lb/ft at 3500 rpm. The HF Integrale had permanent 4-wheel drive, a front transversely mounted engine and five-speed gearbox. An epicyclic centre differential normally split the torque 56 per cent to the front axle, 44 per cent to the rear. A Ferguson viscous coupling balanced the torque split between front and rear axles depending on road conditions and tyre grip. The Torsen rear differential further divided the torque delivered to each rear wheel according to grip available. A shorter final drive ratio (3.111 instead of 2.944 on the HF 4WD) matched the larger 6.5×15 wheels to give 24 mph/1000 rpm in fifth gear. Braking and suspension were uprated to 284 mm ventilated front discs, a larger brake master cylinder and servo, as well as revised front springs, dampers, and front struts. Next update was to change the engine from 8 valves to 16. The 16v Integrale was introduced at the 1989 Geneva Motorshow, and made a winning debut on the 1989 San Remo Rally. It featured a raised centre of the bonnet to accommodate the new 16 valve engine, as well as wider wheels and tyres and new identity badges front and rear. The torque split was changed to 47% front and 53% rear. The turbocharged 2-litre Lancia 16v engine now produced 200 bhp at 5500 rpm, for a maximum speed of 137 mph and 0–100 km/h in 5.5 seconds. Changes included larger injectors, a more responsive Garrett T3 turbocharger, a more efficient intercooler, and the ability to run on unleaded fuel without modification. The first Evoluzione cars were built at the end of 1991 and through 1992. These were to be the final homologation cars for the Lancia Rally Team; the Catalytic Evoluzione II was never rallied by the factory. The Evoluzione I had a wider track front and rear than earlier Deltas. The bodyside arches were extended and became more rounded. The wings were now made in a single pressing. The front strut top mounts were also raised, which necessitated a front strut brace. The new Integrale retained the four wheel drive layout. The engine was modified to produce 210 bhp at 5750 rpm. External changes included: new grilles in the front bumper to improve the air intake for engine compartment cooling; a redesigned bonnet with new lateral air slats to further assist underbonnet ventilation; an adjustable roof spoiler above the tailgate; new five-bolt wheels with the same design of the rally cars; and a new single exhaust pipe. Interior trim was now grey Alcantara on the Recaro seats, as fitted to the earlier 16V cars; leather and air conditioning were offered as options, as well as a leather-covered Momo steering wheel. Presented in June 1993, the second Evolution version of the Delta HF Integrale featured an updated version of the 2-litre 16-valve turbo engine to produce more power, as well as a three-way catalyst and Lambda probe. A Marelli integrated engine control system with an 8 MHz clock frequency which incorporates: timed sequential multipoint injection; self-adapting injection times; automatic idling control; engine protection strategies depending on the temperature of intaken air; Mapped ignition with two double outlet coils; Three-way catalyst and pre-catalyst with lambda probe (oxygen sensor) on the turbine outlet link; anti-evaporation system with air line for canister flushing optimised for the turbo engine; new Garrett turbocharger: water-cooled with boost-drive management i.e. boost controlled by feedback from the central control unit on the basis of revs/throttle angle; Knock control by engine block sensor and new signal handling software for spark park advance, fuel quantity injected, and turbocharging. The engine now developed 215 PS as against 210 PS on the earlier uncatalysed version and marginally more torque. The 1993 Integrale received a cosmetic and functional facelift that included. new 16″ light alloy rims with 205/45 ZR 16 tyres; body colour roof moulding to underline the connection between the roof and the Solar control windows; aluminium fuel cap and air-intake grilles on the front mudguards; red-painted cylinder head; new leather-covered three-spoke MOMO steering wheel; standard Recaro seats upholstered in beige Alcantara with diagonal stitching. In its latter years the Delta HF gave birth to a number of limited and numbered editions, differing mainly in colour, trim and equipment; some were put on general sale, while others were reserved to specific markets, clubs or selected customers. There were several examples of the Integrale here.

LAND ROVER

There plenty of examples of the original Range Rover. The Rover Company had been experimenting with a larger model than the Land Rover Series as far back as 1951, when the Rover P4-based two-wheel-drive “Road Rover” project was developed by Gordon Bashford. This was shelved in 1958, and the idea lay dormant until 1966, when engineers Spen King and Bashford set to work on a new model. In 1967, the first Range Rover prototype was built (number plate SYE 157F), with the classic Range Rover shape clearly discernible, but with a different front grille and headlight configuration. The design of the Range Rover was finalised in 1969. Twenty-six Velar engineering development vehicles were built between 1969 and 1970 and were road registered with the number plates YVB151H through to YVB177H. Though being chassis no. 3, the vehicle YVB 153H is believed to have been the first off the production line as a vehicle in that colour was urgently required for marketing. The Velar name was derived from the Italian “velare” meaning to veil or to cover. Range Rover development engineer Geoff Miller used the name as a decoy for registering pre-production Range Rovers. The Velar company was registered in London and produced 40 pre-production vehicles that were built between 1967 and 1970. Most of these Velar pre-production vehicles are accounted for and have survived into preservation, and one of them was presented here. These models fetch very strong money when sold, between £60 -80,000 for the handful that have appeared for sale in the last couple of years. The production Range Rover was launched in 1970, and it was produced until 1994, undergoing quite a transition into a luxury product en route. Early models are currently the most prized ones, and there were a number of those here, as well as some of the later ones with the longer wheelbase, and luxury trim and the limited edition, and now quite valuable CSK model.

Also here was the second generation “P38A” Range Rover. Twenty-five years after the introduction of the original Range Rover, the second-generation was introduced for the 1995 model year, based on the 8 inches (20 centimetres) longer chassis of the old LWB model, and with an updated version of the Rover V8 engine. There was also the option of a 2.5-litre BMW six-cylinder turbo-diesel with a Bosch injection pump. This was the first diesel injection with electronic controls in a Land Rover, before common rails were introduced. This was a result of BMW’s subsequent ownership of Rover Group and hence the Land Rover brand. The new model offered more equipment and premium trims, positioning the vehicle more strongly above the Land Rover Discovery than the old original, to meet the increased competition in the SUV marketplace. This model was the last to feature the Rover V8 and interior leather supplied by Connolly who went out of business in 2002. It was the first model to feature Satellite Navigation as an option. The car never found the same level of enthusiasm as the model it replaced.

LOTUS

Colin Chapman introduced his first ‘production’ car, the Lotus Mark VI, in 1952. The heart of the Mark VI was a space frame chassis. Rather than a complete car, it was available to the general public as kit, wherein the customer could install any preferred engine and gearbox, making it eligible for a wider number of formulae. The Mark VI in many ways reflected Chapman’s background in engineering: his designs resulted from a stress analysis of loads into the frame, they were extremely light (the 6′ space frame weighed only 55 lbs), and the suspension incorporated the latest advances. The prototype chassis was built up by the Progress Chassis Company and the aluminium body was constructed by panel beaters Williams and Prichard. (Both firms would later furnish bodies and chassis for subsequent models.) The cheap and easily available mechanical parts were sourced from the Ford Prefect. The Mark VI became a popular sight on Britain’s racetracks, and was a frequent winner, beating many more powerful and expensive cars, earning praise for very good handling and superior low-speed acceleration. An important facet of the success of the kit was Chapman’s offering a comprehensive package in the Mark VI, including most of the special parts needed, and not just the chassis. The Mark VI chassis came with mounting points for several different engines including the 1172cc Ford 10, the 1250 cc or 1500 cc MG TF, the 1500cc Consul, and the exalted Coventry Climax. Standardised as far as possible for volume production, some units were customised per the owners wishes. Lotus even modified the owner’s parts, if needed. When fitted with the 1172cc Ford engine, and a 3 speed gearbox, the car put out 50 bhp at 5000 rpm, and generated 57 lb/ft of torque, which gave the car a 0 – 60 time of 15 seconds and a top speed of 93 mph. The success of the Mark VI in competition and sales – 100 had been built by 1955 – established Chapman as a manufacturer of specialty cars.

The Lotus Seven was launched in 1957 to replace the Mark VI as the ‘entry level’ Lotus model, The Seven name was left over from a model that was abandoned by Lotus, which would have been a Riley-engined single-seater that Lotus intended to enter into the Formula Two in 1952 or 1953. However, the car was completed around Chapman’s chassis as a sports car by its backers and christened the Clairmonte Special. Externally similar to Chapman’s earlier Lotus Mark VI, but with a different tubular frame similar to the Lotus Eleven, the Seven was powered by a 40 bhp Ford Side-valve 1,172 cc inline-four engine. It was used both on the road and for club racing The Lotus Seven S2 followed in 1960 and was supplemented by the Lotus Super Seven S2 from 1961. The Super Seven initially used the larger Cosworth modified 1,340cc Ford Classic engine and later examples were fitted with 1,498cc or 1,599cc engines. The Seven S3 was released in 1968. In 1970, Lotus radically changed the shape of the car to create the slightly more conventional sized Series 4 (S4), with a squarer fibreglass shell replacing most of the aluminium bodywork. It also offered some luxuries as standard, such as an internal heater matrix. Between 1970 and 1975, following a representation agreement, Lotus Argentina SA obtained the licence to manufacture the Lotus Seven in Argentina. This production reached approximately 51 units. These vehicles were not replicas, but built under licence and original brand Lotus. Under the Purchase Tax system of the time cars supplied as a kit (known as “completely knocked down” or CKD) did not attract the tax surcharge that would apply if sold in assembled form. Tax rules specified assembly instructions could not be included, but as the rules said nothing about the inclusion of disassembly instructions, they were included instead and all the enthusiast had to do was to follow them in reverse. However, once the UK joined the EEC on 1 January 1973, the VAT system was adopted instead so the tax advantage of the kit-built Lotus Seven came to an end. In 1973, Lotus decided to shed fully its “British tax system”-inspired kit car image and concentrate on limited series motor racing cars. As part of this plan, it sold the rights to the Seven to its only remaining agents Caterham Cars in England and Steel Brothers Limited in New Zealand. Caterham ran out of the Lotus Series 4 kits in the early 1970s. When this occurred and in accordance with their agreement with Lotus, Caterham introduced its own brand version of the Series 3. They have been manufacturing the car ever since as the Caterham Seven.

There were several examples of the Lotus Eleven here, a racing car built in various versions by Lotus from 1956 until 1958. The later versions built in 1958 are sometimes referred to as Lotus 13, although this was not an official designation. In total, about 270 Elevens of all versions were built. The Eleven was designed by Colin Chapman and fitted with a sleek body designed by aerodynamicist Frank Costin. Its top version, dubbed Le Mans, was generally fitted with a 1100 cc Coventry Climax FWA engine and occasionally with a 1500 cc Coventry Climax FWB engine mounted in the front of a tubular space frame and featured a De Dion rear axle and Girling disc brakes. Fully loaded, the car weighed only about 1,000 lb (450 kg). Versions for a 1100 cc Climax engine (Club) and a 1172 cc Ford engine (Sport) were also produced; both featured a live rear axle and drum brakes. Several cars were fitted with alternative engines by their owners, these included Coventry Climax 1500cc FWB and FPF and 1200 cc FWE, Maserati 150S 1500cc, DKW 1000cc SAAB 850cc and 750cc engines. There were two main body styles: one with a headrest and the other with no headrest, just two small fins. Some cars were later fitted with a closed body with gullwing doors to meet GT specifications. Despite the wide variety of engines installed, the car was primarily designed to compete in the 1100 cc class where it was one of the most successful cars during the mid- to late-1950s. In 1956, An Eleven, modified by Costin with a bubble canopy over the cockpit, was driven by Stirling Moss to a class world record of 143 mph (230 km/h) for a lap at Monza. Several class victories at Le Mans and Sebring followed, and the Eleven became Lotus’ most successful race car design. A 750cc version won the Index of Performance at Le Mans in 1957. In 1957, the Eleven underwent a major design change, including a new front suspension and improvements to the drivetrain. Although officially called Eleven Series 2, these late models are sometimes informally referred to as Lotus 13s, since they were produced between the 12 and 14 models and the 13 designation was not used by Lotus. There have been several replicas and re-creations of the Lotus Eleven, including the Kokopelli 11, the Challenger GTS, the Spartak and the best known, the Westfield XI. The car seen here is the first of the S2 cars, with the Formula 2 style double wishbone suspension layout and was given by Chapman to the most successful club drivers of the 1956 season. Alan Stacey took delivery of this car and won the small capacity Championship in 1957, running as a Team Lotus entry. Alan was very quick and went on to larger engined sports cars and then to F1. He crashed fatally at Spa in 1960. The X1 on show had two subsequent owners and then put away for 38 years. The present owner found the car and carefully refurbished the X1 without over-restoration or modernisation. The cars run with the original engine and all original aluminium body panels. The car is now used regularly on the road and for minor events.

This is a Type 14 Elite, the first enclosed Lotus, intended for use as a road car as well as for competition purposes. An ultra-light two-seater coupé, the Elite made its debut at the 1957 London Motor Car Show, Earls Court, as chassis #1008 , following a year in development, aided by “carefully selected racing customers”, before going on sale. The Elite’s most distinctive feature was its highly innovative fibreglass monocoque construction, in which a stressed-skin GRP unibody replaced the previously separate chassis and body components. Unlike the contemporary Chevrolet Corvette, which used fibreglass for only exterior bodywork, the Elite also used this glass-reinforced plastic material for the entire load-bearing structure of the car, though the front of the monocoque incorporated a steel subframe supporting the engine and front suspension, and there was a hoop at the windscreen for mounting door hinges and jacking the car up. The first 250 body units were made by Maximar Mouldings at Pulborough, Sussex. The body construction caused numerous early problems, until manufacture was handed over to Bristol Aeroplane Company. The resultant body was both lighter, stiffer, and provided better driver protection in the event of a crash. Sadly, the full understanding of the engineering qualities of fibreglass reinforced plastic was still several years off and the suspension attachment points were regularly observed to pull out of the fibreglass structure. The weight savings allowed the Elite to achieve sports car performance from a 75 hp 1216 cc Coventry Climax FWE all-aluminium straight-4 engine with fuel consumption at 35mpg. All production Lotus Elites were powered by the FWE engine. (Popular mythology says that cars left the factory with a variety of engines, but this is incorrect.) The FWE engine, derived from a water pump engine usually found bolted to a fire truck, was used by Lucas Electric for electrical component life testing in the presence of intense vibration. The car had independent suspension all round with transverse wishbones at the front and Chapman struts at the rear. The rear struts were so long, that they poked up in the back and the tops could be seen through the rear window. The Series 2 cars, with Bristol-built bodies, had triangulated trailing radius arms for improved toe-in control. Girling disc brakes, usually without servo assistance, of 9.5 in diameter were used, inboard at the rear. When leaving the factory the Elite originally fitted Pirelli Cinturato 155HR15 tyres. Advanced aerodynamics also made a contribution, giving the car a very low drag coefficient of 0.29 – quite low even for modern cars. This accomplishment is all the more remarkable considering the engineers did not enjoy the benefits of computer-aided design or wind tunnel testing. The original Elite drawings were by Peter Kirwan-Taylor. Frank Costin (brother of Mike, one of the co-founders of Cosworth), at that time Chief Aerodynamic Engineer for the de Havilland Aircraft Company, contributed to the final design. The SE was introduced in 1960 as a higher performance variant, featuring twin SU carburettors and fabricated exhaust manifold resulting in 85 bhp, ZF gearboxes in place of the standard “cheap and nasty” MG ones, Lucas PL700 headlamps, and a silver coloured roof. The Super 95 spec, with more power, from a higher-tuned engine with raised compression and a fiercer camshaft with 5 bearings. A very few Super 100 and Super 105 cars were made with Weber carburettors, for racing use. Among its few faults was a resonant vibration at 4000 rpm (where few drivers remained, on either street or track) and poor quality control, handicapped by overly low price (thus losing money on every car produced) and, “perhaps the greatest mistake of all”, offering it as a kit, exactly the opposite of the ideal for a quality manufacturer. Many drivetrain parts were highly stressed and required regreasing at frequent intervals. When production ended in 1963, 1030 had been built, although there are sources claiming that 1,047 were produced.

The original Elan was introduced in 1962 as a roadster, although an optional hardtop was offered in 1963 and a coupé version appeared in 1965, and there were examples of all of these here. The two-seat Lotus Elan replaced the elegant, but unreliable and expensive to produce Lotus Elite. It was the first Lotus road car to use a steel backbone chassis with a fibreglass body. At 1,600 lb (726 kg), the Elan embodied the Colin Chapman minimum weight design philosophy. Initial versions of the Elan were also available as a kit to be assembled by the customer. The Elan was technologically advanced with a DOHC 1557 cc engine, 4-wheel disc brakes, rack and pinion steering, and 4-wheel independent suspension. Gordon Murray, who designed the spectacular McLaren F1 supercar, reportedly said that his only disappointment with the McLaren F1 was that he couldn’t give it the perfect steering of the Lotus Elan. This generation of the two-seater Elan was famously driven by the character Emma Peel on the 1960s British television series The Avengers. The “Lotus TwinCam” engine was based on Ford Kent Pre-Crossflow 4-cylinder 1498 cc engine, with a Harry Mundy-designed 2 valve alloy chain-driven twin-cam head. The rights to this design was later purchased by Ford, who renamed it to “Lotus-Ford Twin Cam”. It would go on to be used in a number of Ford and Lotus production and racing models. Seen here was an example of the Drophead.

There was also a Plus 2 here. Introduced in 1967, the Elan +2 had a longer wheelbase and two rear seats and so was intended for those Lotus customers who needed space to carry (small) people in the back, without sacrificing the same basic principles which made the Elan so appealing. A fast and agile sport coupe, a number of different engines were fitted over the years, with the later models having 130 bhp and a 5 speed gearbox at their disposal, which gave a top speed of 120 mph and 0–60 acceleration of 7.9 seconds and 0-100 mph 21.8 seconds. 5,200 Elans +2 were made, with production ceasing in 1975. Fewer than 1,200 of these cars remain on the roads today. Their relative rarity, beautiful lines, impressive performance and practicality are the main factors for the rising interest on these cars among collectors.

First mid-engined road-going Lotus was the Europa. The concept originated during 1963 with drawings by Ron Hickman, director of Lotus Engineering (Designer of the original Lotus Elan, as well as inventor of the Black and Decker Workmate), for a bid on the Ford GT40 project. That contract went to Lola Cars as Colin Chapman wanted to call the car a Lotus and Henry Ford II insisted it would be called Ford. Chapman chose to use Hickman’s aerodynamic design which had a drag coefficient of Cd 0.29 for the basis for the Europa production model. The car was originally intended to succeed the Lotus 7. Volkswagen owned the rights to the Europa name in Germany so cars for sale in Germany were badged Europe rather than Europa. The original Europa used Lotus founder Colin Chapman’s minimalist steel backbone chassis that was first used in the Lotus Elan, while also relying on its fibreglass moulded body for structural strength. The four-wheel independent suspension was typical of Chapman’s thinking. The rear suspension was a modified Chapman strut, as used for Chapman’s earlier Formula racing car designs. Owing to the rubber suspension bushes used to isolate engine vibration from the car body, the true Chapman strut’s use of the drive shaft as the lower locating link could not be followed whilst still giving the precise track and handling desired. The forward radius arms were increased in size and rigidity, to act as a semi-wishbone. A careful compromise between engine mounting bush isolation and handling was required, culminating eventually in a sandwich bush that was flexible against shear but stiff in compression and tension. The car’s handling prompted automotive writers to describe the Europa as the nearest thing to a Formula car for the road. Aside from the doors, bonnet, and boot, the body was moulded as a single unit of fibreglass. The first cars has Renault 1470cc engines, and suffered from a number of quality issues as well as limited visibility. An S2, released in 1968 brought improvements to the build quality, but Lotus knew that the Renault engine was not powerful enough for what they thought the car could achieve on track and on the road, so the Europa underwent another update in 1971 when the Type 74 Europa Twin Cam was made available to the public, with a 105 bhp 1557cc Lotus-Ford Twin Cam engine and a re-designed bodyshell to improve rearward visibility. Initially with the same gearbox as the earlier cars, once the supply had been exhausted in 1972 a new stronger Renault four-speed gearbox was introduced. Mike Kimberley, who rose to become chief executive of Group Lotus, then a new engineer at Lotus, was appointed Chief Engineer of the Europa TC project. 1,580 cars were shipped as Europa “Twin Cam” before Lotus switched to a 126 bhp “Big Valve” version of the engine. The big valve “Europa Special” version was aspirated by Dell’Orto carburettors version of the same engine; in addition it also offered a new Renault five-speed (Type 365) gearbox option. It weighed 740 kg (1631 lb), Motor magazine famously tested a UK Special to a top speed of 123 mph, did 0–60 mph in 6.6 seconds, and ran the 1/4 mile in 14.9 sec. This at a time when all road tests were carried out with both a driver and passenger, with only the driver on board the 0–60 mph time would have been well under 6 seconds, a phenomenal performance for the period. Introduced in September 1972 the first 100 big valve cars were badged and painted to honour the just won Team Lotus’ 1972 F1 World Championship title with John Player Special as sponsors, all with five-speed gearbox, these were all black with gold pin stripe matching the livery of the GP cars – plus a numbered JPS dash board badge, becoming the first ever John Player Special commemorative motor vehicles. The “Special” name and colour scheme was planned to be dropped after the first 200 cars, reverting to the Twin Cam name, but such was the reaction to the new car that the name and pin stripe scheme remained until the end of Europa Production although colours other than black were made available. In the end only the numbered plaque distinguishing the first 100 JPS cars from other black Europa Specials. According to Lotus sources, no Special left the factory with “numbered JPS badges” or “JPS stickers” – these were added by the American importer & weren’t official done by Lotus. There were no “badged” cars sold in the UK, Australia, etc, just in the USA. In total 4710 Type 74s were produced of which 3130 were “Specials”.

Ford wanted to change a few things for the Mk2 Lotus-Cortina. The Mk1 had done all and more than they could expect in competition, but the public linked its competition wins with Lotus and its bad points with Ford. Ford still wanted to build a Mk2 Lotus and compete with it, but Lotus were moving from Cheshunt to Hethel so it was a bad time for them to build another model. Ford were also concerned with the unreliability of the Lotus built cars. So a decision was made at Ford that to continue with its competition drive and make the car more cost effective they would make the car at Dagenham themselves, alongside the other Cortinas. So the Mk2 had to be much easier to build than the Mk1 so that it could be made alongside Mk2 GT production, just with a different engine and suspension. The Mk2 took a while to appear, first appearing in 1967. The main difference was the choice of colours and the lack of a stripe, although most had them fitted at Ford dealers at extra cost. The only cosmetic changes made were a black front grille, 5.5J x 13 steel wheels and Lotus badges on rear wings and by the rear number plate. The badge on the front grille was an option at first. Unlike the Mk1, the Mk2 was also made in left hand drive from the start of production. The Mk2 Cortina Lotus also gained an improved and more powerful (109 bhp) engine, which was formerly supplied as the special equipment engine option on Lotus Elan and the Cortina Lotus Mk1. The gearbox ratios remained 2000E ones but the car now used the Mk2 GT remote-control gearchange. The car also had a different final drive of 3.77:1 rather than 3.9:1. The Mk2 was a wider car than the Mk1, so although they looked the same, the steel wheels had a different offset so as not to upset the tracking, and radial tyres were now standard. Another attraction was the larger fuel tank. The spare wheel could now be mounted in its wheel well, but the battery remained in the boot to aid weight distribution. The only real difference to the engine bay was the air cleaner mounted on top of the engine. The interior was almost identical to a GT. The Mk2 did exactly what Ford wanted, it was far more reliable whilst still quick enough to be used in competition, until it was replaced by the Escort Twin Cam. The car did receive a few updates, but none as urgent as the Mk1’s. Only a few months after production started, the Lotus badge on the rear panel was cancelled and a new TWIN CAM badge was fitted under the Cortina script on the boot lid. Despite the badge changes, Ford UK continued to market the model as the “Cortina Lotus”. The new combined clock and centre console was fitted. In late 1968 the entire Mk2 range received some cosmetic changes; for the Lotus, this meant that the 4 dials on top of the dash were brought down and made part of the dash. An internal bonnet release and a more conventional mounting for the handbrake were also phased in. A new single-rail gearshift mechanism was used. The car stayed in production until 1970. The Cortina Lotus was marketed in Europe as the Cortina Twin Cam in 1969/70. Two 4-door versions were supplied to the Mid-Anglia Constabulary for evaluation as use as a fast patrol and pursuit car by British Police forces. The trial never went beyond the two vehicles, which are both still in existence.

The Type 75 Elite, announced in 1974, was the first of a new generation of Lotus cars which represented a concerted push up-market. The imposition of VAT had effectively killed off the market for the range of models that Lotus had hitherto produced as kit cars, and the only way to stay profitable was to produce something which could sold at higher prices. So whilst Lotus would tell you that the Elite was a replacement for the Lotus Elan Plus 2, it was more accurate to say that it was a rival for cars like the Reliant Scimitar GTE and Lancia Beta HPE. The styling was quite unlike anything that Lotus had produced before, with distinctive wedge lines penned by Oliver Winterbottom which hid the fact that the bodies were produced out of two separate glassfibre moulds and they had to join up in the middle around the waistline. The shooting brake style, with a hatchback as well as the fact that the Elite had 4 seats made it reasonably practical. luggage compartment. Mechanically there were fewer surprise. It was front engined with rear wheel drive, and had 4-wheel independent suspension using coil springs. The Elite was Lotus’ first car to use the 907 aluminium-block 4-valve, DOHC, four-cylinder, 1973cc, developing 155 bhp. which had previously been used in the Jensen-Healeys, where all the reliability issues had been found) The 907 engine ultimately became the foundation for the 2.0 litre and 2.2 litre Lotus Esprit powerplants, the naturally aspirated 912 and the turbocharged 910. The Elite was fitted with a 4 or 5 speed gearbox and from January 1976 automatic transmission was optional. The Elite had a claimed drag co-efficient of 0.30 and at the time of launch it was the world’s most expensive four cylinder car. Elites were available in 4 main specification variations, 501, 502, 503, and later on 504. The 501 was the ‘base’ version. The 502 added air conditioning, the 503 had power steering and the 504 added automatic transmission. The Elite was the basis for a coupe model, the Eclat which was launched in October 1975. Facelifted versions of both came in 1980, with a larger 2.2 litre engine and refinements to the trim. The Elite would live a couple of years in this form, but market interest shifted to the Coupe and when this was given a more significant revision a couple of years later, and a new name of Excel, the Elite was dropped from the range. Although 2535 of them were made, they are rare these days, so it was nice to see this 503 model.

Perhaps my favourite of all the Lotus models on show were the early Esprit models. The silver Italdesign concept that eventually became the Esprit was unveiled at the Turin Motor Show in 1972 as a concept car, and was a development of a stretched Lotus Europa chassis. It was among the first of designer Giorgetto Giugiaro’s polygonal “folded paper” designs. Originally, the name Kiwi was proposed, but in keeping with the Lotus tradition of having all car model names start with the letter “E”, the name became Esprit. The production Esprit was launched in October 1975 at the Paris Auto Show, and went into production in June 1976, replacing the Europa in the Lotus model lineup. These first cars eventually became known as S1 Esprits. With a steel backbone chassis and a fibreglass body, the Esprit was powered by the Lotus 907 4-cylinder engine, as previously used in the Jensen Healey. This engine displaced 2.0 litre, produced 160 bhp in European trim 140 bhp in US/Federal trim, and was mounted longitudinally behind the passengers, as in its predecessor. The transaxle gearbox was a 5-speed manual unit, previously used in the Citroën SM and Maserati Merak; it featured inboard rear brakes, as was racing practice at the time. The Series 1 embodied Lotus’ performance through light weight mantra, weighing less than 1,000 kg (2,205 lb). The original Esprit was lauded for its handling and is said to have the best steering of any Esprit. However, it was generally regarded as lacking power, especially in markets such as the United States where the engine was down-rated for emissions purposes. Lotus’ claim of 0-60 mph in 6.8 seconds and a top speed of 138 mph may be thought of as optimistic – actual road test times indicated 0-60 mph in 8 seconds and a top speed of around 133 mph. The S1 Esprit can be distinguished from later Esprits by a shovel-style front air dam, Fiat X1/9 tail lights, lack of body-side ducting, and Wolfrace alloy wheels. Inside the car, the most obvious indication of an S1 Esprit is a one-piece instrument cluster with green-faced Veglia gauges. The car gained fame through its appearance in the James Bond film The Spy Who Loved Me (1977) where a fictionally-modified version was featured in a long action sequence. Bond’s Esprit car is first chased on road, by a motorcycle, then by another car, and then a helicopter, then converts into a submarine for an undersea battle. A series of improvements made to the Esprit during its initial run culminated in the S2 Esprit, which was introduced in 1978. The most obvious of these changes are intake and cooling duct “ears” located behind the rear quarter window, tail lights from the Rover SD1, and an integrated front spoiler. S2 Esprits also used 14-inch Speedline alloy wheels designed specifically for Lotus. Other changes included relocating the battery from above the right side fuel tank (under the rear quarter window) to the rear of the car, adding an access door to the engine cover, as well as replacing the instrument cluster made by Veglia with individual gauges made by Smiths and using different style of switches on the dashboard. During this era, a special edition car was released to commemorate Lotus’s racing victories and their victory in the 1978 F1 World Championship. Sharing the black and gold colour scheme of Lotus’ then F1 sponsor, John Player & Sons, these cars are commonly known as the John Player Special (JPS) Esprits. The “JPS” Esprit has the same mechanicals as the regular two-litre S2. According to Lotus themselves a limited series of 300 was built, but most likely the total was considerably lower.Lotus’ records of production figures are notoriously vague, but best estimates suggest that 149 JPS Esprits were produced. The S2.2 was produced as a stop-gap model from May 1980, almost identical to the S2 but with an enlarged (2.2 litre) type 912 engine used. This kept horsepower the same, but bumped up torque from 140 lb·ft to 160 lb·ft. Importantly, the S2.2 also introduced the use of a galvanised chassis, although it did not benefit from the succeeding S3’s chassis improvements. These cars are extremely rare even among Esprits: according to Lotus themselves, only 88 were produced in its thirteen-month production span. In 1980 the first factory turbocharged Esprit was launched. Initially, this was another special edition model commemorating F1 ties and reflecting current sponsorship, this time in the blue, red and chrome livery of Essex Petroleum, and is therefore known as the Essex Esprit. The new turbocharged dry-sump type 910 engine produced 210 hp and 200 lb·ft of torque. 0-60 mph could be achieved in 6.1 seconds, with a top speed of 150 mph. These performance improvements were coupled to a redesign and strengthening of the chassis and rear suspension, where an upper link was added to alleviate strain on the driveshafts, along with brake improvements. The Essex cars introduced a Giugiaro-designed aerodynamic body kit with a rear lip spoiler, prominent louvered rear hatch, more substantial bumpers, a deeper front airdam, and air ducts in the sills just ahead of the rear wheels, which were 15″ Compomotive three piece items. Internally, scarlet leather, combined with a roof-mounted Panasonic stereo, made for a dramatic environment. 45 Essex Esprits were built, interspersed and followed by a number of non Essex-liveried but otherwise identical specification dry-sump turbo cars. Two Essex-spec Turbo Esprits – one in white and the other in copper – were featured in the James Bond film For Your Eyes Only (1981), although these were scripted as the same vehicle – the white one was destroyed by an anti-burglar explosion system in Spain, while the copper red one was a “rebuild” of the original (actually a joke between Bond and Q in the latter’s laboratory), and was fully functional (the copper exterior paint colour for the replacement car was chosen to make the car stand out more in filming against the snowy background of Cortina, Italy, the only locale in which it appears). By the close of 1980, Lotus was effectively building three different models of Esprit, with distinct chassis designs and body moulds – the Domestic S2.2, the Export S2.2, and the dry-sump Turbo Esprit. Introduced in April 1981, the Turbo Esprit and S3 Esprits marked a necessary consolidation: both new models had a common chassis, inheriting much of the configuration of the Essex cars, whilst body production was based on a single common set of moulds. The S3 continued to use the 2.2 litre type 912 engine of the S2.2, whilst the Turbo Esprit reverted to a less complex wet-sump lubrication system, retaining the power and torque outputs of its dry-sump predecessor. The interior for both cars was revised and featured new trim; combined with changes to the body moulds this resulted in more headroom and an enlarged footwell. Externally, the Turbo Esprit retained the full aerodynamic body kit of the Essex cars, and featured prominent ‘turbo esprit’ decals on the nose and sides; the S3 gained the more substantial bumpers, yet retained the simpler sill line and glazed rear hatch of the S2.2 body style. Both models were supplied with 15″ BBS alloy wheels. For the 1985 model year, the S3 and Turbo underwent some slight alterations to the bodywork and to the front suspension. In April 1986, the final incarnations of the Giugiaro-styled Esprit were announced, with raised engine compression giving rise to the ‘HC’ moniker. This increased the output of the naturally aspirated engine to 172 hp and 160 lb·ft for the Esprit HC, and to 215 hp and 220 lb·ft for the Turbo Esprit HC, with the increased torque available at a lower rpm. For markets with stringent emissions requirements (mainly the United States), Lotus introduced the HCi variant, teaming the higher compression engine with Bosch KE-Jetronic fuel injection and a catalytic converter- the first fuel-injected Esprits. This engine had the same peak power as the carburettor version, but at a somewhat higher engine speed, and torque dropped to 202 lb·ft. Among the cars seen here was one of the rare JPS limited edition cars.

There was also numerous examples of the Excel here. Known internally as the Type 89, the Excel, built from 1982 to 1992, was a development of the earlier Lotus Eclat, which itself was based on the Type 75 Elite. Although a promising design, the Elite and Eclat had suffered from numerous quality control issues which were difficult for owners to accept given the price of the cars. The Excel was a concerted effort to address these, and it stood every chance of so doing, as it took advantage of the relationship with Toyota. This had started when Toyota engaged Lotus to assist with engineering work on the Supra. During this period, Toyota then became a major shareholder in Lotus. Part of the deal between the two included the use of many Toyota mechanical components in Lotus’ cars. The original Excel (aka the Eclat Excel) used the W58 manual transmission, driveshafts, rear differential, 14×7 in alloy wheels, and door handles from the Supra Mk II, which was made from 1982 to 1986. The engine was the familiar all-aluminium, DOHC 2.2 litre Lotus 912 Slant Four which was also used in the Lotus Esprit S3. During its lifetime, the Excel received two major upgrades. With the introduction of the Excel SE which had a 180 bhp engine vs the standard 160 bhp car in October 1985, the bumpers, wing and interior was changed, including a new dashboard. In October 1986 the Excel SA with automatic gearbox was introduced. Further facelifts in 1989 saw Citroën-derived mirrors, as featured on the Esprit, and 15 inch OZ alloy wheels to a similar pattern as the Esprit’s. According to Lotus records, only 1 Excel was manufactured to USA specification. The lack of release in the USA was due to the high emission regulations (which would hinder the car’s performance), and poor sales of the car in Europe.

In 1987, a new version of the mid-engined Esprit was unveiled, incorporating rounder styling cues given by designer Peter Stevens (who later designed the McLaren F1). A new Lotus patented process was introduced to create the new body, called the VARI (Vacuum Assisted Resin Injection) process, which offered more advantages than the previous hand laid process. Kevlar reinforcement was added to the roof and sides for roll-over protection, resulting in an increase of the Esprit’s torsional rigidity by 22 percent. Giugiaro is said to have liked the restyling, claiming it was perhaps too close to his original design. The Stevens styled cars retained the mechanical components of the previous High Compression Esprit and Turbo Esprit, but introduced a stronger Renault transaxle, which necessitated a move to outboard rear brakes. However, the MY 1988 North American Esprit Turbo kept its Citroën SM type transaxle and the Bosch K-Jetronic fuel injection system used in the previous model year. The car’s Type 910 engine retained 215 bhp and 220 lb·ft, but decreased its zero to sixty from 5.6 seconds to a varied time between 5.4 – 5.1 seconds and a top speed of over 150 mph. The exterior style changes were accompanied by a redesign of the interior, allowing a little more space for the occupants. The Stevens styled Esprit is often known by its project code of X180. In 1989, the Esprit was again improved with the GM multi-port, electronic fuel injection system and the addition of a water to air intercooler, which Lotus has named the Chargecooler, producing the SE (Special Equipment). This inline-four engine was known as the Type 910S. Horsepower was pushed up to 264 with 280 available on overboost and zero to sixty miles per hour times reduced to 4.7 seconds with a top speed of over 160 mph. Several modifications were made to the body kit as well, like side skirts which are parallel to the body, five air ducts in the front air dam, wing mirrors from the Citroën CX and the addition of a rear wing. Along with the SE, Lotus produced the little seen Esprit S, a midrange turbocharged car offering fewer appointments and 228 hp, as well as the standard turbo still offering 215 hp . The N/A and lower-powered turbo were cancelled after 1990, and the S in 1991. Another unusual variant was a two-litre “tax special” developed for the Italian market, fitted with an intercooled and turbocharged version of a new 1,994 cc version of the venerable 900-series four-cylinder engine. Equipped with SE trim, this appeared in December 1991 and produced 243 PS at 6,250 rpm. Beginning in the autumn of 1996, this engine became available in other markets as well. The Esprit was a popular and successful addition to the American IMSA Bridgestone Supercar Championship and as a result Lotus produced the SE-based X180R, with horsepower bumped to 300 and with racing appointments. The Sport 300 was a derivative of the X180R sold in Europe, which included many modifications. These are known as the fastest of the four-cylinder Esprits and among the most desirable. In 1993, another exterior and interior revamp of the car resulted in the S4 which was the first model to include power steering. The exterior redesign was done by Julian Thompson, which included a smaller rear spoiler placed halfway up the rear decklid. Other major changes were to the front and rear bumpers, side skirts and valence panels. New five spoke alloy wheels were also included in the redesign. The S4 retained the same horsepower as the SE at 264 hp.The S4 was succeeded in 1994 by the S4s (S4 sport), which upped power to 300 bhp and 290 lb·ft of torque, improving all-around performance while retaining the comfort of the previous version. Top speed was increased to 168 mph, skidpad increased to 0.91g, an increased slalom of 61.7 mph and a 0-60 mph time of 4.6 seconds. Although the engine kept its 2.2-litre capacity, many modifications were added to improve engine performance. Some of the changes were enlarged inlet ports, cylinder head modifications, a re-calibrated ECM and a revised turbocharger. The most visible external styling changes was the addition of a larger rear wing taken from the Sport 300. In 1996 the Esprit V8 used Lotus’ self-developed all-aluminium, twin-turbocharged (Garrett T25/60 turbos) 90-degree V-8, Code-named Type 918, in front of the same Renault transmission as before with no Chargecooler. Derek Bell developed an uprated gearbox that overcame a lot of the gearbox problems with a much thicker single piece input shaft. The Type 918 engine was detuned from a potential 500 bhp to 350 bhp to prevent gearbox damage due to the fragility of the Renault UN-1 transmission. In period tests, zero to sixty miles per hour came in at 4.4 seconds and top speeds of over 175 mph were achieved. Produced alongside V8 models was the GT3, a turbocharged four-cylinder car with the type 920 2.0 litre chargecooled and turbocharged engine which had been used only in Italian market cars previously. In 1998 the V8 range was split into SE and GT specifications, both cars with a much changed interior configuration, both offering similar performance with the SE being the more luxurious of the two. The ultimate incarnation of the Esprit came in 1999 with the Sport 350. Only 50 were made, each offering 350 horsepower (per the name) and various engine, chassis and braking improvements, like the addition of AP Racing brakes, stiffer springs and a revised ECU. Several visual changes were made as well, including the addition of a large carbon fibre rear wing on aluminium uprights in place of the standard fibreglass rear wing. By this time the Esprit could reach 60 mph in 4.3 seconds as well as reaching 0-100 mph in less than 10 seconds, and weighed 1,300 kg (2,866 lb) as a result of many modifications. Thereafter, Lotus made little development aside from minor cosmetic changes including a switch to four round tail lights for the 2002 model year. Esprit production ceased in February 2004 after a 28 year production run. A total of 10,675 Esprits were produced.

There has only ever been one front wheel drive model with Lotus badges on it, the “M100” Elan sports car. Like many specialist produced cars of the era, there was a long wait for this car form when news first broke that it was under development to the actual release of cars people could buy. The M100 Elan story goes back to 1986 and the purchase of Lotus by General Motors which provided the financial backing to develop a new, small, affordable car in the same spirit as the original Elan, the last of which had been built in December 1972. A development prototype, the M90 (later renamed the X100) had been built a few years earlier, using a fibreglass body designed by Oliver Winterbottom and a Toyota-supplied 1.6-litre engine and transmission. Lotus was hoping to sell the car through Toyota dealerships worldwide, badged as a Lotus Toyota, but the project never came to fruition and the prototype was shelved, although Lotus’s collaboration with Toyota had some influence on the design of the Toyota MR2. The idea of a small roadster powered by an outsourced engine remained, however, and in late 1986 Peter Stevens’s design for the Type M100 was approved and work began by Lotus engineers to turn the clay styling buck into a car that could be built. This process was completed in just under three years, a remarkably short time from design to production car. The M100 Elan was conceived as a mass-market car and in particular one that would appeal to US buyers. Consequently, Lotus put an enormous effort (for such a small firm) into testing the car; over a two-year period 19 crash cars and 42 development vehicles were built, logging nearly a million test miles in locations from Arizona to the Arctic. The Elan was driven at racing speeds for 24 hours around the track at Snetterton. Finally each new car was test-driven for around 30 miles at Lotus’s Hethel factory to check for any manufacturing defects before being shipped to dealers. The choice of front-wheel drive is unusual for a sports car, but according to Lotus sales literature, “for a given vehicle weight, power and tyre size, a front wheel drive car was always faster over a given section of road. There were definite advantages in traction and controllability, and drawbacks such as torque steer, bump steer and steering kickback were not insurmountable.” This was the only front-wheel-drive vehicle made by Lotus. Every model made since the M100 Elan, such as the Lotus Elise, has been rear-wheel drive. The M100 Elan’s cornering performance was undeniable (on release the Elan was described by Autocar magazine as “the quickest point to point car available”). Press reaction was not uniformly positive, as some reviewers found the handling too secure and predictable compared to a rear-wheel-drive car. However, the Elan’s rigid chassis minimised roll through the corners and has led to its description as ‘the finest front wheel drive [car] bar none’. Unlike the naturally aspirated version, the turbocharged SE received power steering as standard, as well as tyres with a higher ZR speed rating. The M100 Elan used a 1,588 cc double overhead camshaft (DOHC) 16-valve engine, sourced from the Isuzu Gemini and extensively modified by Lotus (a third generation of this engine was later used in the Isuzu Impulse), which produced 162 hp. 0–60 acceleration time was measured by Autocar and Motor magazine at 6.5 seconds, and a top speed of 137 mph was recorded. Significant differences in the Isuzu-Lotus engine from the original include a new exhaust system, re-routed intake plumbing for better thermodynamic efficiency, improved engine suspension, and major modifications to the engine control unit to improve torque and boost response. Almost all models featured an IHI turbocharger. Two variants were available at launch, the 130 bhp Elan 1.6 (retailing at £17,850) and the 162 bhp Turbo SE (£19,850). Initial sales were disappointing, perhaps because its launch coincided with a major economic recession in the UK and USA, and perhaps also because it coincided with the cheaper Mazda MX-5 which was arguably similar in concept, though the MX-5 was quite intentionally nostalgic and old fashioned (apeing the original Elan), while the M100 was deliberately futuristic, modern and forward looking. The Elan was regarded as a good product in a bad market, but was also very expensive to make (the cost to design and produce the dashboard alone was more than the total cost of the Excel production line), and sales figures were too low to recoup its huge development costs. Altogether 3,855 Elans were built between November 1989 and July 1992, including 129 normally aspirated (non-turbo) cars. 559 of them were sold in the US, featuring a ‘stage 2 body’ which had a different rear boot spoiler arrangement together with a lengthened nose to accommodate a USA-compliant crash structure and airbag, and 16-inch wheels (optional in most markets, standard in the U.S.) instead of 15-inch as on the UK model. A limited edition of 800 Series 2 (S2) M100 Elans was released during the Romano Artioli era (produced June 1994–September 1995) when it was discovered that enough surplus engines were available to make this possible. According to Autocar magazine, the S2 addressed some of the concerns over handling, but power was reduced to 155 bhp and the 0–60 acceleration time increased to 7.5 seconds, due to the legislative requirement to fit a catalytic converter in all markets. The S2s have very similar performance to the USA vehicles, having an identical engine management system calibration and a slightly lower overall vehicle weight.

It is now over 20 years since Lotus launched the Elise, a model which showed a return to the core values of simplicity and light-weight which were cornerstones of Colin Chapman’s philosophy when he founded the marque in 1955. The first generation Elise was produced for just over 4 years, with a replacement model, the Series 2 arriving in October 2000. It came about as the Series 1 could not be produced beyond the 2000 model production year due to new European crash sustainability regulations. Lacking the funding to produce a replacement, Lotus needed a development partner to take a share of investment required for the new car. General Motors offered to fund the project, in return for a badged and GM-engined version of the car for their European brands, Opel and Vauxhall. The result was therefore two cars, which although looking quite different, shared much under the skin: a Series 2 Elise and the Vauxhall VX220 and Opel Speedster duo. The Series 2 Elise was a redesigned Series 1 using a slightly modified version of the Series 1 chassis to meet the new regulations, and the same K-series engine with a brand new Lotus-developed ECU. The design of the body paid homage to the earlier M250 concept, and was the first Lotus to be designed by computer. Both the Series 2 Elise and the Opel Speedster/Vauxhall VX220 were built on the same production line, in a new facility at Hethel. Both cars shared many parts, including the chassis, although they had different drive-trains and power-plants. The VX220 carried the Lotus internal model identification Lotus 116, with the code name Skipton for the launch 2.2 normally aspirated version and Tornado for the 2 litre Turbo which came out in 2004. Fitted with 17 inch over the Elise’s 16 inch front wheels, the Vauxhall/Opel version ceased production in late 2005 and was replaced by the Opel GT for February 2007, with no RHD version for the United Kingdom. The Elise lived on. and indeed is still in production now, some 15 years later, though there have been countless different versions produced in that time. Whilst the first of the Series 2 cars came with the Rover K-Series engine, and that included the 111S model which had the VVC engine technology producing 160 hp, a change came about in 2005 when Lotus started to use Toyota engines. This was initially due to Lotus’ plans to introduce the Elise to the US market, meaning that an engine was needed which would comply with US emissions regulations. The selected 1.8 litre (and later 1.6 litre) Toyota units did, and the K-series did not. that MG-Rover went out of business in 2005 and engine production ceased confirmed the need for the change. Since then, Lotus have offered us track focused Elise models like the 135R and Sport 190, with 135 bhp and 192 bhp respectively, as well as the 111R, the Sport Racer, the Elise S and Elise R. In 2008 an even more potent SC model, with 218 bhp thanks to a non-intercooled supercharger was added to the range. In February 2010, Lotus unveiled a facelifted version of the second generation Elise. The new headlights are now single units; triangular in shape they are somewhat larger than the earlier lights. The cheapest version in Europe now has a 1.6 litre engine to comply with Euro 5 emissions, with the same power output as the earlier 1.8 136bhp car. Lotus has been through some difficult times in recent years, but things are looking more optimistic again, with production numbers having risen significantly in the last couple of years, after a period when next to no cars were made. The Elise is still very much part of the range. Seen here were an array of Series 1 and Series 2 models.

 

We are now on the third generation Exige and several of them were here as well as some of the earlier models. The first Exige was launched in 2000 and was effectively a closed coupe version of the Elise. It was fitted with a naturally aspirated 1.8 litre Rover K Series Inline-four engine in VHPD (Very High Performance Derivative) tune. It produces 177 bhp at 7,800 rpm in standard form. There was also a “track spec” version with 192 bhp available. The car has a five-speed manual gearbox, and a claimed top speed of 219 km/h (136 mph). 0–60 mph was achieved in 4.7 seconds and 0–100 km/h (62 mph) in 4.9 seconds. The first Exige used the round, less aggressive headlights of the first generation Elise, although the Elise was updated soon after the introduction of the Exige. The Series 1 was built until 2002, and 604 examples were made. It was not replaced until the Series 2 of 2004.

 

Lotus dusted off the Europa name for a new car In 2005, based on the Elise, which was officially introduced at the 2006 Geneva Motor Show. Lotus Europa S production commenced in July 2006 and continued to 2010. The engine was a 2.0 litre turbo delivering 197 bhp at 5,400 rpm, with a maximum torque of 272 N·m (201 lb·ft) at 5,400 rpm, delivering 0-60 mph in 5.6 seconds and a maximum speed of 143 mph. Lotus did not export the Europa S to the USA, but despite this, the American manufacturer Dodge developed an electric vehicle based on the Europa, known as the Dodge Circuit, which it planned to bring to the US market by 2010, but the project was cancelled in May 2009. The Europa SE was unveiled at the Geneva International Motor Show on 5 March 2008. The Europa was an upgraded model with more comfort in mind, intended to bring in more customers. The Europa S motor was modified to bring power to 222 bhp and torque to 300 N·m (221 lb·ft). Neither version was a success, though and the Europa was discontinued in 2010 after a short model life.

Developed under the project name Project Eagle, this car was launched as the Evora on 22 July 2008 at the British International Motor Show. The Evora is based on the first all-new vehicle platform from Lotus Cars since the introduction of the Lotus Elise in 1995 (the Exige, introduced in 2000, and the 2006 Europa S are both derivatives of the Elise Evora was planned to be the first vehicle of three to be built on the same platform and was the first product of a five-year plan started in 2006 to expand the Lotus line-up beyond its track-specialised offerings, with the aim of making Evora a somewhat of a more practical road car that would appeal to the mainstream. As such it is a larger car than recent Lotus models Elise and its derivatives (Exige, Europa S, etc.), with an unladen weight of 1,383 kg (3,049 lb). It is currently the only Lotus model with a 2+2 configuration, although it is also offered in a two-seater configuration, referred to as the “Plus Zero” option. It is also the only 2+2 mid engined coupé on sale. The interior is larger to allow taller persons of 6’5″ to fit. The cooled boot behind the engine is large enough to fit a set of golf clubs, although Lotus Design Head Russell Carr denies that this was intentional. Lotus intends Evora to compete with different market sectors including the Porsche Cayman. The name “Evora” keeps the Lotus tradition of beginning model names with an “E”. The name is derived from the words evolution, vogue, and aura. and it of course sounds similar to Évora, which is the name of a Portuguese city and UNESCO World Heritage Site. Sales started in summer 2009, with an annual target of 2000 cars per year, with prices between £45,000 and just over £50,000. and in America from the beginning of 2010. The Evora received several accolades at its launch from the British motoring press, including: Britain’s Best Driver’s Car 2009 from Autocar and Car of the Year 2009, from Evo. Sales, however, were far from target, as the car was seen as too costly. A more powerful Evora S was launched in 2010 with a supercharged equipped 3.5-litre V6. A facelifted and more powerful Evora 400 model was unveiled at the 2015 Geneva Motor Show.

MASERATI

Oldest Maserati here was this (recreation) of the A6 CGS Barchetta of the mid 50s.

The original Maserati Quattroporte (Tipo AM107) was built between 1963 and 1969. It was a large saloon powered by V8 engines—both firsts for a series production Maserati. The task of styling the Quattroporte was given to Turinese coachbuilder Pietro Frua, who drew inspiration from a special Maserati 5000 GT (chassis number 103.060) he had designed in 1962 for Prince Karim Aga Khan. While the design was by Frua, body construction was carried out by Vignale. The Quattroporte was introduced at the October-November 1963 Turin Motor Show, where a pre-production prototype was on the Maserati stand next to the Mistral coupé. Regular production began in 1964. The Tipo 107 Quattroporte joined two other grand tourers, the Facel Vega and the Lagonda Rapide, capable of travelling at 200 km/h (124 mph) on the new motorways in Europe. It was equipped with a 4.1-litre V8 engine, producing 260 hp at 5,000 rpm, and either a five-speed ZF manual transmission or a three-speed Borg Warner automatic on request. Maserati claimed a top speed of 230 km/h (143 mph). The car was also exported to the United States, where federal regulations mandated twin round headlamps in place of the single rectangular ones found on European models. Between 1963 and 1966, 230 units were made. In 1966, Maserati revised the Tipo 107, adding the twin headlights already used on the U.S. model. A leaf-sprung solid axle took place of the previous De Dion tube. The interior was completely redesigned, including the dashboard which now had a full width wood-trimmed fascia. In 1968 alongside the 4.1-litre a 4.7-litre version became also available (AM107/4700), developing 286 bhp. Top speed increased to a claimed 255 km/h (158 mph), making the Quattroporte 4700 the fastest four-door sedan in the world at the time. Around 500 of the second series were made, for a total of 776 Tipo 107 Quattroportes. Production ended in 1969.

The Maserati Indy (Tipo AM 116) is a four-seater fastback grand tourer produced from 1969 to 1975. The Indy was conceived as an alternative to the Ghibli offering a V8 engine and room for four people; it effectively replaced both the ageing six-cylinder 2+2 Maserati Sebring—which descended from the 1957 3500 GT— and the first generation Quattroporte. Two coachbuilders showed their proposals at the November 1968 Salone dell’automobile di Torino, both based on a Maserati 4.2-litre chassis. On Ghia’s stand there was the Simùn, a 2+2 berlinetta designed by Giorgetto Giugiaro; on Carrozzeria Vignale’s, a sleek 4-seater fastback penned by Giovanni Michelotti. Both coachbuilders had already an established relationship with Maserati, as Vignale had been responsible for the 3500 GT Spyder, Mexico and Sebring, while Giugiaro had recently penned the Ghibli at Ghia. Vignale’s prototype was preferred, and the production model was launched by Maserati at the Geneva Motor Show the following March. The car was christened Indy in honour of Maserati’s two victories at the Indy 500. At its launch in 1969 the Indy was offered with a 4.2-litre V8 engine. From 1970 a 4.7-litre Indy 4700 was offered alongside the 4200; the same year some interior updates were introduced, including seats with retractable headrests and a new dashboard. In 1972, Maserati added the Indy 4900 to the range, equipped with the new 4.9-litre V8. Production of the Indy ended in 1975. In total 1,104 were produced, 440 of them Indy 4.2s, 364 Indy 4.7s and 300 Indy 4.9s. These days the cars worth a fraction of the prices charged for a Ghibli, which makes them something of a bargain to my mind.

 

The Merak was the marque’s entry level car from the 1970s, introduced at the 1972 Paris Auto Show, over a year after the Bora, a car whose front part of the bodyshell up to the doors, it shares. The front ends are differenced mainly by the use of dual chrome bumpers in place of twin trapezoidal grilles, but the similarities end at the B-pillar. Unlike its bigger sister the Merak doesn’t have a true, fully glassed fastback, but rather a cabin ending abruptly with a vertical rear window and a flat, horizontal engine bonnet pierced by four series of ventilation slats. Giugiaro completed the vehicle’s silhouette by adding open flying buttresses, visually extending the roofline to the tail. The main competitors of the Merak were the similarly Italian, mid-engined, 3-litre and 2+2 Dino 308 GT4 and Lamborghini Urraco P250. However unlike its transverse V8-engined rivals the Merak used a more compact V6, that could therefore be mounted longitudinally. Having been designed during the Citroën ownership of Maserati, certain Citroën hydropneumatic systems were used in the Merak, as for the Bora. These included the braking system and the clutch which were both hydraulically assisted and operated, and the pop-up headlights were hydraulically actuated. After 1976, when the French manufacturer gave up cbontrol of Maserati, the Citroën-derived parts were gradually replaced by more conventional systems. In 1977 Alejandro de Tomaso purchased Maserati and the Bora was discontinued after a production run of less than 600 cars, while the Merak remained on sale for six more years. The Merak’s V6 engine descended from the 2.7 litre Tipo C.114 originally designed by Giulio Alfieri in 1967 for use in the Citroën SM, that was bored out to 91.6 mm to displace 2,965 cc. It was a chain-driven double overhead camshaft, 12-valve unit featuring an unusual 90° angle between the cylinder banks. The lubrication system used a wet sump and an oil cooler. This V6 did not end its days on the Merak: it was later modified and made into the first ever production twin-turbocharged engine in the Biturbo, ending its career in the 1990s Ghibli after reaching the highest specific output of any production engine at the time. The powerplant was mounted longitudinally behind the passenger compartment, and joined through a single-plate dry clutch to a 5-speed, all syncromesh Citroën transaxle gearbox and a limited-slip differential. The original Merak’s three-litre engine produced 190 PS at 6000 rpm. Three twin-choke Weber carburettors (one 42 DCNF 31 and two 42 DCNF 32) fed the engine, and the compression ratio was 8.75:1. Maserati declared a top speed of over 240 km/h (149 mph). Early Meraks (1972 to 1975) were fitted with the Citroën SM’s dashboard, characterised by oval instrument gauges inset in a brushed metal fascia and a single-spoke steering wheel. 630 were made up to 1974. The lightened and more powerful Merak SS (Tipo AM122/A) was introduced at the 41st Geneva Motor Show in March 1975, although it did not enter production until the next year. It featured a 50 kg weight reduction and a 30 PS power increase to 220 PS (217 hp), thanks to the adoption of three larger 44 DCNF 44 carburettors and a higher 9:1 compression ratio. The SS was recognisable from a black grille between the pop-up headlights. A Maserati-designed upper fascia with round instruments and a four-spoke steering wheel replaced the previous SM-derived interior furniture. Later cars were bestowed with the full driver-oriented dashboard and three-spoke padded steering wheel of the Maserati Bora. The US-spec version of the Merak SS also saw a return to traditional hydraulics, eliminating the last of the Citroen high pressure system. 1000 units of the SS had been made by 1983, when all Merak production ceased. A third version of the Merak was made, In November 1977 at the Turin Auto Show, De Tomaso launched the Merak 2000 GT (Tipo AM122/D), which was basically a Merak with a smaller two-litre powerplant. It was built almost exclusively for the Italian market, where a newly introduced law strongly penalised cars with engine capacity over 2000 cc by subjecting them to a 38% Value Added Tax against the usual 19% VAT. The Merak’s competitors already offered similar two-litre models, specifically the Urraco P200 and Dino 208 GT4. The Merak 2000 GT featured a 1,999 cc engine generating 170 PS (168 hp) at 7000 rpm. Colour choice was limited to two shades: metallic light blue or gold. The two-litre cars were also distinguished by a black tape stripe running just below the mid-body character line, matte black bumpers in place of the usual chrome and the absence of the front spoiler, available as an optional. The SS’s front bonnet with the grille between the headlights was used on 2000 GTs. When production ended in 1983 just 200 Meraks 2000 GT had been made. Although a total of 1830 Merak models were made, they are rare cars now. Their low values meant that when they went wrong, which they inevitably did, it was not economic to repair or restore them, and a large number have been scrapped, which is a pity, as this is a great looking car.

Top of the range throughout the 1970s was the stunning Khamsin and there was one of them here. Introduced on the Bertone stand at the November 1972 Turin Auto Show. and designed by Marcello Gandini, it was Bertone’s first work for Maserati. In March 1973 the production model was shown at the Paris Motor Show. Regular production of the vehicle started only a year later, in 1974. The Khamsin was developed under the Citroën ownership for the clientele that demanded a front-engined grand tourer on the lines of the previous Ghibli, more conventional than the mid-engined Bora. The Khamsin’s body is prominently wedge-shaped, with a fastback roofline and kammback rear end. The tail is characterized by a full-width glass rear panel, carrying inset “floating” tail lights. Combined with the wide, almost all-glass rear hatch this gave exceptional rear visibility in comparison to most cars, especially similar sports cars. Cosmetic triangular vented panels are inlaid in the C-pillar, with the right-hand one hiding the fuel filler cap. Another distinguishing feature is the engine bonnet, pierced by asymmetrical vents. Design features as the wedge body, glazed tail panel and the location of the fuel filler cap all carry Gandini’s signature, as they were all present on his earlier Lamborghini Espada. Despite being marketed as a 2+2, the leather-trimmed rear seats, nestled between the two fuel tanks, were found too lacking in headroom and legroom to be usable. The complete instrumentation included gauges for speedometer, tachometer, water temperature, oil temperature, oil pressure, voltmeter and a clock. The Khamsin used an all-steel monocoque construction, with a rear Silentbloc-bushing insulated tubular subframe supporting the rear suspension and differential. Suspension was double wishbones all around – a major improvement over the Ghibli’s leaf-sprung solid axle – with coaxial springs and shock absorbers (single upfront, double at the rear) and anti-roll bars. The front-mid mounted engine gave the car a 50/50 weight distribution; it was pushed so far back towards the firewall that the full size spare tyre could be stored beneath the radiator in front of it, thus freeing up space in the boot. Apart from the adoption of Bosch electronic ignition, Maserati’s 4,930 cc DOHC, 16-valve V8 engine was carried over from the Ghibli SS and delivered 320 bhp at 5500 rpm and 355.5 lb-ft of torque at 4000 rpm. It was fed through four double barrel 42 DCNF 41 Weber carburettors and used dry-sump lubrication. As on the Ghibli the fuel tanks were two, but not of similar size. A small tank is on the right and it is connected to the main tank below the cargo floor, with a single fuel filler on the right hand side feeding directly the small tank. The double exhaust system ended with two resonators, each with twin exhaust tips. Power was routed to the rear wheels through a 5-speed, all syncromesh ZF manual gearbox with a single-plate dry clutch; a 3-speed Borg Warner automatic transmission was also available on request. Khamsins rode on 215/70 Michelin XWX tyres on 7½J 15″ Campagnolo alloy wheels. Having been developed under the Citroën ownership, the Khamsin made large use of its high-pressure hydraulic systems. The power steering used the Citroën SM’s DIRAVI speed-sensitive variable assistance, which made steering lighter for easier parking and decreased its intervention with speed. The all-around vented disc brakes and the clutch command were both hydraulically actuated and assisted. The adjustable seats and the pop-up headlights were also hydraulically actuated. An adjustable steering column (an innovative feature at the time), air conditioning, electric windows, a radio and full leather upholstery were standard. Maserati claimed a 270 km/h (170 mph) top speed for the European-specification model. In 1977 a mild facelift added three horizontal slots on the Khamsin’s nose to aid cooling. Inside it brought a restyled dashboard and a new padded steering wheel. One Khamsin was delivered to Luciano Benetton in 1981. Despite the many improvements over its predecessor, the Khamsin didn’t replicate its success; partly due to the concurrent fuel crisis that decreased demand for big V8 grand tourers. Production ended in 1982, with 435 vehicles made (a mere third of the Ghibli’s 1274 examples production run) – 155 of whose had been exported to the United States.

Not a well known car these days, what was developed under the code of Tipo 129, the Kyalami is a four-seat GT coupé produced from 1976 to 1983. which was named after the Kyalami Grand Prix Circuit in South Africa, where a Maserati-powered Cooper T81 had won the 1967 South African Grand Prix. The Kyalami was the first new model developed under the Alejandro de Tomaso ownership. It was derived from, and mechanically virtually identical (except for some body panels) to the Longchamp, a three-box grand tourer made by De Tomaso Automobili. Pietro Frua was commissioned from De Tomaso to undertake the restyling of the Tom Tjaarda-designed Longchamp, to give the new car a distinctive Maserati feel. The interior was also upgraded to incorporate classic Maserati elements such the steering wheel and instrumentation. A Maserati four overhead camshaft 90° V8 was utilised to power the car, as opposed to the American-sourced Ford V8 which was used in the Longchamp. The Kyalami was launched at the 1976 Geneva Motor Show and was initially powered by a 265 PS 4.2-litre engine. Starting in 1978, an enlarged version of 4.9-litre displacement delivering 290 PS was also available. Both engines were coupled with a ZF five-speed manual transmission or upon request a three-speed Borg Warner automatic. Mechanically the Kyalami was closely related to its contemporary Quattroporte, which was also offered with the same engines and gearboxes. 210 Kyalamis were built between 1976 and 1983. Due to its rarity very little in the way of performance tests were published in the various international magazines when the car was new, and it features very seldom these days.

Maserati replaced their entire range in 1981 with the BiTurbo. Introduced initially as a single model, a 2 door coupe with a 2 litre twin-turbo V6 engine, over the next 15 years, it would evolve into a complex range of different models, and three basic bodystyles, as well as the special low-volume Karif and V8 engined Shamal cars. The car was designed by Pierangelo Andreani, Chief of Centro Stile Maserati up to 1981, and was somewhat influenced by the design of the recent Quattroporte III. The BiTurbo marked quite a change of direction for the Modense firm, a consequence of its acquisition by Alejandro de Tomaso in 1976. de Tomaso’s ambitious plans for the marque were to combine the prestige of the Maserati brand with a sports car that would be more affordable than the earlier high-priced models that had traditionally made up the Maserati range. The Biturbo was initially a strong seller and brought Italian prestige to a wide audience, with sales of about 40,000 units, but it quickly became apparent that the quality of the car was way off what the market expected, and the car is not regarded as one of the marque’s better models. Indeed, the Biturbo is number 28 in the BBC book of “Crap Cars” and in 2007 was selected as Time Magazine’s worst car of 1984, although they ranked the Chrysler TC by Maserati as a “greater ignominy”. Between 1987–89 a facelift was phased in, which helped to soften the sharp bodylines. The redesign included a taller and more rounded grille with mesh grille and bonnet, aerodynamic wing mirrors and 15″ disc-shaped alloy wheels, now mounted on 5-lug hubs. Some models received the wraparound bumpers with integral foglights and the deep sills introduced with the 2.24v. In 1991 the entire lineup was restyled for a second time, again by the hand of Marcello Gandini; the design features introduced with the Shamal were spread to the other models. Gandini, the Shamal’s designer, developed an aerodynamic kit that included a unique spoiler at the base of the windscreen hiding the windshield wipers, a rear spoiler, and side skirts. The new two-element headlights used poli-ellypsoidal projectors developed by Magneti-Marelli. Inset in body-colour housings, they flanked a redesigned grille, slimmer and integrated in the bonnet; the 1988 bumpers were adopted by all models. The 15″ disc-shaped alloys were replaced by new 16″ seven-spoke wheels, with a hubcap designed to look like a centerlock nut. The second facelift was referred to as “nuovolook”. The engines underwent change, too. As well as being the first ever production car with a twin-turbocharged engine, it was also the first production car engine with three valves per cylinder. The aluminium 90-degree SOHC V6 engine was roughly based on the 2.0 litre Merak engine, itself based on earlier V8 Formula One Maserati engines, designed by Giulio Alfieri. Because in Italy new cars with engine displacement over 2000 cc were subjected to a 38% value added tax, against 19% on smaller displacement cars, throughout the Biturbo’s production life there were both two-litre models aimed mainly at the domestic market and “export” versions, initially with a 2.5 litre V6. The carburettor 2.5 unit produced 185 hp and 208 lb·ft of torque in North American spec and slightly more elsewhere. Fuel injection was fitted in 1987 raising power to 187 hp. In 1989 the enlarged 2.8 litre engine bumped power to 225 hp and 246 lb·ft of torque for North America and 250 PS for Europe. In 1988, with the coupés being restyled, the Biturbo name was dropped in favour of 222—meaning 2-door, 2-litre engine and 2nd generation. The car carried all the visual clues of Gandini’s first facelift, with a more rounded grille and bonnet, different wing mirrors and rear spoiler. The engine size of the 222 E export model grew from the Biturbo’s 2.5- to 2.8-litres. A mixed velour-leather interior was standard on the domestic models, while export markets got leather upholstery as standard. 1990 saw the arrival of the 2.8 litre 222 SE, heir to the Biturbo ES. It inherited the latter’s limited paint finish availability (red, silver or black) and the dark trim and grille, while modern aprons and side skirts (blacked out as well) came from the 2.24v. After just a year the 222 SE was replaced by the 1991-restyled 222 SR; the SR offered adaptive suspension as an option. Simultaneously the very similar 222 4v. joined the lineup; it was a 222 SR with a 2.8 litre four-valve engine, the first DOHC car in the direct Biturbo E lineage. It used wider, 16″ 7-spoke wheels.

The Ghibli name was resurrected with the unveiling at the 62nd Turin Motor Show in April 1992. of the 1992 Ghibli (Tipo AM336). Like the V8 Maserati Shamal, it was an evolution of the previous Biturbo coupés; the doors, interior, and basic bodyshell were carried over from the Biturbo. It was powered by updated 24-valve Biturbo engines: a 2.0-litre V6 coupled to a six-speed manual transmission for the Italian market, and a 2.8-litre V6 for export, at first with a 5-speed manual, then from 1995 with the 6-speed. A 4-speed automatic was optional. The coupé was built for luxury as well as performance, and its interior featured Connolly leather upholstery and burl elm trim. At the 1994 Geneva Motor Show, Maserati launched an updated Ghibli. A refreshed interior, new wing mirrors, wider and larger 17″ alloy wheels of a new design, fully adjustable electronic suspension and ABS brakes were added. The Ghibli Open Cup single-make racing car was announced in late 1994. Two sport versions were introduced in 1995. The first was the Ghibli Kit Sportivo, whose namesake handling kit included wider tyres on OZ “Futura III” split-rim wheels, specific springs, dampers and anti-roll bars. The second was the limited edition Ghibli Cup, which brought some features of the Open Cup racer into a road-going model; it debuted at the December 1995 Bologna Motor Show. it mounted a 2-litre engine upgraded to 330 PS. At the time the Ghibli Cup had the highest ever per litre power output of any street legal car, surpassing the Bugatti EB110 and Jaguar XJ220. Chassis upgrades included tweaked suspension and Brembo brakes. Visually the Cup was recognizable from its 5-spoke split-rim Speedline wheels and badges on the doors. Only four paint colours were available: red, white, yellow and French blue. The sporty theme continued in the Cup’s cabin with black leather, carbon fibre trim, aluminium pedals and a MOMO steering wheel. A second round of improvements resulted in the Ghibli GT in 1996. It was fitted with 7-spoked 17″ alloy wheels, black headlight housings, and had suspension and transmission modifications. On 4 November 1996 on the Lake Lugano, Guido Cappellini broke the flying kilometre’s World Speed Record on water in the 5-litre class piloting a composite-hulled speedboat powered by the biturbo V6 from the Ghibli Cup and run by Bruno Abbate’s Primatist/Special Team, at an average speed of 216,703 km/h.To celebrate the world record Maserati made 60 special edition Ghiblis called the Ghibli Primatist. The cars featured special Ultramarine blue paintwork and two-tone blue/turquoise leather interior trimmed in polished burr walnut. Production of the second generation Ghibli ended in summer 1998.

The most numerous Maserati cars at most events these days are those known internally as the Tipo 338 and better known as the 3200GT and 4200GT and Spider, and this design was evident here. After producing BiTurbo based cars for 17 years, Maserati replaced their entire range with a new model in July 1998, the 3200 GT. This very elegant 2+2 grand tourer was styled by Italdesign, whose founder and head Giorgetto Giugiaro had previously designed, among others, the Ghibli, Bora and Merak. The interior design was commissioned to Enrico Fumia. Its name honoured the Maserati 3500 GT, the Trident’s first series production grand tourer. Sold mainly in Europe, the 3200 GT was powered by the twin-turbo, 32-valve, dual overhead cam 3.2-litre V8 engine featured in the Quattroporte Evoluzione, set up to develop 370 PS (365 hp). The car was praised for its styling, with the distinctive array of tail-lights, consisting of LEDs, arranged in the shape of boomerang being particularly worthy of comment. The outer layer of the ‘boomerang’ provided the brake light, with the inner layer providing the directional indicator. The car was also reviewed quite well by the press when they got to drive it in early 1999, though it was clear that they expected more power and excitement. That came after 4,795 cars had been produced, in 2001, with the launch of the 4200 models. Officially called the Coupé and joined by an open-topped Spyder (Tipo M138 in Maserati speak), these models had larger 4.2 litre engines and had been engineered so the cars could be sold in America, marking the return to that market for Maserati after an 11 year gap. There were some detailed styling changes, most notable of which were the replacement of the boomerang rear lights with conventional rectangular units. Few felt that this was an improvement. The cars proved popular, though, selling strongly up until 2007 when they were replaced by the next generation of Maserati. Minor changes were made to the model during its six year production, but more significant was the launch at the 2004 Geneva Show of the GranSport which sported aerodynamic body cladding, a chrome mesh grille, carbon fibre interior trim, and special 19-inch wheels. It used the Skyhook active suspension, with a 0.4 inch lower ride height, and the Cambiocorsa transmission recalibrated for quicker shifts. The exhaust was specially tuned to “growl” on start-up and full throttle. The GranSport was powered by the same 4244 cc, 90° V8 petrol engine used on the Coupé and Spyder, but developing 400 PS (395 hp) at 7000 rpm due primarily to a different exhaust system and improvements on the intake manifolds and valve seats. A six-speed paddle shift transmission came as standard. The GranSport has a claimed top speed of 180 mph (290 km/h) and a 0–62 mph (0–100 km/h) time of 4.8 seconds.

Still acclaimed as one of the best-looking saloons ever produced is this car, the fifth generation Quattroporte, a couple of which were on show. Around 25,000 of these cars were made between 2004 and 2012, making it the second best selling Maserati of all time, beaten only by the cheaper BiTurbo of the 1980s. The Tipo M139 was unveiled to the world at the Frankfurt Motor Show on 9 September 2003, with production starting in 2004. Exterior and interior design was done by Pininfarina, and the result was widely acclaimed to be one of the best looking saloons not just of its time, but ever, an opinion many would not disagree with even now. Built on an entirely new platform, it was 50 cm (19.7 in) longer than its predecessor and sat on a 40 cm (15.7 in) longer wheelbase. The same architecture would later underpin the GranTurismo and GranCabrio coupés and convertibles. Initially it was powered by an evolution of the naturally aspirated dry sump 4.2-litre V8 engine, mounted on the Maserati Coupé, with an improved output of 400 PS . Due to its greater weight compared to the Coupé and Spyder, the 0-62 mph (0–100 km/h) time for the Quattroporte was 5.2 seconds and the top speed 171 mph (275 km/h). Initially offered in only one configuration, equipped with the DuoSelect transmission, the gearbox was the weak point of the car, receiving most of the criticism from the press reviews. Maserati increased the range at the 2005 Frankfurt Motor Show, with the launch of the Executive GT and Sport GT trim levels. The Executive GT came equipped with a wood-rimmed steering wheel, an alcantara suede interior roof lining, ventilated, adaptive, massaging rear seats, rear air conditioning controls, veneered retractable rear tables, and curtain shades on the rear windows. The exterior was distinguished by 19 inch eight-spoke ball-polished wheels and chrome mesh front and side grilles. The Quattroporte Sport GT variant offered several performance upgrades: faster shifting transmission and firmer Skyhook suspensions thanks to new software calibrations, seven-spoke 20 inch wheels with low-profile tyres, cross-drilled brake rotors and braided brake lines. Model-specific exterior trim included dark mesh front and side grilles and red accents to the Trident badges, as on vintage racing Maseratis. Inside there were aluminium pedals, a sport steering wheel and carbon fibre in place of the standard wood inserts. A new automatic transmission was presented at the 2007 Detroit Motor Show, marketed as the Maserati Quattroporte Automatica. As all three trim levels were offered in both DuoSelect and Automatica versions, the lineup grew to six models. The Quattroporte Sport GT S was introduced at the 2007 Frankfurt Motor Show. Taking further the Sport GT’s focus on handling, this version employed Bilstein single-rate dampers in place of the Skyhook adaptive system. Other changes from the Sport GT comprised a lowered ride height and 10 mm wider 295/30 rear tyres, front Brembo iron/aluminium dual-cast brake rotors and red-painted six piston callipers. The cabin was upholstered in mixed alcantara and leather, with carbon fibre accents; outside the door handles were painted in body colour, while the exterior trim, the 20 inch wheels and the exhaust pipes were finished in a “dark chrome” shade. After Images of a facelifted Quattroporte appeared on the Internet in January 2008; the car made its official début at the 2008 Geneva Motor Show. Overseen by Pininfarina, the facelift brought redesigned bumpers, side sills and side mirrors, a convex front grille with vertical bars instead of horizontal, new headlights and tail lights with directional bi-xenon main beams and LED turn signals. Inside there was a new navigation and entertainment system. All Quattroporte models now used the ZF automatic transmission, the DuoSelect being discontinued. The 4.2-litre Quattroporte now came equipped with single-rate damping comfort-tuned suspension and 18 inch wheels. Debuting alongside it was the Quattroporte S, powered by a wet-sump 4.7-litre V8, the same engine of the Maserati GranTurismo S, with a maximum power of 424 bhp and maximum torque of 361 lb·ft. In conjunction with the engine, the braking system was upgraded to cross-drilled discs on both axles and dual-cast 360 mm rotors with six piston callipers at the front. Skyhook active damping suspension and 19 inch V-spoke wheels were standard. Trim differences from the 4.2-litre cars were limited to a chrome instead of titanium-coloured front grille. The Quattroporte Sport GT S was premièred at the North American International Auto Show in January 2009. Its 4.7-litre V8 produced 440 PS (434 hp), ten more than the Quattroporte S, thanks to revised intake and to a sport exhaust system with electronically actuated bypass valves. Other mechanical changes were to the suspensions, where as on the first Sport GT S single-rate dampers took place of the Skyhook system, ride height was further lowered and stiffer springs were adopted. The exterior was distinguished by a specific front grille with convex vertical bars, black headlight bezels, red accents to the Trident badges, the absence of chrome window trim, body colour door handles and black double oval exhaust pipes instead of the four round ones found on other Quattroporte models. Inside veneers were replaced by “Titan Tex” composite material and the cabin was upholstered in mixed Alcantara and leather. This means that there are quite a number of different versions among the 25,256 units produced, with the early DuoSelect cars being the most numerous.

Completing the display were examples of the current GranTurismo and GranCabrio.

MAZDA

There are always large numbers of MX-5 models here, with the Owners club being staunch supporters of the event.

McLAREN

On the Friday and Saturday there was not much of a McLaren presence, but that all changed on the Sunday when in celebration of what would have been Bruce McLaren’s 80th birthday year, the marque had a Parade Lap which featured 115 road cars, believed to be a record. Marque founder Bruce’s daughter, Amanda, was apparently on site, though I did not come across her. Many of the cars were parked up before and after their track parade. Oldest of these is this MP4 12C. This was the first ever production car wholly designed and built by McLaren, and their first production road car produced since the McLaren F1, which ended production in 1998. McLaren started developing the car in 2007 and secretly purchased a Ferrari 360 to use as a test mule. The mule called MV1 was used to test the 3.8-litre twin-turbocharged V8 engine. The car also featured side vents for additional cooling which were later incorporated in the final production model. Later in the year, the company purchased an Ultima GTR to test the braking system and suspension components, that mule was called the MV2. The space frame and body of that car were modified in order to accommodate the new components. Later another prototype was purchased which was another Ferrari 360 dubbed the MV3 which was used to test the exhaust system. McLaren then built two prototypes themselves called CP1 and CP2 incorporating the Carbon Monocell monocoque which were used for testing the heat management system and performance. The MP4-12C features a carbon fibre composite chassis, and is powered by a longitudinally-mounted Rear mid-engine, rear-wheel-drive layout McLaren M838T 3.8 litre twin-turbocharged V8 engine, developing approximately 600 PS (592 bhp) at 7500 rpm and around 600 N⋅m (443 lbf⋅ft) of torque at 5600 rpm. The car makes use of Formula 1-sourced technologies such as “brake steer”, where the inside rear wheel is braked during fast cornering to reduce understeer. Power is transmitted to the wheels through a seven-speed dual-clutch transmission. The entire drivetrain is the first to be entirely designed and produced in house by McLaren. The chassis is based around a F1 style one-piece carbon fibre tub, called the Carbon MonoCell, weighing only 80 kg (176 lb). The MonoCell is made in a single pressing by using a set of patented processes, using Bi-Axial and Tri-Axial carbon fibre multi-axial fabrics produced by Formax UK Ltd. with the MonoCell manufactured by Carbo Tech in Salzburg, Austria. This has reduced the time required to produce a MonoCell from 3,000 hours for the F1 and 500 hours for the Mercedes-Benz SLR McLaren, to 4 hours for the MP4-12C. The McLaren MP4-12C utilizes a unique hydraulic configuration to suspend the vehicle as opposed to more traditional coil springs, dampers and anti-roll bars. What McLaren has called “ProActive Chassis Control,” the system consists of an array of high and low pressure valves interconnected from both left to right and front to back, and the typical anti-roll bars were omitted entirely. When high pressure meets high pressure under roll conditions, stiffness results; and subsequently when high pressure meets low under heave and warp, more give is allowed, ultimately providing a firmer, competent suspension setup in spirited driving, and a very plush, compliant and comfortable ride when moving at slower, constant speeds. The car has a conventional two side-by-side seating arrangement, unlike its predecessor the McLaren F1 which featured an irregular three seat formation (front centre, two behind either side). To make up for this however, the car’s central console is narrower than in other cars, seating the driver closer to the centre. Interior trim and materials can be specified in asymmetric configuration – known as “Driver Zone”. The final car was unveiled to the public on 9 September 2009 before the company’s launch in 2010. A convertible version of the car called the MP4-12C Spider, as added to the range in 2012. The name’s former prefix ‘MP4’ has been the chassis designation for all McLaren Formula 1 cars since 1981. ‘MP4′ stands for McLaren Project 4 as a result of the merger between Ron Dennis’ Project 4 organisation with McLaren. The ’12’ refers to McLaren’s internal Vehicle Performance Index through which it rates key performance criteria both for competitors and for its own cars. The criteria combine power, weight, emissions, and aerodynamic efficiency. The coalition of all these values delivers an overall performance index that has been used as a benchmark throughout the car’s development. The ‘C’ refers to Carbon, highlighting the application of carbon fibre technology to the future range of McLaren sports cars. At the end of 2012, the name of the MP4-12C was reduced to 12C – that name is usually used when referring to the coupe. The open-top version now being called the 12C Spider.

A heavily revised version was announced in February 2014, called the 650S, with revised bodywork, upgraded engine and other technical improvements. In April 2014, McLaren announced the end of production of the 12C. The 650S is the core model in the Super Series, designed and developed to give the enthusiast driver the ultimate in luxury, engagement and excitement. Fitted with the award-winning 3.8-litre twin turbo V8 engine producing 650PS (641bhp) and 678Nm (500lb ft) of torque, it is a no compromise open-top high performance supercar with optimised levels of performance, handling and driver enjoyment. The secret of its success is its carbon fibre MonoCell chassis, which needs no extra strengthening to provide the necessary rigidity or safety when developing a convertible. This keeps any weight increase to a minimum, meaning the McLaren 650S Spider offers all the enjoyment and driver appeal of the fixed-roof sibling – but with the added appeal of roof-down driving. The 650S Spider is fitted with an electrically retractable hard top, which can be automatically raised or lowered on the move in less than 17 seconds. Building on the success of the MP4 12C, with which it shares much, the 650S series, first seen at the 2014 Geneva Show has proved very popular, helping to establish the brand as a serious rival to the established supercar players. Production ended when the even faster (and costlier( 720S arrived in 2017.

Commanding a significant price premium over the regular 650S cars, the 675LT sits in the “Super” part of the range (P1s are in the “Ultimate” collection). Those who thought that the 675LT might look little different from the “regular” 650S, with a simple elongation of the rear end underestimated the engineers at Woking, as the 675LT has a style and appearance all of its own, with lots of different detailing to distinguish it from the standard car, with carbon fibre wings and twin circular titanium exhaust pipes exposed at the rear deck to improve cooling, sitting above a new bumper and diffuser both made from carbon fibre. At the front there is a larger carbon fibre splitter and new front bumper design, aimed at improving cooling and downforce. Designed to be far more track focused than the 650S, it contains many elements aimed at improving handling and performance. The biggest difference to the way it feels is apparently down to 100kg reduction in weight, but it does also contain a significantly modified 666 bhp version of the 650S’ twin turbo 3.8 litre V8. 50% of engine parts are new, including the turbos, camshafts and connecting rods, along with detailed revisions to the cylinder heads and manifolds. As a consequence, the 0-60 time is reduced to 2.9 seconds, 0.1 seconds less than the 650S, though the top speed is slightly reduced due to the extra drag of the aerodynamic pack. 500 examples were built, and they all sold out within weeks, to the surprise of no-one, as this is a very impressive machine indeed.

The 720S – a complete replacement for the 650S – was a star of the 2017 Geneva Show, and it was clear on looking at it, that the Woking firm really is increasingly a serious threat to Ferrari’s supercar supremacy, even before learning that total sales in just five years of production had passed 10,000 units. The 720S was presented as the firm’s new core model and the first of 15 new-generation McLarens, half of which will be hybrids, promised by 2022 under CEO Mike Flewitt’s ambitious Track 22 development plan. The 720S obeys all existing McLaren design rules. It is a two-seat supercar based on an all-carbonfibre tub, with aluminium space frames carrying the front and rear suspension, and it is powered by a twin turbo V8. However, within that envelope, it has been redesigned and updated in every detail. The exterior introduces a new ‘double skin’ door construction that eliminates the need for the prominent side air scoops previously thought essential in supercar design, while the engine grows to 4.0 litres, up from 3.8-litres, and now produces 710bhp. McLaren has further developed its carbonfibre chassis tub and upper structure, taking lessons from previous models, including the P1. Now dubbed Monocage II, the structure is cited as the key to the 720S’s 1283kg dry weight, which undercuts all competitors and beats that of its predecessor by 18kg. Monocage II’s stiffness has allowed McLaren’s designers to give the 720S remarkably thin A-pillars, a deep windscreen, B-pillars set well back and slim, glazed C-pillars, all of which contribute to first-class all-round visibility for the driver. The body panels are made either of carbonfibre or superformed aluminium, and their novel shape plays a key role in the 720S’s impressive aerodynamic performance. Low down at the front there are anti-lift aero blades reminiscent of those on the P1, while ultra-compact LED headlights fit into frontal ‘eye sockets’ that allow room for vents to feed the air conditioning and oil cooler. The body sides incorporate channels, formed by two skins and flowing past the dihedral doors, so cooling air can be directed along the body into the engine bay, uninterrupted by turbulence and resulting in a 15% improvement in cooling airflow. On the outer, lower part of the doors, there are F1-inspired blades that direct air away from the front wheel arches, assisting downforce and cutting drag. A big under-body diffuser at the rear sweeps up from the 720S’s flat floor almost to its rear wing, where the two elements frame the ultra-thin LED tail-lights. Because the top of the 720S’s engine is a remarkable 120mm lower than that of the 650S, the car also has a low, teardrop-shaped engine cover that allows an uninterrupted flow of air over the roof to the hydraulically actuated rear wing, which has a DRS drag reduction setting for optimal straight-line performance, an Aero setting for downforce in corners and a Brake setting (which sets the wing a steep 56deg from the horizontal) to increase drag and improve chassis balance under heavy braking. The result, says McLaren, is that the wing has 30% more downforce and its aero efficiency (the ratio of downforce to drag) is doubled. McLaren claims “new heights of performance” from its expanded turbo V8, now re-engineered for a capacity of 3994cc, thanks to a 3.6mm lengthening of its stroke. The engine also has lighter pistons and conrods and a stiffer, lightened crank, plus twin-scroll turbochargers with faster-spooling turbines, capable of spinning at 145,000rpm, and electronically controlled wastegates. In total, 41% of the engine’s components are new. A cast aluminium air intake system, visible through the mesh engine cover, feeds extra air to the more potent engine that now uses two injectors per cylinder. But rather than simply pumping in more fuel, the improved injection system gives more accurate metering, which helps to cut CO2 emissions by around 10%, to a class-leading 249g/km. Combined economy falls by a similar percentage to 26.4mpg. The 720S’s peak output of 710bhp is produced at 7000rpm, while maximum torque of 568lb ft is delivered at 5500rpm. The engine, longitudinally mounted behind the occupants, drives as before through a seven-speed dual-clutch automatic gearbox mounted end-on to the engine, but McLaren says further refinement of its control software brings smoother gearchanges at low speeds and faster, sharper shifts at higher speeds. The launch control has also been improved, and as before, there are three driving modes — Comfort, Sport and Track — that govern both engine and dynamics. The chassis weight savings, allied to other reductions in mass, including 2kg from the brakes, 3kg from the electrics and 1.5kg from the airboxes, contribute as much to the 720S’s enhanced performance as its 11% power increase. The power-to-weight ratio is now 553bhp per tonne (up 15%) and, according to McLaren, beats the best in the segment. As a result, McLaren claims a “crushing” 0-60mph time of just 2.8sec, 0-124mph in 7.8sec and a top speed of 212mph. The 720S will also dispatch a standing quarter-mile in 10.3sec, representing a blistering performance for a pure road car. To accompany the performance, the 720S has a carefully engineered engine note which can be further enhanced with an optional, louder, sports exhaust system. Despite its performance potential, McLaren is adamant that its new car is as easily handled by ordinary drivers as it is by experts, with throttle response calibrated to provide “the optimum blend of immediate reaction and progressive comfort”. Although only five years old, McLaren’s all-independent system of front and rear double wishbones has been completely re-engineered, both to allow wheel geometry changes and, thanks to a redesign of the uprights and wishbones, to cut unsprung mass by 16kg. The 720S has an updated version of the Proactive chassis control electronics used by the 650S. The system features hydraulically interlinked dampers at each corner that remove the need for anti-roll bars, but the big improvement for the 720S’s system, which is dubbed PCCII, results from new software developed during a six-year collaboration with the University of Cambridge and using sophisticated information gathered by 12 new sensors and accelerometers. The result is even better contact between the tyres and the road surface. The system can assess conditions and adjust the suspension every five milliseconds. It also includes a Variable Drift function, which allows you to slide the car without losing control, and McLaren Brake Steer, pioneered in F1, which enhances agility in corners and traction out of them by braking separate wheels. McLaren engineers have retained electro-hydraulic steering for the 720S, despite rivals’ adoption of electric only systems, because they still feel it gives superior “clarity of feel”. Brakes are large, ventilated carbon-ceramic discs and the tyres are specially developed Pirelli P Zeros, 245/35 ZR19s at the front (up from the 650S’s 235s) and 305/30 ZR20s at the rear. McLaren claims a 6% increase in mechanical grip, which is about the same advantage as fitting track-focused Pirelli Corsas to a 650S. Although the 720S closely follows the outgoing 650S in its major dimensions, there are differences between them. The thin pillars, the depth of the windscreen and the all-round glass give a commanding view to all points that modern supercar drivers will find surprising. The redesigned interior surfaces have been ‘pushed away’ from the occupants as much as possible, to further enhance the feeling of space. Unlock the door and various instrument and courtesy lights go through a welcome sequence as the mirrors unfold. Opening the door also triggers an elaborate sequence on the upright TFT screen which changes its configuration according to driving mode. The driver can also ‘declutter’ the instruments, for example when on a track, via a special Slim mode. There’s a central 8.0in infotainment screen on the centre console, with ventilation settings carried along the bottom. The layout of switches, most of which are machined from aluminium, is simple. Standard cabin trim and seats are plush but, as with previous models, colour and trim material upgrades are available. McLaren has already begun taking orders, with the first cars due to be delivered in May. The entry price in the UK was £207,900. All 400 units of the Launch Edition version were sold even before the general public saw the car though many of these then hit the pre-owned market quite quickly, traded in once owners could take delivery of a car in the spec that they really wanted. McLaren’s goal is to sell around 1200 – 1500 720S models a year.

Sitting below the 720 in the range are the 540 and 570 models. The first of these were revealed at the 2015 New York Auto Show, going on sale towards the end of that year. These were labelled as part of McLaren’s Sports Series. This mid-engine sportscar features the lightweight carbon fibre MonoCell II chassis, and a highly efficient 3.8-litre twin turbo V8 engine generating 562bhp and 443lb/ft of torque. Although the model has been conceived with a greater focus on day-to-day usability and refinement, but it is still very much a pure McLaren, boasting a class-leading power-to-weight ratio of 434PS per tonne, and electrifying performance. The 570S Coupé accelerates from 0 to 100km/h in just 3.2 seconds, reaches 200km/h (124mph) in 9.5 seconds, and on to a top speed of 204mph. Pricing for the 570S Coupé started at £143,250, though like all cars of this type, that figure can quickly rise once you raid the options list.

Third of the hypercars considered to be the “holy trinity” (with the LaFerrari and Porsche 918 Spyder) is the McLaren P1, and there was one of these here. Debuted at the 2012 Paris Motor Show, sales of the P1 began in the United Kingdom in October 2013 and all 375 units were sold out by November. Production ended in early December 2015. The United States accounted for 34% of the units and Europe for 26%. It is considered by the automotive press to be the successor to the F1, utilising hybrid power and Formula 1 technology, but does not have the same three-seat layout. It was later confirmed that the Speedtail served as the actual successor to the F1. The P1 has a mid-engine, rear wheel drive design that used a carbon fibre monocoque and roof structure safety cage concept called MonoCage, which is a development of the MonoCell first used in the MP4-12C and then in subsequent models. Its main competitors were the LaFerrari and the Porsche 918. They are all similar in specifications and performance, and in a race around Silverstone circuit they were all within half a second of each other, the P1 finishing first at 58.24 seconds and the LaFerrari finishing last at 58.58 seconds; the 918 was in-between with 58.46 seconds. 58 units of the track-oriented P1 GTR and 5 units of its road legal counterpart, the P1 LM were produced after the initial run of 375 cars. 13 experimental Prototype ‘XP’, 5 Validation Prototypes ‘VP’ and 3 Pre-Production ‘PP’ cars were produced by McLaren before the production of the P1 started, a number of which have been refurbished, modified and sold to customers.

MERCEDES-BENZ

Oldest Mercedes in the Club display was this example from the “Ponton” series, the main stay of the range from their introduction in 1953 throughout the rest of the 50s. The Ponton was Daimler-Benz’s first totally new Mercedes-Benz series of passenger vehicles produced after World War II. In July 1953, the cars replaced the pre-war-designed Type 170 series and were the bulk of the automaker’s production through 1959, though some models lasted through 1962. The nickname comes from the German word for “pontoon” and refers to one definition of pontoon fenders — and a postwar styling trend, subsequently called ponton styling. A bewildering array of models were produced, with a mixture of 180 four and 220 six cylinder engines, with Mercedes W numbers of W120 for the 4 cylinder cars, and W180 for the 220s, as well as W105 for the little known or seen 219, a six cylinder model with a smaller engine. Mercedes introduced fuel injection to the 220 model in 1958, creating the W128 220SE, and the company was rare among car makers in the 50s in offering a diesel engine, so 180D models were also offered.

These elegant machines are from the W111 series. The Mercedes range of the 1960s was quite complex, with body styles and mechanical updates proceeding at a different rate, and even by referring to the cars by their internal development codes (the “W” number), they are still quite hard to define unambiguously. In the W111 family, the Coupe was the first to appear, a replacement for the two-door W120 “Ponton” models, and work on it began in 1957. Since most of the chassis and drivetrain were to be unified with the sedan, the scope was focused on the exterior styling. Some of the mockups and prototypes show that Mercedes-Benz attempted to give the two-door car a front styling almost identical to what would be realised in the Pagoda (W113), but ultimately favoured the work of engineer Paul Bracq. The rear featured small tailfins, subtle compared to the fintails’ and evocative of the later squarish styling of the W108/W109. Production began in late 1960, with the coupe making its debut at the 75th anniversary of the opening of Mercedes-Benz Museum in Stuttgart in February of the next year. The convertible followed at the Frankfurt Auto Show a few months later. Almost identical to the coupe, its soft-top roof folded into a recess behind the rear seat and was covered by a tightly fitting leather “boot” in the same colour as the seats. Unlike the previous generation of two-door ponton series, the 220SE designation was used for both the coupe and convertible; both received the same version of the 2195 cc M127 engine. Options included a sliding sunroof for the coupe, automatic transmission, power steering, and individual rear seats. In March 1962, Mercedes-Benz released the exclusive two-door M189-powered 300SE. Like the 300 sedan, it was based on the W111 chasis but shared both Daimler’s top-range 2996 cc fuel-injected engine and the unique W112 chassis designation, efforts on Mercedes’ part to distance it from the maker’s modest W110 and W111 lineups and link it to the prestigious W188 300S two-door luxury sports tourer. It was distinguished by a chrome strip, and featured air suspension and a higher level of interior trim and finish. In summer of 1965, Mercedes-Benz launched replacements for both W111 and W112 sedans, the W108 and W109 respectively. With the tailfin fashion well eroded by the mid 1960s, the new design was based on the restrained W111 coupe, widened and squared off. Work on a future new chassis that would fully replace the Ponton-derived W111/W112 and W108/W109 was well under way. With a concept car of the first S-Class shown in 1967, Daimler declined to develop a two-door W108/W109 vehicle, instead continuing production of the aging W111/W112 with modest changes. The 220SE was superseded in early autumn 1965 by the 250SE, which featured the new 2496cc M129 engine. Producing 150 hp. it gave the vehicle a significant improvement in top speed, to 120 mph. Visibly the only changes affected the new 14-inch rims, which came with new hub cabs and beauty rings accommodating the larger disk brakes and new rear axle from the W108 family. In November 1967 the 250 SE was superseded by the 280 SE. It was powered by the new 2778 cc M130 engine, which produced 160 hp. The top speed was hardly affected, but acceleration improved to 10.5 seconds. Inside the car received a wood veneer option on the dashboard and other minor changes, including door lock buttons and different heater levers. The hubcaps were changed yet again to a new one piece wheelcover, and the exterior mirror was changed. Despite its smaller engine, the 280 SE could outperform the early 1950s M189 powered 300 SE, resulting in the more expensive model’s retirement. The coupe and cabriolet retained their shared model model designation until replaced by a new-generation chassis in 1968. A final model was added in August 1969, the 280 SE 3.5. The car was fitted with the brand-new M116 3499 cc V8. It produced 200 hp, and had a top speed of 130 mph and a 0-100 km/h at 9.5 seconds. To accommodate the large engine, the car’s front grille was widened; front and rear bumpers were also modified with the addition of rubber strips. The rear lenses changed to a flatter cleaner design. This change was carried across the standard 280 SE. As the top of its range, the 280 SE 3.5 is seen as an ideological successor to the W112 300 SE, though it lacked the W112’s air suspension. The last 280 SE was produced in January 1971, with the 280 SE 3.5 ending in July. The total production over the decade was: 220 SEb – 16,902, 250 SE – 6,213, 280 SE – 5,187, and 280 SE 3.5 – 4,502 units. Not including 3,127 W112 300 SE models, the grand total of 2-door W111 models was 32,804 of which 7,456 were convertibles. These days the cars are much sought after and prices, especially for the convertible, are high and still rising.

This one comes from the W108 family. The car’s predecessor, the Mercedes-Benz W111 (produced 1959–1971) helped Daimler develop greater sales and achieve economy of scale production. Whereas in the 1950s, Mercedes-Benz was producing the coachwork 300 S and 300 SLs and all but hand-built 300 Adenauers alongside conveyor assembled Pontons (190, 190SL and 220) etc., the fintail (German: Heckflosse) family united the entire Mercedes-Benz range of vehicles onto one automobile platform, reducing production time and costs. However, the design fashion of the early 1960s changed. For example, the tail fins, originally intended to improve aerodynamic stability, died out within a few years as a fashion accessory. By the time the 2-door coupé and cabriolet W111s were launched, the fins lost their chrome trim and sharp appearance, the arrival of the W113 Pagoda in 1963 saw them further buried into the boot’s contour, and finally disappeared on the W100 600 in 1964. The upgrade of the W111 began under the leadership of designer Paul Bracq in 1961 and ended in 1963. Although the fins’ departure was the most visible change, the W108 compared to the W111 had a lower body waist line that increased the window area, (the windscreen was 17 percent larger than W111). The cars had a lower ride (a decrease by 60 mm) and wider doors (+15 mm). The result was a visibly new car with a more sleek appearance and an open and spacious interior. The suspension system featured a reinforced rear axle with hydropneumatic compensating spring. The car sat on larger wheels (14”) and had disc brakes on front and rear. The W109 was identical to the W108, but featured an extended wheelbase of 115 mm (4.5 in) and self-levelling air suspension. This was seen as a successor to the W112 300SEL that was originally intended as an interim car between the 300 “Adenauer” (W189) and the 600 (W100) limousines. However, its success as “premium flagship” convinced Daimler to add an LWB car to the model range. From that moment on, all future S-Class models would feature a LWB line. Although the W108 succeeded the W111 as a premium range full-size car, it did not replace it. Production of the W111 continued, however the 230S was now downgraded to the mid-range series, the Mercedes-Benz W110, and marketed as a flagship of that family until their production ceased in 1968. The W108 is popular with collectors and the most desirable models to collect are the early floor shift models with the classic round gear knob and the 300 SEL’s. The car was premièred at the Frankfurt Auto Show in 1965. The initial model lineup consisted of three W108s: 250S, 250SE, and 300SE, as well as a sole W109, the 300SEL. Engines for the new car were carried over from the previous generation, but enlarged and refined. The 250S was the entry-level vehicle fitted with a 2496 cm³ Straight-six M108 engine, with two dual downdraft carburettors, delivering 130 bhp at 5400 rpm which accelerated the car to 100 km/h (62 mph) in 13 seconds (14 on automatic transmission) and gave a top speed of 182 km/h (177 on auto). The 250SE featured an identical straight-six, but with a six-plunger fuel injection (designated M129) with performance improved to 150 bhp (112 kW) at 5500 rpm, which decreased 0-100 acceleration by one second and increased top speed by 11 km/h (7 mph) for both manual and automatic versions. Both the 300SE and 300SEL came with the M189 2996 cm³ engine, originally developed for the Adenauers. It had a modern six-plunger pump that adjusted automatically to accelerator pedal pressure, engine speed, atmospheric pressure, and cooling water temperature, to deliver the proper mixture depending on driving conditions. Producing 170 bhp at 5,400 rpm the cars could accelerate to 200 km/h (195 km/h with automatic transmission) and reach 100 km/h (62 mph) in 12 seconds. The cylinder capacity of the three litre Mercedes engine was unchanged since 1951. From 1965 to 1967, fewer than 3,000 W109s were produced. However, approximately 130,000 of the less powerful 250 S/SE models were built during the first two years of the W108/109’s existence. By 1967 the fuel consumption of the 3 litre unit in this application was becoming increasingly uncompetitive.

By 1955, Mercedes-Benz Technical Director Prof. Fritz Nallinger and his team held no illusions regarding the 190 SL’s lack of performance, while the high price tag of the legendary 300 SL supercar kept it elusive for all but the most affluent buyers. Thus Mercedes-Benz started evolving the 190 SL on a new platform, model code W127, with a fuel-injected 2.2 litre M127 inline-six engine, internally denoted as 220SL. Encouraged by positive test results, Nallinger proposed that the 220SL be placed in the Mercedes-Benz program, with production commencing in July 1957. However, while technical difficulties kept postponing the production start of the W127, the emerging new S-Class W112 platform introduced novel body manufacturing technology altogether. So in 1960, Nallinger eventually proposed to develop a completely new 220SL design, based on the “fintail” W 111 sedan platform with its chassis shortened by 11.8 in, and technology from the W112. This led to the W113 platform, with an improved fuel-injected 2.3 litre M127 inline-six engine and the distinctive “pagoda” hardtop roof, designated as 230 SL. The 230 SL made its debut at the prestigious Geneva Motor Show in March 1963, where Nallinger introduced it as follows: “It was our aim to create a very safe and fast sports car with high performance, which despite its sports characteristics, provides a very high degree of travelling comfort”. The W113 was the first sports car with a “safety body,” based on Bela Barényi’s extensive work on vehicle safety: It had a rigid passenger cell and designated crumple zones with impact-absorbing front and rear sections built into the vehicle structure. The interior was “rounded,” with all hard corners and edges removed, as in the W111 sedan. Production of the 230 SL commenced in June 1963 and ended on 5 January 1967. Its chassis was based on the W111 sedan platform, with a reduced wheelbase by 11.8 in, recirculating ball steering (with optional power steering), double wishbone front suspension and an independent single-joint, low-pivot swing rear-axle with transverse compensator spring. The dual-circuit brake system had front disc brakes and power-assisted rear drum brakes. The 230 SL was offered with a 4-speed manual transmission, or an optional, very responsive fluid coupled (no torque converter) 4-speed automatic transmission, which was popular for US models. From May 1966, the ZF S5-20 5-speed manual transmission was available as an additional option, which was particularly popular in Italy. The 2,308 cc M127.II inline-six engine with 150 hp and 145 lb/ft torque was based on Mercedes-Benz’ venerable M180 inline-six with four main bearings and mechanical Bosch multi-port fuel injection. Mercedes-Benz made a number of modifications to boost its power, including increasing displacement from 2,197 cc, and using a completely new cylinder head with a higher compression ratio (9.3 vs. 8.7), enlarged valves and a modified camshaft. A fuel injection pump with six plungers instead of two was fitted, which allowed placing the nozzles in the cylinder head and “shooting” the fuel through the intake manifold and open valves directly into the combustion chambers. An optional oil-water heat exchanger was also available. Of the 19,831 230 SLs produced, less than a quarter were sold in the US. Looking identical, the 250 SL was introduced at the 1967 Geneva Motor Show. Production had already commenced in December 1966 and ended in January 1968. The short one-year production run makes the 250 SL the rarest of the W113 series cars. The 250 SL retained the stiffer suspension and sportier feel of the early SLs, but provided improved agility with a new engine and rear disc brakes. Range also improved with increased fuel tank capacity from 65 litres to 82. Like its predecessor, the 250 SL was offered with a 4-speed automatic transmission, and 4-speed or ZF 5-speed manual transmissions. For the first time, an optional limited slip differential was also available. The main change was the use of the 2,496 cc M129.II engine with a larger stroke, increased valve ports, and seven main bearings instead of four. The nominal maximum power remained unchanged at 150 hp, but torque improved from 145 lb/ft to 159 lb/ft. Resiliency also improved with a new cooling water tank (“round top”) with increased capacity and a standard oil-water heat exchanger. The 250 SL also marked the introduction of a 2+2 body style, the so-called “California Coupé”, which had only the removable hardtop and no soft-top: a small fold-down rear bench seat replaced the soft-top well between passenger compartment and boot. It is estimated that only 10% of the 250SLs that were brought into America were California Coupes. Of the 5,196 250 SLs produced, more than a third were sold in the US.The 280 SL was introduced in December 1967 and continued in production through 23 February 1971, when the W113 was replaced by its successor, the entirely new and substantially heavier R107 350 SL. The main change was an upgrade to the 2,778 cc M130 engine with 170 hp and 180 lb/ft, which finally gave the W113 adequate power. The performance improvement was achieved by increasing bore by 4.5 mm (0.2 in), which stretched the limits of the M180 block, and required pairwise cylinder casts without cooling water passages. This mandated an oil-cooler, which was fitted vertically next to the radiator. Each engine was now bench-tested for two hours prior to being fitted, so their power specification was guaranteed at last. The M130 marked the final evolution of Mercedes-Benz’ venerable SOHC M180 inline-six, before it was superseded by the entirely new DOHC M110 inline-six introduced with R107 1974 European 280 SL models. For some time, it was also used in the W 109 300 S-Class, where it retired the expensive 3 liter M189 alloy inline-six. Over the years, the W 113 evolved from a sports car into a comfortable grand tourer, and US models were by then usually equipped with the 4-speed automatic transmission and air conditioning. Manual transmission models came with the standard 4-speed or the optional ZF 5-speed, which was ordered only 882 times and thus is a highly sought-after original option today. In Europe, manual transmissions without air conditioning were still the predominant choice. Of the 23,885 280 SLs produced, more than half were sold in the US.

With prices of the classic Pagoda model having risen to unaffordable for most people attention has started to switch to it successor, the R107 SL range, which had a long production life, being the second longest single series ever produced by the automaker, after the G-Class. The R107 and C107 took the chassis components of the mid-size Mercedes-Benz W114 model and mated them initially to the M116 and M117 V8 engines used in the W108, W109 and W111 series. The SL variant was a 2-seat convertible/roadster with standard soft top and optional hardtop and optional folding seats for the rear bench. The SLC (C107) derivative was a 2-door hardtop coupe with normal rear seats. The SLC is commonly referred to as an ‘SL coupe’, and this was the first time that Mercedes-Benz had based a coupe on an SL roadster platform rather than on a saloon, replacing the former saloon-based 280/300 SE coupé in Mercedes lineup. The SLC was replaced earlier than the SL, with the model run ending in 1981, with a much larger model, the 380 SEC and 500SEC based on the new S class. Volume production of the first R107 car, the 350 SL, started in April 1971 alongside the last of the W113 cars; the 350 SLC followed in October. The early 1971 350SL are very rare and were available with an optional 4 speed fluid coupling automatic gearbox. In addition, the rare 1971 cars were fitted with Bosch electronic fuel injection. Sales in North America began in 1972, and cars wore the name 350 SL, but had a larger 4.5L V8 with 3 speed auto (and were renamed 450 SL for model year 1973); the big V8 became available on other markets with the official introduction of the 450 SL/SLC on non-North American markets in March 1973. US cars sold from 1972 through 1975 used the Bosch D Jetronic fuel injection system, an early electronic engine management system. From July 1974 both SL and SLC could also be ordered with a fuel-injected 2.8L straight-6 as 280 SL and SLC. US models sold from 1976 through 1979 used the Bosch K Jetronic system, an entirely mechanical fuel injection system. All US models used the 4.5 litre engine, and were called 450 SL/SLC. In September 1977 the 450 SLC 5.0 joined the line. This was a homologation version of the big coupé, featuring a new all-aluminium five-litre V8, aluminium alloy bonnet and boot-lid, and a black rubber rear spoiler, along with a small front-lip spoiler. The 450SLC 5.0 was produced in order to homologate the SLC for the 1978 World Rally Championship. Starting in 1980, the 350, 450 and 450 SLC 5.0 models (like the 350 and 450 SL) were discontinued in 1980 with the introduction of the 380 and 500 SLC in March 1980. At the same time, the cars received a very mild makeover; the 3-speed automatic was replaced by a four-speed unit, returning to where the R107 started in 1971 with the optional 4 speed automatic 350SL. The 280, 380 and 500 SLC were discontinued in 1981 with the introduction of the W126 series 380 and 500 SEC coupes. A total of 62,888 SLCs had been manufactured over a ten-year period of which just 1,636 were the 450 SLC-5.0 and 1,133 were the 500 SLC. Both these models are sought by collectors today. With the exception of the SL65 AMG Black Series, the SLC remains the only fixed roof Mercedes-Benz coupe based on a roadster rather than a sedan. Following the discontinuation of the SLC in September 1981, the 107 series continued initially as the 280, 380 and 500 SL. At this time, the V8 engines were re-tuned for greater efficiency, lost a few hp and consumed less fuel- this largely due to substantially higher (numerically lower) axle ratios that went from 3.27:1 to 2.47:1 for the 380 SL and from 2.72:1 to 2.27:1 for the 500 SL. From September 1985 the 280 SL was replaced by a new 300 SL, and the 380 SL by a 420 SL; the 500 SL continued and a 560 SL was introduced for certain extra-European markets, notably the USA, Australia and Japan. Also in 1985, the Bosch KE Jetronic was fitted. The KE Jetronic system varied from the earlier, all mechanical system by the introduction of a more modern engine management “computer”, which controlled idle speed, fuel rate, and air/fuel mixture. The final car of the 18 years running 107 series was a 500 SL painted Signal red, built on August 4, 1989; it currently resides in the Mercedes-Benz museum in Stuttgart.

Mercedes-Benz introduced the W123 four-door versions on 29 January 1976. While there were some technical similarities to their predecessors, the new models were larger in wheelbase and exterior dimensions. The styling was also updated, although stylistic links with the W114 / W115 were maintained. Initially, all models except 280/280E featured quad unequal-size round headlights and the latter large rectangular units. When facelifted, these units became standard across the range. All W115 engines were carried over, with the 3-litre 5-cylinder diesel model being renamed from “240D 3.0” to “300D” (as it had already been called before in North American markets). The only new engine was the 250’s 2,525 cc inline-six (Type M123, a short-stroke version of the 2.8-litre six Type M110) that replaced the old 2,496 cc Type M114 “six”. In the spring of 1976, a Coupé version was introduced on a shorter wheelbase than the saloon (106.7 in versus 110.0 in). This W123C/CE was available as a 230C (later 230CE) and as a 280C/CE in most markets; in North America there were additional 300CD versions with naturally aspirated, later turbocharged 3-litre diesel engines. In North America, buyers favored diesel engines for upmarket cars, while CAFE legislation meant that Mercedes-Benz North America had to lower their corporate average fuel economy. This led to the introduction of a few diesel models only sold in the United States. It is a tribute to the car’s instant popularity – and possibly to the caution built into the production schedules – that nine months after its introduction, a black market had developed in Germany for Mercedes-Benz W123s available for immediate delivery. Customers willing to order new cars from their local authorised dealer for the recommended list price faced waiting times in excess of twelve months. Meanwhile, models that were barely used and were available almost immediately commanded a premium over the new price of around DM 5,000. From August 1976, long-wheelbase versions (134.8 in) were produced. These were available as 7/8 seater saloons with works bodies or as a chassis with complete front body clip, the latter serving as the base for ambulance and hearse bodies by external suppliers like Binz or Miesen. These “Lang” versions could be ordered as 240D, 300D and 250 models. At the Frankfurt Auto Show in September, 1977 the W123T estate was introduced; the T in the model designation stood for “Touring and Transport”. All engines derivative except “200TD” were available in the range. T production began in March, 1978 in Mercedes’ Bremen factory. It was the first factory-built Mercedes-Benz estate, previous estates had been custom-built by external coachbuilders, such as Binz. In early 1979, the diesel models’ power output was increased; power rose from 54 hp to 59 hp in the 200D, from 64 hp to 71 hp in the 240D and from 79 hp to 87 hp in the 300D; at the same time, the 220D went out of production. The first Mercedes turbo diesel production W123 appeared in September, 1981. This was the 300 TD Turbodiesel, available with automatic transmission only. In most markets, the turbocharged 5-cylinder 3-litre diesel engine (Type OM617.95) was offered only in the T body style, while in North America it was also available in saloon and coupé guises. June 1980 saw the introduction of new four-cylinder petrol engines (Type M102). A new 2-litre four with shorter stroke replaced the old M115, a fuel-injected 2.3-litre version of this engine (in 230E/TE/CE) the old carburettor 230. Both engines were more powerful than their predecessors. In 1980/81, the carburettor 280 versions went out of production; the fuel-injected 280E continued to be offered. In September 1982, all models received a mild facelift. The rectangular headlights, previously fitted only to the 280/280E, were standardised across the board, as was power steering. Since February 1982, an optional five-speed manual transmission was available in all models (except the automatic-only 300 turbodiesel). W123 production ended in January, 1986 with 63 final T-models rolling out. Most popular single models were the 240D (455,000 built), the 230E (442,000 built), and the 200D (378,000 built). The W123 introduced innovations including ABS (optional from August, 1980), a retractable steering column and an airbag for the driver (optional from 1982). Power (vacuum servo) assisted disc brakes were standard on all W123s. Available options included MB-Tex (Mercedes-Benz Texturized Punctured Vinyl) upholstery or velour or leather upholstery, interior wood trim, passenger side exterior mirror (standard on T models), 5-speed manual transmission (European market only), 4-speed automatic transmission (standard in turbodiesel models), power windows with rear-seat switch cut-outs, vacuum powered central locking, rear-facing extra seats (estate only), Standheizung (prestart timer-controlled engine heating), self-locking differential, sun roof, air conditioning, climate control, “Alpine” horn (selectable quieter horn), headlamp wipers (European market only), Tempomat (cruise control), power steering (standard after 1982/08), seat heating, catalytic converter (available from 1984 for California only, from fall (autumn) 1984 also in Germany for the 230E of which one thousand were built). These days, the cars are very popular “youngtimer” classics, with all models highly rated.

It is quite sobering to realise that the W201 is now more than 30 years olds as a design. Mercedes spent over £600 million researching and developing the 190 and subsequently said it was ‘massively over-engineered’. It marked a new venture for Mercedes-Benz, finally giving it a new smaller model to compete with the likes of the BMW 3 Series. The W201-based 190 was introduced in November 1982, and was sold in right-hand drive for the UK market from September 1983. Local red tape in Bremen (which produced commercial vehicles at the time) prevented Daimler-Benz from building the 190 there, so production was started in Sindelfingen at a capacity of just 140,000 units per year. Eventually after just the first year, Bremen was cleared for production of the 190, replacing its commercial vehicle lines, and there the 190 was built with the first running modifications since release. Initially there were just two models, the 190 and 190 E. Each was fitted with an M102 1,997 cc displacement engine. The 190 was fitted with an M102.921 90 hp engine and the 190 E fitted with an M102.962 122 hp engine. In September 1983, the 190 E 2.3 (2,299 cc) was released for the North American market only (although a 190 E 2.3 appeared in other countries later), fitted with a 113 hp M102.961 engine. This reduction in power was due to the emissions standards in the North American market at the time. The intake manifold, camshaft, and fuel injection system were refined in 1984, and the engine produced 122 hp. The carburettor 190 was revised in 1984 as well, increasing its horsepower rating to 105 hp. 1984 also saw the arrival of the 2.3-16 “Cosworth.” In 1985, the 190 E 2.3 now came fitted with the M102.985 engine, producing 130 hp until it was revised in 1987 to use Bosch KE3-Jetronic Injection, a different ignition system, and a higher compression ratio, producing 136 hp. 1987 marked the arrival of the first inline-six equipped 190, the 190 E 2.6. Fitted with the M103.940 engine, the 190 E 2.6 provided 160 hp with a catalyst and 164 hp without. In the North American market, the 190 E 2.6 was sold until 1993, the end of the W201 chassis’s production. From 1992-1993 the 2.6 was available as a special “Sportline” model, with an upgraded suspension and interior. The 190 E 2.3 was sold until 1988, then went on a brief hiatus until it was sold again from 1991 until 1993. The W201 190 D is known for its extreme reliability and ruggedness with many examples doing more than 500,000 miles without any major work. The 190 D was available in three different engines. The 2.0 was the baseline, and was never marketed in North America. The 2.2, with the same power as the 2.0, was introduced in September 1983. It was only available in model years 1984 and 1985, and only in the USA and Canada. The 2.5 was available in the late 80’s and early 90’s. The 2.5 Turbo, while sold in mainland Europe, but not the UK for many years, was available to American buyers only in 1987 and is now somewhat of a collectors item. The exterior of the 2.5 Turbo is different from other models in that it has fender vents in the front passenger side wing for the turbo to breathe. Although the early cars were very basic and not very powerful, they sold strongly, and things only got better as the model evolved, with the result that over 1.8 million had been produced by the time the W202 model arrived in 2002 to replace it.

Designed in 1984, and launched in 1989, the R129 was based on the shortened floorpan of the Mercedes-Benz W124 and featured many innovative details for the time, for instance electronically controlled damping (Adaptive Damping System ADS, optional) and a hidden, automatically extending roll-over bar. The R107’s somewhat dated rear suspension with semi-trailing arms gave way to a modern multi-link axle. The number of standard features was high, with electric action for the windows, mirrors, seats and hydraulic convertible top. This car has the distinction of being the first passenger vehicle to have seat belts integrated into the seats as opposed to anchoring to the floor, B-pillar, and transmission tunnel. Initially, there were three different engines available: 300 SL with a M103 3.0 L 12-valve SOHC I6 (188 bhp), a 300 SL-24 with a M104 3.0 L 24-valve DOHC I6 (228 bhp) and the 500 SL with a M119 5.0 L 32-valve DOHC V8 (322 bhp) . These were joined in July 1992 by the 600 SL with a M120 6.0 L 48-valve DOHC V12 (389 bhp). There was a choice of 5-speed manual or 4–5 speed automatic for the six-cylinder cars; the V8 and V12 could only be ordered with a 4-speed automatic gearbox. In autumn 1993 Mercedes-Benz rearranged names and models. Also, the 300 SL and 300 SL-24 were respectively replaced by: SL 280 with a M104 2.8 L 24-valve DOHC I6 (190 bhp) and the SL 320 with a M104 3.2 L 24-valve DOHC I6 (228 bhp). Only the 280 was available with a manual gearbox. SL 500 and 600 continued with their respective engines.Starting in 1993, the cars were re-designated. For example, 500 SL became SL 500. Starting in model year 1994, Mercedes-Benz offered special SL models from time to time, such as the Mille Miglia edition cars of model year 1994 or the SL edition of model year 2000. 1994 cars had minor updates for the car and then in 1995 there was a minor facelift for the car, with the front fender vents updated to only 2 rounded slots, rather than 3 squared slots, and bumpers in body colour. The V8 and V12s were upgraded to 5 speed electronic transmission, the previous transmission was hydraulic 4-speed. A second facelift occurred in 1998 with many detailed changes applied, including new external mirrors, 17″ wheels and new bumpers. Also new were the engines, a SL 280 with a M112 2.8 L 18-valve SOHC V6 (201 bhp); SL 320 with a M112 3.2 L 18-valve SOHC V6 (221 bhp) and a SL 500 with a M113 5.0 L 24-valve SOHC V8 (302 bhp). The V12 engine remained unchanged. The car was replaced by the R230 generation SL in 2001, after 213,089 had been built.

Also here was its successor, the R230 generation SL.

AMG-badged cars here included a C36 Estate version of the W202 generation, the later C63 Coupe from the C204 family, a rare modified W126 S Class, and from the top of the range the SLS and its replacement the AMG GT.

Known under development as the W198, the first iteration of the SL-Class grand tourer was the fastest production car of its day. Introduced in 1954 as a two-seat coupé with distinctive gull-wing doors, it was later offered as an open roadster. Built by Daimler-Benz AG, the direct fuel injected production model was based on the company’s highly successful yet somewhat less powerful carburettor overhead cam straight 6 1952 racer, the W194. The idea of a toned-down Grand Prix car tailored to affluent performance enthusiasts in the booming post-war American market was suggested by Max Hoffman. Mercedes accepted the gamble and the new 300 SL – 300 for its 3.0 litre engine displacement and SL for Sport Leicht (Sport Light) – was introduced at the 1954 New York Auto Show rather than the Frankfurt or Geneva gatherings company models made their usual debuts. Immediately successful and today iconic, the 300 SL stood alone with its distinctive doors, first-ever production fuel injection, and world’s fastest top speed. Even with the upward opening doors, the 300 SL had an unusually high sill, making entry and exit from the car’s cockpit problematic. A steering wheel with a tilt-away column was added to improve driver access. The 300 SL’s main body was steel, with aluminium bonnet, doors and boot lid. It could also be ordered with an 80 kg (180 lb) saving all-aluminium outer skin at tremendous added cost; just 29 were made. Like the W194, the 300 SL borrowed its 3.0 litre overhead cam straight-6 from the regular four-door 300 (W186 “Adenauer”) luxury tourer introduced in 1951. Featuring an innovative diagonal aluminium head that allowed for larger intake and exhaust valves, it was canted to the right at forty-five-degrees to fit under the SL’s considerably lower bonnet line. In place of the W194’s triple two-barrel Solex carburettors, a groundbreaking Bosch mechanical direct fuel injection was installed, boosting power almost 25% over the Grand Prix car’s. Derived from the DB 601 V12 used on the Messerschmitt Bf 109E fighter of World War II, it raised output from 175 hp to 215 hp, almost double that of the original Type 300 sedan’s 115 hp. An optional, even more powerful version, with radical camshaft developed 240 hp @ 6100 rpm and a maximum torque of 217 lb⋅ft @ 4800 rpm, but was rough for city use. The result was a top speed of up to 260 km/h (160 mph) depending on gear ratio and drag, making the 300 SL the fastest production car of its time. However, unlike today’s electrically powered fuel injection systems, the 300 SL’s mechanical fuel pump would continue to inject gasoline into the engine during the interval between shutting off the ignition and the engine’s coming to a stop; this unburned gasoline washed lubricating oil from the cylinder walls, which not only left them unprotected in affected areas during start-up but would dilute the engine’s entire oil supply if the car was not driven hard or long enough to reach a sufficient temperature to evaporate the fuel out of the oil. Exacerbating the problem was the engine’s large racing-oriented oil cooler and enormous 10 litre oil capacity, which virtually guaranteed the oil would not get hot enough. In practice, many owners would block off airflow through the oil cooler and stick rigidly to the appropriately low 1,000 mile recommended oil change interval. An auxiliary fuel pump provided additional fuel for extended high speed operation or cold starts; overuse would also lead to dilution of the oil., Clutch operation was initially very heavy, remedied by an improved clutch arm helper spring which reduced pedal force. From March 1963 to the end of production later that year, a light alloy crankcase was used on a total of 209 vehicles. Aerodynamics played an important role in the car’s speed, with Mercedes-Benz engineers placing horizontal “eyebrows” over the wheel openings to reduce drag. Unlike many cars of the 1950s, steering was relatively precise and the four-wheel independent suspension allowed for a reasonably comfortable ride and markedly better overall handling. However, the rear swing axle, jointed only at the differential, not at the wheels themselves, could be treacherous at high speeds or on imperfect roads due to extreme changes in camber. The enormous fuel tank capacity also caused a considerable difference in handling depending on the quantity of fuel on board. More than 80% of the vehicle’s total production of approximately 1400 units were sold in the US, making the Gullwing the first Mercedes-Benz widely successful outside its home market and thoroughly validating Hoffman’s prediction. The 300 SL is credited with changing the company’s image in America from a manufacturer of solid but staid luxury automobiles to one capable of rendering high-performance sports cars. It should be noted initial sales were sluggish due to many things, of which the price was one. Initial prices were about $6,400, a new Chevrolet Bel-Air could be purchased for $1,700 in the same year. Then there were few mechanics, even at the dealers, who understood the fuel injection system enough to do repairs. Nonetheless, 1400 were built by 1957, at which point Mercedes introduced a roadster version which was broadly similar, but with conventional doors. It was produced until 1963, and achieved sales of 1858 units.

MG

The first of the T Series sports cars appeared in 1936, to replace the PB. Visually they were initially quite similar, and as was the way in the 1930s, updates came frequently, so both TA and TB models were produced before global hostilities caused production to cease. Whilst the TC, the first postwar MG and launched in 1945, was quite similar to the pre-war TB, sharing the same 1,250 cc pushrod-OHV engine, it had a slightly higher compression ratio of 7.4:1 giving 54.5 bhp at 5200 rpm. The makers also provided several alternative stages of tuning for “specific purposes”. It was exported to the United States, even though only ever built in right-hand drive. The export version had slightly smaller US specification sealed-beam headlights and larger twin rear lights, as well as turn signals and chrome-plated front and rear bumpers. The body of the TC was approximately 4 inches wider than the TB measured at the rear of the doors to give more cockpit space. The overall car width remained the same resulting in narrower running boards with two tread strips as opposed to the previous three. The tachometer was directly in front of the driver, while the speedometer was on the other side of the dash in front of the passenger. 10,001 TCs were produced, from September 1945 to Nov. 1949, more than any previous MG model. It cost £527 on the home market in 1947.

The MGA replaced the long running T Series sports cars and presented a complete styling break from MG’s earlier sports cars. Announced on 26 September 1955, the car was officially launched at the Frankfurt Motor Show. A total of 101,081 units were sold through the end of production in July 1962, the vast majority of the 58.750 cars made were exported. Only 5869 cars were sold on the home market, the lowest percentage of any British car. It was replaced by the MGB. The MGA design dates back to 1951, when MG designer Syd Enever created a streamlined body for George Philips’ TD Le Mans car. The problem with this car was the high seating position of the driver because of the limitations of using the TD chassis. A new chassis was designed with the side members further apart and the floor attached to the bottom rather than the top of the frame sections. A prototype was built and shown to the BMC chairman Leonard Lord. He turned down the idea of producing the new car as he had just signed a deal with Donald Healey to produce Austin-Healey cars two weeks before. Falling sales of the traditional MG models caused a change of heart, and the car, initially to be called the UA-series, was brought back. As it was so different from the older MG models it was called the MGA, the “first of a new line” to quote the contemporary advertising. There was also a new engine available, therefore the car did not have the originally intended XPAG unit but was fitted with the BMC corporate B-Series type allowing a lower bonnet line. The MGA convertible had no exterior door handles, however the coupe did. It was a body-on-frame design and used the straight-4 1489cc “B series” engine from the MG Magnette saloon driving the rear wheels through a 4-speed gearbox. Suspension was independent with coil springs and wishbones at the front and a rigid axle with semi-elliptic springs at the rear. Steering was by rack and pinion. The car was available with either wire-spoked or steel-disc road wheels. The 1489 cc engine fitted with twin H4 type SU Carburettors produced 68 hp at first, but was soon uprated to 72 hp. Lockheed hydraulic drum brakes were used on all wheels. A high-performance Twin-Cam model was added for 1958. It used a high-compression (9.9:1 later 8.3:1) DOHC aluminium cylinder head version of the B-Series engine producing 108 hp. Due to detonation problems, a 100 bhp low-compression version was introduced later. Four-wheel disc brakes by Dunlop were fitted, along with Dunlop peg drive knock-off steel wheels similar to wheels used on racing Jaguars, unique to the Twin-Cam and “DeLuxe” MGA 1600 and 1600 MkII roadsters. These wheels and chassis upgrades were used on a small number of the “DeLuxe” models built after Twin-Cam production came to a halt. Aside from the wheels, the only outside identifier was a “Twin-Cam” logo near the vent aside the bonnet. A careful look at the rear wheel vents would also reveal another feature unique to Twin-Cam and DeLuxe: those 4 wheel Dunlop disc brakes . The temperamental engine was notorious for warranty problems during the course of production, and sales dropped quickly. The engine suffered from detonation and burnt oil. Most of the problems with the Twin-Cam engine were rectified with the low-compression version, but by then the damage had been done. Many restored Twin-Cams are running more reliably today than they ever did during production. The Twin-Cam was dropped in 1960 after 2,111 had been produced. Production ended in April 1960, but had slowed to a trickle long before. In May 1959 the standard cars also received an updated engine, now at 1588 cc producing 79.5 bhp . At the front disc brakes were fitted, but drums remained in the rear. Externally the car was very similar to the 1500 with differences including: amber or white (depending on market) front turn indicators shared with white parking lamps, separate stop/tail and turn lamps in the rear, and 1600 badging on the boot and the cowl. 31,501 of these were produced in less than three years. A number of 1600 De Luxe versions were produced with leftover special wheels and four-wheel disc brakes of the departed Twin-Cam, or using complete modified Twincam chassis left redundant by the discontinuance of that model. Seventy roadsters and 12 coupés were built. The engine size was increased again to 1622 cc by increasing the bore from 75.4 mm to 76.2 mm for the 1961 Mark II MGA. The cylinder head was also revised with larger valves and re-engineered combustion chambers. Horsepower increased to 90 bhp. It also had a higher ratio 4:1 rear axle, which made for more relaxed high-speed driving. An inset grille and Morris Mini tail lamps appearing horizontally below the deck lid were the most obvious visual changes. 8,198 Mark II roadsters and 521 coupés were built. As with the 1600 De Luxe, there were also some Mark II De Luxe versions; 290 roadsters and 23 coupés were produced.

As one of Britain’s most popular classic cars, it was no surprise to find several examples of the MGB here, with cars from throughout the model’s long life, both in Roadster and MGB GT guise, as well as one of the short-lived V8 engined cars. Launched in October 1962, this car was produced for the next 18 years and it went on to become Britain’s best selling sports car. When first announced, the MGB was an innovative, modern design, with a monocoque structure instead of the traditional body-on-frame construction used on both the MGA and MG T-types and the MGB’s rival, the Triumph TR series, though components such as the brakes and suspension were developments of the earlier 1955 MGA and the B-Series engine had its origins back in 1947. The lightweight design reduced manufacturing costs while adding to overall vehicle strength, and with a 95hp 3-bearing 1798cc engine under the bonnet, performance was quite respectable with a 0–60 mph time of just over 11 seconds. The car was rather more civilised than its predecessor, with wind-up windows now fitted as standard, and a comfortable driver’s compartment offered plenty of legroom. The roadster was the first of the MGB range to be produced. The body was a pure two-seater but a small rear seat was a rare option at one point. By making better use of space the MGB was able to offer more passenger and luggage accommodation than the earlier MGA while being 3 inches shorter overall. The suspension was also softer, giving a smoother ride, and the larger engine gave a slightly higher top speed. The four-speed gearbox was an uprated version of the one used in the MGA with an optional (electrically activated) overdrive transmission. A five-bearing engine was introduced in 1964 and a number of other modifications crept into the specification. In late 1967, sufficient changes were introduced for the factory to define a Mark II model. Alterations included synchromesh on all 4 gears with revised ratios, an optional Borg-Warner automatic gearbox, a new rear axle, and an alternator in place of the dynamo with a change to a negative earth system. To accommodate the new gearboxes there were significant changes to the sheet metal in the floorpan, and a new flat-topped transmission tunnel. US market cars got a new safety padded dashboard, but the steel item continued for the rest of the world. Rostyle wheels were introduced to replace the previous pressed steel versions in 1969 and reclining seats were standardised. 1970 also saw a new front grille, recessed, in black aluminium. The more traditional-looking polished grille returned in 1973 with a black “honeycomb” insert. Further changes in 1972 were to the interior with a new fascia. To meet impact regulations, in late 1974, the chrome bumpers were replaced with new, steel-reinforced black rubber bumpers, the one at the front incorporating the grille area as well, giving a major restyling to the B’s nose, and a matching rear bumper completed the change. New US headlight height regulations also meant that the headlamps were now too low. Rather than redesign the front of the car, British Leyland raised the car’s suspension by 1-inch. This, in combination with the new, far heavier bumpers resulted in significantly poorer handling. For the 1975 model year only, the front anti-roll bar was deleted as a cost-saving measure (though still available as an option). The damage done by the British Leyland response to US legislation was partially alleviated by revisions to the suspension geometry in 1977, when a rear anti-roll bar was made standard equipment on all models. US emissions regulations also reduced horsepower. In March 1979 British Leyland started the production of black painted limited edition MGB roadsters for the US market, meant for a total of 500 examples. Due to a high demand of the limited edition model, production ended with 6682 examples. The United Kingdom received bronze painted roadsters and a silver GT model limited editions. The production run of home market limited edition MGBs was split between 421 roadsters and 579 GTs. Meanwhile, the fixed-roof MGB GT had been introduced in October 1965, and production continued until 1980, although export to the US ceased in 1974. The MGB GT sported a ground-breaking greenhouse designed by Pininfarina and launched the sporty “hatchback” style. By combining the sloping rear window with the rear deck lid, the B GT offered the utility of a station wagon while retaining the style and shape of a coupe. This new configuration was a 2+2 design with a right-angled rear bench seat and far more luggage space than in the roadster. Relatively few components differed, although the MGB GT did receive different suspension springs and anti-roll bars and a different windscreen which was more easily and inexpensively serviceable. Although acceleration of the GT was slightly slower than that of the roadster, owing to its increased weight, top speed improved by 5 mph to 105 mph because of better aerodynamics. 523,826 examples of the MGB of all model types were built, and although many of these were initially sold new in North America, a lot have been repatriated here. There were several Roadsters and MGB GT models here.

The MGC was produced as a sort of replacement for the Big Healey, though apart from sharing that car’s 3 litre straight six C Series engine, the reality is that the car was quite different and generally appealed to a different sort of customer. Or, if you look at the sales figures, you could say that it did not really appeal to anyone much, as the car struggled to find favour and buyers when new. More of a lazy grand tourer than an out and out sports car, the handling characteristics were less pleasing than in the B as the heavy engine up front did the car no favours. The market now, finally, takes a different view, though and if you want an MGC, in Roadster or the MGC GT form the latter of which was to be seen here, you will have to dig surprisingly deeply into your pocket.

This is an MG 1300, the second of the Issigonis trio of space efficient front wheel drive ADO16 family of cars, which was first seen in August 1962 as the Morris 1100. A four door saloon, with styling that had been influenced by Pininfarina, this car applied the same principles as had been seen in the Mini of three years earlier, but in a larger package, creating plenty of space for 4 or even 5 adults and with more luggage room. Power came from a 1098cc version of the proven A Series engine, which gave it a lively (for the time!) performance and the combination of a long wheelbase and innovative hydrolastic suspension gave it a particularly comfortable ride. A sporting MG model, with twin carburettors was added to the range before the year was out. In 1963 an Austin model appeared, identical to the Morris in all but grille and tail end treatment, and then Wolseley, Riley and even Vanden Plas models were added to the range in 1965 and 1966, as well as Countryman and Traveller estate versions of the Austin and Morris. The Vanden Plas Princess model came out in the autumn of 1965, applying the sort of levels of equipment and luxury finish that were usually found on large cars to something much smaller. Despite the lofty price tag, there was a definite market for these cars, many of which had relatively gentle use when new, so there are a few survivors, including this later 1300 model. Mark 2 models were launched in 1967 with the option of a 1300 engine, and a slightly less spartan interior. The car became Britain’s best seller, a position it held until 1972, The MG models received the 1275cc engine in 1967 and with twin carburettors were quite brisk for their day. Combine that with good handling (this was an era when front wheel drive was good and rear wheel drive was not!), and the cars were popular with enthusiasts, though you do not see many these days. The MG and Riley versions were replaced by the 1300GT. Sold in Austin and Morris versions, these cars had a vinyl roof and rostyle wheels to give them the looks to match the performance delivered by the twin carburettor A Series 1275cc engine, and they were popular for a little while, with few direct rivals in the market.

The Metro range was expanded in May 1982 to include the luxury Vanden Plas and higher performance MG versions; the MG Metro marked a quick comeback for the marque previously used on sports cars until the Abingdon plant making the MG B closed in 1980. The Vanden Plas featured higher levels of luxury and equipment, while the slightly more powerful MG Metro 1.3 sold as a sports model (0–60 mph in 10.9 seconds, top speed 103 mph). The Vanden Plas variant received the same MG engine from 1984 onwards (with the exception of the VP Automatic, which retained the 63 bhp 1275 cc unit). The luxury fittings marking out the Metro Vanden Plas took the form of a radio-cassette player, electric front windows, an improved instrument panel with tachometer, and a variety of optional extras such as trip computer, leather trim, remote boot release, and front fog lamps. The changes between the MG engine (taken directly from the Mini Cooper) and the standard 1275 included a modified cylinder head, with larger valves and improved porting, altered cam profile and larger carburettor leading to a 20% increase in BHP to 72 bhp. At the October 1982 Birmingham Motor Show the MG Metro Turbo variant was first shown. With a quoted bhp of 93, 0–60 mph in 9.9 seconds, and top speed of 112 mph (180 km/h) this car had few direct competitors at the time, although the growing demand for “hot hatches” meant that it soon had a host of competitors including the Ford Fiesta XR2, Peugeot 205 GTI and Renault 5 GT Turbo.[10] This model had a few addition modifications bolted on over the normally aspirated MG model to give an additional 21 bhp. Aside from the turbocharger and exhaust system itself, and what was (at the time) a relatively sophisticated boost delivery and control system, the MG Turbo variant incorporated stiffer suspension (purportedly with engineering input from Lotus), and an uprated crankshaft of nitrided steel and sodium-cooled exhaust valves. Both MG variants were given a “sporty” interior with red seat belts, red carpets and a sports-style steering wheel. The Turbo also benefitted from an LCD boost pressure gauge. The Turbo also received alloy wheels, black wheel arch extensions, blacked out trim, a rear spoiler surrounding the windshield, and prominent “TURBO” decals. While it retained rear drums, the front disc brakes were changed to ventilated units.[10] The later MG variants were emblazoned with the MG logo both inside and out, which only served to fuel claims of badge engineering from some of the more steadfast MG enthusiasts. Others believed that this sentiment was unfounded, particularly in the case of the turbo variant, due to the undeniably increased performance and handling when compared to the non-MG models.

Also here was an MG Maestro. This was launched a few weeks after the Austin-badged ars, initially as an R Series Weber twin carburettor engined 1.6 model, which was produced for less than a year, before a rather better O Series 2.0i car replaced it. Objectively very good, it never found the sales success that it perhaps deserved. At the NEC Birmingham Show in October 1988, Austin-Rover Group showed a Turbo version of the MG, and it was launched in early 1989. The final car from Austin-Rover, before the company changed names again to Rover Group, this was only ever intended to be a limited edition car with 500 cars for sale and 5 press cars. It made use of the 2.0’s already impressive engine, but the combination of carburettor and turbocharger gave it a top speed of 128 mph and an 0–60 mph time of 6.7 seconds. It was faster than the majority of its competitors, but the high performance, Tickford designed bodykit and alloys did little to disguise the fact that it was very much still a Maestro. Sales were slow, as it appeared six years after the Maestro’s launch.

In advance of the all-new MX5 rival that was still some way off production, MG decided to re-enter the open topped sports car market in 1992 when they launched the MGR V8, which combined new body panels with the standard MGB body shell to create an updated MGB model. The suspension was only slightly updated, sharing the leaf spring rear of the MGB. The boot lid and doors were shared with the original car, as were the rear drum brakes. The engine was the 3.9-litre version of the aluminium Rover V8, similar to the one previously used in the MGB GT V8. A limited-slip differential was also fitted. The interior featured veneered burr elm woodwork and Connolly Leather. The engine produced 190 bhp at 4,750 rpm, achieving 0–60 mph in 5.9 seconds, which was fast but largely due to the rear drum brakes and rear leaf springs, the RV8 was not popular with road testers at the time. A large proportion of the limited production went to Japan – 1579 of the 2000 produced. Only 330 RV8s were sold initially in the UK, but several hundred (possibly as many as 700) of these cars were re-imported back to the UK and also Australia between 2000–2010 with a peak number of 485 registered at the DVLA in the UK.

There was quite an array of the most recent MG sportscar here, with MGF and TF models. MG re-entered the sports car market in 1995 with the launch of the MGF Two versions of this mid-engined and affordable rival to the Mazda MX5 were offered: both of which used the 1.8 litre K-Series 16-valve engine. The cheaper of the two put out 118 hp and the more costly VVC model (by dint of its variable valve control) had 143 hp. Rover Special Projects had overseen the development of the F’s design and before finalising the styling bought-in outside contractors to determine the most appropriate mechanical configuration for the new car. Steve Harper of MGA Developments produced the initial design concept in January 1991 (inspired by the Jaguar XJR-15 and the Ferrari 250LM), before Rover’s in house design team refined the concept under the leadership of Gerry McGovern. The MGF used the Hydragas suspension, a system employing interconnected fluid and gas displacers, which gave the car a surprisingly compliant ride and which could be tuned to provide excellent handling characteristics. The MG F quickly shot to the top of the affordable sports car charts in Britain and remained there until the introduction of the MG TF in 2002. The MG F underwent a facelift in Autumn of 1999 which gave the car a revised interior as well as styling tweaks and fresh alloy wheels designs. There was also the introduction of a base 1.6 version and a more powerful 160 hp variant called the Trophy 160, which had a 0-60 mph time of 6.9 seconds. It was only produced for a limited time. An automatic version with a CVT called the Steptronic was also introduced. A comprehensive update in 2002 resulted in the MG TF, named after the MG TF Midget of the 1950s. Based upon the MG F platform but heavily redesigned and re-engineered, the most significant mechanical changes were the abandonment of Hydragas suspension in favour of conventional coil springs, the new design of the air-induction system that along with new camshafts produces more power than in MG F engines, and the torsional stiffness of the body increased by 20%. Various cosmetic changes included a revised grille, redesigned front headlights, bumpers, side air-intake grills and changes to the rear boot,. The car continued to sell well. Production was suspended when MG-Rover went out of business, but resumed again in 2007 when Nanjing built a number more.

Unless you go back to the 1930s. when MG made a few high performance cars which had racing more in mind than road use, the only model to get anywhere supercar status that bears the famous roundel is the SV, and this was also represented here. This car came about after MG-Rover acquired Qvale of Italy. Taking the Qvale Mangusta as a base, a car which had been designed, but not quite made production, MG Rover allocated the project code X80 and set up a subsidiary company, MG X80 Ltd., to produce their new model. A big factor behind the project was that was seen as having the potential sales in the United States, as the Mangusta had already been homologated for the American market. The MG X80 was originally revealed as a concept car in 2001. However, the styling was considered too sedate, so when the production model, now renamed MG XPower SV, was eventually launched the following year, designer Peter Stevens had made the car’s styling more aggressive. The conversion from a clay model to a production car, including all requirements, was done in just 300 days by the Swedish company Caran. The production process was complex, partly caused by the use of carbon fibre to make the body panels. The basic body parts were made in the UK by SP Systems and then shipped to Belco Avia near Turin for assembly into body panels. These were then assembled into a complete body shell and fitted onto the box frame chassis and running gear and shipped to MG Rover’s Longbridge factory to be trimmed and finished. Several of the cars’ exterior and interior parts were borrowed from current and past Fiat models. The headlights, for example, were taken from a Punto Mk.2 and the rear lights borrowed from a Fiat Coupe. The goal had been to get a street price of under £100,000, and on launch, the base model came in well under that at £65,000, and even the uprated XPower SV-R model was priced at £83,000. Those were ambitious prices for a car bearing MG badges, though, so not surprisingly, sales were slow. It is understood that just 82 cars were produced excluding the 4 ‘XP’ pre-production prototypes. This included a few pre-production and show cars which were later dismantled, before production was stopped due to lack of sales. Most were sold to private owners, with the final ones being sold to customers in early 2008.

In mid 2001, an MG version of the 45 had been launched, called the ZS, which gave MG a range of 3 different models as well as the TF sports car. The view of the press was that the suspension and steering alterations completely transformed the car, but this model was in a difficult part of the market, compared to the smaller ZR and is found fewer buyers. Those who did sample the ZS, especially in ZS 180 guise with the 2.5 litre KV6 got an absolutely cracking car though. It sported a V6 with all the aural benefits when all its rivals had 4 cylinder turbo engines. Later cars were facelifted to distinguish them more clearly from the Rover 45, with elements of the X Power bodykit being made standard.

Three years after the launch of the Rover 75 and less than a year after the de-merger of MG Rover from BMW, the MG ZT and MG ZT-T were launched, along with the cheaper 25-based ZR and 45-based ZS models. The basic shape and styling of the MG ZT remained the same as for the Rover 75 but with changes to the front bumper, now with an integrated grille, and detail alterations including colour coding of the chromed waistline, a new bootlid plinth and different alloy wheels and tyres sizes. The interior featured revised seats and dashboard treatment with new instrument faces. Engineering changes ranged from uprated suspension and brakes to revised engine tuning for the petrol and diesel models. Development of the MG ZT was headed by Rob Oldaker, Product Development Director, with styling changes undertaken by Peter Stevens, who was previously responsible for the styling of the McLaren F1 and X180 version of the Lotus Esprit. At launch, the most potent ZT was the 190bhp petrol powered model, but in 2003, the 260 version of the car was launched, which utilised a 4.6 litre V8 from the Ford Mustang range. The model was converted from front-wheel drive to rear-wheel drive and was largely engineered by motorsport and engineering company Prodrive before being completed by MG. Apart from the badges, the only visual difference externally between the 260 and other ZTs are the quad exhausts. The 4.6 version is regarded as a true Q-car. and it has its own every enthusiastic and active Owners Club.

The GS is the latest addition to the range, a family-sized crossover, for which as a genre there is huge and growing demand. It will be interesting to see how well this one sells.

MINI

Once again, the RAF Mini Club had a stand right in the middle of the event, with a variety of examples of Issigonis’ classic on show.

In 1969, now under the ownership of British Leyland, the Mini was given a facelift by stylist Roy Haynes, who had previously worked for Ford. The restyled version was called the Mini Clubman, and had a squarer frontal look, using the same indicator/sidelight assembly as the Austin Maxi. The Mini Clubman was intended to replace the upmarket Riley and Wolseley versions, and a new model, dubbed the 1275 GT, was slated as the replacement for the 998 cc Mini Cooper, the 1,275 cc Mini Cooper S continuing alongside the 1275 GT until 1971. The Clubman Estate replaced the Countryman and Traveller. The original “round-front” design remained in production alongside the Clubman and 1275 GT. Production of the Clubman and 1275 GT got off to a slow start because the cars incorporated “lots of production changes” including the relocation of tooling from Cowley to the Longbridge plant: so very few cars were handed over to customers before the early months of 1970. Early domestic market Clubmans were still delivered on cross-ply tyres despite the fact that by 1970 radials had become the norm for the car’s mainstream competitors. By 1973 new Minis were, by default, being shipped with radial tyres, though cross-plies could be specified by special order, giving British buyers a price saving of £8. The most significant update after this came in 1976, when the engine was upgraded to the 110cc A Series unit, cloth seat trim was made standard and the wiper functions were moved to a column stalk. The stick on “wood” trim was replaced by painted coachlines at this time. The Clubman models were deleted in 1980, effectively replaced by the Metro, and they are relatively rare these days. The 1275 GT is often incorrectly described as the “Mini Clubman 1275 GT”. The official name was always just the “Mini 1275 GT”, and it was a separate, distinct model from the Clubman (although it shared the same frontal treatment as the Mini Clubman, and was launched at the same time). It had the 1275cc A Series unit and a 4 speed gearbox, as well as larger wheels. It was also deleted in the autumn of 1980. Although moderately popular when new, it is now seen as something of a poor substitute for the Cooper models, and the survival rate is pretty low, so you don’t see them that often. There were a couple here, in very period colours.

This elegant looking Mini was built in 1989 to mark the 30th anniversary of the model. Based on the Mini Mayfair, it had the standard 998 cc and was mechanically identical to the normal production cars. It could be distinguished by its chrome bumpers and grille, coachlines and 1959-1989 crests, whilst inside there was half leather/lightning cloth upholstery with red piping. Additional equipment included Minilite-style wheels, a security coded stereo and a leather-bound copy of Rob Golding’s book (“Mini”). Of the 3,000 produced for the UK, 2,000 were in Cherry Red and 1,000 were Black; 2,800 were manual and 200 had an automatic gearbox. 600 were made with an optional sun roof.

Representing the modern MINI was this example of a first generation MINI John Cooper Works GP, the last Mk I MINI variant to be produced using the supercharged Tritec engine. This was sold as a light-weight, quasi-race-prepped John Cooper Works model, hand-finished by Bertone in Italy. It was offered as a limited-production run of 2000 cars during the 2006 model year, with 444 of those originally intended for the UK market, although ultimately, 459 were sold, even though the price was somewhat eye-watering. The GP featured more bolstered Recaro front seats but had no rear seats, which along with reduced sound-deadening, removal of the rear wash-wipe system, optional air-conditioning and radio, and other weight-reduction steps, resulted in a weight saving of around 40 kg (88 lb) compared to a Cooper S. Mechanically, it featured a less restrictive intercooler, recalibrated engine management, high-volume injector nozzles, and a freer-flowing exhaust system. Extra cooling capabilities lets the supercharged engine run longer on cooler temperatures for better track performance. This resulted in an output of 218 hp from a faster revving engine. Additionally, the car had enhanced braking, suspension, and a smooth under-body for better aerodynamics. The whole geometry of the rear axle was modified with parts from the Mini Challenge race car to enhance the handling. In place of the rear seats there is a metal bar for a stiffer chassis performance. The car also offered many unique styling points, such as the red door mirrors, a carbon fibre rear spoiler, unique body kit, bespoke, 2 kg lighter four-spoke alloy wheels, and specialised badging. Available in just one colour scheme (Thunder Blue with a Pure Silver roof), each car was individually numbered and featured a decal on the roof along with a plaque on the dashboard. Although they were costly when new, they have held their value very well, and rarely come up for sale even now, more than 10 years after they were new.

MORGAN

There were plenty of Morgan models here, most of them the classic shape that first appeared in the mid 50s and which is still available brand new now as the Plus 4 and Roadster.

Oldest Morgan here was a “Flat Rad”, the name given to the first of the 4-wheeled cars, produced from 1935. and more correctly called the 4-4. The first cars had the sliding pillar suspension of the three-wheeler plus an underslung live rear axle sitting over Z-section cross-section chassis side rails, carried in leaf springs. The first cars had a 34 bhp 1122 Coventry Climax four cylinder engine, a crossflow with overhead inlet and side exhaust valves. In competition form it had a slightly smaller capacity of 1098cc and it put out a healthy 50 – 60 bhp. The car enjoyed considerable success with a lightened car winning the Tourist Trophy in 1937 on handicap and in 1938 if finished second in class at Le mans. In 1939, Morgan changed to the 1267 cc overhead valve Standard Special engine which was both lighter and more powerful. Post was the name was changed to Plus 4 and in 1950 the engine was replaced by the much larger 2088cc 68 bhp Standard engine from the Vanguard and the body was revised to be slightly wider and roomier. The bodies were made of steel over a wooden frame. three different styles were offered: a two seater, a four seat tourer and a drophead coupe. This last was more sophisticated with a fixed windscreen frame sliding windows and a three position hood. The first of the cowled radiator cars arrived in 1953.

Also here was an Aero 8, the first new design from the Malvern Link company for over 35 years. Morgan’s first supercar, the first run of Aero models was unveiled at the Geneva motorshow in 2000 by Charles Morgan, it was in his words “the result of the biggest development project ever undertaken by the Morgan Motor Company”. The result of many years of hard work, a development programme that included racing in the FIA GT series and a partnership with BMW. Whilst the car structure comes as pre-formed bonded aluminium elements significant work goes into hand making the overall vehicle continuing the handmade history of the company. The method of building the car was ahead of most companies in the marketplace and represented a dramatic shift for the company. The superformed and bonded aluminium chassis has elements of an ash frame to provide a link to the more traditional cars. It was designed by Chris Lawrence who had a long standing relationship with Morgan and included many features of racing cars of the time. Items such as in-board shock absorbers, double wishbones all round, a flat floor, centre lock magnesium wheels, rose-jointed suspension and other elements were included providing significant handling improvements over previous models. Complete with a bespoke aluminium chassis, all independent suspension and powered by a 4.4 litre BMW V8 engine (M62TUB44) producing 286 bhp at 5500 rpm and 322 lbs-ft (430Nm) at 3750 rpm this was a radical departure from the traditionally built Morgans. Performance was 0 to 62 mph in 4.8 seconds with a top speed of 160 mph. The interior had a turned aluminium dashboard, unusual asymmetric design and a custom made Burberry case for use as a removable glovebox, along with nods to modern services such as cruise control, air-conditioning and a heated windscreen. With many elements from BMW including the engine, gearbox and axle to push 1100kgs the performance was on a par with Ferraris, Porsches, TVRs and other supercars of the day. Whilst the car did include an LSD the absence of other stability and traction aids mean the driver had total control over the car. Famous for its cross-eyed squint courtesy of the reversed VW Beetle headlamps, this was a culmination of both aerodynamic requirements and availability of light units at the time. Initially Porsche lights had been trialled along with the yet to be released new Mini units, the Mini lights were a favourite but BMW didn’t want the first model to launch their new headlights to be the Aero so these were not an option. Aerodynamically (extensive wind tunnel testing was carried out at MIRA – another Morgan first) Morgan needed a way to allow the leading edge of the front wings to be forward of the radiator, thus providing space to incorporate a front splitter. The VW Beetle headlamps were spotted by Chris Lawrence who invisaged reversing them to give the perfect angle to meet the aerodynamic requirements, and thus the cross-eyed look was born. Around 210 Series 1 cars were made with many smaller changes being made to the car over this period internally and externally. The Series 2 of the Aero 8 was launched at the 2004 Los Angeles Motor Show. This was the first Aero that was made for sale in North America. It was called the Aero Series 2 or Aero America as a result. The back of the car was changed in a number of ways. The petrol tank was repositioned to comply with US rear impact regulations. The boot lid was raised to improve aero-dynamics and storage. The previous folding roof was changed for a pram style changing the shape from the previous low “gangster” style roof of the Series 1. Now using the BMW V8 4.4L engine N62B44 333 bhp at 6,100 rpm and 331 lb-ft (450Nm) at 3,600 rpm using VarioCam on the inlet manifold. The factory offered single side exit exhausts as an option with the exit just in front of the rear wheels on each side. The new V8 provided a top speed of 160 mph with 0 to 62 mph acceleration in 4.8 seconds. Further revisions included a conversion to standard 5 stud wheels, uprated gearbox, brakes and other elements of the running gear. The car retained the same overall dimensions but internal space was increased by moving the doors further out and making the wings/running boards narrower over the Series 1. The unusual asymmetric dashboard of the Series 1 was replaced with a more conventionally styled dashboard however the fly-off handbrake was retained. Something in the region of 60 cars (both LHD and RHD) were produced. The third iteration of the Aero was largely around adding the new style Mini headlamps with changes to the wings and front panels resolving the famous squint of the earlier cars. It retained the interior and mechanical platform of the Series 2. This new front design went on to be used on the new AeroMax and subsequent Aero models. Version 4 of the Morgan Aero 8 saw the 3rd new engine in the life of the vehicle; the BMW 4.4 V8 has been replaced with the BMW 4.8 V8 (N62B48) with 362 bhp and 370 lb/ft of torque. This 13% power increase over the previous Aero gives the new Series 4 Aero 8 a power to weight ratio of 315bhp per tonne. A first for the Aero 8 also comes in the form of an optional automatic transmission; Morgan state: – ZFs 6 HP26 six speed gives even better performance than a manual gearbox due to its special lock up clutch, low power loss design and instant change characteristic. The automatic is usable either as a full automatic for more relaxed driving or in sport manual mode when the bespoke gear lever will hold the engine revs up to the maximum in each gear, increase change speed and blip the throttle to smooth down changes. In addition to these technical changes, a repositioned fuel tank (to improve the weight distribution), revised instrumentation (from cream dials with blue numerals to black with white), an increase in luggage space, revised air vents, a move to a conventional handbrake lever and air intakes and exits on the front wings distinguish the Series 4 Aero 8 from previous models. 179 of these were produced between 2007 and 2010.

Completing the display was the latest Three Wheeler. First referred to in 2011, and launched in production spec in 2012, has been a huge success for Morgan, and for a while the company simply could not build them fast enough. Relatively affordable, compared to the other products in the range, this fun machine has a 2 litre S&S engine coupled to an MX-5 gearbox, and a weight of 550 kg, which is enough to give it a top speed of around 115 mpg and a 0- 60 time of less than 5 seconds.

MORRIS

No surprise to see the evergreen Morris Minor here as this is a very popular classic. The Minor was conceived in 1941. Although the Nuffield Organization was heavily involved in war work and there was a governmental ban on civilian car production, Morris Motors’ vice chairman, Miles Thomas, wanted to prepare the ground for new products to be launched as soon as the war was over. Vic Oak, the company’s chief engineer, had already brought to Thomas’ attention a promising junior engineer, Alec Issigonis, who had been employed at Morris since 1935 and specialised in suspension design but he had frequently impressed Oak with his advanced ideas about car design in general. Issigonis had come to Oak’s particular attention with his work on the new Morris Ten, which was in development during 1936/7. This was the first Morris to use unitary construction and was conceived with independent front suspension. Issigonis designed a coil-sprung wishbone system which was later dropped on cost grounds. Although the design would later be used on the MG Y-type and many other post-war MGs the Morris Ten entered production with a front beam axle. Despite his brief being to focus on the Ten’s suspension Issigonis had also drawn up a rack and pinion steering system for the car. Like his suspension design this was not adopted but would resurface in the post-war years on the MG Y-type, but these ideas proved that he was the perfect candidate to lead the design work on a new advanced small car. With virtually all resources required for the war effort, Thomas nonetheless approved the development of a new small family car that would replace the Morris Eight. Although Oak (and Morris’ technical director, Sidney Smith) were in overall charge of the project it was Issigonis who was ultimately responsible for the design, working with only two other draughtsmen. Thomas named the project ‘Mosquito’ and ensured that it remained as secret as possible, both from the Ministry of Supply and from company founder William Morris (now Lord Nuffield), who was still chairman of Morris Motors and, it was widely expected, would not look favourably on Issigonis’ radical ideas. Issigonis’ overall concept was to produce a practical, economical and affordable car for the general public that would equal, if not surpass, the convenience and design quality of a more expensive car. In later years he summed up his approach to the Minor; that he wanted to design an economy car that “the average man would take pleasure in owning, rather than feeling of it as something he’d been sentenced to” and “people who drive small cars are the same size as those who drive large cars and they should not be expected to put up with claustrophobic interiors.” Issigonis wanted the car to be as spacious as possible for its size and comfortable to drive for inexperienced motorists. Just as he would with the Mini ten years later, he designed the Mosquito with excellent roadholding and accurate, quick steering not with any pretence of making a sports car, but to make it safe and easy to drive by all. As work proceeded, there were plenty of battle to overcome, to get Issigonis’ ideas approved, and not all of them were. The production car, called the Minor was launched at the British Motor Show at Earls Court in London on October 27, 1948. At the same show Morris also launched the new Morris Oxford and Morris Six models, plus Wolseley variants of both cars, which were scaled-up versions of the new Minor, incorporating all the same features and designed with Issigonis’ input under Vic Oak’s supervision. Thus Issigonis’ ideas and design principles underpinned the complete post-war Morris and Wolseley car ranges. The original Minor MM series was produced from 1948 until 1953. It included a pair of four-seat saloons, two-door and (from 1950) a four-door, and a convertible four-seat Tourer. The front torsion bar suspension was shared with the larger Morris Oxford MO, as was the almost-unibody construction. Although the Minor was originally designed to accept a flat-4 engine, late in the development stage it was replaced by a 918 cc side-valve inline-four engine, little changed from that fitted in the 1935 Morris 8, and producing 27.5 hp and 39 lbf·ft of torque. This little engine pushed the Minor to just 64 mph but delivered 40 mpg. Brakes were four-wheel drums. Early cars had a painted section in the centre of the bumpers to cover the widening of the production car from the prototypes. This widening of 4 inches is also visible in the creases in the bonnet. Exports to the United States began in 1949 with the headlamps removed from within the grille surround to be mounted higher on the wings to meet local safety requirements. In 1950 a four-door version was released, initially available only for export, and featuring from the start the headlamps faired into the wings rather than set lower down on either side of the grille. The raised headlight position became standard on all Minors in time for 1951. From the start, the Minor had semaphore-type turn indicators, and subsequent Minor versions persisted with these until 1961 An Autocar magazine road test in 1950 reported that these were “not of the usual self-cancelling type, but incorporate[d] a time-basis return mechanism in a switch below the facia, in front of the driver”. It was all too easy for a passenger hurriedly emerging from the front passenger seat to collide with and snap off a tardy indicator “flipper” that was still sticking out of the B-pillar, having not yet been safely returned by the time-basis return mechanism to its folded position. Another innovation towards the end of 1950 was a water pump (replacing a gravity dependent system), which permitted the manufacturer to offer an interior heater “as optional equipment”. When production of the first series ended, just over a quarter of a million had been sold, 30 per cent of them the convertible Tourer model. In 1952, the Minor line was updated with an Austin-designed 803 cc overhead valve A-series engine, replacing the original side-valve unit. The engine had been designed for the Minor’s main competition, the Austin A30, but became available as Austin and Morris were merged into the British Motor Corporation. The new engine felt stronger, though all measurements were smaller than the old. The 52 second drive to 60 mph was still calm, with 63 mph as the top speed. Fuel consumption also rose to 36 mpg. An estate version was introduced in 1952, known as the Traveller (a Morris naming tradition for estates, also seen on the Mini). The Traveller featured an external structural ash (wood) frame for the rear bodywork, with two side-hinged rear doors. The frame was varnished rather than painted and a highly visible feature of the body style. Commercial models, marketed as the Morris Quarter Ton Van and Pick-up were added in May 1953. Rear bodies of the van versions were all steel. The 4-seat convertible and saloon variants continued as well. The car was again updated in 1956 when the engine was increased in capacity to 948 cc. The two-piece split windscreen was replaced with a curved one-piece one and the rear window was enlarged. In 1961 the semaphore-style trafficators were replaced by the flashing direction indicators, these were US-style red at the rear (using the same bulb filament as the brake lamp) and white at the front (using a second brighter filament in the parking lamp bulb) which was legal in the UK and many export markets at the time (such as New Zealand). An upmarket car based on the Minor floorpan using the larger BMC B-Series engine was sold as the Riley One-Point-Five/Wolseley 1500 beginning in 1957: versions of this Wolseley/Riley variant were also produced by BMC Australia as the Morris Major and the Austin Lancer. In December 1960 the Morris Minor became the first British car to sell more than 1,000,000 units. To commemorate the achievement, a limited edition of 350 two-door Minor saloons (one for each UK Morris dealership) was produced with distinctive lilac paintwork and a white interior. Also the badge name on the side of the bonnet was modified to read “Minor 1,000,000” instead of the standard “Minor 1000”. The millionth Minor was donated to the National Union of Journalists, who planned to use it as a prize in a competition in aid of the union’s Widow and Orphan Fund. The company, at the same time, presented a celebratory Minor to London’s Great Ormond Street Hospital for Sick Children, but this car was constructed of cake.The final major upgrades to the Minor were made in 1962. Although the name Minor 1000 was retained, the changes were sufficient for the new model to be given its own ADO development number. A larger version of the existing A-Series engine had been developed in conjunction with cylinder head specialist Harry Weslake for the then new ADO16 Austin/Morris 1100 range. This new engine used a taller block than did the 948 cc unit, with increased bore and stroke bringing total capacity up to 1,098 cc. Although fuel consumption suffered moderately at 38 mpg, the Minor’s top speed increased to 77 mph with noticeable improvements in low-end torque, giving an altogether more responsive drive. Other changes included a modified dashboard layout with toggle switches, textured steel instrument binnacle, and larger convex glove box covers. A different heater completed the interior upgrade, whilst the larger combined front side/indicator light units, common to many BMC vehicles of the time, were fitted to the front wings. These now included a separate bulb and amber lens for indicators while larger tail lamp units also included amber rear flashers. During the life of the Minor 1000 model, production declined. The last Convertible/Tourer was manufactured on 18 August 1969, and the saloon models were discontinued the following year. Production of the more practical Traveller and commercial versions ceased in 1972, although examples of all models were still theoretically available from dealers with a surplus of unsold cars for a short time afterwards. 1,619,857 Minors of all variants were ultimately sold and to be seen here were a number of variants including one of the Minor Million cars.

NISSAN/DATSUN

Although not many of the Datsun 240Z were sold in the UK, or indeed Europe, this car proved phenomenally popular in the US, and was really the beginning of the end for the British sports cars which American buyers had been buying in large quantities throughout the 1960s. Known internally as the Nissan S30, and sold in Japan as the Nissan Fairlady Z, the car we call the the Datsun 240Z, and the later 260Z and 280Z was the first generation of Z GT two-seat coupe, produced by Nissan from 1969 to 1978. It was designed by a team led by Yoshihiko Matsuo, the head of Nissan’s Sports Car Styling Studio. With strong performance from the 2.4 litre engine, and excellent ride and handling from the four-wheel independent suspension, the car was good to drive, In the United States, Datsun priced the 240Z within $200 of the MGB-GT, and dealers soon had long waiting lists for the “Z”. Its modern design, relatively low price, and growing dealer network compared to other imported sports cars of the time (Jaguar, BMW, Porsche, etc.), made it a major success for the Nissan Motor Corporation, which at the time sold cars in North America under the name Datsun. As a “halo” car, the 240Z broadened the image of Japanese car-makers beyond their econobox success. The car was updated to the 260Z in 1975, when a larger 2.6 litre engine was used. Both 240Z and 260Z cars were here.

It is quite surprising to realise that the Figaro is now more than 25 years old. This well-known retro-styled fixed-profile convertible was manufactured for just one year, 1991, and originally marketed solely in Japan at their Nissan Cherry Stores. The Figaro was introduced at the 1989 Tokyo Motor Show under the slogan “Back to the Future”. The name references the title character in the play The Marriage of Figaro by Pierre Beaumarchais. Based on the Nissan Micra, the Figaro was built at Aichi Machine Industry, a special projects group which Nissan would later call “Pike Factory,” which also produced three other niche automobiles: the Be-1, Pao and S-Cargo. As a fixed-profile convertible, the upper side elements of the Figaro’s bodywork remain fixed, while its fabric soft top retracts to provide a less fully open experience than a typical convertible. The fixed-profile concept is seen on other convertibles, including the Citroën 2CV and the 1957 Fiat 500. The Figaro was marketed in four colours representing the four seasons: Topaz Mist (Autumn), Emerald Green (Spring), Pale Aqua (Summer) and Lapis Grey (Winter). Few, reportedly 2,000, were marketed in Topaz Mist. The Figaro was equipped with leather seats, air conditioning, CD player and a fixed-profile slide-back open roof. 8000 were originally available with an additional 12,000 added to production numbers to meet demand. Prospective purchasers entered a lottery to purchase a Figaro. Limited edition cars came with passenger side baskets and cup holders. A surprising number of them have been imported to the UK in recent years.

PANTHER

Styled to evoke the Jaguar SS100 and sold from 1972 through 1981, it used mechanicals from the Jaguar XJ, including its 5.3 L V12 engine. It was also offered with Jaguar’s 3.8 L and 4.2 L XK engines. The J.72 was a success for the small company, with its Connolly coachwork beating Rolls-Royce at the 1973 London Motor Show. The car was purchased by a number of celebrities. A total of 368 were produced.

To try to boost sales, they came up with a smaller and cheaper product, the Lima, which was first seen at the 1976 London Motor Show. It used Vauxhall Viva and Magnum mechanicals, including that car’s 2279 cc four cylinder engine. A later Mark II model used a purpose-built chassis, and this is one of those cars. The body was built of fibreglass in a roadster style reminiscent of an Allard or Morgan. The Lima was produced in volume, with over 500 built by the time of the introduction of the Lima Turbo in February 1979. The Turbo Lima was fitted with 14-inch alloy wheels, and had a TURBO graphic on the bonnet. The turbocharged version, with an engine developed in Southern California, had 178 hp rather than the 108 hp of the original and claimed a 0-100 km/h acceleration time of less than six seconds. Lima production lasted until 1982 with 897 cars produced. It was replaced by the similar Panther Kallista for the 1980s.

The Panther Kallista replaced the Panther Lima as Panther’s volume model for the 1980s. Unlike the Vauxhall-based Lima, the Kallista used Ford mechanicals, including a range of engines from 1.6 L straight-4 to 2.9 L Cologne V6. Like its predecessor, it featured styling resembling earlier Allard and Morgan cars. The later SsangYong-built models of the 1990s used a 2.0 L engine. The Kallista used an aluminium body over a purpose-built steel chassis. Performance was good, with a sprint to 60 mph (96.6 km/h) taking under 8 seconds. The Kallista was produced from 1982 through 1990 until SsangYong Motor Company released a badge engineered version in 1992 called the SsangYong Kallista. Only 78 of the SsangYong models were ever built.

The Solo 2 used the Ford Sierra RS 1,993 cc engine with twice the horsepower of the Solo 1. It was mated to the Borg-Warner T-5 (same as in the RS), which drove a Ferguson four-wheel drive system modified by Panther to use XR4x4 components, including both differentials. The company decided also to stretch the wheelbase to accommodate 2+2 seating, which was partly done by ex-Ford Europe engineers who had worked on the Sierra Cosworth and XR4x4. March did the aerodynamics, producing a Cd of 0.33, as well as producing the composite construction, encouraged by March chairman Robin Herd. One of the development cars had a twin turbo setup due to the known turbo lag issues. A troublesome area was with the 4 wheel drive transfer box. This was a custom made part, the internals were chain-driven and the chains had a propensity for self-destruction under heavy engine load. The lower body of the Solo 2 was a space frame made primarily of steel with the upper body being made from aluminium honeycomb sandwiched between multiple sheets of impregnated glass fibre bonded with epoxy. The upper body was to be glued using an aerospace adhesive to the lower chassis. No rollbar was needed. Suspension used Escort struts in front, while the disc brakes were fitted with Scorpio-derived ABS. It is not known exactly how many vehicles were built (believed to have been between 12 and 25), as sometimes Panther would change the chassis number of prototype cars. All but three Solos were sold to the public, two were destroyed and one is still owned by the owner of Panther.

PIPER

Piper Cars was a United Kingdom manufacturer of specialist sports cars (an associate company of a camshaft and engine tuning parts manufacturer of the same name). The company was initially based in Hayes, then in Kent, with production taking place from 1968 at Wokingham, Berkshire and from 1973 at South Willingham, Lincolnshire. The first Piper GT road model to a design by Tony Hilder, was introduced at the January 1967 Racing Car Show and immediately afterwards entered production as a body/chassis unit for home completion. The front engine rear drive tubular steel chassis using Triumph Herald front suspension and Ford rear axle components could accommodate a variety of engines. Problems with the first few produced caused further production to be delayed until the following year when a substantially better developed version was introduced and became known as the GTT. At the same time, a mid-engined Group 6 racing car, the GTR, was being developed but only a handful were produced before this was abandoned following the death of company owner Brian Sherwood in late 1969. The GTR was only 30 inches high, and had a drag co-efficient of only 0.28.[1] Designer Hilder achieved this by moving all the mechanical parts, such as the water and oil radiators to the rear of the car. The car was entered for the 1969 Le Mans 24 Hours Race, but overheating problems and the failure of driver John Burton to record a qualifying time meant that the car did not start the race. Two employees, Bill Atkinson and Tony Waller, took over the company renaming it Embrook Engineering, ceased all racing activity and focused on improving the road cars. In 1971 this led to a further revision known as the Piper P2 with many improvements to chassis, body and interior design. This model continued in production until the mid-1970s. Estimates of total Piper production vary from around 80 (Piper Sports and Racing Car Club) to somewhere over 100.

PONTIAC

Sole Pontiac here was a 1978 Firebird Trans Am. The first significant change to the styling of the second generation Firebird came for 1974 when a slant nose with mandatory 5 mph impact absorbing bumpers was adopted. These added significant weight to the car, blunting its performance, but this was happening to everything on the market at the time. Detailed changes followed again in 1975 and 1976 and then in 1977, a distinctive, slant-nose facelift occurred, with the Firebird now using four square headlamps, while the Camaro continued to retain the two round headlights that had been shared by both Second Generation designs. Pontiac offered the Trans Am 6.6 litre 400 (RPO W72) rated at 200 hp), as opposed to the regular 6.6 litre 400 (RPO L78) rated at 180 hp. The Trans am 6.6 equipped engines had chrome valve covers, while the base 400 engines had painted valve covers. In addition, California and high-altitude cars received the Olds 403 engine, which offered a slightly higher compression ratio and a more usable torque band than the Pontiac engines of 1977. The 1977 Trans-Am Special Edition became famous after being featured in Smokey and the Bandit. Changes for 1978 were slight, with a switch from a honeycomb to a crosshatch pattern grille being the most obvious from the outside. Beginning in 1978, the Pontiac group introduced a new special edition vehicle. The Firebird Formula LT Sport Edition which featured a revised 10% raised compression Chevy 305 V8 powertrain producing 155 hp (same as 1977 Chevy Monza Mirage) combined with a floor centre console 4 speed Manual T-10 BW Transmission coupled to a limited-slip differential final drive. The Limited Touring package (LT) also included a cabin roof, door, fender and hood graphics scheme, the Trans-Am sports handling package with HD gas shocks, Modular Alloy Wheels and the SE Trans-Am rear deck Spoiler with “Formula” word graphic detail. The engineers also revised the compression ratio in the 400ci through the installation of different cylinder heads with smaller combustion chambers This increased power by 10% for a total of 220 during the 1978–79 model years. The 400/403 options remained available until 1979, when the 400 CID engines were only available in the 4-speed transmission Trans Ams and Formulas (the engines had actually been stockpiled from 1978, when PMD had cut production of the engine).

PORSCHE

As in previous years, there was a huge Porsche presence here. Unless you are a true aficionado of the marque, you would probably say that it was too big, as vast areas were given over to row upon row of Porsche model, a lot of them recent 911 models. There were some more unusual cars here as well, and in taking photos of a representative sample of what was nearly 2000 Porsche cars parked up, it was these on which I concentrated.

The 356 was created by Ferdinand “Ferry” Porsche (son of Dr. Ing. Ferdinand Porsche, founder of the German company), who founded the Austrian company with his sister, Louise. Like its cousin, the Volkswagen Beetle (which Ferdinand Porsche Senior had designed), the 356 was a four-cylinder, air-cooled, rear-engine, rear-wheel-drive car utilising unitised pan and body construction. The chassis was a completely new design as was the 356’s body which was designed by Porsche employee Erwin Komenda, while certain mechanical components including the engine case and some suspension components were based on and initially sourced from Volkswagen. Ferry Porsche described the thinking behind the development of the 356 in an interview with the editor of Panorama, the PCA magazine, in September 1972. “….I had always driven very speedy cars. I had an Alfa Romeo, also a BMW and others. ….By the end of the war I had a Volkswagen Cabriolet with a supercharged engine and that was the basic idea. I saw that if you had enough power in a small car it is nicer to drive than if you have a big car which is also overpowered. And it is more fun. On this basic idea we started the first Porsche prototype. To make the car lighter, to have an engine with more horsepower…that was the first two seater that we built in Carinthia (Gmünd)”. The first 356 was road certified in Austria on June 8, 1948, and was entered in a race in Innsbruck where it won its class. Porsche re-engineered and refined the car with a focus on performance. Fewer and fewer parts were shared between Volkswagen and Porsche as the ’50’s progressed. The early 356 automobile bodies produced at Gmünd were handcrafted in aluminium, but when production moved to Zuffenhausen, Germany in 1950, models produced there were steel-bodied. Looking back, the aluminium bodied cars from that very small company are what we now would refer to as prototypes. Porsche contracted with Reutter to build the steel bodies and eventually bought the Reutter company in 1963. The Reutter company retained the seat manufacturing part of the business and changed its name to Recaro. Little noticed at its inception, mostly by a small number of auto racing enthusiasts, the first 356s sold primarily in Austria and Germany. It took Porsche two years, starting with the first prototype in 1948, to manufacture the first 50 automobiles. By the early 1950s the 356 had gained some renown among enthusiasts on both sides of the Atlantic for its aerodynamics, handling, and excellent build quality. The class win at Le Mans in 1951 was clearly a factor. It was always common for owners to race the car as well as drive them on the streets. They introduced the four-cam racing “Carrera” engine, a totally new design and unique to Porsche sports cars, in late 1954. Increasing success with its racing and road cars brought Porsche orders for over 10,000 units in 1964, and by the time 356 production ended in 1965 approximately 76,000 had been produced. The 356 was built in four distinct series, the original (“pre-A”), followed by the 356 A, 356 B, and then finally the 356 C. To distinguish among the major revisions of the model, 356’s are generally classified into a few major groups. 356 coupés and “cabriolets” (soft-top) built through 1955 are readily identifiable by their split (1948 to 1952) or bent (centre-creased, 1953 to 1955) windscreens. In late 1955 the 356 A appeared, with a curved windshield. The A was the first road going Porsche to offer the Carrera 4 cam engine as an option. In late 1959 the T5 356 B appeared; followed by the redesigned T6 series 356 B in 1962. The final version was the 356 C, little changed from the late T6 B cars but with disc brakes to replace the drums.

The 911 traces its roots to sketches drawn by Ferdinand “Butzi” Porsche in 1959. The Porsche 911 was developed as a more powerful, larger and a more comfortable replacement for the 356, the company’s first model. The new car made its public debut at the 1963 Frankfurt Motor Show. The car was developed with the proof-of-concept twin-fan Type 745 flat-six engine, but the car presented at the auto show had a non-operational mockup of the single-fan 901 engine, receiving a working unit in February 1964. It originally was designated as the “Porsche 901” (901 being its internal project number). A total of 82 cars were built as which were badges as 901s.[7] However, French automobile manufacturer Peugeot protested on the grounds that in France it had exclusive rights to car names formed by three numbers with a zero in the middle. Instead of selling the new model with a different name in France, Porsche changed the name to 911. Internally, the cars’ part numbers carried on the prefix 901 for years. Production began in September 1964,[9] with the first 911s exported to the US in February 1965. The first models of the 911 had a rear-mounted 130 hp Type 901/01 flat-6 engine, in the “boxer” configuration like the 356, the engine is air-cooled and displaces 1,991 cc as compared to the 356’s four-cylinder, 1,582 cc unit. The car had four seats although the rear seats were small, thus it is usually called a 2+2 rather than a four-seater (the 356 was also a 2+2). A four or five-speed “Type 901” manual transmission was available. The styling was largely penned by Ferdinand “Butzi” Porsche, son of Ferdinand “Ferry” Porsche. Butzi Porsche initially came up with a notchback design with proper space for seating two rear passengers but Ferry Porsche insisted that the 356’s successor was to use its fastback styling. 7 prototypes were built based on Butzi Porsche’s original design and were internally called the Porsche 754 T7. Erwin Komenda, the leader of the Porsche car body construction department who initially objected, was also involved later in the design. In 1966, Porsche introduced the more powerful 911S with Type 901/02 engine having a power output of 160 PS. Forged aluminum alloy wheels from Fuchsfelge, with a 5-spoke design, were offered for the first time. In motorsport at the same time, the engine was developed into the Type 901/20 and was installed in the mid-engine 904 and 906 with an increased power output of 210 PS, as well as fuel injected Type 901/21 installed in later variants of the 906 and 910 with a power output of 220 PS. In August 1967, the A series went into production with dual brake circuits and widened (5.5J-15) wheels still fitted with Pirelli Cinturato 165HR15 CA67 tyres. and the previously standard gasoline-burning heater became optional. The Targa version was introduced. The Targa had a stainless steel-clad roll bar, as automakers believed that proposed rollover safety requirements by the US National Highway Traffic Safety Administration (NHTSA) would make it difficult for fully open convertibles to meet regulations for sale in the US, an important market for the 911. The name “Targa” came from the Targa Florio sports car road race in Sicily, Italy in which Porsche had several victories until 1973. The last win in the subsequently discontinued event was scored with a 911 Carrera RS against prototypes entered by Ferrari and Alfa Romeo. The road going Targa was equipped with a removable roof panel and a removable plastic rear window (although a fixed glass version was offered from 1968). The 110 PS 911T was also launched in 1967 with Type 901/03 engine. The 130 PS model was renamed the 911L with Type 901/06 engine and ventilated front disc brakes. The brakes had been introduced on the previous 911S. The 911R with 901/22 engine had a limited production (20 in all), as this was a lightweight racing version with thin fibreglass reinforced plastic doors, a magnesium crankcase, twin overhead camshafts, and a power output of 210 PS. A clutchless semi-automatic Sportomatic model, composed of a torque converter, an automatic clutch, and the four-speed transmission was added in Autumn 1967. It was cancelled after the 1980 model year partly because of the elimination of a forward gear to make it a three-speed. The B series went into production in August 1968, replacing the 911L model with 911E with fuel injection. It remained in production until July 1969. The 911E gained 185/70VR15 Pirelli Cinturato CN36.[16] and 6J-15 wheels. The C series was introduced in August 1969 with an enlarged 2.2-litre engine. The wheelbase for all 911 and 912 models was increased from 2,211–2,268 mm (87.0–89.3 in), to help as a remedy to the car’s nervous handling at the limit. The overall length of the car did not change, but the rear wheels were relocated further back. Fuel injection arrived for the 911S (901/10 engine) and for a new middle model, 911E (901/09 engine). The D series was produced from Aug. 1970 to July 1971. The 2.2-litre 911E (C and D series) had lower power output of the 911/01 engine (155 PS) compared to the 911S’s Type 911/02 (180 PS, but 911E was quicker in acceleration up to 160 km/h. The E series for 1972–1973 model years (August 1971 to July 1972 production) consisted of the same models, but with a new, larger 2,341 cc engine. This is known as the “2.4 L” engine, despite its displacement being closer to 2.3 litres. The 911E (Type 911/52 engine) and 911S (Type 911/53) used Bosch mechanical fuel injection (MFI) in all markets. For 1972 the 911T (Type 911/57) was carbureted, except in the US and some Asian markets where the 911T also came with (MFI) mechanical fuel injection (Type 911/51 engine) with power increase over European models (130 hp) to 140 hp commonly known as a 911T/E. With power and torque increase, the 2.4-litre cars also got a newer, stronger transmission, identified by its Porsche type number 915. Derived from the transmission in the 908 race car, the 915 did away with the 901 transmission’s “dog-leg” style first gear arrangement, opting for a traditional H pattern with first gear up to the left, second gear underneath first, etc. The E series had the unusual oil filler behind the right side door, with the dry sump oil tank relocated from behind the right rear wheel to the front of it in an attempt to move the center of gravity slightly forward for better handling. An extra oil filler/inspection flap was located on the rear wing, for this reason it became known as an “Oil Klapper”, “Ölklappe” or “Vierte Tür (4th door)”. The F series (August 1972 to July 1973 production) moved the oil tank back to the original behind-the-wheel location. This change was in response to complaints that gas-station attendants often filled gasoline into the oil tank. In January 1973, US 911Ts were switched to the new K-Jetronic CIS (Continuous Fuel Injection) system from Bosch on Type 911/91 engine. 911S models also gained a small spoiler under the front bumper to improve high-speed stability. The cars weighed 1,050 kg (2,310 lb). The 911 ST was produced in small numbers for racing (the production run for the ST lasted from 1970 to 1971). The cars were available with engines of either 1,987 cc or 2,404 cc, having a power output of 270 PS at 8,000 rpm. Weight was down to 960 kg (2,120 lb). The cars had success at the Daytona 6 Hours, the Sebring 12 Hours, the 1000 km Nürburgring, and the Targa Florio. The G Series cars, with revised bodies and larger impact-absorbing bumpers arrived in the autumn of 1973 and would continue in production with few visual changes but plenty of mechanical ones for a further 16 years.

The car continued to evolve throughout the 1960s and early 1970s, though changes initially were quite small. The SC appeared in the autumn of 1977, proving that any earlier plans there had been to replace the car with the front engined 924 and 928 had been shelved. The SC followed on from the Carrera 3.0 of 1967 and 1977. It had the same 3 litre engine, with a lower compression ratio and detuned to provide 180 PS . The “SC” designation was reintroduced by Porsche for the first time since the 356 SC. No Carrera versions were produced though the 930 Turbo remained at the top of the range. Porsche’s engineers felt that the weight of the extra luxury, safety and emissions equipment on these cars was blunting performance compared to the earlier, lighter cars with the same power output, so in non-US cars, power was increased to 188 PS for 1980, then finally to 204 PS. However, cars sold in the US market retained their lower-compression 180 PS engines throughout. This enabled them to be run on lower-octane fuel. In model year 1980, Porsche offered a Weissach special edition version of the 911 SC, named after the town in Germany where Porsche has their research centre. Designated M439, it was offered in two colours with the turbo whale tail & front chin spoiler, body colour-matched Fuchs alloy wheels and other convenience features as standard. 408 cars were built for North America. In 1982, a Ferry Porsche Edition was made and a total of 200 cars were sold with this cosmetic package. SCs sold in the UK could be specified with the Sport Group Package (UK) which added stiffer suspension, the rear spoiler, front rubber lip and black Fuchs wheels. In 1981 a Cabriolet concept car was shown at the Frankfurt Motor Show. Not only was the car a true convertible, but it also featured four-wheel drive, although this was dropped in the production version. The first 911 Cabriolet debuted in late 1982, as a 1983 model. This was Porsche’s first cabriolet since the 356 of the mid-1960s. It proved very popular with 4,214 sold in its introductory year, despite its premium price relative to the open-top targa. Cabriolet versions of the 911 have been offered ever since. 911 SC sales totalled 58,914 cars before the next iteration, the 3.2 Carrera, which was introduced for the 1984 model year. Coupe models outsold the Targa topped cars by a big margin.

It was only really with the launch in 1989 of the 964 that a truly “new” model would appear. Designed by Benjamin Dimson in 1986, it featured significant styling revisions over previous 911 models, most prominently the more integrated bumpers. The 964 was considered to be 85% new as compared to its predecessor. The first 964s available in 1989 were all wheel drive equipped “Carrera 4” models; Porsche added the rear wheel drive Carrera 2 variant to the range in 1990. Both variants were available as a coupe, Targa or Cabriolet. The 964 Carrera was the last generation sold with the traditional removable Targa roof until the 2011 991. A new naturally aspirated engine called the M64 was used for 964 models, with a flat-6 displacement of 3.6 litres. Porsche substantially revised the suspension, replacing torsion bars with coil springs and shock absorbers. Power steering and ABS brakes were added to the 911 for the first time; both were standard. The exterior bumpers and fog lamps became flush with the car for better aerodynamics. A new electric rear spoiler raised at speeds above 50 mph and lowered down flush with the rear engine lid at lower speeds. A revised interior featured standard dual airbags beginning in 1990 for all North American production cars. A new automatic climate control system provided improved heating and cooling. Revised instrumentation housed a large set of warning lights that were tied into the car’s central warning system, alerting the driver to a possible problem or malfunction. In 1992, Porsche produced a super-lightweight, rear-wheel-drive only version of the 964 dubbed Carrera RS for the European market. It was based on Porsche’s 911 “Carrera Cup” race car and harked back to the 2.7 and 3.0 RS and RSR models. It featured a revised version of the standard engine, titled M64/03 internally, with an increased power output of 260 bhp and lightweight flywheel coupled to the G50/10 transmission with closer ratios, asymmetrical Limited Slip Differential and steel synchromesh. A track-oriented suspension system with 40 mm (1.6 in) lower ride height, stiffer springs, shocks and adjustable stabiliser bars without power steering (RHD UK cars did have power steering). A stripped-out interior devoid of power windows or seats, rear seats, air conditioning, cruise control, sound deadening or a stereo system (optionally fitted) and new racing-bucket front seats were part of the package. The front boot cover was made of aluminium and the chassis was seam welded. Wheels were made of magnesium and the glass was thinner in the doors and rear window. The Carrera RS is approximately 345 pounds (155 kg) lighter than the Carrera 2 model. Also available were a heavier Touring variant (with sound deadening, power seats (optional), undercarriage protection and power windows) and an N/GT racing variant with a stripped, blank metal interior and a roll cage. They also came with optional lights on the visors. The RS was regarded as somewhat challenging to drive, though as time has gone by, everyone seems to have warmed to it. Many were finished in some very bold colours, like this one was.

During the 1990s, Porsche was facing financial troubles and rumours of a proposed takeover were being spread. The signature air-cooled flat-6 of the 911 was reaching the limits of its potential as made evident by the 993. Stricter emissions regulations world wide further forced Porsche to think of a replacement of the air-cooled unit. In order to improve manufacturing processes, Porsche took the aid of leading Japanese car manufacturer Toyota whose consultants would assist in the overhaul of the Zuffenhausen manufacturing facility introducing mass production techniques which would allow Porsche to carry out production processes more efficiently. Porsche had realised that in order to keep the 911 in production, it would need radical changes. This led to the development of the 996. The sharing of development between the new 911 and the entry level Boxster model allowed Porsche to save development costs. This move also resulted in interchangeable parts between the two models bringing down maintenance costs. The Porsche 996 was a new design developed by Pinky Lai under Porsche design chief Harm Lagaay from 1992 to 1994; it was the first 911 that was completely redesigned, and carried over little from its predecessor as Porsche wanted the design team to design a 911 for the next millennium. Featuring an all new body work, interior, and the first water-cooled engine, the 996 replaced the 993 from which only the front suspension, rear multi-link suspension, and a 6-speed manual transmission were retained in revised form. The 996 had a drag coefficient of Cd=0.30 resulting from hours spent in the wind tunnel. The 996 is 185 mm (7 in) longer and 40 mm (2 in) wider than its predecessor. It is also 45% stiffer courtesy of a chassis formed from high-strength steel. Additionally, it is 50 kg (110 lb) lighter despite having additional radiators and coolant. All of the M96 engines offered in the 996 (except for the variants fitted to the Turbo and GT2/GT3 models) are susceptible to the Porsche Intermediate Shaft Bearing issue which can potentially cause serious engine failure if not addressed via a retrofit. The 996 was initially available in a coupé or a cabriolet (Convertible) bodystyle with rear-wheel drive, and later with four-wheel drive, utilising a 3.4 litre flat-6 engine generating a maximum power output of 296 bhp. The 996 had the same front end as the entry-level Boxster. After requests from the Carrera owners about their premium cars looking like a “lower priced car that looked just like theirs did”, Porsche redesigned the headlamps of the Carrera in 2002 similar to the high performance Turbo’s headlamps. The design for the initial “fried egg” shaped headlamps could be traced back to the 1997 911 GT1 race car. In 2000, Porsche introduced the 996 Turbo, equipped with a four-wheel-drive system and a 3.6-litre, twin-turbocharged and intercooled flat-six engine generating a maximum power output of 420 bhp, making the car capable of accelerating from 0–60 mph in 4.2 seconds. An X50 option which included larger turbochargers and intercoolers along with revised engine control software became available from the factory in 2002, increasing power output to 451 bhp. In 2005, Porsche introduced the Turbo S, which had the X50 option included as standard equipment, with the formerly optional Carbon fibre-reinforced Silicon Carbide (C/SiC) composite ceramic brakes (PCCB) also included as standard. In 2000, power output on the base Carrera model was increased to 300 bhp. 2001 marked the final year of production for the base Carrera 4 Coupé in narrow body format. In 2002, the standard Carrera models underwent the above-mentioned facelift. In addition, engine capacity was also increased to 3.6-litres across the range, yielding gains of 15 bhp for the naturally aspirated models. 2002 also marked the start of the production of the 996 based Targa model, with a sliding glass “green house” roof system as introduced on its predecessor. It also features a rear glass hatch which gave the driver access to the storage compartment. Also in 2002, the Carrera 4S model was first introduced. The C4S, as it is called among the enthusiasts, shares the wide-body look of the Turbo as well as the brakes and suspension.

There were plenty of examples of the 996, 997 and 991 cars here, too.

The 997 GT3 RS was first announced in early 2006 as a homologation version of the GT3 RSR racing car for competition events like Sebring and the 24 Hours of Le Mans. The drivetrain of the RS is based on the 911 GT3, except for the addition of a lightweight flywheel and closer gear ratios for further improved response under acceleration. Unlike the GT3, the RS is built on the body and chassis of the 911 Carrera 4 and Turbo, and accordingly has a wider rear track for better cornering characteristics on the track. Visually, the RS is distinguished by its distinctive colour scheme – bright orange or green with black accents, which traces its roots to the iconic Carrera RS of 1973. The plastic rear deck lid is topped by a wide carbon-fibre rear wing. The front airdam has been fitted with an aero splitter to improve front downforce and provide more cooling air through the radiator. The European version of the RS is fitted with lightweight plexiglass rear windows and a factory-installed roll cage. Production of the first generation 997 GT3 RS ended in 2009, with worldwide production estimated to be under 2,000 vehicles. In August 2009, Porsche announced the second generation of the 997 GT3 RS with an enlarged 3.8-litre engine having a power output of 450 PS (444 hp), a modified suspension, dynamic engine mounts, new titanium sport exhaust, and modified lightweight bodywork. In April 2011, Porsche announced the third generation of the 997 GT3 RS with an enlarged 4.0-litre engine having a power output of 500 PS (493 hp), Porsche designed the GT3 RS 4.0 using lightweight components such as bucket seats, carbon-fibre bonnet and front wings, and poly carbonate plastic rear windows for weight reduction, while using suspension components from the racing version. Other characteristics include low centre of gravity, a large rear wing and an aerodynamically optimised body. The lateral front air deflection vanes, a first on a production Porsche, increase downforce on the front axle. Aided by a steeply inclined rear wing, aerodynamic forces exert an additional 190 kg, enhancing the 911 GT3 RS 4.0’s grip to the tarmac. The GT3 RS 4.0 weighs 1,360 kg.

The RS version of the 991 GT3 was launched at the 2015 Geneva Motor Show, and featured in first drive articles in the press a few weeks later, with cars reaching the UK in the summer and another series of universally positive articles duly appearing. It had very big shoes to fill, as the 997 GT3 RS model was rated by everyone lucky enough to get behind the wheel, where the combination of extra power and reduced weight made it even better to drive than the standard non-RS version of the car. A slightly different approach was taken here, with the result weighing just 10kg less than the GT3. It is based on the extra wide body of the 991 Turbo. Compared to the 991 GT3, the front wings are now equipped with louvres above the wheels and the rear wings now include Turbo-like intakes, rather than an intake below the rear wing. The roof is made from magnesium a bonnet, whilst the front wings, rear deck and rear spoiler all in carbonfibre-reinforced plastic (CFRP), the rear apron is in a new polyurethane-carbonfibre polymer and polycarbonate glazing is used for the side and rear windows. The wider body allows the RS’s axle tracks to grow, to the point where the rear track is some 72mm wider than that of a standard 3.4-litre Carrera and the tyres are the widest yet to be fitted to a road-going 911. A long-throw crankshaft made of extra-pure tempered steel delivers the 4mm of added piston stroke necessary to take the GT3’s 3.8-litre flat six out to 3996cc . The engine also uses a new induction system, breathing through the lateral air intakes of the Turbo’s body rather than through the rear deck cover like every other 911. This gives more ram-air effect for the engine and makes more power available at high speeds. It results in an output of 500 bhp and 339 lb/ft of torque. A titanium exhaust also saves weight. The suspension has been updated and retuned, with more rigid ball-jointed mountings and helper springs fitted at the rear, while Porsche’s optional carbon-ceramic brakes get a new outer friction layer. Which is to say nothing of the RS’s biggest advancement over any other 911: downforce. The rear wing makes up to 220kg of it, while the front spoiler and body profile generates up to 110kg. In both respects, that’s double the downforce of the old 997 GT3 RS 4.0. The transmission is PDK only. The result is a 0-62 mph time of just 3.3 seconds, some 0.6 seconds quicker than the 997 GT3 RS 4.0 and 0-124 mph (0-200kmh) in 10.9 seconds. The 991 GT3 RS also comes with functions such as declutching by “paddle neutral” — comparable to pressing the clutch with a conventional manual gearbox –- and Pit Speed limiter button. As with the 991 GT3, there is rear-axle steering and Porsche Torque Vectoring Plus with fully variable rear axle differential lock. The Nürburgring Nordschleife time is 7 minutes and 20 seconds. The interior includes full bucket seats (based on the carbon seats of the 918 Spyder), carbon-fibre inserts, lightweight door handles and the Club Sport Package as standard (a bolted-on roll cage behind the front seats, preparation for a battery master switch, and a six-point safety harness for the driver and fire extinguisher with mounting bracket). Needless to say, the car was an instant sell out, even at a starting price of £131,296.

I spotted one of the special 991 50th Anniversary Edition cars. Like the original 911, the 911 50th Anniversary Edition is a coupé with a flat-six rear engine and rear wheel drive. Its efficient performance, active sport suspension – and special body have current relevancy: the anniversary 911 features the wide body, which is typically reserved for the all-wheel drive Carrera 4 models. This special edition was limited to 1963 cars, a number that represents the year of the 911 world premiere. It was presented at the 2013 edition of the IAA motor show in Frankfurt, which was fitting as in 1963, Porsche presented the original model to the public at this leading international show for the automotive industry. Since its first presentation – initially as the type 901 – the sports car icon has excited automotive fans across the globe, and today it is considered the reference for all other sports cars. Since making its debut in 1963, the model series has progressively developed without interruption. In the process, the unique character of the 911 was always preserved. The result of this evolution over a 50-year period – which included countless race victories as well – is a sports car that fully embodies the authenticity of the Porsche brand. Its DNA is reflected in all Porsche models. This limited edition of the 400 hp 911 Carrera S includes features that have contributed to the 50-year success story of the 911. For example, the limited edition includes Porsche Active Suspension Management (PASM) with special tuning to complement its increased track width and to add support to the exceptional cornering dynamics of the 911. The sport exhaust system outputs a fitting emotional sound. Special 20-inch wheels are a visual tribute to the legendary “Fuchs” wheels and are finished in matte black paint with machine polished centres. Chrome trim strips on the front air inlets, the fins of the engine compartment grille and the panel between the rear lights emphasise the distinctive appearance of this limited edition model. Another technical highlight of the car’s equipment is the Porsche Dynamic Light System (PDLS) with bi-xenon headlights and dynamic cornering lights. Two unique colours are available for the anniversary 911, a darker graphite grey and a lighter geyser grey metallic. In addition black monochrome is also available. Each of the cars has a two-tone 3D-effect badge on the rear lid with the numbers “911 50”. This is repeated in three colour embroidery on the headrest and in two colours as a logo on the tachometer and the aluminium door sill plates. It can also be found on the cup holder panel – together with the limited edition number of the individual vehicle. Other exterior characteristics of the special model are high-gloss window frames and sport design exterior mirrors on the doors panels. There are tributes to the original 911 in the interior as well: green labelling on the instruments with white pointer needles and silver caps on the instrument pivot pins, just like 50 years ago. Another special feature is the centre panels of the leather seats, which are designed with a fabric pattern reminiscent of the “Pepita” tartan design from the 1960s. The full-leather interior is designed in agate grey or black with decorative stitching, some in contrasting colour. The driver and front passenger experience typical 911 driving fun in 14-way sport seats or optional 18 way sport seats plus. The gear shift or selector lever – which matches the decorative panels on the dashboard, doors and centre console in brushed aluminium – comes from the Porsche Exclusive program.

Also here was the 914, a model born of a joint need that Porsche had for a replacement for the 912, and Volkswagen’s desire for a new range-topping sports coupe to replace the Karmann Ghia. At the time, the majority of Volkswagen’s developmental work was handled by Porsche, part of a setup that dated back to Porsche’s founding; Volkswagen needed to contract out one last project to Porsche to fulfill the contract, and decided to make this that project. Ferdinand Piëch, who was in charge of research and development at Porsche, was put in charge of the 914 project. Originally intending to sell the vehicle with a flat four-cylinder engine as a Volkswagen and with a flat six-cylinder engine as a Porsche, Porsche decided during development that having Volkswagen and Porsche models sharing the same body would be risky for business in the American market, and convinced Volkswagen to allow them to sell both versions as Porsches in North America. On March 1, 1968, the first 914 prototype was presented. However, development became complicated after the death of Volkswagen’s chairman, Heinz Nordhoff, on April 12, 1968. His successor, Kurt Lotz, was not connected with the Porsche dynasty and the verbal agreement between Volkswagen and Porsche fell apart. In Lotz’s opinion, Volkswagen had all rights to the model, and no incentive to share it with Porsche if they would not share in tooling expenses. With this decision, the price and marketing concept for the 914 had failed before series production had begun. As a result, the price of the chassis went up considerably, and the 914/6 ended up costing only a bit less than the 911T, Porsche’s next lowest price car. The 914/6 sold quite poorly while the much less expensive 914/4 became Porsche’s top seller during its model run, outselling the Porsche 911 by a wide margin with over 118,000 units sold worldwide. Volkswagen versions originally featured an 80 PS fuel-injected 1.7 L flat-4 engine based on the Volkswagen air-cooled engine. Porsche’s 914/6 variant featured a carburettor 110 PS 2.0 litre flat-6 engine from the 1969 911T, placed amidships in front of a version of the 1969 911’s “901” gearbox configured for a mid-engine car. Karmann manufactured the rolling chassis at their plant, completing Volkswagen production in-house or delivering versions to Porsche for their final assembly. 914/6 models used lower gear ratios and high brake gearing in order to try to overcome the greater weight of the 6 cylinder engine along with higher power output. Suspension, brakes, and handling were otherwise the same. A Volkswagen-Porsche joint venture, Volkswagen of America, handled export to the U.S., where both versions were badged and sold as Porsches, except in California, where they were sold in Volkswagen dealerships. The four-cylinder cars were sold as Volkswagen-Porsches at European Volkswagen dealerships. Slow sales and rising costs prompted Porsche to discontinue the 914/6 variant in 1972 after producing 3,351 of them; its place in the lineup was filled by a variant powered by a new 100 PS 2.0 litre, fuel-injected version of Volkswagen’s Type 4 engine in 1973. For 1974, the 1.7 L engine was replaced by a 85 PS 1.8 litre, and the new Bosch L-Jetronic fuel injection system was added to American units to help with emissions control. 914 production ended in 1976. The 2.0 litre flat-4 engine continued to be used in the 912E, which provided an entry-level model until the 924 was introduced.

There were a number of the front engined cars here, too, starting with the 924, in standard and Turbo guises, as well as one of the rare Carrera GT cars. The 924 was originally another joint project of Volkswagen and Porsche created by the Vertriebsgesellschaft (VG), the joint sales and marketing company funded by Porsche and VW to market and sell sports cars, For Volkswagen, it was intended to be that company’s flagship coupé sports car and was dubbed “Project 425” during its development. For Porsche, it was to be its entry-level sports car replacing the 914. At the time, Volkswagen lacked a significant internal research and design division for developing sports cars; further, Porsche had been doing the bulk of the company’s development work anyway, per a deal that went back to the 1940s. In keeping with this history, Porsche was contracted to develop a new sporting vehicle with the caveat that this vehicle must work with an existing VW/Audi inline-four engine. Porsche chose a rear-wheel drive layout and a rear-mounted transaxle for the design to help provide 48/52 front/rear weight distribution; this slight rear weight bias aided both traction and brake balance. The 1973 oil crisis, a series of automobile-related regulatory changes enacted during the 1970s and a change of directors at Volkswagen made the case for a Volkswagen sports car less striking and the 425 project was put on hold. After serious deliberation at VW, the project was scrapped entirely after a decision was made to move forward with the cheaper, more practical, Golf-based Scirocco model instead. Porsche, which needed a model to replace the 914, made a deal with Volkswagen leadership to buy the design back. The deal specified that the car would be built at the ex-NSU factory in Neckarsulm located north of the Porsche headquarters in Stuttgart, Volkswagen becoming the subcontractor. Hence, Volkswagen employees would do the actual production line work (supervised by Porsche’s own production specialists) and that Porsche would own the design. It became one of Porsche’s best-selling models, and the relative cheapness of building the car made it both profitable and fairly easy for Porsche to finance. The original design used an Audi-sourced four-speed manual transmission from a front wheel drive car but now placed and used as a rear transaxle. It was mated to VW’s EA831 2.0 litre 4 cylinder engine, subsequently used in the Audi 100 and the Volkswagen LT van (common belief is that ‘the engine originated in the LT van’, but it first appeared in the Audi car and in 924 form has a Porsche-designed cylinder head). The 924 engine used Bosch K-Jetronic fuel injection, producing 125 bhp in European cars, but a rather paltry 95 bhp for the US market models, though this was improved to 110 hp in mid-1977 with the introduction of a catalytic converter, which reduced the need for power-robbing smog equipment. The four-speed manual was the only transmission available for the initial 1976 model, later this was replaced by a five-speed dog-leg unit. An Audi three-speed automatic was offered starting with the 1977.5 model. In 1980 the five-speed transmission was changed to a conventional H-pattern, with reverse now on the right beneath fifth gear. Porsche made small improvements to the 924 each model year between 1977 and 1985, but nothing major was changed on non-turbo cars. Porsche soon recognised the need for a higher-performance version of the 924 that could bridge the gap between the basic 924s and the 911s. Having already found the benefits of turbochargers on several race cars and the 1975 911 turbo, Porsche chose to use this technology for the 924, eventually introducing the 924 turbo as a 1978 model. Porsche started with the same Audi-sourced VW EA831 2.0 litre engine, designed an all new cylinder head (which was hand assembled at Stuttgart), dropped the compression to 7.5:1 and engineered a KKK K-26 turbocharger for it. With 10 psi boost, output increased to 170 hp. The 924 turbo’s engine assembly weighed about 65 lb more, so front spring rates and anti-roll bars were revised. Weight distribution was now 49/51 compared to the original 924 figure of 48/52 front to rear. In order to help make the car more functional, as well as to distinguish it from the naturally aspirated version, Porsche added an NACA duct in the bonnet and air intakes in the badge panel in the nose, 15-inch spoke-style alloy wheels, four-wheel disc brakes with five-stud hubs and a five-speed transmission. Forged 16-inch flat wheels of the style used on the 928 were optional, but fitment specification was that of the 911 which the 924 shared wheel offsets with. Internally, Porsche called it the “931” (left hand drive) and “932” (right hand drive). The turbocharged VW EA831 engine allowed the 924’s performance to come surprisingly close to that of the 911 SC (180 bhp), thanks in part to a lighter curb weight, but it also brought reliability problems.This was in part due to the fact that the general public did not know how to operate, or care for, what is by today’s standards a primitive turbo setup. A turbocharger cooled only by engine oil led to short component life and turbo-related seal and seat problems. To fix the problems, Porsche released a revised 924 turbo series 2 (although badging still read “924 turbo”) in 1979. By using a smaller turbocharger running at increased boost, slightly higher compression of 8:1 and an improved fuel injection system with DITC ignition triggered by the flywheel, reliability improved and power rose to 177 hp. In 1984, VW decided to stop manufacturing the engine blocks used in the 2.0 litre 924, leaving Porsche with a predicament. The 924 was considerably cheaper than its 944 stablemate, and dropping the model left Porsche without an affordable entry-level option. The decision was made to equip the narrower bodied 924 with a slightly detuned version of the 944’s 163 bhp 2.5 litre straight four, upgrading the suspension but retaining the 924’s early interior. The result was 1986’s 150 bhp 924S. In 1988, the 924S’ final year of production, power increased to 160 bhp matching that of the previous year’s Le Mans spec cars and the base model 944, itself detuned by 3 bhp. This was achieved using different pistons which raised the S’ compression ratio from 9.7:1 to 10.2:1, the knock-on effect being an increase in the octane rating, up from 91 RON to 95. This made the 924S slightly faster than the base 944 due to its lighter weight and more aerodynamic body. With unfavourable exchange rates in the late 1980s, Porsche decided to focus its efforts on its more upmarket models, dropping the 924S for 1989 and the base 944 later that same year.

There were also several examples of the car’s sort of successor, sort of stablemate, the 944. Whilst its precursor, the 924, had received largely positive reviews, it was criticised by many including Porsche enthusiasts for its Audi-sourced engine and although the Turbo model had increased performance, this model carried a high price, which caused Porsche to decide to develop the 924, as they had with generations of the 911. They re-worked the platform and a new all-alloy 2.5 litre inline-four engine, that was, in essence, half of the 928’s 5.0 litre V8, although very few parts were actually interchangeable. Not typical in luxury sports cars, the four-cylinder engine was chosen for fuel efficiency and size, because it had to be fitted from below on the Neckarsulm production line. To overcome roughness caused by the unbalanced secondary forces that are typical of four-cylinder engines, Porsche included two counter-rotating balance shafts running at twice engine speed. Invented in 1904 by British engineer Frederick Lanchester, and further developed and patented in 1975 by Mitsubishi Motors, balance shafts carry eccentric weights which produce inertial forces that balance out the unbalanced secondary forces, making a four-cylinder engine feel as smooth as a six-cylinder. The engine was factory-rated at 150 hp in its U.S. configuration. Revised bodywork with wider wheel arches, similar to that of the 924 Carrera GT, a fresh interior and upgrades to the braking and suspension systems rounded out the major changes and Porsche introduced the car as the 944 in 1982. It was slightly faster (despite having a poorer drag co-efficient than the 924), the 944 was better equipped and more refined than the 924; it had better handling and stopping power, and was more comfortable to drive. The factory-claimed 0-60 mph time of less than 9 seconds and a top speed of 130 mph which turned out to be somewhat pessimistic, In mid-1985, the 944 underwent its first significant changes. These included : a new dash and door panels, embedded radio antenna, upgraded alternator, increased oil sump capacity, new front and rear cast alloy control arms and semi-trailing arms, larger fuel tank, optional heated and powered seats, Porsche HiFi sound system, and revisions in the mounting of the transaxle to reduce noise and vibration. The “cookie cutter” style wheels used in the early 944s were upgraded to new “phone dial” style wheels (Fuchs wheels remained an option). 1985 model year cars incorporating these changes are sometimes referred to as “1985B”, “85.5” or “1985½” cars. For the 1987 model year, the 944 Motronic DME was updated, and newly incorporated anti-lock braking and air bags. Because of the ABS system, the wheel offset changed and Fuchs wheels were no longer an option. In early 1989 before the release of the 944S2, Porsche upgraded the 944 from the 2.5 to a 2.7 litre engine, with a rated 162 hp and a significant increase in torque. For the 1985 model year, Porsche introduced the 944 Turbo, known internally as the 951. This had a turbocharged and intercooled version of the standard car’s engine that produced 220 PS at 6000 rpm. In 1987, Car and Driver tested the 944 Turbo and achieved a 0-60 mph time of 5.9 seconds. The Turbo was the first car using a ceramic port liner to retain exhaust gas temperature and new forged pistons and was also the first vehicle to produce identical power output with or without a catalytic converter. The Turbo also featured several other changes, such as improved aerodynamics, notably an integrated front bumper. This featured the widest turn signals (indicators) fitted to any production car, a strengthened gearbox with a different final drive ratio, standard external oil coolers for both the engine and transmission, standard 16 inch wheels (optional forged Fuchs wheels), and a slightly stiffer suspension (progressive springs) to handle the extra weight. The Turbo’s front and rear brakes were borrowed from the Porsche 911, with Brembo 4-piston fixed calipers and 12-inch discs as ABS also came standard. Engine component revisions, more than thirty in all, were made to the 951 to compensate for increased internal loads and heat. Changes occurred for the 1987 model year. On the interior, the 1987 944 Turbo for North America became the first production car in the world to be equipped with driver and passenger side air bags as standard equipment. A low oil level light was added to the dash as well as a 180 mph (290 km/h) speedometer as opposed to the 170 mph speedometer on the 1986 model Turbos. Also included is the deletion of the transmission oil cooler, and a change in suspension control arms to reduce the car’s scrub radius. The engine remained the same M44/51 as in the 1986 model. In 1988, Porsche introduced the Turbo S. The 944 Turbo S had a more powerful engine (designation number M44/52) with 250 hp and 258 lb·ft torque (standard 944 Turbo 220 hp and 243 lb·ft. This higher output was achieved by using a larger K26-8 turbine housing and revised engine mapping which allowed maintaining maximum boost until 5800 rpm, compared to the standard 944 Turbo the boost would decrease from 1.75 bar at 3000 rpm to 1.52 bar at 5800 rpm. Top speed was factory rated at 162 mph. The 944 Turbo S’s suspension had the “M030” option consisting of Koni adjustable shocks front and rear, with ride height adjusting threaded collars on the front struts, progressive rate springs, larger hollow rear anti-roll/torsion bars, harder durometer suspension bushings, larger hollow anti-roll/torsion bars at the front, and chassis stiffening brackets in the front frame rails. The air conditioning dryer lines are routed so as to clear the front frame brace on the driver’s side. The 944 Turbo S wheels, known as the Club Sport design, were 16-inch Fuchs forged and flat-dished, similar to the Design 90 wheel. Wheel widths were 7 inches in the front, and 9 inches in the rear with 2.047 in offset; sizes of the Z-rated tyres were 225/50 in the front and 245/45 in the rear. The front and rear fender edges were rolled to accommodate the larger wheels. The manual transmission featured a higher friction clutch disc setup, an external cooler, and a limited slip differential with a 40% lockup setting. The Turbo S front brakes were borrowed from the Porsche 928 S4, with larger Brembo GT 4-piston fixed calipers and 12-inch discs; rear Brembo brakes remained the same as a standard Turbo. ABS also came standard. The 944 Turbo S interior featured power seats for both driver and passenger, where the majority of the factory-built Turbo S models sported a “Burgundy plaid” (Silver Rose edition) but other interior/exterior colours were available. A 10-speaker sound system and equalizer + amp was a common option with the Turbo S and S/SE prototypes. Only the earlier 1986, 250 bhp prototypes featured a “special wishes custom interior” options package. In 1989 and later production, the ‘S’ designation was dropped from the 944 Turbo S, and all 944 Turbos featured the Turbo S enhancements as standard, however the “M030” suspension and the Club Sport wheels were not part of that standard. The 944 Turbo S was the fastest production four cylinder car of its time. For the 1987 model year, the 944S “Super” was introduced, featuring a high performance normally aspirated, dual-overhead-cam 16-valve 190 PS version of the 2.5 litre engine (M44/40) featuring a self-adjusting timing belt tensioner. This marked the first use of four-valve-per-cylinder heads and DOHC in the 944 series, derived from the 928 S4 featuring a redesigned camshaft drive, a magnesium intake tract/passages, magnesium valve cover, larger capacity oil sump, and revised exhaust system. The alternator capacity was 115 amps. The wheel bearings were also strengthened and the brake servo action was made more powerful. Floating 944 calipers were standard, but the rear wheel brake circuit pressure regulator from the 944 turbo was used. Small ’16 Ventiler’ script badges were added on the sides in front of the body protection mouldings. Performance was quoted as 0 – 100 km/h in 6.5 seconds and a 144 mph top speed due to a 2857 lb weight. It also featured an improved programmed Bosch Digital Motronic 2 Computer/DME with dual knock sensors for improved fuel performance for the higher 10.9:1 compression ratio cylinder head. Like the 944 Turbo, the 944S received progressive springs for greater handling, Larger front and rear anti-roll bars, revised transmission and gearing to better suit the 2.5 litre DOHC higher 6800 rpm rev limit. Dual safety air bags, limited-slip differential, and ABS braking system were optional on the 944S. A Club Sport touring package (M637) was available as was the lightweight 16 inch CS/Sport Fuch 16×7 and 16×9 forged alloy wheels. This SC version car was raced in Canada, Europe and in the U.S. IMSA Firehawk Cup Series. Production was only during 1987 and 1988. It was superseded in 1989 by the ‘S2’ 944 edition. The 1987 944S power-to-weight ratio was such that it was able to accelerate from 0 to 62 mph in 6.5 seconds thus matching the acceleration of its newer larger displacement 3.0 litre 944 S2 sibling. In 1989 the 944S2 was introduced, powered by a 211 PS normally aspirated, dual-overhead-cam 16-valve 3.0 litre version of the 944S engine, the largest production 4-cylinder engine of its time. The 944S2 also received a revised transmission and gearing to better suit the 3.0 litre M44/41 powerplant. The 944S2 had the same rounded nose and a rear valance found on the Turbo model. This was the first example of the use of an integrated front bumper, where the fender and hood profiles would merge smoothly with the bumper, a design feature that has only now seen widespread adoption on the 1990 onward production cars. Performance was quoted as 0-60 mph in 6.0 seconds with a top speed of 240 km/h (150 mph) via manual transmission. A Club Sport touring package (M637) was also available. Dual air bags (left hand drive models), limited-slip differential and ABS were optional. Series 90 16-inch cast alloy wheels were standard equipment. In 1989, Porsche released the 944 S2 Cabriolet, a first for the 944 line that featured the cabriolet body built by ASC-American Sunroof Company at Weinsberg Germany. The first year of production included sixteen 944 S2 Cabriolet for the U.S. market. For the 1990 model year, Porsche produced 3,938 944 S2 Cabriolets for all markets including right-hand drive units for the United Kingdom, Australia and South Africa. This car was raced, including the British championship that was called the Porsche Motorsport Championship. Production was during 1989, 1990, and 1991. The 944 S2 power-to-weight ratio was such that it was able to accelerate from 0 to 60 mph in 6.5 seconds. In February 1991, Porsche released the 944 Turbo Cabriolet, which combined the Turbo S’s 250 hp engine with the cabriolet body built by ASC-American Sunroof Company at Weinsberg Germany. Porsche initially announced that 600 would be made; ultimately 625 were built, 100 of which were right-hand drive for the United Kingdom, Japanese, Australian, and South African market. None were imported to the U.S. and The Americas. In early 1990, Porsche engineers began working on what they had intended to be the third evolution of the 944, the S3. As they progressed with the development process, they realised that so many parts were being changed that they had produced an almost entirely new vehicle. Porsche consequently shifted development from the 944 S/S2 to the car that would replace the 944 entirely, the 968. The 944’s final year of production was 1991. A grand total 163,192 cars in the 944 family were produced between 1982 and 1991. This made it the most successful car line in Porsche’s history until the introductions of the Boxster and 997 Carrera.

The 968 was launched in 1992, renamed from the 944, as so little of the outgoing S2 remained unaltered. In addition to the numerous mechanical upgrades, the new model also received significantly evolved styling both inside and out, with a more modern, streamlined look and more standard luxury than on the 944. Production was moved from the Audi plant in Neckarsulm to Porsche’s own factory in Zuffenhausen. The 968 was powered by an updated version of the 944’s straight-four engine, now displacing 3.0 L with 104 mm bore, 88 mm stroke and producing 240 PS. Changes to the 968’s powertrain also included the addition of Porsche’s then-new VarioCam variable valve timing system, newly optimized induction and exhaust systems, a dual-mass flywheel, and updated engine management electronics among other more minor revisions. The 968’s engine was the second-largest four-cylinder ever offered in a production car up to that time. A new 6-speed manual transmission replaced the 944’s old 5-speed, and Porsche’s dual-mode Tiptronic automatic became an available option. Both the VarioCam timing system and Tiptronic transmission were very recent developments for Porsche. The Tiptronic transmission had debuted for the first time ever only 3 years prior to the debut of the 968, on the 1989 Type 964 911. The VarioCam timing system was first introduced on the 968 and would later become a feature of the Type 993 air-cooled six-cylinder engine. The 968’s styling was an evolution on that of the outgoing 944, itself styled evolutionarily from the earlier 924, but elements were borrowed from the more expensive 928 model in an attempt to create a “family resemblance” between models, and the swooping headlamp design, inspired by those of the 959, previewed similar units found later on the Type 993 911. Along with the new styling, the 968 featured numerous small equipment and detail upgrades, including a Fuba roof-mounted antenna, updated single lens tail lamps, “Cup” style 16″ alloy wheels, a wider selection of interior and exterior colours, and a slightly updated “B” pillar and rear quarter window to accommodate adhesive installation to replace the older rubber gasket installation. Because some parts are interchangeable between the 968, 944 and 924, some enthusiasts purchase those parts from Porsche parts warehouses as “upgrades” for their older models. Like the 944, the 968 was sold as both a coupe and a convertible. Much of the 968’s chassis was carried over from the 944 S2, which in itself shared many components with the 944 Turbo. Borrowed components include the Brembo-sourced four-piston brake calipers on all four wheels, aluminium semi-trailing arms and aluminium front A-arms, used in a Macpherson strut arrangement. The steel unibody structure was also very similar to that of the previous models. Porsche maintained that 80% of the car was new. From 1993 through 1995, Porsche offered a lighter-weight “Club Sport” version of the 968 designed for enthusiasts seeking increased track performance. Much of the 968’s luxury-oriented equipment was removed or taken off the options list; less sound deadening material was used, electrical windows were replaced with crank-driven units, upgraded stereo systems, A/C and sunroof were still optional as on the standard Coupe and Convertible models. In addition, Porsche installed manually adjustable lightweight Recaro racing seats rather than the standard power-operated leather buckets (also manufactured by Recaro), a revised suspension system optimised and lowered by 20 mm for possible track use, 17-inch wheels rather than the 16-inch and wider tyres, 225 front and 255 rears rather than 205 and 225 respectively. The four-spoke airbag steering wheel was replaced with a thicker-rimmed three-spoke steering wheel with no airbag, heated washer jets were replaced with non heated, vanity covers in the engine bay were deleted, as was the rear wiper. The Club Sport has no rear seats, unlike the 2+2 Coupé. Club Sports were only available in Grand Prix White, black, Speed yellow, Guards red, Riviera blue or Maritime blue. Seat backs were colour-coded to the body. Club Sport decals were standard in either black, red or white but there was a ‘delete’ option. All Club Sports had black interiors with the 944 S2 door cards. Due to the reduction in the number of electrical items the wiring loom was reduced in complexity which saved weight and also the battery was replaced with a smaller one, again reducing weight. With the no frills approach meaning less weight, as well as the optimising of the suspension, Porsche could focus media attention on the Club Sport variants fast road and track abilities. This helped to slightly bolster the flagging sales figures in the mid-1990s. The Club Sport variant achieved a ‘Performance Car Of The Year’ award in 1993 from Performance Car magazine in the UK. Club Sport models were only officially available in the UK, Europe, Japan & Australia, although “grey market” cars found their way elsewhere. The declared weight of the 968 CS is 1320 kg, ~100 kg lighter than the regular 968. Acceleration from standstill to 100 km/h is 6.3 seconds and a top speed is 260 km/h (160 mph). A UK-only version called “968 Sport”, was offered in 1994 and 1995, and was essentially a Club Sport model (and was produced on the same production line with similar chassis numbers) with electric windows, electric release boot, central locking, cloth comfort seats (different from both the standard and the Club Sport). With the added electrics the larger wiring loom was used. The Sport Variant also got back the two rear seats, again in the cloth material specific to the Sport. At £29,975, the 968 Sport was priced £5,500 lower than the standard 968, but had most of the latter’s desirable “luxuries” and consequently outsold it by a large margin (306 of the 968 Sport models compared to 40 standard 968 coupés). In 1993, Porsche Motorsports at Weissach briefly produced a turbocharged 968 Turbo S, a fairly odd naming choice for Porsche which usually reserves the added “S” moniker for models that have been tuned for more power over a “lesser” counterpart, such as with the 911 Turbo. The 968 Turbo S shared the same body and interior as the Club Sport and visually can be identified by the NACA bonnet hood scoops, adjustable rear wing and deeper front spoiler. Powered by a large 8 valve SOHC cylinder head (944 Turbo S) with 3.0 Litre 944S2 style engine block. Tests conducted in 1993 produced a 0 to 60 mph of 4.7 seconds and a top speed of 282 km/h (175 mph), performance comparable to the much newer Type 996 911. It generated 305 bhp at 5600 rpm with a maximum torque of 370 lb/ft) at 3000rpm. Only 16 were produced in total and only for sale in mainland Europe. Between 1992 and 1994, Porsche Motorsports Research and Development built and provided a full “Race” version (stripped out 968 Turbo S) for Porsche’s customer race teams. The 968 Turbo RS was available in two variations; a 337 bhp version using the K27 turbocharger from the Turbo S, which was built to the German ADAC GT specification (ballast added to bring the car up to the 1350 kg minimum weight limit), and an international spec version which used a KKK L41 turbocharger producing 350 bhp and was reduced to 1212 kg in weight. Only 4 were ever produced ; 1 Guards Red, 1 Speed Yellow, 1 Black and 1 White. These are the rarest 968s ever produced.

There were also plenty of examples of the larger and long-running 928 model. The first V8 engined Porsche, it was originally conceived to replace the 911, though as we all know, that did not happen, with the two complementing each other in the range during the 18 year life of the 928. By the late 1960s, Porsche had changed significantly as a company, and executives including owner Ferdinand Porsche were toying with the idea of adding a luxury touring car to the line-up. Managing Director Ernst Fuhrmann was also pressuring Ferdinand to approve development of the new model in light of concerns that the current flagship model at the time, the 911, was quickly reaching the limits of its potential. Slumping sales of the 911 seemed to confirm that the model was approaching the end of its economic life cycle. Fuhrmann envisioned the new range-topping model as being the best possible combination of a sports coupe and a luxury sedan, something well equipped and comfortable enough to be easily driven over long distances that also had the power, poise and handling prowess necessary to be driven like a sports car. This set it apart from the 911, which was intended to be an out-and-out sports car. Ordered by Ferdinand Porsche to come up with a production-feasible concept for his new model, Fuhrmann initiated a design study in 1971, eventually taking from the process the final specification for the 928. Several drivetrain layouts were considered during early development, including rear and mid-engined designs, but most were dismissed because of technical and/or legislative difficulties. Having the engine, transmission, catalytic converter(s) and exhaust all cramped into a small rear engine bay made emission and noise control more difficult, something Porsche was already facing problems with on the 911 and wanted to avoid. After deciding that the mid-engine layout didn’t allow enough room in the passenger compartment, a front engine/rear wheel drive layout was chosen. Porsche also may have feared that the U.S. government would soon ban the sale of rear-engined cars in response to the consumer concern over safety problems with the rear-engined Chevrolet Corvair. Porsche engineers wanted a large-displacement engine to power the 928, and prototype units were built with a 5-litre V8 producing close to 300 hp. Ferdinand Piëch wanted this car to use a 4.6-litre V10 based upon Audi’s five-cylinder engine. Several members of the Porsche board objected, chiefly because they wished for Porsche AG to maintain some separation from Volkswagen. The first two running prototypes of Porsche’s M28 V8 used one four-barrel carburettor, but this was just for initial testing. The cars were sold with the planned Bosch K-Jetronic fuel injection system. When increasing concern within the company over the pricing and availability of fuel during the oil crisis of the 1970s became an issue of contention, smaller engines were considered in the interest of fuel economy. A push began for the development of a 3.3 litre 180 hp powerplant they had drawn up designs for, but company engineers balked at this suggestion. Both sides finally settled on a 4.5 litre SOHC per bank 16-valve V8 producing 240 PS which they considered to have an acceptable compromise of performance and fuel economy. The finished car debuted at the 1977 Geneva Motor Show, going on sale later that year. Although it won early acclaim for its comfort and power, sales were slow. Base prices were much higher than that of the 911 model and the 928’s front-engined, water-cooled design put off many Porsche purists, not least because the design marked a major change in direction for Porsche started with the introduction of the Porsche 924 in 1976 which purists found hard to accept. Porsche utilised a transaxle in the 928 to help achieve 50/50 front/rear weight distribution, aiding the car’s balance. Although it weighed more than the difficult-to-handle 911, its more neutral weight balance and higher power output gave it similar performance on the track. The 928 was regarded as the more relaxing car to drive at the time. It came with either a five-speed dog leg manual transmission, or a Mercedes-Benz-derived automatic transmission, originally with three speeds, with four-speed from 1983 in North America and 1984 in other markets. More than 80% had the automatic transmission. Exact percentage of manual gearbox cars for entire production run is not known but it is believed to be between 15 and 20%. The body, styled by Wolfgang Möbius under guidance of Anatole Lapine, was mainly galvanised steel, but the doors, front fenders, and hood were aluminium in order to make the car more lightweight. It had a substantial luggage area accessed via a large hatchback. The new polyurethane elastic bumpers were integrated into the nose and tail and covered in body-coloured plastic; an unusual feature for the time that aided the car visually and reduced its drag. Porsche opted not to offer a convertible variant but several aftermarket modifiers offered convertible conversions, most notably Carelli, based in Orange County, CA. The Carelli conversions were sold as complete cars, with the conversion doubling the price of the car. A reported 12 units were made. The 928 qualified as a 2+2, having two small seats in the rear. Both rear seats could be folded down to enlarge the luggage area, and both the front and rear seats had sun visors for occupants. The rear seats are small (due to the prominent transmission hump) and have very little leg room; they are only suitable for adults on very short trips or children. The 928 was also the first vehicle in which the instrument cluster moved along with the adjustable steering wheel in order to maintain maximum instrument visibility. The 928 included several other innovations such as the “Weissach Axle”, a simple rear-wheel steering system that provides passive rear-wheel steering to increase stability while braking during a turn, and an unsleeved, silicon alloy engine block made of aluminium, which reduced weight and provided a highly durable cylinder bore. Porsche’s design and development efforts paid off during the 1978 European Car of the Year, where the 928 won ahead of the BMW 7 Series, and the Ford Granada. The 928 is the only sports car ever to have won this competition, which is regarded as proof of how advanced the 928 was, compared to its contemporaries. Porsche introduced a refreshed 928 S into the European market in 1980 model year. Externally, the S wore new front and rear spoilers and sported wider wheels and tyres than the older variant, but the main change for the 928 S was under the bonnet where a revised 4.7 litre engine was used. European versions debuted with 300 PS, and were upgraded to 310 PS for 1984, though it is rumoured that they typically made around 330 hp. From 1984 to 1986, the S model was called S2 in UK. These cars used Bosch LH-Jetronic fuel injection and purely electronic Bosch ignition, the same systems used on the later 32-valve cars, though without the pollution controls. North American-spec 1983 and 1984 S models used, among other differences, smaller valves, milder camshafts, smaller diameter intake manifolds, and additional pollution equipment in order to meet emissions regulations, and were limited to 234 hp as a result. Due to low grade fuel 16V low compression S engine was made for Australian market in 1985 model year. It had 9.3:1 compression ratio pistons instead of normal 10.4:1 but used same large intake, high lift cams, large valves etc. of other S engines. In 1982, two special models were available for different markets. 202 “Weissach Edition” cars were sold in North America. Unusual features were champagne gold metallic paint, matching brushed gold flat disc wheels, two-tone leather interior, a plaque containing the production number on the dash and the extremely collectible three-piece Porsche luggage set. It’s believed these cars were not made with S spoilers even though these were available in U.S. during this time period as part of the “Competition Group” option. The “Weissach Edition” option was also available for the US market 911 in 1980 model year and 924 in 1981 model year. 141 special “50th Jubilee” 928 S models were available outside the U.S. and Canada to celebrate the company’s 50-year existence as a car manufacturer. This model is also sometimes referred to as the “Ferry Porsche Edition” because his signature was embroidered into the front seats. It was painted meteor metallic and fitted with flat disc wheels, wine red leather and special striped fabric seat centres. Similar 911 and 924 specials were also made for world markets. Porsche updated the North American 928 S for 1985, replacing the 4.7 litre SOHC engine with a new 5.0 litre DOHC unit sporting four valves per cylinder and producing 288 hp. Seats were also updated to a new style, these cars are sometimes unofficially called S3 to distinguish them from 16-valve “S” models. European models kept a 4.7 litre engine, which was somewhat more powerful as standard, though lower 9.3:1 compression 32-valve engine together with catalytic converters became an option in some European countries and Australia for 1986. In 1986, revised suspension settings, larger brakes with 4-piston calipers and modified exhaust was installed on the 928S, marking the final changes to old body style cars. These were straight from the 928S4, which was slated to debut a few months later. These changes came starting from VIN 1001, which means that the first thousand ’86’s had the old brakes, but later cars had the later systems. This later 1986 model is sometimes referred to as a 19861⁄2 or 1986.5 because of these changes. The name is a little misleading as more than 3/4 of the 1986 production had these updates. The 928 S4 variant debuted in the second half of 1986 with an updated version of the 5.0 litre V8 producing 320 PS, sporting a new single-disc clutch in manual gearbox cars, larger torque converter in automatics and fairly significant styling updates which gave the car a cleaner, sleeker look. S4 was much closer to being a truly world car than previous models as only major differences for North American models were instrumentation in either kilometers or miles, lighting, front and rear bumper shocks and the availability of catalytic converters in many other markets. The Australian market version was only one with different horsepower rating at 300 PS due to preparation for possible low grade fuel. Even this was achieved without engine changes. A Club Sport variant which was up to 100 kg (220 lb) lighter became available to continental Europe and U.S. in 1988. This model was watered down version of the 1987 factory prototype which had a lightened body. Also in 1987 the factory made four white lightened manual gearbox S4 models for racecar drivers who were on their payroll at the time. These were close to same as later actual Club Sport models and can also be considered prototypes for it. An SE (sometimes called the S4 Sport due to model designation on rear bumper), a sort of halfway point between a normally equipped S4 and the more race-oriented Club Sport, became available to the UK. It’s generally believed these Porsche Motorsport-engined cars have more hp than the S4. They utilise parts which later became known as GT pistons, cams and engine ECU programs. Some of them had stronger, short geared manual gearbox. The automatic gearbox was not available. For the 1989 model year, a visible change inside was digital trip computer in dashboard. At the same time Australian models received the same 320 PS engine management setup as other markets. Porsche debuted the 928 GT in the late winter 1988/89 after dropping the slowly selling CS and SE. In terms of equipment, the GT was like the 928 SE, having more equipment than a Club Sport model but less than a 928 S4 to keep the weight down somewhat. It had the ZF 40% limited-slip differential as standard like the Club Sport and SE before it. Also like the CS and SE, the GT was only available with a manual gearbox. European 1989 CS and GT wheels had an RDK tyre pressure monitoring system as standard, which was also optional for the same year S4. For 1990 model year Porsche made RDK and a 0-100% variable ratio limited-slip called PSD (Porsche SperrDifferential) standard in both GT and S4 models for all markets. This system is much like the one from the 959 and gives the vehicle even more grip. In 1990 the S4 was no longer available with a manual gearbox. The S4 and GT variants were both cut at the end of 1991 model year, making way for the final version of the 928. The 928 GTS came for sale in late 1991. Changed bodywork, larger front brakes and a new, more powerful 5.4 litre 350 PS engine were the big advertised changes; what Porsche wasn’t advertising was the price. Loaded GTS models could eclipse US$100,000 in 1995, making them among the most expensive cars on the road at the time. This severely hampered sales despite the model’s high competency and long standard equipment list. Porsche discontinued the GTS model that year after shipping only 77 of them to the United States. Total worldwide production of 928s over an 18 year period was a little over 61,000 cars. Second-hand models’ value decreased as a result of generally high maintenance costs due largely to spare parts that are expensive to manufacture, with the result that there are fewer survivors than you might expect, though with values hardening, people are now spending the money required to restore these cars.

Perhaps the rarest of the road-going Porsche was this Carrera GT. Synonymous with Porsche’s endurance racing programme and Le Mans in particular, where they have triumphed some 17 times, the design of the Porsche Carrera GT is firmly rooted in its motorsport lineage. After success in 1998 at the famous 24-hour race, a team of engineers started work on a new mid-engined V-10 model utilising advanced technologies and materials. However, the project was soon put on hold as the company decided to focus its energies in a different direction with the introduction of a new SUV and the development of the Porsche Cayenne. Fortunately, the Carrera GT project was kept alive, and a prototype was shown at the 2000 Paris Auto Show. Response to the car was enthusiastic prompting Porsche to commit to a limited production run of 1,500 cars. By the end of production in 2006, only 1,270 cars were built, making it rarer still. With its 5.7 litre, dry sump V-10 engine (producing around 612 brake horsepower) sitting low in the carbon-fibre chassis, the Carrera GT weighed in at 1,380kg and was capable of 0-60 mph in 3.5 seconds with a top speed of 205 mph. Open the driver’s door and you are immediately aware that this is a totally focussed, seriously fast Porsche with the sense of function only just lightened by the Beechwood gear knob – a nod to the famous Porsche 917 and its racing past.

Much rumoured for some time, the Cayman GT4 was officially launched at the 2015 Geneva Show, positioned to sit between the Cayman GTS and the 911 GT3. By the time of the official unveiling, the car was supposedly sold out many times over, though more recently it has become apparent that at least some Porsche dealers have been holding onto cars claiming that the first purchaser changed their mind, and then offering them to those who did not get one of the allocation a year ago, at vastly inflated prices. If true, this is very sharp practice indeed, but seems to be the sort to tricks that are becoming increasingly common as enthusiasts are being fleeced in the name of extra profit. For a starting price of around £65,000 in the UK, the lucky customer would get a car which used used a stiffened and strengthened Cayman bodyshell as a starting point, but lowered by 30mm . Porsche say that in fitting as many GT parts as possible, they did not make it out of a Cayman GTS, but rather they produced an entry-level mid-engined GT3 car. That sounds like PR spin to me, as of course the car does use an awful lot of parts from the regular Cayman. However, plenty is changed, too. There is a reworked version of the Carrera S’s 3.8-litre flat six engine, producing 380bhp at 7400rpm and 310lb ft at 4750-6000rpm, hooked up to a modified version of the Cayman GTS’s six-speed manual gearbox. A PDK dual-clutch automatic was considered but rejected, meaning the Cayman GT4 is manual only. This is enough to mean that the 0-62mph sprint takes 4.4sec and the top speed is 183mph, with combined fuel economy of 27.4mpg and CO2 emissions rated at 238g/km. The front axle and suspension are borrowed from the 911 GT3 and the rear axle and forged aluminium double wishbone suspension are completely new. Dampers are taken from the 911 GT3. The electric steering system from the 911 GT3 does make it onto the Cayman GT4 but is given new software. Stopping power is provided by standard steel brakes, or optional carbon-ceramics from the 911 GT3. The forged 20in alloy wheels were new and are shod with Michelin Pilot Sport Cup 2 tyres. The rear 295/30 ZR20 tyres are bespoke, but the front 245/35 ZR20s were borrowed from the 911 GT3 as they were “a perfect match”. design-wise, the goal was to create a “zero lift car”, but thanks to the extensive aerodynamic and cooling package on the car – which includes a front splitter, a larger front grille and increased frontal air intakes, side air intakes, not one but two rear spoilers and a fully functional diffuser – the Cayman GT4 produces as much downforce at speed (100kg) as the 911 GT3. Every single part on the Cayman GT4 has a functional use. Other design features include “cool” black glass on the front and rear lights, blackened twin central exhausts and quality stitching on the twin lightweight bucket seats, taken from the 918 Spyder, as small details adding to that ‘want factor’.Despite all the extra equipment, the Cayman GT4 weighs no more than a Cayman GTS, tipping the scales at 1340kg dry. You could delete items such as the sat-nav and air-con to save weight, but few customers did, just as with the 911 GT3 RS were just 2% of buyers deleted the air-con. Inside, the steering wheel was new. The sports seats were trimmed in both leather and Alcantara. Standard equipment included bi-xenon headlights, a sports exhaust system, a Sport Chrono Package with dynamic engine mounts, the Porsche Torque Vectoring system, a mechanical limited-slip differential at the rear and the Porsche Stability Management system. On the options list were items such as carbonfibre-reinforced, plastic-backed seats for the two-seat interior. These weigh just 15kg each and were inspired by the 918 Spyder. A customised version of the Sport Chrono Package was offered, as is a Club Sport Package. Initially it was declared that production would be very limited, but Porsche soon relented and far more were built than had originally been declared.

There were a number of examples of the regular Boxster and Cayman models here, this 718 Cayman being the only one that my camera has recorded.

On 5 November 2009, Porsche officially announced a new variant of the Boxster, which was officially unveiled at the 2009 Los Angeles Motor Show. Positioned above the Boxster S, the Boxster Spyder was the lightest Porsche on the market at the time, weighing 1,275 kg (2,811 lb), 80 kg (176 lb) lighter than a Boxster S. This was achieved through the elimination of the conventional soft top’s operating mechanism, the radio/PCM unit, door handles, air conditioning, storage compartments, cup holders and large LED light modules on the front fascia, although some of these could be re-added to the car in the form of options. Weight saving was also gained using aluminium doors, an aluminium rear deck and the lightest 19-inch wheels in the Porsche pallet. The Spyder has a firmer suspension setup than the other Boxster models, and is almost one inch lower in order to have improved handling. A manually operated canvas top, carbon fibre sports bucket seats and two signature humps running along the back of the vehicle provide characteristic design elements. It is powered by a six-cylinder boxer engine rated at 321 bhp and 273 lb/ft (370 Nm) of torque, a 10 bhp increase in power over the Boxster S and the related Cayman S. The Boxster Spyder came with a 6-speed manual transmission as standard and had Porsche’s 7-speed PDK dual-clutch gearbox available as an option. The vehicle was released worldwide in February 2010.

Porsche revealed the latest Boxster Spyder based on the 981 Boxster in April 2015 at the New York Auto Show. The styling of the car is similar to the previous generation Spyder, continuing the twin hump rear deck and manually operated canvas top. It also shares some styling with the Cayman GT4, using the same front and rear fascia. The engine is also shared with the Cayman GT4, a 3.8 litre flat-6, making this the largest and most powerful engine used in a Boxster with 385 bhp. It was the lightest Porsche, weighing 1,315 kilograms (2,899 lb). This was achieved through the use of aluminium doors and rear boot lid, a manually operated roof and unique lightweight 20 inch wheels. The air conditioning and audio system were also removed, although they can be added as no cost options. Braking is via larger brakes than used on the Boxster S, being 340mm front and 330mm rear units taken from the 911 Carrera S. Also shared with the GT4 is a limited slip differential combined with Porsche Torque Vectoring and features a 20mm lower ride height. Additionally it also borrows the steering rack from the 911 Turbo S along with the same reduced diameter GT steering wheel as used in both the GT3 and GT4. The Boxster Spyder was only available with a 6 speed manual transmission. The Spyder had a base price of US$82,100 and was only available as a 2016 model with a total worldwide production of 2400 units, with 850 destined for the US.

The Porsche 919 Hybrid is a Le Mans Prototype 1 (LMP1) racing car built and used by Porsche in the 2014, 2015, 2016 and 2017 seasons of the FIA World Endurance Championship. It has a two-litre 90-degree V4 mid-mounted mono-turbocharged petrol engine that produces 500 hp (370 kW) and acts as a chassis load-bearing member – and two separate energy-recovery hybrid systems to recover thermal energy from exhaust gases and convert kinetic energy into electrical energy under braking for storage into lithium-ion battery packs. In accordance with the 2014 regulations, the vehicle was placed in the 6 MJ (1.7 kWh) class. On 4 March 2014, the 919 Hybrid was shown to the press for the first time during the Geneva Motor Show. Porsche supplied two cars, driven by six drivers, for the season. Romain Dumas, Neel Jani and Marc Lieb won three pole positions and the season-ending 6 Hours of São Paulo as Timo Bernhard, Brendon Hartley and Mark Webber helped the team to finish third in the World Manufacturers’ Championship. In 2015, the car was further developed and was categorized into the 8 MJ (2.2 kWh) category. Bernhard, Hartley, and Webber won four out of eight races to claim the 2015 World Endurance Drivers’ Championship and the World Manufacturers’ Championship. Earl Bamber, Nico Hülkenberg and Nick Tandy won the 6 Hours of Spa-Francorchamps and 24 Hours of Le Mans, driving a third 919 Hybrid. In 2016 Dumas, Jani, and Lieb won the 6 Hours of Silverstone and the 24 Hours of Le Mans with the car after further development. Consistent performances from the trio won them the 2016 World Endurance Drivers’ Championship and the team’s second. Although Bernhard, Hartley, and Webber had reliability issues in the season’s first three races, the trio won four of the six remaining rounds to help Porsche win its second consecutive World Manufacturers’ Championship. The next year, 2017, Tandy and former Audi LMP1 driver André Lotterer joined Jani in place of Dumas and Lieb, and Bamber teamed up with Bernhard and Hartley, replacing the retired Webber. Porsche finished on the podium in the first two rounds. Bamber, Bernhard, and Hartley recovered from a 13-lap deficit to win the 24 Hours of Le Mans and three more races for Porsche’s third consecutive World Drivers’ and Manufacturers’ Championships at the season’s penultimate round, the 2017 6 Hours of Shanghai.

At the around the time that Porsche were building the three all wheel drive Porsche 953 cars for their successful debut Paris Dakar campaign in 1984, they also built a series of 20 2 wheel drive evolutions of the Porsche 911 SC known as the 911 SC RS or 954 models for customers to compete in the Group B class for highly evolved / modified versions of production cars of which at least 200 examples had been built. These 20 evolution SC RS models featured modifications including extensive use of light weight aluminium panels that replaced steel items for the hood / bonnet, doors, fender / wings, and boot lid. Additionally the SC RS models were fitted with aluminium safety cages Porsche 911 Turbo brakes, with new castings for the rear calipers required to work with the coil over suspension that was tethered at the rear so that the rear suspension did not drop beyond a prescribed limit when the rear wheels left the ground. Porsche sold the 911 SC RS evolutions to customers at over double the price of a standard 911 SC with motors that produced 250 hp in touring trim and over 270 bhp when fitted with a competition exhaust. These cars were considered the heirs to the by now legendary 911 RS and 911 RSR models of the early mid 1970’s. After winning the 1981 World Rally Championship as co-driver to Ari Vatanen in a Rothmans sponsored Ford Escort RS1800 Dave Richards hung up his helmet and did a deal with Rothmans for his new venture Prodrive to prepare and run works Porsche 911 SC RS’s, officially registered Porsche’s UK importer in Reading, for Saeed Al-Hajri of Qatar and British co-driver John Spiller to compete in the 1984 and 1985 Middle East Rally Championships (MERC) which the pair won two years running with 18 overall victories. Alongside the MERC programme Prodrive entered selected events in both the World Rally Championship, in which Al-Hajri became the first Arab to score points and European Rally Championship. Amongst other Prodrive 911 SC drivers Finn Henri Toivonen won five European Championship events and but for a back injury, which nearly ended his career, might have become 1984 European champion. Other drivers who rallied 911 SC’s included; Frenchman Bernard Béguin, Brit Roger Clark, Irishman Billy Coleman and Belgians Robert Droogmans and 1984 Belgian Rally Champion Patrick Snijers. Porsche and Prodrive went their separate ways in 1986. Porsche was busy preparing their Group B 959 Rally Raid and 961 racing models, while Prodrive forged new relationships with MG and BMW before linking up with Subaru in 1990 with whom they became synonymous through the 1990’s thanks to a successful world championship rally programme. Today Prodrive is best known for its links with the Aston Martin racing programme, David Richards being Chairman of both companies which are not structurally financially interdependent.

A number of examples of the current range were on show here, including the latest Panamera Sport Turismo.

Inside the large marquee there was a display containing a number of restored road and race cars as well as this rather nice 550RS.

And finally, there was one example of Porsche’s Tractor production. The Porsche-Diesel Standard 218, also known as N 218, is the third generation of the two-cylinder Standard tractor series, manufactured by Porsche-Diesel Motorenbau GmbH in Friedrichshafen am Bodensee, succeeding its predecessor, the Porsche-Diesel 208 in 1957. The Porsche 218 utilises a frameless block construction. The rear axle is a live portal axle, the front axle is a dead beam axle with a central pivot point. The wheelbase measures 1668 mm. The track width of the front wheels can be adjusted by turning the rims on the vertical axis. On its rear wheels, the tractor has drum brakes. Either brake can act as a steering brake. Both the steering gear and the gearbox were produced by ZF Friedrichshafen. The H, S, and U Porsche-Diesel 218 models have a six-speed gearbox with a crawler gear. The clutch is a single-disc dry clutch of the type K 200 Z, made by Fichtel & Sachs. It works in conjunction with an oil-hydraulic clutch made by Voith. The Standard V 218 is a stripped-down model: it has a five-speed gearbox, and it lacks the oil-hydraulic clutch. Porsche-Diesel offered a Three-point linkage as a factory option. It can lift a mass of up to 550 kg. Another factory option was a mower bar, which cost DM 500. The tractor’s mass is 1625 kg including the three-point-linkage, the mower bar, and the extra weights. The maximum permissible mass is 2300 kg. The paint colour is RAL 3002 Karminrot for the body, and RAL 1014 or 1015 Elfenbein for the rims. The Standard 218 does not have a fuel tap due to tightness problems. Four different models of the Porsche 218 were produced: the H 218 was the base model with a six-speed gearbox, oil-hydraulic clutch, chrome decoration trim. H for hydraulic clutch; the V 218 was a simplified model with a five-speed gearbox, no hydraulic clutch, no trim. V stood or vereinfacht (simplified). The S 218 was a narrow gauge model. Like the H 218, but with a track width of 840 / 1240 mm and a wheelbase of 1620 mm. S for Schmalspur (narrow gauge). There was also the U 218, a shaft switching model. In addition to the standard H-equipment, it has a switchable gear shaft and a switchable power take-off shaft. It was offered with a cab and extended front wheel mudguards. U for umschaltbar (switchable). In total, the Porsche plant produced more than 12,000 Standard 218 tractors from 1957 to 1963.

RELIANT

Oldest Reliant here was a Sabre. Developed in collaboration with the Israeli motor company Autocars, as a result of the Managing Director Itzhak Shubinsky visiting the 1960 London Racing Car Show, where he saw the Ashley 1172 fibreglass body and also a Leslie Ballamy-designed chassis, the EB Debonair, exhibited on the LMB Components stand. Autocars obtained licences for both parts and contracted Reliant to develop the Sabra for Autocars. Reliant introduced a right-hand drive version for the UK market and renamed it the Sabre. At Reliant, David Page redesigned the chassis and the bodyshell was redesigned by Eddie Pepall to meet US requirements. Launched in 1961 as two-door convertibles, front-engined, rear-drive, with four-cylinder OHV, Ford Consul (later “Zephyr 4”) engines of 1,703 cc. They had front disc brakes, rack and pinion steering, and a ZF all-synchro gearbox. The front suspension was an unusual leading-arm set-up. Power output was 73 bhp giving at least 90 mph. Coupés were introduced in June 1962, and total production reached 208 cars. At Earls Court in October 1962 the Sabre was shown with a redesigned, “less bizarre” front end. A six-cylinder Super Sabre SE2 prototype was also shown, which then became the Sabre Six. In 1962, the Reliant Sabre Six was introduced, with a 109 bhp six-cylinder Ford engine of 2,553 cc, capable of 110 mph and 0-60 mph in 12.2 seconds. The nose of the car was different from the earlier Sabres, and all but the first 17 Sabre Sixes had more conventional suspension, taken from the Triumph TR4. From a production total of 77, 75 were coupés and just two were convertibles. The Reliant competitions department modified three factory cars and three privateer cars for entry into a number of International rallies. Modifications included a Raymond Mays alloy head with triple twin-choke Weber carburettors and independently-branched exhaust manifolds. Between 1963 and 1965, the cars participated in the Alpine Rally, RAC Rally, Welsh Rally and Monte Carlo Rally.

Following the success of the Scimitar GT Coupe, Reliant looked as to how to evolve the car and Tom Karen of Ogle was asked to submit some body designs based on the Ogle Design GTS estate car experiment for a new four seater Scimitar, the SE5 Reliant Scimitar. Managing Director Ray Wiggin, Chief Engineer John Crosthwaite and fibreglass body expert Ken Wood went to Ogle’s in Letchworth to look at a couple of mock-up body designs for the new SE5. Wiggin told Wood to go ahead and do a proper master. The SE5 was conceived and ready for the 1968 Motor Show in under 12 months. For the SE5 John Crosthwaite and his team designed a completely different longer chassis frame, revised and improved suspension, new and relocated fuel tank, a rollover bar, new cooling system, spare wheel mounted in the nose to give increased rear space and a 17 1⁄4 gallon) fuel tank. When designing the chassis Crosthwaite worked closely with Ogle body stylist Peter Bailey to modify and refine the prototype. The SE5 came with the same 3.0 litre Ford Essex engine used in the SE4a/b. This gave the SE5 a claimed top speed of over 120 mph. A Borg-Warner automatic transmission was added as an option in 1970 and by 1971, overdrive on the 4-speed manual was offered. In 1972 several improvements were included in the upgrade to SE5A, including a boost in power. The extra 7 hp and maximum engine speed raised performance quite a bit and the GTE was now capable of 0-60 mph in 8.5 seconds and top speed was raised to 121 mph. The SE5’s flat dashboard also gave way to a curved and moulded plastic one. The 5a can be recognised from a 5 at the rear by the reverse lamps which are below the bumper on the earlier model and are incorporated into the rear clusters on the later version (these were also carried over onto the SE6 and later). 4311 SE5s were produced. It was an instant success; GT production was cut down and the proportion of GTEs to GTs being built was four-to-one. Reliant increased their volume by 20 per cent in the first year. The 5A model sold more than any other Scimitar, with 5105 manufactured. Princess Anne was given a manual overdrive SE5 as a joint 20th birthday present and Christmas present in November 1970 by the Queen and the Duke of Edinburgh. It was Air Force blue in colour with a grey leather interior and registered 1420 H in recognition of her position as Colonel-in-Chief of the 14th/20th Hussars. Princess Anne subsequently owned eight other GTEs.

More of a luxury model than the SE5, the SE6 series Scimitar GT, launched in October 1975, was aimed more at the executive market. These models were two-door sports estates, again with the Ford V6 3.0 litre engine as used in the 5a with 135 bhp,: the wheelbase was increased by 4 inches and the track by 3 inches making the cars correspondingly longer and wider than their predecessors. The extra length was used to improve rear-seat legroom and access which enhanced the car’s credentials as a ‘genuine’ four-seater. The SE6 was replaced by the SE6A in late 1976. 543 SE6 models were produced. The SE6A displayed a number of changes, including Lockheed brakes and suspension revisions. An easy way to spot a 6A from a 6 is the change to orange from red reflectors on the rear extractor vents, and the 3 vertical grooves in the front bumper (in front of the wheelarches) were removed. 3877 SE6As were made – making it the most popular version of all the SE6 shape. Ford stopped making the “Essex” engine for the Capri by 1981, and production stopped completely in 1988 so one of the major differences with the SE6B was the engine. The German-built Ford “Cologne” 2.8 litre V6 was used instead (thus the chassis on the 6B differs from the 6/6A at the front) and provided similar power but rather less torque at low revs. The final drive ratio was lowered from 3.31:1 to 3.54:1 to compensate. All SE6Bs (and the SE8) were equipped with the quite troublesome Pierburg/Solex carburettored engines (many owners have changed to the Weber 38DGAS from the Essex engine) and although the battery was moved from the 6/6A position to allow for injection equipment to be fitted, none ever left the factory so fitted. Some late versions (around 1983 on) came with the galvanised chassis as standard but the exact numbers and chassis details are vague. Introduced at the 1980 Geneva Motor Show, only 437 SE6Bs were manufactured. Production ceased by 1986. But that was not the end of the story. After production at Reliant ceased, Middlebridge Scimitar Ltd. acquired the manufacturing rights to the Scimitar GTE and GTC in June 1987. This company, based in Beeston, Nottingham, produced a 2.9 litre version of the GTE with many modifications and modernisations (over 450) including electronic fuel injection and a five-speed Ford T9 gearbox.(with the Ford A4LD 4 speed auto as an option). The fifth Middlebridge Scimitar built was delivered to HRH The Princess Anne. Only 78 Scimitars (all but 3 cars in RHD) were ever produced by Middlebridge before the company went into receivership in 1990. One GTC was made, using a LHD body from Reliant which was converted by Middlebridge to RHD but the car was never completed and eventually the body and chassis were separated and sold off to new owners. The production rights were subsequently acquired by Graham Walker Ltd., which as of 2014 built Scimitars to order

Tamworth-based manufacturer began planning an open topped version of their popular Scimitar GTE as early as 1977, and they Ogle Design, who were also responsible for the GTE, to create a proposal. Tom Karen adapted his earlier GTE design and created a beautifully proportioned four-seater convertible with a good sized boot. From the B post back, all of the panels were new, with extra bracing introduced between the rear side panels and door hinge plates running under the dash board. The roll hoop from the GTE was retained, and for additional support this was linked to extra tubes running around the front screen creating a T bar design that would ensure the rigidity of the new body design. As the car sported a separate chassis and the extra bracing it did not suffer from the scuttle shake that can bedevil many monocoque convertibles. The hood was designed in house by adapting the hood frame from a Triumph Stag, with a bespoke cover made of mohair. A prototype car was produced in 1978, still in existence today, powered by a 3.0 Essex engine. Later Reliant replaced it with a 2.8 Cologne engine, because had Ford withdrawn their Essex engines from the European market in favour of the Cologne unit. This was slightly down on torque compared to the Essex engine, so to improve performance Reliant changed the final drive ratio from 3.31 to 3.54. The GTC, which surprisingly is lighter than the SE6B model GTE, was launched in March 1980 and was well received by the motoring press. However, in 1980 the country was heading into a recession and Reliant struggled to sell their £11,360 convertibles in great numbers. As a result, many cars were left sitting at the factory for months until owners could be found. A total of 442 production GTCs were manufactured by Reliant, 340 of which were manufactured in 1980. Just 3 were manufactured in 1981, 20 in 1982, 24 in 1983, 29 in 1984, 13 in 1985 and the final 13 in 1986. Today the GTC is a very rare sight on our roads and is possibly the most desirable of the Scimitar models.

The SS1 was a brave effort, but which never delivered on the potential of the concept. When word leaked out in the early 1980s, that Reliant was developing a small two seater sports car, everyone got rather excited. But the result was something of a disappointment, with rather gawky lines penned and not that much driving fun thanks to the (cheap to acquire) Ford CVH engines under the bonnet. Whilst the upgrade to the 1800cc turbo Nissan engine addressed the relative lack of go, the real problem was that a low volume manufacturer could not compete against one of the automotive giants and one of these, Toyota, launched a mid-engined rival even before the Reliant could establish itself in the market. Although production soldiered on for 10 years, rather than building 2000 cars a year, as the Tamworth maker had planned, only around this number were made in a 10 year period.

RENAULT

There were a couple here of the Renault Clio V6 Renault Sport, to give the car its full and rather cumbersome name. This was a rear mid-engine, rear-wheel-drive layout hot hatch based on the Renault Clio launched in 2001, very much in the same style as the earlier mid-engined R5 Turbo models of the 1980s. Designed by Renault, the Phase 1 models were built by Tom Walkinshaw Racing and Phase 2 were designed and helped by Porsche and built by Renault Sport in Dieppe. The Clio V6 was based on the Clio Mk II, though it shared very few parts with that car. The 3.0 litre 60° V6 engine, sourced from the PSA group. It was the ES9J unit as used in the Peugeot 406, 407 and 607, and the Citroen C 5 and not the one that Renault used in the 3 litre Laguna engine, which had an PRV (Peugeot, Renault & Volvo) an earlier development 90° V based on a V8 that never was. For this car it was upgraded to around 227 bhp and placed in the middle of the vehicle where the more ordinary Clios have rear seats – making this car a two-seater hot hatch. In order to accommodate the radical change from front-engine, front-wheel drive hatchback to mid-engine, rear-wheel drive two-seater quasi-coupé, the car had to be extensively reworked structurally, leading to the Phase 1 version being some 300 kg (660 lb) heavier than the sportiest “regular” Clio, the 172 Cup. Due to this, even though the V6 model had significantly more power, it was not remarkably faster in a straight line accelerating to legal road speeds than the 172 Cup – accelerating to 60 mph in 6.2 seconds compared to the Cup’s 6.7 seconds – though its maximum speed was significantly higher at 146 mph compared to 138 mph. Opinions varied on the handling, but many found it very twitchy and the car soon a gained a reputation for breaking away with little warning. That was largely addressed by the Phase 2 cars which were launched in 2003. The front end took on the same sort of new design as had been applied to the regular models. The engine was upgraded, to make the Phase 2 Clio V6 the most powerful serial produced hot hatch in the world with 255 bhp exceeding the 247 bhp of the Alfa Romeo 147 GTA and the 222 bhp SEAT León Cupra R. Based on the Phase 1 engine, its extra performance was helped with assistance from Porsche and although the Phase 2 gained even more weight, the result was a a reduced 0–60 mph run at 5.9 seconds and a top speed of 153 mph. Though based on a utilitarian hatchback, the Clio V6 was not a practical family car. With an average fuel consumption of 24 mpg, this resulted in an empty fuel tank in just over 300 miles. The loss of the back seats and most of the boot space, due to the engine placement, resulted in a severe restriction in luggage space – there was only a small space in the front where the engine used to be, suitable for a holdall or week-end groceries, a small netted area behind the seats plus a small stash area under the tailgate. The enhanced steering made tight manoeuvring a little challenging, the turning circle being a rather awkward 13 m (42.7 ft) – around three car lengths – turning what might normally be a three-point turn into a five-point turn. Standard equipment in the car was good, this was not a stripped-out special, and it included rain sensing windscreen wipers, automatic headlights, air conditioning, and six speakers and CD changer. The Phase 2 Clio V6 retailed for £27,125 in the United Kingdom, until it was withdrawn from sale in 2005 coinciding with a facelift for the Clio range. The Phase 2 was received far more enthusiastically by the ever-critical UK press. These days there is no doubting the fact that this is a a modern classic.

You don’t see one of these very often, the Renault Sport Spider that was made in small quantities between 1996 and 1999. The idea for the Renault Spider was formulated in the early 1990s: in the midst of a revival after a difficult second half of the 1980s, Renault wanted a car to promote it as a sporting brand in much the way the Renault 5 Turbo had done a decade earlier. The Spider was intended to both serve as a racing car, in a one-make series organised by Renault, and as a road car. The first prototypes for Project W94, as it was known at the time, were completed in mid-1994 and a concept version was presented to the public at the Geneva Motor Show a year later. The concept featured several differences to the version that ultimately became the road car, most notably butterfly doors and the absence of a windshield. The car went on sale in early 1996, assembled at the Alpine factory in Dieppe. Designed from the outset as a driver’s car, the chassis was made of aluminium for its combination of low weight and substantial strength, while the actual bodywork is a plastic composite. Unusually, the Spider did not have a roof, either folding or hard-top. The gearbox and the engine were one unit transversally fixed in an oscillating hinge (an arrangement inspired by aeronautical design), which all but eradicated the interference of engine vibration with the chassis, and the pedals of the Spider were adjustable as well as the seat so the driver could achieve a better driving position. Power for the Spider came from a version of the 2-litre F7R engine from the Renault Megane Coupe, producing 148 hp. Either a windscreen or a small wind deflector was fitted, with the driver wearing a helmet in vehicles without a windscreen. Despite the promise of the design, the initial reviews were not particularly effusive and the car was expensive, so it struggled for sales. Around 1800 were made over a three year period.

RENAULT-ALPINE

Sole Renault-Alpine type I came across was the GTA, the first car launched by Alpine under Renault ownership (though Alpine had been affiliated with Renault for many years, with its earlier models using many Renault parts). It effectively updated the design of its predecessor, the Alpine A310, updating that car’s silhouette with modern design features like body-integrated bumpers and a triangular C pillar with large rear windshield. It used the PRV V6 engine in a rear-engined layout, with extensive use of Polyester plastics and fibreglass for the body panels making it considerably lighter and quicker than rivals such as the Porsche 944. It was one of the most aerodynamic cars of its time, the naturally aspirated version achieved a world record 0.28 drag coefficient in its class. The GTA name, used to denote the entire range of this generation, stood for “Grand Tourisme Alpine” but in most markets the car was marketed as the Renault Alpine V6 GT or as the Renault Alpine V6 Turbo. In Great Britain it was sold simply as the Renault GTA, Rather than being cast in a single piece as for the preceding A310, the new Alpine’s body was cast in a large number of small separate panels. This required a major overhaul of the Alpine plant, leaving only the sandblasting machinery intact. The car was also considerably more efficient to manufacture, with the time necessary to build a finished car dropping from 130 to 77 hours – still a long time, but acceptable for a small-scale specialty car. The PRV engine in the naturally aspirated model was identical to the version used in the Renault 25, a 2849 cc unit producing 160 hp. Also available was the smaller (2.5 litres) turbocharged model. The central backbone chassis (with outriggers for side impact protection) was built by Heuliez and then transferred to Dieppe – aside from the body, most of the car was subcontracted to various suppliers. At the time of introduction, daily production was ten cars. This soon dropped considerably, as the somewhat less than prestigious Renault had a hard time in the sports car marketplace. The average production for the six full years of production was just above 1000 per annum, or just above three per day. The first model introduced was the naturally aspirated V6 GT, which entered production in November 1984, although press photos had been released in September 1984. The car was first shown at the 1985 Amsterdam Rai, immediately after which it also went on sale. In July 1985 the Europa Cup model appeared; this limited edition model was intended for a single-make racing championship and 69 cars were built (54 in 1985 and 15 more in 1987). In September 1985 the turbo model followed, which increased the power of the PRV unit to 200 PS. At the 1986 Birmingham Show the right-hand-drive version was presented and UK sales, as the Renault GTA, commenced. In early 1987 a catalysed version appeared, with fifteen less horsepower. This meant that the Turbo could finally be sold in Switzerland, and later in other European countries such as Germany and the Netherlands when they adopted stricter legislation. The catalysed model had lower gearing in fourth and fifth gears, in order to somewhat mask its power deficit. In 1988 anti-lock brakes became available. For the 1989 model year the Mille Miles version appeared. With the non-catalysed engine, this model heralded a re-focus on the Alpine name. The Renault logo was gone from the car, with an alpine logo up front and a large “Alpine” print appearing between the taillights. However, as the name ‘Alpine’ could not be used in the UK the name Alpine was removed from cars destined for the UK; there was no large print at the back of these cars and a UK specific logo was fitted to the front of the car. The Mille Miles, a limited edition of 100 cars, also featured a special dark red metallic paintjob, polished aluminium wheels, and a large silver grey triangular stripe with the Alpine “A” across the left side of the front. In February 1990 the limited edition Le Mans arrived, this car had a more aggressive body kit with polyester wheel arch extensions and a one piece front with smaller headlights. Wheels were 3 piece BBS style produced by ACT, 8×16″ front & 10×17″ rear. Many of these changes were adopted for the succeeding A610. The regular V6 GT and V6 Turbo ended production during 1990, while the Le Mans version continued to be produced until February 1991. 325 of these were built in total. Also in 1990, Renault was forced to install the less powerful catalysed engine in cars destined for the home market, leading to grumbling amongst Alpine enthusiasts about the loss of power (down to 185 PS) while the 25 Turbo saloon actually gained power when it became catalysed. In response Danielson SA, a famous French tuner, created an upgraded version of the Le Mans with 210 PS.

ROCHDALE

This is a Rochdale Olympic, The Rochdale company was founded in 1948 by Frank Butterworth and Harry Smith in an old mill building in Hudson Street, Rochdale. They performed general motor repairs and made themselves some alloy bodies, usually single-seaters, for racing Austin 7s and other cars. They went on to sell the bodies as the Mk II. A number of new models followed in the next few years, but the breakthrough came in 1959 with the monocoque Olympic designed by Richard Parker and only the third glass fibre monocoque bodied car to enter production (after the Berkeley and Lotus Elite). This featured a closed coupé style bodyshell with the provision for 2+2 seating but the rear seats were very cramped and many builders left them out. Unlike many sports and low production cars of the time, wind down windows were installed. Production started in 1960 using a Riley, twin-carburettor version, of the 1.5 litre BMC B Series engine, independent front suspension by torsion bar modified from that of the Morris Minor and live rear axle suspended by coil springs. Other engines could be fitted including the Morris Minor, MG MGA, and Ford 109E. The engine and front suspension was mounted on a tubular steel subframe bonded to the body shell and roll over protection was provided by a steel tube over the windscreen. The car appeared at the Copenhagen Racing Car Show and the Geneva Motor Show. A very complete kit, including an engine and all other mechanical parts, cost £670. About 250 were made when the fire caused production to be suspended. The car was available in both left and right hand drive and cars were exported to several countries including Australia and the United States. On test by The Motor magazine in 1961 a 1.5 litre Riley engined model achieved a top speed of 102 mph (164 km/h) and a 0-60 mph time of 11.9 seconds. The Phase II Olympic was introduced in 1963 at the London Racing Car Show and was now standardised on a 78 bhp Ford 116E 1500 cc engine. Front suspension now used Triumph wishbone units whilst the rear used a BMC axle with coil springs. Front disc brakes were fitted. The car weighed under 12 cwt and could reach 114 mph (183 km/h) with a 0-60 mph time of under 11 seconds. The rear window was made to open to give better access to the interior. The car was available as a complete kit for around £735 or fully built for £930 and about 150 were made. Production declined rapidly after 1967 but the last body was made in 1973. The body moulds are now owned by the Rochdale Owners Club.

ROLLS ROYCE

This is a Silver Cloud S1. First introduced in 1955, it was, with its later iterations the Cloud II and III, to prove the core of Rolls-Royce production until the arrival of the monocoque Silver Shadow in 1966. Construction of all Cloud models was body-on-frame, which allowed a number of creative coach-builders to work their magic, but over the course of its eleven years of production the vast majority were built with the standard Pressed Steel shell. The Silver Cloud II was notable for introducing a new engine, the essence of which is still used by Bentley today. The Silver Cloud III was the final version and deliveries to customers commenced in mid 1963. External dimensions were slightly altered with a one and a half inch reduction in grille height and by necessity, a slightly more sloping bonnet, but the most distinctive difference was the grouping of the headlights in a four headlamp unit which was sufficiently attractive to be carried over to the new Shadow. The car’s weight was reduced by over 100kg, and performance was improved by fitting 2″ SU carburettors and increasing the compression ratio to 9:1. One of the respected coach-builders who created something different on the Cloud III chassis was H.J.Mulliner (later Mulliner Park Ward), who offered a supremely elegant two door Drophead Coupe. These cars are now very sought after and are few and far between.

Also here was a Corniche. This was a development of the Rolls-Royce Silver Shadow, with the two door variants of that model marketed as the “Silver Shadow Mulliner Park Ward two door fixed head coupé & drop head coupé” until March 1971 when the Corniche name was applied. The exterior design was by John Polwhele Blatchley. The model was assembled and finished in London at Mulliner Park Ward as continuation of the 1965 Silver Shadow coupe and 1966 drophead. A Bentley version was also sold, becoming known as the Continental in 1984. The Corniche, available as coupé or convertible, used the standard Rolls-Royce 6750 cc V8 engine with an aluminium-silicon alloy block and aluminium cylinder heads with cast iron wet cylinder liners. Twin SU carburettors were initially fitted, but were replaced with a single Solex 4A1 four-barrel carburetor introduced in 1977. A three-speed automatic transmission (a Turbo Hydramatic 350 sourced from General Motors) was standard. A four-wheel independent suspension with coil springs was augmented with a hydraulic self-levelling system (using the same system as did Citroën, but without pneumatic springs, and with the hydraulic components built under licence by Rolls-Royce), at first on all four, but later on the rear wheels only. Four wheel disc brakes were specified, with ventilated discs added for 1972. The car originally used a 119.75 in (3,042 mm) wheelbase. This was extended to 120 in (3,048 mm) in 1974 and 120.5 in (3,061 mm) in 1979. The Corniche received a mild restyling in the spring of 1977. Difference included rack-and-pinion steering, alloy and rubber bumpers, aluminium radiator, oil cooler and a bi-level air conditioning system was added. Later changes included a modified rear independent suspension in March 1979. In March 1981, after the Silver Spirit had gone on sale, the Coupé version of the Corniche and its Bentley sister were discontinued. For 1985 there were also cosmetic and interior changes. Corniche models received Bosch KE/K-Jetronic fuel injection in 1977. This engine, called the L410I, produced approximately 240 PS at just above 4,000 rpm for a top speed of 190 km/h (118 mph). The Bentley version was updated in July 1984 with a new name, the Continental, revised and colour-coded bumpers, rear view mirrors, a new dash and improvements to the seats. Production totalled 1090 Rolls-Royce Corniche Saloons, 3239 Rolls-Royce Corniche Convertibles, 69 Bentley Corniche Saloons and 77 Bentley Corniche Convertibles.

ROVER

Whilst the 3 litre P5 model may have been thought of as a replacement for the top end of the long running P4 Rovers, it was really this car, the P6 model, first seen in October 1963 which was its true successor. Very different from the long-running 60/75/80/90/95/100/105/110 models, this car took some of its inspiration, it is claimed, from the Citroen DS as well as lessons learned from Rover’s Jet Turbine program of the 1950s and early 60s. It was a “clean sheet” design, carrying nothing over, and was advanced for the time with a de Dion tube suspension at the rear, four-wheel disc brakes (inboard on the rear), and a fully synchromesh transmission. The unibody design featured non-stressed panels bolted to a unit frame. The de Dion set-up was unique in that the “tube” was in two parts that could telescope, thereby avoiding the need for sliding splines in the drive shafts, with consequent stiction under drive or braking torque, while still keeping the wheels vertical and parallel in relation to the body. The Rover 2000 won industry awards for safety when it was introduced and included a carefully designed “safety” interior. One innovative feature was the prism of glass on the top of the front side lights. This allowed the driver to see the front corner of the car in low light conditions, and also confirmed that they were operative. One unique feature of the Rover 2000 was the design of the front suspension system, in which a bell crank (an L-shaped rotating bracket trailing the upper hub carrier joint) conveyed the vertical motion of the wheel to a fore-and-aft-horizontally mounted spring fastened to the rear wall of the engine compartment. A single hydraulically damped arm was mounted on the firewall for the steering. The front suspension was designed to allow as much width for the engine compartment as possible so that Rover’s Gas Turbine engine could be fitted. In the event, the engine was never used for the production vehicle, but the engine compartment width helped the accommodation of the V8 engine adopted years after the car’s initial launch for the 2000. The luggage compartment was limited in terms of usable space, because of the “base unit” construction, complex rear suspension and, in series II vehicles, the battery location. Lack of luggage space (and hence the need to re-locate the spare tyre) led to innovative options for spare tyre provision including boot lid mountings and optional Dunlop Denovo run-flat technology. The car’s primary competitor on the domestic UK market was the Triumph 2000, also released in October 1963, just one week after the Rover, and in continental Europe, it contended in the same sector as the Citroen DS which, like the initial Rover offering, was offered only with a four-cylinder engine – a deficiency which in the Rover was resolved, four years after its launch, when Rover’s compact V8 was engineered to fit into the engine bay. The Rover 2000 interior was not as spacious as those of its Triumph and Citroen rivals, especially in the back, where its sculpted two-person rear seat implied that Rover customers wishing to accommodate three in the back of a Rover should opt for the larger and older Rover 3 Litre. The first P6 used a 1,978 cc engine designed specifically for the car, which put out around 104 bhp. That was not enough to live up to the sports saloon ambitions, so Rover later developed a twin SU carburettor version with a re-designed top end and marketed the revised specification vehicles as the 2000 TC. The 2000 TC was launched in March 1966 for export markets in North America and continental Europe, relenting and making it available to UK buyers later that year. This engine generated around 124 bhp. The standard specification engines continued in production in vehicles designated as 2000 SC models. These featured the original single SU. More performance was to come. Rover saw Buick’s compact 3528 cc V8 unit that they had been looking at developing as the means of differentiating the P6 from its chief rival, the Triumph 2000. They purchased the rights to the innovative aluminium engine, and, once improved for production by Rover’s own engineers, it became an instant hit. The Rover V8 engine, as it became known, outlived its original host, the P5B, by more than thirty years. The 3500 was introduced in April 1968, one year after the Rover company was purchased by Triumph’s owner, Leyland and continued to be offered until 1977. The light metal V8 engine weighed the same as the four-cylinder unit of the Rover 2000, and the more powerful car’s maximum speed of 114 mph as well as its 10.5-second acceleration time from 0–60 mph were considered impressive, and usefully faster than most of the cars with which, on the UK market, the car competed on price and specifications. It was necessary to modify the under-bonnet space to squeeze the V8 engine into the P6 engine bay: the front suspension cross-member had to be relocated forward, while a more visible change was an extra air intake beneath the front bumper to accommodate the larger radiator. There was no longer space under the bonnet for the car’s battery, which in the 3500 retreated to a position on the right side of the boot. Nevertheless, the overall length and width of the body were unchanged when compared with the smaller-engined original P6. Having invested heavily in the car’s engine and running gear, the manufacturer left most other aspects of the car unchanged. However, the new Rover 3500 could be readily distinguished from the 2000 thanks to various prominent V8 badges on the outside and beneath the radio. The 3500 was also delivered with a black vinyl covering on the C-pillar, although this decoration later appeared also on four-cylinder cars. A 3-speed Borg Warner 35 automatic was the only transmission until the 1971 addition of a four-speed manual 3500S model, fitted with a modified version of the gearbox used in the 2000/2200. The letter “S” did not denote “Sport”, it was chosen because it stood for something specific on those cars: “Synchromesh”. However it is important to note that the 3500S was noticeably quicker than the automatic version of this car with a 0-60mph time of 9 seconds, compared with 10.1 for the standard car. Moreover, due to the fuel-guzzling nature of automatic gearboxes of this era, the manual car’s official cycle was 24mpg compared to the automatic’s 22mpg. The Series II, or Mark II as it was actually named by Rover, was launched in 1970. All variants carried the battery in the boot and had new exterior fixtures such as a plastic front air intake (to replace the alloy version), new bonnet pressings (with V8 blips even for the 4-cylinder-engined cars) and new rear lights. The interior of the 3500 and 2000TC versions was updated with new instrumentation with circular gauges and rotary switches. The old-style instrumentation with a linear speedometer and toggle switches continued on the 2000SC versions. The final changes to the P6 came in the autumn of 1973 when the 2200 SC and 2200 TC replaced the 2000 SC and TC. These cars used an enlarged 2,205 cc version of the 2000 engine, which increased power outputs to 98 and 115 bhp respectively as well as offering improved torque. The P6 was replaced by the SD1 Rover, a completely different sort of car indeed, after 322,302 cars had been built.

It is hard to imagine now just how excited people were when this dramatically different looking Rover burst onto the scene in July 1976. These days it takes a very extreme supercar for most car enthusiasts to get truly animated, but back then, a 3.5 litre V8 engined 5 seater British hatchback was all it took, and it was no surprise that the model collected the “Car of the Year” award later in 1976, fending off the second placed Ford Fiesta and the new Audi 100. Replacing both the Rover P6 and the big Triumphs which had been launched at the 1963 Motor Show and updated only in detail since then, this new David Bache styled car, with more than a hint of Ferrari Daytona in its profile really was something very different indeed to look at, even if underneath it was more of a clever update of proven mechanicals, with the 3.5 litre V8 engine carried over from its predecessor. Early press reports suggested that the car was as good to drive as it was to behold, and quickly there were long waiting lists as Rover struggled to produce the car fast enough in an all-new manufacturing facility in Solihull. Sadly, it did not take too long before it became apparent that although the car had been a long time in gestation, there were a number of design and manufacturing quality issues, quite apart form the extra ones that were inflicted by a still very truculent and strike-prone workforce. These frustrations did little to quell demand, though, which increased when the promised 6 cylinder models arrived in the autumn of 1977. 2300 and 2600 models sported a new 6 cylinder engine and were the more obvious replacement for the big Triumph and the Rover 2200 than the V8 car had been. BL’s next move was to take the car up market with the launch of the V8S in 1979 which was available in a rather bright Triton Green metalllic paint and a choice of gold or silver alloy wheels, as well having a far higher standard level of equipment. It was replaced by the even more luxurious Vanden Plas model in late 1980. More significant was a facelift which came in early 1982. A revised rear window line was aimed at improving the rather limited rear visibility and finally a rear wiper was fitted, this having been excluded from the earlier cars as it had been deemed unnecessary by a BL management who still thought that they knew better than the customers who clamoured for one) and the bumpers and lights were altered, along with significant interior trim and equipment changes. A few weeks later, a cheaper 4 cylinder 2000 model appeared, with the O Series engine under the bonnet, aimed at the all important fleet market and later that year it was joined by a diesel version, using the VM Motor engine, creating the 90 bhp 2400SD. The real joy though was the car revealed at the 1982 British Motor Show, the Vitesse, which boasted fuel injection and 190 bhp to give the car better performance, and with a new front and rear spoiler, the looks to suggest that this was an Autobahn-stormer to rival BMW and Mercedes. Of course, the other reason for the Vitesse was so as to homologate some of the changes for what turned out to be a less than successful career on the race track. It was this which led to the final handful of Vitesse models having a further power upgrade with the TwinPlenum versions, and these are the most highly prized cars of the lot these days. That said, values of SD1 remain very low, with the result that the majority of the cars have been scrapped as they are economic to restore. You see more Vitesse models than anything else so it was nice to see here that there are other models still around. There were a couple of Touring Car versions here as well as the road cars.

STANDARD

The Phase III Vanguard, released to the market for the mid-October 1955 Earls Court Motor Show, was a radical change with the elimination of the separate chassis. There was an overlap in availability of the old model with the Phase II estate continuing into 1956. UK fuel was no longer restricted to the 72 octane “Pool petrol” of the 1940s and early 1950s, and with the modest increases in available octane levels, the Vanguard’s compression ratio was increased to 7.0:1. The 2,088 cc engine with its single Solex downdraught carburettor now produced 68 bhp. The front suspension was independent, using coil springs, and was bolted to a substantial sub-frame which also carried the recirculating ball steering gear. Semi-elliptic leaf springs were used on the rear axle. Lockheed hydraulic brakes with 9 in (229 mm) drums were fitted front and rear. The three-speed gearbox had a column change and the optional overdrive was operated by a switch on the steering column. A four-speed floor change became an option. The new body was lower and had an increased glass area, making it look much more modern, and the old two-piece flat windscreen gave way to a one-piece curved design. The wheelbase increased by 8 in (203 mm), giving much better passenger accommodation. A heater was now a standard fitting. Bench seats were fitted in front and rear with folding centre arm rests. They were covered in Vynide, with leather available as an option. The car was lighter than the superseded model, and the gearing was changed to deliver better economy with performance virtually unchanged. The car was updated during the 1950s but by the time it was replaced it 1963 it definitely like a car from a prior era.

SUBARU

By the time that Subaru launched the third generation Impreza, the glory rally days were behind and interest in the marque was shifting somewhat. There were sporting models, both in warm WRX and hot STi guise, but the market seemed to have moved on and not that many were sold, so this is quite a rare car.

TOYOTA

Displayed at the October 1970 Tokyo Motor Show and marketed from December of the same year, the Celica was a two-door hardtop coupe that emphasised styling and driving enjoyment based on a platform shared with the Toyota Carina sedan which is one size above the Toyota Corolla. This car was aimed at the North American market and was Toyota’s response to the 1964 Ford Mustang (Pony car) which also was a standard sedan (Ford Falcon) with stylised 2+2 bodywork. In Europe, where it arrived in 1971, it was aimed at the successful Ford Capri. For export markets the Celica was available in three different levels of trim; LT, ST, GT, all with the same 1.6 litre 4 cylinder engine, though the LT had a single carburettor and the ST and GT had twin carbs. At its introduction the Celica was only available as a pillarless hardtop notchback coupe, adopting “coke bottle styling”. The prototype SV-1 liftback was shown as a concept car at the 1971 Tokyo Motor Show & with slight modifications this was introduced in Japan in April 1973 and this arrived in Europe in 1974. Minor styling changes were made during the car’s life before it was replaced by a second generation car in late 1977.

The MR2 derived from a 1976 Toyota design project with the goal of a car which would be enjoyable to drive, yet still provide good fuel economy – not necessarily a sports car. Design work began in 1979 when Akio Yoshida from Toyota’s testing department started to evaluate alternatives for engine placement and drive method, finalising a mid-transverse engine placement. Toyota called the 1981 prototype SA-X. From its original design, the car evolved into a sports car, and further prototypes were tested both in Japan and in the US. Significant testing was performed on race circuits including Willow Springs, where former Formula One driver Dan Gurney tested the car. All three generations were in compliance with Japanese government regulations concerning exterior dimensions and engine displacement. The MR2 appeared around the same time as the Honda CR-X, the Nissan EXA, the VW Scirocco from Europe, and the Pontiac Fiero and Ford EXP from North America. Toyota debuted its SV-3 concept car in October 1983 at the Tokyo Motor Show, gathering press and audience publicity. The car was scheduled for a Japanese launch in the second quarter of 1984 under the name MR2. Toyota introduced the first-generation MR2 in 1984, designating it the model code “W10”. When fitted with the 1.5-litre 3A engine, it was known as the “AW10”. Likewise, the 1.6-litre 4A version is identified by the “AW11” code. The MR2’s suspension and handling were designed by Toyota with the help of Lotus engineer Roger Becker. Toyota’s cooperation with Lotus during the prototype phase can be seen in the AW11, and it owes much to Lotus’s sports cars of the 1960s and 1970s. Toyota’s active suspension technology, called TEMS, was not installed. With five structural bulkheads, the MR2 was quite heavy for a two-seater of its size. Toyota employed the naturally aspirated 4A-GE 1,587 cc inline-four engine, a DOHC four-valve-per-cylinder motor, borrowed from the E80 series Corolla. This engine was also equipped with Denso electronic port fuel injection and T-VIS variable intake geometry, giving the engine a maximum power output of 112 hp in the US, 128 hp in the UK, 116 or 124 PS (114 or 122 hp) in Europe (with or without catalytic converter), 118 hp in Australia and 130 PS (128 hp) in Japan. Japanese models were later detuned to 120 PS (118 hp). A five-speed manual transmission was standard, with a four-speed automatic available as an option. In 1986 (1988 for the US market), Toyota introduced a supercharged engine for the MR2. Based on the same block and head, the 4A-GZE was equipped with a small Roots-type supercharger and a Denso intercooler. T-VIS was eliminated and the compression ratio was lowered to 8:1. It produced 145 hp at 6,400 rpm and 186 N⋅m; 137 lb⋅ft (19 kg⋅m) of torque at 4,400 rpm and accelerated the car from 0 to 100 km/h (62 mph) in 6.5 to 7.0 seconds. The supercharger was belt-driven but actuated by an electromagnetic clutch, so that it would not be driven except when needed, increasing fuel economy. Curb weight increased to as much as 2,494 lb (1,131 kg) for supercharged models, due to the weight of the supercharger equipment and a new, stronger transmission. A fuel selector switch was also added in some markets, to allow the car to run on regular unleaded fuel if required to. In addition to the new engine, the MR2 SC was also equipped with stiffer springs, and received special “tear-drop” aluminium wheels. The engine cover had two raised vents (only one of which was functional) that visually distinguished it from the naturally aspirated models. It was also labelled “SUPER CHARGER” on the rear trunk and body mouldings behind both doors. This model was never offered outside of the Japanese and North American markets, although some cars were privately imported to other countries. Toyota made detailed changes to the car every year until replacing it with a second generation model in 1989.

TRIUMPH

Triumph is always one of the best represented of marques at this event, and whilst there were not the number of anniversaries that there had been in 2015, there were still lots of these much loved classics here this time.

Launched in 1955, the TR3 was an evolution of the TR2 and not a brand new model. It was powered by a 1991 cc straight-4 OHV engine initially producing 95 bhp, an increase of 5 hp over the TR2 thanks to the larger SU-H6 carburettors fitted. This was later increased to 100 bhp at 5000 rpm by the addition of a “high port” cylinder head and enlarged manifold. The four-speed manual gearbox could be supplemented by an overdrive unit on the top three ratios, electrically operated and controlled by a switch on the dashboard. In 1956 the front brakes were changed from drums to discs, the TR3 thus becoming the first British series production car to be so fitted. The TR3 was updated in 1957, with various changes of which the full width radiator grille is the easiest recognition point and the facelifted model is commonly referred to as the Triumph “TR3A”, though unlike the later TR4 series, where the “A” suffix was adopted, the cars were not badged as such and the “TR3A” name was not used officially, Other updates included exterior door handles, a lockable boot handle and the car came with a full tool kit as standard (this was an option on the TR3). The total production run of the “TR3A” was 58,236. This makes it the third best-selling TR after the TR6 and TR7. The TR3A was so successful that the original panel moulds eventually wore out and had to be replaced. In 1959 a slightly modified version came out that had raised stampings under the bonnet and boot hinges and under the door handles, as well as a redesigned rear floor section. In addition, the windscreen was attached with bolts rather than the Dzus connectors used on the early “A” models. Partly because it was produced for less time, the original TR3 sold 13,377 examples, of which 1286 were sold within the UK; the rest being exported mainly to the USA.

Also here was the TR4. Successor to the TR3a, and code named “Zest” during development, the TR4 was based on the chassis and drivetrain of the previous TR sports cars, but with a modern Michelotti styled body. The TR 4 engine was carried over from the earlier TR2/3 models, but the displacement was increased from 1991cc to 2138 cc by increasing the bore size. Gradual improvements in the manifolds and cylinder head allowed for some improvements culminating in the TR4A model. The 1991 cc engine became a no-cost option for those cars destined to race in the under-two-litre classes of the day. Some cars were fitted with vane-type superchargers, as the three main bearing engine was liable to crankshaft failure if revved beyond 6,500 rpm; superchargers allowed a TR4 to produce much more horse-power and torque at relatively modest revolutions. The standard engine produced 105 bhp but, supercharged and otherwise performance-tuned, a 2.2-litre I4 version could produce in excess of 200 bhp at the flywheel. The TR4, in common with its predecessors, was fitted with a wet-sleeve engine, so that for competition use the engine’s cubic capacity could be changed by swapping the cylinder liners and pistons, allowing a competitor to race under different capacity rules (i.e. below or above 2 litres for example). Other key improvements over the TR3 included a wider track front and rear, slightly larger standard engine displacement, full synchromesh on all forward gears, and rack and pinion steering. In addition, the optional Laycock de Normanville electrically operated overdrive Laycock Overdrive could now be selected for 2nd and 3rd gear as well as 4th, effectively providing the TR4 with a seven-speed manual close ratio gearbox. The TR4 was originally fitted with 15×4.5″ disc wheels. Optional 48-lace wire wheels could be ordered painted the same colour as the car’s bodywork (rare), stove-enamelled (matte silver with chrome spinners, most common) or in matte or polished chrome finishes (originally rare, but now more commonly fitted). The most typical tyre originally fitted was 590-15 bias ply or optional radial tires. In the US at one point, American Racing alloy (magnesium and aluminium) wheels were offered as an option, in 15×5.5″ or 15×6″ size. Tyres were a problem for original owners who opted for 60-spoke wire wheels, as the correct size radial-ply tyre for the factory rims was 155-15, an odd-sized tyre at the time only available from Michelin at considerable expense. Some original TR4 sales literature says the original radial size was 165-15. The much more common 185-15 radials were too wide to be fitted safely. As a result, many owners had new and wider rims fitted and their wheels re-laced. The new TR4 body style did away with the classical cutaway door design of the previous TRs to allow for wind-down windows (in place of less convenient side-curtains), and the angular rear allowed a boot with considerable capacity for a sports car. Advanced features included the use of adjustable fascia ventilation, and the option of a unique hard top that consisted of a fixed glass rear window (called a backlight) with an integral rollbar and a detachable, steel centre panel (aluminium for the first 500 units). This was the first such roof system on a production car and preceded by 5 years the Porsche 911/912 Targa, which has since become a generic name for this style of top. On the TR4 the rigid roof panel was replaceable with an easily folded and stowed vinyl insert and supporting frame called a Surrey Top. The entire hard top assembly is often mistakenly referred to as a Surrey Top. In original factory parts catalogues the rigid top and backlight assembly is listed as the Hard Top kit. The vinyl insert and frame are offered separately as a Surrey Top. Features such as wind-down windows were seen as a necessary step forward to meet competition and achieve good sales in the important US market, where the vast majority of TR4s were eventually sold. Dealers had concerns that buyers might not fully appreciate the new amenities, therefore a special short run of TR3As (commonly called TR3Bs) was produced in 1961 and ’62. The TR4 proved very successful and continued the rugged, “hairy-chested” image that the previous TRs had enjoyed. 40,253 cars were built during production years. Most were sold new to the US, but plenty have returned, and it is estimated that there are not far short of 900 examples of the model in the UK at present.

Replacement for the TR4 was – predictably – the Triumph TR5, which was built for a 13-month period between August 1967 and September 1968. Visually identical to the Michelotti styled TR4,the TR5 hid the main differences under the body. The most significant change from the TR4 was the 2.5-litre straight-6 fuel-injected engine, developing around 145 hp, and which was carried forward to the TR6. At the time, fuel injection (or PI petrol injection, as it was sometimes then called) was uncommon in road cars. Triumph claimed in their sales brochure that it was the “First British production sports car with petrol injection”. Sadly, it was also somewhat troublesome, with mechanical issues a common occurrence. A carburetted version of the TR5 named Triumph TR250 was manufactured during the same period, to be sold in place of the fuel injected car on the North American market. A few of these have now been brought over to the UK and indeed there were both TR250 and TR5 cars here. The Triumph TR250, built during the same period for the North American market, was nearly identical to the TR5. But, because of price pressures and emission regulations the TR250 was fitted with twin Zenith-Stromberg carburettors rather than the Lucas fuel injection system. The reasons for this difference came down to price pressures of the American market, and tighter emissions regulations. The TR250’s straight-six engine delivered 111 bhp, 39 bhp less than the TR5; 0–60 mph acceleration took 10.6 seconds. Standard equipment on both models included front disc brakes, independent rear suspension, rack and pinion steering and a four speed gearbox. Optional extras included overdrive and wire wheels. Both the TR5 and the TR250 were available with the “Surrey Top” hard top system: a weather protection system with rigid rear section including the rear window and removable fabric section over the driver and passenger’s heads.

Next up was the TR6, the first Triumph for some time not to have been styled by Michelotti. By the mid 1960s, money was tight, so when it came to replacing the TR4 and TR5 models, Triumph were forced into trying to minimise the costs of the redesign, which meant that they kept the central section of the old car, but came up with new bodywork with the front and back ends were squared off, reportedly based on a consultancy contract involving Karmann. The resulting design, which did look modern when it was unveiled in January 1969 has what is referred to as a Kamm tail, which was very common during 1970s era of cars and a feature on most Triumphs of the era. All TR6 models featured inline six-cylinder engines. For the US market the engine was carburetted, as had been the case for the US-only TR250 engine. Like the TR5, the TR6 was fuel-injected for other world markets including the United Kingdom, hence the TR6PI (petrol-injection) designation. The Lucas mechanical fuel injection system helped the home-market TR6 produce 150 bhp at model introduction. Later, the non-US TR6 variant was detuned to 125 bhp for it to be easier to drive, while the US variant continued to be carburetted with a mere 104 hp. Sadly, the Lucas injection system proved somewhat troublesome, somewhat denting the appeal of the car. The TR6 featured a four-speed manual transmission. An optional overdrive unit was a desirable feature because it gave drivers close gearing for aggressive driving with an electrically switched overdrive which could operate on second, third, and fourth gears on early models and third and fourth on later models because of constant gearbox failures in second at high revs. Both provided “long legs” for open motorways. TR6 also featured semi-trailing arm independent rear suspension, rack and pinion steering, 15-inch wheels and tyres, pile carpet on floors and trunk/boot, bucket seats, and a full complement of instrumentation. Braking was accomplished by disc brakes at the front and drum brakes at the rear. A factory steel hardtop was optional, requiring two people to fit it. TR6 construction was fundamentally old-fashioned: the body was bolted onto a frame instead of the two being integrated into a unibody structure; the TR6 dashboard was wooden (plywood with veneer). Other factory options included a rear anti-roll bar and a limited-slip differential. Some say that the car is one of Leyland’s best achievements, but a number of issues were present and remain because of poor design. As well as the fuel injection problems, other issues include a low level radiator top-up bottle and a poor hand-brake. As is the case with other cars of the era, the TR6 can suffer from rust issues, although surviving examples tend to be well-cared for. The TR6 can be prone to overheating. Many owners fit an aftermarket electric radiator fan to supplement or replace the original engine-driven fan. Also the Leyland factory option of an oil cooler existed. Despite the reliability woes, the car proved popular, selling in greater quantity than any previous TR, with 94,619 of them produced before production ended in mid 1976. Of these, 86,249 were exported and only 8,370 were sold in the UK. A significant number have since been re-imported, as there are nearly 3000 of these much loved classics on the road and a further 1300 on SORN, helped by the fact that parts and services to support ownership of a TR6 are readily available and a number of classic car owners’ clubs cater for the model.

What turned out to be the final TR model was launched in January 1975, and this time it really was all new. A dramatic Harris Mann wedge shaped was shock enough for the purists, but the fact that at launch it only came as a Fixed Head Coupe was almost too much for some to bear. In the end, though. more TR7s were sold than any other TR model, so it really cannot have been all that bad even if the car had a somewhat bumpy existence, moving production plant from Speke, Liverpool where the early cars were made, to Canley, Coventry in 1978 and then finally to the Rover Solihull plant in 1980. An open topped model did join the range in 1980 and small numbers of factory built TR8s with the 135 bhp Rover V8 engine under the bonnet were made, but the proposed 2+2 Lynx model, and a version with the 16 valve Dolomite Sprint engine and the 2 litre O Series unit never made production. The car was launched in the United States in January 1975, with its UK home market debut in May 1976. The UK launch was delayed at least twice because of high demand for the vehicle in the US, with final sales of new TR7s continuing into 1982. The TR7 was characterised by its “wedge” shape, which was commonly advertised as: “The Shape of Things to Come”, and by a swage line sweeping down from the rear wing to just behind the front wheel. It had an overall length of 160 inches, width of 66 inches, wheelbase of 85 inches and height of 49.5 inches, and a kerbside weight of 2205 pounds, exactly 1000 kg. During development, the TR7 was referred to by the code name “Bullet”.The original full size model wore MG logos because it was styled at Longbridge, which was not a Triumph factory. Power was provided by a 105 bhp 1,998 cc eight-valve four-cylinder engine that shared the same basic design as the Triumph Dolomite Sprint engine, mounted in-line at the front of the car. Drive was to the rear wheels via a four-speed gearbox initially with optional five-speed manual gearbox, or three-speed automatic from 1976. The front independent suspension used coil spring and damper struts and lower single link at the front, and at the rear was a four-link system, again with coil springs. There were front and rear anti roll bars, with disc brakes at the front and drums at the rear. The interior trim was revised in March 1977, with the broadcord seat covers being replaced with red or green “tartan” check inserts with black leather effect vinyl edging, which looks so very period. now The tartan trim was also reflected in the door cards in padded matching red or green tartan cloth inserts in the black leather effect vinyl. A number of other detailed changes were made, partly to ensure commonality of parts in future models, such as the Convertible and the TR8, and also based on what else was available from the corporate parts bin. Badging changed a number of times, but there were no other significant alterations before the end of production in 1981. In total approximately 115,000 TR7 models were built which includes 28,864 soft top/convertibles, and approximately 2,800 TR8 models. Seen here were both Coupe and Convertible models, one of them with an uprated 4.6 litre V8 under the bonnet.

The TR’s smaller and cheaper brother was the Spitfire and there were a couple of examples from the later part of production. Based on the chassis and mechanicals of the Triumph Herald, the Spitfire was conceived as a rival to the Austin-Healey Sprite and MG Midget, which were launched a year earlier. The Triumph soon found a strong following, with many preferring it to the BMC cars which in time would become in-house stablemates. Mark II models arrived in 1965 and a more comprehensive facelift in 1967 with the distinctive “bone in mouth” front grille necessitated by US bumper height regulations also brought changes, but it was with the Mark IV that the greatest number of alterations would come about. The Mark IV featured a completely re-designed cut-off rear end, giving a strong family resemblance to the Triumph Stag and Triumph 2000 models, both of which were also Michelotti-designed. The front end was also cleaned up, with a new bonnet pressing losing the weld lines on top of the wings from the older models, and the doors were given recessed handles and squared-off glass in the top rear corner. The interior was much improved: a proper full-width dashboard was provided, putting the instruments ahead of the driver rather than over the centre console. This was initially black plastic however was replaced with wood in 1973. An all-new hardtop was also available, with rear quarter-lights and a flatter rear screen. By far the most significant change, however, was to the rear suspension, which was de-cambered and redesigned to eliminate the unfortunate tendencies of the original swing-axle design. The Triumph GT6 and Triumph Vitesse had already been modified, and the result on all these cars was safe and progressive handling even at the limit. The 75 hp engine was now rated at 63 hp (for UK market employing the 9:1 compression ratio and twin SU HS2 carburettors; the less powerful North American version still used a single Zenith Stromberg carburettor and an 8.5:1 compression ratio) due to the German DIN system; the actual output was the same for the early Mark IV. However, it was slightly slower than the previous Mark III due to carrying more weight, and employing a taller 3.89:1 final drive as opposed to the earlier 4.11:1. The engine continued at 1296 cc, but in 1973 was modified with larger big-end bearings to rationalise production with the TR6 2.5 litre engines, which somewhat decreased its “revvy” nature; there was some detuning, to meet new emissions laws, which resulted in the new car being a little tamer. With the overall weight also increasing to 1,717 lb (779 kg) the performance dropped as a consequence, 0 to 60 mph now being achieved in 15.8 seconds and the top speed reducing to 90 mph. The overall fuel economy also dipped to 32mpg. The gearbox gained synchromesh on its bottom gear. The Mark IV went on sale in the UK at the end of 1970 with a base price of £735. In 1973 in the United States and Canada, and 1975 in the rest of the world, the 1500 engine was used to make the Spitfire 1500. Although in this final incarnation the engine was rather rougher and more prone to failure than the earlier units, torque was greatly increased by increasing the cylinder stroke to 87.5 mm (3.44 in), which made it much more drivable in traffic. While the rest of the world saw 1500s with the compression ratio reduced to 8.0:1, the American market model was fitted with a single Zenith-Stromberg carburettor and a compression ratio reduced to 7.5:1 to allow it to run on lower octane unleaded fuel, and after adding a catalytic converter and exhaust gas recirculating system, the engine only delivered 53 bhp with a slower 0–60 time of 16.3 seconds. The notable exception to this was the 1976 model year, where the compression ratio was raised to 9.1:1. This improvement was short-lived, however, as the ratio was again reduced to 7.5:1 for the remaining years of production. In the UK the 9:1 compression ratio, less restrictive emissions control equipment, and the Type HS2 SU carburettors now being replaced with larger Type HS4 models, led to the most powerful variant to date. The 1500 Spitfire now produced 71hp (DIN) at 5500 rpm, and produced 82 lb/ft of torque at 3000 rpm. Top speed was now at the magical 100 mph mark, and 0 to 60 mph was reached in 13.2 seconds. Fuel economy was reduced to 29mpg. Further improvements to the suspension followed with the 1500 included longer swing axles and a lowered spring mounting point for more negative camber and a wider rear track. The wider, lower stance gave an impressive skid pad result of 0.87g average. This put the Spitfire head and shoulders over its competition in handling. The American market Spitfire 1500 is easily identified by the big plastic over-riders and wing mounted reflectors on the front and back wings. The US specification models up to 1978 still had chrome bumpers, but on the 1979 and 1980 models these were replaced by black rubber bumpers with built-in over-riders. Chassis extensions were also fitted under the boot to support the bumpers. Detail improvements continued to be made throughout the life of the Mark IV, and included reclining seats with “chequered brushed nylon centre panels” and head restraints, introduced for domestic market cars early in 1977 along with a new set of column stalk operated minor controls (as fitted already in the TR7) replacing the old dashboard mounted knobs and switches. Also added for the model’s final years were a wood dash, hazard flashers and an electric screen washer, in place of the previous manual pump operated ones. Options such as the hard top, tonneau cover, map light and overdrive continued to be popular, but wire wheels ceased to be available. The 1980 model was the last and the heaviest of the entire run, weighing 1,875 lb (850.5 kg). Base prices for the 1980 model year was £3,631 in the UK. The last Spitfire, an Inca Yellow UK-market model with hardtop and overdrive, rolled off the assembly line at Canley in August 1980, shortly before the factory closed. It was never sold and is now displayed at the museum at Gaydon.

Contemporary Triumph marketing advertised the GT6 as being developed from the “race winning Le Mans Spitfires” to capitalise on their aesthetic similarities, whereas the Le Mans Spitfires and the GT6 were actually two entirely separate development programmes (the GT programme pre-dating the racing programme). However, the marketing spin was so successful that many people erroneously believed the Le Mans Spitfires to actually be GT6s. The production car was introduced in 1966 and called the Triumph GT6. The new body was a sleek fastback design with an opening rear hatch which gave the GT6 the nickname “Poor man’s E-Type”. It was really a 2-seater, but a small extra rear seat could be ordered if required and was large enough for small children. The family resemblance to the Spitfire Mk II was strong, the longer 6-cylinder engine necessitated a new bonnet top with a power bulge and the doors were provided with opening quarter light windows and squared-off glass in the top rear corner. The 6-cylinder engine was tuned to develop 95 bhp at 5000 rpm, and produced 117 lb·ft of torque at 3000 rpm. The increased power necessitated certain changes to the Spitfire mechanics; the radiator was new and mounted further forward in the car and the gearbox was the stronger unit from the Vitesse, with optional overdrive. Front springs were uprated to cope with the extra weight of the new engine. The overall vehicle weight unladed was 1,904 lb (864 kg). The interior of the GT6 was well equipped; a wooden dashboard housed a full complement of instruments, with carpets and heater included as standard. The new car had some very strong selling points. The new engine provided a 106 mph top speed and 0–60 mph in 12 seconds, a little better than the MGB GT. Moreover, the unit was comparatively smooth and tractable, in marked contrast to the MG’s rather harsh 4-cylinder engine. Fuel economy was very reasonable for the period at 20mpg, and the interior well up to the competition. The only major criticism was of its rear suspension; the GT6 inherited the swing-axle system from the Spitfire, which in turn was copied from the Herald small saloon. In the saloon it was tolerated, in the little Spitfire it was not liked and in the powerful GT6 it was heavily criticised. Triumph had done nothing to improve the system for the GT6 and the tendency to break away if the driver lifted off the power mid-corner was not helped at all by the increased weight at the front of the car. The handling was most bitterly criticised in the USA, an important export market for Triumph, where they were traditionally very strong. Similar criticism was being levelled at the Vitesse saloon, which shared the GT6’s engine and its handling problems. Triumph realised that they needed to find an answer to the handling problem, if only to maintain their reputation in the USA. Their response came with the 1969 model year, with the introduction of the GT6 Mk II, known in the States as the GT6+. The rear suspension was significantly re-engineered using reversed lower wishbones and Rotoflex driveshaft couplings, taming the handling and turning the Triumph into an MGB beater. The Vitesse was also modified, but the Spitfire had to wait until 1970 for any improvements to be made. There were other changes for the Mk II; the front bumper was raised (in common with the Spitfire Mk.3) to conform to new crash regulations, necessitating a revised front end, and side vents were added to the front wings and rear pillars. Under the bonnet, the engine was uprated to develop 104 bhp with a new cylinder head, camshaft, and manifolds. Performance improved to 107 mph but perhaps more noteworthy the 0–60 mph time dropped to 10 seconds. The fuel economy was also improved to 25 mpg. The interior was updated with a new dashboard and better ventilation, a two-speed heater fan and a black headlining. Overdrive remained a popular option for the manual transmission. A further update to the Series 3 came in the autumn of 1970, at the same time as the Spitfire Mark IV was launched, but sales remained low and the car was deleted in the autumn of 1973 with production having reached 40,926 examples.

Envisioned as a luxury sports car, this car was designed to compete directly with the Mercedes-Benz SL. It started as a styling experiment, cut and shaped from a 1963–4 Triumph 2000 pre-production saloon, which had also been styled by Michelotti, and loaned to him by Harry Webster, Director of Engineering at Triumph. Their agreement was that if Webster liked the design, Triumph could use the prototype as the basis of a new Triumph model. Harry Webster, who was a long time friend of Giovanni Michelotti, whom he called “Micho”, loved the design and took the prototype back to England. The end result, a two-door drop head (convertible), had little in common with the styling of its progenitor 2000, but retained the suspension and drive line. Triumph liked the Michelotti design so much that they propagated the styling lines of the Stag into the new Mark 2 2000/2500 saloon and estate. The initial Stag design was based around the saloon’s 2.5-litre six cylinder engine, but Harry Webster intended the Stag, large saloons and estate cars to use a new Triumph-designed overhead cam 2.5-litre fuel injected V8. Under the direction of Harry Webster’s successor, Spen King in 1968, the new Triumph OHC 2.5 PI V8 was enlarged to 2997 cc to increase torque. To meet emission standards in the USA, a key target market, the troublesome mechanical fuel injection was dropped in favour of dual Zenith-Stromberg 175 CDSE carburettors. A key aim of Triumph’s engineering strategy at the time was to create a family of engines of different size around a common crankshaft. This would enable the production of power plants of capacity between 1.5 and 4 litres, sharing many parts, and hence offering economies of manufacturing scale and of mechanic training. A number of iterations of this design went into production, notably a slant four-cylinder engine used in the later Triumph Dolomite and Triumph TR7, and a variant manufactured by StanPart that was initially used in the Saab 99. The Stag’s V8 was the first of these engines into production. Sometimes described as two four-cylinder engines Siamesed together, it is more correct to say that the later four-cylinder versions were half a Stag engine. It has sometimes been alleged that Triumph were instructed to use the proven all-aluminium Rover V8, originally designed by Buick, but claimed that it would not fit. Although there was a factory attempt by Triumph to fit a Rover engine, which was pronounced unsuccessful, the decision to go with the Triumph V8 was probably driven more by the wider engineering strategy and by the fact that the Buick’s different weight and torque characteristics would have entailed substantial re-engineering of the Stag when it was almost ready to go on sale. Furthermore Rover, also owned by British Leyland, could not necessarily have supplied the numbers of V8 engines to match the anticipated production of the Stag anyway. As in the Triumph 2000 model line, unitary construction was employed, as was fully independent suspension – MacPherson struts in front, semi-trailing arms at the rear. Braking was by front disc and rear drum brakes, while steering was power-assisted rack and pinion. Although other bodystyles were envisaged, these never made production, so all Stags were four-seater convertible coupés. For structural rigidity – and to meet new American rollover standards of the time – the Stag required a B-pillar “roll bar” hoop connected to the windscreen frame by a T-bar. A removable hardtop was a popular factory option for the early Stags, and was later supplied as a standard fitment. The car was launched one year late in 1970, to a warm welcome at the various international auto shows. Sadly, it rapidly acquired a reputation for mechanical unreliability, usually in the form of overheating. These problems arose from a variety of causes, all of which are now well understood, and for which solutions have been identified, but at the time, they really hurt the reputation and hence sales of the car. They ranged from late changes to the engine which gave rise to design features that were questionable from an engineering perspective, the choice of materials which necessitated the use of antifreeze all year round, the engine’s use of long, simplex roller link chains, which would first stretch and then often fail inside fewer than 25,000 miles; the arrangement of the cylinder head fixing studs, half of which were vertical and the other half at an angle causing sideways forces which caused premature failure of the cylinder head gaskets. and poor quality production from a plant troubled with industrial unrest and poor quality control. At the time, British Leyland never provided a budget sufficient to correct the few design shortcomings of the Triumph 3.0 litre OHC V8, and the dealers did not help matters. The Stag was always a relatively rare car. British Leyland had around 2,500 UK dealers when the Stag was on sale and a total of around 19,000 were sold in the UK. Thus the average dealer sold only seven or eight Stags during the car’s whole production run, or roughly one car per year. This meant that few dealers saw defective Stags often enough to recognise and diagnose the cause of the various problems. Many owners simply replaced the engine altogether, often with the Rover V8, Ford Essex V6, or even the Triumph 6-cylinder engine around which the car was originally designed. Perhaps thanks to such a reputation for its unreliable engine, only 25,877 cars were produced between 1970 and 1977. Of this number, 6780 were export models, of which 2871 went to the United States. The majority of cars were fitted with a Borg-Warner 3-speed automatic transmission. The other choice was a derivative of the ancient Triumph TR2 gearbox which had been modified and improved over the years for use in the TR series of sports cars. Other than the choice of transmissions there were very few factory-installed options. On early cars buyers could choose to have the car fitted with just the soft-top, just the hard-top (with the hood storage compartment empty) or with both. Later cars were supplied with both roofs. Three wheel styles were offered. The standard fitments were steel wheels with Rostyle “tin-plate” trims. Five-spoke alloy wheels were an option, as were a set of traditional steel spoke wheels with “knock-off”‘ hubcaps. The latter were more commonly found on Stags sold in North America on Federal Specification vehicles. Electric windows, power steering and power-assisted brakes were standard. Options included air conditioning, a luggage rack, uprated Koni shock absorbers, floor mats and Lucas Square Eight fog lamps, and a range of after-market products, most of which were dealer installed as optional accessories could also be fitted. Rather unusually for a 4-seat touring car, the accessory list included a sump protector plate that was never produced. This was probably included as a slightly “gimmicky” tribute to Triumph’s rallying successes. Nowadays, the Stag is seen in a very different light, with lots of very enthusiastic and knowledgeable owners who enjoy the good points of this attractive looking car and who revel in the fact that the market has not yet boosted prices into the unaffordable category, as one day will surely happen.

There were several saloon-based models here, too. Among them was an example of the Triumph Herald. Towards the end of the 1950s Standard-Triumph offered a range of two-seater Triumph sports cars alongside its Standard saloons, the Standard 8 and 10, powered by a small (803 cc or 948 cc) 4-cylinder engine, which by the late 1950s were due for an update. Standard-Triumph therefore started work on the Herald. The choice of the Herald name suggests that the car was originally intended to be marketed as a Standard, as it fits the model-naming scheme of the time (Ensign, Pennant and Standard itself). But by 1959 it was felt that the Triumph name had more brand equity, and the Standard name was phased out in Britain after 1963. Giovanni Michelotti was commissioned to style the car by the Standard-Triumph board, encouraged by chief engineer Harry Webster, and quickly produced designs for a two-door saloon with a large glass area that gave 93 per cent all-round visibility in the saloon variant and the “razor-edge” looks to which many makers were turning. As Fisher & Ludlow, Standard-Triumph’s body suppliers became part of an uncooperative BMC, it was decided that the car should have a separate chassis rather than adopting the newer monocoque construction. The main body tub was bolted to the chassis and the whole front end hinged forward to allow access to the engine. Every panel – including the sills and roof – could be unbolted from the car so that different body styles could be easily built on the same chassis. As an addition to the original coupé and saloon models, a convertible was introduced in 1960. The Standard Pennant’s 4-cylinder 948 cc OHV engine and 4 speed manual gearbox was used with synchromesh on the top three gears and remote gear shift and driving the rear wheels. Most of the engine parts were previously used in the Standard 8/10. The rack and pinion steering afforded the Herald a tight 25-foot turning circle. Coil and double-wishbone front suspension was fitted, while the rear suspension, a new departure for Triumph, offered “limited” independent springing via a single transverse leaf-spring bolted to the top of the final drive unit and swing axles. Instruments were confined to a single large speedometer with fuel gauge in the saloon (a temperature gauge was available as an option) on a dashboard of grey pressed fibreboard. The coupé dashboard was equipped with speedometer, fuel and temperature gauges, together with a lockable glovebox. The car had loop-pile carpeting and heater as standard. A number of extras were available including twin SU carburettors, leather seats, a wood-veneered dashboard, Telaflo shock absorbers and paint options. In late 1958, prototype cars embarked on a test run from Cape Town to Tangiers. An account of the journey was embellished by PR at the time. However only minor changes were deemed necessary between the prototype and production cars. The new car was launched at the Royal Albert Hall in London on 22 April 1959 but was not an immediate sales success, partly owing to its relatively high cost, approaching £700 (including 45 per cent Purchase Tax). In standard single-carburettor form the 34.5 bhp car was no better than average in terms of performance. A saloon tested by The Motor magazine in 1959 was found to have a top speed of 70.9 mph and could accelerate from 0–60 mph in 31.1 seconds. A fuel consumption of 34.5 mpg was recorded. The rear suspension was criticised as yielding poor handling at the extremes of performance though the model was considered easy to drive with its good vision, light steering (smallest turning circle of any production car) and controls, and ease of repair. A Herald S variant was introduced in 1961 with a lower equipment level and less chromium than the Herald, offered in saloon form only. The 948cc Herald Coupe and Convertible models were discontinued in 1961, the 948cc Herald Saloon in 1962 and the Herald S in 1964. Standard-Triumph experienced financial difficulties at the beginning of the 1960s and was taken over by Leyland Motors Ltd in 1961. This released new resources to develop the Herald and the car was re-launched in April 1961 with an 1147 cc engine as the Herald 1200. The new model featured rubber-covered bumpers, a wooden laminate dashboard and improved seating. Quality control was also tightened up. Twin carburettors were no longer fitted to any of the range as standard although they remained an option, the standard being a single down-draught Solex carburettor. Claimed maximum power of the Herald 1200 was 39 bhp, as against the 34.5 bhp claimed for the 948 cc model. One month after the release of the Herald 1200, a 2-door estate was added to the range. Disc brakes became an option from 1962. Sales picked up despite growing competition from the BMC Mini and the Ford Anglia, with the car proving particularly popular to women drivers. The coupé was dropped from the range in late 1964 as it was by then in direct competition with the Triumph Spitfire. The Triumph Courier van, a Herald estate with side panels in place of rear side windows, was produced from 1962 until 1966, but was dropped following poor sales. Production in England ceased in mid-1964. CKD assembly by MCA in Malta continued till late 1965, at least. The Courier was powered by the 1147 cc engine. An upmarket version, the Herald 12/50, was offered from 1963 to 1967. It featured a tuned engine with a claimed output of 51 bhp in place of the previous 39, along with a sliding (Webasto) vinyl-fabric sunroof and front disc brakes as standard. The 12/50, which was offered only as a 2-door saloon, was fitted with a fine-barred aluminium grille. The power output of the 1200, which remained in production alongside the 12/50, was subsequently boosted to 48 bhp. In October 1967 the range was updated with the introduction at the London Motor Show of the Herald 13/60, which was offered in saloon, convertible and estate-bodied versions. The sun-roof remained available for the saloon as an optional extra rather than a standard feature. The front end was restyled using a bonnet similar to the Triumph Vitesse’s and the interior substantially revised though still featuring the wooden dashboard. Interior space was improved by recessing a rear armrest in each side panel. The engine was enlarged to 1296 cc, essentially the unit employed since 1965 in the Triumph 1300, fitted with a Stromberg CD150 carburettor, offering 61 bhp and much improved performance. In this form (though the 1200 saloon was sold alongside it until the end of 1970) the Herald Saloon lasted until December 1970 and the Convertible and Estate until May 1971, by which time, severely outdated in style if not performance, it had already outlived the introduction of the Triumph 1300 Saloon, the car designed to replace it and was still selling reasonably well but, because of its labour-intensive method of construction, selling at a loss.

Also here was a unique Herald model. This is a prototype which was built around 1965, as a potential hatchback addition to the range. Look carefully and you will see that the two sides are different one with a long rear side window, the other more turned up at the rear end. Sadly the model was pushed forwar to production. Quite how the car came to be sold on is unclear. It was found around 10 years ago in a very rotten state and has been completely rebuilt since then.

Three years after the launch of the Herald, Triumph created a more sporting version by putting a 1600cc 6 cylinder engine under the bonnet, calling the result the Vitesse. Handling of the early cars, on their swing axle suspension was best described as “interesting”, but Triumph worked hard to revise (tame!) it so by the time that the 2 litre models were launched in 1965, the car was rather easier to drive briskly on bendy roads. A Mark 2 version was launched in 1968, with new front end styling and other trim differences, and the model lived on until 1971. To be seen here was a late model 2 litre Convertible as well as one of the earlier cars.

Launched at the same time as the Rover 2000 was Triumph’s large saloon car, also called 2000. A replacement for the long running Standard Vanguard, this was the more sporting of the duo, with a subtly different appeal from the Rover. Between them, the cars defined a new market sector in the UK, promising levels of comfort and luxury hitherto associated with larger Rover and Jaguar models, but with usefully lower running costs and purchase prices, all in a modern package. Both added more powerful models to their range, with Rover going down the twin carburettor route, whilst in 1967, Triumph installed a larger 2.5 litre engine and the then relatively new fuel injection system, creating the 2.5PI, which is what was to be seen here. This Lucas system was not renowned for its reliability in the early days, but it did make the car rapid and refined. A facelift in 1969 brought new styling front and rear, which turned out to be a taster for a new grand tourer model which would emerge a few months later, and in this Mark 2 guise, the car was sold until 1977, in both saloon and estate guises. A mid range model, with twin carburettors but the larger engine, the 2500TC was introduced in 1974 and the 2500S arrived in 1975 with more power but also carb fed, to replace the troublesome and thirsty PI. These are the most sought after models now.

The Dolomite really was the 3 Series of its day, a family sized saloon that offered a combination of luxury and sportiness that made it a cut above the average Cortina and Marina. Designed as the successor for the upmarket variants of Triumph’s front-wheel drive designs, and also to replace a sporting relative of the Herald, the 6-cylinder Triumph Vitesse, the Triumph Dolomite was unveiled at the London Motor Show in October 1971. However, due to a number of strikes and other industrial upsets, the car was not reported to be in full production until October 1972. The Dolomite used the longer bodyshell of the front wheel drive Triumph 1500, but with the majority of the running gear carried over from the rear-wheel drive Triumph Toledo. Initially, the only version available used the new slant-four 1854 cc engine, which mated an alloy OHC head to an iron block, providing 91 bhp which offered sprightly performance. This was a version of the engine that the company was already providing to Saab for use in their 99 model. The car was aimed at the then-new compact performance-luxury sector, vying for sales against cars such as the BMW 2002 and Ford Cortina GXL, and was offered with a high level of standard equipment, including twin headlamps, a clock, full instrumentation, luxury seats and carpets, a heated rear window, and a cigar lighter. Styling was similar to the Triumph 1500, with some updates such as a black painted rear panel, vinyl D-posts, and new wheel trims. The car was capable of 100 mph with 60 mph coming up in just over 11 seconds. An overdrive gearbox was soon made available as an option, offering relaxed motorway cruising and improved fuel economy, and there was also an optional automatic transmission. Although the Dolomite proved to be refined and rapid, competitors such as the BMW 2002 had a performance advantage which was costing Triumph dearly, both in terms of sales and prestige. To remedy this, Triumph unveiled the Dolomite Sprint in June 1973, although the launch had been delayed by a year; it had been due to go on sale in 1972. A team of engineers led by Spen King developed a 16-valve cylinder head with all of the valves being actuated using a single camshaft rather than the more conventional DOHC arrangement. The capacity was also increased to 1,998 cc and combined with bigger carburettors the output was upped to 127 bhp. This represented a significant power increase over the smaller 1850cc variant, however it fell short of the original target of 135 bhp Despite BL engineers being able to extract a reliable 150 bhp from test engines, the production line was unable to build the engines to the same level of quality, with production outputs being in the region of 125 bhp to 130 bhp. This led to the original model designation, the Dolomite 135, being replaced at short notice with the Sprint name. As a result of the use of this engine, the Dolomite Sprint has been claimed to be “the world’s first mass-produced multi-valve car”. While other multi-valve engines (notably the Lotus 907) were produced in volume, they were not used in mass production vehicles until after the introduction of the Dolomite Sprint. The design of the cylinder head won a British Design Council award in 1974. Performance was excellent, with 0–60 mph taking around 8.4 seconds, with a maximum speed of 119 mph. Trim was similar to the 1850, with the addition of standard alloy wheels (another first for a British production car), a vinyl roof, front spoiler, twin exhausts and lowered suspension. By now seats were cloth on the 1850, and these were also fitted to the Sprint. Due to the increase in power brought by the new engine, the rest of the driveline was upgraded to be able to withstand the extra torque. The gearbox and differential were replaced by a version of those fitted to the TR and 2000 series cars, albeit with a close ratio gearset in the gearbox. The brakes were upgraded with new pad materials at the front, and the fitment of larger drums and a load sensing valve at the rear. Other changes over the standard Dolomite included the option of a limited slip differential. The optional overdrive and automatic transmission from the 1850 model were also offered as options on the Sprint. Initial models were only offered in Mimosa Yellow, although further colours were available from 1974 on. At launch the Sprint was priced at £1740, which compared extremely well to similar cars from other manufacturers. Prospective buyers would have been hard pressed to justify the extra £1000 cost of the BMW 2002 Tii, which offered similar performance. The four-door practicality of the Sprint also made it a very attractive proposition for the young executive choosing his first company car. The press gave the Dolomite Sprint an enthusiastic reception. Motor summarised its road test (subtitled “Britain leads the way”) with glowing praise: ” …the Sprint must be the answer to many people’s prayer. It is well appointed, compact, yet deceptively roomy. Performance is there in plenty, yet economy is good and the model’s manners quite impeccable … Most important of all, it is a tremendously satisfying car to drive”. Sadly, it proved not quite so satisfying to own, as the legendary BL lack of reliability was a feature on some, but by no means all Sprints. In 1976, Triumph rationalised their range, calling all their small models, Dolomite, and using the same body shell, so the Toledo (which had maintained its stubby tail until this point) and 1500TC became the Dolomite 1300, 1500 and 1500HL respectively. With minor changes to trim and equipment, the cars continued in production until 1980.

TURNER

The first Turner models were produced between 1951 and 1966 by Turner Sports Car Company Limited, a company established by Jack Turner near Wolverhampton, England. As well as complete cars, Turners were available in kit form. From the late 1940s, Jack Turner built a series of one-off specials, and prepared racing cars, including building his own engines. The first cars for sale were based on one of the specials, and consisted of chassis, independent suspension units using transverse leaf springs, and Turner’s own alloy wheels. It was up to the customer to arrange engine, transmission and body. Eight are thought to have been made. The first complete car was the Turner A30 Sports, a two-seater also known as the 803 and using an 803 cc Austin A30 engine, transmission and suspension. The car featured a simple ladder frame chassis and open fibreglass two-seater sports bodywork. As BMC would not supply components directly, they had to be purchased from dealers, which increased the price of the car. In 1956, the uprated 948 cc unit from the Austin A35 was adopted, and the model renamed Turner 950 Sports, but, apart from fully hydraulic brakes with optional front discs, was otherwise unchanged. The majority were exported mainly to the United States and South Africa. In 1959, the Turner Sports Mk I was introduced, and although similar to the outgoing model, featured substantial revisions to the body and chassis, and front disc brakes became an option. The 948 cc Austin engined version was named the Turner Sports Mk I, and versions known as Turner-Climaxes were also available with the powerful Coventry Climax 1,097 cc FWA and 1,216 FWE units. Almost 40 of the Sports Mk Is were made. In 1960, a Turner Sports Mk II model appeared, with improved interior trim and further minor styling revisions. From 1960, the front suspension became Triumph Herald-based. In 1961, as well as the Austin and Coventry Climax engines, other options were introduced, such as the Ford 105E 997 cc and 109E 1,340 cc units. Finally, in 1963, the new Ford Cortina 1,500 cc engine was also made available. About 150 Turner Sports Mk II models were made. Many Turners had illustrious racing careers such as the legendary VUD 701 driven by John E Miles in the Autosport National Race Championship of 1963–64, winning outright 15 of the 17 races against the works cars of Jaguar, Lotus and Aston Martin. Fully developed as a space-framed Modsports Race Car using a Cosworth engineered Ford 1824cc, VUD 701 is known to be the fastest of all the racing Turner Sports Cars, holding many UK class lap records to the present day. Throughout the UK, USA and Australia, the owner drivers of these lightweight nimble Turner Sports Cars are still winning in their class and overall, beating much more powerful cars. In early 1962, a completely new, larger, fixed-head Turner GT had been introduced, at the London Racing Car Show. It had a glass fibre monocoque centre section and could be had with a choice of Ford or Coventry Climax engines. Only nine of this model were produced, all believed to be fitted with the Ford 1,500 cc engine, before the model was discontinued in 1964. In late 1963, the final model was introduced as the Turner Sports Mk III, and featured a tuned version of the Ford 1,500 cc engine as standard. Externally, the bonnet gained a large air scoop. This model remained in production until the company went into liquidation in April 1966, when approximately 100 had been produced. In 1966, the company closed, after the founder had a heart attack. The company’s demise may also have been due to the development cost of a completely new coupé model with a rear-mounted Hillman Imp engine, the prototype of which was incomplete.

TVR

Oldest TVR model here was a Vixen. First introduced in 1967 as an evolution of the discontinued 1800S, the new Vixen used the same chassis as the outgoing car, but a significant change was the use of the 1599 cc Ford Kent engine (as found in the Ford Cortina GT), developing 88 bhp, a change necessitated by the problems TVR were having with receiving MG engine deliveries, and also in an effort to lower the price of the car. To use up remaining supplies, the first twelve Vixens built still received the MGB engine. The bodywork was also slightly revised, with the bonnet having a broad flat air intake scoop. The rear of the car with fitted with the round Cortina Mark I tail lamps. 117 of these were built before the S2 model arrived in 1968. This version was built with the longer (90 inch) wheelbase chassis, introduced on the Tuscan V8 but which TVR had now standardised to address complaints about difficulty of ingress. The bonnet was restyled again, with some early cars having a prominent central bulge, and later cars having twin intake ducts at the front corners of the bonnet. The tail lamps were updated from the round Cortina Mark I style to the newer wraparound Mark II style. Also very significant was the fact that the body was bolted (rather than bonded) to the chassis, meaning that it could be easily removed for repairs. The interior was improved, with a leather-skinned steering wheel mounted much lower than before. In a further attempt to improve the quality feel, the body was thicker and panel fit was improved. Sales were strong, with 438 of these made before the arrival of the S3, which continued to improve the car with a number of detail changes. The heat extraction vents on the bonnet were decorated with “Aeroflow” grilles borrowed from the Ford Zodiac Mark IV, and the Ford four-cylinder engine was now in the same tune as in the Ford Capri, producing 92 bhp. Instead of wire wheels, cast alloy wheels were fitted as standard. 165 of these were made before the final iteration, the S4 was launched. This was an interim model that used the TVR M Series chassis with the Vixen body shell. Apart from the chassis, there were no significant mechanical or cosmetic changes between the S3 and S4. Twenty-two were built in 1972 and one in 1973. TVR added a 1300 model to the range in late 1971. This was built in an attempt to fill an “economy” market segment for sports cars. It was powered by a 1296 cc Triumph Spitfire engine making 63 bhp, but its lacklustre performance limited its sales success. Top speed was barely 90 mph. Only fifteen were built, all in 1972. The final six of these cars were built on a M Series chassis, and the very last 1300 was also built with M Series bodywork, although it never received a “1300M” designation. Not to be confused with the later 2500M, the 2500 (marketed as the Vixen 2500 in the United States) was built between 1971 and 1972, and was designed to take advantage of the fact that the Triumph 2.5 litre inline-six engine had already been certified for US emissions standards (although only in 105 bhp form.) The final production run of the 2500 (comprising 96 cars) used the M Series chassis with Vixen-style bodywork. 385 of these cars were made.

The TVR M Series cars were built between 1972 and 1979, replacing the Vixen and Tuscan models. The styling showed a clear resemblance to the models that the M replaced, with the centre section of the car being carried forward and conceptually, the cars were little different, with a front mid-engine, rear-wheel drive layout and body-on-frame construction. The bodies themselves were built from glass-reinforced plastic (GRP). The engines were bought in, sourced from Triumph and Ford, which resulted in a number of different models being made. These included the 1600M, 2500M, 3000M, 3000S, and Taimar, as well as turbocharged versions of the 3000M, 3000S, and Taimar. The first model to start production was the 2500M in March 1972, after being built as a prototype in 1971, which had the 2500cc engine from the Triumph 2.5PI and TR6 under the bonnet. Ford engined 1600M and 3000M models followed later. The American market was financially very important to TVR, and Gerry Sagerman oversaw import and distribution of the cars within the United States from his facility on Long Island. Approximately thirty dealers sold TVRs in the eastern part of the country. John Wadman handled distribution of the cars in Canada through his business, JAG Auto Enterprises.. A small number of 5.0 litre Ford V8-powered cars were finished or converted by the TVR North America importer; these were sold as the 5000M. A total of 2,465 M Series cars were built over the nine years of production. Because of the hand-built and low-volume nature of TVR production, there are many small and often-undocumented variations between cars of the same model that arise due to component availability and minor changes in the build process. The M Series was regarded by contemporary reviewers as being loud and fast and having excellent roadholding. This came at the expense of unusual ergonomics, and heating and ventilation systems that were sometimes problematic. The first major alteration to the M Series body was the hatchback Taimar, introduced at the October 1976 British International Motor Show and using the same mechanicals as the 3000M. The name was inspired by the name of Martin’s friend’s girlfriend, Tayma. The opening hatchback alleviated the previous difficulty of manoeuvering luggage over the seats to stow it in the cargo area, and the hatch itself was opened electrically via a solenoid-actuated latch triggered by a button on the driver’s doorjamb. Over its three-year production, a total of 395 normally aspirated Taimars were built. The final body style for the M Series, an open roadster, arrived in 1978 as the TVR 3000S (marketed in some places as the “Convertible”, and referred to at least once as the “Taimar Roadster”.) Like the Taimar, the 3000S was mechanically identical to the 3000M; the body, however, had undergone significant changes. Only the nose of the car was the same as the previous coupes, as the windscreen, doors, and rear end had all been reworked. The redesign of the doors precluded the possibility of using wind-up windows, so sliding sidecurtains were instead fitted. These could be removed entirely and stowed in the boot, which, for the first time on a TVR, was a separate compartment with its own lid. The boot lid was operated electrically in a manner similar to the Taimar’s hatch. Its design was not finalised by the time the first cars entered production, so the first several cars (including the prototype) were built with no cutout for boot access. The final styling tweaks and the production of moulds for the fibreglass were done by Topolec Ltd. of Norfolk. The styling of the 3000S was revived in a somewhat modernised form later, with the 1987 introduction of the TVR S Series (although the S Series shared almost no components with the M Series cars.) The windscreen and convertible top had been adapted from those used on the Jensen-Healey roadster. Because Jensen Motors had ceased operation in 1976, the windscreen and sidecurtain designs were done by a company named Jensen Special Products, which was run by former Jensen employees. The design for the convertible top was finalised by Car Hood Company in Coventry. One of the minor undocumented variations found on M Series cars is the presence of a map light built into the upper windscreen surround of the 3000S. It appears to have been included only on a very small number of cars built near the end of the production run. When production of the 3000S ended (with 258 cars built), it cost £8,730. Reportedly, 67 of these cars were in a left-hand drive configuration, and 49 were exported to North America.

TVR replaced their long-running shape with something really quite radical looking in early 1980. with the Tasmin, and there was a relatively early version of these “wedge” era TVRs here. During the 1970s, when Martin Lilley started to look where to take the Blackpool based company next, he noted that Lotus appeared to have reinvented itself with the Elite, Eclat and Esprit, losing much of the kit-car image in the process, and he thought he needed to do something similar. He needed a new design language, so he contacted Oliver Winterbottom who had done the Elite/Eclat for the Norfolk firm, hoping for something new. The wedge-shaped design that Winterbottom created was produced in 1977, and a prototype was created the following year, before the new car’s launch very early in 1980. Based on the Taimar, but with very different wedge styling, the car was not exactly received with massive enthusiasm. The styling looked a bit like yesterday’s car, as the wedge era was on the wane, and the car’s price pitched it against cars like the Porsche 924 Turbo. Development of the new car had drained TVR’s finances, which led to Lilley ceding control of the company in 1981 to Peter Wheeler. The convertible that followed helped matters a bit, whereas the 2 litre 200 and the 2+2 model did not, but in 1983, TVR announced a revised version with the potent Rover 3.5 litre V8 under the bonnet, in lieu of the 2.8 litre Ford Essex unit, and it transformed the car. It was just what was needed, and over the next few years, a series of ever more potent models, with ever wilder styling came into the range. By 1986, the 450SEAC boasted 340 bhp, making this something of a supercar.

TVR’s next model took something of a retro look, the S Series which was announced at the 1986 British International Motor Show, initially as a concept. Due to a massive positive response, the car went into production in less than 12 months, with 250 pre-manufacture orders. This was Peter Wheeler’s first major development since buying the company from Martin Lilley, and the turning point in TVR’s fortunes, which had struggled with the “Wedge” based cars that had been introduced in 1980 to replace the long running M Series models. With styling which looked more like these popular M Series cars, the first S Series cars used Ford’s Cologne V6 in 2.8 litre 160 hp and for the later S2 to S4 had the later 2.9 litre 170 hp unit. TVR made frequent updates to the cars, moving from those retrospectively called the S1 to S2 and later S3 and S4 in short succession. The S3 and S4 received longer doors, although some late S2’s were also thus equipped. Vehicle models ending with “C” were used to denote vehicles which were fitted with a catalytic converter. Only the S3 and S4 were fitted with catalysts. The Cat was only introduced to the UK in August 1992, at “K” registration, but catalysed cars were produced before that, intended for export to markets with tighter emissions standards. Just as they had done with the “wedges”, TVR found more excitement by putting the Rover V8 engine under the bonnet of the car in lieu of the Ford unit, though the two models were offered in parallel. The V8S used a 4.0 litre fuel-injected Rover V8 engine, with gas-flowed cylinder heads, higher lift camshaft, compression ratio upped to 10:5:1, revised manifold, new chip for the engine management system and a limited slip differential. The result was 240 bhp at 5250 rpm and 270 lb/ft of torque at 3000 rpm. The V8S had a number of cosmetic differences over the V6. The bonnet had a large hump – created to house the Italian specification supercharger but carried over to all V8S models. The V8S had a small vent facing the windscreen, whereas S1 to S3 models face forward. Very late S3 and S4 models had no hump at all. As with all TVR’s there is no specific point in time when they changed styles, probably when they ran out! The suspension track was slightly wider on the V8S achieved with revised wishbones at the front and revised trailing arms at the rear. Disc brakes are fitted all round. The standard specification of the V8S included ½ hide leather interior, walnut trim, mohair hood, OZ alloy wheels, driving lamps, electric windows and door mirrors. 0-60 mph could be achieved in 4.9 seconds and 0-100 mph in 12.9 seconds. It was faster than an Aston Martin Virage, a Ferrari Testarossa, Lotus Esprit Turbo SE and Porsche Carrera 2 the supercars of the early 1990s. Between 1986 and 1994 2,604 S Series cars were made; 410 of these were of the V8S variety.

The Griffith was the first of the modern generation TVRs. First seen as a concept at the 1990 British Motor Show, it wowed the crowds sufficiently that unlike the Show Cars of precediing years, may of which were never seen again, Peter Wheeler and his small team in Blackpool immediately set about preparing it for production. It took until mid 1992 before they were ready. Like its forerunner namesakes, the Griffith 200 and Griffith 400, the modern Griffith was a lightweight (1048 kg) fibreglass-bodied, 2-door, 2-seat sports car with a V8 engine. Originally, it used a 4.0 litre 240 hp Rover V8 engine, but that could be optionally increased to a 4.3 litre 280 hp unit, with a further option of big-valve cylinder heads. In 1993, a TVR-developed 5.0 litre 340 hp version of the Rover V8 became available. All versions of the Griffith used the Lucas 14CUX engine management system and had a five-speed manual transmission. The car spawned a cheaper, and bigger-selling relative, the Chimaera, which was launched in 1993. 602 were sold in the first year and then around 250 cars a year were bought throughout the 90s, but demand started to wane, so iIn 2000, TVR announced that the Griffith production was going to end. A limited edition run of 100 Special Edition (SE) cars were built to mark the end of production. Although still very similar to the previous Griffith 500 model, the SE had a hybrid interior using the Chimaera dashboard and Cerbera seats. Noticeably, the rear lights were different along with different door mirrors, higher powered headlights and clear indicator lenses. Some also came with 16-inch wheels. Each car came with a numbered plaque in the glove box including the build number and a Special Edition Badge on its boot. All cars also had a unique signature in the boot under the carpet. The SEs were built between 2000 and 2002, with the last registered in 2003. A register of the last 100 SEs can be found at TVR Griffith 500 SE Register. These days, the Griffith remains a much loved classic and to celebrate the car, the owners have a meet called “The Griff Growl.”

Most numerous TVR here was the Chimaera, the slightly softer version of the Griffith, that was sold from 1993 to 2003. Offered with a choice of 4.0, 4,3 and later 4.5 and 5 litre Rover V8-based engines, this was still an exciting car, and a good looking one as well.

The next car that TVR added to the range was the Cerbera, which was first shown as a prototype at the 1994 Birmingham Show, entering production in 1996. The name derives from Cerberus the three-headed beast of Greek legend that guarded the entrance of Hades. This was the third car manufactured by TVR under the leadership of Peter Wheeler, and it represented three firsts for the Wheeler-led company: the first hard-top—the Griffith and the Chimaera were both convertibles; the first 2+2—TVRs were traditionally two-seaters; the first to be driven by TVR’s own engines—historically, TVR had purchased engines from mainstream manufacturers like Rover, Ford and Triumph. Prior to the Cerbera, TVR had purchased V8 engines from Rover and then tuned them for their own use. When Rover was purchased by BMW, Peter Wheeler did not want to risk problems should the Germans decide to stop manufacturing the engine. In response, he engaged the services of race engineer Al Melling to design a V8 engine that TVR could manufacture in-house and even potentially offer for sale to other car-makers. In an interview for the television programme Top Gear, Wheeler explained “Basically, we designed the engine as a race engine. It was my idea at the time that if we wanted to expand, we ought to make something that we could sell to other people. We’ve ended up with a 75-degree V8 with a flat-plane crank. The bottom-half of the engine to the heads is exactly as you would see in current Formula One engines.” Wheeler was quoted at the time of the car’s launch as saying that the combination of light weight and high power was too much for a road car, a quote which ensured much free publicity in the press. Enthusiasts still argue about whether this was a typical example of Wheeler’s legendary frankness, or an equally typical example of his PR chief Ben Samuelson’s knack for saving on advertising costs by creating a story. The result was dubbed the “Speed Eight” (official designation ‘AJP8’) after Al Melling, John Ravenscroft and Peter Wheeler, a 4.2 litre V8 producing 360 hp and gave the Cerbera a top speed of 185 mph (297 km/h). A 4.5 litre version of the engine was later offered with 420 hp. The AJP8 has one of the highest specific outputs of any naturally aspirated V8 in the automotive world at 83.3 hp/litre for the 4.2 and 93.3 hp/litre for the 4.5. Later models of the 4.5 litre engine had the ‘Red Rose’ option, which increased output to 440 bhp (97.7 hp/litre) when fuelled with super-unleaded (high octane) and the driver pushed the unmarked button on the dashboard which altered the engine mapping to suit. In some cases, real-world outputs for production V8s (4.5 in particular) were down from TVRs quoted output. Some of these have seen some form of modification (ECU, induction, exhaust etc.) to bring the power back up to the factory quoted output. One of the attractions of the V8 Cerberas for many owners was the loud backfire produced on overrun, particularly at low speeds. In fact this was the result of an argument at the factory between one of TVR’s executives and the engineers mapping the engine. The engineers wanted to map out this “irregularity” to improve fuel efficiency and CO2 emissions, whilst the executive insisted it was exactly the kind of thing owners would like. In the end a compromise was reached in which the popping and banging remained on the 4.5 litre cars. With the success of the Speed Eight program, Wheeler also undertook the design of a “Speed Six” engine to complement it. This engine also made its debut in the Cerbera but was a 4.0 litre inline slant six design with four valves per cylinder to the Speed Eight’s two. In service however it gained a reputation for unreliability and many engines had to be rebuilt. The car itself was designed from the start as a four-seater. The rear seats are smaller than the front, a design commonly referred to as a “2+2”. However, the interior is designed so that the passenger seat can slide farther forward than the driver’s seat. This allows more room for the person sitting behind the front passenger. TVR have referred to this as a “3+1” design. TVR maintained its tradition of building cars that were not only exceptionally powerful but also very light for their size and power output. The Cerbera’s weight was quoted by TVR at 1100 kilograms, although customers claimed the weight varied between 1,060 kg (2,337 lb) and 1,200 kg (2,646 lb). The dashboard was designed especially for the Cerbera and uses a two-spar steering wheel as opposed to the typical three-spar previously found in most TVRs. The reason for this is that minor instruments are located on a small panel below the steering wheel and a third spar in the wheel would have made them difficult to read. Like all TVRs of the Peter Wheeler era, the Cerbera had a long-travel throttle to compensate for the lack of electronic traction-control and very sharp steering. The V8 powered cars were two turns from lock to lock and the Speed Six car was 2.4 turns. This made it easier for experienced drivers to maintain or regain control of the car in the event of a loss of traction but some less experienced drivers complained that it made the cars feel “twitchy” and more responsive than they would otherwise have preferred. In 2000, TVR changed the styling of the car slightly by modifying the headlights to more closely resemble those seen in the TVR Tuscan. The “facelift” features were available with all three engine configurations. In addition, the cars equipped with the 4.5 litre engine were offered with the “lightweight” option, reducing the overall weight through the use of lighter body panels and a slightly reworked interior. The final car was made in 2006.

The Tuscan was launched in 2000, by which time there had been a series of what we think of as the modern era TVRs produced for nearly a decade, the Cerbera, Griffith and Cerbera. The Tuscan did not replace any of them, but was intended to help with the company’s ambitious push further up market to become a sort of Blackpool-built alternative to Ferrari. It did not lack the styling for the task, and unlike the preceding models with their Rover V8 engines, the new car came with TVR’s own engine, a straight six unit of 3.6 litre capacity putting out 360 bhp. The Tuscan was intended to be the grand tourer of the range, perfectly practical for everyday use, though with only two seats, no ABS, no airbags and no traction control, it was a tough sell on wet days in a more safety conscious world, but at least there was a removable targa top roof panel for those days when the sun came out. The car may have lacked the rumble of a V8, but when pushed hard, the sound track from the engine was still pretty special, and the car was faster than the Cerbera, but sadly, the car proved less than reliable, which really started to harm TVR’s reputation, something which would ultimately prove to be its undoing.

The T350 cars were made from 2002 to 2006. They were based on the TVR Tamora, and powered by TVR’s Speed Six engine in 3.6 litre form, producing 350 hp. The T350 was available in coupe and targa versions, the coupe version being known as the T350C, and the targa version the T350T. The T350 later formed the base of the TVR Sagaris. Function dominates form evident by the car’s aero-dynamic design which has been created for maximum downforce and minimal drag. The smooth frontal nose and the sharp rear cut tail allows the car to be aerodynamically efficient while reducing drag. The sloping rear line of the car ensures that the car generates minimum lift at high speeds. The car takes many components from the entry level Tamora such as the interior, multi-function display and analogue metres. The optional Sport package adds extra options in the multi-functional display such as lap-times, oil temperature and water temperature. The fastback design of the car gives the customer an advantage of increased boot space. The powerful Speed Six engine is a proven race winning unit and very responsive suiting the car’s aggressive character with a 0 – 100 km/h time of just 4.4 seconds.

Final TVR present was a Tamora. This car was launched in 2002, as the entry point of the range, taking over from the Chimaera. It was fitted with TVR’s in-house ‘Speed Six’, a DOHC 3605 cc six-cylinder engine rated at 350 hp and 290 lb/ft of torque at 5500 rpm, mated to a five-speed manual. Brake rotors were 12.0 inches up front, and 11.1 inches in the back, both clamped by AP Racing calipers. The suspension is a double wishbone setup at all four corners. Standard wheels are 16×7 inch aluminium, with 225/50ZR-16 Avon ZZ3 tyres. The Tamora was built on a 93-inch wheelbase, and the car’s overall profile measured 154.5 inches long, 67.5 inches wide and 47.4 inches high. It weighed 2,337 pounds, with 58/42 weight distribution. Keeping with the TVR tradition, the Tamora lacked driving aids such as traction control and ABS as well as air bags. It was still in production when TVR went bankrupt in 2006.

ULTIMA

Although the model has been in low volume “production” for many years now, there are still plenty of people who do not know what the car is, and the fact that there are no badges on it, and now no tax disc, means that there are no clues even when you see it in person. The Ultima is manufactured by Ultima Sports Ltd of Hinckley in Leicestershire, and is generally described by commentators as a supercar. It is available both in kit form and as a “turnkey” (i.e. assembled by the factory) vehicle. The design is a mid-engined, rear wheel drive layout, with a tubular steel space frame chassis and GRP bodywork. Both close coupe and convertible versions have been made. The latter is called the Ultima Can-Am. Kit builders are free to source and fit a variety of engines and transmissions but the Chevrolet small block V8 supplied by American Speed mated to either a Porsche or Getrag transaxle is the factory recommended standard, and this configuration is fitted to all turnkey cars.

VAUXHALL

This is a Chevette 2300 HS, the limited production car that was made in the late 1970s. The concept goes back to 1976, when at the instigation of new chairman Bob Price, Vauxhall decided to increase their profile in international rallying. They developed a rally version of the Chevette in conjunction with Blydenstein Racing, who ran Dealer Team Vauxhall, the nearest equivalent to a ‘works’ competition team that GM policy would allow. In order to compete in international rallying, the car had to be homologated; for Group 4, the class the HS was to compete in, this meant building 400 production vehicles for public sale. Vauxhall created a far more powerful Chevette variant by fitting the 2.3 litre Slant Four engine, using a sixteen valve cylinder head which Vauxhall was developing. Fitted with two Stromberg carburettors the engine developed 135 bhp. Suspension and rear axle were from the Opel Kadett C GT/E and the gearbox was a Getrag 5-speed. Chevrolet Vega Alloy wheels (similar in appearance to the Avon wheels used on the droopsnoot Firenza) were used, as well as a newly developed glass-reinforced plastic air dam. The result was a very fast and well handling, if rather unrefined, road car. Like the Droopsnoot Firenza, the HS was available only in silver, with red highlighting and a bright red, black and tartan interior; though (partly to help sell unsold vehicles) some cars were repainted in other colours, such as the black Mamos Garage HS-X. The HS became a great success as a rally car, clocking up notable wins for drivers such as Pentti Airikkala and Tony Pond. It was a challenge to the most successful rally car of the time, the Ford Escort, winning the British Open Rally Championship for Drivers in 1979 and for manufacturers in 1981. It was also successful in other national rally championships, such as Belgium’s. To keep the rally car competitive into the 1980s an evolution version, the Chevette HSR, was developed which was successful for several more years. The modified cars featured glass reinforced plastic (fibreglass) front and rear wings, spoiler, bonnet and tailgate (giving the HSR the nickname ‘Plastic Fantastic’), revised suspension (particularly at the rear, where extra suspension links were fitted), and other minor changes. Group 4 evolution required a production run of 50 cars incorporating the new modifications; these were made by rebuilding unsold HSs and by modifying customers’ vehicles. However, the merger of the Vauxhall and Opel marketing departments resulted in Dealer Team Vauxhall and Dealer Opel Team (DOT) joining to form GM Dealer Sport (GMDS); with the Chevette soon to be obsolete, Opel were able to force the cancellation of the HSR rally programme in favour of the Manta 400.

Now rare, the second generation Senator was the car that used to instill fear into many a motorway traveller, as this car was a popular issue with the police. The second generation Senator arrived in the spring of 1987, a long wheelbase version of the Opel Omega. There was no Monza equivalent. In the UK, they were sold with Vauxhall badging. There were various versions of the Senator B: twelve valve 2.5 litre and 3.0 litre sized engines were released in 1987 along with a luxury “CD” model with the 3.0 litre engine. The CD version boasted Electronic adjustable suspension, “ERC” for the first time in a mass produced European car. air conditioning, heated seats also in the backseat, genuine walnut panels, leather covered centre console, trip computer and cruise control. The cars were available with either five speed manual or four speed automatic gearboxes. A digitally controlled 4-speed automatic from Aisin-Warner equipped with three different switching programs Sport, Economy and Winter. It was also equipped with torque delay at each shift, called “torque retard” for not notable gear changes. In winter mode the car starts on the third gear and switches immediately to fourth as soon as possible to prevent spinning wheels and instability. This mode remains to the speed of 80 km/h and then automatically switches off. The gearbox also had built-in diagnostic system and emergency program. Later Lexus and Volvo used similar versions of this transmission. As a luxury car, there were many options but much was also standard, option was leather seats and heated seats both front and rear, electronic air conditioning including refrigerator in the glove box. LCD instrumentation was an option, digital electronic power steering ZF-Servotronic, the same as in the BMW 7 Series, was standard, as was a new front axle design which allowed the axle to slide under the car in a crash and thus increasing the length of the deformation zone and prevent deformation of the footwell. The 3.0 24V was equipped with BBS styled multispoke alloy wheels made by Ronal. A 24 valve 3.0 litre was introduced in 1989, generating 201 bhp compared with 175 bhp for the older twelve valve version. This model was very popular with the police force in the United Kingdom, with several cars being supplied to upgraded police specification. The main feature of the new engine was a “Dual Ram” system, increasing torque at low engine speeds by means of a redirected air flow system engaged at 4,000 rpm. For 1990 the 2.5 litre was replaced by a 2.6 litre Dual Ram, and the 3.0 litre twelve valve was deleted from the range in 1992. CD versions of the 2.6 litre, and a 24 valve 3.0 litre were available up to the model’s withdrawal in 1993. With the second generation Omega presented at the end of 1993, and available for sale from March 1994, Opel considered that it was sufficiently represented in the upper end of the market by the top specification Omega B. Production of the Opel Senator B ended in the Autumn/Fall of 1993 with a disappointing 69,943 cars produced since the car’s launch six and a half years earlier. Annual production had slumped from 14,007 in 1990 to 5,952 in 1992, with only 2,688 cars produced in 1993

VOLGA

The GAZ M21 Volga was produced in the Soviet Union by GAZ (“Gorkovsky Avtomobilniy Zavod”, in English : “Gorky automobile factory”) from 1956 to 1970. The first car to carry the Volga name, it was developed in the early 1950s. Volgas were built with high ground clearance (which gives it a specific “high” look, contrary to “low-long-sleek” look of Western cars of similar design), rugged suspension, strong and forgiving engine, and rustproofing on a scale unheard of in the 1950s. The Volga was stylistically in line with the major American manufacturers of the period in which it was introduced, and incorporated such then-luxury features as the reclining front seat, cigarette lighter, heater, windshield washer and 3-wave radio. When in 1959 the six-cylinder line of GAZ cars was discontinued, Volga M-21 became the biggest and most luxurious car officially sold to individual owners in the USSR in large quantities, though its price was very high and made it unavailable for most car buyers. 639,478 cars were produced in total. Three series GAZ-21 were released, most easily distinguished by the grille. The First Series (1956–58), known as the Star, featured a lattice of three large horizontal bars in the centre of which was a medallion with a star. Vehicles of the Second Series (1958–1962), known as the Shark, featured a grille with 16 vertical slits. Finally, the Third Series (1962–1970), known as the Baleen, featured a grille with 34 thin vertical rods. The design process leading to the GAZ 21 began in November 1953. Alexander Nevzorov, head of the design team, was given a free hand to develop whatever he wanted to reach the objective of competing with American automobiles. The designer Lev Eremeyev decided to follow the fashion set by the Chevrolet Bel Air, Plymouth Savoy, and Ford Mainline; the finished product bears a resemblance to the 1955 Mainline, although according to archive documents the latter was purchased for comparison and onroad testing by GAZ only in mid-1954 – after the first prototypes of the GAZ-21 had already been built and tested. The prototype appeared in the first quarter of 1954, powered by an inline four with overhead camshaft (driven by chain) and cross-flow hemi head. Since the OHV engine was not ready in time, production M21s had a 65 PS 2,432 cc sidevalve four, based on the GAZ-20’s. The Volga was offered with a three-speed transmission, either manual (with synchronized 2nd and 3rd gear) or automatic. Front suspension was independent, while the rear was a live axle with semi-elliptical springs; there were lever shock absorbers on all four corners. Lubrication was by a central oiling system, from a drum and foot-operated pump; the oil lines were prone to puncturing, and not all of the nineteen lubricated points were supplied equally. The Volga offered front seats able to fold flat (not unlike a contemporary Nash option) and came standard with cigarette lighter and a radio (still optional on most U.S. cars). There were three variants: the standard M21G, an M21B taxi (with a taximeter in place of the radio and bucket seats in front instead of a bench), and a tropical model, the M21GYU, all with the GAZ leaping deer hood ornament. Drag coefficient was a surprisingly good 0.42. The Volga made its public debut in 1955, with a three cars on a demonstration drive from Moscow to the Crimea, two automatic models and a manual. It was, however, still far from production-ready; in the first year, 1956, only five cars were assembled, the first on 10 October 1956. Full-scale production began in 1957, with a list price of 5,400 rubles. The new 1957 production cars, known as Series Ones, had a brand-new 2,445 cc OHV engine, the first model produced by Zavolzhskiy Motorniy Zavod (Zavolzhye Engine Factory, ZMZ). Unusual for the era, it had aluminium block and head, with gear-driven camshaft and compression ratio of 6.6:1; it produced 70 PS. The automatic transmission model would soon be discontinued, with only 700 built: it was widely criticised as being too difficult for Soviet drivers to maintain, there were few service stations to do the work and few private mechanics qualified, and there was a shortage of transmission oil. From 1958, a three-speed manual, with synchromesh on the top two gears, was the only transmission available; this would be the M21V, while the taxi became the M21A. The automatic did go on to be used in the low-production GAZ-13 Chaika, which would also be maintained by professionals. Standard equipment on all models included spare parts and two tool kits, with spanners, wrenches, screwdrivers, a tyre pump, and a can of paint to fix minor dings. There were also export models M21D with the manual transmission and M21E with the automatic, both with a higher 7.2:1 compression engine, producing 80 PS. Cars produced in the fall of 1958 combined features of the First and Second Series. Second Series Volgas were introduced in 1959, with a new grille painted the body color or in chrome. Halfway through the 1959 production run (model year 1959½), a vinyl cover was added to the dash. Added were windscreen washers and tubeless tyres. Just before the second series production concluded, telescopic shocks replaced the lever type. The 1961 Volgas were priced at 5,100 rubles. Variants of the Series Two included the M21 and M21A taxi with the 70 PS inline four, and the M21K and right-hand drive M21H (for export) with the 80 PS engine. The Volga was shown at the 1958 Brussels World’s Fair and together with the GAZ-52 truck and the GAZ-13 Chaika it won the award. In the same year, production for export began. The Second Series Volgas became known for having no frills but outstanding durability, helped by the 23 cm (9.1 in) ground clearance. In 1959, a Volga took a class win at the Thousand Lakes Rally in Finland, and third at the Acropolis Rally. That year, the central lubrication system was deleted, in favour of a more traditional local grease-application nipple. In early 1962, a small number of cars were built that combined features of the Second and Third Series. The Third Series was produced from 1962 to 1970. The 1962 models dropped the leaping deer hood ornament, and had a new grille.It used a 6.7:1 compression engine of 75 PS with an optional 7.65:1 compression of 80 PS (usually reserved for the export models). The headliner changed from cloth to vinyl, and the radio became optional. It was offered as the standard M21L, M21T taxi, and right-hand drive M21N export model. Also in 1962, GAZ advertised a Station wagon/estate model, the M22; most of these were exported or reserved for official use. The first station wagons/estates were delivered in 1963, and were designated M22 (75 PS), M22G (export, 75 hp) M22T (export, 85 PS); ambulances were M22B (75 PS) and M22BK (85 PS). An M22 prototype four-wheel drive station wagon/estate was also built, as was an M22A van. The Belgian importer Sobimpex N.V. assembled Volgas locally for sale in Western Europe. These were often fitted with diesel engines; the cars arrived in Antwerp without an engine and with the gearbox in the trunk. Originally (beginning in 1960) Sobimpex fitted a 1.6-litre Perkins 4.99 unit, a larger Rover engine supplanted that in 1963, and the more modern Indenor four-cylinder units replaced the Rover engine in 1964. Belgian-built cars were marketed as “Scaldia-Volgas,” named after the Latin name for the river Scheldt. While the diesel models cost considerably more than ones with the original engine, they were quite popular for their economy and reliability and outsold the petrol models in both Belgium and the Netherlands. The car’s large size and tough construction made it popular in the police and taxi trades, and V8-engined versions (designated GAZ M23) were produced for the KGB. An automatic transmission was briefly offered in the late 1950s, but later discontinued due to lack of service stations, and then through the 1960s on the KGB’s V8 version only, with the driver’s controls being very similar to the discontinued “civil” automatic. The Volga M21 was produced in saloon form from 1956 to 1970 and station wagon form (GAZ M22 Universal) from 1962 to 1970. This left the design quite outdated by the 1960s. GAZ developed a boxier, more modern replacement and in 1970, the M21 platform was discontinued by GAZ. Until the late 1970s, however, spare parts were produced by different plants all over the USSR, and some plants were re-building M21s using spare parts, wrecked, and junked cars. In 1988, about 80,000 M21 Volgas were registered in the USSR.

VOLKSWAGEN

There were very few Volkswagen here, but among the few that I did spot was this classic Beetle.

VW had launched the second generation Golf in August of 1983, nearly 9 years after production of the first model to bear the name had begun. This time, a GTi version was included in the product plans from the start, and the new GTi was announced in May 1984. Like the regular Golf 2, it was almost 7″ longer than the Mark 1, with 3″ extra in the wheelbase and a 2″ wider track. It was also 10% heavier, but with significantly improved aerodynamics, resulting from attention to detail which included integrated gutters and flush glass as well as more rounded styling, the cd fell from 0.42 to 0.34. Initially it was powered by the same 1781cc fuel injected engine, but there were all round disc brakes and longer suspension travel improved the ride. Competitors came snapping at its heels, though, so after 2/5 years, VW responded by giving the car 24% more power, achieved by doubling the number of valves to 16. Lower stiffer suspension and bigger front brakes were also fitted, all of which restored the Golf GTi 16V to the top of the Hot Hatch pile. For most people that is, though the 8v car retained a following thanks to its broader torque spread. This less powerful car changed from a mechanical K-Jetronic injection system to a new Digifant electronic set up in 1987 at which point the front quarterlights were deleted, and a digital instrument pack became an option on the 16v car. Power steering became standard in late 1990 and the 8v gained the interior from the 16v model. Production ran through to February 1992, by which time the Mark 3 GTi was waiting in the wings. over 600,000 were built over an 8 year period, around 10% of all Mark 2 Golf production.

VOLVO

There was a late model example of the “Amazon” Volvo here. Although costly when new, thanks to the UK’s Import Duty which applied to foreign car imports at the time, the Volvo of this era was surprisingly popular with UK buyers. The cars were tough, as strong success in rallying evidenced, but not that many have survived. There’s a complex history to this model, with lots of different numbers applied to the car during a 13 year production run. When introduced, the car was named the Amason (with an ‘s’), deriving from the fierce female warriors of Greek mythology, the Amazons. German motorcycle manufacturer Kreidler had already registered the name, and the two companies finally agreed that Volvo could only use the name domestically (i.e., within Sweden), modifying the spelling to Amazon. Subsequently, Volvo began its tri-digit nomenclature and the line became known as the 120 Series. Under prototype designation 1200, following the PV444’s internal designation as the 1100, the Amazon was released in the press in February 1956, with production initially set to begin in July of the same year, and deliveries commenced in August 1956 — under the now modified internal designation 120 series. The Amazon sedan’s ponton genre, three-box styling was inspired by US cars of the early 1950s, strongly resembling the Chrysler New Yorker sedan and the Chrysler 300C hardtop Coupe. According to designer Jan Wilsgaard, the Amazon’s styling was inspired by a Kaiser he saw at the Gothenburg harbour. The Amazon featured strong articulation front to rear, pronounced “shoulders”, and slight but visible tailfins. These features became inspiration for Peter Horbury when reconceiving Volvo’s design direction with the V70 after decades of rectilinear, slab-sided, boxy designs. The Amazon’s bodywork was constructed of phosphate-treated steel (to improve paint adhesion) and with heavy use of undercoating and anti-corrosive oil treatment. The Amazon shared the wheelbase, tall posture and high H-point seating of its predecessor, the PV. In 1959 Volvo became the world’s first manufacturer to provide front seat belts as standard equipment — by providing them on all Amazon models, including the export models — and later becoming the first car featuring three-point seat belts as standard equipment. The Amazon’s handbrake location, outboard of the driver’s seat, was intended to accommodate subsequent bench seat models with column shift transmissions — which never materialised. Buyers began to receive the first cars in February 1957, and initial models were two-tone red and black with light grey roof, light grey with a black roof, followed by a dark blue with grey roof in 1958. Further iterations included the 121, the base model with a single carburettor 66 bhp engine, the 122S introduced in 1958 as a performance model equipped with a dual carburettor 85 bhp engine. The estate version was introduced at the 1962 Stockholm Auto Show, and Volvo manufactured 73,000 examples between 1962 and 1969. The Amazon estate featured a two-piece tailgate, with the lower section folding down to provide a load surface and the upper section that hinged overhead. The vehicle’s rear licence plate, attached to the lower tailgate, could fold “up” such that when the tailgate was lowered and the vehicle in use, the plate was still visible. This idea was used by the original 1959 Mini. In recent years a similar arrangement was used on the tailgate of the Subaru Baja. In 1966 the Volvo PV ended production, replaced by the Amazon Favorit, a less expensive version of the Amazon, without exterior chrome trim, a passenger-side sun visor or cigarette lighter, and with a three-speed rather than four-speed transmission — available in black with red interior and later white or black with red interior. The newer Volvo 140 was becoming the company’s mainstream model, and the last of the four-door 120 saloons were produced in 1967, the year which saw the launch of the 123GT, which was a Model 130 with high-compression four-cylinder B18B engine (from the Volvo P1800), M41 gearbox, fully reclining seats, front fog and driving lights (on some markets), alternator, fender mounted mirrors, special steering wheel, dash with a shelf and tachometer, and other cosmetic upgrades. In 1969 the displacement of the old B18 engine was increased and the engine was called the B20. The last Amazon was manufactured on 3 July 1970. By the end of production, 234,653 four-door models, 359,917 two-door models and 73,220 station wagons had been produced, of which 60% were exported; a total of 667,791 vehicles.

Popular in its day. but certainly rare now was this Volvo 360 GLT a model introduced first seen in 1976 as the 343 DL. DAF had already begun development of this car as a replacement for the Volvo (previously DAF) 66. It was fitted with a 1.4 litre Renault engine in the front and DAF’s radical Variomatic continuously variable transmission unusually mounted in the rear, helping weight distribution. To add to the appeal of the car and boost its sales, Volvo adapted the M45 manual transmission from the 200 series to fit in place of the CVT, and was sold alongside the CVT models from 1979. The CVT continued to be offered but sold in ever more marginal numbers; down to 200 per year in Sweden in the late 1980s. A five-door model, the 345, was added in August 1979. The extra doors added 30 kg (66 lb); other modifications included better brakes, a slightly larger track due to wider rims, and interval wipers. During 1980 larger wrap around bumpers were introduced. In 1981 another engine option was added to the range, the Volvo designed B19, only available with the manual transmission. A revised bonnet, grille and front lamp arrangement and slightly different wings signalled a facelift in summer 1981, which also gave the car a new dashboard and revised interior. From having been mostly a DAF design, the dashboard gradually became more aligned with the design of other Volvos over the years. The overall length crept up to 4,300 mm (169 in). The third digit designating the number of doors was dropped from model designations in 1983. The more powerful 360 arrived that year with two 2.0 litre engine choices, the 95 PS B19A and the 115 PS B19E, also from Volvo. These were four-cylinders and not sixes as implied by the name; it was used to “give the new model a stronger profile in the Volvo range.” This 2-litre 360 model was available in five-door and three-door hatchback form, with four-door saloon models added in 1984. Trim levels were GL, GLE, or GLT, depending on output and specifications. In 1985, the 300 Series received a major facelift. Amongst other small changes, (optionally body coloured) wrap-around bumpers with the indicator repeaters attached to them were fitted. The taillights were also redesigned. Instrumentation changed from Smiths units to VDO. The older Volvo redblock engines in the 360 were upgraded to the low friction B200 unit. Capacities and outputs remained much the same. The carburettor version was designated B200K and the Bosch LE-Jet fuel injected version is known as the B200E. From 1987 on, incremental improvements in features and emissions control were made. The newly designed power steering from the new Volvo 480 became available as an option for the 1988 model year, while rust protection was improved with increased use of galvanized steel. Production of the 360 came to an end in 1990, while the 340 was discontinued in 1991, despite the fact it had supposedly been replaced by the Volvo 440 in 1987. The last ever car of the Volvo 300 series (a white Volvo 340) rolled off the production line on 13 March 1991, three years after the launch of the 400-series. Sales began at a low level, not helped by the absence of a manual transmission option, but gradually increased as the lineup expanded. 300-series cumulative production broke the 100,000 barrier on 12 December 1983, with the total reaching 102,000 before the end of the year. The 100,000th car, finished in white, was donated to the Dutch Red Cross. 66,207 360 sedans were built in total, along with 79,964 340 sedans, for a total of 146,171 four-door sedans in the 300-series.

OTHER DISPLAYS and ATTRACTIONS

STREET SHOOTOUT

Taking place in a part of the track that was not being used for the main event was the Street Shootout where a number of heavily modified cars, many of them based on US models, were burning lots of rubber in their dramatic displays.

JAGUAR LAND ROVER EXPERIENCE

Located among the Car Club displays, once more, Jaguar Land Rover had a display with a surfaced area used to demonstrate the popular F Type in action, as it was drifted around the track. It was a popular attraction, with long queues of people waiting for their turn in the passenger seat. Some of the latest additions to the road car range were displayed here, including the Range Rover Velar.

THE JET VILLAGE

Located right at the heart of the event, the JET Village Green was where you would find many of the other attractions of the event, as this was a place to relax, get a bite to eat or even something to drink from the Classic’s very own pop-up pub, the Scarf & Goggles. There was Wi-Fi, a big screen to follow the racing, traditional fun fair rides, the ever-popular racing simulators (this year for juniors as well as seniors), rides on the JET Big Wheel, crazy golf, the chance of a selfie with the JET mascot ‘Philup’, plus a plethora of other fun and games to keep all ages amused. This historic Spitfire was a popular attraction in the area.

This splendid machine is the very first tanker that was used by the JET company. JET was established in 1954 by John Willy ‘Bill’ Roberts. Bill, who was born in Halifax in 1898, started working part-time in the mills at the age of 11. By the age of 12 he was working full-time and studying economics. Bill Roberts served in the First World War and though barely out of his teens, he was keen to get on. One story typifies his character. After complaining that the sergeants were getting roast beef instead of stew like the men, he was told, ‘If you like roast beef, work to become a sergeant and you’ll be entitled to it.’ Before long Sgt. Bill Roberts was enjoying roast beef too. in civilian life, Bill started working for a chemical company. His business acumen helped make the company, Trent Oil Products, a formidable oil distributor in the competitive years between the wars. JET In 1954 when the petrol supply was de-regulated, Bill set up Jet Petroleum Ltd – a name inspired by ‘JET’ – the prefix of vehicles registered in Rotherham, Yorkshire and his first tanker, JET 855. Soon Bill was seeing demand from the smaller independent retailers around Yorkshire for an alternative supplier to the major brands which effectively controlled the supply and price of petrol. He began selling fuel at lower prices and the JET network started to grow as motorists began searching out these lower price outlets. In 1999 the rusting skeleton of JET 855 was discovered in a farmers field by an Oxfordshire haulier. In a fitting way to celebrate 50 years of the JET brand, the vehicle has now been restored to its former glory. The restoration of JET 855 is an amazing story of coincidences and uncompromising dedication.

MASERATI

One of few manufacturers who had a presence here were Maserati, who have examples of their current range, the Ghibli, Levante and GranTurismo all on show.

MIKE BREWER

In action on a large stage several times a day, every day, was Mike Brewer, holding his popular “Car Clinic”.

OTHER CARS

This striking machine is the 1933 Barnato-Hassan Special. Built around the 6¼-litre engine of ‘Old No 1’, with a unique frame of Walter Hassan’s design, the Barnato-Hassan Special is one very special Bentley. The special’s most frequent driver in period was Oliver Bertram. When its engine broke at the 1934 500 Miles Race, the car was fitted with a new 8-litre unit and with that Bertram set a new Brooklands lap record of 142.60mph, later beaten by Cobbs’ Napier-Railton. It was rebuilt as a single-seater with central steering in 1936.

First seen at the 2017 Top Marques event in Monaco, the second car that the David Brown firm produced is inspired by Sir Alec Issigonis’ classic icon, which David Brown’s design and engineering teams have then worked on meticulously to remaster the vision to create a contemporary design classic. De-seamed, strengthened and sound-proofed throughout, Mini Remastered not only looks subtly different, but has improved structural integrity and comfort. The clean and elegant lines of Mini Remastered are brought to life with sculpted body-coloured wheel arch extensions and centrally-mounted exhaust outlets, providing the car with a classic, yet dynamic stance. A hand-applied paint process that lasts for four weeks, ensures that every car is not only flawlessly finished but protected for a lifetime. Finished with beautiful badges which are handcrafted using traditional die-sinking enamel techniques, every detail has been considered. Jewel-like LED rear light clusters and indicators, framed by bespoke aluminium surrounds, alongside the signature aluminium grille take inspiration from the David Brown Automotive design language, whilst chrome bullet-style door-mounted wing mirrors with integrated LED puddle lamps bring function and style together. None of this comes cheap, though. Prices start from £75,000.

IN THE PITS and PADDOCKS

There is so much to see among the Car Club displays that it easy to neglect the racing. And that would be a huge opportunity missed. As well as finding a good vantage point around the circuit to watch, with some of the grandstands being open, you can also get up close to the action by going to the pits. There is pretty much unrestricted access, so you can wander around and get really close to the cars as they are being worked upon in readiness for track action. Both the old and the new international pits are used during the event, which does help to address the challenge of quite how you cram in everything that is needed for such a busy program over 3 days. Whilst you can walk down to the International pits, it is a long walk, and it is much better to take one of the frequently-operating shuttle buses. You do need to allow quite a but of time for the inevitable queues that form at either end, and of course once there, you will be entranced by all that is there to see. You do always need to remember that the historic racing program is not confined to this event, so many of the competitors and teams entered will be packing up as soon as their last race is done here, as they need to get on the road towards wherever they will be competing next. That means that by Sunday, the pits are not quite as congested, with several of the entrants having departed. This time I did make a number of sorties down to the international pits, so I could take in more of the activity that was going on there.

The pit area is big, and you can quite see why some value having some means of wheel transport to get around the area and potentially out to other areas of this massive site. Moped and scooters are used by some, but cars also feature including this classic Mini Moke and a rather fabulous BMW Isetta.

And so to the race cars. There were well over 1000 of them featuring over the three days, with the oldest being a 1923 Bentley and the most recent a 2005 BTCC Honda Integra. More than 750 drivers were signed up to appear, hailing from 25 different countries. There were no fewer than 22 races packed into the schedule. Some were short 20 minute bursts of activity, whereas others lasted longer, with a total of 31 hours of track action crammed into the schedule. You could spend most of your weekend watching the activity on track, and every year, I vow that I should do more of that than I do, but with so much to see, I never do, and so the most I end up seeing of many of the cars that are competing is when they are in the pits either before or after their races. Presented here are just a small subset of the cars that competed.

JAGUAR XJ220 CELEBRATION

Centrepiece of the International Pits was something very special: what is probably the largest ever collection of Jaguar XJ220 cars that you will ever see, with 42 of them assembled in a record-breaking reunion to mark the 25th birthday of what was once the fastest production car in the world. The dramatically-styled, mid-engined, two-seater supercar was introduced in 1992, with its top speed of 212.3mph making it Jaguar’s quickest road-going car – an accolade it still holds to this day. Just 271 XJ220s were manufactured in tandem with Jaguar’ competition partner Tom Walkinshaw Racing between 1992 and 1994 – each priced at an eye-watering £470,000 – and such is their rarity that no more than a handful have ever been seen together. Until today. Curated by renowned XJ220 specialist Don Law Racing, the unprecedented display of 42 XJ220s from all around the globe helped to create a spectacular on-track parade led by David Brabham, riving the very #50 car (kindly loaned by JD Classics) in which he claimed GT class victory at Le Mans in 1993 before being controversially disqualified – with Walkinshaw’s widow Elizabeth alongside.

Indeed, all four competition specification XJ220Cs in existence were on show at Silverstone, including the #52 team car which had come all the way from Japan just to be part of the anniversary celebrations. The XJ220C competition version of Jaguar’s remarkable mid-engined two-seater was launched just months after the first customer cars were delivered in June 1992 (hence the 25th birthday celebrations) and a three-car TWR JaguarSport factory-backed team was entered into the increasingly-important GT class at the following year’s running of the famous French endurance classic. Numbered 50, 51 and 52, they were raced respectively by David Brabham, David Coulthard and John Nielsen; Armin Hahne, Win Percy and David Leslie plus Paul Belmondo, Jay Cochran and Andreas Fuchs. Both the #51 and #52 cars succumbed to engine issues but the #50 car survived to finish the 24 Hours in an impressive tenth overall and take top class honours in the key GT category. The XJ220Cs had been running under appeal for not racing with catalytic converters. They were later deemed to be totally legal as they had been entered under American IMSA regulations, though a month later the French still controversially disqualified the victorious Brabham, Coulthard and Nielsen ‘winner’ as the paperwork for the original appeal had been wrongly filed. Come the stunning XJ220 track parade, the #50 Le Mans car was rightly back on pole position, flanked by #51 and #52. The first is owned by renowned classic car dealer and race preparation experts JD Classics, while the other two have recently been restored to their respective former glories – and racing colours – by XJ220 specialists Don Law Racing.

“I’ve never seen so many 220s in one place,” Brabham remarked. “I remember when the race programme all came about and Tom asked me to be part of it. It was such an epic feat to even get to the first race and to go to Le Mans in reasonable shape, and of course, at the end of the day we finished first on-track. “To be involved as one of the lead drivers was very cool. It was a brilliant time, and seeing this car again always brings back memories. It’s a special day to see so many 220s turn up.” Others to participate in the evocative showcase included Tiff Needell – who similarly raced an XJ220 at Le Mans, in 1995 – and Don Law, the undisputed doyen of the marque’s most famous supercar and the mastermind behind this extraordinary gathering. “What a spectacle, with the three Le Mans cars at the front in an arrow formation and all the other cars behind – absolutely incredible,” enthused Law, who drove the XJ220-powered van – originally used as a test mule – at the rear of the parade. “We could never have dreamt that Mr. Fukuda would bring his Le Mans car all the way from Japan in an aeroplane, but such is the passion for these cars that people have travelled from all over. I think Liz Walkinshaw was very emotional today. The XJ220 has been a big part of a lot of people’s lives.” Although originally conceived to feature a V12 engine plus four-wheel-drive, to meet emissions legislation and performance targets, the showroom XJ220 model arrived with a 3.5-litre, twin-turbocharged V6 developing 542bhp, delivered to the rear transaxle via a five-speed manual gearbox.

Amongst the invited guests with close ties with the illustrious car’s design, development and on-track success were erstwhile Jaguar Engineering Director Jim Randle and senior sports car designer Keith Helfet, the brains behind the XJ220’s stunning and ageless styling. Both were leading lights in the famous ‘Saturday Club’, whose members secretly built the original concept car in their spare time. “Today certainly brought back a few memories,” reflected Randle. “It’s a fitting tribute to the 12 of us who put together this extremely special car, and although sadly some of them are not around anymore, it’s great to see a few here today. It was a crazy programme, and if my bosses at Jaguar had known what we were doing, I’m sure we would have been fired!” “I knew this would be a memorable day, but I couldn’t have imagined the scale and how emotional I would be, seeing all these cars and being part of the convoy around Silverstone,” added Helfet. “It really is one of the standout days of my life and career. The car’s power is something else. I hardly got the chance to try it today, but when you unleash it and the turbo kicks in, it’s really visceral – what a feeling!”

SUPERCARS

Also in the centre of the long International PIt area was a display of other classic and more modern supercar and hypercars. This was organised by the Supercar Drivers Club, who brought all the cars in under convoy on the Friday. Later that day they were able to participate in a parade lap around the circuit.

Alvis TE21: Conceived in 1956, this design was launched as the TD21, and it was quite a departure from the lovely, but rather “post-war” TC21. However, on its arrival in dealer’s showrooms, it quickly set about changing established views of the Alvis. Following the loss of coachbuilders Mulliner and Tickford (who were now tied to other companies), Alvis turned to the Swiss coachbuilder, Graber whose tradition of producing sleek, modern and very elegant saloons and dropheads proved a good fit in terms of the way Alvis saw their future. Graber first presented this new style to the Alvis board in late 1957 who were very impressed with the Swiss company’s flowing design and commissioned the body to be built on the new TD chassis. To ease logistical problems, Park Ward of London, built the Graber designed bodies in the UK. The Alvis Three Litre TD21 Series I was produced between the end of 1958 and April 1962, and was powered by the TC’s 2993 cc engine, uprated by 15bhp to 115 as a result of an improved cylinder head design and an increased compression ratio. A new four-speed gearbox from the Austin-Healey 100 was incorporated, while the suspension remained similar to the cars predecessor, independent at the front using coil springs and leaf springs at the rear, but the track was increased slightly and a front anti-roll bar added. From 1959 the all drum brake set up was changed to discs at the front retaining drums at the rear. In April 1962, the car was upgraded with four wheel Dunlop disc brakes in place of the disc/drum combination, aluminium doors, a five-speed ZF gearbox and pretty recessed spotlights either side of the grille, these improvements coming together to create the TD21 Series II. The car would be updated in 1963 to create the TE21, with its distinctive dual headlights proving a recognition point, and the later TF21, continuing in production until 1967 at which point Alvis ceased car manufacture.

Bugatti Veyron

Ferrari 275 GTB

Ferrari F40

Ferrari 488 GTB

Pagani Zonda

Porsche 918

Friday saw no less than 15 practice sessions, all of which ran smoothly. There were then the competitive races on Saturday and Sunday, with a chance to see the enormous variety of competing cars in action.

FORMULA FORD Ford 50 presented by Historic Motorsport International

Saturday kicked off with Formula Ford, and in fitting fashion, the world’s pre-eminent junior single-seater series celebrated its 50th anniversary with a traditional Silverstone slip-streaming spectacle, as five drivers energetically disputed the Formula Ford 50 presented by Historic Motorsport International spoils. Seasoned competitor Michael O’Brien fought back from an early error to triumph at the end of a terrific tussle, with the similarly delayed Ed Thurston carving through to second. Callum Grant produced a heroic recovery from a costly spin to finish sixth. There was a second race, on the Sunday. and this saw Michael O’Brien replicate his Saturday success, as he expertly navigated a track surface still damp from overnight rain. Despite seeing his early lead erased by a safety car intervention, the Merlyn Mk20A driver maintained his composure and had enough pace to head off a challenge from reigning champion Callum Grant in the closing stages, with Benn Tilley getting the better of Ed Thurston in a last lap tussle over third.

Commander Yorke Trophy for HISTORIC FORMULA JUNIOR

Renowned Formula Junior exponent Sam Wilson doubled up in the Commander Yorke Trophy for Historic Formula Junior in what was another capacity, 50 car-plus contest. Wilson replicated his results from last year’s event, although he was made to work hard by the ever-present Andrew Hibberd as the pair sped clear in a class of their own. The single-seater star later completed a hat-trick of triumphs in the Maserati Trophy for HGPCA Pre ’66 Grand Prix Cars.

Stirling Moss Trophy for PRE ’61 SPORTS CARS

Former Silverstone chief instructor Chris Ward demonstrated the benefits of track knowledge to dominate the Stirling Moss Trophy for Pre ’61 Sports Cars behind the wheel of his Lister Costin, with Oliver Bryant threatening to challenge before being forced into retirement, promoting Rob Barff to the runner-up spot.

John Fitzpatrick Trophy for UNDER 2 Litre TOURING CARS

Tin-top legend Steve Soper looked set to add another success to his impressive career CV in the John Fitzpatrick Trophy for Under 2 Litre Touring Cars (U2TC), only for late misfortune to hand victory to Mark Sumpter in a similar Ford Lotus Cortina.

Royal Automobile Club Tourist Trophy for HISTORIC CARS (Pre ’63 GT)

The blue riband Royal Automobile Club Tourist Trophy for Historic Cars (Pre ’63 GT) was arguably the highlight of Sunday morning – with a dramatic final twist in the tail for good measure. Lukas Halusa overhauled early leader James Cottingham behind the wheel of his unique Ferrari 250 GT SWB ‘Breadvan’, and went on to comfortably control proceedings up to the final few laps. Despite losing a chunk of time a handful of laps from home, Halusa remained in charge and finished first-on-the-road – before being handed a retrospective 45-second penalty speeding in the pit-lane, relegating the scarlet Ferrari to fifth. Halusa’s misfortune meant the duel for the runner-up spot between Simon Hadfield and Patrick Blakeney-Edwards was in actual fact the battle for victory. When Hadfield took over in the Aston Martin DP212 ‘project car’, the car was languishing down the order, and notwithstanding a brace of off-track excursions, a string of fastest laps saw him charge back through the field to pip the AC Cobra within sight of the chequered flag. An interesting entry in the race was European Parliament Brexit Co-ordinator Guy Verhofstadt, who was spotted with both the UK’s Secretary of State for Brexit, David Davis, and Event Director, Nick Wigley, in the Silverstone Classic Heritage Paddock.

Royal Automobile Club Woodcote Trophy for PRE ’56 SPORTS CARS

Making up for his disappointment in the previous race, Blakeney-Edwards produced a tremendous performance to triumph in the following Royal Automobile Club Woodcote Trophy for Pre ’56 Sports Cars, with the Cooper T38 he shared with Frederic Wakeman leapfrogged the Jaguar D-type of the Pearson brothers during the pit-stops to take the lead. John Pearson subsequently fell back into the clutches of the hard-charging Chris Ward, who stole second place in the closing stages in his Cooper Jaguar T33.

Kidston Trophy for PRE WAR SPORTS CARS

The Kidston Trophy for Pre War Sports Cars, meanwhile, served up a superb David vs. Goliath duel between the ‘GO 52’ Talbot 105 behemoth of Gareth Burnett and Frederic Wakeman / Pat Blakeney-Edwards in the nifty and nimble Frazer Nash Super Sports. A shortened race it might have been following an early safety car intervention, but it was an epic encounter as the Talbot ultimately got the verdict by a scant 0.162s.

There were a large number of 3 Litre Bentley models entered for this race, and a splendid sight they made. The 3 Litre was the company’s first model, first shown in 1919 and made available to customers’ coachbuilders from 1921 to 1929. It was conceived for racing. The Bentley was very much larger than the 1368 cc Bugattis that dominated racing at the time, but double the size of engine and strength compensated for the extra weight. The 4000 lb (1800 kg) car won the 24 Hours of Le Mans in 1924, with drivers John Duff and Frank Clement, and again in 1927, this time in Super Sports form, with drivers S. C. H. “Sammy” Davis and Dudley Benjafield. Its weight, size, and speed prompted Ettore Bugatti to call it “the fastest lorry in the world.” The 3 Litre was delivered as a running chassis to the coachbuilder of the buyer’s choice. Bentley referred many customers to their near neighbour Vanden Plas for bodies. Dealers might order a short cost-saving run of identical bodies to their own distinctive design. Most bodies took the simplest and cheapest form, tourers, but as it was all “custom” coachwork there was plenty of variation. The 2,996 cc straight-4 engine was designed by ex-Royal Flying Corps engineer Clive Gallop and was technically very advanced for its time. It was one of the first production car engines with 4 valves per cylinder, dry-sump lubrication and an overhead camshaft. The four valve SOHC Hemi design, with a bevel-geared shaft drive for the camshaft, was based on the pre-war 1914 Mercedes Daimler M93654 racing engine. Just before the outbreak of the war Mercedes had placed one of the winning Grand Prix cars in their London showroom in Long Acre. At the suggestion of W.O. Bentley, then being commissioned in the Royal Naval Air Service, the vehicle was confiscated in 1915 by the British army, dismantled at Rolls-Royce and subjected to scrutiny. A notable difference to both the Mercedes and the aero engines was the cast-iron monobloc design, and the fully Aluminium enclosed camshaft, which greatly contributed to its durability. But having the valve-head and block in one-piece made for a complicated and labour intensive casting and machining. This was a feature shared during that time by the Bugattis which the car was later to compete with. The engine was also among the first with two spark plugs per cylinder, pent-roof combustion chambers, and twin carburettors. It was extremely undersquare, optimised for low-end torque, with a bore of 80 mm and a stroke of 149 mm. Untuned power output was around 70 hp, allowing the 3 Litre to reach 80 mph. he Speed Model could reach 90 mph; the Super Sports could exceed 100 mph. A four-speed gearbox was fitted. Only the rear wheels had brakes until 1924, when four-wheel brakes were introduced. There were three main variants of the 3 litre and they became known by the colours commonly used on the radiator badge. There was a definite rule controlling badge colours but astonishingly it has since been established that given “special circumstances” the factory would indeed supply a “wrong” colour. Blue label was the standard model with 117.5 in wheelbase from 1921 to 1929 or long 130.0 in wheelbase from 1923 to 1929. The Red label used a 5.3:1 high compression engine in the 117.5 in wheelbase chassis and was made from 1924 to 1929. The Green label was made between 1924 and 1929 and was the high performance model with 6.3:1 compression ratio and short 108 in wheelbase chassis. 100 mph performance was guaranteed. As well as 3 Experimental cars, Bentley produced 1088 examples of the 3 litre, and the Speed Model numbered 513 and there were 18 Super Sports.

FIA Masters HISTORIC FORMULA ONE

In the afternoon, Saturday star Jonathan Kennard in the pole-sitting, Warsteiner-liveried Arrows A3 was unable to hold off the charging Williams FW07C of Nick Padmore as the FIA Masters Historic Formula One race progressed, finding himself forced to settle for a close second place. Young gun Michael Lyons completed the top three in a similar Williams.

Mansell’s triumphant Williams FW14B chassis hasn’t raced since its hugely popular home win in 1992. However, earlier in 2017 it returned to Silverstone, the location of that stirring victory, to make a reappearance at the Silverstone Classic Media Day. It has subsequently been fully restored by Williams Heritage, the team’s increasingly active division which preserves, showcases and runs a fleet of cars dating back to the company’s birth in 1977. Underlining the growing importance of this dedicated Heritage department, it is headed by Sir Frank’s son Jonathan Williams and managed by long-time Williams team manager and engineer Dickie Stanford. Today, revived and re-armed with its glorious-sounding Renault V10 engine, Mansell’s legendary ‘Red Five’ lives again. Proudly displaying its iconic yellow, blue and white livery, the all-conquering FW14B was not only be on public display here, but also provided visitors with some dramatic high-speed demonstration laps during the lunch breaks on both Saturday and Sunday, this time with experienced GP2 and sportscar driver Nick Yelloly at the wheel.

Having played such an important role in Williams’ remarkable history – which has seen the locally-based team amass no fewer than 114 grand prix victories en route to nine Constructors’ and seven Drivers’ World Championships – Silverstone was the perfect venue for its ruby anniversary celebrations. Williams’ very first grand prix win came at the super-fast Northamptonshire venue in 1979, when Swiss star Clay Regazzoni took the chequered flag – a victory that opened the floodgates for further Williams success over the following years, with Mansell, Alain Prost, Damon Hill and Jacques Villeneuve all triumphing at Silverstone.

Gallet International Trophy for CLASSIC GT CARS (Pre ’66)

The heavens opened properly for the Gallet International Trophy for Classic GT Cars (Pre ’66), giving David Pittard the opportunity to truly take the fight to bigger-engined rivals in his little Lotus Elan 26R. The British GT race-winner scythed through the spray to snatch the lead from eighth on the grid before the pit-stop driver change, but ultimately, it was Oliver Bryant in the 1964 AC Cobra that held off Roger Wills, Andrew Haddon and Jason Minshaw in a thrilling finish that saw the top four blanketed by less than two seconds.

Maserati Trophy for HGPCA Pre ’66 GRAND PRIX CARS

The Maserati Trophy for HGPCA Pre ’66 Grand Prix Cars delivered a superb scrap between Jon Fairley in his 1964 Brabham BT11/19 and Sam Wilson’s older Lotus 18 372 – resolved in favour of the former – with an equally good battle for earlier front-engined car honours pitting Julian Bronson’s brutal Scarab Offenhauser against the unique Maserati TecMec piloted by Tony Wood, whose challenge was scuppered by a ten-second false start penalty.

FIA MASTERS HISTORIC SPORTS CARS

The FIA Masters Historic Sports Cars contest was rather dramatic and ended behind a safety car after several damaged cars were abandoned around the circuit. Martin O’Connell’s fast-starting Chevron B19 burst past the front row sitters to lead the pack. Behind him, a fierce battle for second developed between Dan Gibson (Lola T70 Mk3b) and Nick Padmore’s Chevron B19. Just as Padmore appeared to have taken the place, the cars touched with the Chevron spearing into the barriers.

GROUP C

Saturday’s action concluded with the Group C twilight race, although twilight descended rather quickly into darkness in the prevailing conditions. Steve Tandy and Mike Wrigley indulged in an old Spice battle at the front of the field, before a brace of spins for the latter settled the result. The second Group C contest of the weekend was again affected by rain, with the field starting on slick tyres but obliged to pit for wet weather rubber as the precipitation intensified. When the race was rejoined, the ex-Michael Schumacher ‘Silver Arrows’ Mercedes C11 held a commanding lead, with driver Kriton Lendoudis even able to afford a couple of off-track excursions on his way to victory. Following a pit-stop delay, yesterday’s winner Steve Tandy charged back through to snatch the runner-up spoils.

JET SUPER TOURING CAR TROPHY

The JET Super Touring Car Trophy featured a split grid for Super Tourers and older Group A machinery. For the first time ever both JET Super Touring Car Trophy showdowns taking place on the Saturday and Sunday afternoons of the Classic featured not one, but two stellar grids racing simultaneously. The first will be filled with high-tech Super Tourers, the second with Group 1 and Group A racing saloons, including a large number of legendary RS500s. The focus on the famed RS500 – the competition version of the original Sierra RS Cosworth – is highly significant, too, as the all-conquering turbocharged winged icon was first launched in July 1987 and thus celebrated its 30th anniversary milestone at the Classic. Introduced by Ford to put some much-needed sparkle into its humdrum showroom Sierra, the three-door RS500 is rated by many to be the world’s most successful competition car of all times. With its signature whale-tail rear spoiler and Cosworth inspired 500+ bhp power pack, in its era the seminal Sierra was virtually unbeatable totally dominating Group A touring car championships right around the globe. Perhaps its greatest triumph came at the 24 Hours of Spa in 1989 when Gianfranco Brancatelli, Win Percy and Bernd Schneider took top honours in their Eggenberger Motorsport entered RS500. Today that victorious Bastos liveried car resides in far away New Zealand but it will be coming to Silverstone for a very special reunion at the Classic. Once again, multiple touring car champion Brancatelli will be back behind the wheel and team principal Rudi Eggenberger will be back on the pit wall. Welsh racer Karl Jones is another reliving his RS500 glory days at Silverstone this summer. Back in the late eighties, he raced a Duckhams branded Sierra (below middle right) in the BTCC, scoring several podium finishes. Come July, Jones will be sharing a drive with Paul Linfoot in the striking Lui liveried RS500, (below middle left) formerly raced successfully in the 1988 German DTM championship by twice Le Mans winner Manuel Reuter. As befits a 30th birthday party, Brancatelli and Jones were joined by a number of other notable RS500 revellers. Those already confirmed include Andrew Kirkley in his ex-Laurence Bristow CAM Shipping liveried Sierra, Mark Wright’s iconic Texaco liveried machine plus the yellow Dunlop RS500 as raced in the Japanese Touring Car Championship.

In total, the amazing and unprecedented line-up featured more than 50 iconic entries spanning more than 25 years of glorious touring car racing history, all still displaying their evocative period liveries. There were Group 1 Capris and Rover Vitesses from the late seventies and early eighties, Group A favourites such as the mighty RS500 and impressively rapid BMW M3s from the late eighties plus, of course, the more extreme Super Tourers from the nineties. After a hectic joint qualifying session on Friday, the field then was split into two individual grids for the weekend’s pair of stand-out races. The more modern Super Tourers lined up in front and took the first rolling start. Then, 30 seconds later, the combined Group 1 and Group A grid flashed across the line thus providing spectators with two spectacular showdowns running in parallel on the full Silverstone Grand Prix circuit.Following a typically hectic tin-top start that saw cars scattering in all directions, Jason Minshaw dominated the Super Tourer element behind the wheel of his ex-Rickard Rydell title-winning Volvo S40. Behind, a fantastic scrap saw Mark Wright narrowly defeat former European Touring Car Champion Gianfranco Brancatelli in a battle of the flame-spitting Ford Sierra RS500 Cosworths, with Soper and ‘Gentleman Jim’ Richards engaging in a similarly entertaining duel further back.

The JET Super Touring Car Trophy appropriately brought the curtain down on another super-successful Silverstone Classic, with Saturday star Jason Minshaw and James Dodd waging a titanic duel for glory on a drying track. Dodd’s Honda Accord ultimately got the better of the ex-Rickard Rydell Volvo S40, as former European Touring Car king Gianfranco Brancatelli winning the simultaneous Group A race in his flame-spitting, Spa 24 Hour-winning Ford Sierra RS500.

One car that travelled to Silverstone from even further afield was the striking, shark-nosed BMW 635 CSi, the first time that the striking JPS 635 CSi has ever been seen outside its native Australasia, which made the trip to be piloted in both JET Super Touring Car Trophy races by its original driver, ‘Gentleman Jim’ Richards – one of which saw the New Zealander indulge in an entertaining wheel-to-wheel duel with fellow tin-top hero Steve Soper. As a seven-time winner of the legendary Bathurst 1000 race and multiple Australian touring car titles under his belt, Richards needs little introduction to motor sport aficionados and his presence at the Classic will be special. Richards and the stunning BMW 635 CSi first joined forces in 1983 racing for the renowned Frank Gardner Racing team. Back then, Australia had its own Group C touring car regulations permitting more freedom than the more widely adopted Group A rulebook. Although the ‘Black Beauty’ won the hearts of many fans, at first success was limited against an opposition armed with more powerful V8 propelled Fords and Holdens. However, when Australia finally adopted the international Group A formula in 1985, the combination proved utterly unstoppable – Richards winning seven of the ten rounds and, with them, the inaugural Australian Touring Car Championship title. In a golden year for JPS Team BMW, Richards also went undefeated in the AMSCAR Series and then added the Australian Endurance Championship crown by winning five out of six races. The illustrious BMW was still in this less tuned Group A specification when acquired by its current owner, New Zealand collector Peter Sturgeon. However, Richards and Pip Baker, who had worked with Frank Gardner back in the day, convinced Sturgeon to put the 635 back into its more dramatic Group C guise. Pip adopted the project and it took him almost 18 months to complete. It was worth all the effort, though, as the final result is utterly amazing,” enthused Sturgeon who is now flying the car half way round the world to be at the Silverstone Classic. “The sound of the straight six, twin-cam engine revving at more than 8000rpm is something all petrol heads should hear,” he continued. “In Group C form, this is the one and only 24-valve engined BMW 635 ever raced and to have Jim back driving it is very, very special.” The JPS-liveried car was brought over by its owner Peter Sturgeon, who was rewarded for his outstanding endeavour with the Stuart Graham ‘Scarf and Goggles’ trophy. Introduced in 2015 to mark the festival’s 25th anniversary, the award is now presented annually to what is judged to be the most admired car competing at the Classic. Sturgeon received the accolade from Graham, one of the inspirations behind the original Classic event staged at Silverstone and a TT winner on both two wheels and four.

Also rather special was this Ford Capri RS3100, being one of just three works cars built for the 1974 European Touring Car Championship and was a winner at both Jarama and Hockenheim. Drivers in period included Niki Lauda, Jochen Mass and Klaus Ludwig.The Capri is equally special being one of just three works cars built for the 1974 European Touring Car Championship and was a winner at both Jarama and Hockenheim. Drivers in period included Niki Lauda, Jochen Mass and Klaus Ludwig.

JAGUAR CLASSIC CHALLENGE

The new-to-the-bill Jaguar Classic Challenge was an instant crowd-pleaser, with no fewer than 35 eye-catching E-types as well as a mix of other models including saloon cars producing a spectacular showpiece as they were pushed right to their limits and occasionally beyond. The low-drag example of Julian Thomas grabbed the early lead but its glory was short-lived – a technical issue leading to its retirement. Victory finally went to Gary Pearson from the fast-finishing James Dodd.

Silverstone Classic CELEBRITY CHALLENGE

One of the highest profile races of the event was this one, which saw 26 celebrity drivers from the worlds of sport showbiz and the media, all in Austin A30 and A35s competing for honours. The stellar big-name line-up featured no fewer than five gold medal-winning athletes, topped by Jason Kenny CBE who, along with fellow track cyclist Sir Chris Hoy, is Britain’s most successful Olympian having amassed no fewer than six gold medals. Other standout sportsmen included 500cc World Motorcycle Champions Wayne Gardner and ‘Fast’ Freddie Spencer plus three-time boxing World Champion, Carl Froch. Famous musicians were out in force, too – notably Howard Donald from chart-toppers Take That and Brian Johnson, who fronted rock legends AC/DC for over 35 years. Crime writer Peter James is another best-seller on the grid alongside a host of TV personalities including Ant Anstead (Wheeler Dealers), Tiff Needell (ex-BBC Top Gear) and Theo Paphitis (Dragons’ Den). Some had extensive racing experience whilst others had had to get a racing licence just so they could take part in the event. Celebrities were split into five teams representing their professions, and each team was mentored by a renowned racing driver. Three of these are former F1 aces – Mark Blundell, Martin Donnelly and Rupert Keegan – the other two are touring car heroes: Anthony Reid and Steve Soper. Those teams were Screen Stars, Bike Racers, Sky Sports Legends, Rocking & Racing and Going for Gold. Led by former Formula 1 ace and Le Mans winner Mark Blundell, the winning team included Dragon’s Den host Theo Paphitis, Wheeler Dealers presenter Ant Anstead, BBC Radio 2 sports presenter Vassos Alexander, Sky Sports F1 pundit Tony Jardine and former Top Gear anchor Tiff Needell. Between them, the speedy sextet helped towards raising £10,000 for the event’s official charity partner, Prostate Cancer UK. Their victory did not come easy, however, with the race staged in increasingly difficult conditions as early evening drizzle turned into rain to leave grip at a premium on the famous 3.6-mile Silverstone Grand Prix circuit – a particular challenge for many of the celebrity rookies making their track racing debut in the star-studded encounter. To add to the spectacle, all 26 entrants were behind the wheel of equally-matched Austin A30s and A35s kindly provided by members of the HRDC (Historic Racing Drivers’ Club) Academy, who had their own race on the Sunday. Following a short familiarisation and afternoon qualifying session held under sunny skies, the rain began to fall as the cars took to the track for the early evening race, with a brief red flag intermission and safety car re-start adding to the drama. In such tricky conditions, it was no surprise that the experienced team captains came to the fore, as Blundell, fellow ex-grand prix driver Martin Donnelly and touring car legends Steve Soper and Anthony Reid diced furiously at the front, exchanging positions with brio. In a four-car slipstreaming thriller, it was Soper that prevailed, with a last lap spin for Reid elevating Donnelly to second and Blundell to third. Former Motorcycling 500cc World Champion Wayne Gardner came home ‘best-of-the-rest’ in fourth, with Jason Kenny CBE – Britain’s equal-most successful Olympic athlete and a man with a modicum of prior motor racing experience – finishing a commendable ninth. Take That’s Howard Donald claimed rookie bragging rights, ahead of multiple super-middleweight boxing world champion Carl Froch MBE and gold medal-winning Olympian Amy Williams MBE. Amongst those with hard luck stories to tell were former AC/DC front man Brian Johnson – who was unable to start the race after taking a tumble his car in qualifying – and all three Olympic gold medal rowers, with Jonny Searle MBE, Greg Searle MBE and Mark Hunter MBE all struggling to conquer the treacherous conditions. Thankfully, everybody emerged unscathed.

RAC DISPLAY

The RAC had a display here, and among the items on show was this Isetta from their historic fleet. Originating in Italy, the Isetta was constructed under licence in Britain from 1957 to 1964. BMW also obtained the rights to build the Isetta in Germany in the early 1950s. The vehicle had a short lifespan, with production ending in 1966. The Royal Automobile Club’s Isetta is a replica produced in 1960. The RAC, when it was owned by the Club, purchased six of the vehicles to combat congestion in London. The Isetta was not popular with patrol drivers, however, due to the limited space for both equipment and one passenger. The Isetta was used for carrying petrol and a heavy-duty battery in the equipment holder at the rear. The little single-cylinder engine of 298cc produced 13hp and gave a top speed of just 50mph.

Also here was an RAC Austin Seven Tourer, affectionately called the ‘Chummy’. These were manufactured from 1922 to 1939. It was marketed as an affordable car for ordinary families. By 1923 the car cost £165.00 to buy ‒ equivalent to £5,000 today. Our Chummy is powered by a 750cc, three-speed engine. The RAC logo, folding roof and traditional bodywork mean the vehicle is authentic to the last detail.

BY PADDOCK

Parked just outside the International Pit complex were a number of other interesting cars, including these:

Among the cars I had seen elsewhere on site were an Alfa Romeo Nuova Giulia, an Aston Martin DB2, a Bentley 4.5 litre and Porsche 356 and 993.

Alfa Romeo 6C 1750: In the mid-1920s, Alfa’s RL was considered too large and heavy, so a new development began. The 2-litre formula that had led to Alfa Romeo winning the Automobile World Championship in 1925, changed to 1.5-litre for the 1926 season. The 6C 1500 was introduced in 1925 at the Milan Motor Show and production started in 1927, with the P2 Grand Prix car as starting point. Engine capacity was now 1487 cc, against the P2’s 1987 cc, while supercharging was dropped. The first versions were bodied by James Young and Touring. In 1928, a 6C Sport was released, with a dual overhead camshafts engine. Its sport version won many races, including the 1928 Mille Miglia. Total production was 3000 (200 with DOHC engine). Ten copies of a supercharged (compressore, compressor) Super Sport variant were also made. The more powerful 6C 1750 was introduced in 1929 in Rome. The car had a top speed of 95 mph, a chassis designed to flex and undulate over wavy surfaces, as well as sensitive geared-up steering. It was produced in six series between 1929 and 1933. The base model had a single overhead cam; Super Sport and Gran Sport versions had double overhead cam engines. Again, a supercharger was available. Most of the cars were sold as rolling chassis and bodied by coachbuilders such as Zagato, and Touring. Additionally, there were 3 examples built with James Young bodywork. In 1929, the 6C 1750 won every major racing event it was entered, including the Grands Prix of Belgium, Spain, Tunis and Monza, as well as the Mille Miglia was won with Giuseppe Campari and Giulio Ramponi, the Brooklands Double Twelve and the Ulster TT was won also, in 1930 it won again the Mille Miglia and Spa 24 Hours. Total production was 2635. There were several of them here, with a variety of different bodies.

Fiat 8V: The Fiat 8V was first presented at the Geneva Motor Show 1952 as a high performance 2-seater aerodynamic coupé. The name derives from the 8 cylinder vee-form engine developed by famous Fiat engineer Dante Giacosa. The V angle was set at 70 degree for a compact arrangement. The engine was positioned just behind the front axle which make the Fiat 8V a front mid-engine sports car ensuring an optimized weight distribution. In his memory book, Dante Giacosa quoted ” The chassis, designated the “104”, was passed to Pininfarina so that the great coachbuilder could get out a preliminary study of the coachwork. This was all in 1950. Bono showed a a certain antipathy for the project and Valetta seemed to ignore it. For my part I was against it, because the automobile was too big and heavy for an engine of a mere two litres or little more, even if it had eight cylinders. The prototype with coachwork by Pininfarina confirmed expectations. It aroused little interest and was turned down for production by Fiat. In the meantime we had gone on perfecting the engine, awaiting approval for construction of the “106” sports model with independent suspension all around”. The “106” was an internally developed sports coupé designed internally that was finally introduced at the Geneva Motor Show and ended in limited production. It was the first Fiat with independent suspension front and rear. The engine which was the type 104.000, was available in two forms. One version produced 115 hp at 6.000 rpm. This was the 104.003. The second version, the 140.000, with different timing, carburation, and a 8,75:1 compression ratio, produced 127 hp at 6.600 rpm. The 8V distinguished itself in a few motor sport events such as the 6th Stella Alpina event, the Pescara 12 hours and the Monza Cup. In 1954 it was exhibited at the Turin Motor Show with a glass fibre body. Total 8V production was precisely 114 units with several model fitted with bodywork prepared by Zagato, Vignale, Ghia or Pininfarina.

Frazer Nash le Mans Replica

Once again, my expectations for this event were sky-high, and they were easily meet and in many respects exceeded. The decision to attend for all three days was a good one. I had wondered if the Friday would seem somewhat quiet compared to the buzz that pervades the entire site over the weekend, but that proved not to be the case. The Car Club displays are well populated on this day just as they are on the Saturday and Sunday, and the crowds of attendees are such that it felt little different to the other days. That being so, then I will have no hesitation in booking a three-day ticket for 2018, and would strongly encourage everyone else to do the same.