The picturesque and historic Shelsley Walsh location, home to the Midland Automobile Club, extended the range of events that it offers some time ago when a series of Breakfast Clubs were scheduled on a regular basis. They proved extremely popular and are now sell-out events where, even before Covid regulations required it, pre-booking became essential. It was a natural extension to this idea to look to run a regular evening event, taking advantage of the long hours of daylight in the summer months. “Cars in the Valley”, as the new event was christened was launched in May this year, scheduled for the first Thursday of the month. I attended the second such meeting, in June, and thoroughly enjoyed it. I vowed to try to return in July and my resolve to do so became ever greater when I saw that they had decided to give it in an Italian Car theme. That was all the incentive I needed to publicise the event to fellow Abarth Owners Club members, a good number of whom signed up, and did indeed come along. The weather gods looked kindly on the event meaning that there was a big turnout, with cars parked up in an overflow area as well as the paddock and lining the Start line. The Italian cars were grouped together and then everything else was accommodated wherever there was space. Some of the cars present were ones I had seen before, but there were plenty that were new to me, and the variety was excellent. Here is what I saw:
There was plenty of interest from Abarth Owners, with people coming from both the West Midlands and the newly formed Abarth Three Counties groups, so we amassed a good number of cars. Not surprisingly, the majority of them were 500-based cars, with a wide variety of different versions here, all of them different from each other in at least some detail, and that’s even before taking account of the modifications that many owners make. One of the most distinctive cars on this occasion was that of Michael Brown who has certainly given his car a distinctive look as well as the mechanical modifications he has made.
Whilst a sliding glass sunroof (Skydome in Fiat/Abarth parlance) was an option from inception, fans of open air motoring had to wait until Geneva 2010 for the launch of the 500C models, with a roll-back roof which provided the best of open-topped motoring and yet still with the rigidity of the regular body style. For the first few months these cars only came with the robotised manual gearbox, which limited the appeal in the eyes of some, but they also introduced us to the “bi-colore”, a series of two tone cars, with upper and lower halves of the body painted in different colours. It took us a while to get used to this, as no other production road cars had been painted like this for some time, but now this is seen as yet another of those marque defining attributes, and (perhaps with the exception of the rarely seen Rally Beige and Officina Red combination that would come for 2014) in the eyes of many this distinctive look enhances the appeal of the cars still further.
Having used the legendary 695 badging from the 1960s on the Tributo cars, at the 2012 Geneva Show, Abarth dusted off the 595 name that had been used on the less powerful of the Nuova 500 based cars of the same generation, and created two new versions which we should think of as Series 2 cars, the 595 Turismo and Competizione, both of which could be bought in either closed or open top C guise, with either the 5 speed manual or robotised automated gearshifts. Both models had the 160 bhp engine as standard. Effectively they were a replacement for the Esseesse kit, and it meant that the cars were produced complete at the factory, rather than needing the dealer to undertake the upgrade (and the associated paperwork), though Abarth did not withdraw the Esseesse kits from the market for some while. Turismo, as the name suggests was aimed slightly less extreme in intent, featuring standard leather upholstery, upgraded dampers and climate control, Xenon headlights and Alutex interior details. The sportier Abarth 595 Competizione replaced the leather seats with Sabelt cloth sport seats and Alutex with aluminium, while adding p-cross-drilled brakes and the Record Monza dual-mode exhaust.
What is known as the Series 4 version of the familiar 595 reached the markets in the middle of 2016. After rumours had circulated all winter following the launch of the facelifted Fiat 500 last year, Abarth finally unveiled the Series 4 at the end of May 2016. Initially, we were told that the cars would not be available in the UK until September, but that came forward somewhat, with dealers all receiving demo cars in June, and the first customers taking delivery in July. Three regular production versions of both the closed car and the open-topped C were initially available, all badged 595, and called Custom, Turismo and Competizione, as before, though numerous limited edition models have since appeared and in most case disappeared. The most significant changes with the Series 4 are visual, with a couple of new colours, including the much asked for Modena Yellow and a different red, called Abarth Red, which replaces both the non-metallic Officina and – slightly surprisingly – the tri-coat pearlescent Cordolo Red. as well as styling changes front and rear. The jury is still out on these, with many, me included, remaining to be convinced. At the front, the new air intake does apparently allow around 15 – 20 % more air in and out, which will be welcome, as these cars do generate quite a lot of heat under the bonnet. Competizione models for the UK retain the old style headlights, as they have Xenon lights as standard, whereas the Custom and Turismo cars have reshaped units. At the back, there are new light clusters and a new rear bumper and diffuser. Inside, the most notable change is the replacement of the Blue & Me system with a more modern uConnect Audio set up, which brings a new colour screen to the dash. Mechanically, there is an additional 5 bhp on the Custom (now 145) and Turismo (now 165 bhp) and the option of a Limited Slip Diff for the Competizione, which is likely to prove a popular option. Details of the interior trim have changed, with a filled-in glovebox like the US market cars have always had, and electric windows switches that are like the US ones, as well as a part Alcantara trim to the steering wheel in Competizione cars. These cars have now been on offer for five years and with Abarth sales on the rise, it was no surprise that they were particularly well represented here.
There have been an almost bewildering array of limited production models over the years, Among them is the 695 XSR Yamaha Edition, a limited production car that was made in 2017. Creatted in recognition of the fact that for the third year running, in 2017 Abarth was to be Official Sponsor and Official Car Supplier of the Yamaha Factory Racing Team, competing in the 2017 FIM MotoGP World Championship. In the wake of the Abarth 595 Yamaha Factory Racing and the 695 biposto Yamaha Factory Racing Edition, the 695 XSR Yamaha Limited Edition special series is available exclusively with a Pista Grey livery: only 695 sedans and 695 convertibles will be made. The new car was created to celebrate the Yamaha XSR900 Abarth, which is the first exclusive motorcycle to spring from the collaboration between the two brands and which sports the same grey livery with red trim as the 695 XSR, as well as sharing many of its features. The special series makes extensive use of carbon fibre to demonstrate its affinity with the front fairing, front mudguard and saddle cover of the two-wheel Yamaha. The Abarth 695 XSR and the Yamaha XSR900 Abarth also share Akrapovič ultralight exhaust developed in the racing world to boost the personality, sound and performance of both vehicles. On the Abarth car, the carbon fibre tailpipes enhance the looks and technology of the exhaust system. The XSR logo on the tailgate distinguishes the Abarth 695 XSR, while an aluminium badge identifies the sequential number of 695 units for each body type. Other carbon fibre details, in addition to the mirror caps and Akrapovič tailpipes, are available as optional equipment, such as dashboard fascia, pedal covers, gear knob and kick plate. The car uses the 1.4 T-Jet engine delivering 165 bhp. Equipment on this special series includes Koni rear suspension and Eibach springs, 17” Supersport alloy rims with Matt Black finish, Satin Chrome accents on handles and badge supports, red details on bumpers and mirrors, red brake callipers and a braking system with perforated discs. This version can be customised even further using the tuning kit to increase the power to 180 HP, improve handling by fitting a Koni front suspension with FSD (Frequency Selective Damping) valve and make braking even prompter with 305x28mm perforated and self-ventilating Brembo floating front discs with high-performance Ferodo HP 1000/1 front brake pads. It also features the new UconnectTM 7″ HD LIVE system integrated with Apple CarPlay allows iPhone users to access contents such as Apple Maps, Messages, telephone calls, Apple Music, also with Siri voice assistance.
Abarth announced two limited edition models in the autumn of 2020 and one of these was here, the 595 Scorpioneoro. Another model which takes its inspiration from a history which few in the Uk will be familiar with, there will be just 2000 units of this distinctive model available globally. The 595 Scorpioneoro was born to continue the legacy of the famous A112 Abarth “Gold Ring” of 1979, better known as the A112 Abarthj “Targa Oro”, of which only 150 models produced and, as with the new Abarth 595 Scorpioneoro, what made it so special were its stylistic details. These details included black livery, gold-coloured decorative line contouring the bodywork and the alloy wheels, also painted in the distinctive gold colour. This car is liveried in the same way, marked out by its black livery, decorative gold bodywork lining and gold-painted alloy wheels. It also boasts a matt black chessboard roof and grey finish on the door handles and mirror caps. And to mirror the ‘Gold Scorpion’ name, the car is adorned with gold scorpions on the bonnet and the wheel centres. Inside the cabin of this new exciting new model, you’ll be greeted with a black dashboard which is home to the new gold finished 500 logo. Leather detailing on the seats introduces the original “scorpionflage”. The seats are further embellished with dedicated stitching and personalised headrests with the word “Scorpioneoro”, the Italian flag and Abarth embroidered on them. An additional touch of exclusivity comes from the numbered, gold coloured plaque, available solely on this model. The Scorpioneoro also comes with Abarth’s top-of-the-range seven-inch touchscreen infotainment system, complete with Apple CarPlay and Android Auto, as well as a Beats Audio sound system. Mechanically, there is nothing new, as the car has the 165 bhp version of the familiar T-Jet engine and the other features you get in the regular production Trofeo cars.
There were a number of examples of the 124 Spider here, too. 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. The final cars have largely been sold, so there are only around 1800 of them in the UK, which means that this is always going to be quite a rare sighting.
There are so many replica and recreation examples of the Cobra that it is tempting to assume that whenever you see one, that is what it is. Occasionally, of course, the car before you is actually one of the original ones from the 1960s and that is the case with this fabulous Cobra 289. Like many British manufacturers, AC Cars had been using the Bristol straight-6 engine in its small-volume production, including its AC Ace two-seater roadster. This had a hand-built body with a steel tube frame, and aluminium body panels that were made using English wheeling machines. The engine was a pre-World War II design by BMW which by the 1960s was considered dated. In 1961 Bristol decided to cease production of its engine. In September 1961, American retired race car driver and automotive designer Carroll Shelby wrote to AC asking if they would build him a car modified to accept a V8 engine. Bristol engines for the AC Ace two-seater sports car had recently been discontinued so AC agreed, provided a suitable engine could be found. Shelby went to Chevrolet to see if they would provide him with engines, but not wanting to add competition to the Corvette they said no. However, Ford wanted a car that could compete with the Corvette and they happened to have a brand new engine which could be used in this endeavor: the Windsor 3.6-litre (221 cu in) engine – a new lightweight, thin-wall cast small-block V8. Ford provided Shelby with two engines. In January 1962 mechanics at AC Cars in Thames Ditton, Surrey designed the “AC Ace 3.6” prototype with chassis number CSX2000. AC had already made most of the modifications needed for the small-block V8 when they installed the 2.553-litre (156 cu in) inline 6 Ford Zephyr engine, including the extensive rework of the AC Ace’s front end bodywork. The only modification of the front end of the first Cobra from that of the “AC Ace 2.6” was the steering box, which had to be moved outward to clear the wider V8 engine. The most important modification was the fitting of a stronger rear differential to handle the increased engine power. A Salisbury 4HU unit with inboard disc brakes to reduce unsprung weight was chosen instead of the old E.N.V. unit. It was the same unit used on the Jaguar E-Type. After testing and modification, the engine and transmission were removed and the chassis was air-freighted to Shelby in Los Angeles on 2 February 1962, By this time the small-block’s displacement was increased to 4.7 L (289 cu in). Shelby’s team paired this engine along with a transmission into CSX2000, in less than eight hours at Dean Moon’s shop in Santa Fe Springs, California, and began road-testing. A few changes were made to the production version: The inboard brakes were moved outboard to reduce cost; the fuel tank filler was relocated from the fender to the cenre of the trunk; the trunk lid had to be shortened to accommodate this change. AC exported completed, painted, and trimmed cars (less engine and gearbox) to Shelby who then finished the cars in his workshop in Los Angeles by installing the engine and gearbox and correcting any bodywork flaws caused by the car’s passage by sea. A small number of cars were also completed on the East Coast of the US by Ed Hugus in Pennsylvania, including the first production car; CSX2001. The first 75 Cobra Mk1 models (including the prototype) were fitted with the 4.3 L (260 cu in). The remaining 51 Mk1 models were fitted with a larger version of the Windsor Ford engine, the 4.7-litre (289 cu in) V8. In late 1962, Alan Turner, AC’s chief engineer completed a major design change of the car’s front end to accommodate rack and pinion steering while still using transverse leaf spring suspension (with the leaf spring doubling as the upper suspension link). The new car entered production in early 1963 and was designated Mark II. The steering rack was borrowed from the MGB while the new steering column came from the VW Beetle. About 528 Mark II Cobras were produced from 1963 to the summer of 1965 (the last US-bound Mark II was produced in November 1964). In 1963 to keep production focused on producing cars for Shelby American Inc., the Ruddspeed Ace was discontinued. To supply cars to the European market, AC began to market and sell the Cobra in Europe. Advertisements from the time state that the Cobra was designed to meet the requirements of Shelby American Inc. Shelby experimented with a larger Ford FE engine, of 6.4 L (390 cu in) in chassis number CSX2196. Unfortunately, the car was not able to receive the development it needed, as resources were aimed at taking the crown from Ferrari in the GT class. Ken Miles drove and raced the FE-powered Mark II at Sebring and pronounced the car virtually undrivable, naming it “The Turd”. It failed to finish with the engine expiring due to damper failure. CSX2196 was revised for the showdown at Nassau which allowed a more relaxed class division of racing. This allowed the Cobras to run with a prototype Ford GT40, GM Grand Sport Corvettes and a Lola Mk6. An aluminium 6.4-litre (390 cu in) engine was used. By the end of the first lap, the Cobra had a lead of the length of the start-finish straight. However, the car failed to finish due to brake problems. A new chassis was required, developed, and designated Mark III. The new car was designed in cooperation with Ford in Detroit. A new chassis was built using 101.6 mm (4 in) main chassis tubes, up from 76.2 mm (3 in) and coil spring suspension all around (an especially significant change up front, where the previously-used transverse leaf spring had done double duty as the top link). The new car also had wide fenders and a larger radiator opening. It was powered by the “side oiler” Ford 7.0 L (427 cu in) FE engine equipped with a single 4-barrel 780 CFM Holley carburetor rated at 425 bhp at 6000 rpm and 651 N⋅m (480 lb⋅ft) at 3700 rpm of torque, which provided a top speed of 264 km/h (164 mph) in the standard model. The more powerful tune of 485 bhp with a top speed of 298 km/h (185 mph) in the semi-competition (S/C) model. Cobra Mark III production began on 1 January 1965; two prototypes had been sent to the United States in October 1964. Cars were sent to the US as unpainted rolling chassis, and they were finished in Shelby’s workshop. Unfortunately, The MK III missed homologation for the 1965 racing season and was not raced by the Shelby team. Only 56 of the 100 planned cars were produced. Of those, 31 unsold competition models were detuned and fitted with windscreens for street use. Called S/C for semi-competition, an original example can currently sell for US$1.5 million, making it one of the most valuable Cobra variants. Some Cobra 427s were actually fitted with Ford’s 7-litre (428 cu in) engine, a long stroke, smaller bore, lower cost engine, intended for road use rather than racing. The AC Cobra was a financial failure that led Ford and Carroll Shelby to discontinue importing cars from England in 1967. AC Cars kept producing the coil-spring AC Roadster with narrow fenders and a small block Ford 289. It was built and sold in Europe until late 1969.
The Alfa range of the 1960s was somewhat complex, as cars evolved and new ranges overlapped. This Giulia Spider is a case in point, as this had in fact started out as part of the 750/101 series of the Giulietta range. A couple of the family were later rebadged as a Giulia. The more commonly seen of the pair is the lovely Giulia Spider 1600. Alfa had followed up the 1950 launch of the 1900 Berlina with a smaller model, the Giulietta. Known as the Type 750 and later 101 Series, the Giulietta evolved into a family of models. The first to be introduced was the Giulietta Sprint 2+2 coupé at the 1954 Turin Motor Show. Designed by Franco Scaglione at Bertone, it was produced at the coachbuilder’s Grugliasco plant near Turin. A year later, at the Turin Motor Show in April 1955, the Sprint was joined by the 4-door saloon Berlina. In mid 1955, the open two-seat Giulietta Spider, featuring convertible bodywork by Pininfarina, and it was one of these achingly pretty cars that was to be seen here. Alfa replaced the Giulietta with the Giulia in 1962, but as the Coupe and Spider were not ready, the Giulietta based models were kept in production, and renamed as Giulia. They gained a larger 1600cc engine, and this meant that the bonnet need to be raised a little to accommodate the new unit, so the easy recognition beyond Giulietta and Giulia Spiders is whether there is a flat bonnet or one with a slight hump and a vent in it.
By 1963, Alfa were ready to add a Coupe version to their new 105 Series Giulia range. It evolved over a 14 year production life, with plenty of different models, though the basic design changed little. 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 superseded 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 186 N·m (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. Oil and radiator capacities remained unchanged. 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.
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.
The current Giulietta arrived in 2010 as a much awaited replacement for the 147. Spy photos had suggested that the car was going to look very like Fiat’s ill-fated Bravo, but the reality was that it had a style all of its own. A range of very efficient petrol and diesel engines were among the most emissions-efficient in their class at the time, and a 250 bhp Quadrifoglio version at the top of the range made sure there was something for the man who wanted a rapid, but quite subtle hatch. The car has enjoyed reasonable success in the UK, and the car has certainly found favour among Alfa enthusiasts, so it was not a surprise to see one here.
Another Alfa here was this 4C Competizione. First seen as a concept at the 2011 Geneva Show, the production 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! – and most love their car. I know I would if I could find space (and funds!) for one in my garage!
There were a number of examples of the Giulia here, all of them the top-dog Quadrifoglio model, and there was also one example of the only other model that Alfa are currently producing, the Stelvio.
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. The Aston Martin DB9, designed by Marek Reichmann and Hendrik Fisker, was first shown by Aston Martin 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. Production of the DB9 ended in 2016 being replaced by its successor, the DB11.
A couple of the last 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 center 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. All told, Aston produced 18 different versions of the model in a production run which continued until 2018, with a number limited edition cars swelling the ranks.
Also here was the latest version of the Vantage.
Final Aston model here was a Rapide AMR. This version of the Rapide was launched in June 2018, very much as a high-performance iteration of the model first seen in 2012. The 5.9-litre naturally aspirated AM29 V12 engine produces 603 PS (444 kW; 595 hp) and 630 N⋅m (465 lb⋅ft) of torque, courtesy of better air flow to the engine and new calibration software. The 8-speed automatic transmission has also received recalibration for better shift timing. The car now comes standard with Michelin Pilot Supersport tyres and 21-inch alloy wheels, the biggest wheels ever fitted to an Aston Martin. The new model features carbon ceramic braking system with six piston calipers at the front and four piston calipers at the rear featuring 400 mm and 360 mm brake rotors front and aft. The car features a new front grille, “sprout” fog lamps and side sills, rear diffuser and bootlid made from carbon fibre. The Rapide AMR can accelerate from 0–100 km/h (0–62 mph) in 4.4 seconds and can reach a claimed top speed of 330 km/h (205 mph). Interior options include a One-77 steering wheel, a personalised plaque along with logos and a variety of colour schemes. Production was limited to 210 examples only.
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, 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.
This is a Mark II Sprite. 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
BMW’s most recent 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.
As well as the latest, and somewhat controversially styled M4 was an example of one of the car’s antecedents, the E92 generation M3.
It is hard to imagine just how revolutionary this car must have seemed when it was unveiled at the Paris Show in 1955. 18 years in secret development as the successor to the Traction Avant, the DS 19 stole the show, and within 15 minutes of opening, 743 orders were taken. By the end of the first day, that number had risen to 12,000. Contemporary journalists said the DS pushed the envelope in the ride vs. handling compromise possible in a motor vehicle. To a France still deep in reconstruction after the devastation of World War II, and also building its identity in the post-colonial world, the DS was a symbol of French ingenuity. It also posited the nation’s relevance in the Space Age, during the global race for technology of the Cold War. Structuralist philosopher Roland Barthes, in an essay about the car, said that it looked as if it had “fallen from the sky”. An American advertisement summarised this selling point: “It takes a special person to drive a special car”. Because they were owned by the technologically aggressive tyre manufacturer Michelin, Citroën had designed their cars around the technically superior radial tyre since 1948, and the DS was no exception. The car featured a novel hydropneumatic suspension including an automatic levelling system and variable ground clearance, developed in-house by Paul Magès. This suspension allowed the DS to travel quickly on the poor road surfaces common in France. In addition, the vehicle had power steering and a semi-automatic transmission (the transmission required no clutch pedal, but gears still had to be shifted by hand though the shift lever controlled a powered hydraulic shift mechanism in place of a mechanical linkage, and a fibreglass roof which lowered the centre of gravity and so reduced weight transfer. Inboard front brakes (as well as independent suspension) reduced unsprung weight. Different front and rear track widths and tyre sizes reduced the unequal tyre loading, which is well known to promote understeer, typical of front-engined and front-wheel drive cars. As with all French cars, the DS design was affected by the tax horsepower system, which effectively mandated very small engines. Unlike the Traction Avant predecessor, there was no top-of-range model with a powerful six-cylinder engine. Citroën had planned an air-cooled flat-6 engine for the car, but did not have the funds to put the prototype engine into production. The 1955 DS19 was 65% more expensive than the car it replaced, the Citroën Traction Avant. This did impact potential sales in a country still recovering economically from World War II, so a cheaper submodel, the Citroën ID, was introduced in 1957. The ID shared the DS’s body but was less powerful and luxurious. Although it shared the engine capacity of the DS engine (at this stage 1,911 cc), the ID provided a maximum power output of only 69 hp compared to the 75 hp claimed for the DS19. Power outputs were further differentiated in 1961 when the DS19 acquired a Weber-32 twin bodied carburettor, and the increasing availability of higher octane fuel enabled the manufacturer to increase the compression ratio from 7.5:1 to 8.5:1. A new DS19 now came with a promised 83 hp of power. The ID19 was also more traditional mechanically: it had no power steering and had conventional transmission and clutch instead of the DS’s hydraulically controlled set-up. Initially the basic ID19 was sold on the French market with a price saving of more than 25% against the DS, although the differential was reduced at the end of 1961 when the manufacturer quietly withdrew the entry level ID19 “Normale” from sale. An estate version was introduced in 1958. It was known by various names in different markets: Break in France, Safari and Estate in the UK, Wagon in the US, and Citroën Australia used the terms Safari and Station-Wagon. It had a steel roof to support the standard roof rack. ‘Familiales’ had a rear seat mounted further back in the cabin, with three folding seats between the front and rear squabs. The standard Break had two side-facing seats in the main load area at the back. During the 20 year production life, improvements were made on an ongoing basis. In September 1962, the DS was restyled with a more aerodynamically efficient nose, better ventilation and other improvements. It retained the open two headlamp appearance, but was available with an optional set of driving lights mounted on the front bumpers. A more luxurious Pallas trim came in for 1965 Named after the Greek goddess Pallas, this included comfort features such as better noise insulation, a more luxurious (and optional leather) upholstery and external trim embellishments. The cars were complex, and not always totally reliable, One of the issues that emerged during long term use was addressed with a change which came in for 1967. The original hydropneumatic system used a vegetable oil liquide hydraulique végétal (LHV), similar to that used in other cars at the time, but later switched to a synthetic fluid liquide hydraulique synthétique (LHS). Both of these had the disadvantage that they are hygroscopic, as is the case with most brake fluids. Disuse allows water to enter the hydraulic components causing deterioration and expensive maintenance work. The difficulty with hygroscopic hydraulic fluid was exacerbated in the DS/ID due to the extreme rise and fall in the fluid level in the reservoir, which went from nearly full to nearly empty when the suspension extended to maximum height and the six accumulators in the system filled with fluid. With every “inhalation” of fresh moisture- (and dust-) laden air, the fluid absorbed more water. For the 1967 model year, Citroën introduced a new mineral oil-based fluid liquide hydraulique minéral (LHM). This fluid was much less harsh on the system. LHM remained in use within Citroën until the Xantia was discontinued in 2001. LHM required completely different materials for the seals. Using either fluid in the incorrect system would completely destroy the hydraulic seals very quickly. To help avoid this problem, Citroën added a bright green dye to the LHM fluid and also painted all hydraulic elements bright green. The former LHS parts were painted black. All models, including the Safari and ID, were upgraded at the same time. The hydraulic fluid changed to the technically superior LHM (Liquide Hydraulique Minéral) in all markets except the US and Canada, where the change did not take place until January 1969, due to local regulations. Rarest and most collectable of all DS variants, a convertible was offered from 1958 until 1973. The Cabriolet d’Usine (factory convertible) were built by French carrossier Henri Chapron, for the Citroën dealer network. It was an expensive car, so only 1,365 were sold. These DS convertibles used a special frame which was reinforced on the sidemembers and rear suspension swingarm bearing box, similar to, but not identical to the Break/Safari frame.
Still seen by many as the most beautiful Ferrari ever built was the 246 GT Dino and there was a rather nice 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.
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 tires (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 car seen here sported a Koenig-modified body. Koenig’s package of upgrades for the 512BB/BBi was a great success with some 50-or-so cars being built by the factory or fitted with kits by their owners. The Koenig changes included different pistons, camshaft and exhaust system which meant that their 512BBi produced 450bhp, up from the standard car’s 340 bhp. Some cars had more than this, thanks to the addition of twin turbochargers, which boosted power to 650 bhp. This meant that the 512BBi, already no slouch, was elevated to the forefront of contemporary supercars, performance figures of 100km/h in 4.3 seconds and a top speed of 330km/h being claimed. This is some 48km/h faster than the standard car and comparable with the performance of the later Ferrari F40, though the latter made do with ‘only’ 478bhp. To cope with extra power, the gearbox was strengthened and fitted with an additional oil cooler. With a top speed higher than the take-off velocity of many light aircraft, the Koenig-tuned 512BBi needed all the downforce it could get, which came courtesy of a specially developed body kit. Made of polyester, the latter consisted of a new front bumper incorporating brake cooling ducts; a rear spoiler; body side skirts; smaller rear view mirrors; and roof-mounted intakes for the turbochargers. In addition, the rear wheelarches were extended to cover magnesium wheels shod with Pirelli P Zero 345/55VR15 tyres, while the front tyres were reduced in size to 225/50VR15 (stock is 240/55VR15 all round). Stiffer road springs and shock absorbers were fitted but the ride height was left standard. The brake discs and callipers were up-rated and adjustable brake bias incorporated into the system. The original owner was not tempted by Koenig’s extensive range of upgrades for the interior, which was left standard. Koenig is no longer in the performance conversion business, though it still manufactures parts and accessories for Ferraris. Surprisingly, there were two examples here, both of the BB512 versions.
The 360 was followed by F430, which 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 its predecessor, the Ferrari 360, 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.
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
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
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 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.
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.
Among my favourite cars of all time are the Fiat Dino Coupe and Spider and I was pleased to see an example of the Coupe here. They came about because of Enzo Ferrari’s need to homologate a V6 engine for Formula 2 racing cars. In 1965 the Commission Sportive Internationale de la FIA had drawn up new rules, to be enacted for the 1967 season. F2 engines were required to have no more than six cylinders, and to be derived from a production engine, from a road car homologated in the GT class and produced in at least 500 examples within 12 months. Since a small manufacturer like Ferrari did not possess the production capacity to reach such quotas, an agreement was signed with Fiat and made public on 1 March 1965: Fiat would produce the 500 engines needed for the homologation, to be installed in a yet unspecified GT car. The Fiat Dino was introduced as a 2-seater Spider at the Turin Motor Show in October 1966; a 2+2 Coupé version, built on a 270 mm (10.6 in) longer wheelbase, bowed a few months later at the Geneva Motor Show in March 1967. The two bodies showed very different lines, as they had been designed and were manufactured for Fiat by two different coachbuilders: the Spider by Pininfarina, and the Coupé by Bertone—where it had been sketched out by Giorgetto Giugiaro. Curiously the Spider type approval identified it as a 2+1 seater. The Spider had poorer interior trim than the Coupé, below par for its class: the dashboard was covered in vinyl, the metal-spoke steering wheel had a plastic rim, and the interior switchgear was derived from cheaper Fiat models. After a few months this issue was addressed, and Spiders produced after February 1967 had a wood-rimmed steering wheel as well as a wood trim on the dashboard like the sister Coupé car had since the beginning. Option lists for both models were limited to radio, metallic paint, leather upholstery, and for the Spider a vinyl-covered hardtop with roll-bar style stainless steel trim. The car was offered with an all-aluminium DOHC 2.0 litre V6, coupled to a 5-speed manual transmission. The same 2.0-litre engine was used in mid-engined, Ferrari-built Dino 206 GT, which was introduced in pre-production form at the 1967 Turin Motor Show and went on sale in 1968. Fiat quoted 160 PS (158 hp) for the Fiat Dino, while in 1967 Ferrari—presenting the first prototype of the Dino 206 GT—claimed 180 hp despite both engines were made by Fiat workers in Turin on the same production line, without any discrimination as to their destination. Jean-Pierre Gabriel in “Les Ferraris de Turin” notes that, “La declaration de Ferrari ne reposait sur aucun fondament technique”—Ferrari’s statement had no technical basis. The real reason for this difference was a mistake in between quotes made in SAE and BHP power output. In 1969, both Ferrari and Fiat introduced new 2.4-litre Dino models. The Fiat Dino 2400 premiered in October 1969 at the Turin Motor show; besides the larger engine, another notable improvements was independent rear suspension. The V6 now put out 180 PS, and used a cast iron instead of the previous light alloy engine block; the same engine was installed on the Dino 246 GT, Ferrari’s evolution of the 206. Whereas the original Dino was equipped with a rigid axle suspended by leaf springs and 4 shock absorbers, 2.4-litre cars used a coil-sprung independent rear suspension with 2 shock absorbers derived from the Fiat 130. Rather than engine power and absolute speed, the most important consequence of the larger displacement was a marked increase in torque, available at lower engine speeds; the Dino 2400 had much better pickup, and it was found more usable, even in city traffic. Other modifications went on to improve the car’s drivability and safety: larger diameter clutch, new dogleg ZF gearbox with revised gear ratios, wider section 205/70VR -14 tyres, and up-sized brake discs and callipers. Cosmetic changes were comparatively minor. Both models were now badged “Dino 2400”. On the coupé the previous silver honeycomb grille with the round Fiat logo on its centre had been replaced by a new black grille and a bonnet badge. A host of details were changed from chrome to matte black, namely part of the wheels, the vents on the front wings and the cabin ventilation outlets—the latter moved from next the side windows to the rear window. At the rear there were different tail lights. The spider also sported a new grille with two horizontal chrome bars, 5-bolts instead of knock-off wheels, as well as a new bumpers with rubber strips. Inside only the coupé received an entirely redesigned dashboard and new cloth seats, with optional leather seat upholstery; front seat headrests were standard on the coupé and optional on the spider. Spider and coupé bodies were produced respectively by Pininfarina and Bertone. 2.0-litre and early 2.4-litre cars were assembled by Fiat in Rivalta di Torino. Starting from December 1969 the Fiat Dino was assembled in Maranello on Ferrari’s production line, alongside the 246 GT. Between 1966 and 1969 there were 3,670 2.0-litre coupés and 1,163 2.0-litre spiders made; with only 420 built, the 2400 Spider is the rarest of the Fiat’s Dinos. Of the total 7,803 Fiat Dino produced, 74% were the popular coupés and only 26% were spiders. Spiders are worth big money now – good ones are over £100k – which means that the car is way beyond my means, but every time I see one, I go weak at the knees. To my eyes, it is one of the best looking cars ever made.
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 Focus was 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.
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 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. There were a number of the open two seater version seen here.
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, 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.
There were two examples of the F Type here, in pre- and post-facelift forms.
Something of a surprise appearance – until I saw the MAC members sticker in the car – was this fabulous Miura, a car some will say was the first true supercar. For sure, this car, produced between 1966 and 1973, is widely considered to have instigated the trend of high performance, two-seater, mid-engined sports cars. When released, it was the fastest production road car available. The Miura was originally conceived by Lamborghini’s engineering team, Gian Paolo Dallara, Paolo Stanzani, and Bob Wallace who in 1965 put their own time into developing a prototype car known as the P400. The engineers envisioned a road car with racing pedigree – one which could win on the track and be driven on the road by enthusiasts. The three men worked on its design at night, hoping to convince Lamborghini such a vehicle would neither be too expensive nor distract from the company’s focus. When finally brought aboard, Lamborghini gave his engineers a free hand in the belief the P400 was a potentially valuable marketing tool, if nothing more. The car featured a transversely-mounted mid-engine layout, a departure from previous Lamborghini cars. The V12 was also unusual in that it was effectively merged with the transmission and differential, reflecting a lack of space in the tightly-wrapped design. The rolling chassis was displayed at the Turin Salon in 1965. Impressed showgoers placed orders for the car despite the lack of a body to go over the chassis. Bertone was placed in charge of styling the prototype, which was finished just days before its debut at the 1966 Geneva motor show. Curiously, none of the engineers had found time to check if the engine would fit inside its compartment. Committed to showing the car, they decided to fill the engine bay with ballast and keep the car locked throughout the show, as they had three years earlier for the début of the 350GTV. Sales head Sgarzi was forced to turn away members of the motoring press who wanted to see the P400’s power plant. Despite this setback, the car was the highlight of the show, immediately boosting stylist Marcello Gandini’s reputation. The favourable reaction at Geneva meant the P400 was to go into production by the following year. The name “Miura”, a famous type of fighting bull, was chosen, and featured in the company’s newly created badge. The car gained the worldwide attention of automotive enthusiasts when it was chosen for the opening sequence of the original 1969 version of The Italian Job. In press interviews of the time company founder Ferruccio Lamborghini was reticent about his precise birth date, but stressed that he was born under the star sign Taurus the bull. Early Miuras, known as P400s (for Posteriore 4 litri), were powered by a version of the 3.9 litre Lamborghini V12 engine used in the 400GT at the time, only mounted transversely and producing 350 hp. Exactly 275 P400 were produced between 1966 and 1969 – a success for Lamborghini despite its then-steep price. Taking a cue from the Morris Mini, Lamborghini formed the engine and gearbox in one casting. Its shared lubrication continued until the last 96 SVs, when the case was split to allow the correct oils to be used for each element. An unconfirmed claim holds the first 125 Miuras were built of 0.9 mm steel and are therefore lighter than later cars. All cars had steel frames and doors, with aluminium front and rear skinned body sections. When leaving the factory they were originally fitted with Pirelli Cinturato 205VR15 tyres (CN72). The P400S Miura, also known as the Miura S, made its introduction at the Turin Motorshow in November 1968, where the original chassis had been introduced three years earlier. It was slightly revised from the P400, with the addition of power windows, bright chrome trim around external windows and headlights, new overhead inline console with new rocker switches, engine intake manifolds made 2 mm larger, different camshaft profiles, and notched trunk end panels (allowing for slightly more luggage space). Engine changes were reportedly good for an additional 20 hp. Other revisions were limited to creature comforts, such as a locking glovebox lid, a reversed position of the cigarette lighter and windshield wiper switch, and single release handles for front and rear body sections. Other interior improvements included the addition of power windows and optional air conditioning, available for US$800. About 338 P400S Miura were produced between December 1968 and March 1971. One S #4407 was owned by Frank Sinatra. Miles Davis also owned one, which he crashed in October 1972 under the influence of cocaine, breaking both ankles. The last and most famous Miura, the P400SV or Miura SV featured different cam timing and altered carburettors. These gave the engine an additional 15 hp to a total of 380 hp. The last 96 SV engines had a split sump. The gearbox now had its lubrication system separate from the engine, which allowed the use of the appropriate types of oil for the gearbox and the engine. This also alleviated concerns that metal shavings from the gearbox could travel into the engine with disastrous and expensive results and made the application of an optional LSD far easier. The SV can be distinguished from its predecessors from its lack of “eyelashes” around the headlamps, wider rear wings to accommodate the new 9-inch-wide rear wheels and Pirelli Cinturato tyres, and different taillights. 150 SVs were produced.
The Lamborghini Gallardo is a sports car built by the Italian automotive manufacturer Lamborghini from 2003 to 2013. Named after a famous breed of fighting bull, the V10 powered Gallardo has been Lamborghini’s sales leader and stable-mate to a succession of V12 flagship models—first to the Murciélago (4,099 built between 2001 and 2010), then to the current flagship, the Aventador. The first generation of the Gallardo was powered with an even firing 4,961 cc (5.0 L) 90 degree V10 engine generating a maximum power output of 500 PS at 7500 rpm and 510 Nm (376 lb/ft) of torque at 4500 rpm. The Gallardo was offered with two choices of transmission; a conventional (H-pattern) six-speed manual transmission, and a six-speed electro-hydraulically actuated single-clutch automated manual transmission that Lamborghini called “E-gear”. The “E-gear” transmission provides gear changes more quickly than could be achieved through a manual shift. The driver shifts up and down via paddles behind the steering wheel, but can also change to an automatic mode via the gear selector located in place of the gear shift lever. The vehicle was designed by Luc Donckerwolke and was based on the 1995 Calà prototype designed by Italdesign Giugiaro. For the 2006 model year (launched in late 2005), Lamborghini introduced many changes to the car to counter some criticisms garnered from the press and owners. The exhaust system was changed to a more sporty one (including a flap to make it quieter during city driving), the suspension was revised, a new steering rack was fitted, the engine power was increased by 20 PS to a maximum of 520 PS and the biggest change was overall lower gearing ratios, especially in 1st to 5th gear. These changes gave the car a much better performance than the original and were also included in the limited edition Gallardo SE. The convertible variant of the Gallardo, called the Gallardo Spyder, was unveiled at the Los Angeles Auto Show in January 2006. It was considered by the company to be an entirely new model, with the engine having a power output of 520 PS (513 bhp) and a low-ratio six-speed manual transmission. The Spyder has a retractable soft-top. At the 2007 Geneva Auto Show, Lamborghini unveiled the Gallardo Superleggera. The name paid tribute to the construction style of the first Lamborghini production model, the 350 GT, designed and built by Carrozzeria Touring and its emphasis on weight reduction. The Superleggera is lighter than the base model by 100 kg (220 lb) due to the use of carbon fibre panels for the rear diffuser, undertray, the rearview-mirror housings, the interior door panels, the central tunnel, engine cover; titanium wheel nuts and carbon fibre sports seats. The engine power was uprated by 10 PS courtesy of an improved intake, exhaust and ECU for a total power output of 530 PS. The 6-speed E-Gear transmission was standard on US spec models with the 6-speed manual transmission offered as a no cost option. Production of the Superleggera amounted to 618 units worldwide. Presented at the 2008 Geneva Motor Show, the Gallardo LP 560-4 was a significant update of the Gallardo, powered by a new, uneven firing 5,200 cc V10 engine that produces 560 PS at 8,000 rpm and 540 Nm (398 lb/ft) of torque at 6,500 rpm. Featuring “Iniezione Diretta Stratificata” direct fuel injection system to improve efficiency; fuel consumption and CO2 emissions have been reduced by 18% despite the increase in performance. The car was redesigned, inspired by the Murciélago LP 640 and Reventón. The new engine, 40 PS more powerful than in the previous car, comes with two transmission choices: a 6-speed manual or 6-speed E-gear, the latter of which was revised to offer a Corsa mode which makes 40% quicker shifts than before and decreases traction control restrictions, a Thrust Mode launch control system was also added. Accompanied with a 20 kg (44 lb) weight reduction. All the improvements add up to a claimed performance of 0-100 km/h (62 mph) in 3.7 seconds, 0-200 km/h (124 mph) of 11.8 and a top speed of 325 km/h (202 mph). The MSRP base price was $198,000 in the US and £147,330 (including NavTrak vehicle tracking system and delivery package) in the UK. The first US car was sold in the 16th Annual Race to Erase MS charity auction for $198,000 to former True Religion Jeans co-founder/co-creator Kymberly Gold and music producer Victor Newman. The Lamborghini Gallardo LP 560-4 Spyder was unveiled at the 2008 LA Auto Show.as the replacement for the previous Gallardo Spyder. It is the convertible model of the Gallardo LP 560-4 and as such possess all of its features like the new uneven firing 5.2 L V10 engine, improved E-gear transmission and 20 kg (44 lb) weight reduction. Performance has been improved to 0-100 km/h (62 mph) in 3.8 seconds, 0-200 km/h (124 mph) of 13.1 and a top speed of 324 km/h (201 mph) In March 2010, Lamborghini announced the release of the Gallardo LP 570-4 Superleggera, a lightweight and more powerful version of the Gallardo LP 560–4 in the same vein as the previous Superleggera. With carbon fibre used extensively inside and out to reduce weight to just 1,340 kg (2,954 lb) making it the lightest road-going Lamborghini in the range. The odd firing 5.2 L V10 on the LP 570-4 gets a power bump over the standard Gallardo to 570 PS at 8,000 rpm and 540 Nm (398 lb/ft) at 6,500 rpm of torque. Performance has been improved to 0-100 km/h (62 mph) in 3.2 seconds, and a 329 km/h (204 mph) top speed. The Gallardo became Lamborghini’s best-selling model with 14,022 built throughout its production run. On 25 November 2013, the last Gallardo was rolled off the production line. The Gallardo was replaced by the Huracán in 2014
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.
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.
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 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.
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.
There were a number of examples here of the range known internally as the Tipo 338 and better known as the 3200GT and 4200GT and Spider. 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.
Final Maserati here was my recently acquired Ghibli. It attracted lots of attention, the combination of the Blu Passione colour and the fact that it is the recently available facelift car no doubt adding to the allure.
There were a number of sporting Mercedes models here. The top of the range sports car, the AMG GT was the most striking perhaps, and there were also a number of examples of the much smaller and more affordable SLK/SLC model.
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 were a couple of examples of the classic Morgan style, the long-running Plus 4.
First Nissan of note was one of the popular 350Z Coupe models. Released on July 2002 in Japan at reorganized Nissan Japanese dealerships called Nissan Blue Stage, and August 20, 2002 in the US., the 350Z coupé was available in 5 trim packages: ‘350Z’ (Base), ‘Enthusiast’, ‘Performance’, ‘Touring’, and ‘Track’ editions. In Europe, only the ‘Track’ trim was available, although it was badged and marketed as ‘350Z’. The Base model did not include a VLSD or Traction Control and was only available with cloth seats. It did not include cruise control, nor power or heated seats. The Enthusiast model came with traction control, a VLSD, and cruise control. The Performance model came with bigger 18-inch wheels, front air dam, rear spoiler, optional Brembo brakes, and VDC instead of Traction Control. Touring was made more of the luxury model. It had power, leather, heated seats, VDC, a VLSD, xenon headlamps, optional Brembos, 18-inch wheels, and optional GPS. The Track model included Brembo brakes, front air dam, rear spoiler, traction control, cloth seats, 18-inch wheels, VLSD, and optional GPS. In 2004 Nissan introduced the 350Z Roadster with an electrically retractable soft-top roof. In the U.S. market the car was available in two trim packages (Enthusiast and Touring), while in Europe, the same versions as the coupé were offered. Nissan added the Grand Touring (GT) trim to the Roadster trim packages for 2005. In 2005 Nissan launched a 35th Anniversary edition, with a revised exterior and interior. Early 2005 model-year 35th anniversary edition models were equipped with the original VQ35DE with 287 hp and automatic transmission. In January 2005, Nissan introduced the 35th Anniversary 6-speed manual models and Track models (mid-year introduction), which included the updated VQ35DE 300 hp Rev-up engine and new updated CD009 manual transmission. As well as minor changes to suspension tuning and parts. For the 2006 model year, the 350Z received changes for its mid-cycle facelift. The VQ35DE 300 hp Rev-up engine that was introduced mid-year 2005 on the Track and 35th Anniversary Edition with 6-speed manual transmission models was offered for every trim level that had a manual transmission option. The VQ35DE with 287 hp continued to be offered with only the 5-speed automatic. Additions included bi-xenon projectors, a revised front fascia, new LED rear lights, changes to the interior trim and speed sensitive steering. Touring and Grand Touring models had radio-steering controls standard, MP3 CD compatibility, and Satellite Radio became an available option. For the 2007 model year, the 350Z was again moderately revised. The VQ35DE V6 was replaced with a new VQ35HR V6. It produced 306 hp at 6800 rpm with 268 ft·lb at 4800 rpm using the revised SAE certified power benchmark. The VQ35HR had a raised redline to 7500 rpm and more torque across the rpm range. The bonnet was redesigned with a bulge reminiscent of the original 240Z to accommodate the raised deck height of the new VQ35HR. In the US, trim levels were narrowed down to 350Z (base), Enthusiast, Touring, and Grand Touring, while in Europe the same trim levels remained. Bluetooth was added for the 2007 model year. The car was replaced by the 370Z for the 2009 model year. It has never found quite the same levels of enthusiasm that greeted – and have stayed with – the 350Z.
There was also an R35 generation GT-R.
The second-generation debut for the 1970 model year was delayed until February 26, 1970, because of tooling and engineering problems; thus, its popular designation as a 1970½ model, while leftover 1969s were listed in early Pontiac literature without a model-year identification. This generation of Firebirds were available in coupe form only; after the 1969 model year, convertibles were not available until 1989. Replacing the “Coke bottle” styling was a more “swoopy” body style, while still retaining some traditional elements. The top of the rear window line going almost straight down to the lip of the trunk lid, a look that was to epitomize F-body styling for the longest period during the Firebird’s lifetime. The new design was initially characterized by a large B-pillar, until 1975 when the rear window was enlarged.
There were two Ram Air 400 cu in (6.6 L) engines for 1970: the 335 hp L74 Ram Air 400 (366 hp in GTO) and the 345 hp LS1 Ram Air IV (370 hp in the GTO) that were carried over from 1969. The difference between the GTO and Firebird engines was that the secondary carburettor’s throttle linkage had a restrictor which prevented the rear barrels from opening completely, adjusting the linkage could allow full carburetor operation resulting in identical engine performance. For the 1970 and 1971 model years, all Firebirds equipped with radios had the antennae mounted “in-glass” in the windshield. The Pontiac 455 cu in (7.5 L) engine first became available in the second generation Firebird in 1971. The 455 engine was available in the L75 325 hp version and the LS5 335 hp HO version, which was the standard, and only engine option, for the Trans Am. The HO engine also included Ram Air IV. During a 1972 strike, the Firebird (and the similar F-body Camaro) were nearly dropped. Again the 455 HO was the only engine available for the Trans Am. Starting in 1972, and continuing until 1977, the Firebird was only produced at the Norwood, Ohio, facility. In 1973, the Trans Am added two new colors to the Cameo White, Buccaneer Red and Brewster Green. Of the colours, the Buccaneer Red cars seemed to be very popular with the public. Other exterior upgrades included the updated more modern nose bird and the new, soon to be iconic, hood bird option was the “RPO WW7 Hood Decal”, which was a $55 option exclusive to Trans Am. The “Trans Am” decals were a bit larger than previous versions, and shared the same accent colour schemes as the hood bird. Inside the 1973, Trans Am the standard interior equipment was almost the same as prior years. The new “Horse Collar” optional custom interior featured new seat coverings and door panels. The custom interior is well liked by the public as sporty and luxurious. Interior colours were limited to Black, White, Burgundy and Saddle but interestingly you could special order orange, red and blue carpet to any of the interiors colours. The 1973 Trans Am also had to meet the new safety and emissions requirements for 1973. There were now extra steel reinforcements in the bumper and core to support the fender. All Pontiac motors now had to be fitted with new EGR system, which delayed the SD-455 Program until late into production year. The 1973 Trans Am engine displaced 455 cubic inches, the base L75 and Super Duty LS2 option. The engines might have offered the same displacement, but that is where the similarity ended. The base 455 produced 40 fewer horsepower than the round port Super Duty 455. Horsepower for the base L75 455 was rated at 250@4000 rpm and 370 lb/ft @2800 rpm. Pontiac removed the H.O. designation from the base engine, and simply decaled the now nonfunctional shaker with “455”. The “all hand assembled” LS2 SD455 engine has so many difference than the base L75 that it would take up multiple paragraphs, so there are multiple page articles dedicated to these changes. Horsepower for the specially ordered LS2 SD-455 was rated at 290@4000 rpm and 395 lb/ft @3600 rpm. Pontiac engineer’s shaker decal was called the “SD-455.” The 1973 Trans Am introduced “Radial Tuned Suspension” to the automotive world. When ordered, it included the 15” radial tires. Radial Tuned Suspensions with radial tires delivered a much more comfortable ride, while providing outstanding cornering grip. Radial tires where just coming onto the market and Pontiac’s Engineering department fully utilized the RTS option on future Trans Am. The 1973 Trans Am production was up over previous years, the L75 455 production had 3130 Automatics and 1420 Manuals. The Special Ordered $550 Option LS2 SD-455 production had 180 Automatics and 72 Manuals. The 1973 Trans Am has been consider by many as a pinnacle Trans Am offering SD power, great colour combinations, better that ever handling, refined exterior and interior styling and of course that outrageous hood bird. In 1973 and 1974, a special version of the 455, called the “Super Duty 455”
(SD-455), was offered. The SD-455 consisted of a strengthened cylinder block that included four-bolt main bearings and added material in various locations for improved strength. Original plans called for a forged crankshaft, although actual production SD455s received nodular iron crankshafts with minor enhancements. Forged rods and forged aluminum pistons were specified, as were unique high-flow cylinder heads. The 480737 code cam (identical grind to the RAIV “041” cam) was originally specified for the SD455 engine and was fitted into the “pre-production” test cars (source: former Pontiac special projects engineer McCully), one of which was tested by both Hot Rod and Car and Driver magazines. However, actual production cars were fitted with the milder 493323 cam and 1.5:1 rocker ratios, due to the ever-tightening emissions standards of the era. This cam and rocker combination, combined with a low compression ratio of 8.4:1 advertised (7.9:1 actual) yielded 290 SAE net horsepower. Production SD455 cars did not have functional hood scoops, while the “pre-production” test cars did. McCully verified that no production SD455s released to the public were fitted with the 480737 cam. When asked about the compromises for the production SD455 engine, McCully responded, “Compression, camshaft, jetting, and vacuum advance”. He followed by stating that he would have preferred a compression ratio of 10.25:1, a camshaft with 041 valve timing, slightly richer carburetor jetting, and as much vacuum advance as the engine would tolerate. However, that proved to be impossible due to the emissions regulations of the era. Curb weights rose dramatically in the 1974 model year because of the implementation of 5 mph (8.0 km/h) telescoping bumpers and various other crash- and safety-related structural enhancements; SD455 Trans Ams weighed in at 3,850 lb (1,746 kg) in their first year of production (1974 model year; actually 1973). The 1974 models featured a redesigned “shovel-nose” front end and new wide “slotted” taillights. The model would continue with annual revisions right through to 1981.
There were plenty of Porsche here, as you might have predicted. The majority were from the 911 family, spread across several of the different generations that have been produced. 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. 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, 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. 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 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.
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 C
arrera 4S model was first introduced.
The 996 was replaced with the 997 in 2005. It retains the 996’s basic profile, with an even lower 0.28 drag coefficient, but draws on the 993 for detailing. In addition, the new headlights revert to the original bug-eye design from the teardrop scheme of the 996. Its interior is also similarly revised, with strong links to the earlier 911 interiors while at the same time looking fresh and modern. The 997 shares less than a third of its parts with the outgoing 996, but is still technically similar to it. Initially, two versions of the 997 were introduced— the rear-wheel-drive Carrera and Carrera S. While the base 997 Carrera had a power output of 321 hp from its 3.6 L Flat 6, a more powerful 3.8 L 350 hp Flat 6 powers the Carrera S. Besides a more powerful engine, the Carrera S also comes standard with 19 inch “Lobster Fork” style wheels, more powerful and larger brakes (with red calipers), lowered suspension with PASM (Porsche Active Suspension Management: dynamically adjustable dampers), Xenon headlamps, and a sports steering wheel. In late 2005, Porsche introduced the all-wheel-drive versions to the 997 lineup. Carrera 4 models (both Carrera 4 and Carrera 4S) were announced as 2006 models. Both Carrera 4 models are wider than their rear-wheel-drive counterparts by 1.76 inches (32 mm) to cover wider rear tyres. The 0–100 km/h (62 mph) acceleration time for the Carrera 4S with the 350 hp engine equipped with a manual transmission was reported at 4.8 seconds. The 0–100 km/h (62 mph) acceleration for the Carrera S with the 350 hp was noted to be as fast as 4.2 seconds in a Motor Trend comparison, and Road & Track has timed it at 3.8 seconds. The 997 lineup includes both 2- and 4-wheel-drive variants, named Carrera and Carrera 4 respectively. The Targas (4 and 4S), released in November 2006, are 4-wheel-drive versions that divide the difference between the coupés and the cabriolets with their dual, sliding glass tops. The 997 received a larger air intake in the front bumper, new headlights, new rear taillights, new clean-sheet design direct fuel injection engines, and the introduction of a dual-clutch gearbox called PDK for the 2009 model year. They were also equipped with Bluetooth support. The change to the 7th generation (991) took place in the middle of the 2012 model year. A 2012 Porsche 911 can either be a 997 or a 991, depending on the month of the production.
Porsche also offered an RS version of the 997 GT3. In common with its predecessors, it was a homologation model for use in a range of racing series. The 997 GT3 RS was introduced in Europe in October 2006 and in North America in spring 2007. The 997 GT3 RS is 20 kg (44 lb) lighter than the 997 GT3, weighing in at 1,370 kg (3,020 lb). This weight-saving was achieved by the use of an adjustable carbon fibre wing, a steel engine cover, and a lightweight plastic windscreen. The weight savings gives the 997 GT3 RS corresponding engine power to curb weight ratio of 300 bhp per tonne. The body of the 997 GT3 RS is 64 mm (2.5 in) wider at the rear than the 997 GT3 (a legacy from the Carrera 4 models with which it shares its body shell). The muscular-looking rear end conceals a wider track that not only improves directional stability but also increases the potential cornering grip. However, drag is increased and top speed is reduced due to the larger rear wing. In addition to the new technology, the paint scheme and body panels are all designed specifically for the RS. The US version of the 997 GT3 RS has a standard rear window (not plexiglas) and the smaller 911 fuel tank to comply with rules of SCCA, Can-Am, and IMSA. For Grand-Am races, the central locking wheel nut is replaced with the standard five-lug pattern required under Grand-Am rules. Production of the first generation 997 GT3 RS (997.1 GT3 RS) ended in 2009. An estimated 1,168 vehicles were delivered worldwide, with a total of 410 units sold in the United States and 42 units in Canada. For 2010, the second generation 911 GT3 RS (known as 997.2 GT3 RS) received an additional 15 PS due to a new 3.8-litre flat-6 engine, bringing total power output up to 450 PS. Production continued until the introduction of the 991 generation range.
The 991 introduced in 2012 is an entirely new platform, only the third since the original 911. Porsche revealed basic information on the new Carrera and Carrera S models on 23 August 2011. The Carrera is powered by a 350 hp 3.4-litre engine. The Carrera S features a 3.8-litre engine rated at 400 hp. A Power Kit (option X51) is available for the Carrera S, increasing power output to 430 hp. The new 991’s overall length grows by 56 mm (2.2 in) and wheelbase grows by 99 mm (3.9 in) (now 96.5 in.) Overhangs are trimmed and the rear axle moves rearward at roughly 76 mm (3 in) towards the engine (made possible by new 3-shaft transmissions whose output flanges are moved closer to the engine). There is a wider front track (51 mm (2 in) wider for the Carrera S). The design team for the 991 was headed by Michael Mauer. At the front, the new 991 has wide-set headlights that are more three-dimensional. The front fender peaks are a bit more prominent, and wedgy directionals now appear to float above the intakes for the twin coolant radiators. The stretched rear 3/4 view has changed the most, with a slightly more voluminous form and thin taillights capped with the protruding lip of the bodywork. The biggest and main change in the interior is the center console, inspired by the Carrera GT and adopted by the Panamera. The 991 is the first 911 to use a predominantly aluminium construction. This means that even though the car is larger than the outgoing model, it is still up to 50 kilograms (110 lb) lighter. The reduced weight and increased power means that both the Carrera and Carrera S are appreciably faster than the outgoing models. The 0–60 mph acceleration time for the manual transmission cars are 4.6 seconds for the Carrera and 4.3 seconds for the Carrera S. When equipped with the PDK transmission, the two 991 models can accelerate from 0–97 km/h in 4.4 seconds and 4.1 seconds. With the optional sports chrono package, available for the cars with the PDK transmission, the 991 Carrera can accelerate from 0–97 km/h in as little as 4.2 seconds and the Carrera S can do the same in 3.9 seconds. Apart from the reworked PDK transmission, the new 991 is also equipped with an industry-first 7-speed manual transmission. On vehicles produced in late 2012 (2013 model year) Rev Matching is available on the 7-speed manual transmission when equipped with the Sport Chrono package. Rev-Matching is a new feature with the manual transmission that blips the throttle during downshifts (if in Sport Plus mode). Also, the 7th gear cannot be engaged unless the car is already in 5th or 6th gear. One of Porsche’s primary objectives with the new model was to improve fuel economy as well as increase performance. In order to meet these objectives, Porsche introduced a number of new technologies in the 911. One of the most controversial of these is the introduction of electromechanical power steering instead of the previous hydraulic steering. This steering helps reduce fuel consumption, but some enthusiasts feel that the precise steering feedback for which the 911 is famous is reduced with the new system. The cars also feature an engine stop/start system that turns the engine off at red lights, as well as a coasting system that allows the engine to idle while maintaining speed on downhill gradients on highways. This allows for up to a 16% reduction in fuel consumption and emissions over the outgoing models. The new cars also have a number of technologies aimed at improving handling. The cars include a torque vectoring system (standard on the Carrera S and optional on the Carrera) which brakes the inner wheel of the car when going into turns. This helps the car to turn in quicker and with more precision. The cars also feature hydraulic engine mounts (which help reduce the inertia of the engine when going into turns) as part of the optional sports chrono package. Active suspension management is standard on the Carrera S and optional on the Carrera. This helps improve ride quality on straights while stiffening the suspension during aggressive driving. The new 991 is also equipped with a new feature called Porsche Dynamic Chassis Control (PDCC). Porsche claims that this new feature alone has shaved 4 seconds off the standard car’s lap time around the Nürburgring. PDCC helps the car corner flat and is said to improve high-speed directional stability and outright lateral body control, but according to several reviews, the car is more prone to understeer when equipped with this new technology. In January 2013, Porsche introduced the all-wheel-drive variants of the Carrera models. The ‘4’ and ‘4S’ models are distinguishable by wider tyres, marginally wider rear body-work and a red-reflector strip that sits in between the tail-lights. In terms of technology, the 4 and 4S models are equipped with an all-new variable all-wheel-drive system that sends power to the front wheels only when needed, giving the driver a sense of being in a rear-wheel-drive 911. In May 2013, Porsche announced changes to the model year 2014 911 Turbo and Turbo S models, increasing their power to 513 hp on the ‘Turbo’, and 552 hp on the ‘Turbo S’, giving them a 0–97 km/h acceleration time of 3.2 and 2.9 seconds, respectively. A rear-wheel steering system has also been incorporated on the Turbo models that steers the rear wheels in the opposite direction at low speeds or the same direction at high speeds to improve handling. During low-speed manoeuvres, this has the virtual effect of shortening the wheelbase, while at high speeds, it is virtually extending the wheelbase for higher driving stability and agility. In January 2014, Porsche introduced the new model year 2015 Targa 4 and Targa 4S models. These new models come equipped with an all-new roof technology with the original Targa design, now with an all-electric cabriolet roof along with the B-pillar and the glass ‘dome’ at the rear. In September 2015, Porsche introduced the second generation of 991 Carrera models at the Frankfurt Motor Show. Both Carrera and Carrera S models break with previous tradition by featuring a 3.0-litre turbocharged 6-cylinder boxer engine, marking the first time that a forced induction engine has been fitted to the base models within the 911 range
Porsche unveiled the facelifted 991.2 GT3 at the 2017 Geneva Motor Show. Extensive changes were made to the engine allowing for a 9,000 rpm redline from the 4.0 litre flat-six engine derived from Porsche 911 GT3 R and Cup racing cars. The engine has a power output of 500 PS (493 bhp) and 460 Nm (339 lb/ft) of torque. Porsche’s focus was on reducing internal friction to improve throttle response. Compared to the 991.1, the rear spoiler is 0.8 inch taller and located farther back to be more effective resulting in a 20% increase in downforce. There is a new front spoiler and changes to the rear suspension along with larger ram air ducts. The car generates 154 kg (340 lb) of downforce at top speed. The 991.2 GT3 brought back the choice between a manual transmission or a PDK dual clutch transmission. Performance figures include a 0-97 km/h (60 mph) acceleration time of 3.8 seconds (3.2 seconds for the PDK version) and a quarter mile time of 11.6 seconds. The GT3 can attain a top speed of 319 km/h (198 mph).
Completing the collection of 911 models was an example of the latest car, known as the 992.
There were a number of examples of the smaller Boxster and Cayman here, mostly the recent 981 generation.
One of the oldest cars of the evening, and one attracting a lot of interest was this immaculate looking 4CV. There seem to be several different accounts surrounding the conception of the car, one being that it was originally conceived and designed covertly by Renault engineers during the World War II German occupation of France, when the manufacturer was under strict orders to design and produce only commercial and military vehicles, in defiance of the direction of the boss, Louis Renault, whereas another version says that in 1940, he had directed his engineering team to “make him a car like the Germans’. Regardless, the truth is that work did go on during the war, with the occupying Germans who were keeping a watch on the company turning a blind eye to what came to be known as Project 106E. Certainly those working on the project were looking closely at the Volkswagen and their new car had a similar overall architecture to that, while recalling the modern designs of the fashionable front-engined passenger cars produced in Detroit during the earlier 1940s. The first prototype had only two doors and was completed in 1942, and two more prototypes were produced in the following three years. An important part of the 4CV’s success was due to the new methodologies used in its manufacture, pioneered by Pierre Bézier, who had begun his 42-year tenure at Renault as a tool setter, moving up to tool designer and then becoming head of the Tool Design Office. As Director of Production Engineering in 1949, he designed the transfer lines (or transfer machines) producing most of the mechanical parts for the 4CV. The transfer machines were high-performance work tools designed to machine engine blocks. While imprisoned during World War II, Bézier developed and improved on the automatic machine principle, introduced before the war by GM. The new transfer station with multiple workstations and electromagnetic heads (antecedents to robots), enabled different operations on a single part to be consecutively performed by transferring the part from one station to another. The 4CV was ultimately presented to the public and media at the 1946 Paris Motor Show and went on sale a year later. Volume production was said to have commenced at the company’s Billancourt plant a few weeks before the Paris Motor Show of October 1947, although the cars were in very short supply for the next year or so. Renault’s advertising highlighted the hundreds of machine-tools installed and processes adopted for the assembly of the first high volume car to be produced since the war, boasting that the little car was now no longer a prototype but a reality. On the 4CV’s launch, it was nicknamed “La motte de beurre” (the lump of butter); this was due to the combination of its shape and the fact that early deliveries all used surplus paint from the German Army vehicles of Rommel’s Afrika Korps, which were a sand-yellow colour. Later it was known affectionately as the “quatre pattes”, “four paws”.The 4CV was initially powered by a 760 cc rear-mounted four-cylinder engine coupled to a three-speed manual transmission. In 1950, the 760 cc unit was replaced by a 747 cc version of the “Ventoux” engine producing 17 hp. Despite an initial period of uncertainty and poor sales due to the ravaged state of the French economy, the 4CV had sold 37,000 units by mid-1949 and was the most popular car in France. Across the Rhine 1,760 4CVs were sold in West Germany in 1950, accounting for 23% of that country’s imported cars, and ranking second only to the Fiat 500 on the list. The car remained in production for more than another decade. Claimed power output increased subsequently to 21 hp as increased fuel octanes allowed for higher compression ratios, which along with the relatively low weight of the car (620 kg) enabled the manufacturers to report a 0–90 km/h (0–56 mph) time of 38 seconds and a top speed barely under 100 km/h (62 mph) The engine was notable also for its elasticity, the second and top gear both being usable for speeds between 5 and 100 km/h (3 and 62 mph); the absence of sy
nchromesh on first gear would presumably have discouraged use of the bottom gear except when starting from rest. The rear mounting of the engine meant that the steering could be highly geared while remaining relatively light; in the early cars, only 2¼ turns were needed from lock to lock. The unusually direct steering no doubt delighted some keen drivers, but road tests of the time nonetheless included warnings to take great care with the car’s handling on wet roads. In due course, the manufacturers switched from one extreme to the other, and on later cars 4½ turns were needed to turn the steering wheel from lock to lock. Early in 1953, Renault launched a stripped-down version of the 4CV bereft of anything which might be considered a luxury. Tyre width was reduced, and the dummy grille was removed from the front of the car along with the chrome headlamp surrounds. The seats were simplified and the number of bars incorporated in the steering wheel reduced from three to two. The only colour offered was grey. The car achieved its objective of retailing for less than 400,000 Francs. With the Dauphine already at an advanced stage of development it may have made sense to try and expand the 4CV’s own market coverage downwards in order to open up a clearer gap between the two models which would be produced in parallel for several years, but reaction to the down-market 4 CV, branded as the “Renault 4CV Service”, must have disappointed Renault as this version disappeared from the Renault showrooms after less than a year. The poor sales performance may have been linked to the growing popularity of the Citroën 2CV: although at this stage powered by an engine of just 375 cc and offering sclerotic performance, the 2CV was bigger than the Renault and in 1952 came with a starting price of just 341,870 francs The 4CV’s direct replacement was the Dauphine, launched in 1956, but the 4CV in fact remained in production until 1961. The 4CV was replaced by the Renault 4 which used the same engine as the 4CV and sold for a similar price.
In complete contrast was this Clio RS182. In 1999 Renault presented the first officially branded RenaultSport Clio, this was the third Clio produced by the RenaultSport division succeeding the Clio 16V and Clio Williams. This new Clio, the 172 was based on the 3 door Clio II shell however had numerous features over the standard car including wider arches, restyled bumpers, side skirts and 15-inch OZ F1 alloy wheels. Power was delivered by the F4R730 engine, a 2.0-litre 16-valve Inline 4 engine with a Variable valve timing (VVT) system via a dephaser on the intake camshaft pulley. The engine was a modified version of the F4R used in models such as the Laguna and Espace and was modified by Mecachrome to deliver a power output of 172 PS. Power was delivered to the wheels via a JC5-089 five-speed manual gearbox. The 172 also featured interior changes over the standard car including Half Leather, Half Alcantara seats embossed with the RenaultSport logo and the car also came standard with manually controlled Air Conditioning. A limited edition of the Phase 1 172 was produced and known as the Clio 172 Exclusive. This was limited to 172 units, all 172 of this “Exclusive” edition were 296 Scarab Green, featured BBS alloy wheels and a full leather interior as opposed to the half-leather half Alcantara seats featured in the standard car. In 2001 the interior and exterior of the Clio II were face-lifted, the Clio RS followed suit shortly after. This facelift of the Clio 172 included redesigned front and rear bumpers, the front bumper falling in line with the style of the face-lifted Clio II. The rear bumper was now less rounded and featured a strip of ABS plastic effectively splitting the bumper into two. The lights, bonnet and boot lid were also matched to the face-lifted Clio II. The interior was also changed to closer match that of the face-lifted Clio II, the seats were slightly revised however still featured the same Half Leather, Half Alcantara fabrics and the embossed RenaultSport logo. One new feature that the Phase 2 172 featured was automatic climate control as opposed to the manual air-conditioning featured in the Phase 1. The dashboard featured Silver interior trims and the steering wheel included a plastic insert featuring the RenaultSport logo. The gear shifter was changed from the metal ball featured on the Phase 1 to a Leather wrapped shifter with a silver coloured insert on the top. The Phase 2 172 also featured increased equipment including automatic Xenon headlights and headlight washers, Rain Sensing wipers a six-disc CD changer, and it also included side-impact airbags integrated into the seats. The 15-inch OZ F1 alloy wheels were also replaced with a 16-inch Alloy Wheel of Renault’s own design. The facelift of the 172 also brought about a number of changes to the engine of the car. A revised version of the F4R used, the F4R 736, this featured a revised cylinder head with the exhaust ports being approximately 30% smaller than those featured on the Phase 1 172. The airbox was also redesigned to be much more square than the original airbox. A revised version of the JC5 gearbox, the JC5-129 was introduced in this version of the Clio 172, which revised JC5 featured a shorter final drive to counter the increased weight of the face-lifted 172. The catalytic converter, which on the PH1 172 had been dual barrel was reduced to a single barrel and featured 2 lambda sensors, one before and one after the catalytic converter. The biggest change to the PH2 172 over the PH1 was the introduction of an electric throttle. This meant the Idle Control Valve of the PH1 was no longer required leading to a minor redesign of the intake manifold. In 2002 Renault released the 172 Cup, which bore the chassis code CB1N and was known by Renault as the “sport lightweight version”. The vast majority of cars were produced in D43 Mondial Blue (metallic) with a limited run of around 90 cars being produced in 640 Iceberg Silver (metallic). The Cup, originally built for Gr.N homologation of the Clio 172 was differentiated from the “non cup” 172 by
its lack of many of the luxuries included in the regular car. Instead of the leather / Alcantara seats instead the same style seat was upholstered in a durable but low-cost fabric, the automatic Xenon headlights were replaced by manually controlled halogen units and the washer jets replaced with blanks. The rain sensing wipers and solar reflective coated windscreen were also omitted from the 172 Cup. However the car had features not before seen on a production version of the 172, which included lightweight 16-inch Speedline Turini alloy wheels, matte blue door strips, ABS plastic “Cup” front splitter and a restyled “Cup” rear spoiler. The dash strips which were silver on the regular car were painted to match the outside of the car. One of the main features of the 172 Cup was its significant weight saving, having a kerb weight of 1021 kg, making it the lightest of 172 versions produced. This was achieved by the removal of a majority of sound deadening from the car alongside thinner glass to reduce weight even further. One large difference was also the lack of air conditioning which was a standard fit component on the regular 172, which typically led to the cup producing more power due to the engine having less ancillaries to drive. This however was reintroduced as an optional extra later in the production run of the Cup. The 0–60 time of the 172 Cup was officially marketed by Renault as being 6.5 seconds; however AutoCar Magazine reportedly timed the 0–60 at 6.2 seconds which if this were the case would make the 172 Cup the second fastest road going Clio produced at the time of this article, second to only the V6. Many enthusiasts regard the 172 Cup as the last “hardcore” hot hatch due to its lack of anti-lock brakes; the car also featured modified suspension which gave it a wider track thanks to modified wishbones, the car also sat lower than standard and featured stiffer shocks and springs, the suspension geometry was revised to suit these components and to mean that the steering response was increased, this also lead to an increase in oversteer thanks to the lack of weight and revised geometry. Due to the lack of ABS the brake bias of the car was fixed by way of disconnecting the rear axle compensator, within the UK this often lead to the cars failing the MOT test, VOSA eventually issued an advisory to prevent this from happening. 2004 marked yet another refresh of the Clio II. The inserts of the headlights were changed from Black to Grey, new wheels styles were introduced and new colour options were added with others being dropped. The basic design of the car stayed the same with only minor changes. The Six-Disc CD changer was dropped as standard equipment however was still available as a cost option. This refresh marked the introduction of cruise control and Electronic Stability Program (ESP) as standard equipment. The Clio RS featured a lot more changes than the regular Clio. The engine was again revised and became the F4R 738. The difference between the F4R 738 and F4R 736 was a revised oil breather setup meaning the intake manifold found on a 172 would not fit a 182. Thanks to a number of other changes this engine produced 182 PS . This increase in power was thanks to the addition of a 4-2-1 Manifold and high flow 200 cell sports catalytic converter. The spare wheel well was removed and replaced with a flat floor to make way for the new dual exit exhaust featured on the 182. Minor revisions were made to the interior, the perforated texture of the Alcantara on the seats now featured white dots. The car also featured a new 8 spoke wheel design which came in Silver on a regular car and Anthracite on a “Cup Packed” car. The rarest optional extra available was the Carminat Sat-Nav which was fitted to very few cars. However, the unit wasn’t a popular option due to its high cost and rumoured poor performance compared to aftermarket options. The “Cup” Front Splitter and “Cup” Spoiler originally fitted to the 172 Cup made a reappearance as a cost option known as the Cup Style Pack. This was one of two cup packs available, the other being the Cup Chassis. This Cup Chassis pack included a strengthened hub with 60mm spacing on the strut bolt holes as opposed 54mm on non cup packed cars. The Cup Chassis also featured lowered suspension with stiffer shocks and springs and an anthracite version of the standard alloy wheels. The Clio 182 could also be ordered in a more race focused than ‘base’ RS model called “Cup Specification”, this was available in just two colours, J45 Racing Blue and D38 Inferno Orange, however came as Standard with the Cup Chassis and Cup Style Pack. The 182 Cup lacked the automatic Xenon headlights and headlight washer jets, climate control (rear footwell heater vents were also removed), illuminated sun visors, Solar Reflective Windscreen and Automatic Wipers. The leather / Alcantara seats were replaced with cloth items and the rear bench was downgraded to match. The engine cover and sill plates were removed and the steering wheel was downgraded to no longer include the RenaultSport Logo or rubber thumb grips. Carpet and headlining were downgraded to basic specification and even the documentation wallet was changed from faux leather to cloth. Sound deadening was removed from the 182 Cup, the horn was downgraded from a twin to single unit and the interior light no longer included a map reading function. Despite all of these reductions in specification the 182 Cup was still considerably heavier than the previous 172 Cup, meaning this version of the Clio II RS was considered one of the least desirable versions. The final version of the Clio 182 was known as the 182 Trophy. This version was based on the 182 Cup and featured the same strengthened hubs with 60 mm bolt spacing. Originally only 500 cars were to be produced for the UK market however an additional 50 were produced to be sold in Switzerland. At the time, believing there was no market for this version of the Clio, the Marketing Department of Renault France failed to order a 182 Trophy. The 182 Trophy included 16 Inch Speedline Turini Alloy wheels as seen on the 172 Cup, the Spoiler from the Clio 255 V6, Recaro Trendline seats and exclusive 727 Capsicum Red Paint with Trophy Decals lacquered onto the Side skirts. Each car had an individually numbered plaque on the base of the driver’s seat. The biggest difference however between the 182 Cup and 182 Trophy was the inclusion of Sachs Remote-Reservoir dampers. The basic principle of a Remote-Reservoir damper is that because there is a separate reservoir for the gas or oil which fills the shock they can either be of a reduced length or can house a longer rod, this means that the sizing of the shock can be optimised for the application in which it is being used. These changes definitely made a big difference to the 182 Trophy and have led to its being heralded as one of the best hot hatches of all time and it won Evo Magazine’s “People’s Performance Car of The Year” 2005, whilst also beating off rivals such as the Lamborghini Gallardo and other exotica in an Evo Magazine Group Test. AutoCar Magazine’s front cover from 5 July 2005 simply stated “World’s Greatest Hot Hatch”.
The A110 was introduced as an evolution of the A108. Like other road-going Alpines, the 1961 A110 used many Renault parts – including engines. But while the preceding A108 was designed around Dauphine components, the A110 was updated to use R8 parts. Unlike the A108, which was available first as a cabriolet and only later as a coupé, the A110 was delivered first with “Berlinetta” bodywork and then as a cabriolet. The main visible difference with the A108 coupé was a restyling of the rear body to fit the larger engine, which gave the car a more aggressive look. Like the A108, the A110 featured a steel backbone chassis with fibreglass body. The A110 was originally available with 1.1 litre R8 Major or R8 Gordini engines. The Gordini engine delivered 95 hp at 6,500 rpm. The A110 achieved most of its fame in the early 1970s as a victorious rally car. After winning several rallies in France in the late 1960s with iron-cast R8 Gordini engines the car was fitted with the aluminium-block Renault 16 TS engine. With two dual-chamber Weber 45 carburettors, the TS engine delivered 125 hp at 6,000 rpm. This allowed the production 1600S to reach a top speed of 210 km/h (130 mph). The longer wheelbase 2+2 Alpine GT4, originally considered a version of the A108, was updated with A110 engines and mechanicals, now being marketed as the “A110 GT4”. The car reached international fame during the 1970–1972 seasons when it participated in the newly created International Championship for Manufacturers, winning several events around Europe and being considered one of the strongest rally cars of its time. Notable performances from the car included victory in the 1971 Monte Carlo Rally with Swedish driver Ove Andersson. With the buy-out of Alpine by Renault complete, the International Championship was replaced by the World Rally Championship for 1973, at which time Renault elected to compete with the A110. With a team featuring Bernard Darniche, Jean-Pierre Nicolas and Jean-Luc Thérier as permanent drivers and “guest stars” like Jean-Claude Andruet (who won the 1973 Monte Carlo Rally) the A110 won most races where the works team was entered, making Alpine the first World Rally Champion. Later competition-spec A110s received engines of up to 1.8 litres. As well as being built at Alpine’s Dieppe factory, A110 models were constructed by various other vehicle manufacturers around the world. The Alpine A110 was produced in Mexico under the name “Dinalpin”, from 1965 to 1974, by Diesel Nacional (DINA), which also produced Renault vehicles. The Alpine A110 was also produced in Bulgaria under the name “Bulgaralpine”, from 1967 to 1969, by a cooperative formed between SPC Metalhim and ETO Bulet, whose collaboration also resulted in the production of the Bulgarrenault. In 1974 the mid-engined Lancia Stratos, the first car designed from scratch for rally racing, was operational and homologated. At the same time, it was obvious that the tail-engined A110 had begun reaching the end of its development. The adoption of fuel injection brought no performance increase. On some cars, a DOHC 16-valve head was fitted to the engine, but it proved unreliable. Chassis modification, like the use of an A310 double wishbone rear suspension, homologated with the A110 1600SC, also failed to increase performance. On the international stage, the Stratos proved to be the “ultimate weapon”, making the A110, as well as many other rally cars, soon obsolete.
The new A110 has been on sale for a couple of years now, and whilst total sales have levelled off once the initial demand was satisfied, there are often examples of the car at enthusiast events like this and indeed there was one here.
The first Sunbeam to bear the Alpine name was an open-topped version of the Sunbeam-Talbot 90 sports saloon, named after the model’s success in rallying, especially the Monte Carlo rally, launched in 1953. Kenneth Howes and Jeff Crompton were tasked with doing a complete redesign in 1956, with the goal of producing a dedicated sports car aimed principally at the US market to compete with the MGs and Triumphs that were very popular. Ken Howes contributed some 80 per cent of the overall design work, which bears more than incidental resemblance to the early Ford Thunderbird, hardly a surprise, as Howe had worked at Ford before joining Rootes. The Alpine was produced in four subsequent revisions until 1968. Total production numbered around 70,000. Production stopped shortly after the Chrysler takeover of the Rootes Group. Styled by the Loewy Studios for the Rootes Group, the “Series” Alpine started production in late 1959. One of the original prototypes still survives and was raced by British Touring car champion Bernard Unett. The car made extensive use of components from other Rootes Group vehicles and was built on a modified floorpan from the Hillman Husky estate car. The Series I used a 1,494 cc engine with dual downdraft carburettors, a soft top that could be hidden by special integral covers and the first available wind-up side windows offered in a British sports car of that time. The running gear came mainly from the Sunbeam Rapier, but with front disc brakes replacing the saloon car’s drums. An overdrive unit and wire wheels were optional. The suspension was independent at the front using coil springs and at the rear had a live axle and semi-elliptic springing. The Girling-manufactured brakes used 9.5 in discs at the front and 9 in drums at the rear. An open car with overdrive was tested by The Motor in 1959. It had a top speed of 99.5 mph and could accelerate from 0–60 mph in 13.6 seconds. A fuel consumption of 31.4 mpg was recorded. The test car cost £1031 including taxes. 11,904 examples of the series I were produced. The Series II of 1962 featured an enlarged 1,592 cc engine producing 80 bhp and revised rear suspension, but there were few other changes. When it was replaced in 1963, 19,956 had been made. The Series III was produced in open and removable hardtop versions. On the hardtop version the top could be removed and the soft-top was stored behind the small rear seat; also the 1592 cc engine was less powerful. To provide more room in the boot, twin fuel tanks in the rear wings were fitted. Quarter light were fitted to the windows. Between 1963 and 1964, 5863 were made. For the Series IV, made in 1964 and 1965, there was no longer a lower-output engine option; the convertible and hardtop versions shared the same 82 bhp engine with single Solex carburettor. A new rear styling was introduced with the fins largely removed. Automatic transmission with floor-mounted control became an option, but was unpopular. From autumn 1964 a new manual gearbox with synchromesh on first gear was adopted in line with its use in other Rootes cars. A total of 12,406 were made. The final version was the Series V, produced between 1965–68 which had the new five-bearing 1,725 cc engine with twin Zenith-Stromberg semi-downdraught carburettors producing 93 bhp. There was no longer an automatic transmission option. 19,122 were made.
This is one of a large number of Toyota models which were not sold new in the UK or Europe and is a Chaser Hardtop. In September 1996, the X100 Chaser replaced the X90 Chaser. The product lineup consisted mostly of Avante and Tourer trim, with the Avante as the luxury model (with more interior accessories) and the Tourer as the sporty model (with large 16-inch wheels). Toyota’s VVTi, the company’s version of variable-valve timing, was added to the 1JZ engines; they were also upgraded to have more torque, since they had already reached the agreed voluntary limit set by Japanese Automobile Manufacturer’s Association regarding horsepower. The 1JZ-GTE was powered by a single turbo configuration instead of the twin turbo of its predecessors. New to the lineup was the Avante Four and the Avante Four G Package (basically the Avante 2.5 L with a full-time 4WD system). These cars were only available with a 4-speed electronic control type (ECT) automatic transmission. The Tourer V and the automatic-only Avante G 3.0 L (2JZ) models had the option of electronic control flex lockup attaching 4-speed automatic (intelligent) (ECT-iE) transmission, besides the ECT-E automatic in the lower-end models. In 1997, the lineup remained largely unchanged, although a basic Tourer 2.0 L model was added. The Tourer was powered by a 1G-FE engine, rated at 140 PS at 5,600 rpm. It was sold with only the 4-speed electronic control type (ECT) automatic transmission. In 1998, the base Tourer model received the optional manual gearbox and a 4WD option was added to the base Avante models; the Avante Four S Package received a higher special-edition interior. Additionally, the Chaser received a facelift, with the most significant changes to the rear tail lights. Other changes included new fog lights with a slightly redesigned front bar to accommodate them, different interior fabric, a 3-spoke steering wheel instead of 4 spokes, orange gauge lighting instead of white and a grille with 2 horizontal bars instead of 3. The Chaser was discontinued in June 2001. It was replaced with a new model called the Verossa which shared the same model code. The Cresta suffered the same fate, but the Mark II continued for another generation (X110) before it was also discontinued. In 2004, the all-new X120 Mark X was introduced in Japan, incorporating many characteristics of the Chaser and the Cresta. In fact, the aim of the Mark X was to combine the characteristics of the 3 models into one single model.
The Yaris GR is a definite “car of the moment”, following its rave reception last autumn. Long waits are in store for those ordering the car at present, but clearly those who got in early have now received their cars and I am seeing more and more of them where enthusiasts are gathered. There was one here.
Envisioned as a luxury sports car, the Stag 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.
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.”
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.
Taking its name from the Greek name of a lightweight battle-axe used by the Scythians which was feared for its ability to penetrate the armour of their enemies, the final TVR model to be seen here was a Sagaris, a car which made its debut at the MPH03 Auto Show in 2003. The pre-production model was then shown at the 2004 Birmingham Motorshow. In 2005 the production model was released for public sale at TVR dealerships around the world. Based on the TVR T350, the Sagaris was designed with endurance racing in mind. Several design features of the production model lend themselves to TVR’s intentions to use the car for such racing. The multitude of air vents, intake openings and other features on the bodywork allow the car to be driven for extended periods of time on race tracks with no modifications required for cooling and ventilation. The final production model came with several variations from the pre-production show models such as the vents on the wings not being cut out, different wing mirrors, location of the fuel filler and bonnet hinges. As with all modern TVRs the Sagaris ignored the European Union guideline that all new cars should be fitted with ABS and at least front airbags because Peter Wheeler believed that such devices promote overconfidence and risk the life of a driver in the event of a rollover, which TVRs are engineered to resist. It also eschewed electronic driver’s aids (such as traction control or electronic stability control). In 2008, TVR unveiled the Sagaris 2, which was designed to replace the original Sagaris. In the prototype revealed, there were minor changes to the car including a revised rear fascia and exhaust system, and modifications to the interior. Sagaris models. on the rare occasions that they come up for sale, are pricey.
Follow on to the Prince Henry was the 30/98. Constructed at the behest of car dealer and motor sport competitor Joseph Higginson, inventor of the Autovac fuel lifter, he won the Shelsley Walsh hill-climb motoring competition on 7 June 1913 in his new Vauxhall, setting a hill record in the process, having in previous weeks made fastest time of the day at Waddington Pike and Aston Clinton. The 30-98s used the Prince Henry chassis, they were distinguished by having more-or-less flat rather than V-shaped radiators. Laurence Pomeroy took the Prince Henry L-head side-valve engine, bored it out 3 mm, then cold-stretched the crankshaft throws 5 mm using a steam power hammer to lengthen the stroke. The camshaft was given a new chain drive at the front of the engine, high lift cams and new tappet clearances. The Prince Henry chassis was slightly modified and the whole given a narrow alloy four-seater body, a pair of alloy wings and no doors. Before war intervened only 13 30-98s were made and they were for selected drivers, the last in 1915 for Percy Kidner a joint managing director of Vauxhall. Actual production did not really begin until 1919. The 30-98 name is believed to have been coined because the car had an output of 30 bhp at 1,000 rpm and 98 bhp at 3,000 rpm but another explanation is that it had an RAC horsepower rating of 30 and a cylinder bore of 98 mm though perhaps the most likely of all is that there was then a popular but heavier slower Mercedes 38/90. However it was found, the name 30-98 looked and sounded so well. The 30/98 was not really a racing machines but a fast touring car. The exhaust made a tranquillising rumble, there was no howl, no shriek, no wail. But there was the quiet satisfaction, if stripped for action, the car could lap Brooklands at 100 mph. The makers guaranteed that. Some owners had to watch their car being given the test to be reassured. Production continued until 1927.
The Westfield Megabusa is a British-made Lotus Seven inspired car with a 1,299 cc motorcycle engine, taken from the Suzuki Hayabusa, and six-speed sequential gearbox. The Megabusa is a road legal track car in at least some European countries.
Needless to say, this was a most enjoyable evening. The venue was packed out with cars, with lots to see, and not just those of Italian origin. Indeed, I was so busy with the camera and talking to people – both Abarth owners and others – that I never actually got as far as finding any food! There is no doubt that this event – helped by some good weather on this occasion – has captured the imagination of many, and now can count on support as big as that for the venue’s Breakfast Clubs. There are two more of them scheduled for the remainder of the year and I certainly plan to attend them.