Wheels on Wednesday at Morgan – September 2023

Just a few days after the final “Wheels on Wednesday” event at Spetchley Park for the 2023 season came another meeting organised by the same team, this one being held at the Morgan Cars factory in Malvern Link, a venue which Robin Webb and his organiser team have used on a number of occasions in the past, as a joint venture with Morgan themselves. There is not as much space here as there is at Spetchley Park, but there is still room for around 300 cars, as there is a large field area behind the showroom and museum buildings and this was fully used for this event, as it almost always is. There was lots September sunshine for this event but by mid September, it pays to remember that the day light will start to face not long after 7pm, so most people tend to arrive early and don’t stay that long. I planned my visit accordingly. There were already plenty of cars parked up when I arrive and a lot more poured into the site for quite a while after that. Here are the automotive highlights of the evening:

ABARTH

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.

Picture 264

AC

Genuine Cobra cars from the 1960s are exceedingly rare, but almost ever since there have been large numbers of continuation series, replicas and recreations built, so the basic style of the car is one you see quite frequently There were a couple here one of which (the black one) is a Pilgrim. Pilgrim have been building cars since the sixties. From humble beginnings of single car-builds to a fully functioning large factory in the mid-eighties, Pilgrim’s huge success was largely down to its recreation of the famous AC Cobra. A few years later the Pilgrim Speedster was introduced. Both replicas were and remain very popular, in both factory-build form or build-your-own. Pilgrim Motorsports have now built over 14,000 bespoke cars with the majority being Cobras. The first Sumo cars were based on a mark 2 Ford Cortina but when supplies of those ran out, they switched to other Ford chassis including the Granada and Sierra. More recent cars have had 7 litre Chevrolet engines installed. This car was ordered in 2016.

Picture 299 Picture 298

ALFA ROMEO

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

Picture 301

ASTON MARTIN

The latest and still current Aston Martin Vantage was unveiled on 21 November 2017 with production starting in June 2018, replacing the previous model which had been in production for 12 years. It introduced a new styling direction but this was not universally well received and the car had a hefty price increase over its predecessor. Muted press enthusiasm did not help and sales have been disappointing. Aston Martin have continued to develop the model with a number of new versions introduced, to try to improve demand. The Vantage AMR is a track-focused variant of the Vantage. The main highlight of the model is the replacement of the ZF 8-speed automatic transmission with a dog-leg Graziano Trasmissioni 7-speed manual transmission previously used on the V12 Vantage S. The AMR also comes with a driver-selectable AMSHIFT system which controls the throttle during gear shifting. A new limited-slip differential ensures linear delivery of power. The power-band of the engine is wider and the unit is designed to deliver 625 Nm (461 lb/ft) of torque from 2,000 rpm to 5,000 rpm. The use of a manual transmission and carbon-ceramic brakes reduce the weight by 95 kg (209 lb). New adaptive dampers with the section of Sport, Sport + and Track modes improve handling. Performance figures include a 0–97 km/h (60 mph) acceleration time of 3.9 seconds, half a second more than the standard Vantage while the top speed remains the same as the standard model. Visual changes include 20-inch forged wheels as available on the Rapide AMR, new carbon fibre side vents and cooling vents present on the hood a sports exhaust system with quad tailpipes and racing bucket seats. Production of the AMR will be limited to 200 units worldwide. Available exterior colours for the AMR include Sabiro Blue, Pnyx Black, China Grey and White Stone. The final 59 cars will be finished in a Sterling Green exterior colour with Lime accents and will pay homage to the 1959 24 Hours of LeMans victory of Aston Martin. Once the production of the AMR ceases, the 7-speed manual transmission will become available on the standard Vantage. The vehicle went on sale in May 2019, with delivery set to begin in Q4 2019. Revealed in February 2020, the Vantage Roadster is a convertible version of the V8 Coupe with a fabric roof. The roof claimed to be the fastest of any automotive automatic convertible system, takes 6.7 seconds to lower and 6.8 seconds to raise and can be operated at speeds of up to 50 km/h (31 mph). The Vantage Roadster has a dry weight of 1,628 kg (3,589 lb). The F1 Edition is a version of the V8 Coupe and V8 Roadster commemorating Aston Martin’s return to Formula One after 61 years. The car features a fixed rear wing at the back, increased engine power to 535 PS (528 bhp), a top speed of 314 km/h (195 mph), new 21-inch wheel rims, and a 0–100 km/h (0–62 mph) acceleration time of 3.5 seconds. The car is available in three colours: Aston Martin Racing Green, Jet Black, and Lunar White. A convertible version called the Roadster is also available. Delivery began in May 2021.

Picture 255

Also here was the recently superceded DB11.

Picture 339 Picture 338

AUDI

The first Audi 100, developed by Auto Union (Volkswagen’s subsidiary) in Ingolstadt, was unveiled as a four-door sedan on November 26, 1968. Its name originally denoting a power output of 100 PS, the Audi 100 was the company’s largest car since the revival of the Audi brand by Volkswagen in 1965. The C1 platform spawned several variants: the Audi 100 two- and four-door saloons, and the Audi 100 Coupé S, a fastback coupé, which bore a resemblance to the Aston Martin DBS released a year earlier with similar details such as the louvres behind the rear side windows and the shape of the rear light clusters. Audi followed the introduction of the four-door saloon in November 1968 with a two-door saloon in October 1969 and the 100 Coupé S in autumn 1970. The cars’ 1.8 litre four cylinder engines originally came in base 100 (79 bhp), 100 S (89 bhp), and 100 LS (99 bhp) versions, while the coupé was powered by a bored-out 1.9 litre developing 113b hp. From April 1970 the 100 LS could be ordered with a three-speed automatic transmission sourced from Volkswagen. Although the Audi 100’s engines were considered ‘rough’, critics stated that buyers whose first car had been a Beetle and aspired to upgrade to a contemporary diesel-powered Mercedes-Benz were unlikely to be discouraged. The Ingolstadt production line was at full capacity, yet fell short of demand during the summer of 1970 and an additional line was set up in Volkswagen’s own Wolfsburg plant, which made it the first water cooled car produced there. For the Swiss market, the 100 LS was equipped with a version of the 1.8 litre engine bored out by 0.5 mm (0.020 in), producing 107 PS. This placed the engine above the 9 horsepower tax threshold in the 19 cantons where this system was in use; why this was desired is unknown. Starting with the 1972 model year, the 80 and 90 PS versions were replaced by a new regular petrol variant of the 1.8 litre engine developing 85 PS; at the same time, the 100 GL was introduced featuring the 1.9–litre engine formerly used only in the Coupé S. In March 1971, the 500,000th Audi was produced. By now the Audi 100 had become the most commercially successful model in the company’s history.[8] In 1976 the two millionth Audi was built, of which the 100 represented 800,000 cars. In September 1973 (for the 1974 model year) the 100 received a facelift with a somewhat smaller squared-off grille, correspondingly more angular front fenders, and changed taillight lens patterns. The rear torsion beam suspension was replaced by coil springs. For the model year 1975, the base 100 was renamed the 100 L and received a 1.6 litre four cylinder engine (coming out of the Audi 80). A four-wheel drive prototype of the Audi 100 C1 was built in 1976, long before the appearance of quattro. In South Africa, where the 100 was also assembled, the 100 was available as the L, LS, GL, and S Coupé. Local production began towards the end of 1972; by October 1976 33,000 units had been built in South Africa. The GL received a vinyl roof and “GL” lettering on the C-pillar. The LS was dropped for 1976, but returned for 1977 along with the new GLS saloon. The Coupé was discontinued. The LS and GLS were special versions of the L and GL, with silver paintjobs, automatic transmissions, and special red interiors. L and LS have a 1760 cc engine with 101 bhp, while the GL and GLS have the larger 1871 cc engine producing 113 hp. A replacement model was launched in the summer of 1976, UK sales starting early in 1977.

Picture 350

The Audi Coupé (B2, Typ 81/85) was produced from 1980 to 1988, as a less expensive version of its turbocharged, permanent four-wheel drive Audi Quattro without turbocharger(s) or four wheel drive. Later, quattro was added as an option (Typ 85). Typ 81 was the internal model code for front-wheel drive Audi Coupés. The Coupé, first displayed at the Paris Salon 1980, featured a similar body shape to the Quattro, but without the knife-edged fender flares of the more expensive car. Mechanically, the biggest changes from the Quattro to the Coupé were the use of a naturally aspirated 1.9-litre carburettor petrol engine, 2.0-litre, 2.1-, 2.2-, or 2.3-litre fuel injected inline five-cylinder engine and a front-wheel drive drivetrain. Some lesser Coupés were also fitted with a 1.8-litre inline four-cylinder engine, injected or carburetted, and for the very first year of production a 1.6-litre “YN” 75 PS engine was available. The short-lived 1.6 was the only Coupé not to be fitted with a black rear spoiler. The Coupé was available as just plain “Coupé” or GL (four-cylinders only), “Coupé GT”, and “Coupé quattro” (without the GT tag). From 1986 until the end of production in late 1988, the Coupé GT was also available with the 110–112 PS 1.8-litre PV/DZ inline-four best known from the Golf GTi. For the last model year, the new 2,309 cc “NG” five cylinder was available, offering 136 PS at 5,600 rpm. This engine became available during 1987 for the last of the Audi Coupés sold in the US, where it produced 130 hp at 5,700 rpm as opposed to the 110 hp at 5,500 rpm available from the 2.2-litre five which had been used since the facelift for model year 1985. The Coupé had originally gone on sale in the US late in model year 1981 with the 100 hp 2,144 cc five-cylinder also used in the 5000 (Audi 100). The updated Coupé, introduced after the German industrial holidays in the autumn of 1984, was given new, slightly sloped radiator grille and headlights, a large wrap-around bumper with integrated spotlights and turn signals, plastic sill covers, and the large rear spoiler from the Audi Quattro. These changes brought the drag coefficient down to 0.36. A new dashboard was also introduced, as was a new interior. GL and standard versions were cancelled for model year 1987 and all FWD Coupés were from then referred to as “Coupé GT”. For the 1986 model year, the Coupés (as with all Audis) were available with more catalysed engine options. Also, the entire B2 range (Audi 80/90/Coupé) received stainless steel exhausts (for European markets at least). Also in September 1984, Audi made available the option of the quattro permanent four-wheel drive system to produce the Audi Coupé quattro, a model which was rarer than the turbocharged Quattro model. While most common with the 2.2-litre engine (also 2.3 for the last year, introduced 1987 for the US), in some markets the 1.8-litre four-cylinder models (90 and 112 PS engines) were also available with four-wheel drive. The Coupé and Coupé quattro models appear almost identical from the outside except for a few minor “quattro” specifics. While the GT had “COUPE GT” on the rear side windows, the CQ had the “quattro” decal as used on the Ur-Quattro. Similarly at the rear, the badging was “GT” and “quattro” respectively. The quattro versions also used the Ur-Quattro rear windscreen with “quattro” written into the heater elements (very obviously so on a cold and frosty morning), and the front grille was also adorned with the “quattro” badge from the Ur-Q. Inside, the cabin was identical except that the centre console received a differential lock switch, and LED bargraph displays in place of the GT’s three analogue-style gauges. Some Coupé quattros were distinguished by a body-coloured rear spoiler. Mechanically, the Coupé quattro depended on a combination of components from the GT and the Audi 80 quattro. The quattro permanent four-wheel drive drivetrain was almost identical to that used on the Ur-Quattro – the main differences being the use of the Coupé GT front struts, smaller 256 mm (10 in) diameter front brake disks, and lower ratios in the gearbox and rear differential. The damper and spring rates were also different from the Ur-Q. It was thus largely identical to the Audi 90 quattro and the North American Audi 4000 quattro. Wheels were 6.0Jx14″, with steel or aluminium alloy rims dependent on the market. 7.0Jx15″ Ronals, almost identical to the Ur-Quattro wheels, were also available. The CQ/90Q/4000Q also received their own exhaust manifold and downpipe. From September 1980 to September 1987, 174,687 Typ 81 Coupés were built. Quattro production ran from late 1984 to 1988, and was in the total region of 8,000 cars.

Picture 273 Picture 274 Picture 275

The Audi A2 (internally designated Typ 8Z) is a lightweight compact MPV-styled supermini car, with a five-door hatchback body style and four or five seats, produced by the German manufacturer Audi from November 1999 to August 2005. Based on the Audi Al2 concept car first shown at the Frankfurt Motor Show in 1997, the A2 was notable for being constructed from aluminium, which in combination with its efficient engines, made it an extremely economical car on fuel. Packages available in Germany included ‘Advance’, ‘Style’, ‘High Tech’, and later ‘S line’; whereas in the United Kingdom, the A2 was available in various trim levels, including: ‘Standard’, ‘SE’ (for ‘Special Equipment’), ‘Sport’, ‘Special Edition’ (2005 only). The A2 was produced at Audi’s “aluminium” Neckarsulm plant in Germany on a special line purpose-built for it. It was the first five-door vehicle on sale in Europe with an average fuel consumption less than 3 l/100 km (94.2 mpg‑imp; 78.4 mpg‑US), although these figures only applied to the special “3L” version with a diesel engine, automatic gearbox, stop-start system, less power and narrower tyres. Due to its construction, the average A2 weighs 830 kg. The last A2s to be produced were built in August 2005. The A2 was a surprise when it debuted only two years after the original Al2 study. The avant-garde styling did not, however, win favour with some potential customers. Audi was reported to be disappointed with the level of sales. The final production was only 176,377 units, in comparison to rival Mercedes-Benz’s A-Class sales of 1 million. The overriding theme in the design and engineering of the A2 was summarized by the then Audi UK product manager in an interview after the car won a design award in 2001 as “create a small Audi, not a cheap Audi”, and the creative brief is said to have been “Transport four people from Stuttgart to Milan on a single tank of petrol”. The A2 is built with a considerable amount of aluminium and aluminium alloy, making it weigh significantly less than cars of similar size. Its reduced weight helps it to use much less fuel than vehicles using traditional steel monocoques. Under certain circumstances, consumption for the 1.2 TDI model can be as low as just over 2 l/100 km (140 mpg‑imp; 120 mpg‑US). This version of the Audi A2 won the “Nordic Eco Run” fuel economy race in 2003, with a consumption of 2.62 L/100 km (107.8 mpg‑imp; 89.8 mpg‑US). Even the normal versions with petrol engines are capable of 5 L/100 km (56.5 mpg‑imp; 47.0 mpg‑US). The A2 was also notable for being the first Audi model since the 1970s Audi 50 (type 86) and Audi 100 (type 43) not to be offered with its ‘trademark’ quattro four-wheel drive option. The A2 has a coefficient of drag of between 0.25 and 0.29, depending on the specific version. The A2 still uses a contemporary unibody construction, with significant elements of space frame principles, and it is tagged by Audi as an ‘Audi Space Frame’ design. The outer panels of the body have little or no structural function – similarities exist with the original Renault Espace – and the space frame bears the forces working on the car. The frame uses casts and extrusions which are laser welded together to make the space frame. Improvements in shell stability, durability and stiffness, lower weight, and more interior space are results of its construction. “The A2, on the other hand, was designed as an aluminum car and the spaceframe has been optimized by parts consolidation, using large, cost-effective castings instead of aluminium stampings”. Unfortunately, the cost of working with aluminium, particularly with small production runs, meant that the A2 was more expensive than other cars in its sector, competing with the A-class and losing. Much of the high production cost was due to so many parts not being “off the shelf” and being specifically optimized for the A2. From Autobild in 2003: “The A2 is not one of the models with the highest return on investment”. The same article quotes the sales figures for 2002 as being 20,000 in Germany against 80,000 for the A-Class and “…lots of money for a car that is only 3.8m long.” Audi was the first manufacturer to try to incorporate lightweight building concepts using aluminium and associated alloys into a “mass market” vehicle. Previous efforts at using the Audi Space Frame were limited to the rather more expensive Audi A8. As a guide to the mass involved, the entire shell weighs so little that two people can easily pick it up, and the side panel over the doors including the A- and D-pillars weighs approximately 2 kg (4 lb). A 2002 model A2 with standard equipment has a mass of 895 kg (1,973 lb). The A2 can thus be considered a trailblazer for various newer aluminium-based vehicles, such as the second generation Audi A8, the Audi TT, and Jaguar’s X350 Jaguar XJ and 2006 Jaguar XK. Parts of the A2 which are still made of steel include the bulkhead behind the front bumper (the “slam panel”), the wiper arm, standard A2 suspension components (the 3 L ones are frequently of aluminium alloy), the rear brake drums and the exhaust system. The A2 has a large interior space for the exterior dimensions, including a boot with 390 litres (13.8 cu ft) of space when the rear seats are in place. This is significantly larger than the luggage space of the next model in Audi’s range, the Audi A3. Due to the “sandwich”-type construction, similar again to that of the Renault Espace or the Mercedes A-Class, the floorpan has an upper and a lower portion. The space in the middle is used to house various components, such as the fuel tank and the engine’s electronics. The rear passengers also benefit, as their foot space reaches into this sandwich space, creating a comfortable seating position even for tall rear seat passengers. This is in direct contrast to the comfort available on the rear bench of an A-Class. To improve the weight distribution of the vehicle, its battery is located inside the boot, under the floor. The A2’s interior was very upmarket in comparison with other superminis. In both the UK and Europe, there were several choices of seat material and colour, comprising the standard Cirrus cloth, optional Matrix cloth, optional Alcantara/leather, or full pearl Nappa leather seat coverings. Sport models received sport seats with electrically adjustable lumbar support as standard in jacquard satin cloth. Seat materials were available in a choice of red, blue, beige (“jive” or “twist”, code 4QC), pale grey (“platinum”, code EC3), dark grey (“swing”, 24S) or black (“soul”, 6PS). Individual options were also available such as vivid yellow, red or blue seats, steering wheels, gear lever, handbrake lever and door armrests. The color.storm models introduced in 2003 brought bright colours to both the outside and inside of the A2, including “papaya” orange. Soft touch materials are used on the doors and contact areas in the centre console, though they have a tendency to wear over time, especially on the climate control keys. The A2 had many innovative ideas, such as the space floor storage system which was a box that slotted in the rear passenger foot well, a rear cup holder which unclipped, and a double (false) floor boot where items could be hidden from thieves or where the space saver spare wheel could be stored. The warning triangle and first aid kit are stowed directly to the left of the boot opening. The toolkit was stored, depending on equipment, next to the battery. If space was needed for the navigation system and/or the Bose subwoofer, it was moved to the sandwich compartment in front of the right-front seat (driver on UK cars, passenger on LHD ones). The headrests also do not need to be removed from the rear seats when they are folded, and a four-seater can have the rear seats removed in a matter of seconds. The rear seat belts have a clip in the upper section of the c-pillar, so that when the seats are folded and returned to their normal position, the belts do not get tangled. More examples of energy saving can be found in the glovebox light that only turns on when the lights are on and the freewheel pulley on the alternator belt, meaning that the alternator is only used when necessary. The climate compressor is also turned off when the ambient temperature drops below 5 °C. The ECON function of the climate control (where fitted) also turns off the auxiliary heating or the compressor, depending on temperature. This functionality is unaffected by the presence of fuel-powered or electrical auxiliary heating. The front of the car included an unusual design feature called the “Serviceklappe” in German – this translates to “service hatch” or “service panel”. On early cars, this was a glossy black panel at the lower edge of the bonnet (hood), where the radiator grille would normally be sited. Behind it are the filling points for oil and screen wash fluid and the dipstick. Thanks to these features, the bonnet does not need to be raised often. The bonnet was widely rumoured to be sealed. Actually, the bonnet is easily removed, being held in place by two twist-lock catches. The bonnet, weighing 8 kg, then comes away from the car altogether, unlike the usual hinged flip-up arrangement on most other cars. Due to the service hatch, the bonnet does not need to be removed frequently for access to the engine. The service hatch is the most obvious indicator of the age of any particular A2. It was changed to matte black for the “color.storm” colour schemes, and for model year 2004 it acquired fake grille slats. However it can be changed easily, so it should not be taken as a reliable age indicator. Very little else was changed externally during the life of the car. Colours and wheels designs were changed mildly during the production run. The only other external indicator of the age of the car is the windscreen wiper. Very early models have a traditional blade, but starting in model year 2002, newer cars have a “flex” version (“Aerotwin” from Bosch, model 760). The car seen here is one of the colour.storm cars. These were one of an array of limited edition cars produced in 2004/5 which introduced some of the colours only generally available on S and RS Audi models to the A2.

Picture 322 Picture 323 Picture 321 Picture 320

AUSTIN HEALEY

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

Picture 239 Picture 348

BMW

First introduced as the Concept Vision EfficientDynamics, the i8 was part of BMW’s “Project i” and was marketed as a new brand, BMW i, sold separately from BMW or Mini. The BMW i3, launched for customers in Europe in the fourth quarter of 2013, was the first model of the i brand available in the market, and it was followed by the i8, released in Germany in June 2014 as a 2015 model year. Other i models were expected to follow.The initial turbodiesel concept car was unveiled at the 2009 International Motor Show Germany, In 2010, BMW announced the mass production of the Vision EfficientDynamics concept in Leipzig beginning in 2013 as the BMW i8. The BMW i8 gasoline-powered concept car destined for production was unveiled at the 2011 Frankfurt Motor Show. The production version of the BMW i8 was unveiled at the 2013 International Motor Show Germany. The following are the concept and pre-production models developed by BMW that preceded the production version. When BMW i sponsored the ABB FIA Formula E World Championship, they announced that they would provide support vehicles; the i8 operated as the official safety car. BMW Vision EfficientDynamics concept car was a plug-in hybrid with a 1.5L three-cylinder turbo-diesel engine. Additionally, there were two electric motors with 104 kW (139 hp). It allowed an acceleration to 100 km/h (62 mph) in 4.8 seconds, with an electronically limited top speed of 250 km/h (155 mph). According to BMW, the average fuel consumption in the EU test cycle (KV01) was 3.76 L/100 km (75.1 mpg imp), with a carbon dioxide emission rating of 99 g/km(1,3 L/100 km and 33g CO2/kabelham; EU-PHEV ECE-R101). The estimated all-electric range was 50 km (31 mi), and the 24-litre petrol tank extended the total vehicle range to up to 700 km (430 mi). The lightweight chassis was made mainly from aluminium. The windshield, top, doors, and fenders were made from polycarbonate glass, with the body having a drag coefficient of 0.22. The designers of the BMW Vision EfficientDynamics concept were Mario Majdandzic for the exterior and Jochen Paesen (lead interior design), Markus Speck (interior design), and Felix Staudacher former Baerlin (detail design) for the interior. While Jochen Paesen took care of the main interior theme, Markus Speck was in charge of the seats, all the visible structure, and some details. Felix Baerlin supported Jochen Paesen on details including the steering wheel and center console. The vehicle was unveiled at the 2009 International Motor Show Germany, followed by Auto China 2010. The BMW i8 Concept plug-in hybrid electric vehicle included an electric motor located in the front axle powering the front wheels rated 96 kW (131 PS; 129 hp) and 250 Nm (184 lb/ft, a turbocharged 1.5-litre 3-cylinder petrol engine driving rear wheels rated 164 kW (223 PS; 220 hp) and 300 Nm (221 lb/ft of torque, with combined output of 260 kW (354 PS; 349 hp) and 550 Nm (406 lb/ft), a 7.2 kWh (26 MJ) lithium-ion battery pack that allowed an all-electric range of 35 km (22 mi). All four wheels provided regenerative braking. The location of the battery pack in the energy tunnel gave the vehicle a low centre of gravity, enhancing its dynamics. Its top speed was electronically limited to 250 km/h (155 mph) and was expected to go from 0 to 100 km/h (0 to 60 mph) in 4.6 seconds. Under normal driving conditions the i8 was expected to deliver 80 mpg US (2.9 L/100 km; 96 mpg imp) under the European cycle. A full charge of the battery would take less than two hours at 220 V. The positioning of the motor and engine over the axles resulted in 50/50 weight distribution.The vehicle was unveiled at the 2011 International Motor Show Germany, followed by CENTER 548 in New York City, 42nd Tokyo Motor Show 2011, 82nd Geneva Motor Show 2012, BMW i Born Electric Tour at the Palazzo Delle Esposizioni at Via Nazionale 194 in Rome, and Auto Shanghai 2013. This concept car was featured in the film Mission: Impossible – Ghost Protocol. The BMW i8 Concept Spyder included a slightly shorter wheelbase and overall length compared to the BMW i8 Concept, carbon-fiber-reinforced plastic (CFRP) Life module, drive modules made primarily from aluminium components, interlocking of surfaces and lines, 8.8-inch (22.4 cm) screen display, off-white outer layer, and orange-toned naturally tanned leather upholstery. The vehicle was unveiled at Auto China 2012 in Beijing where it won Concept Car of the Year, followed by the 83rd Geneva International Motor Show 2013. The designer of the BMW i8 Concept Spyder was Richard Kim. The design of the BMW i8 coupe prototype was based on the BMW i8 Concept. The BMW i8 prototype had an average fuel efficiency of less than 2.5 L/100 km (113.0 mpg imp; 94.1 mpg US) under the New European Driving Cycle with carbon emissions of less than 59 g/km. The i8 with its carbon-fibre-reinforced plastic (CFRP) passenger cell lightweight, aerodynamically optimized body, and BMW eDrive technology offered the dynamic performance of a sports car, with an expected 0–100 km/h (0–62 mph) sprint time of less than 4.5 seconds using both power sources. The plug-in hybrid system of the BMW i8 comprised a three-cylinder, 1.5-liter BMW TwinPower Turbo gasoline engine combined with BMW eDrive technology used in the BMW i3 and developed maximum power of 170 kW (228 hp). The BMW i8 was the first BMW production model to be powered by a three-cylinder gasoline engine and the resulting specific output of 115 kW (154 hp) per liter of displacement was on par with high-performance sports car engines and was the highest of any engine produced by the BMW Group. The BMW i8’s second power source was a hybrid synchronous electric motor specially developed and produced by the BMW Group for BMW i. The electric motor developed maximum power of 131 hp (98 kW) and produced its maximum torque of around 320 Nm (236 lb/ft) from a standstill. Typical of an electric motor, responsive power was instantly available when starting and this continued into the higher load ranges. As well as providing a power boost to assist the gasoline engine during acceleration, the electric motor could also power the vehicle by itself. Top speed in electric mode was approximately 120 km/h (75 mph), with a maximum driving range of up to 35 km (22 mi). Linear acceleration was maintained even at higher speeds since the interplay between the two power sources efficiently absorbed any power flow interruptions when shifting gears. The model-specific version of the high-voltage 7.2 lithium-ion battery had a liquid cooling system and could be recharged at a conventional household power socket, at a BMW I Wallbox, or at a public charging station. In the US, a full recharge took approximately 3.5 hours from a conventional 120 V, 12 amp household circuit or approximately 1.5 hours from a 240 V Level 2 charger. The driver could select several driving modes: SPORT, COMFORT, and ECO PRO. Using the gear selector, the driver could either select position D for automated gear selection or could switch to SPORT mode. SPORT mode offered manual gear selection and at the same time switched to sporty drive and suspension settings. In SPORT mode, the engine and electric motor delivered extra performance, accelerator response was faster, and the power boost from the electric motor was maximized. And to keep the battery topped up, SPORT mode also activated maximum energy recuperation during overrun and braking as the electric motor’s generator function, which recharged the battery using kinetic energy, switched to a more powerful setting. The Driving Experience Control switch on the center console offered a choice of two settings. On starting, COMFORT mode was activated, which offered a balance between performance and fuel efficiency, with unrestricted access to all convenience functions. Alternatively, the ECO PRO mode could be engaged, which, on the BMW i8 as on other models, supported an efficiency-optimized driving style. In this mode, the powertrain controller coordinated the cooperation between the gasoline engine and the electric motor for maximum fuel economy. On deceleration, the intelligent energy management system automatically decided, in line with the driving situation and vehicle status, whether to recuperate braking energy or to coast with the powertrain disengaged. At the same time, ECO PRO mode also programmed electrical convenience functions such as the air conditioning, seat heating, and heated mirrors to operate at minimum power consumption, but without compromising safety. The maximum driving range of the BMW i8 on a full fuel tank and with a fully charged battery was more than 500 km (310 mi) in COMFORT mode, which could be increased by up to 20% in ECO PRO mode. The BMW i8’s ECO PRO mode could also be used during all-electric operation. The vehicle was then powered solely by the electric motor. Only if the battery charge dropped below a given level, or under sudden intense throttle application such as kick down, was the internal combustion engine automatically activated. The vehicle was unveiled in BMW Group’s Miramas test track in France. The production BMW i8 was designed by Benoit Jacob. The production version was unveiled at the 2013 Frankfurt International Motor Show followed by 2013 Les Voiles de Saint-Tropez. Its design was heavily influenced by the BMW M1 Homage concept car, which in turn pays homage to BMW’s last production mid-engined sports car prior to the i8: the BMW M1. The BMW i8 featured butterfly doors, head-up display, rear-view cameras and partially false engine noise. Series production of customer vehicles began in April 2014. The electric two-speed drivetrain was developed and produced by GKN. It was the first production car with laser headlights, reaching farther than LED lights. The i8 had a vehicle weight of 1,485 kg (3,274 lb) (DIN kerb weight) and a low drag coefficient (Cd) of 0.26. In all-electric mode, the BMW i8 had a top speed of 120 km/h (75 mph). In Sport mode, the i8 delivered a mid-range acceleration from 80 to 120 km/h (50 to 75 mph) in 2.6 seconds. The electronically controlled top speed was 250 km/h (155 mph). The 20,000th i8 was produced in December 2019, one of the limited Ultimate Sophisto Edition models. The last i8 rolled off the production line on 11 June 2020. In total, there were 20,465 units produced: 16,581 coupés and 3,884 roadsters.

Picture 352

CHEVROLET

First seen in 1963, this Corvette model introduced us to the name Sting Ray. It  continued with fibreglass body panels, and overall, was smaller than the first generation. The car was designed by Larry Shinoda with major inspiration from a previous concept design called the “Q Corvette,” which was created by Peter Brock and Chuck Pohlmann under the styling direction of Bill Mitchell. Earlier, Mitchell had sponsored a car known as the “Mitchell Sting Ray” in 1959 because Chevrolet no longer participated in factory racing. This vehicle had the largest impact on the styling of this generation, although it had no top and did not give away what the final version of the C2 would look like. The third inspiration was a Mako Shark Mitchell had caught while deep-sea fishing. Production started for the 1963 model year and ended in 1967. The 1963 model was the first year for a Corvette coupé and it featured a distinctive tapering rear deck (a feature that later reappeared on the 1971 “Boattail” Buick Riviera) with, for 1963 only, a split rear window. The Sting Ray featured hidden headlamps, non-functional bonnet vents, and an independent rear suspension. Corvette chief engineer Zora Arkus-Duntov never liked the split rear window because it blocked rear vision, but Mitchell thought it to be a key part of the entire design. Maximum power for 1963 was 360 bhp, raised to 375 bhp in 1964. Options included electronic ignition, the breakerless magnetic pulse-triggered Delcotronic first offered on some 1963 Pontiac models. On 1964 models the decorative bonnet vents were eliminated and Duntov, the Corvette’s chief engineer, got his way with the split rear window changed to a full width window. Four-wheel disc brakes were introduced in 1965, as was a “big block” engine option: the 396 cu in (6.49 litre) V8. Side exhaust pipes were also optionally available in 1965, and continued to be offered through 1967. The introduction of the 425 bhp 396 cu in  big block in 1965 spelled the beginning of the end for the Rochester fuel injection system. The 396 cu in option cost $292.70 while the fuel injected 327 cu in (5.36 litre) engine cost $538.00. Few people could justify spending $245.00 more for 50 bhp less, even though FI could deliver over 20 mpg on the highway and would keep delivering fuel despite high G-loading in corners taken at racing speeds. Another rare ’63 and ’64 option was the Z06 competition package, which offered stiffer suspension, bigger, multi-segment lined brakes with finned drums and more, only a couple hundred coupes and ONE convertible were factory-equipped this way in 1963. With only 771 fuel-injected cars built in 1965, Chevrolet discontinued the option at the end of the ’65 production, having introduced a less-expensive big block 396 engine rated at 425 hp in the middle of the production year and selling over 2,000 in just a few months. For 1966, Chevrolet introduced an even larger 427 cu in  7 litre Big Block version. Other options available on the C2 included the Wonderbar auto-tuning AM radio, AM-FM radio (mid-1963), air conditioning (late-1963), a telescopic steering wheel (1965), and headrests (1966). The Sting Ray’s independent rear suspension was successfully adapted for the new-for-1965 Chevrolet Corvair, which solved the quirky handling problems of that unique rear-engine compact. 1967 was the final year for the C2 generation. The 1967 model featured restyled bumper vents, less ornamentation, and back-up lamps which were on the inboard in 1966 were now rectangular and centrally located. The first use of all four taillights in red started in 1961 and was continued thru the C-2 line-up except for the 1966. The 1967 and subsequent models continuing on all Corvettes since. 1967 had the first L88 engine option which was rated at 430 bhp, but unofficial estimates place the actual output at 560 bhp or more. Only twenty such engines were installed at the factory. From 1967 (to 1969), the Holley triple two-barrel carburettor, or Tri-Power, was available on the 427 L89 (a $368 option, on top of the cost for the high-performance 427). Despite these changes, sales slipped over 15%, to 22,940 – 8,504 coupes and 14,436 convertibles.

Picture 285 Picture 246

The third generation Corvette, which was patterned after the Mako Shark II concept car, and made its debut for the 1968 model year, then staying in production until 1982. C3 coupes featured the first use of T-top removable roof panels. The C3 introduced monikers that were later revived, such as LT-1, ZR-1, Z07 and Collector Edition. In 1978, the Corvette’s 25th anniversary was celebrated with a two-tone Silver Anniversary Edition and an Indy Pace Car replica edition of the C3. This was also the first time that a Corvette was used as a Pace Car for the Indianapolis 500. Engines and chassis components were mostly carried over from the C2, but the body and interior were new. The 350 cu in (5.7 litre) engine replaced the old 327 cu in (5.36 litre) as the base engine in 1969, but power remained at 300 bhp. 1969 was the only year for a C3 to optionally offer either a factory installed side exhaust or normal rear exit with chrome tips. The all-aluminium ZL1 engine was also new for 1969; the special big-block engine was listed at 430-hp but was reported to produce 560 hp and propelled a ZL1 through the 1/4 mile in 10.89 seconds. There was an extended production run for the 1969 model year due a lengthy labour strike, which meant sales were down on the 1970 models, to 17,316. 1970 small-block power peaked with the optional high compression, high-revving LT-1 that produced 370 bhp. The 427 big-block was enlarged to 454 cu in (7.44 litre) with a 390 bhp rating. The ZR-1 special package was an option available on the 1970 through 1972 model years, and included the LT-1 engine combined with special racing equipment. Only 53 ZR-1’s were built. In 1971, to accommodate regular low-lead fuel with lower anti-knock properties, the engine compression ratios were lowered which resulted in reduced power ratings. The power rating for the 350 cu in (5.7 litre) L48 base engine decreased from 300 to 270 hp and the optional special high performance LT1 engine decreased from 370 to 330 hp. The big-block LS6 454 was reduced from 450 to 425 bhp, though it was not used in Corvettes for 1970; it was used in the Chevelle SS. For the 1972 model year, GM moved to the SAE Net measurement which resulted in further reduced, but more realistic, power ratings than the previous SAE Gross standard. Although the 1972 model’s 350 cu in horsepower was actually the same as that for the 1971 model year, the lower net horsepower numbers were used instead of gross horsepower. The L48 base engine was now rated at 200 bhp and the optional LT1 engine was now rated at 270 bhp. 1974 models had the last true dual exhaust system that was dropped on the 1975 models with the introduction of catalytic converters requiring the use of no-lead fuel. Engine power decreased with the base ZQ3 engine producing 165 bhp, the optional L82’s output 250 bhp, while the 454 big-block engine was discontinued. Gradual power increases after 1975 peaked with the 1980 model’s optional L82 producing 230 bhp. Styling changed subtly throughout the generation until 1978 for the car’s 25th anniversary. The Sting Ray nameplate was not used on the 1968 model, but Chevrolet still referred to the Corvette as a Sting Ray; however, the 1969 (through 1976) models used the “Stingray” name as one word, without the space. In 1970, the body design was updated including fender flares, and interiors were refined, which included redesigned seats, and indication lights near the gear shift that were an early use of fibre optics . Due to government regulation, the 1973 Corvette’s chrome front bumper was changed to a 5 mph system with a urethane bumper cover. 1973 Corvettes are unique in that sense, as they are the only year where the front bumper was polyurethane and the rear retained the chrome two-piece bumper set. 1973 was also the last year chrome bumpers were used. The optional wire-spoked wheel covers were offered for the last time in 1973. Only 45 Z07 were built in 1973. From 1974 onwards both the front and rear bumpers were polyurethane. In 1974, a 5-mph rear bumper system with a two-piece, tapering urethane bumper cover replaced the Kamm-tail and chrome bumper blades, and matched the new front design from the previous year. 1975 was the last year for the convertible, (which did not return for 11 years). For the 1976 models the fibreglass floor was replaced with steel panels to provide protection from the catalytic converter’s high operating temperature. 1977 was last year the tunnelled roof treatment with vertical back window was used, in addition leather seats were available at no additional cost for the first time. The 1978 25th Anniversary model introduced the fastback glass rear window and featured a new interior and dashboard. Corvette’s 25th anniversary was celebrated with the Indy 500 Pace Car limited edition and a Silver Anniversary model featuring silver over gray lower body paint. All 1979 models featured the previous year’s pace car seats and offered the front and rear spoilers as optional equipment. 53,807 were produced for the model year, making 1979 the peak production year for all versions of the Corvette. Sales have trended downward since then. In 1980, the Corvette received an integrated aerodynamic redesign that resulted in a significant reduction in drag. After several years of weight increases, 1980 Corvettes were lighter as engineers trimmed both body and chassis weight. In mid-1981, production shifted from St. Louis, Missouri to Bowling Green, Kentucky, and several two-tone paint options were offered. The 1981 models were the last available with a manual transmission until well into the 1984 production run. In 1982, a fuel-injected engine returned, and a final C3 tribute Collectors Edition featured an exclusive, opening rear window hatch.

Picture 289 Picture 288

The next-generation (C7) Corvette had been in development since 2007. Originally set to be introduced for the 2011 model year, its introduction was delayed for 3 years. It was finally released for the 2014 model year. Mid-engine and rear-engine layouts had been considered, but the front-engine, rear-wheel drive platform was chosen to keep production costs lower. To GM’s product planners and marketers, the fact that the Corvette had become known as an “old man’s toy” became a prime factor in developing the next generation. Studies showed that about 46 percent of Corvette buyers in 2012, through October, were 55 or older, compared with 22 percent of Audi R8 and 30 percent of Porsche 911 customers. The head of Chevy marketing, Chris Perry, acknowledges that too many people saw it as the car of “the successful plumber.” John Fitzpatrick, Corvette’s marketing manager said “It’s the old saying, ‘Nobody wants to be seen driving an old man’s car, but everybody wants to be seen driving a young man’s car. ” To counter that perception GM planned to make the new generation C7 more aspirational to younger people. Towards that end, a camouflaged version of the car was made available in the popular video game Gran Turismo 5 in November 2012. As part of the marketing effort associated with the introduction of the new generation, the 2013 Indianapolis 500 utilised a Corvette for the 12th time as its pace car. Pace car editions are planned. Sales success of the new Corvette is important to GM. The Motley Fool reports that the Corvette could be earning GM $10,000 or more in gross profit for every Corvette it sells.The 2014 Chevrolet Corvette uses an LT1 6.2 litre V8 making 455 bhp. The LT1 engine is in the Gen 5 family of small block engines, which will be used in GM vehicles as the new small V8 option. It features three technologies new to the GM V8, though widely available on other engines in the marketplace: direct injection, variable valve timing, and an active fuel management system. Fuel injectors are located under the intake manifold. The Corvette remains rear-wheel drive with the transaxle located in the rear. Transmission choices include a 7-speed manual or a 8-speed automatic with paddle shifters. The new interior includes wide-bottom seats as standard, with sportier versions with high side bolsters optional. The Corvette’s flag logo has been revised for the new car and a small casting of a stingray has been added to the car’s ornamentation. Features of the new generation’s structure include a carbon fibre bonnet and removable roof panel. The fenders, doors and rear quarter panels remain composite. At the rear of the car, the trademark round taillights have changed to a more squarish form. The underbody panels are made of “carbon-nano” composite and it makes use of a new aluminium frame which locates the four wheels an inch farther apart, front to rear and side to side. Luggage space decreased by 33% from the previous generation’s. The overall weight of the car was not announced by General Motors for many months after its first showing in January 2013. Despite the increased use of aluminium and other light weight materials, numerous publications reported that the weight would remain essentially unchanged from that of the previous generation’s. In August, 2013, the weight of the new Corvette was reported to be 3,444 lb meaning it would weigh more than the previous generation’s C6 ZR1 model (3,324 lb (1,508 kg)). The ZR1 C6 weight included a supercharger and intercooler on its 6.2 litre engine. Chevrolet announced the C7 Z06 at the 2014 Detroit Auto Show. The 2015 Z06 Corvette has 650 bhp from the supercharged LT4 aluminium 6.2L V-8 engine. The final C7 generation cars were produced in 2019.

Picture 287 Picture 244 Picture 247

Completing the line-up of Corvette models were examples of the current car, the mid-engined C8 generation.

Picture 369 Picture 286 Picture 245

Rather different, and arriving relatively late was this Monte Carlo. For 1973, a redesigned Monte Carlo was introduced alongside other GM intermediates. Like other GM mid-size cars, the 1973 Monte Carlo was no longer a hardtop, but a pillared “Colonnade” coupe with rear side opera windows and frameless door glass. Prominent styling included an egg-crate grille, a Monte Carlo emblem, and vertical taillights above the bumper. The front bumper was a large federally mandated 5 mph (8.0 km/h) bumper that was among the required 1973 federal safety standards for all passenger cars sold in the U.S. with the 5 mph (8.0 km/h) requirement extended to rear bumpers on 1974 models. Also new was a double-shell roof for improved noise reduction and rollover protection, along with the flush-mounted pull-up exterior door handles first introduced on the 1970½ Camaro and 1971 full-sized Chevrolets and Vegas. The separate body-on-frame construction carried over for 1973, along with the basic all-coil suspension. The standard Monte Carlo with manual transmission retained “traditional” steering and bias-ply tires, but the radial-tuned system was included when the automatic transmission was ordered, earning the Monte Carlo S label. Optional were radial-ply tires, “Pliacell” shock absorbers (internal plastic membranes that separate the hydraulic fluid from the gas), high-caster steering, and front and rear anti-roll bars (previously offered only with the SS package). A new model for 1973 was the Monte Carlo Landau, an “S” with a rear quarter Landau vinyl roof, Turbine II wheels, and driver and passenger-side sports mirrors. The interior of the 1973 Monte Carlo featured an all-new, wraparound cockpit-style instrument panel, similar to that found in some contemporary Pontiacs, Oldsmobiles, and Buicks, in which gauges and various instruments were centred within easy reach of the driver. The simulated burl elm trim was retained. A split bench seat was standard, but “Strato Bucket” seats of a new design were optional, along with a floor console featuring an equally new shifter with knob and button similar to Pontiac’s Rally Sports Shifter replacing the Buick-like horseshoe shifter of previous years, and storage compartment. The bucket seats were of a one-piece high-back design with built-in headrests and could swivel almost 90 degrees to permit the driver and front passenger easier entry and exit, a feature previously offered on the 1962 Chrysler 300H. Cloth and vinyl trims were offered for bench and bucket seats. The standard engine was a 145 hp 350 cu in (5.7 L) “Turbo-Fire” V8. Optional engines included a 175 hp 350 cu in (5.7 L) with a four-barrel carburettor and a four-barrel carburetted 454 cu in (7.4 L) “Turbo-Jet” V8 rated at 245 hp. The 1973 Monte Carlo was named “Car of the Year” by Motor Trend based on its new styling and emphasis on Euro-style ride and handling. The 1973 Monte Carlo set a new sales record for Chevrolet, with nearly 250,000 sold for the model year. The success of the Monte Carlo and Pontiac’s similar Grand Prix led to several new personal luxury cars from competitors, including a revised Mercury Cougar, the Ford Gran Torino Elite, the Chrysler Cordoba, and restyled Dodge Charger as well as high-line versions of the AMC Matador that introduced a new coupe design for 1974. The 1974 Monte Carlo received minor detail changes from its 1973 predecessor, most notably a revised egg-crate grille in the front, flush mount taillights (no longer recessed with horizontal chrome bars), a shorter trunk deck that housed the relocated license plate and the trunk lock mechanism. In 1973, the trunk lock was below the trunk deck and above the rear bumper in a space that no longer existed in the 1974 versions. A larger 5 mph (8.0 km/h) rear bumper was added. The driver and passenger door map pockets were no longer available. The base Monte Carlo with a manual transmission, standard suspension, and bias-ply tires was discontinued, leaving only the “S” and “Landau” models equipped with radial-ply tyres, upgraded suspensions, and standard power steering and front disc brakes. A three-speed manual transmission was listed as standard equipment on 1974 “S” and “Landau” models equipped with the standard 350 cu in (5.7 L) and an automatic transmission was a required option with the larger 400 and 454 CID V8s. However, some sources indicate that Chevrolet built almost all 1974 Monte Carlos with the Turbo Hydra-Matic transmission. The standard 350 cu in (5.7 L) “Turbo-Fire” V8 was again rated at 145 hp with a two-barrel carburettor in 49 states. For Californians, the standard engine was a 350 “Turbo-Fire” V8 with a four-barrel carburettor rated at 160 hp that was not offered in the other 49 states. Reappearing on the options list for the first time since 1970 was a 400 cu in (6.6 L) “Turbo-Fire” small block V8 rated at 150 hp with a two-barrel carburetor (not offered in California) or 180 hp with a four-barrel carburettor. The top engine was again the 454 cu in (7.4 L) “Turbo-Jet” big block V8 rated at 235 hp. Despite the Arab Oil Embargo of late 1973 and early 1974 that significantly cut into sales of standard and intermediate-sized cars in favour of smaller compacts and imported subcompacts, the Monte Carlo went the other way on the sales charts by setting a new sales record this year of over 300,000 units despite the long lines at gas stations and record-high gasoline prices. The Monte Carlo continued to lead in intermediate personal luxury car sales, with the Grand Prix placing second and the arrival of new competitors this year, including an upsized Mercury Cougar, Ford Gran Torino Elite, and AMC’s Matador coupe. Chrysler would introduce its entries in this field for 1975, including the Chrysler Cordoba and redesigned Dodge Charger. The 1975 Monte Carlo received only minor styling changes from the 1974 model, including a new grille with the Monte Carlo emblem moved to the centre section and new vertically shaped taillights with horizontal louvers. All models received catalytic converters to meet Federal and California emission requirements, including bonuses such as improved fuel economy and drivability, extended spark plug and muffler life, but required lower-octane unleaded gasoline. Engines were a carryover from 1974, except for the addition of GM’s High Energy electronic ignition, which was made standard equipment. Power ratings for all engines were decreased due to the addition of the catalytic converter. The 454 cu in (7.4 L) V8 was no longer offered on California cars, leaving the 400 cu in (6.6 L) four-barrel the top engine in that market. The base 350 cu in (5.7 L) two-barrel was rated at 145 hp (standard in 49 states), the 350 CID 4-barrel was rated at 155 hp (available only in California), the 400 CID 4-barrel 175 hp, and the 454 CID 4-barrel 215 hp (now equipped with single exhaust with dual exhaust as an option). A three-speed manual transmission was standard equipment with the base 350 CID V8 used in 49 states and California-only 350 four-barrel V8. The Turbo Hydra-Matic was optional and a required option for the 400 and 454 V8s. Company sources claim that all 1975 Monte Carlos were equipped with the Turbo Hydra-Matic transmission, which became standard equipment for 1976. New for 1975 was a Custom interior option that included a plusher cloth 50/50 bench seat with recliner on the passenger side and lower door panel carpeting. The standard interior consisted of a bench seat with knit-cloth and vinyl or all-vinyl upholstery. The swivelling Strato bucket seats with a centre console and floor shifter were still optional, along with a knit cloth or vinyl upholstery. Also, white all-vinyl interiors were available for the first time this year, with either bench or bucket seats and contrasting colours for carpeting and instrument panels, including black, red, blue, and green. A gauge that showed if one was using too much gas, a part of the “Economider” Gauge package, became optional. Sales dropped from 1974’s record-setting pace due to higher list prices, a domestic economy with double-digit inflation, and new competition from Chrysler’s Cordoba and Dodge’s Charger SE. Monte Carlo production ended up at around 250,000 units. The 1976 Chevrolet Monte Carlo had a new crosshatch grille, vertically mounted rectangular headlamps, and reshaped taillights identified the 1976 Monte Carlo (the reshaped taillight pattern was later incorporated into the fourth-generation Monte Carlo). Under the hood, a new 140 hp 305 cu in (5.0 L) 2-barrel V8 became the standard engine with the 145 hp 350 cu in (5.7 L) 2-barrel and 175 hp 400 cu in (6.6 L) V8s optional. California cars included a 165 hp 350 cu in (5.7 L) 4-barrel as the base engine (not available in 49 states), and could be equipped with the 400 cu in (6.6 L) 4-barrel V8. The big-block 454 cu in (7.4 L) V8 was discontinued. The Turbo Hydramatic transmission became standard equipment on all 1976 Monte Carlos. Interior trims remained the same as in 1975, with both base and custom levels, but the instrument panel and steering wheel featured a new rosewood trim that replaced the burled elm of previous years. A new option was a two-toned “Fashion Tone” paint combination. Monte Carlo sales hit a record total with 353,272 units this year. Of these, 191,370 were “S” Coupes and 161,902 Landau Coupes, which was an extra $293. For 1977 there was a revised grille with smaller segments with the Monte Carlo “knight’s crest” emblem moved to a stand-up hood ornament and revised taillight lenses marked the 1977 Monte Carlo, which was the last year for the 1973-vintage design before the introduction of a downsized 1978 Monte Carlo. Engine offerings were reduced to two engines for 1977. The base engine for 49 states was the 140 hp 305 cu in (5.0 L) 2-barrel V8 and the 170 hp 350 cu in (5.7 L) 4-barrel V8 was optional (standard in California). The 400-cubic-inch V8 was dropped as an engine option. The only transmission was the Turbo Hydra-Matic transmission. Interior trim received only minor revisions this year with upholstery choices, including cloth, velour, and vinyl in base and Custom trims. Swivel-out front seats and an 8-track tape player were optional. This model year marks the only time in history when an intermediate model was bigger in every dimension than Chevrolet’s full-sized models. The B-body Chevrolet Caprice/Impala had been redesigned and downsized for 1977. The Monte Carlo also weighed more. In 1977, sales totalled 224,327 S coupes and 186,711 Landau coupes. All GM intermediate-sized cars, including the Monte Carlo, were downsized for the 1978 model year

Picture 371 Picture 372

DODGE

It was good to see this example of the Charger here. Familiar to those who have been to America, these large saloons have never been officially sold in the UK and only a few of them have made their way here.

Picture 260 Picture 261 Picture 349

FERRARI

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

Picture 250

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

Picture 243

Also here was the Ferrari 812 Superfast. Known internally as the Type F152M, this is a front mid-engine, rear-wheel-drive grand tourer that made its debut at the 2017 Geneva Motor Show. The 812 Superfast is the successor to the F12berlinetta. The 812 Superfast has a 6,496 cc F140 GA V12, an enlarged version of the 6.3-litre engine used in the F12berlinetta. It generates a power output of 800 PS (789 bhp) at 8,500 rpm and 718 Nm (530 lb/ft) of torque at 7,000 rpm. According to Ferrari in 2018, the 812 Superfast’s engine was, at the time, the most powerful naturally aspirated production car engine ever made. It does not feature turbocharging or hybrid technology.

Picture 353 Picture 355 Picture 356

FORD

The Mark I Ford Consul and Zephyr models were first displayed at the Earls Court Motor Show in 1950, the first British cars to use in mass production the MacPherson Strut independent front suspension which is widely used today. Production began with the Consul on 1 January 1951. The first of the Zephyr range was a lengthened version of the four-cylinder 1,508 cc Consul, with a 2,262 cc six-cylinder engine producing 68 bhp  Like the Consul, the Zephyr came with a three-speed gear box, controlled by a column-mounted lever. The front suspension design, based on that first seen in the Ford Vedette, employed what would later come to be known as MacPherson struts while a more conventional configuration for the rear suspension used a live axle with half-elliptic springs. The car could reach just over 80 mph and 23 mpg. The Ford Zephyr Six was available with 4-door saloon, estate and two-door convertible bodies. The convertible version was made by Carbodies and had a power-operated hood; the estate car was by Abbotts of Farnham and was sold as the Farnham.

Picture 251

In early 1962 Ford replaced the existing Consul/Zephyr/ Zodiac range with a dramatically restyled model although the new cars did share some of the mechanical components, as well as the basic chassis design, with the Mark II models. At the bottom of the range, the Consul name disappeared, to be replaced by Zephyr 4. Once again, the range was topped by the Zodiac, which  was an upmarket version of the Zephyr 6, but differed considerably from that model with its limousine-type rear doors, sharper roofline with a much narrower C-pillar, a revised rear end, a unique grille with four headlights instead of two, exclusive bumper bars, plusher seating, and up-market upholstery, dashboard and interior fittings. A choice of individual or bench front seat was available trimmed in leather or cloth. The front doors and bonnet panels were shared with the Zephyr 6. The Executive version had extra luxury fittings again. The 2553 cc single-carburettor six-cylinder engine was improved internally to increase the power output to 109 bhp and a new four-speed all synchromesh transmission with column change was fitted. The brakes, servo assisted, use discs at the front and drum at the rear. On test with The Motor magazine in 1962, the Zodiac Mark 3  had a top speed of 100.7 mph and could accelerate from 0-60 mph in 13.4 seconds and it delivered a touring fuel consumption of 22.6 mpg. The test car cost £1070 including taxes on the UK market. Mark 3 models were produced for 4 years before being replaced by the Mark IV in January 1966.

Picture 315 Picture 316

Sporting Escorts appeared only a matter of months after the launch of the regular 1100 and 1300cc cars. The first of these was a higher performance version designed for rallies and racing, the Escort Twin Cam. Built for Group 2 international rallying, it had an engine with a Lotus-made eight-valve twin camshaft head fitted to the 1.5 L non-crossflow block, which had a bigger bore than usual to give a capacity of 1,557 cc. This engine had originally been developed for the Lotus Elan. Production of the Twin Cam, which was originally produced at Halewood, was phased out as the Cosworth-engined RS1600 production began. The most famous edition of the Twin Cam was raced on behalf of Ford by Alan Mann Racing in the British Saloon Car Championship in 1968 and 1969, sporting a full Formula 2 Ford FVC 16-valve engine producing over 200 hp. The Escort, driven by Australian driver Frank Gardner went on to comfortably win the 1968 championship. The Mark I Escorts became successful as a rally car, and they eventually went on to become one of the most successful rally cars of all time with arguably the Escort’s greatest victory in the 1970 London to Mexico World Cup Rally, co-driven by Finnish legend Hannu Mikkola and Swedish co-driver Gunnar Palm. This gave rise to the Escort Mexico, which had a 1600cc “crossflow”-engined, as a special edition road version in honour of the rally car. Introduced in November 1970, 10,352 Mexico Mark I’s were built. In addition to the Mexico, the RS1600 was developed with a 1,601 cc Cosworth BDA which used a Crossflow block with a 16-valve Cosworth cylinder head, named for “Belt Drive A Series”. Both the Mexico and RS1600 were built at Ford’s Advanced Vehicle Operations (AVO) facility located at the Aveley Plant in South Essex. As well as higher performance engines and sports suspension, these models featured strengthened bodyshells utilising seam welding in places of spot welding, making them more suitable for competition. After updating the factory team cars with a larger 1701 cc Cosworth BDB engine in 1972 and then with fuel injected BDC, Ford also produced, in the autumn of 1973, an RS2000 model as an alternative to the somewhat temperamental RS1600, featuring a 2.0 litre Pinto OHC engine. This also clocked up some rally and racing victories; and pre-empted the hot hatch market as a desirable but affordable performance road car. Like the Mexico and RS1600, this car was produced at the Aveley plant.

Picture 310 Picture 283

The fourth-generation Cortina was a more conventional design than its predecessor, but this was largely appreciated by fleet buyers. Generally a rebody of the Mark III, as an integration of Ford’s model range, this car was really a rebadged Ford Taunus. However, although the updated Taunus was introduced to Continental Europe in January 1976, Ford were able to continue selling the Cortina Mark III in undiminished numbers in the UK until they were ready to launch its successor as the Dagenham built Cortina Mark IV, which went on sale on 29 September 1976. Many parts were carried over, most notably the running gear. The raised driving position and the new instrument panel had, along with some of the suspension upgrades, already been introduced to the Cortina Mark III in 1975, so that from the driving position the new car looked much more familiar to owners of recent existing Cortinas than from the outside. Cinema audiences received an early glimpse of the new Cortina (or Taunus) through its appearance in the James Bond The Spy Who Loved Me 1977 film. The most obvious change was the new body, which achieved the marketing department objective of larger windows giving a better view out and a brighter feel to the cabin, but at the expense of body weight which was increased, albeit only marginally, by approximately 30 lb. Ford claimed an overall increase in window area of some 15%, with “40% better visibility” through the wider deeper back window. Regardless of how these figures were computed, there must have been substantial weight-saving gains through reduced steel usage in the design, given the unavoidable extra weight of glass. This series spawned the first Ghia top-of-the-range model, which replaced the 2000E. The 2.3 litre Ford Cologne V6 engine was introduced in 1977 as an engine above the 2.0 litre Pinto engine, already a staple of the Capri and Granada ranges. However, 2.3 litre Cortinas never sold particularly well in the UK. The Cologne V6 was certainly a much smoother and more refined power unit than the Pinto, but the V6 models were more expensive to fuel and insure and were only slightly faster, being about 0.5 seconds faster from 0–60 and having a top speed of about 109 mph compared to the 104 mph of the 2.0 litre models. The 2.0 litre Ford Cologne V6 engine continued to be offered on Taunus badged cars in parallel with the Pinto unit, and offers here an interesting comparison with the similarly sized in-line four-cylinder Pinto engine. The V6 with a lower compression ratio offered less power and less performance, needing over an extra second to reach 50 mph.It did, however, consume 12½% less fuel and was considered by motor journalists to be a far quieter and smoother unit. The 2.3 litre was available to the GL, S and Ghia variants. A 1.6 litre Ghia option was also introduced at the same time as the 2.3 litre V6 models in response to private and fleet buyers who wanted Ghia refinements with the improved fuel economy of the smaller 1.6 litre Pinto engine. Few cars were sold with the 1.6 litre engine though, the 2.0 litre Pinto was always by far the most common engine option for Ghia models. Two-door and four-door saloons and a five-door estate were offered with all other engines being carried over. However, at launch only 1.3 litre engined cars could be ordered in the UK with the two-door body, and then only with “standard” or “L” equipment packages. In practice, relatively few two-door Mark IV Cortinas were sold. In some markets, the two-door saloon was marketed as a coupe, but this was not the case in Britain. Ford already competed in the coupe sector in Europe with the Capri, which was particularly successful on the British market. There was a choice of base, L, GL, S and Ghia trims, again not universal to all engines and body styles. Rostyle wheels were fitted as standard to all Mark IV GL, S and Ghia models, with alloy wheels available as an extra cost option. The dashboard was carried over intact from the last of the Mark III Cortinas while the estate used the rear body pressings of the previous 1970 release Taunus. Despite its status as Britain’s bestselling car throughout its production run the Mark IV is now the rarest Cortina, with poor rustproofing and the model’s popularity with banger racers cited as being the main reasons for its demise.

Picture 280

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

Picture 346 Picture 311 Picture 266 Picture 270 Picture 272 Picture 271

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

Picture 300

GN

A relatively late arrival, at which point it did generate a lot of interest was this diminutive GN cyclecar.  Designed by H R Godfrey and Archibald Frazer Nash, the GN was Britain’s first and best-known cyclecar. The two young engineers set up shop initially in Hendon, North London from whence the first GN emerged in December 1910. An unusually large proportion of the car was manufactured in house and GN used proprietary JAP and Peugeot v-twin engines before commencing production of their own in 1911. The chassis was a simple ash framework, in which the engine was mounted fore-and-aft, while the rear wheels were driven by chains, a transmission system that would be continued on the later Frazer Nash. Weighing only 400lbs (182kg), the GN made the most of its relatively modest power output and was capable of reaching 60mph, a highly respectable performance at the time. From 1913 the engine was mounted transversely with the cylinder heads protruding from the bonnet sides, and that same year GN entered a team in the French Cyclecar Grand Prix. Vitesse and Grand Prix sports models followed and by the outbreak of The Great War, GN had sold approximately 200 cars. After the War’s end, GN was bought by the British Gregoire Company and production moved to larger premises in Wandsworth, South West London in 1919. A steel chassis was adopted and the belt final drive was replaced by chains, and for the next few years the little GNs sold well. The French Salmson company purchased a licence to the design and would go on to build around 1,600 GN-type cyclecars up to 1922. Société Des Moteurs Salmson had been a pioneering force in the development of aircraft and aero-engines. Indeed, many historians consider Salmson’s as the most notable of the radial aero-engines produced during WWI. When war was over, Salmson diversified into other activities including manufacturing machine tools, automobile bodies and, from 1919 onwards, its own version of the GN. In 1921 an additional model was introduced by Salmson, known as the Type Sport, which differed from GN’s high performance models of the time. Better made than the British version, the 1,086cc overhead-valve engine featured bronze cylinder heads, hairpin valve springs, gear-driven cams and a Salmson/GN magneto, while its individual components were number-stamped like those of Salmson’s radial aero engines.

Picture 370 Picture 344 Picture 343

HONDA

The Honda Beat is a kei car produced from May 1991 until February 1996. It is a two-seater roadster with a rear mid-engine, rear-wheel-drive layout. The last car to be approved by Soichiro Honda before he died in 1991, in total around 33,600 were made, with roughly two-thirds of these built in the first year of production. The design of the car originated from Pininfarina, who then sold the design plan to Honda. The Beat was one of many cars designed to take advantage of Japan’s tax-efficient kei car class. There were two mainstream models of the Beat (the PP1–100 and the PP1–110) and a couple of limited edition versions. Variations on the first model were just cosmetic updates. Only the second model had any real mechanical differences. All cars were offered with the option of a driver-side airbag. The car was marketed by Honda as “Midship Amusement” and was sold exclusively in Japan, at Honda Primo dealership sales channels. In typical Honda fashion, the Beat’s engine did not utilize a turbocharger or supercharger. The 656 cc engine was modified with the MTREC (Multi Throttle Responsive Engine Control) system, with individual throttle bodies for each of the three cylinders, to produce 64 PS (63 bhp) at 8,100 rpm with an electronically-limited top speed of 135 km/h (84 mph). Only a 5-speed manual transmission was available. The MTREC design would filter down to the 1993 Honda Today kei car. The Beat was the first kei car to feature disc brakes on all four wheels. The Beat was part of a wave of kei car-sized sports cars in the early 1990s; its competitors included the Suzuki Cappuccino and Mazda’s Autozam AZ-1. Together they anticipated the arrival of the Smart Roadster over a decade later, while Japan would not see a new model of the genre until the 2002 Daihatsu Copen.

Picture 296 Picture 295 Picture 294

JAGUAR

There was a Series 3 example of the well-respected XJ6 here. This was released in April 1979, and was based solely on the long-wheelbase version of the car, and incorporated a subtle redesign by Pininfarina. Externally, the most obvious changes over the SII were the thicker and more incorporated rubber bumpers with decorative chrome only on the top edge, flush door handles for increased safety, a one-piece front door glass without a separate 1/4 light, a grille with only vertical vanes, reverse lights moved from the boot plinth to the larger rear light clusters and a revised roofline with narrower door frames and increased glass area. There were three engine variants, including the 5.3 litre V12, the 4.2 litre straight-six and 3.4 litre straight-six. The larger six-cylinder, and V12 models incorporated Bosch fuel injection (made under licence by Lucas) while the smaller six-cylinder was carburettor fed. There was also the option of a sunroof and cruise control for the first time on an XJ model. In 1981 the 5.3 V12 models received the new Michael May designed “fireball” high compression cylinder head engines and were badged from this time onwards to 1985 as HE (High Efficiency) models. In late 1981 Daimler Sovereign and Double Six models received a minor interior upgrade for the 1982 model year with features similar to Vanden Plas models. Also for the 1982 model year, a top spec “Jaguar” Vanden Plas model was introduced for the US market. In late 1982 the interior of all Series III models underwent a minor update for the 1983 model year. A trip computer appeared for the first time and was fitted as standard on V12 models. A new and much sought-after alloy wheel featuring numerous distinctive circular holes was also introduced, commonly known as the “pepperpot” wheel. In late 1983 revision and changes were made across the Series III model range for the 1984 model year, with the Sovereign name being transferred from Daimler to a new top spec Jaguar model, the “Jaguar Sovereign”. A base spec Jaguar XJ12 was no longer available, with the V12 engine only being offered as a Jaguar Sovereign HE or Daimler Double Six. The Vanden Plas name was also dropped at this time in the UK market, due to Jaguar being sold by BL and the designation being used on top-of-the-range Rover-branded cars in the home UK market. Daimler models became the Daimler 4.2 and Double Six and were the most luxurious XJ Series III models, being fully optioned with Vanden Plas spec interiors. Production of the Series III XJ6 continued until early 1987 and on till 1992 with the V12 engine. In 1992, the last 100 cars built were numbered and sold as part of a special series commemorating the end of production for Canada. These 100 cars featured the option of having a brass plaque located in the cabin. This initiative did not come from Jaguar in Coventry. It was a local effort, by Jaguar Canada staff and the brass plaques were engraved locally.132,952 Series III cars were built, 10,500 with the V12 engine. In total between 1968 and 1992 there were around 318,000 XJ6 and XJ12 Jaguars produced.

Picture 333 Picture 325

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.

Picture 357 Picture 319

JENSEN

An enduring classic that has far more appeal now than when it was new (not an uncommon story) is the Jensen Interceptor,  launched as a replacement for the rather gawky looking CV8 of the early 1960s. After a false start when a car with the same name was shown in 1965, which received a massive “thumbs down”, Jensen went to Italy to find a new stylist for another attempt. They ended up with Carozzeria Touring, who produced a stunning looking grand tourer which, although sharing some styling cues with other models that they had designed, had a style all of its own, and they then approached another,  Vignale,  to build the bodies before they would be shipped back to West Bromwich for final assembly. As with the CV8, motive power came from a large Chrysler V8 engine, which gave the car effortless performance, and a somewhat prodigious thirst. The original specification included electric windows, reclining front seats, a wood rimmed steering wheel, radio with twin speakers, reversing lights and an electric clock. Power steering was included as standard from September 1968. The Mark II was announced in October 1969, with slightly revised styling around the headlamps, front grille and bumper and revised rear lights. The interior was substantially revised in order to meet US regulations, and air conditioning was an option. The Mark III, introduced in 1971, revised the front grille, headlamp finishers and bumper treatment again. It had GKN alloy wheels and air conditioning as standard, and revised seats. It was divided into G-, H-, and J-series depending on the production year. The 6.3 litre engine was superseded by the 7.2 litre in 1971. A Convertible version was premiered in 1974,. but just 267 were built, and then in 1975 a Coupe model was shown, effectively a fixed roof version of the Convertible, just 60 of which were made as by this time, the company had fallen on hard times due to the then world-wide recession, and massive and costly reliability problems with its Jensen-Healey sports car. It was placed into receivership and the receivers allowed production to be wrapped up using the available cache of parts. Production of the Interceptor ended in 1976. Enthusiasm for the car remained, though, so in the late 1980s, a group of investors stepped in and re-launched production of the Interceptor, as the Series 4, back as a low-volume hand built and bespoke affair, marketed in a similar way to Bristol, with a price (£70,000 and more) to match. Though the body remained essentially the same as the last of the main production run of series 3; the engine was a much smaller Chrysler supplied 5.9 litre unit which used more modern controls to reduce emissions comparatively and still produce about 230 hp. In addition, the interior was slightly re-designed with the addition of modern “sports” front seats as opposed to the armchair style of the earlier models, as well as a revised dashboard and electronics. The then owner sold up in 1990 to an engineering company believed to be in a stronger position to manufacture the car which lasted until 1993 with approximately 36 cars built, and while work commenced on development of a Series 5 Interceptor, once again receivers were called in and the company was liquidated. Even that was not quite the end of the story, as the Jensen specialist based at Cropredy Bridge has made a business out of rebuilding original Interceptors using modern components, with a General Motors supplied 6.2 litre LS3 engine and transmission from a Chevrolet Corvette. In May 2010, Jensen International Automotive was set up, with the financial backing and know-how of Carphone Warehouse founder and chairman Charles Dunstone who joined its board of directors. A small number of Jensen Interceptor Ss, which had started production under a previous company, are being completed by Jensen International Automotive (JIA), in parallel with JIA’s own production of the new Jensen Interceptor R; deliveries of the latter started at the beginning of 2011.

Picture 304 Picture 303

LAMBORGHINI

The Lamborghini Huracán (Spanish for “hurricane”; [uɾaˈkan]) is a sports car replacing the previous V10 offering, the Gallardo. The Huracán was revealed online in December 2013, making its worldwide debut at the 2014 Geneva Auto Show, and was released in the market in the second quarter of 2014. The Huracán’s name (huracán being the Spanish word for hurricane) is inspired by a Spanish fighting bull. Historic Spanish fighting bulls have traditionally provided the names of most Lamborghini car models. Huracán was a bull known for its courage that fought in 1879. The Huracán maintains the 5.2-litre naturally aspirated Audi/Lamborghini V10 engine with an additional 0.2 litres, compared to the Gallardo, tuned to generate a maximum power output of 602 bhp/610 PS. To ensure its balance and performance, the car is mid-engined. The engine has both direct fuel injection and multi-point fuel injection. It combines the benefits of both of these systems; it is the first time this combination is used in a V10 engine. To increase its efficiency, the Huracán’s engine also includes a start-stop system.[citation needed] The firing order of the engine is 1, 6, 5, 10, 2, 7, 3, 8, 4, 9. This is printed on a metal plate on the top of the engine, as with all other Lamborghini models. The drag coefficient of Cd=0.39 was undisclosed until 2021. The LP 610-4 designation comes from the car having 610 PS and four-wheel drive, while LP stands for “Longitudinale Posteriore”, which refers to the longitudinal mid-rear engine position. Changes from the Gallardo include full LED illumination, a 12.3 inch full-colour TFT instrument panel, fine napa leather and Alcantara interior upholstery, redesigned dashboard and central tunnel, Iniezione Diretta Stratificata (IDS, essentially an adapted version of parent Audi’s Fuel Stratified Injection) direct and indirect gasoline injections, engine Stop & Start technology, EU6 emissions regulation compliance, Lamborghini Doppia Frizione (LDF) 7-speed dual-clutch transmission with 3 modes (STRADA, SPORT and CORSA), 20-inch wheels, carbon-ceramic braking system, optional Lamborghini Dynamic Steering variable steering system and MagneRide electromagnetic damper control. The main competitors of the Huracán include the McLaren 650S (as well as the 720S), the Audi R8, the Ferrari 458 Speciale and the 488 GTB. Extra options that increase the price of the car include interior enhancements, special paint schemes, improved suspension, and a lifting system, as well as multiple components optionally available in carbon fibre, rather than aluminium. The convertible variant of the Huracán LP 610-4 was revealed at the Frankfurt Motor Show on 14 September 2015. The 5.2-litre naturally-aspirated V10 engine is the same as the coupé and generates a maximum power output of 602 bhp/610 PS. Acceleration from 0 to 100 km/h (62 mph) takes 3.4 seconds and the top speed is 323 km/h (201 mph). It has the same 7-speed Lamborghini Doppia Frizione (LDF) dual-clutch transmission as that of the coupé. The Spyder has a dry weight of 1,542 kg (3,400 lb) which is 120 kg (265 lb) more than the coupé due to chassis reinforcing components. The Spyder has a CO2 emission of about 280 g/km. Unveiled at the 2016 Geneva Motor Show, the Huracán LP 580-2 is a lower cost derivative of the Huracán LP 610-4 that differs mostly in having the 5.2 L V10 engine detuned to 572 bhp/580 PS and 533 Nm (393 lb/ft) of torque along with having a rear wheel drive drivetrain instead of the all-wheel drive drivetrain found in the standard Huracán. Lamborghini claims the car will accelerate from 0–100 km/h (0–62 mph) in 3.4 seconds and 0–200 km/h (0–124 mph) in 10.1 seconds. The top speed is claimed to be as high as 320 km/h (199 mph). It also features slight visual differences to the standard variant of the car – with a different front fascia and larger air vents at the rear of the car for improved brake cooling. The seven-speed dual-clutch transmission is the same as used in the standard LP 610–4. The base level LP 580-2 costs US$201,100, about US$40,000 less than the base level LP 610–4. A convertible variant of the Huracán LP 580-2 was unveiled at the Los Angeles Auto Show on 16 November 2016. The 5.2-litre naturally-aspirated V10 engine is the same as in the coupé, and generates a maximum power output of 572 bhp/580 PS. 0 to 100 km/h (62 mph) takes 3.6 seconds and the top speed is 320 km/h (199 mph). A track oriented variant of the Huracán, called the Performante, was unveiled at the 2017 Geneva Motor Show. The Performante underwent various exterior changes with the most noticeable being the front and rear bumpers. Carbon fibre is used for the bumpers and the side skirts. An adjustable carbon fibre rear wing has been added to increase downforce. The position of the exhaust has also been changed, and is now just a bit above the rear diffuser. The interior also underwent noticeable changes, now sporting new seats and a new digital speedometer (similar to that of the Aventador SV’s speedometer). The Performante’s 5.2-litre V10 has been tuned to have a power output of 631 bhp/640 PS at 8,000 rpm and 601 Nm (443 lb/ft) of torque at 6,500 rpm. The weight has also decreased by 40 kg (88 lb), courtesy of the forged aluminium and forged carbon fibre body components (first used in the construction of the Sesto Elemento). All the new aero components on the car have active aerodynamic capability and help keep the car stable at high speeds. The Performante is capable of accelerating from 0–100 km/h (0–62 mph) in 2.9 seconds, 0–200 km/h (0–124 mph) in 8.9 seconds. It also has a theoretical top speed of 325 km/h (200 mph). The car has been stiffened by 10% with new springs, roll bars, and radial axial arm bushings. The magnetorheological suspension has been reworked to give a driver a serious track experience. The Lamborghini Dynamic Steering has been re-calibrated. The Performante utilises Lamborghini’s new ALA (Aerodinamica Lamborghini Attiva) system, which is said to be 80% lighter than regular sports car hydraulic systems. According to Lamborghini, ALA is also said to provide 750% more downforce than the standard Huracán. The Lamborghini Huracán Performante Spyder was unveiled at the 2018 Geneva Motor Show. It takes much of the styling inspiration from the coupé and the outgoing LP 610-4 Spyder. The Spyder is identical to the coupé from performance and technological standpoint, but the acceleration time from 0–60 mph has risen by one-tenth of a second and stands at 3.1 seconds while the 0–200 km/h (0–124 mph) has risen by four-tenths of a second and stands at 9.3 seconds. Due to the loss of the roof, the Spyder weighs 125 kg (276 lb) more than the coupé due to chassis reinforcing components. Top speed remains the same as well and stands at 325 km/h (202 mph). Deliveries of the Spyder began in the fourth quarter of 2018. The Huracán received a mid-cycle update in 2019, now being called the Huracán Evo. It now shares its engine and some of the technology with the Performante variant. The updated version of the Huracán has a more aggressive design language, the new front bumper has integrated aeroblades for improved downforce along with the rear styling inspired by the Performante variant, having the same rear diffuser, exhaust pipe position and radiators. A new ducktail spoiler improves downforce by 5 times as compared to the outgoing model. The engine is shared with the Performante and generates 631 bhp/640 PS at 8,000 rpm and 601 Nm (443 lb/ft) of torque at 6,500 rpm. The exhaust system is more refined and has titanium intake valves. This allows the car to achieve a 0–60 mph) acceleration time of 2.9 seconds, 0–200 km/h (0–124 mph) acceleration time of 9 seconds and a top speed of 325 km/h (202 mph). The car has a braking distance from 100–0 km/h (62–0 mph) of 104 ft (32 m). The Huracán Evo has a rear-wheel steering system for improved handling and a torque vectoring system. A new central processing unit controls the various functions of the car and monitors various settings. The control system is controlled by the new infotainment system (via an 8.4 inch touchscreen) dubbed the Lamborghini Dinamica Veicolo Integrata which has integrated both Apple CarPlay and Android Auto. The infotainment system predicts the driving modes by a feed forward logic. The feed forward logic works by sensors monitoring the lateral, longitudinal and vertical accelerations, as well as roll, pitch and yaw rate to predict the best possible driving mode for the driver. The magnetorheological suspension is also revised and now uses electromagnetic current to adjust the suspension system in accordance with the driving mode. The transmission system from the outgoing model is retained which transfers power to all four wheels. A new Ego mode allows the driver to change driving settings to their own preference. The Huracán Evo Spyder was introduced online in February 2019. The Spyder has the same enhancements as the coupé but is 100 kg (220 lb) heavier due to the addition of chassis reinforcement components owing to the loss of the roof. The car has the same canvas folding soft top as the outgoing model which takes 17 seconds for operation and is operable at speeds up to 50 km/h (31 mph). The Spyder can accelerate to 100 km/h (62 mph) in 3.1 seconds from a standstill, to 200 km/h (124 mph) in 9.3 seconds and can attain a top speed of 325 km/h (202 mph). A rear-wheel drive variant of the Evo debuted in January 2020, replacing the LP 580–2. The front splitter has been reshaped and generates more airflow, which is directed to the revised diffuser. Unique to the RWD model is P-TCS (Performance Traction Control System) that ensures that torque is not cut off abruptly; Lamborghini claims this increases oversteer by 30 percent compared to the LP 580–2. The engine is detuned and is now rated at 602 bhp/610 PS. Due to the detuned engine, the car is slower than the standard Huracán Evo accelerating to 100 km/h (62 mph) in 3.3 seconds while having the same top speed. The car also receives a unique paint option, Giallo Belenus, along with a matching interior upholstered in leather and microsuede. A convertible version of the rear-wheel drive variant of the Evo was showcased in May 2020, replacing the LP 580-2 Spyder. Like the Coupé variant, the convertible has a power output of 602 bhp/610 PS. The convertible has a 0– 60 mph acceleration time of 3.5 seconds and has a claimed top speed of 323 km/h (201 mph). Unveiled on April 12, 2022, The Huracán Tecnica sits between the EVO RWD and the track-focused STO. It is 6.1 cm (2.4 in) longer than the EVO, but is the same height and width. It uses the naturally-aspirated V10 engine from the STO and has a top speed of 325 km/h (202 mph) and an acceleration time of 0–100 km/h (0–62 mph) in 3.2 seconds. According to Lamborghini, the Tecnica’s aerodynamic changes increase downforce 35 percent and reduce drag by 20 percent compared to the EVO. It is expected that production will end in 2024.

Picture 242

LANCIA

Homologation requirements for the World Rally Championship’s Group B mandated Lancia to produce at minimum 200 verifiable road-going examples in order to compete with the 037. 207 037 Stradale (Italian for “road going/for the road”) cars are known to have been produced from 1982 through 1984. This road-going 037 variant was equipped with an Abarth-developed DOHC 2.0-litre (1,995 cc) 16-valve Inline-four engine, mated to an Abarth Volumex Roots-type supercharger generating 205 hp at 7,000 rpm. It was capable of pushing the car to over 220 km/h (137 mph) and to 100 km/h (62 mph) from a standstill in 5.8 seconds.

Picture 277 Picture 278 Picture 241Picture 240 Picture 347 Picture 276 Picture 284

LAND ROVER

The first-generation Range Rover was produced between 1969 and 1996. It was available only in a 2-door body until 1981. (Before then, 4-door models had been produced by specialist firms). Unlike other 4x4s such as the Jeep Wagoneer, the original Range Rover was not designed as a luxury vehicle. It was up-market compared to preceding Land Rover models, but the early Range Rovers had fairly basic, utilitarian, interiors with vinyl seats and plastic dashboards that were designed to be washed down with a hose. Convenience features such as power steering, carpeted floors, air conditioning, cloth/leather seats, and wooden interior trim were fitted later. The Range Rover was a body-on-frame design with a box section ladder type chassis, like the contemporary Series Land Rovers. The Range Rover used coil springs as opposed to leaf springs, permanent four-wheel drive, and four-wheel disc brakes. The Range Rover was originally powered by various Rover V8 engines and diesel engines. Originally, the Range Rover was fitted with a detuned 130 hp version of the Buick-derived Rover V8 engine. In 1984, the engine was fitted with Lucas fuel injection, boosting power to 155 bhp. The 3.5-litre (3,528 cc) engine was bored out to a displacement of 3.9 litres for the 1990 model year, and 4.2-litre in 1992  for the 108-inch Long Wheelbase Vogue LSE (County LWB [long wheelbase] in North America). One of the first significant changes came in 1981, with the introduction of a four-door body. Shortly after twin thermo fan technology was introduced to reduce significant overheating problems 1970s models experienced in Australia. In 1988, LR introduced a 2.4-litre turbodiesel (badged Vogue Turbo D) with 112 bhp, manufactured by Italian VM Motori. The same engine was available in the Rover SD1 passenger car. The diesel project was codenamed project Beaver. During the project, 12 world records were broken, including the fastest diesel off-roader to reach 100 mph (160 km/h), and the furthest a diesel off-roader has travelled in 24 hours. In 1990 project Otter was unveiled. This was a mildly tuned 2.5-litre, 119 bhp version of the ‘Beaver’ 2.4. In 1992, Land Rover finally introduced their own diesel engines in the Range Rover, beginning with the 111 bhp 200TDi, first released in the Land Rover Discovery and following in 1994, the 300 TDi, again with 111 bhp. The first generation was known as the Range Rover until almost the end of its production when Land Rover introduced the name Range Rover Classic to distinguish it from its successors. The original model served as the basis for the 1989 introduced 1st generation Discovery (directly based on the standard (short) wheelbase Range Rover), and for the 2nd generation Range Rover, based on the LWB chassis of the Classic.

Picture 337 Picture 335

LOTUS

At the Frankfurt 2011 Show, the 2012 version of the Exige S was announced. It features a supercharged 3.5 litre V6 engine (from the Evora S) rated at 345 hp. In 2013, a roadster version was introduced with only minor changes to the design for the removable top. The engine and performance were virtually unchanged from the coupe. To accommodate the V6 engine, the new model is approximately 25 cm (9.8 inches) longer and 5 cm (2.0 in) wider (exterior bodywise) than the model with the inline-four engine, being 4,052 mm (159.5 inches) long, 1,802 mm (70.9 in) wide (not counting the mirrors) and 1,153 mm (45.4 in) tall. The drag coefficient is 0.433. Since that time there have been a bewildering array of different versions and you need to be a real marque expert to tell them all apart. The policy has worked, though, as sales have remained steady whilst Lotus try to amass the finances to develop any all new models. The Exige V6 Cup is a track oriented version of the Exige S while the Exige CupR is the track-only version of Exige V6 Cup. The Exige V6 Cup is offered for sale in the United States as a track only car. If purchased, US Lotus Dealers will only provide a bill of sale instead of a title. The vehicles were unveiled at the 2013 Autosport International motor show. Limited to 50 examples, the Lotus Exige 360 Cup was revealed on 14 August 2015. The car is powered by a 3.5-liter supercharged Toyota V6 delivering 355 hp. The Lotus Exige Sport 380 is a track focused and more powerful version of the Lotus Exige lineup. It was unveiled on 23 November 2016. Lotus’ CEO, Jean-Marc Gales describes it as, “The Exige Sport 380 is so good, that it is no longer the best in class, it’s now in a class of its own”, and it fulfills this statement by taking on some of the powerful and expensive super cars both on the track and the streets. The 3.5-litre, super-charged V6 engine is now uprated and produces 375 hp and 410 Nm (302 lb/ft) of torque with a 6500 rpm red line achieved by revised supercharger and ECU. It can accelerate from 0 to 60 mph in 3.5 seconds and has a top speed of 178 mph (286 km/h). The interior is also stripped out and features necessary driver aids. The Exige Sport 380 weighs 1,076 kg (2,372 lb), thanks to the extensive use of carbon fibre on the exterior as well as the interior, the application of polycarbonate windows instead of traditional glass windows and a newly designed rear transom panel which features two rear lights instead of four.The Lotus Exige Cup 380 is a more hardcore variant of the Exige Sport 380. Performance of the car remains the same as the Sport 380 but it features more aero components and a larger rear wing to produce more downforce at high speeds. The Exige Cup 380 generates 200 kg (441 lb) of downforce at its maximum speed of 175 mph (282 km/h); the top speed is reduced due to excess downforce and more drag. It features a more stripped out interior in order to save weight and other light weight carbon fiber components, Lotus states a lowest possible dry weight of only 1,057 kg (2,330 lb). On 9 November 2017, Lotus unveiled the most powerful version of the Exige to date called the Exige Cup 430, producing 430 PS (424 hp) and using the Evora GT430’s powertrain, modified to fit in the smaller Exige. The car body can produce 220 kg (485 lb) of downforce. The Cup 430 is 19 kg (42 lb) lighter than the Sport 380 due to the use of carbon fibre in body panels and interior and a titanium exhaust. The gearbox allows quicker gearshifts than the previous model. The Cup 430 is not offered with an automatic gearbox. The Lotus Exige Cup 430 is capable of covering the Hethel circuit in 1 minute 24.8 seconds – the fastest production car to lap the circuit – 1.2 seconds faster than the road going Lotus 3-Eleven.

Picture 263

Currently Lotus are only producing one car, the Emira, though more are – all electric – are coming. Production of the Emira was somewhat delayed but there are now significant numbers of the cars (by Lotus standards!) out perhaps it was not a surprise to see the model here.

Picture 302

MASERATI

The Maserati GranTurismo and GranCabrio (Tipo M145) are a series of a grand tourers produced from 2007 to 2019. They succeeded the 2-door V8 grand tourers offered by the company, the Maserati Coupé, and Spyder. The GranTurismo set a record for the most quickly developed car in the auto industry, going from design to production stage in just nine months. The reason being that Ferrari, after selling off Maserati to the Fiat Chrysler Group, took the designs of the proposed replacement of the Maserati Coupé and after some modifications, launched it as the Ferrari California. Unveiled at the 2007 Geneva Motor Show, the GranTurismo has a drag coefficient of 0.33. The model was initially equipped with a 4.2-litre V8 engine developed in conjunction with Ferrari. The engine generates a maximum power output of 405 PS and is equipped with a 6-speed ZF automatic transmission. The 2+2 body was derived from the Maserati M139 platform, also shared with the Maserati Quattroporte V, with double-wishbone front suspension and a multilink rear suspension. The grand tourer emphasises comfort in harmony with speed and driver-enjoyment. The better equipped S variant was unveiled at the 2008 Geneva Motor Show and features the enlarged 4.7-litre V8 engine shared with the Alfa Romeo 8C Competizione, rated at 440 PS at 7,000 rpm and 490 Nm (361 lb/ft) of torque at 4,750 rpm. At the time of its introduction, it was the most powerful road-legal Maserati offered for sale (excluding the homologation special MC12). The engine is mated to the 6-speed automated manual shared with the Ferrari F430. With the transaxle layout weight distribution improved to 47% front and 53% rear. The standard suspension set-up is fixed-setting steel dampers, with the Skyhook adaptive suspension available as an option along with a new exhaust system, and upgraded Brembo brakes. The seats were also offered with various leather and Alcantara trim options. The upgrades were made to make the car more powerful and more appealing to the buyers while increasing performance, with acceleration from 0–100 km/h (0–62 mph) happening in 4.9 seconds and a maximum speed of 295 km/h (183 mph). Aside from the power upgrades, the car featured new side skirts, unique 20-inch wheels unavailable on the standard car, a small boot lip spoiler, and black headlight clusters in place of the original silver. The variant was available in the North American market only for MY2009 with only 300 units offered for sale. The GranTurismo MC is the racing version of the GranTurismo S developed to compete in the FIA GT4 European Cup and is based on the Maserati MC concept. The car included a 6-point racing harness, 120 litre fuel tank, 380 mm (15.0 in) front and 326 mm (12.8 in) rear brake discs with 6-piston calipers at the front and 4-piston calipers at the rear, 18-inch racing wheels with 305/645/18 front and 305/680/18 rear tyres, carbon fibre bodywork and lexan windows throughout along with a race interior. All the weight-saving measures lower the weight to about 3,000 lb (1,361 kg). The car shares the 4.7-litre V8 engine from the GranTurismo S but is tuned to generate a maximum power output of 450 PS along with the 6-speed automated manual transmission. The GranTurismo MC was unveiled at the Paul Ricard Circuit in France. It went on sale in October, 2009 through the Maserati Corse programme. 15 GranTurismo MC racecars were developed, homologated for the European Cup and National Endurance Series, one of which was taken to be raced by GT motorsport organization Cool Victory in Dubai in January, 2010. Introduced in 2008, the GranTurismo MC Sport Line is a customisation programme based on the GranTurismo MC concept. Changes include front and rear carbon-fibre spoilers, carbon-fibre mirror housings and door handles, 20-inch wheels, carbon-fibre interior (steering wheel rim, paddle shifters, instrument panel, dashboard, door panels), stiffer springs, shock absorbers and anti-roll bars with custom Maserati Stability Programme software and 10 mm (0.4 in) lower height than GranTurismo S. The programme was initially offered for the GranTurismo S only, with the product line expanded to all GranTurismo variants and eventually all Maserati vehicles in 2009. Replacing both the GranTurismo S and S Automatic, the Granturismo Sport was unveiled in March 2012 at the Geneva Motor Show. The revised 4.7L engine is rated at 460 PS. The Sport features a unique MC Stradale-inspired front fascia, new headlights and new, sportier steering wheel and seats. The ZF six-speed automatic gearbox is now standard, while the six-speed automated manual transaxle is available as an option. The latter has steering column-mounted paddle-shifters, a feature that’s optional with the automatic gearbox. New redesigned front bumper and air splitter lowers drag coefficient from Cd=0.33 to 0.32. In September 2010, Maserati announced plans to unveil a new version of the GranTurismo – the MC Stradale – at the 2010 Paris Motor Show. The strictly two-seat MC Stradale is more powerful than the GranTurismo at 450 PS, friction reduction accounts for the increase, says Maserati, due to the strategic use of “diamond-like coating”, an antifriction technology derived from Formula 1, on wear parts such as the cams and followers. It is also 110 kg lighter (1,670 kg dry weight) from the GranTurismo, and more aerodynamic than any previous GranTurismo model – all with the same fuel consumption as the regular GranTurismo. In addition to two air intakes in the bonnet, the MC Stradale also receives a new front splitter and rear air dam for better aerodynamics, downforce, and improved cooling of carbon-ceramic brakes and engine. The body modifications make the car 48 mm (2 in) longer. The MC Race Shift 6-speed robotised manual gearbox (which shares its electronics and some of its hardware from the Ferrari 599 GTO) usually operates in an “auto” mode, but the driver can switch this to ‘sport’ or ‘race’ (shifting happening in 60 milliseconds in ‘race’ mode), which affects gearbox operations, suspension, traction control, and even the sound of the engine. The MC Stradale is the first GranTurismo to break the 300 km/h (186 mph) barrier, with a claimed top speed of 303 km/h (188 mph). The push for the Maserati GranTurismo MC Stradale came from existing Maserati customers who wanted a road-legal super sports car that looked and felt like the GT4, GTD, and Trofeo race cars. It has been confirmed by the Maserati head office that only 497 units of 2-seater MC Stradales were built in total from 2011 to 2013 in the world, Europe: 225 units, China: 45 units, Hong Kong: 12, Taiwan: 23 units, Japan: 33 units, Oceania: 15 units and 144 units in other countries. US market MC’s do not have the “Stradale” part of the name, and they are sold with a fully automatic six-speed transmission rather than the one available in the rest of the world. US market cars also do not come with carbon fibre lightweight seats like the rest of the world. The MC Stradale’s suspension is 8% stiffer and the car rides slightly lower than the GranTurismo S following feedback from racing drivers who appreciated the better grip and intuitive driving feel of the lower profile. Pirelli has custom-designed extra-wide 20-inch P Zero Corsa tyres to fit new flow-formed alloy wheels. The Brembo braking system with carbon-ceramic discs weighs around 60% less than the traditional system with steel discs. The front is equipped with 380 x 34 mm ventilated discs, operated by a 6 piston caliper. The rear discs measure 360 x 32 mm with four-piston calipers. The stopping distance is 33 m at 100 km/h (62 mph) with an average deceleration of 1.2g. At the 2013 Geneva Motor Show, an update to the GranTurismo MC Stradale was unveiled. It features an updated 4.7 litre V8 engine rated at 460 PS at 7,000 rpm and 520 Nm (384 lb/ft) of torque at 4,750 rpm, as well as the MC Race Shift 6-speed robotized manual gearbox which shifts in 60 milliseconds in ‘race’ mode. The top speed is 303 km/h (188 mph). All models were built at the historic factory in viale Ciro Menotti in Modena. A total of 28,805 GranTurismos and 11,715 units of the convertible were produced. The final production example of the GranTurismo, called Zéda, was presented painted in a gradient of blue, black and white colours.

Picture 262 Picture 265

MAZDA

There were three generations of the RX7 and this is the first. During its production life, there were three distinct series. Series 1 (1978–1980) is commonly referred to as the “SA22C” from the first alphanumerics of the vehicle identification number. In Japan it was introduced in March 1978, replacing the Savanna RX-3, and joined Mazda’s only other remaining rotary engine powered products, the Cosmo, a two-door luxury coupe, and the Luce luxury sedan. The lead designer at Mazda was Matasaburo Maeda, whose son, Ikuo, would go on to design the Mazda2 and Mazda RX-8. The transition of the Savanna to a sports car appearance reflected products from other Japanese manufacturers. The advantage the RX-7 had was its minimal size and weight, and the compact rotary engine installed behind the front axle, which helped balance the front to rear weight distribution, and provide a low centre of gravity. In Japan, sales were enhanced by the fact that the RX-7 complied with Japanese Government dimension regulations, and Japanese buyers were not liable for yearly taxes for driving a larger car. The rotary engine had financial advantages to Japanese consumers in that the engine displacement remained below 1.5 litres, a significant determination when paying the Japanese annual road tax which kept the obligation affordable to most buyers, while having more power than the traditional inline engines. The Series 2 (1981–1983) had integrated plastic-covered bumpers, wide black rubber body side mouldings, wraparound taillights and updated engine control components. While marginally longer overall, the new model was 135 lb (61 kg) lighter in federalised trim. The four-speed manual option was dropped for 1981 as well, while the gas tank grew larger and the dashboard was redesigned, including a shorter gear stick mounted closer to the driver. In 1983, the 130 mph speedometer returned for the RX-7. The GSL package provided optional four-wheel disc brakes, front ventilated (Australian model) and clutch-type rear limited slip differential (LSD). The second generation model was launched in late 1984.

Picture 305

MERCEDES-BENZ

The R170 Mercedes-Benz SLK-Class is the first generation of the Mercedes-Benz SLK-Class range of compact luxury roadsters produced by Mercedes-Benz between 1996 and 2004. SLK stands for the company’s design mission to create a sportlich (sporty), leicht (light) and kurz (compact) roadster, and is based on a shortened platform of the W202 Mercedes C-Class. The R170 Mercedes SLK is based on the SLK I Concept and SLK II Concept, which is a two-seater roadster concept car that features a folding metal electro-hydraulic roof, dubbed ‘vario-roof’ by Mercedes, and takes 25 seconds to operate. A German design patent was filed on 30 September 1993, with the final production version of the SLK introduced at the Turin Motor Show on 22 April 1996. The R170 SLK is based on the W202 C-Class platform, sharing many drivetrain and chassis components, as well as using a shortened version of the floor pan. The wheelbase is also identical to the wheelbase of the 190SL and 300SL, at 2,400 mm (94 in). The platform of the R170 Mercedes SLK is also used by the Chrysler Crossfire, which shares 80% of its components with the car. The SLK 200 was exported and sold exclusively to Italy, Netherlands, Portugal, Turkey, and Greece, and was only available with the Getrag five-speed manual transmission in most countries. After the 2000 facelift, the SLK 200 Kompressor was introduced to the worldwide market, replacing the SLK 200. The SLK 32 AMG was introduced in 2001, designed to rival the BMW M Roadster and Porsche Boxster S. The car featured the same M112 engine as in the SLK 320, but has a helical twin-screw supercharger and water-to-air intercooler. The SLK 32 AMG introduced Mercedes’ new ‘SpeedShift’ 5G-Tronic (automatic) transmission, that allow for manual shifting of the gears, and faster automatic downshifts before overtaking. There was no manual transmission option available for the SLK 32 AMG. The SLK 32 AMG features a more angular steering wheel, AMG instrument dials, an updated front and rear bumper with larger air intakes, and larger brakes; from 300 mm (12 in), upgraded to 334 mm (13 in) in diameter. SLK 32 production started from January 2001, to March 2004. A total of 4,333 were produced; 979 were sold in Germany, 2,056 were imported to the US, and 263 to the UK. It was replaced by the Mercedes R171 SLK in 2004.

Picture 306 Picture 307

The second generation Mercedes-Benz SLK, internally designated model R171, is a two-passenger, front-engine, rear-drive, retractable hardtop roadster, unveiled at the 74th Geneva International Motor Show—and manufactured and marketed for model years 2004–2010. Currently in its third generation and manufactured at Mercedes’ Bremen plant, the SLK nameplate designates Sportlich (sporty), Leicht (light), and Kurz (compact). The R171 features a number of revisions compared to its predecessor, the R170: a 30mm longer wheelbase, increased length (72mm) and width (65mm), 40% increased use of high strength steel, seven-speed automatic transmission, adaptive two-stage airbags, head/thorax sidebags and a revised roof mechanism (marketed as the Vario roof) deployable in 22 seconds (previously 25 seconds) with a rotary-pivoting rear window enabling a more compact folded roof stack and trunk storage increased by 63 litres with the roof retracted.[6] Optional features include remote operation of the retractable hardtop as well as an innovative forced air, neck-level heating system integral to the headrests, marketed as Airscarf. The fully galvanized bodywork, which features 19 percent improvement in static bending and 46 percent improvement in torsional strength with the roof down, also features a 3% improvement in aerodynamic efficiency, with a Cd value of 0.32. The design has been aerodynamically optimised to minimise interior draughts with the top retracted and includes a fabric windblocker which can be pulled up over the two roll-over bars. Mercedes marketed the R171’s tapering front end styling by designer Steve Mattin as “Formula One-inspired”. In 2008, the SLK reached sales of 500,000.  The R171 SLK were the last series that a manual transmission was available in a 6 Cylinder Mercedes-Benz Convertible. The successor to the R171, R172, only offered manual transmission in their 4-cylinder vehicles.

Picture 308

MG

Sitting alongside the MGB in the MG range was the smaller Midget, and there were a couple of these cars here, a Series 3 model and one of the later rubber-bumpered cars. The 1961 Midget resurrected the name that was used by MG for their smallest car, the M Type, in the late 20s, was the Midget announced in 1961, and was essentially a slightly more expensive badge-engineered version of the MkII Austin-Healey Sprite. The original ‘Frogeye’ Sprite had been introduced specifically to fill the gap in the market left by the end of production of the MG T-type Midget as its replacement, the MGA had been a significantly larger and more expensive car with greater performance. Many existing MG enthusiast and buyers turned to the Sprite to provide a modern low-cost sports car and so a badge-engineered MG version reusing the Midget name made sense. The new Midget differed from the Sprite only in its grille design, badging, colour options and having both leather seats and more external chrome trim as standard to justify its higher purchase price. Mechanically the car was identical to its Austin-Healey counterpart, retaining the rear suspension using quarter-elliptic leaf springs and trailing arms from the ‘Frogeye’. The engine was initially a 948 cc A-Series with twin SU carburettors producing 46 hp at 5500 rpm and 53 lb/ft at 3000 rpm. Brakes were 7″ drums all round. A hard top, heater, radio and luggage rack were available as factory-fitted extras. In October 1962 the engine was increased to 1098 cc, raising the output to 56 hp at 5500 rpm and 62 lb/ft at 3250 rpm, and disc brakes replaced the drums at the front. Wire spoked wheels became available. The doors had no external handles or locks and the windows were sliding Perspex side-screens. A heater was still an optional extra. The car sold well, with 16,080 of the small-engined version and 9601 of the 1098 being made before the arrival in 1964 of the Mark II. Externally the main changes were to the doors, which gained wind-up windows, swivelling quarter lights, external handles and separate locks. The windscreen also gained a slight curvature and was retained in a more substantial frame. The hood, though modified, continued to have a removable frame that had to be erected before the cover was put on. The rear springs were replaced by more conventional semi-elliptic types which gave a better ride. The engine block was strengthened and larger main bearings were fitted, increasing the power to 59 hp at 5750 rpm and torque to 65 lbf·ft at 3500 rpm. A total of 26,601 were made. 1967 saw the arrival of the Mark III. The engine now grew to 1275 cc using the development seen on the Mini-Cooper ‘S’. Enthusiasts were disappointed that this was a detuned version of the 76-bhp Cooper ‘S’ engine, giving only 65 hp at 6000 rpm and 72 lbf·ft  at 3000 rpm. A reduced compression ratio of 8.8:1 was used instead of the 9.75:1 employed on the Cooper S engine. The Midget used the 12G940 cylinder head casting that was common to other BMC 1300 cars, whereas the Cooper ‘S’ had a special head with not only larger inlet, but also larger exhaust valves; however, these exhaust valves caused many ‘S’ heads to fail through cracking between the valve seats. The detuned engine was used for reasons of model range placement – with the Cooper ‘S’ spec engine, the Midget would have been faster than the more expensive MGB. The hydraulic system gained a separate master cylinder for the clutch. The hood was now permanently attached to the car, with an improved mechanism making it much easier to use. Minor facelift changes were made to the body trim in late 1969 with the sills painted black, a revised recessed black grille, and squared off taillights as on the MGB. The 13″ “Rostyle” wheels were standardised, but wire-spoked ones remained an option. The square-shaped rear wheel arches became rounded in January 1972 and later that year a Triumph steering rack was fitted, giving a gearing that was somewhat lower than earlier Midgets. A second exhaust silencer was also added in 1972. Alternators were fitted instead of dynamos from 1973 onwards. Many consider the round-arch Midgets with chrome bumpers produced for model years 1972 and 1974 to be the most desirable. These round-arch cars started leaving the Abingdon factory in late 1971. Between 1966 and the 1969 face lift, 22,415 were made, and a further 77,831 up to 1974.

Picture 256

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

Picture 342

MINI

A rare Mini present was one of the Cabriolet models. Although there had been conversions done before – notably by Crayford in the early 1960s – this was the first one that was sold new through Austin-Rover dealers. It dates from 1991. Initially, 100 cars were produced by LAMM Autohaus, with their own body kit on the car, and they were all painted in Cherry red. A further 25 were ordered, before Rover committed to a greater volume, and in a wider variety of colours. They were based on the Cooper, and had upgraded trim, with a leather steering wheel, and wood-grained dash, door cappings and gear knob as well as bespoke badging, to help to justify the rather steep price tag of £12,250.

Picture 358 Picture 253

This is an example of the Paul Smith Mini. These were produced in March 1998, based on the Mini Cooper, powered by the familiar 1,275 cc engine. They were all painted in Paul Smith Blue, though some Japanese market cars were available in Black and White, Outside there was a chrome grille, handles, and bumpers and a green Great Britain isle badge on grille as well as a 24ct gold enamelled “Paul Smith” bonnet badge and Paul Smith rear window sticker. Inside you got Black leather trim, a Paul Smith-scripted instrument graphics; Citrus Green glovebox interior, petrol tank and solid boot liner. There were Charcoal grey Minilite alloy wheels, two spotlamps, Special “Paul Smith” denim jack & tool bag 300 were made foe the UK and 1,500 for the rest of the world. Paul Smith also designed a one-off Mini with 86 different-coloured stripes.

Picture 309

MORGAN

Based on Morgan’s first four wheeler, the rare Le Mans replica came with a 1098 cc Coventry Climax engine, cycle wing and sloping tail.

Picture 293 Picture 292

There were a number of what we think of as the traditional shaped Morgans here, as is usually the case at this event.

Picture 313 Picture 317 Picture 291

Also present here is the latest version of the three-wheeled Morgan, the Super 3.

Picture 249

NISSAN

Known in the UK as the Nissan 200SX, this is the Silvia S12, which was produced from August 1983 to 1989, with revisions to the exterior trim in 1986 (referred to as “Mark II”). It used retractable pop-up headlights and was sold in two configurations — a coupé (often called a “notchback” due to the side profile view of its rear window section) and a hatchback version, which bore heavy resemblance to the liftback versions of the Toyota Corolla Levin and Sprinter Trueno AE86. A number of different engines were equipped in the S12 chassis, depending on geographic market and production year, also a change in available engines again with the Mk2 revision. The NAPS system was carried over on the CA20E which replaced the Z engines of the S110 in North America. A CA18ET 1.8l turbo engine with ECCS was added for SE trims, Certain US trims had the S12 equipped with an optional VG30E V6 engine, also shared by the 300ZX (Z31). The FJ20 was replaced with the CA18DET in the Mk2 revision in markets where it was offered. The S12 chassis in Europe was badged as a “Silvia”, with a notable exception of Sweden where it was sold as the “180ZX”. “ZX” is traditionally associated with the Nissan Z-cars; the name change was done to avoid giving the car the same name as the Queen of Sweden. The ZX name was also used because Nissan’s Swedish importer decided to stop carrying the Z31 300ZX when the naturally aspirated version was discontinued for Europe; the Silvia acted as a partial replacement for the Z-car in that region. The European S12 was available only in the hatchback configuration, few were equipped with a rally package that included a rally foot brace for the navigator, headlamp guards, headlamp dust cleaners, with the same 1.8L SOHC Turbo (CA18ET) used in North America, and in some areas the 2.0L DOHC “FJ” engine (FJ20E). These models equipped with the rally package were dubbed “Rally Spec”. The “FJ” engine series was originally designed for the “DR30” Nissan Skyline chassis, in both turbocharged and naturally aspirated versions. The CA18ET was also available catalyzed, producing 122 PS.

Picture 354 Picture 279

PEUGEOT

Mindful of the success of the Golf GTi, in the class above, and how a small car with good handling could take more power, as the Mini Cooper had proved, Peugeot came up with the GTi in early 1984. The first models had a 1.6 litre  XU5J engine, producing 105 PS, which was uprated in 1987 with a cylinder head with larger valves thus becoming XU5JA, which took the power output up to 115 bhp. Visually the car retained the good looks of the 3 door version of the regular models, but it featured plastic wheel arch extensions and trim, beefier front and rear bumper valances and judicious use of red badging and trim. The shell also underwent some minor changes, including larger wheel arches (to suit the larger wheels , and the suspension was redesigned and sat lower on the GTI with stiffer springs, different wishbones and a drop-linked anti-roll bar. Red was a dominant colour inside. The car was an instant hit. At the end of 1986, Peugeot followed up with a more potent model, the 1.9 GTi, whose XU9JA engine produced 128 PS.  Internally the engine of this car and the 1.6 model are very similar, the main differences on 1.9 litre versions being the longer stroke, oil cooler, and some parts of the fuel injection system. The shorter stroke 1.6 litre engine is famed for being revvy and eager, while the 1.9 litre feels lazier and torquier. Outside the engine bay the main differences between the 1.6 GTi and the 1.9 GTi are half-leather seats on the 1.9 GTi  vs. cloth seats  and disc brakes all-round (1.9 GTi) vs. discs at the front and drum brakes at the back; as well as the 14-inch Speedline SL201 wheels on the 1.6 GTi  vs. 15 inch Speedline SL299 alloys on the 1.9 GTi. The 205 is still often treated as a benchmark in group car tests of the newest GTI models or equivalent. Peugeot itself has never truly recreated this success in future GTI models, although they came very close with the highly regarded GTI-6 variant of the Peugeot 306.

Picture 351 Picture 330 Picture 329

PORSCHE

Replacing the 964, the 993 models were first seen in October 1993, with production starting a few weeks later. Its arrival marked the end of air-cooled 911 models. The 993 was much improved over, and quite different from its predecessor. According to Porsche, every part of the car was designed from the ground up, including the engine and only 20% of its parts were carried over from the previous generation. Porsche refers to the 993 as “a significant advance, not just from a technical, but also a visual perspective.” Porsche’s engineers devised a new light-alloy subframe with coil and wishbone suspension (an all new multi-link system), putting behind the previous lift-off oversteer and making significant progress with the engine and handling, creating a more civilised car overall providing an improved driving experience. The 993 was also the first 911 to hreceive a six speed transmission. The 993 had several variants, as its predecessors, varying in body style, engines, drivetrains and included equipment. Power was increased by the addition of the VarioRam system, which added additional power, particularly in the mid-ranges, and also resulted in more throttle noise at higher revs; as a consequence, resulted in a 15% increase in power over its predecessor. The external design of the Porsche 993, penned by English designer Tony Hatter, retained the basic body shell architecture of the 964 and other earlier 911 models, but with revised exterior panels, with much more flared wheel arches, a smoother front and rear bumper design, an enlarged retractable rear wing and teardrop mirrors. A major change was the implementation of all alloy multi-link rear suspension attached to an alloy sub frame, a completely new design derived from the 989, a four-door sedan which never went into production. The system later continued in the 993’s successor, the 996, and required the widening of the rear wheel arches, which gave better stability. The new suspension improved handling, making it more direct, more stable, and helping to reduce the tendency to oversteer if the throttle was lifted during hard cornering, a trait of earlier 911s. It also reduced interior noise and improved ride quality. The 993 was the first generation of the 911 to have a 6-speed manual transmission included as standard; its predecessors had 4 or 5-speed transmissions. In virtually every situation, it was possible to keep the engine at its best torque range above 4,500 rpm. The Carrera, Carrera S, Cabriolet and Targa models (rear wheel drive) were available with a “Tiptronic” 4-speed automatic transmission, first introduced in the 964. From the 1995 model year, Porsche offered the Tiptronic S with additional steering wheel mounted controls and refined software for smoother, quicker shifts. Since the 993’s introduction, the Tiptronic is capable of recognising climbs and descents. The Tiptronic equipped cars suffer as compared to the manual transmission equipped cars in both acceleration and also top speed, but the differences are not much notable. Tiptronic cars also suffered a 55 lb (25 kg) increase in weight. The 993’s optional all wheel drive system was refined over that of the 964. Porsche departed from the 964’s setup consisting of three differentials and revised the system based on the layout from its 959 flagship, replacing the centre differential with a viscous coupling unit. In conjunction with the 993’s redesigned suspension, this system improved handling characteristics in inclement weather and still retained the stability offered by all wheel drive without having to suffer as many compromises as the previous all-wheel-drive system. Its simpler layout also reduced weight, though the four wheel drive Carrera 4 weighs 111 lb (50 kg) more than its rear wheel drive counterpart (at 3,131 lb (1,420 kg) vs. 3,020 lb (1,370 kg)). Other improvements over the 964 include a new dual-flow exhaust system, larger brakes with drilled discs, and a revised power steering. A full range of models arrived before the arrival of the 996 generation in 1998.

Picture 345 Picture 314 Picture 312

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

Picture 336

RENAULT

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 synchromesh 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.

Picture 252 Picture 257

ROVER

In December 1994 the revised R6 model appeared. In the United Kingdom, Rover finally scrapped the Metro nameplate, replacing it with a new name, Rover 100, which had been adopted on continental Europe on the Rover Metro’s launch in 1990, due to the weakness of the Austin marque in Europe. The mechanics of the car remained much the same with 1.1 and 1.4 petrol engines and Hydragas suspension, but there was now the option of a Peugeot-sourced 1.5 diesel rather than the previous 1.4. The exterior was altered in an attempt to disguise the car’s age, meet the increased cooling requirements of the Peugeot motor and offer a reduced-format Rover family grille. This was achieved through fitment of new front and rear bumpers, sill covers, rear boot handle and headlamps, bonnet and grille. A variety of bolder paint colours and the use of chrome trim helped give a more upmarket appearance. The interior trim was revised to give a greater impression of quality and luxury, but since the basic architecture had remained unchanged since the original 1980 car it was considered by many as being short on space and outdated in comparison to its most modern rivals (most of which had been replaced with all-new models since the launch of the Rover Metro, and in the cases of the Ford Fiesta and Vauxhall Nova/Corsa, replaced with all-new models twice) It was criticised by the press for its lack of equipment, with front electric windows only available on the range-topping 114 GSi. Rear electric windows were never an option on the 100. Neither were Anti-Lock Brakes, Power Steering or a rev-counter (except the GTa and later manual 114 GSi models) One saving grace for the 100 was the option of full leather trim, a rarity in a small car and coupled with the standard wood veneer dashboard inserts, a tinted glass sunroof and the optional wood veneer door cappings, the 114 GSi made for traditional luxury motoring; an image Rover was trying to retain. The only safety efforts came in the form of an optional drivers airbag, an alarm, a passive engine immobiliser, a removable radio keypad, central locking and side intrusion beams. Overall, the 100 series was considered a rather typical facelift of a car which had been a class leader on launch some years earlier, only to be overtaken by newer cars including the Renault Clio, Fiat Punto and Volkswagen Polo. It was launched only a year before a heavily revised Ford Fiesta. A ‘warm’ version of the 100 called the 114 GTa was available from launch. The main differences over the 114 SLi three-door – which has the same engine – were sports seats, red seatbelts, a rev-counter, sports suspension, a slightly higher top speed, faster acceleration, GSi alloy wheels and GTa badging. It was only available as a three-door. In 1997, the Rover 100 gave a poor performance in Euro NCAP crash tests (despite the improved safety features, including side impact bars in the doors and an optional driver’s airbag, the 1970s design was showing its age) – it was at the time the only car tested to receive a one-star Adult Occupant Rating. Other small cars tested at the same time received 2 or 3 stars out of five. The passenger compartment was subjected to severe structural damage in the frontal-offset test and results showed a high risk of injury to all body regions for the driver. Meanwhile, the side impact test also showed high injury risks. The Rover 100’s dismal safety showing was not its only problem by 1997. It was fast falling behind the best cars in its sector when it came to design, build quality, refinement and specification, although it remained strong in terms of fuel economy and affordability. Unlike the Ford Fiesta, Volkswagen Polo and Vauxhall Corsa, the Rover 100 could still provide sub-£7,000 motoring. Facing a complete collapse of sales, Rover withdrew the 100 from production – marking the end of nearly 18 years of production. There was no direct replacement for the Metro/100, although the 1995 Rover 200 had been developed inside Rover Cars to serve as a replacement for the 100 as well as the previous 200 model, which was slightly larger. The 100 and 200 were sold concurrently until 1998, when the 100 was withdrawn. When the Rover 200 was facelifted in late 1999 and rebadged as the Rover 25, Rover marketed this as a supermini reflecting the continued, steady, growth of all car classes. The plan was for both the 100 and the 25 to be on the market until the launch of the true replacement for the Metro in the shape of the MINI. However, BMW’s sale of Rover put an end to those plans. BMW kept the MINI design and MG Rover’s notional successor to the Metro was the Rover 25 and its MG ZR relative. The gap left by the Metro as a true Rover city car was not filled until late 2003, when the Rover CityRover was launched – it was a 1.4 engined city car built in India alongside the Tata Indica. This model was nowhere near as popular as the Metro or even the Rover 100, and was not included in the revived product range by Nanjing Automobile following MG Rover’s bankruptcy in 2005.

Picture 281 Picture 282 Picture 341

TALBOT

The Sunbeam started off life as a Chrysler, launched in 1977, as the long awaited replacement for the Hillman Imp, production of which had ended a year earlier. Based on a cut-down version of the Avenger chassis, this neat looking hatch was initially offered with a choice of 1.0, 1.3 and 1.6 litre 4 cylinder engines and it retained rear wheel drive at a time when all the rivals were switching front wheel drive This was a move forced upon its maker by the lack of capital to do anything else, but whilst it was not great for space efficiency, it would have an advantage when it came to the sporting versions and indeed for what would turn out to be a very successful career in motorsport. The sporting road cars hit the market in 1979, and these are the only examples of the Sunbeam that you tend to see these days. By the time they hit the market, the Chrysler badging had gone, as a consequence of the sale of Chrysler’s European business to Peugeot-Citroen in the summer of 1978 meant that by mid 1979 a new name was required. The old Talbot branding was dusted off and overnight the cars all became Talbots. The first potent Sunbeam to appear had been the Ti, a sort of modern day version of the Avenger Tiger, with a 110 bhp twin carb 1600cc engine under the bonnet. It went on sale in the spring of 1979, as an appetiser for something more special, which had been unveiled at the Geneva Show in March, a few weeks earlier. The Sunbeam Lotus was the fruits of Chrysler’s commission to sports car manufacturer and engineering company Lotus to develop a strict rally version of the Sunbeam. The resulting ‘”Sunbeam Lotus” was based on the Sunbeam 1.6 GLS, but fitted with stiffer suspension, a larger anti-roll bar and a larger transmission tunnel. The drivetrain comprised an enlarged 2172 cc version of the Lotus 1973 cc 907 engine, a 16 valve slant four engine (the Sunbeam version being type 911, similar to the “Lotus 912”), along with a ZF gearbox, both mounted in the car at Ludham Airfield, close to the Lotus facility in Hethel, Norfolk, where the almost-complete cars were shipped from Linwood. Final inspection, in turn, took place in Stoke, Coventry. In road trim, the Lotus type 911 engine produced 150 bhp at 5,750rpm and 150 lb/ft of torque at 4,500rpm. In rallying trim this was increased to 250 bhp  Production cars were  not actually ready for deliveries to the public until after the mid-year rebranding, and thus became the “Talbot Sunbeam Lotus”. At first these were produced mostly in black and silver, although later models came in a moonstone blue and silver (or black) scheme. The car saw not only enthusiastic press reviews, but also much success in the World Rally Championship – in 1980, Henri Toivonen won the 29th Lombard RAC Rally in one, and, in 1981, the Sunbeam Lotus brought the entire manufacturer’s championship to Talbot. There is an enthusiastic following for Sunbeam Lotus cars these days.

Picture 254

TOYOTA

In July 1999, Toyota began production of the seventh-generation Celica, with European sales beginning late that year. It closely resembled the XYR concept with the exception of the front bumper and rear spoiler, while omitting the previously available coupe body style. The 2000 model year Celica was an element of Toyota Project Genesis, an effort to bring younger buyers to the marque in the United States. Toyota took time to lighten the car and lower cost wherever possible. Power window and door lock controls were placed in the center console so only 1 set was necessary for both doors. Initial sunroofs were made of polymer plastic instead of the traditional glass. This generation was assembled by Kanto Auto Works at its Higashi-Fuji plant in Susono, Shizuoka Prefecture, Japan. The Celica came in only one Liftback body style with the choice of two different engines. The ZZT230 was powered by a relatively economical 1.8 L 4-cylinder 140 hp 1ZZ-FE engine and the ZZT231 powered by a higher-performance 1.8 L 4-cylinder 192 hp (in Europe and Japan) 2ZZ-GE version, co-developed with Yamaha, the latter featuring a two-step variable valve lift control in conjunction with its variable valve timing. In 2004, CNNMoney.com rated the Celica as one of the best cars to purchase for fuel economy. Exporting of the Celica ceased in July 2005. However, until mid-May, customers could still order one, although it was advised they took action before that time ended. The last Celica was rolled off production line on 21 April 2006, after 36 years and seven generations. In its last year, the Celica was only officially sold in Japan. There has been no direct successor to the Celica, however, the Scion tC (exclusive to North America) is seen by some people as the spiritual successor to the Celica.

Picture 328

TRIUMPH

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

Picture 297

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

Picture 269 Picture 258

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

Picture 332 Picture 331

Based on the chassis and mechanicals of the Triumph Herald, the Spitfire was conceived as a rival to the Austin-Healey Sprite and MG Midget, which were launched a year earlier. The Triumph soon found a strong following, with many preferring it to the BMC cars which in time would become in-house stablemates. Mark II models arrived in 1965 and a more comprehensive facelift in 1967 with the distinctive “bone in mouth” front grille necessitated by US bumper height regulations also brought changes, but it was with the Mark IV that the greatest number of alterations would come about. The Mark IV featured a completely re-designed cut-off rear end, giving a strong family resemblance to the Triumph Stag and Triumph 2000 models, both of which were also Michelotti-designed. The front end was also cleaned up, with a new bonnet pressing losing the weld lines on top of the wings from the older models, and the doors were given recessed handles and squared-off glass in the top rear corner. The interior was much improved: a proper full-width dashboard was provided, putting the instruments ahead of the driver rather than over the centre console. This was initially black plastic however was replaced with wood in 1973. An all-new hardtop was also available, with rear quarter-lights and a flatter rear screen. By far the most significant change, however, was to the rear suspension, which was de-cambered and redesigned to eliminate the unfortunate tendencies of the original swing-axle design. The Triumph GT6 and Triumph Vitesse had already been modified, and the result on all these cars was safe and progressive handling even at the limit. The 75 hp engine was now rated at 63 hp (for UK market employing the 9:1 compression ratio and twin SU HS2 carburettors; the less powerful North American version still used a single Zenith Stromberg carburettor and an 8.5:1 compression ratio) due to the German DIN system; the actual output was the same for the early Mark IV. However, it was slightly slower than the previous Mark III due to carrying more weight, and employing a taller 3.89:1 final drive as opposed to the earlier 4.11:1. The engine continued at 1296 cc, but in 1973 was modified with larger big-end bearings to rationalise production with the TR6 2.5 litre engines, which somewhat decreased its “revvy” nature; there was some detuning, to meet new emissions laws, which resulted in the new car being a little tamer. With the overall weight also increasing to 1,717 lb (779 kg) the performance dropped as a consequence, 0 to 60 mph now being achieved in 15.8 seconds and the top speed reducing to 90 mph. The overall fuel economy also dipped to 32mpg. The gearbox gained synchromesh on its bottom gear. The Mark IV went on sale in the UK at the end of 1970 with a base price of £735. In 1973 in the United States and Canada, and 1975 in the rest of the world, the 1500 engine was used to make the Spitfire 1500. Although in this final incarnation the engine was rather rougher and more prone to failure than the earlier units, torque was greatly increased by increasing the cylinder stroke to 87.5 mm, which made it much more drivable in traffic. While the rest of the world saw 1500s with the compression ratio reduced to 8.0:1, the American market model was fitted with a single Zenith-Stromberg carburettor and a compression ratio reduced to 7.5:1 to allow it to run on lower octane unleaded fuel, and after adding a catalytic converter and exhaust gas recirculating system, the engine only delivered 53 bhp with a slower 0–60 time of 16.3 seconds. The notable exception to this was the 1976 model year, where the compression ratio was raised to 9.1:1. This improvement was short-lived, however, as the ratio was again reduced to 7.5:1 for the remaining years of production. In the UK the 9:1 compression ratio, less restrictive emissions control equipment, and the Type HS2 SU carburettors now being replaced with larger Type HS4 models, led to the most powerful variant to date. The 1500 Spitfire now produced 71hp (DIN) at 5500 rpm, and produced 82 lb/ft of torque at 3000 rpm. Top speed was now at the magical 100 mph mark, and 0 to 60 mph was reached in 13.2 seconds. Fuel economy was reduced to 29mpg. Further improvements to the suspension followed with the 1500 included longer swing axles and a lowered spring mounting point for more negative camber and a wider rear track. The wider, lower stance gave an impressive skid pad result of 0.87g average. This put the Spitfire head and shoulders over its competition in handling. The American market Spitfire 1500 is easily identified by the big plastic over-riders and wing mounted reflectors on the front and back wings. The US specification models up to 1978 still had chrome bumpers, but on the 1979 and 1980 models these were replaced by black rubber bumpers with built-in over-riders. Chassis extensions were also fitted under the boot to support the bumpers. Detail improvements continued to be made throughout the life of the Mark IV, and included reclining seats with “chequered brushed nylon centre panels” and head restraints, introduced for domestic market cars early in 1977 along with a new set of column stalk operated minor controls (as fitted already in the TR7) replacing the old dashboard mounted knobs and switches. Also added for the model’s final years were a wood dash, hazard flashers and an electric screen washer, in place of the previous manual pump operated ones.  Options such as the hard top, tonneau cover, map light and overdrive continued to be popular, but wire wheels ceased to be available. The 1980 model was the last and the heaviest of the entire run, weighing 1,875 lb (850.5 kg). Base prices for the 1980 model year was £3,631 in the UK.

Picture 267 Picture 268

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.

Picture 324 Picture 334

The 1300 Saloon, a medium sized luxury car, was intended as a replacement of the popular Triumph Herald. Launched at the London Motor Show in October 1965, the 1300 was designed by Michelotti in a style similar to the larger Triumph 2000. It was Leyland’s first front-wheel drive design. Their major rival was BMC, who were at the time producing three FWD model ranges including the Mini and the best-selling Austin 1100 series; it was hoped by Leyland that some of the 1100s phenomenal success would rub off on the new Triumph. Triumph decided to adopt a different layout to BMC however, placing the engine above the gearbox in a front-back configuration (but not sharing the same oil) rather than BMC’s transverse engine layout. This resulted in a tall profile for the engine/gearbox combination which limited styling options. The engine was the same 1296 cc unit as used in the Triumph Herald 13/60. (the engine had originated in 1953 in the Standard Eight in 803 cc form) A conventional OHV four-cylinder unit, it developed 61 hp with the single Stromberg CD150 carburettor (also as used in the Herald 13/60) and was mated to a 4-speed all-synchromesh gearbox. Front suspension was by double wishbone layout, attached to a shock-absorber/spring unit, and the rear suspension by semi-trailing arms and coil springs like the 2000. The interior was particularly well-appointed with full instrumentation in a wooden dashboard, wooden door cappings, adjustable steering column and comfortable seats with ventilated PVC upholstery. There was through-flow ventilation with outlets under the rear roof lip. The car was fairly roomy, and aside from a slightly baulky gearchange, easy to drive with very reasonable performance. Standard equipment was generous and included thick carpeting but no heated backlight. Although not reclining, the front seats were remarkably versatile and could be easily adjusted for height and rake. The steering column was adjustable not only up and down but back and forth as well. From a safety angle the door handles were recessed and could not be caught on clothing and the (awkward to operate) window winders were spring-loaded and similarly recessed. The instrument panel had a speedometer, fuel gauge, temperature gauge, ammeter and a comprehensive cluster of warning lights arranged in a “pie chart” formation. The rear seat had a centre armrest which could be folded up when not in use. Although the car was costly compared to its more humdrum rivals, it did find favour, both with the press, who rated it, and the public, who bought it in decent quantity. For 1968, the 1300TC joined the basic model. The TC used the engine then fitted in the Triumph Spitfire, which featured twin SU carburettors and in this configuration provided an advertised 75 hp. The compression ratio of the TC was 9.0:1, whereas the single carb engine compression was rated 8.5:1 The car was identified by discreet “TC” badges. Top speed was significantly higher than the 1300 at a claimed 90 mph and acceleration times were cut by 11 percent to a 0–50 mph time of 11.5 seconds. A road test a few months later significantly improved on the company’s performance claims, achieving a maximum speed of 93 mph and 0–50 mph time of 10.5 seconds. With the car then retailing for a recommended UK price of £909, the road test concluded that “the 1300 TC costs only £41 more than the original model, and is a very good bargain indeed”.  An estate version of the 1300 reached the concept stages, but was never produced due to budgetary constraints, so all 1300s are four door saloons. In August 1970 the 1300 and 1300TC were replaced by the Triumph 1500. The engine was enlarged to 1493 cc, providing a useful increase in torque, but a decrease in overall power and increased fuel consumption. The front end was cleaned up considerably, and the rear redesigned with longer tail, providing a useful increase in boot space. Production of the FWD Triumphs came to an end in 1973. 113,00 examples of the regular 1300 were made and 35,342 1300TCs, but there are surprisingly few left now.

Picture 374 Picture 376Picture 377 Picture 375 Picture 373

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

Picture 290 Picture 259 Picture 248

VAUXHALL

The front-wheel drive Opel Corsa was first launched in September 1982. It went on sale first in France, Italy, and Spain – markets where small cars represented from 34 to 43 percent of sales. Built-in Zaragoza, Spain, the first Corsas were three-door hatchback and two-door saloon models, with four-door and five-door versions arriving in 1984. In certain markets, commercial “van” models were also sold, with or without rear windows depending on local requirements. In mainland Europe, the saloon versions were known as the “Corsa TR” until May 1985 and received an egg-crate grille rather than the four slits used on hatchbacks. The saloons were intended to appeal to customers of the Opel Kadett C and its sister the Vauxhall Chevette who still desired a traditional 3-box sedan shape – but it did not sell particularly well in most of Europe but were popular in Spain and Portugal, among other markets. While only taking ten percent of French Corsa sales during the car’s first half-year, the TR represented half of all Corsas sold in Spain. The basic trim level was called just the Corsa, which was followed by the Corsa Luxus, Corsa Berlina, and the sporty Corsa SR. The SR receives a spoiler which surrounds the rear window, alloy wheels, checkered sport seats, and a somewhat more powerful 70 PS engine. Six years later, the Corsa received a facelift, which included a new front fascia and some other minor changes. The models were called LS, GL, GLS, and GT. The Corsa A was known in the United Kingdom market as the Vauxhall Nova (as it was considered that Corsa sounded too much like “coarser”), where it was launched in April 1983, following a seven-month-long union dispute due to British workers being angry about the car not being built there, in contrast to the rival Ford Fiesta, Austin Metro and Talbot Samba. In addition, there was also a dispute about the disparity of import tariffs, as while cars exported from Spain to the European Community were subject to tariffs of only 4.4 per cent, those exported in the other direction were subject to tariffs as high as 36.7 per cent. Power first came from 1.0 L 45 hp, 1.2 L 55 hp, and 1.3 L 70 hp petrol engines. (The first engines were all equipped with carburettors; fuel injection came later, but never for the 1.0.) The engines were based on the well proven Family II design, except for the 1.0 L and early 1.2 L engines, which were based on the OHV unit from the Kadett C. There was also an Isuzu-built, 67 PS 1.5 L turbo diesel engine available, which was also used in the Isuzu Gemini at around the same time. The diesel joined the line up in May 1987, at the Frankfurt Motor Show, along with the sporty GSi. The engines and most of the mechanical componentry were derived from those used in the Astra/Kadett. In September 1987 the Corsa received a light facelift, with a new grille that was now the same on hatchbacks and sedans, an updated interior, and other slight changes. For the 1989 model year, the 1.3 was bored out to 1.4 litres. Power remained the same, although torque increased. A rare “Sport” model was produced in 1985 to homologate for the sub 1,300 cc class of Group A for the British Rally Championship. These Sport models were white and came with unique vinyl decals, a 13SB engine with twin Weber 40 DCOE carburettors, an optional bespoke camshaft, a replacement rear silencer, and few luxuries. This gave 93 hp and a top speed of 112 mph (180 km/h) with a 0–60 mph time of 8.9 seconds. These are by far the rarest models (500 produced) and thus acquire a high market price if one does become available. A 1.6 L multi point fuel-injected engine with 101 PS at 5600 rpm (98 PS in the catalysed version) and capable of 186 km/h (116 mph) was added to the Corsa/Nova at the 1987 Frankfurt Motor Show, giving decent performance and being badged as a GSi (“Nova GTE” in pre-facelift models in the United Kingdom, later models were all called GSi). The GSi’s engine mapping had been carried out by Opel tuning specialists Irmscher. A model with the 82 PS 1.4 L multi-point fuel-injected engine, which was otherwise mechanically identical to the GSi, also became available as the Nova SRi in the United Kingdom. In January 1988, a turbocharged version of the Isuzu diesel engine was introduced, with power increased to 67 PS. The design was freshened in September 1990, with new bumpers, headlights, grille, and interior, but it was clearly recognisable as a gentle makeover of an early 1980s design when it had to compete with the latest two all-new superminis in Europe – the Peugeot 106 and the Renault Clio. The car was finally replaced in the spring of 1993.  Nearly 500,000 Novas were sold in Britain over its ten years on sale. In its best year, 1989, it was Britain’s seventh best selling car with more than 70,000 sales, but by February 2016, only 1,757 were still on the road.

Picture 318

VOLKSWAGEN

The all-electric retro-styled ID.Buzz is starting to appear on our roads and there was an example here which caught my eye.

Picture 326 Picture 327

VOLVO

Making another appearance here was this Volvo Cross Country C303the base model of a range of military vehicles produced by Volvo. The car was developed in the late 60s based on the successful L-3314 series and went into production in 1974. This version was produced both as a 4×4 and a 6×6. An 8×8 was planned but dropped. Engines were the B30 (B20 in the prototypes) from Volvo’s civilian cars. The C3 series feature portal axles with locking differentials resulting in very high ground-clearance (similar to the Unimog) and outstanding performance offroad. The cars are narrow to make it possible to navigate between trees and on narrow forest roads. They were also sold to civilian customers for rescue services, electricity companies etc. and private use. In the Swedish army the vehicles are designated “Terrängbil xx” (or “Tgb” for short) where “xx” is a number defining the type of vehicle. In the 1983 Paris-Dakar rally a Volvo C303 won the class for trucks under 10 tonnes. A total of 8,718 vehicles of the C3 series were made. Roughly 75% of these went into military service, with the remaining sold to civilian contracts. It was used by the Malaysian Army c. 1970–1990, the Royal Malaysian Police, and civilian users like Telekom Malaysia c. 1980s.

Picture 340

MORGAN SHOWROOM

The Showroom and Morgan museum are always open at events like this and it is always good to get the opportunity to have a look. Every time I come, I am reminded not just how expensive the modern Morgan is, but also how the cars hold their value well, as the pre-owned ones don’t come cheap either!

Picture 359 Picture 360 Picture 361 Picture 364 Picture 365Picture 363 Picture 362 Picture 366 Picture 367 Picture 368

This was a fitting finale to the 2023 season of events organised by Robin Webb and his team, split between Spetchley Park and this venue. I did ask if there are plans for anything over the winter months and at present, nothing can be confirmed, so it may be Spring 2024 before the series resumes. I look forward to that with eager anticipation.

Leave a Reply

Your email address will not be published. Required fields are marked *