As this is such a large event, and I took some many photos, and there is so much info about what I saw, everything does not fit in a single report, so there are three further articles from this event. The first of the series covers the Car Club displays (A to L), whilst another features the race activities and everything else that was on site, whilst the final one focuses specifically on the Iconic Auction that took place during the event.

CAR CLUB DISPLAYS

MASERATI

Known internally as Tipo AM109, the Mistral was a 2-seat gran turismo produced between 1963 and 1970, as a successor to the 3500 GT. It was styled by Frua and bodied by Maggiora of Turin. Named after a cold northerly wind of southern France, it was the first in a series of classic Maseratis to be given the name of a wind. The Mistral was the last model from the Casa del Tridente (“House of the Trident”) to have the company’s renowned twin-spark, double overhead cam straight six engine. Fitted to the Maserati 250F Grand Prix cars, it won 8 Grand Prix between 1954 and 1960 and one F1 World Championship in 1957 driven by Juan Manuel Fangio. The engine featured hemispherical combustion chambers fed by a Lucas indirect fuel injection system, a new development for Italian car manufacturers. Maserati subsequently moved on to V8 engines for their later production cars to keep up with the demand for ever more powerful machines. Three engine were fitted to the Mistral, displacing 3500, 3700 and 4000 cc and developing 235 bhp at 5500 rpm, 245 bhp at 5500 rpm and 255 bhp at 5200 rpm, respectively. Only the earliest of the Mistrals were equipped with the 3500 cc, the most sought after derivative is the 4000 cc model. Unusually, the body was offered in both aluminium and, from 1967, in steel, but no one is quite sure how many of each were built. The car came as standard with a five speed ZF transmission and four wheel solid disc brakes. Per Maserati practice, the front suspension was independent and the rear solid axle. Acceleration 0-60 for both the 3.7 litre and 4.0 litre engines was around or just under 7 seconds, and top speed approximately 140 mph (225 km/h) to 145 mph (233 km/h). The body was designed by Pietro Frua and first shown in a preview at the Salone Internazionale dell’Automobile di Torino in November 1963. It is generally considered one of the most beautiful Maseratis of all time. It is also often confused with the very similar looking but larger and more powerful Frua designed AC 428. A total of 828 coupés and 125 Spyders were built. Only the Spyder received the 3500 engine; just 12 were made, along with 76 3.7 litre and 37 4.0 litre versions. Twenty Spyders were right hand drive. The Mistral was succeeded by the Ghibli, which overlapped production from 1967 on.

The Sebring was based on the earlier Maserati 3500 GT, and aimed at the American Gran Turismo market, taking its name from Maserati’s 1957 racing victory at the 12 Hours of Sebring. A single two-seat spyder was built by Vignale in 1963 but did not enter production. The Series I (Tipo AM 101/S) was shown at the Salon International de l’Auto 1962 and again at the Salone dell’automobile di Torino in 1963. Employing all but the Maserati 3500’s coachwork, it could reach 137 mph and 0–60 mph in 8.5 seconds on 185×15 Pirelli Cinturato tyres. A Borg-Warner automatic transmission was available, a first for Italian automobiles. When leaving the factory it originally fitted Pirelli Cinturato 205VR15 tyres (CN72). A total of 348 Series I Sebrings were built between 1962 and 1965. The engine was updated in 1963, gaining 15PS for a total of 235 PS. The 3700 engine first appeared in 1964, although only a handful of Series I cars were thus equipped. In 1965, the modified Series II (Tipo AM 101/10) was introduced. It had lightly redesigned headlamps, modernised bumpers, new front indicators, and new side grilles replacing the lower extraction vents used hitherto. It took minor design cues from the contemporary Quattroporte. At the rear, aside from the squared off bumpers, the taillights were now mounted horizontally rather than vertically and the bootlid opening was narrowed somewhat. The Series II rode on larger 205×15 Pirelli Cinturatos. A run of 247 units were made from 1964 until 1968. Along with the 3500 engine, the 3700 and the even larger 4000 were added. The 4000 GTiS has a 4,012 cc engine producing 255 PS at 5,200 rpm. It remained in production until 1968, when financial constraints forced Maserati to drop its older models from production. No major updates took place over the last three years of production, except for a slight power gain for the 4000, now up to 265 PS. 348 units of Sebring 3.5 and 245 of 3.7 and 4.0 (combined) were made, for a total of 593 units from 1962 to 1969.

The Maserati Mexico’s design derived from a 2+2 prototype bodywork shown on the Vignale stand at the October 1965 Salone di Torino and built upon a 4.9-litre 5000 GT chassis, rebodied after it had been damaged. As the car after the show was sold to Mexican president Adolfo López Mateos, the model became known as the Mexico. By coincidence, John Surtees won the Mexican Grand Prix on a Cooper-Maserati T81 the following year. Vignale’s prototype was so well received that Maserati immediately made plans to put a version into production. The production Maserati Mexico debuted in August 1966 at the 20° Concorso internazionale di eleganza per auto in Rimini, while its international première was at the October Paris Motor Show. It was built on the first generation Quattroporte chassis with a wheelbase shortened by 11 cm (4.3 in). Originally powered by a 4.7-litre 90° V8 fed by four twin-choke 38 DCNL5 Weber carburetors that produced 290 bhp, the car managed to turn out a top speed between 240–250 km/h (149–155 mph). In 1969, however, contrary to Maserati tradition, the Mexico was also made available with a smaller engine, the 4.2-litre V8 engine. Apart from the smaller engine option the Mexico underwent few changes during its lifetime. Its luxurious interior included a rich leather seating for four adults, electric windows, wooden dashboard, iodine headlights and air conditioning as standard. Automatic transmission, power steering and a radio were available as optional extras. The 4.7-litre version was fitted with 650×15″ Borrani chrome wire wheels and the 4.2-litre version with steel disc wheels. When leaving the factory all Maserati Mexicos originally fitted Pirelli Cinturato 205VR15 tyres (CN72). The Mexico was the first production Maserati to be fitted with servo assisted ventilated disc brakes on all four wheels. In May 1967, under commission from the German concessionaire Auto Koenig for one client, Herr Rupertzhoven, Maserati built a ‘Mexico’ similar to Vignale’s original prototype design but was the work of Frua. Appearing like a 4-seat Mistral and built on the same tubular chassis as the 3500 GT (2600 mm wheelbase), this prototype ‘Mexico’ was fitted with the Mistral’s six-cylinder 3.7-litre Lucas fuel-injected engine. It was finished in Oro Longchamps with a black leather interior. Its dashboard came from the Quattroporte. 485 Mexicos were produced, 175 equipped with the 4.7 engine and 305 with the 4.2.

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

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

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

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

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.

Final Maserati here was the newly released Grecale in the striking Bianca Astro colour.

MATRA-SIMCA

The Matra Bagheera is a sports car built by the automotive division of the French engineering group Matra from 1973 to 1980, in cooperation with automaker Simca. It was marketed as the Matra-Simca Bagheera until its final year of production, when its designation was changed to the Talbot-Matra Bagheera following Chrysler Europe’s demise and subsequent takeover by PSA. In December 1969 Matra and Simca entered into an agreement that rebranded Matra’s racing cars as Matra-Simcas and give Matra access to the Simca dealer network in France and the Common Market. The first joint project of the new liaison was development of a replacement for the Matra 530, which had not reached either its targeted market or its projected sales volumes. Work on the new car began in 1970 under project code M550. Development was led by Matra’s head of engineering and design Philippe Guédon and Chrysler-Simca product planner Jacques Rousseau. Additional direction for the design was provided by Chrysler-Simca planner Marc Honoré. Honoré identified Simca’s strongest market as being cars displacing between 1.3 and 1.5 litres and suggested the team focus on building a car of that class, which would constrain the size of the car if performance was to be acceptable. As many as possible of the major components were sourced from the Chrysler-Simca parts inventory. Although the engine, gearbox and many suspension elements came directly from the Simca 1100, this new Matra was to be a mid-engined car rather than front-wheel drive like the donor car. Chrysler-Simca’s planners also wanted a car with more than just two seats. Guédon agreed, but he was also not satisfied with the 2+2 arrangement used in the M530, feeling that the rear seats were too small to be really useful. The solution came to him on a lengthy trip he took in a Ford Taunus station wagon with two colleagues. The back of the car was so full that the travelers sat three across in the front of the car. The M550 sat three abreast. Eleven prototypes were built and used for road-testing in environments ranging from Saharan Mauritania to Lapland, as well as for crash-testing. Development was complete by the end of 1972. The car was built in Matra’s factory in the commune of Romorantin-Lanthenay in the department of Loir-et-Cher in central France. Rather than being sold under its development code name, the car took its name from the character in Rudyard Kipling’s The Jungle Book. The Bagheera was unveiled to the press at an event held at Lake Annecy on April 14, 1973. The public release of the car took place at the 1973 24 Heures du Mans. At the same time Simca had arranged to have 500 yellow Bagheeras available at their dealers across France. Towards the end of 1973, production levels had reached 65 cars per day. In June 1974, within eighteen months of its release, more than 10,000 Bagheeras had been sold. The initial shape of the car was drawn by Jean Toprieux and later refined by Jacques Nochet. Greek designer Antonis Volanis joined the project and contributed to the interior, handling the instrument panel and steering wheel shapes. The body’s shape was that of a sleek hatchback with hidden headlights. The rear hatch opened to access the engine mounted behind the passenger compartment and a rear luggage space. The unusual three-abreast seating dictated by Guédon was implemented as a 2+1 arrangement. The driver had a regular seat while on the passenger side was a single two-place bench with two individual seatbacks inspired by a lounge chair Guédon had found in a Paris shop. Seen in plan view it is apparent that the body sides are slightly convex to accommodate the seating. The 19 panels that made up the Bagheera’s body were made of fiberglass-reinforced polyester, which were then attached to the chassis. The process used to make the panels was called `LP’, and it used a low-pressure high-temperature pressing method to produce panels using relatively inexpensive tooling.[6] The advantages of using LP for Matra were its ability to produce large, high quality panels with precision and economy. The LP process had only been in use for twelve month prior to the beginning of production, which means that Matra had introduced this new technology at the car’s early development stage. Problems with the car’s finish served to hamper sales when new, and in 1975 the Bagheera received German ADAC’s “Silver Lemon” award for being the new car with the most problems. The Bagheera won the 1973 Style Auto Award, beating out competition that included the Lancia Stratos, Lancia Beta coupé and Ferrari Dino 308 GT4. The Bagheera was also very aerodynamic, with a drag coefficient of 0.33 for the early models. This rose slightly to 0.35 after a mid-life redesign. The chassis was fabricated of pressed steel. While it has been called a space-frame it more closely resembled a unitary body. The shapes of some pieces were simplified to accommodate the low production numbers that the car was built in. The front suspension was from the Simca 1100. It consisted of upper and lower A-arms with telescopic hydraulic dampers and longitudinal torsion bars running back along the chassis for springing. An anti-roll bar was fitted at the front as well. The rear of the M550 prototype used the same type of suspension as the front, moved rearward along with the engine and transaxle. This proved unsatisfactory and so the final production cars received a new system that comprised new trailing arms designed by Matra with transverse torsion bars and telescopic shock-absorbers. An anti-roll bar was also fitted at the rear.No right-hand-drive Bagheeras were ever built by the factory, but a number were converted to RHD by Wooler-Hodec in England. The only engine offered at first was the 1,294 cc “Poissy engine” from Simca’s 1100 Ti model. In the Bagheera this ohv straight-4 engine developed 84 hp at 6000 rpm, two more horsepower than in the 1100 Ti. The transversely mounted engine was paired with the 4-speed manual transaxle from the 1100. In 1976 a larger version of the same engine became available when the 1,442 cc engine from the Simca 1308 GT was added to the lineup. The first Bagheera to use this engine was the newly introduced `S’ version. Changes were also made to the carburation. A 4-speed manual was still the only transmission offered. The Bagheera was released as a 1974 model-year car. This version had the original bodywork and 1294 cc engine with two two-barrel Weber carburetors. Although not an official designation, this model was often called the type I. For 1974 the `Courrèges’ model was launched. While mechanically identical to the Mark I this version, styled by fashion designer André Courrèges, had an all-white exterior and interior and dash trimmed in imitation gold. Apart from the colour it was distinguished by custom exterior badging and custom interior trim. In 1975  the Bagheera S’ model was launched. This car got the larger 1,442 cc engine from the Simca 1308 GT, as did the Courrèges the same year. With two two-barrel carburetors the engine produced 90 bhp. The `S’ was also distinguished by special exterior trim and badging. For 1976  the Bagheera received a major restyling. All body panels with the exception of the rear hatch were modified at least slightly. Most obvious were the new wrap-around bumpers, the new rear-quarter glass and the larger tail lamps. The changes raised the drag coefficient to 0.35. Inside there was a new dashboard. This model was now referred to by some as the type II. The base engine remained at 1294 cc, while both the `S’ and the Courrèges continued with the 1442 cc engine as standard. In 1977 the Courrèges model was dropped, and a new, fully optioned “Bagheera X” model took its place. For 1978 all models received a new dashboard and seats. In April a new “Jubilé” series was launched to commemorate Simca’s second “Car of the Year” win for the Horizon in 1978. Since PSA took control of Simca in the previous year (after the demise of Chrysler Europe), all Matra-Simcas became Talbot-Matras. In 1979 the 1294 engine was dropped and all Bagheeras got the 1442 cc engine but with variations in carburation. New doors and handles from the Rancho replaced the previously `hidden’ door handles. This necessitated a change to the rear quarter of the car. The `S’ was dropped from the lineup and only the base model and the `X’ model were available. Production of the Bagheera ended in April 1980 with 47,802 having been built in total. It was succeeded by the Matra Murena.

MAZDA

The MX-5 was unveiled at the Chicago Auto Show on February 10, 1989, with a price tag of US$14,000. The MX-5, with production code NA, was made available for delivery to buyers worldwide in the following dates: May 1989 (as a 1990 model) in the US and Canada; September 1, 1989 in Japan; and 1990 in Europe. An optional hardtop was made available at the same time, in sheet moulding compound (SMC). Demand initially outstripped production, fueled by enthusiastic press reviews. In Japan, the car was not badged as a Mazda, as the company was in the process of launching different marques for deluxe models, similar to Nissan’s Infiniti, Honda’s Acura and Toyota’s Lexus. Instead, the Mazda MX-5 was sold as the Eunos Roadster, and was joined by the MX-3/AZ-3/Eunos Presso (based on Japanese Mazda dealerships). The exterior dimensions and the engine displacement were also in compliance with Japanese Government compact car regulation. The body shell of the NA was all-steel with a lightweight aluminium bonnet. Overall dimensions were 3,970 mm (156 in) in length, 1,675 mm (65.9 in) in width, and 1,235 mm (48.6 in) in height. Without options, the NA weighed only 980 kg (2,160 lb). It had a drag coefficient of Cd=0.38. Suspension was an independent double wishbone on all four wheels, with an anti-roll bar at the front and rear. Four-wheel disc brakes, ventilated at the front, were behind alloy wheels with 185/60HR14 radial tyres. The base model came with stamped steel wheels from the then-current 323/Protege.The original MX-5, with standard manual transmission, came with a 1.6 L DOHC inline four-cylinder engine, producing 115 bhp at 6,500 rpm, and 136 N⋅m (100 lbf⋅ft) of torque at 5,500 rpm. The engine employs an electronic fuel injection system using a vane-type air flow meter and an electronic ignition system with a camshaft angle sensor instead of a distributor. This engine, codenamed B6ZE(RS), was specifically designed for the MX-5 and featured a lightened crankshaft, flywheel, and aluminium sump with cooling fins. An MX-5 with the optional automatic transmission had its 1.6L engine tuned to develop peak torque at lower rpm’s (136 Nm, 100 lb/ft at 4000 rpm) to better mate with the automatic transmission gearing and torque requirements. This tuning resulted in a lower peak power of 105 bhp at 6500 rpm. The standard transmission was a five-speed manual, derived from the one used in the Mazda 929/Luce (also rear-wheel drive) The gear shift was the subject of close attention during development, with engineers told to make it shift in as small a gear pattern as possible and with minimal effort. In Japan and the US, an optional automatic transmission was also offered. The Japanese and American markets also received an optional viscous limited-slip differential, although it was only available for cars with a manual transmission. To achieve the low introductory price, the base model was stripped. It had steel wheels, manual steering, roll-up windows, and no stereo or air-conditioning. Power steering, air-conditioning, and stereo were added as standard equipment in later years. The NA could reach 60 mph in 8.3 seconds and had a top speed of 203 km/h (126 mph) although Japanese market Eunos models were limited to 180 km/h (110 mph). This first generation of Miata (often referred to as the NA) included a special Limited Edition of 2000 examples in 1991, produced in British racing green with the first use of tan interior, to celebrate the highly successful launch of the MX-5 in the UK.[citation needed] These have a numbered brass plaque on the Windshield Frame and on the front of the Owners Book, and are fitted with alloy wheels from MSW (Mazda Sports Workshop) which are often mistaken for BBS, but which are entirely unique to this model. The NA with an automatic transmission reached 60 mph in 9.9 seconds and had a top speed of 181 km/h (112 mph). In 1993, 1,500 LE (Limited Edition) cars were produced. This model featured red leather interior, upgraded stereo, Nardi shift knob, leather-wrapped steering wheel, cruise control, limited-slip differential, power windows, power mirrors, power steering, air conditioning, BBS wheels, Bilstein shocks, front and rear spoilers, ABS brakes, stainless sill plates, and Harley style peanut tank door speaker trim. All 1993 LE cars came in black. For the 1994 model year, the first-generation MX-5 was freshened with the introduction of the more powerful 1,839 cc BP-ZE engine, dual airbags placed in a redesigned dashboard, the addition of a Mazda badge on the front fascia in the US and a limited-slip differential in some markets. The chassis was substantially braced to meet new side-impact standards, most visibly by adding a “track bar” between the seatbelt towers inside the car, but also to the front and rear subframes. Also, 1994 and 1995 were the only years in which Mazda offered a light metallic blue paint (Laguna Blue Mica), making these cars rare collector’s cars to some. 1994 also saw the introduction of the “R” package, a sport-themed package with Bilstein shocks, stiffer sway bars, retuned springs, subtle front and rear underbody spoilers, and a Torsen LSD. Air conditioning was optional, but the “R” package was not available with power steering, leather, or an automatic transmission. It can also be identified by a red Miata badge on the rear instead of the usual black. No body style changes were made, however. Halfway through the 1997 model year the hazard light button was changed to a black button with red symbol as opposed to the earlier red button with white symbol. The new 1,839 cc engine produced 129 bhp at 6,500 rpm and 149 Nm (110 lb/ft) of torque at 5,500 rpm, which was then increased to 133 bhp at 6,500 rpm and 155 Nm (114 lb/ft) of torque at 5,500 rpm for the 1996 model year. The base weight increased to 990 kg (2,180 lb). Performance was thus improved slightly, because the additional weight was more than offset by the extra power. In some markets such as Europe, the 1.6 L engine continued to be available as a lower-cost option, but was detuned to 89 bhp. This lower-powered model did not receive all the additional chassis bracing of the new 1.8 L. Japanese and U.S. models offered an optional Torsen LSD, which was far more durable than the previous viscous differential. There were a number of trim levels and special editions available, determined by local Mazda marketing departments. In the US, the base model was offered for US$13,995 at launch and was very basic, with manual windows, steel wheels, and without air conditioning or power steering. The “A Package” offered power steering, a leather-wrapped steering wheel, aluminium alloy wheels and cassette stereo. The “B Package” added power windows, along with cruise control and headrest speakers, while the “C Package” included a tan interior and top with leather seats. The “R Package” was for racing, and the annual special editions were formalized as “M Editions”. These included all of the luxury options from the “C Package” as well as special paint and, sometimes, special wheels. The first generation MX-5 was phased out after the 1997 model year (with the exception of 400 limited edition Berkeley models sold only in the UK in 1998 to mark the end of the NA), with the final 1,500 NAs produced for the US market being the “STO” (“Special Touring Option”) versions. In the UK, to celebrate Mazda’s 24 hours of Le Mans win, Mazda brought out a special edition of the MX-5, with the winner’s colour scheme (see Mazda 787B) and came equipped with BBR (Brodie Brittain Racing) turbo conversion; the car is one of the most sought after special edition cars of the MX-5s.

The Mazda MX-5 (NC) is the third generation of the Mazda MX-5 manufactured from 2005 to 2015. At its introduction in 2005, it won the Car of the Year Japan Award and made Car and Driver’s 10Best list from 2006 to 2013. The NC is the first MX-5 generation to feature a retractable hardtop variant, with its roof being able to fold and unfold in 12 seconds without sacrificing trunk space. The exterior styling by Yasushi Nakamuta resembled the original design, but unlike the update from NA to NB, which was mostly a nose/tail/interior change, the NC shares no components with the NB, except for the fender-mounted turn signal lights on non-U.S. models (and rear differential internals). The chief designer of this model generation was Moray Callum. The 2003 Mazda Ibuki concept served as a preview of the new model. The suspension changed from a four-wheel double wishbone setup to a front wishbone/rear multilink setup, shared with the Mazda RX-8. Technologies including traction control and stability control were added to increase driveability. According to Car and Driver, the NC has a skidpad number of 0.90g. For the U.S., the engine was the 16-valve, 2.0 L MZR LF-VE DOHC I4, producing 170 bhp and 190 Nm (140 lb/ft) of torque coupled to either a 5-speed or a 6-speed manual transmission or 158 bhp with the optional 6-speed automatic transmission. A limited-slip differential was available with the 6-speed option. In Australia, the 2.0 L MZR was offered, rated at 158 bhp and 188 N⋅m (139 lb/ft) of torque and the 6-speed transmission and LSD are standard. In Europe, two engines were offered: the 2.0 L MZR LF-VE rated at 158 bhp and 188 Nm (139 lb/ft) of torque, coupled to the 6-speed manual transmission; and a new 1.8 L MZR L8-VE, rated at 126 bhp and 167 Nm (123 lb/ft), coupled to the 5-speed manual transmission. A six-speed automatic transmission, with steering wheel mounted paddle shifters, was optional. A test by Car and Driver magazine revealed a 0-60 mph time of 6.5 s for the 2.0 L U.S.-spec NC. Manufacturer figures for the European-spec model are: 0-100 km/h (62 mph) in 9.4 s for the 1.8 and 7.9 s for the 2.0. As of this generation, the car no longer complies with Japanese law’s maximum exterior width dimension for the mid-size vehicle tax class, making Japanese buyers liable for additional costs for ownership. In July 2006, Mazda debuted a Power Retractable Hard Top (PRHT) version of the NC with a two-piece folding hardtop, named MX-5 Roadster Coupé in Europe, Roadster Power Retractable Hard Top in Japan, and MX-5 Miata Power Retractable Hard Top in the U.S. and Canada. Designed by Webasto and constructed of polycarbonate, the top requires 12 seconds to raise or lower, and the first models were delivered to customers in late August 2006. The hardtop adds 36 kg (79 lb) to the weight of a comparably equipped soft-top, without diminishing trunk space when retracted. The PRHT omits the soft-top’s storage compartments behind the seats to accommodate the folding roof mechanism. Performance times are slightly affected with the weight increase, with the 0-100 km/h (62 mph) time increased to 9.6 s for the 1.8 and 8.2 seconds for the 2.0. Thanks to better aerodynamics, though, top speed is increased from 196 km/h (121.8 mph) to 200 km/h (124.3 mph) for the smaller-engined model and from 210 km/h (130 mph) to 215 km/h (134 mph) for the 2.0. These figures are for the European- versions. The MX-5 facelift was unveiled at the 2008 Paris Motor Show and Science Museum in London, and later at the 2009 Chicago Auto Show. The Japanese model went on sale on December 9, 2008 at Mazda and Mazda Anfini dealers. Major changes concern the restyled front which now incorporates elements from Mazda’s newer models like the larger grille and new head and fog lights. Further restyled elements include the side skirts, rear bumper and the tail lights. The soft-top Touring and Grand Touring models feature a mesh grille bordered by a chrome frame. The hardtop Roadster Coupe now features a mesh grille bordered by a chrome frame and chrome elements inside the headlamps and outer door handles. The instrument panel gained darker features and redesigned graphics for the gauges. To create more leg space in the cabin, a protrusion from the door pockets was eliminated. The 2.0 L; I4 engine was rated 167 bhp at 7,000 rpm and 190 Nm (140 lb/ft) at 5,000 rpm for the 5-speed manual transmission, 158 bhp at 6,700 rpm with the fuel cut-off at 7,200 rpm and 190 Nm (140 lb/ft) at 5,000 rpm for the automatic transmission. Engine redline was raised by 500 rpm to 7,200 rpm in manual model and fuel cut at 7,500 rpm. The suspension and gearbox have been fine-tuned; with the latter offering smoother shifts and an automatic transmission will be introduced in Europe for the first time.

The fourth-generation Mazda MX-5 was unveiled in 2014 and has been in production since 2015. An updated model was introduced in 2019 and is visually identical to the pre-update model; it has been designated as series “ND2” due to an engine upgrade to 181 bhp and several other improvements around the car. The ND generation introduced a Retractable Fastback (RF) variant that features a rigid roof and buttresses that give the silhouette a more coupé-like appearance than the soft top convertible. The fourth generation MX-5 has received several accolades such as the 2015-2016 Car of the Year Japan Award, the 2016 World Car of the Year Award, Car and Driver’s 10Best list from 2016 to 2019, and the Red Dot Best of the Best Award in Product Design 2017. In addition, the car is the basis for the Fiat 124 Spider and Abarth 124 Spider.

Making another appearance here was this car which is the result of an owner imagining what the once talked about Alfa version of the ND generation MX-5 might look like before parent company FCA decided to switch course and produce the Abarth 124 Spider instead.

MERCEDES-BENZ

Oldest of the Mercedes models here was this 190SL. Produced between May 1955 and February 1963, having first been seen in prototype at the 1954 New York Auto Show, this was designed as a more affordable sports car than the exclusive and rather pricey 300SL, sharing its basic styling, engineering, detailing, and fully independent suspension. While both cars had double wishbones in front and swing axles at the rear, the 190 SL did not use the 300 SL’s purpose-built W198 tubular spaceframe. Instead, it was built on a shortened monocoque R121 platform modified from the W120 saloon. The 190 SL was powered by a new, slightly oversquare 105 PS Type M121 1.9 litre four cylinder engine. Based on the 300 SL’s straight six, it had an unchanged 85 mm bore and 4.3 mm reduced 83.6 mm stroke, was fitted with twin-choke dual Solex carburettors, and produced 120 gross hp. In detuned form, it was later used in the W120 180 and W121 190 models. Both the 190 SL and the 300 SL were replaced by the Mercedes-Benz 230SL in 1963.

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

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

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

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

Designed in 1984, and launched in 1989, the R129 was based on the shortened floorpan of the Mercedes-Benz W124 and featured many innovative details for the time, for instance electronically controlled damping (Adaptive Damping System ADS, optional) and a hidden, automatically extending roll-over bar. The R107’s somewhat dated rear suspension with semi-trailing arms gave way to a modern multi-link axle. The number of standard features was high, with electric action for the windows, mirrors, seats and hydraulic convertible top. This car has the distinction of being the first passenger vehicle to have seat belts integrated into the seats as opposed to anchoring to the floor, B-pillar, and transmission tunnel. Initially, there were three different engines available: 300 SL with a M103 3.0 L 12-valve SOHC I6 (188 bhp), a 300 SL-24 with a M104 3.0 L 24-valve DOHC I6 (228 bhp)  and the 500 SL with a M119 5.0 L 32-valve DOHC V8 (322 bhp) . These were joined in July 1992 by the 600 SL with a M120 6.0 L 48-valve DOHC V12 (389 bhp). There was a choice of 5-speed manual or 4–5 speed automatic for the six-cylinder cars; the V8 and V12 could only be ordered with a 4-speed automatic gearbox. In autumn 1993 Mercedes-Benz rearranged names and models. Also, the 300 SL and 300 SL-24 were respectively replaced by:  SL 280 with a M104 2.8 L 24-valve DOHC I6 (190 bhp) and the SL 320 with a M104 3.2 L 24-valve DOHC I6 (228 bhp). Only the 280 was available with a manual gearbox. SL 500 and 600 continued with their respective engines. Starting in 1993, the cars were re-designated. For example, 500 SL became SL 500. Starting in model year 1994, Mercedes-Benz offered special SL models from time to time, such as the Mille Miglia edition cars of model year 1994 or the SL edition of model year 2000. 1994 cars had minor updates for the car and then in 1995 there was a minor facelift for the car, with the front fender vents updated to only 2 rounded slots, rather than 3 squared slots, and bumpers in body colour. The V8 and V12s were  upgraded to 5 speed electronic transmission, the previous transmission was hydraulic 4-speed. A second facelift occurred in 1998 with many detailed changes applied, including  new external mirrors, 17″ wheels and new bumpers. Also new were the engines, a SL 280 with a M112 2.8 L 18-valve SOHC V6 (201 bhp);  SL 320 with a M112 3.2 L 18-valve SOHC V6 (221 bhp) and a  SL 500 with a M113 5.0 L 24-valve SOHC V8 (302 bhp). The V12 engine remained unchanged. The car was replaced by the R230 generation SL in 2001, after 213,089 had been built. There were a number of very low volume AMG versions of the car, including this SL70 AMG. This was powered by a 7.1 litres (7,055 cc) V12 engine developing 496 PS (489 bhp) at 5,500 rpm and a maximum torque of 720 Nm (531 lb/ft) at 3,900 rpm. It was a bored out version of M120 6.0 V12 and with a longer stroke. Produced between 1996 and 1997, just 150 units were made.

Completing the array of cars with the Three Pointed Star was this AMG GT

MG

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

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

The 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.

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

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

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

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

MINI

MORGAN

MORRIS

The Series I Isis was launched in March 1955 as a replacement for the Morris Six MS. It featured a 6-cylinder engine, the 2.6 litre 86 bhp C-Series unit from the Austin Westminster. Unlike the Westminster, the Isis had a single SU carburettor. The four-speed gearbox had a column change and was available with an optional Borg-Warner overdrive unit. The car was based on the four-cylinder Morris Oxford series II, sharing its almost-unibody shell and torsion bar front suspension. The wheelbase and front end were lengthened to accept the larger straight-six engine, and a “woody” 2-door estate version was also available. With the strong engine, the Isis could reach 90 mph (145 km/h). Unlike its sister car, the Austin Westminster, which enjoyed moderate success against the volume-selling Ford and Vauxhall sixes of the time, sales were poor, with only 8,500 sold. The Morris Isis Series II was based on the Morris Oxford Series III body but again with longer wheelbase and differing front wings and bonnet to accommodate the larger, six-cylinder engine. In line with changes to the corresponding Oxford line, BMC redesigned the Isis for 1956 with updated styling including a more elaborate mesh grille, chrome side strips and small fins. The engine power increased to 90 bhp. An automatic transmission option was also added. The manual version had a four-speed box operated by a short gearstick on the right-hand side of the front bench seat. The handbrake lever was just behind the gearstick. Sales remained weak, and the line ended in 1958. A de luxe saloon with overdrive tested by British magazine The Motor in 1956 had a top speed of 90 mph (145 km/h) and could accelerate from 0–60 mph in 17.6 seconds. A fuel consumption of 26.2 miles per imperial gallon (10.8 L/100 km; 21.8 mpg‑US) was recorded. The test car cost £1025 including taxes. The overdrive unit had added £63 to the price. There was also a Traveller version with similar rear design to the Morris Oxford Estate car. The Isis Traveller accommodated the spare wheel either within the rear well or, when it was required to use this region for a passenger (the small floor area was hinged with a padded underside so that the passenger faced “backwards”), then the spare would be attached to the nearside, again to the rear of the vehicle. In this way it would be possible to accommodate two adult passengers on the front bench seat next to the driver, three in the middle rear bench seat and one in the very back.

NISSAN/DATSUN

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

The KPGC10’s successor, the KPGC110, was introduced in 1973 after its introduction at the 1972 Tokyo Motor Show. Powered by a 1,989 cc S20 inline-6 engine, the second generation of the GT-R delivered power to the rear wheels through a 5-speed manual gearbox. This car also had both front and rear disc brakes. The suspension was a semi-trailing ring arm setup and minor aerodynamic parts were added. This model of the GT-R was also known as the “Kenmeri” Skyline, due to a popular advertisement featuring a young couple (Ken and Mary) enjoying the Hokkaido countryside. The advertisement later spawned a hit song by Buzz, and the tree featured in the advertisement later became a minor star itself. Unfortunately, the second generation GT-R was unsuccessful, for a gasoline crisis hit in the early 1970s, drying out any demand for high-performance sports cars. A total of 197 cars were built by the end of its short production run. For the next decade, this was the last GT-R until the production of the R32 in 1989.

Displayed with it were examples of the long-running and still current R35 generation GT-R.

Released on July 2002 in Japan at reorganized Nissan Japanese dealerships called Nissan Blue Stage, and August 20, 2002 in the US., the 350Z coupé was available in 5 trim packages: ‘350Z’ (Base), ‘Enthusiast’, ‘Performance’, ‘Touring’, and ‘Track’ editions. In Europe, only the ‘Track’ trim was available, although it was badged and marketed as ‘350Z’. The Base model did not include a VLSD or Traction Control and was only available with cloth seats. It did not include cruise control, nor power or heated seats. The Enthusiast model came with traction control, a VLSD, and cruise control. The Performance model came with bigger 18-inch wheels, front air dam, rear spoiler, optional Brembo brakes, and VDC instead of Traction Control. Touring was made more of the luxury model. It had power, leather, heated seats, VDC, a VLSD, xenon headlamps, optional Brembos, 18-inch wheels, and optional GPS. The Track model included Brembo brakes, front air dam, rear spoiler, traction control, cloth seats, 18-inch wheels, VLSD, and optional GPS. In 2004 Nissan introduced the 350Z Roadster with an electrically retractable soft-top roof. In the U.S. market the car was available in two trim packages (Enthusiast and Touring), while in Europe, the same versions as the coupé were offered. Nissan added the Grand Touring (GT) trim to the Roadster trim packages for 2005. In 2005 Nissan launched a 35th Anniversary edition, with a revised exterior and interior. Early 2005 model-year 35th anniversary edition models were equipped with the original VQ35DE with 287 hp and automatic transmission. In January 2005, Nissan introduced the 35th Anniversary 6-speed manual models and Track models (mid-year introduction), which included the updated VQ35DE 300 hp Rev-up engine and new updated CD009 manual transmission. As well as minor changes to suspension tuning and parts. For the 2006 model year, the 350Z received changes for its mid-cycle facelift. The VQ35DE 300 hp Rev-up engine that was introduced mid-year 2005 on the Track and 35th Anniversary Edition with 6-speed manual transmission models was offered for every trim level that had a manual transmission option. The VQ35DE with 287 hp continued to be offered with only the 5-speed automatic. Additions included bi-xenon projectors, a revised front fascia, new LED rear lights, changes to the interior trim and speed sensitive steering. Touring and Grand Touring models had radio-steering controls standard, MP3 CD compatibility, and Satellite Radio became an available option. For the 2007 model year, the 350Z was again moderately revised. The VQ35DE V6 was replaced with a new VQ35HR V6. It produced 306 hp at 6800 rpm with 268 ft·lb at 4800 rpm using the revised SAE certified power benchmark. The VQ35HR had a raised redline to 7500 rpm and more torque across the rpm range. The bonnet was redesigned with a bulge reminiscent of the original 240Z to accommodate the raised deck height of the new VQ35HR. In the US, trim levels were narrowed down to 350Z (base), Enthusiast, Touring, and Grand Touring, while in Europe the same trim levels remained. Bluetooth was added for the 2007 model year. The car was replaced by the 370Z for the 2009 model year. It has never found quite the same levels of enthusiasm that greeted – and have stayed with – the 350Z.

The Nissan NX is a front wheel drive 2-door sports car and was, loosely, an evolution of the Nissan Pulsar NX/Nissan EXA sold from 1987 to 1990 and the Nissan Sunny Coupe lines of the 1970s and 1980s, merging the Nissan B13 and N14 lineages. The NX was released in Japan in 1990. The NX1600 was based on the standard 1.6-litre Sentra (engine code GA16DE), and the NX2000 was based on the 2.0 L SE-R model (engine code SR20DE). Most models were fitted with T-Tops, whilst the remainder were hardtops. Constructed in Japan, it was sold from 1991 to 1993 in the US (mainly competing with the Mazda MX-3, Isuzu Piazza, Toyota MR2, and Honda Civic Del Sol). It was produced for a few more years for other countries. Its body was designed at NDI (Nissan Design International) in San Diego under the direction of NDI President Jerry Hirshberg, Blue Studio Chief Designer Allan Flowers, and staff designers Bruce Campbell and Doug Wilson. The NX2000 model included some mechanical improvements over its SE-R sibling in the form of larger brakes and more aggressive tires on wider 6″ wheels (195/55VR-14 with 14×6″ wheels vs. the 185/60HR-14 with 14×5.5″ wheels and tires in the SE-R). The NX2000 brakes are a common aftermarket upgrade for B13 Sentra SE-Rs. The NX2000 also had a centre armrest, a larger two-core radiator, and slightly lower ride height compared to the SE-R. However, the T-top roof in the NX2000 along with the mechanical upgrades made it slightly heavier than the SE-R. The NX2000, with its light weight, stiff chassis, and limited-slip differential, was considered one of the best-handling front-wheel-drive cars of the time. In 1992, Road & Track magazine included the NX2000 in a test of the world’s best-handling cars against such competition as the Acura NSX, Porsche 911, Nissan 300ZX, Mazda Miata, and Lotus Elan. The cars were sold in Europe from spring 1991 but were very pricey (initially) and found few buyers.

The Nissan Pao is a retro-styled three-door hatchback manufactured by Nissan for model years 1989–1991, and originally marketed solely in Japan at their Nissan Cherry Stores. First announced at the Tokyo Motor Show in October 1987, the Pao was available with or without a textile sun roof and was originally marketed without Nissan branding, by reservation only from January 15 through April 14, 1989. Orders were delivered on a first come, first served basis. With 51,657 applications for the vehicle, it sold out in 3 months. The UK’s GTR-Registry website provided updated production figures in 2022 with per-colour code quantities, and a total production quantity of 31,352. Because of its origins at Pike Factory, Nissan’s special project group, the Pao – along with the Nissan Figaro, Be-1 and S-Cargo – are known as Nissan’s “Pike cars”. The promotional campaign for the car included a surreal and futuristic animated video featuring members of the Pike Factory team. In 2011, noted design critic Phil Patton, writing for the New York Times, called the Pike cars “the height of postmodernism” and “unabashedly retro, promiscuously combining elements of the Citroën 2CV, Renault 4, Mini [and] Fiat 500”. Part of Nissan’s “Pike” series, it was designed as a retro fashionable city car in the mould of the Be-1. It included external door hinges like the original 1960s Austin Mini which had become fashionable in Japan, ‘flap-up’ windows like those of a Citroën 2CV, and a split rear tailgate of the first British hatchback car the Austin A40 Farina Countryman. The Be-1, Pao, Figaro, and S-Cargo were attempts to create cars with designs as desirable as those of Panasonic, Sony, and other personal electronics products. The Pao’s side strakes evoked the construction of earlier Woodie car body styles. The design of the Pao is usually credited to Naoki Sakai who also worked for Olympus, where he brought back “the brushed aluminium look”. Sakai also helped design Toyota’s later WiLL cars, which echo the Pike series.

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

OLDSMOBILE

The 4-4-2 was born out of competition between Pontiac and Oldsmobile divisions of GM. The high performance GTO version of the Pontiac LeMans intermediate had proved an unexpected success midway through the 1964 model year. Oldsmobile’s hasty response was to beef up their own popular Cutlass, a task given to a team led by performance enthusiast and Olds engineer John Beltz (later responsible for the distinctive and powerful Toronado), aided by Dale Smith and division chief engineer Bob Dorshimer. Contrasted with the 1964 Tempest LeMans GTO with its 389 cubic inch V-8 (introduced in September, 1963[6] as an option package), the Oldsmobile offering was a conservative package. Technically the “B09 Police Apprehender Pursuit” option, it used the four-barrel carbureted 330 CID (5.4 L) V8 with heavy-duty valve gear, and a hotter camshaft, raising rated (SAE gross) output to 310 hp at 5,200 rpm. Torque remained 355 lb⋅ft (481 N⋅m), although the torque peak rose from 2800 rpm to 3600 rpm. Also included was a stiffened frame, adjustable pinion angle by way of added holes in the frame mounts for the rear upper control arms, Muncie four-speed manual transmission, a heavy duty drive shaft connected to a 3.36:1 rear end, oversized brakes (155.6 vs 118sq.in lining area) and the heavy-duty police-package suspension, with heavy duty wheels, higher-rate coil springs front (410 lbs/in) and rear, heavy-duty shock absorbers, a larger front anti-roll bar, an additional rear anti-roll bar bolted to a fully boxed lower control arm, and dual snorkel air cleaner. Two-speed windshield wipers, A/C, an AM/FM radio, vacuum controlled trunk release, and a tilt steering wheel were optional. Unlike the 1965 4-4-2 model built in Lansing, the 1964 4-4-2 does not have an option code on the data plate. There is documentation available showing that the 1964 4-4-2 was built in both Lansing and Fremont. The package was dubbed 4-4-2 based on its combination of four-barrel carburetor, four-speed manual transmission, and dual exhausts. It was available on any F-85 or Cutlass model except the station wagon, although most were Cutlass hardtop coupés (Oldsmobile archives indicate that approximately 10 four-door sedans were built with the B09 option). Motor Trend tested an early 1964 4-4-2 with a 3:55 rear axle (standard ratio was 3.36:1) and found that the 3,440-lb (1,560 kg) car ran 0–60 mph (0–96 km/h) in 7.5 seconds, the standing quarter mile in 15.5 seconds at 90 mph (140 km/h), and reached a top speed of 116 mph (185.6 km/h). A total of 2,999 were sold. With the GTO receiving GM corporate sanction to receive their full-sized car’s 389 V-8, Oldsmobile followed suit and replaced the 4-4-2’s standard 330 CID with the new 400 CID (6.6 L). The definition of “4-4-2” was then restated as referring to 400 cubic inches, a four-barrel carburettor (a 515 cfm Rochester four-jet), and two exhausts. Output for the big engine rose to 345 hp and 440 lb⋅ft (597 N⋅m). The standard transmission became a three-speed manual with column shifter, with a floor shifter four-speed and Oldsmobile’s two-speed Jetaway automatic transmission as optional. A heavy duty three-speed with Hurst floor shifter was introduced as a mid-year option. Other touches added to the 1965 were chrome body side scoops adorned with 4-4-2 badging, chambered dual exhaust pipes, chrome single snout air cleaner, and 4-4-2 badging on the dash. Late in the year option N98 was added, which were chrome 14 in × 6 in (356 mm × 152 mm) wheels. It also offered standard bucket seats when optioned on the Cutlass and a 6,000 rpm tachometer, mounted in the optional console, more as decoration than for usefulness. Retractable front seat belts were optional. The turning diameter was 41 feet. Modern Rod tested a 1965 F85 4-4-2 with the four-speed manual, slicks, and headers and obtained a quarter mile acceleration of 13.78 seconds at 102.73 mph (165 km/h); Car Life’s automatic 1965 ran the quarter mile in 15.5 seconds at 89 mph (143 km/h), with a 0 to 60 mph time of 7.8 seconds. Car and Driver tested a 1965 4-4-2 and did 0–60 mph in 5.5 seconds. Offered in four body styles, 4-4-2 sales rose to 25,003, including 3,468 convertibles. The 1966 4-4-2 shared a modest facelift with other Cutlasses. It came with a 400 ci L78 V8 rated at 350 hp 440 lb•ft with a single four-barrel carburetor. Two new optional 400 ci engines offered even higher performance: the 360 hp L69, with three two-barrel Rochester 2GC carburetors on a progressive linkage and 440 lb⋅ft (597 N⋅m) of torque, which was priced at US$264.54, and the rare W30. Besides the convertible, the 4-4-2 option was available on both hardtop and pillared coupes, which shared the same roofline. Besides the new sweeping C pillar on coupes which featured a “flying buttress” recessed rear window, kthe new body had high, round rear fenders giving the car a more muscular appearance. The W30 engine added an outside-air induction system (admitting cool air to the carburettors via tubing from the front grill) and a hotter cam, under-rated as producing the same 360 hp as the L69. The battery was relocated to the trunk to make room for the air hoses, which prevented the package from being ordered on convertible models. Only 54 W30s were built by the factory, although an additional 97 were produced for dealer installation. The standard transmission was a three-speed manual with column shift and the two-speed Jetaway automatic with switch-pitch torque converter was optional. Hurst shifters became standard equipment with floor-mounted manual transmissions including the optional heavy-duty three-speed, M-20 wide-ratio four-speed or M-21 close-ratio four-speed. The standard 350-horsepower 400 engine could be ordered with any of the four transmissions, while only manual transmissions could be ordered with the L69 three two-barrel option. Inside, a revised instrument panel featured two round pods for the speedometer and other instruments, replacing the horizontal sweep speedometer of 1964–65 models, but the rest of the basic dashboard designed was unchanged. F-85 models had base interiors with bench seats and rubber floor mats while the more lavish Cutlass versions came with full carpeting and featured Strato bucket seats of a new design with higher and thinner seat backs, or a no-cost bench seat option. Head rests were an option. Car Life tested an L69 4-4-2 with four-speed transmission and obtained a 0–60 time of 6.3 seconds and a quarter mile of 14.8 seconds at 97 mph (156 km/h). Motor Trend’s similar test car ran 0–60 mph in 7.2 seconds, with a quarter mile time of 15.2 seconds at 96.6 mph (155.5 km/h). Production slumped to 21,997. The 4-4-2 still constituted only about 10 percent of Cutlass sales. For 1967 the 4-4-2’s styling and base engine remained the same, save for minor trim changes, a distinctive louvered hood, and an increase in intake valve size to 2.067 from 1.99. The three-speed Turbo Hydra-Matic automatic transmission with Switch Pitch became available, replacing the two-speed Switch Pitch Jetaway, as was the case with the mid-sized muscle cars from other GM divisions (Pontiac GTO, Chevrolet Chevelle SS396, and Buick GS400). The heavy-duty floor-mounted three-speed manual transmission was now standard with the Muncie M-20 and M-21 four-speeds optional, all with Hurst shifters. Front disc brakes were a new option. A GM policy decision banning multiple carburetors for all vehicles except Ed Cole’s beloved Corvette and the Corvair saw the demise of the L69 with its triple carburetors, a rare option for Olds and an icon for Pontiacs since 1957. The W30 remained available, although the four-barrel Quadrajet carburetor replaced the tri carb setup. New red plastic inner fender liners became part of the W30 package. 502 factory W30 engines were built to meet NHRA homologation rules, along with an unknown number of dealer-installed packages. Cars tested a W30 4-4-2 with close-ratio four-speed and 4.33 rear axle (a dealer-installed only option),[5] obtaining a quarter mile of 14.1 seconds at 103 mph (166 km/h) in completely stock form. 0–60 mph times were between 6.5 and 6.7 seconds. Unlike in previous years which the 4-4-2 option could be ordered on either baseline F-85 or upscale Cutlass models, the 1967 4-4-2 package was based on the top-line Cutlass Supreme series, including the sport coupe (with center post), Holiday hardtop coupe and convertible. Standard equipment on all models included Strato bucket seats or no-cost notchback bench seat, full carpeting, expanded Morocceen vinyl upholstery, heavy-duty suspension with rear sway bar, and wide-oval tyres. Like all cars sold in the U.S. for 1967, the 4-4-2 came standard with a group of occupant protection and accident avoidance features mandated by Federal law. This package included an energy-absorbing steering column and safety steering wheel, padded dash, recessed controls, four-way hazard flashers, and a dual-circuit brake hydraulic master cylinder. Production rose somewhat from the previous year, rising to 24,833.

OPEL

This is a first generation Commodore GS/E Coupe. The Commodore A was manufactured from 1967 to 1971, based on the Rekord C. After having offered a Rekord-6 powered by a 2.6 litre 6-cylinder engine since March 1964, in February 1967 Opel launched the Commodore as a faster up-market version of the Rekord. The Commodore was initially available with the familiar 2.2-litre six or a larger 2.5 litre engine developing 115 PS with a single carburettor. Body styles comprised a two-door or four-door saloon and a two-door hardtop/fastback coupé. In September 1967 the sporty Commodore GS offering 130 hp from a twin carburettor 2.5 litre six was introduced. For 1969, the carryover 2.2-litre six was dropped and the optional 2-speed Powerglide automatic was abandoned in favour of Opel’s new 3-speed automatic transmission. From September 1969, the base 2.5 litre engine was pumped up to 120 PS; at the same time, both remaining engines received hydraulic valves for smoother running, a new exhaust system and six camshaft bearings. The handbrake lever was moved from its position under the dash to a location between the front seats and the fuel tank was enlarged from 55 to 70 litres. An even more sporty model than the GS, the Commodore GS/E, debuted in March 1970. It had a 2.5 litre engine equipped with Bosch D-jetronic fuel injection system developing 150 PS, which gave the car a top speed of 197 km/h (123 mph). The Commodore GS/E also had a career in motorsports, with a car prepared by Steinmetz. In April 1970 a Commodore with a detuned and carburetted 2.8 litre six giving 145 PS followed, called the GS 2800. 156,330 Commodore As were built, including 2,574 GS and GS/E variants. Making this car even more unusual is the fact that it was built from a complete knock-down kit at the firm’s Bienne factory in Switzerland. All sorts of Opels were assembled at the plant from 1934 to ’73, and carry a ‘Suisse Bienne’ VIN plate.

 

PANTHER

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

The De Ville is a neo-classic luxury vehicle which was produced by Panther Westwinds, from 1974 to 1985. The De Ville was conceived by Robert Jankel to appeal to the taste of nouveau riche customers, including singer Elton John and actor Oliver Reed. With a wheelbase of 142 inches (3,600 mm), the tubular-framed De Ville used a straight-six engine or a V12 engine from Jaguar Cars. The flowing wing lines and big headlights of the De Ville were styled to imitate the Bugatti Royale. The cockpit of the De Ville was modern, without the exterior’s pretense of pre-war styling. The Panther De Ville was equipped with Jaguar suspension, power steering and automatic transmission, so it was an easy car to drive and quite quick, although poor aerodynamics tended to keep the top speed low. Interiors were lavish and often featured TV sets and drinks bars. The doors of the De Ville were from the BMC 1800 family car. About 60 De Villes were hand-built, including eleven two-door convertibles (for many years Britain’s most expensive listed production car), and one pink and gold six-door limousine.

The Panther Rio used Triumph Dolomite mechanicals. According to the company, it differed from the family saloon-class Dolomite, in being finished to “Rolls-Royce standards”. Only 38 were built between 1975 and 1977. A rarer Rio Especial used the high-performance Triumph Dolomite Sprint as its basis. Panther Westwinds had been set up by fashion designer Robert Jankel to produce expensive and bespoke cars for the customer that wanted something entirely different. Such vehicles held a lucrative market at the time. Jankel began working on a car that would appeal to the Rolls-Royce owner looking to trade down to something more economic, yet still considered higher class — losing nothing in terms of luxury or build quality. Following the 1973 energy crisis, demand for such cars began to diminish. The Triumph Dolomite was selected for improvement, due in part to the vehicle’s combination of advanced engines and upright driving position, which offered a blend of modern and traditional luxuries. The Panther Rio was the result, and was launched in September 1975. When released the car had leather and walnut internal fittings and a hand-beaten aluminium skin. The Rio was advertised as: “Combining characteristics combined in no other single car — the very highest level of luxury, appointments and smooth quietness with superb handling, a 115 mph (185 km/h) maximum speed, 0–60 mph acceleration in 8.7 seconds, the opulence of Connolly Leather, deep pile carpeting and burr walnut in the finest limousine traditions with the fuel economy and manoeuvrability of a compact family saloon; Panther coachbuilt quality and safety engineering with total functionalism; hand-crafted exclusivity without ostentation.” The compact family saloon was offered in two forms: the 1850 cc version, which was the “base” model; and the 2.0 litre 16-valve version (using the engine from the Dolomite Sprint), called the Rio Especial. Problems for the Rio included the fact that the new thicker, fatter seats resulted in a more cramped interior than the Dolomite. Panther was optimistic over the car’s chances and prematurely announced a pre-order of 100 cars from the H.R.Owen luxury line of dealerships. This would have meant a financial boom, clearing the way for the Rio to be offered for sale amongst some of the highest quality vehicles of the time. However, the 100 car deal never materialized and the Rio sold at extremely slow rates, largely in part to customer awareness of the Rio’s relatively humble Triumph Dolomite underpinnings. The price was high too. In February 1976, a Rio Especial cost £9445. In comparison, the Dolomite Sprint sold for £3283 and the Jaguar XJ 5.3 for £7496. The latter advertised luxury to equal the Rio’s.

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

PORSCHE

Last year the traditionally massive Porsche presence was scaled right back and instead of around 2000 cars bright together by Porsche Club GB and a number of other Porsche Clubs there were only a couple of hundred. This year it looked like there were none at all, and then we spotted them on the map. Situated in an area that was a few minutes walk beyond the International Pits, they were in an area which a lot of people probably never even found. There were not huge numbers of them, either. When we finally made it down there, it started to rain, so photos are a bit more limited than they perhaps otherwise would be, concentrating on the more interesting models.

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

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

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

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

In 1985, Porsche introduced the first Carrera Club Sport prototype with the identification number WP0ZZZ91ZF100848. Later on in that year, a 911 Club Sport Row (Rest Of World) with the identification number WP0ZZZ91ZFS101166 was special ordered for a Porsche driver that was particularly inspired by the CS prototype on the track. From 1987 to September 1989, Porsche decided to produced 340 units for their customers that wanted a track inspired road car, The 911 Carrera Club Sport (CS) (option M637), is a reduced weight version of the standard Carrera purposely built for club racing, it gained engine and suspension modifications. The CS had a blueprinted engine with hollow intake valves and a higher rev limit, deletion of: all power options, sunroof (except one unit), air conditioning (except two units), radio, rear seat, undercoating, sound insulation, rear wiper, door pocket lids, fog lamps, front hood locking mechanism, engine and luggage compartment lights, lockable wheel nuts and even the rear lid “Carrera” logo, all in order to save an estimated 70 kg (150 lb) in weight. With the exception of CS cars delivered to the UK, all are identifiable by the “CS Club Sport” decal on the left front fender and came in a variety of colours, some special ordered. Some U.S. CS cars did not have the decal installed by the dealer; however, all have a “SP” stamp on the crankcase and cylinder head. The UK cars were all finished “Grand Prix White” with a red “Carrera CS” decal on each side of the car and red wheels. Although the CS was well received by the club racers, because it cost more than the standard 911, but had fewer comfort features. According to Porsche Club of America and Porsche Club Great Britain CS Registers, 21 are documented as delivered to the U.S. in 1988 with 7 in 1989, one to Canada in 1988 and 53 to the United Kingdom from 1987 to 1989.

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

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 receive 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.

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

The 996 was replaced with the 997 in 2005. It retains the 996’s basic profile, with an even lower 0.28 drag coefficient, but draws on the 993 for detailing. In addition, the new headlights revert to the original bug-eye design from the teardrop scheme of the 996. Its interior is also similarly revised, with strong links to the earlier 911 interiors while at the same time looking fresh and modern. The 997 shares less than a third of its parts with the outgoing 996, but is still technically similar to it. Initially, two versions of the 997 were introduced— the rear-wheel-drive Carrera and Carrera S. While the base 997 Carrera had a power output of 321 hp from its 3.6 L Flat 6, a more powerful 3.8 L 350 hp Flat 6 powers the Carrera S. Besides a more powerful engine, the Carrera S also comes standard with 19 inch “Lobster Fork” style wheels, more powerful and larger brakes (with red calipers), lowered suspension with PASM (Porsche Active Suspension Management: dynamically adjustable dampers), Xenon headlamps, and a sports steering wheel. In late 2005, Porsche introduced the all-wheel-drive versions to the 997 lineup. Carrera 4 models (both Carrera 4 and Carrera 4S) were announced as 2006 models. Both Carrera 4 models are wider than their rear-wheel-drive counterparts by 1.76 inches (32 mm) to cover wider rear tyres. The 0–100 km/h (62 mph) acceleration time for the Carrera 4S with the 350 hp engine equipped with a manual transmission was reported at 4.8 seconds. The 0–100 km/h (62 mph) acceleration for the Carrera S with the 350 hp was noted to be as fast as 4.2 seconds in a Motor Trend comparison, and Road & Track has timed it at 3.8 seconds. The 997 lineup includes both 2- and 4-wheel-drive variants, named Carrera and Carrera 4 respectively. The Targas (4 and 4S), released in November 2006, are 4-wheel-drive versions that divide the difference between the coupés and the cabriolets with their dual, sliding glass tops. The 997 received a larger air intake in the front bumper, new headlights, new rear taillights, new clean-sheet design direct fuel injection engines, and the introduction of a dual-clutch gearbox called PDK for the 2009 model year. They were also equipped with Bluetooth support. The change to the 7th generation (991) took place in the middle of the 2012 model year. A 2012 Porsche 911 can either be a 997 or a 991, depending on the month of the production.

In February 2006, Porsche unveiled the second generation of GT3, the 997 commonly now known as the 997.1 GT3. In addition to a new 415 PS 3.6 litre flat-six engine, the vehicle featured “zero lift” aerodynamics, meaning the car creates only aerodynamic downforce and no grip-diminishing “lift” upwards and away from the road surface. The GT3 made use of a modified, track oriented version of Porsche’s active PASM suspension making it the first of Porsche’s RS or GT3 versions to feature an electronically adjustable suspension system. Also available was a navigation system and Porsche’s “sports chrono” gauge package. The car went to sale in summer of 2006. A total of 917 units were sold in the United States and 46 units in Canada. The 997 GT3 has a rated 0–60 mph acceleration time of 4.1 seconds and has a top speed of 311 km/h (193 mph). Road and Track was able to achieve a 0–60 mph acceleration time of 3.8 seconds. Porsche’s official test-driver Walter Röhrl completed the Nürburgring Nordschleife in 7 minutes 42 seconds with the 997 GT3 in 2006. In 2009, Porsche launched the 2nd Generation 997 GT3 (commonly known as the 997.2 GT3), with an enlarged 3.8 litre engine rated at 435 PS. It also featured a number of new options including dynamic engine mounts and a pneumatically lifting front axle to compensate for the low ground clearance. The rear spoiler was also modified along with other parts of the bodywork. Deliveries in Europe commenced in November the same year. A total of 654 units were sold in the United States and 58 units in Canada.

The 991 introduced in 2012 is an entirely new platform, only the third since the original 911. Porsche revealed basic information on the new Carrera and Carrera S models on 23 August 2011. The Carrera is powered by a 350 hp 3.4-litre engine. The Carrera S features a 3.8-litre engine rated at 400 hp. A Power Kit (option X51) is available for the Carrera S, increasing power output to 430 hp. The new 991’s overall length grows by 56 mm (2.2 in) and wheelbase grows by 99 mm (3.9 in) (now 96.5 in.) Overhangs are trimmed and the rear axle moves rearward at roughly 76 mm (3 in) towards the engine (made possible by new 3-shaft transmissions whose output flanges are moved closer to the engine). There is a wider front track (51 mm (2 in) wider for the Carrera S). The design team for the 991 was headed by Michael Mauer. At the front, the new 991 has wide-set headlights that are more three-dimensional. The front fender peaks are a bit more prominent, and wedgy directionals now appear to float above the intakes for the twin coolant radiators. The stretched rear 3/4 view has changed the most, with a slightly more voluminous form and thin taillights capped with the protruding lip of the bodywork. The biggest and main change in the interior is the center console, inspired by the Carrera GT and adopted by the Panamera. The 991 is the first 911 to use a predominantly aluminium construction. This means that even though the car is larger than the outgoing model, it is still up to 50 kilograms (110 lb) lighter. The reduced weight and increased power means that both the Carrera and Carrera S are appreciably faster than the outgoing models. The 0–60 mph acceleration time for the manual transmission cars are 4.6 seconds for the Carrera and 4.3 seconds for the Carrera S. When equipped with the PDK transmission, the two 991 models can accelerate from 0–97 km/h in 4.4 seconds and 4.1 seconds. With the optional sports chrono package, available for the cars with the PDK transmission, the 991 Carrera can accelerate from 0–97 km/h in as little as 4.2 seconds and the Carrera S can do the same in 3.9 seconds. Apart from the reworked PDK transmission, the new 991 is also equipped with an industry-first 7-speed manual transmission. On vehicles produced in late 2012 (2013 model year) Rev Matching is available on the 7-speed manual transmission when equipped with the Sport Chrono package. Rev-Matching is a new feature with the manual transmission that blips the throttle during downshifts (if in Sport Plus mode). Also, the 7th gear cannot be engaged unless the car is already in 5th or 6th gear. One of Porsche’s primary objectives with the new model was to improve fuel economy as well as increase performance. In order to meet these objectives, Porsche introduced a number of new technologies in the 911. One of the most controversial of these is the introduction of electromechanical power steering instead of the previous hydraulic steering. This steering helps reduce fuel consumption, but some enthusiasts feel that the precise steering feedback for which the 911 is famous is reduced with the new system.[citation needed] The cars also feature an engine stop/start system that turns the engine off at red lights, as well as a coasting system that allows the engine to idle while maintaining speed on downhill gradients on highways. This allows for up to a 16% reduction in fuel consumption and emissions over the outgoing models. The new cars also have a number of technologies aimed at improving handling. The cars include a torque vectoring system (standard on the Carrera S and optional on the Carrera) which brakes the inner wheel of the car when going into turns. This helps the car to turn in quicker and with more precision. The cars also feature hydraulic engine mounts (which help reduce the inertia of the engine when going into turns) as part of the optional sports chrono package. Active suspension management is standard on the Carrera S and optional on the Carrera. This helps improve ride quality on straights while stiffening the suspension during aggressive driving. The new 991 is also equipped with a new feature called Porsche Dynamic Chassis Control (PDCC). Porsche claims that this new feature alone has shaved 4 seconds off the standard car’s lap time around the Nürburgring. PDCC helps the car corner flat and is said to improve high-speed directional stability and outright lateral body control, but according to several reviews, the car is more prone to understeer when equipped with this new technology. In January 2013, Porsche introduced the all-wheel-drive variants of the Carrera models. The ‘4’ and ‘4S’ models are distinguishable by wider tyres, marginally wider rear body-work and a red-reflector strip that sits in between the tail-lights. In terms of technology, the 4 and 4S models are equipped with an all-new variable all-wheel-drive system that sends power to the front wheels only when needed, giving the driver a sense of being in a rear-wheel-drive 911. In May 2013, Porsche announced changes to the model year 2014 911 Turbo and Turbo S models, increasing their power to 513 hp on the ‘Turbo’, and 552 hp on the ‘Turbo S’, giving them a 0–97 km/h acceleration time of 3.2 and 2.9 seconds, respectively. A rear-wheel steering system has also been incorporated on the Turbo models that steers the rear wheels in the opposite direction at low speeds or the same direction at high speeds to improve handling. During low-speed manoeuvres, this has the virtual effect of shortening the wheelbase, while at high speeds, it is virtually extending the wheelbase for higher driving stability and agility. In January 2014, Porsche introduced the new model year 2015 Targa 4 and Targa 4S models. These new models come equipped with an all-new roof technology with the original Targa design, now with an all-electric cabriolet roof along with the B-pillar and the glass ‘dome’ at the rear. In September 2015, Porsche introduced the second generation of 991 Carrera models at the Frankfurt Motor Show. Both Carrera and Carrera S models break with previous tradition by featuring a 3.0-litre turbocharged 6-cylinder boxer engine, marking the first time that a forced induction engine has been fitted to the base models within the 911 range

Porsche unveiled the facelifted 991.2 GT3 at the 2017 Geneva Motor Show. Extensive changes were made to the engine allowing for a 9,000 rpm redline from the 4.0 litre flat-six engine derived from Porsche 911 GT3 R and Cup racing cars. The engine has a power output of 500 PS (493 bhp) and 460 Nm (339 lb/ft) of torque. Porsche’s focus was on reducing internal friction to improve throttle response. Compared to the 991.1, the rear spoiler is 0.8 inch taller and located farther back to be more effective resulting in a 20% increase in downforce. There is a new front spoiler and changes to the rear suspension along with larger ram air ducts. The car generates 154 kg (340 lb) of downforce at top speed. The 991.2 GT3 brought back the choice between a manual transmission or a PDK dual clutch transmission. Performance figures include a 0-60 mph acceleration time of 3.8 seconds (3.2 seconds for the PDK version) and a quarter mile time of 11.6 seconds. The GT3 can attain a top speed of 319 km/h (198 mph).

Also here were the latest 992-generation cars including the 911 GT3

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

In 1979, Porsche unveiled a concept version of the 924 at the Frankfurt Auto show wearing Carrera badges. One year later, in 1980, Porsche released the 924 Carrera GT, making clear their intention to enter the 924 in competition. By adding an intercooler, increasing compression to 8.5:1, lowering the suspension as well as various other little changes, Porsche was able to develop the 924 Turbo into the race car they had wanted, dubbing it the “924 Carrera GT”. 406 examples (including prototypes) of the Carrera GT were built to qualify it for Group 4 racing requirements. Of the 400 roadgoing examples, 75 were made in right hand drive for the UK market. In 1981 Porsche released the limited production 924 Carrera GTS. 59 GTS models were built, all in left hand drive, with 15 of the 59 being race prepared Clubsport versions. Visually, the Carrera GT differed from the standard 924 Turbo in that it had polyurethane plastic front and rear flared guards, a polyurethane plastic front spoiler, a top mounted air scoop for the intercooler, a much larger rubber rear spoiler and a flush mounted front windscreen. It also featured Recaro seats with fine red pinstripes and body paint was available in black, “Guards Red” and “Diamond Silver”. It featured Pirelli P6 tires as standard, and Pirelli P7 tires were available as an option along with a limited slip differential. It lost the 924 Turbo’s NACA duct in the hood but retained the air intakes in the badge panel. This more aggressive styling was later used for as motivation for the 944. The later Carrera GTS differed stylistically from the GT with fixed headlamps under Perspex covers (instead of the GT’s pop up units). GTS models were also 59 kg (130 lb) lighter than their GT counterparts at 1,121 kg (2,471 lb), and Clubsport versions were even lighter at 1,060 kg (2,337 lb). In order to comply with the homologation regulations, the 924 Carrera GT and later 924 Carrera GTS were offered as road cars, producing 210 and 245 hp respectively. Clubsport versions of the GTS were also available with 280 bhp, and factory included Matter roll cage and race seats. 924 Carrera GT variations were known by model numbers 937 (left hand drive) and 938 (right hand drive).

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

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

The commercially very significant Boxster was also represented here. Grant Larson’s design, inspired by the 356 Cabriolet, Speedster, and 550 Spyder, stimulated a commercial turnaround for Porsche. Through consultation with Toyota. Porsche began widely sharing parts among models and slashed costs. By October 1991 following a visit to the Tokyo Motor Show, Porsche in dire straits, began to devise solutions to succeed the poor selling 928 and incoming 968 (a heavy update of the 944). In February 1992, Porsche began development of a successor to the 928 (mildly updated for 1992) and recently released 968. By June 1992, out of 4 proposals based on dual collaboration between the 986 and 996 (993 successor) design teams, a proposal by Grant Larson and Pinky Lai was chosen by Harm Lagaay. In August 1992, a decision was made to develop the concept into a show vehicle, in time for the 1993 North American International Auto Show. After garnering widespread acclaim from the press and public upon presentation of the Boxster Concept in January 1993, the final production 986 production exterior design by Larson was frozen in March 1993. However, by the second half of 1993, difficulties arose with fitment of some components, resulting in lengthening of the hood and requiring another design freeze by fourth quarter of that year. Prototypes in 968 bodies were built to test the mid-engine power train of the 986 by the end of 1993, with proper prototypes surfacing in 1994. Pilot production began in the second half of 1995, ahead of series production in mid-1996. The Boxster was released ahead of the 996. The 986 Boxster had the same bonnet, front wings, headlights, interior and engine architecture as the 996. All 986 and 987 Boxsters use the M96, a water-cooled, horizontally opposed (“flat”), six-cylinder engine. It was Porsche’s first water-cooled non-front engine. In the Boxster, it is placed in a mid-engine layout, while in the 911, the classic rear-engine layout was used. The mid-engine layout provides a low center of gravity, a near-perfect weight distribution, and neutral handling. The engines had a number of failures, resulting in cracked or slipped cylinder liners, which were resolved by a minor redesign and better control of the casting process in late 1999. A failure for these early engines was a spate of porous engine blocks, as the manufacturer had difficulty in the casting process. In addition to causing problems with coolant and oil systems mingling fluids, it also resulted in Porsche’s decision to repair faulty engines by boring out the cast sleeves on the cylinders where defects were noted in production and inserting new sleeves rather than scrapping the engine block. Normally, the cylinder walls are cast at the same time as the rest of the engine, this being the reason for adopting the casting technology. The model received a minor facelift in 2002. The plastic rear window was replaced by a smaller glass window. The interior received a glove compartment, new electro-mechanical hood and trunk release mechanism (with an electronic emergency release in the fuse box panel) and an updated steering wheel. Porsche installed a reworked exhaust pipe and air intake. In addition, the front headlight’s amber indicators were replaced with clear indicators. The rear light cluster was also changed with translucent grey turn signals replacing the amber ones. The side marker lights on the front wings were changed as well from amber to clear, except on American market cars where they remained amber. The bumpers were also changed slightly for a more defined, chiselled appearance, and new wheel designs were made available. The second generation of the Boxster debuted at the 2004 Paris Motor Show

The second generation of the Boxster debuted at the 2004 Paris Motor Show with the (997) 911 and became available for sale in 2005. Revised styling included modified headlights, larger side intake vents and enlarged wheel arches to allow wheels up to 19 inches in diameter. Interior revisions included a more prominent circular theme for the instrument cluster and cooling vents. The base engine is a 2.7-litre 239 PS/236 bhp flat-six boxer engine, with the Boxster S getting a 3.2-litre 280 PS/ 276 bhp engine. For 2007, the base Boxster received a revised engine featuring VarioCam Plus and the Boxster S engine was upgraded from 3.2-litre to 3.4-litre. These upgrades made the Boxster series and the Cayman series equivalent in terms of power. The 987 is the last generation of the Boxster and Cayman series with hydraulic steering. The Cayman S fastback coupé (987c) was first unveiled and went on sale in late 2005. The base Cayman followed in July 2006. Both the Cayman and second generation Boxster roadster share their mid-engine platform and many components, including the front fenders and trunk lid, doors, headlights, taillights, and forward portion of the interior. Styling incorporates cues from the 356/1, the 550 Coupé and the 904 Coupé. The Cayman’s hatchback enables access to luggage areas on top of and in the back of the engine cover. The suspension design is fundamentally the same as that of the Boxster with revised settings due to the stiffer chassis with the car’s fixed roof. The Cayman S was powered by a 3.4-litre flat-six mated to a 6-speed manual transaxle, a 2.7-litre engine with a 5-speed transmission was standard for the base model. An electronically controlled 5-speed automatic (Tiptronic) was also available on the S and base models. The Boxster and Boxster S models received a facelift in 2008. Changes included an increase in engine displacement to 2.9-litre for the Boxster, incorporation of Direct Fuel Injection (DFI) for the Boxster S. Both models now came standard with a new 6-speed manual gearbox and were available with a 7-speed Porsche Doppelkupplungsgetriebe (PDK) dual clutch gearbox. Cosmetic changes included new head and tail lights, larger front air intakes with incorporated day time running lights, and an altered lower rear end flanked by twin diffusers. A facelift of the Porsche Cayman followed in February 2009. As with the Boxster, the base Cayman’s engine displacement was increased to 2.9-litre while the Cayman S gained direct injection. Both the Cayman and Cayman S maintained a 10 PS/ 9 bhp power advantage over their roadster sibling, the Boxster. A limited slip differential was now a factory option. The third generation, 981 series, cars arrived in March 2012.

After two years of development, the first model of the fastback coupé to be released was the Cayman S (type 987120). Photographs and technical details were released in May 2005, but the public unveiling took place at the September Frankfurt Motor Show. The S suffix (for Sport or Special) indicated that this was a higher performance version of a then unreleased base model. That model, the Cayman (987110), went on sale in July 2006. The Cayman fastback coupé (project 987c) and the second generation Boxster roadster (project 987) shared the same mid-engine platform and many components, including the front fenders and trunk lid, doors, headlights, taillights, and forward portion of the interior. The design of the Cayman’s body incorporates styling cues from classic Porsches; 356/1, the 550 Coupé and the 904 Coupé. The 987.1 Cayman used the M97.20 and M97.21 engines. Unlike the Boxster, the Cayman has a hatchback for access to luggage areas on top of and in the back of the engine cover. The entire rear section rear-wards of the side doors of the Cayman is made from stainless steel. The suspension design is fundamentally the same as that of the Boxster with revised settings due to the stiffer chassis with the car’s fixed roof. The 3.4-litre flat-6 boxer engine (M97.21) in the first generation Cayman S was derived from the 3.2-litre (M96.26) that was used in the Boxster S, with cylinder heads from the 997 S’s 3.8-litre engine (M97.01), which have the VarioCam Plus inlet valve timing and lift system. A less powerful but more fuel efficient version, the 2.7-litre M97.20, powered the base model. The use of these engines exclusively in Caymans ended in the 2007 model year when Porsche upgraded the Boxster (987310) and Boxster S (987320). A 5-speed manual transaxle is standard on the Cayman (G87.01), while a 6-speed manual (Getrag 466) was the standard transmission for the S model (G87.21) and an option on the base model (A87.20). An electronically controlled 5-speed automatic transaxle (Tiptronic) was also available on the S (A87.21) and the non-S version (A87.02) (The 2009 models replaced this option with a seven-speed “PDK”, Porsche’s dual clutch transmission. Other options include active shock absorbers (ThyssenKrupp Bilstein GmbH’s DampTronic, rebadged as PASM by Porsche), ceramic disc brakes (PCCB), xenon headlights (Hella’s Bi-Xenon) and an electronically controlled sport mode (Sport Chrono Package). The first generation Cayman ceased production in November 2011

The Cayman R was introduced in 2011 as the pinnacle of the 987 generation. Based on the 2009 987.2 Cayman S the Cayman R was significantly lighter and came with additional power and handling upgrades. A 55kg weight saving was achieved with the use of 19 inch lightweight wheels shared with the Boxster Spyder, lighter aluminium doors from 997 911 GT3, lighter carbon fibre bucket seats from the 997 911 GT2, and with the removal of the radio, storage compartments, air-conditioning, door handles and rear wiper, the Cayman R weighs in at 54.8 kg (121 lb) less than a Cayman S. Porsche Ceramic Composite Brake (PCCB) system was an additional option available for the Cayman R. Styling: The Cayman R also received various cosmetic changes, such as decals on the doors, instrument cover delete, gloss black painted mirrors, black ‘R’ model designation emblem on the trunk, dashboard and door sills, as well as black painted wheels. There were minor changes to aerodynamics with the Cayman R, mostly coming from the use of the rarely selected Porsche OEM aerokit, introduced as an option in 2007. A carbon rear spoiler was added as well as more aggressive front fascia spoilers. With all new passive sports suspension, the Cayman R was 10 mm (0.4 in) lower than a Cayman S equipped with PASM, or a full 20 mm (0.8 in) lower than a Cayman S equipped with standard passive suspension. The powertrain was a 3,436 cc direct injection flat-six engine that was rated at 330 PS at 7,400 rpm and 370 Nm (273 lb/ft) of torque at 4,750 rpm. 6 speed Manual or 7 speed PDK automatic gearbox. The standard Cayman R can accelerate from 0–100 km/h (62 mph) in 5 seconds, and with the optional 7-speed PDK dual clutch transmission, it can accelerate from 0–100 km/h (62 mph) in 4.9 seconds with the optional Sport Chrono Package offering launch control it can accelerate from 0–100 km/h (62 mph) in 4.7 seconds. The Cayman R with the manual transmission can reach a top speed of 282 km/h (175 mph) and 280 km/h (174 mph) with the PDK. The Cayman R made its debut at the 2010 Los Angeles Auto Show on 17 November 2010. Only 1,621 Cayman R were made worldwide with 220 for the UK market.

The third-generation Boxster (internally known as the 981) was announced on 13 March 2012 at the Geneva Motor Show with sales starting in early summer 2012. The 981 Boxster reflected the new design language from the 911 (991) and 918, and featured new and revised engine and transmission specifications. Together with a new body, the type 981 Boxster featured a new, 40 per cent more torsionally rigid chassis, the front track was 40 mm (1.6 in) wider, the rear 18 mm (0.7 in) wider and the wheelbase extended by 60 mm (2.4 in), but with a small weight reduction of up to 35 kg (77 lb) compared to the previous type 987 Boxster. The standard Boxster was fitted with a new 2.7-litre flat-6 engine, and the Boxster S was fitted with the existing 3.4-litre engine but with revised performance. Both engines were equipped with a 6-speed manual gearbox and an optional 7-speed reworked PDK. Both manual and automatic models were available with several technical options, including Porsche Torque Vectoring (PTV) and a Sport Chrono Package that included active transmission mounts, and made the PDK-equipped model even faster. Porsche claimed that the new generation Boxster provided fuel savings of 15% over the outgoing model. The range was expanded in March 2014 with the addition of the GTS derivative, with slightly altered front and rear bumpers and an additional 15 PS/ 15 bhp from the 3.4-litre engine. In 2015 the GT4 derivative was introduced, seeing the engine from a 991.1 Carrera S rotated 180 degrees. The GT4 also saw a lowered ride height, altered bumpers, a rear wing and additional GT package upgrades including brakes and certain suspension components from a 991.1 GT3. These special cars were manufactured from 2015 – 2016 with a total of 2500 being made, making this model one of the more desirable collector’s cars in Porsche’s lineup. The GT4 was widely considered one of the best cars of 2015/2016 where it won many awards for its impeccable handling and performance. The third generation Cayman was unveiled at the 2012 Geneva Motor Show. The production version of the 981 Cayman was released as a 2014 model in the spring of 2013. The new car was available in both the standard trim with a 2.7-litre engine, and in the S trim with a 3.4-litre engine. Both versions were available with either a 6-speed manual or a dual-clutch 7-speed PDK transmission. The 981 Cayman featured upgrades including a new body, a longer wheelbase, a wider front track, electrically powered steering, and a redesigned interior that matched the firm’s contemporaneous 911 models. The new model gained acclaim in the motoring press as one of the best handling sports cars at any price, due to its mid-engine layout and driving dynamics. The Cayman S benefited from the same engine and running gear as Porsche’s 3.4-litre version of the 911. A heavily revamped version of both models, known as the 982 generation was launched in 2016 to replace these cars.

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

In 2021, Porsche unveiled the 718 Cayman GT4 RS, the first Cayman to receive the RS treatment which is usually reserved for the 911 models. With a 4.0 naturally aspirated flat-six derived from the 911 GT3, it puts out 500 PS (490 bhp) and 450 Nm (330 lb/ft) with an rpm limit of 9,000rpm, which allows it to sprint from 0–100 km/h (0–62 mph) in just 3.4 seconds. It generates 25% more downforce than the GT4 variant, through a swan-neck attachment fixed rear wing. The GT4 RS lapped the Nürburgring Nordschleife 23 seconds faster than the GT4. There is a hefty price premium over the GT4 model.

QUANTUM

Quantum’s first car was the Mark 1 hatchback (also referred to as the Mk 1 Coupé) which was based on the Ford Fiesta Mark 1. It reused all of the donor’s mechanical and trim components in an elongated, more rounded shape. Due to its reduced weight over the donor vehicle, performance was significantly improved. The Coupé is unusual for low-volume car manufacturer in that it has a glass-reinforced plastic (grp) monocoque rather than a separate metal chassis. This approach relied upon the use of computer analysis to ensure that structural rigidity would not be compromised, offering the strength of a steel chassis but without the weight penalty. The first Mark 1 Quantum, bearing chassis number 001, was a development mule and was subject to so much adjustment that the Wooldridge brothers eventually decided the car would be too dangerous to keep on the road. This car was therefore disposed of in landfill. Chassis 002 was later believed to have been damaged beyond repair in a head-on collision, so chassis 003 is now the oldest surviving example of a Quantum model and the first to be sold, after a short period being used for magazine tests and promotional materials. To ensure this historic car survives, the Quantum Owners Club has acquired this car and are in the process of restoring it. The club also owns the last Mark 1 Coupé produced, chassis number 017. In 2015 a club member claimed to own chassis 002, which was believed to have been exported to the Isle of Man, and hence removed from the DVLA records. At the National Kit Car Motor Show in 2017 chassis number was validated by the Committee Members in the Quantum Owners Club who can now confirm this is the oldest surviving Quantum. In 1991 a restyled version was introduced, now based on the Ford Fiesta Mark 2 with the rear-end shape changed from a hatchback to a saloon. This and other styling revisions led to far greater sales success: a total of 215 saloon models were produced before that model also ceased production.

By 1993 the firm was also offering a 2+2 convertible, also based on the Ford Fiesta Mark 2, which has been Quantum’s most successful model with 431 examples built to date. Since the previous model had evolved, at the time the Wooldridges considered this to be their second model: numbering therefore began “Q2-001”, which is now owned by a long term club member. One 2+2 with a two-litre engine rather than the more common Fiesta XR2 one, was featured in magazine articles and also loaned to the BBC’s Top Gear for testing. Jeremy Clarkson and his wife drove the car and compared it favourably with mass-market alternatives such as the Mazda MX-5 during the test. The only criticism was based on the smell of new fibreglass. The 2+2 is a practical open top sports tourer, with a large boot and spacious interior, while remaining light and sporty. The prototype, and a handful of early customer cars, had round headlights but the alternative nose with the drop down flaps was offered as production started and proved far more popular. Chassis number 013, built by its owner in Pinner, Middlesex in 1993, one of two outside Europe, is now in New Zealand. A Ford 1800cc diesel was substituted for the original XR2 petrol engine, and a turbocharger has been added. The vehicle is in daily use, both as a family car and – with or without a trailer – for some of the parcel carrying trade of Allbays Transport, an Auckland North Shore passenger and courier goods transport business. Chassis number 212, the other car outside Europe, is in Australia and currently being restored by its owner. A handful of 2+2 LHD cars are in The Netherlands and one is in Germany. One owner has converted his car to full electric drive using a HPEVS AC50 motor with Curtis 1238 controller with Li battery pack front and rear. It also has power steering, Mk4 fiesta dash, electric heating and many other upgrades. The 2+2 is no longer made but plans had been mooted by the previous owners of QSC to further revise the design to offer more spacious rear seats, although to date this has not happened. About 455 2+2 cars were built.

There was a change of ownership and a move to Devon in 2001, and around the same time the Sunrunner and XTreme models were introduced. The Sunrunner was a beach-buggy style of car based on the Mk 3 Fiesta and brought in to add to the Quantum portfolio rather than designed in-house. It was rear-engined and rear wheel drive. It is still in production as Quantum Sports Cars showed a slightly revised car at the Stoneleigh National Kit Car Motor Show in May 2018.

RELIANT

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

RENAULT

The R8 was first launched in the autumn of 1962, as a replacement for the Dauphine, still rear engined, but featuring a boxier and roomier body and an all new 956cc engine that developed 43 bhp. A more powerful model, the 8 Major, was released in 1964, featuring an 1108 cc engine developing 49 hp. A still more powerful version, the R8 Gordini, was also released that year, with a tuned engine of the same capacity but developing 89 hp. The extra power was obtained by a cross-flow head and twin dual-choke 40mm side-draft Solex carburettors. A four-speed close ratio manual transmission, dual rear shock absorbers and uprated springs were fitted. The Gordini was originally available only in blue, with two stick-on white stripes. It was also distinguishable from the 8 Major by the bigger 200mm headlamp units. In 1965, the Renault 10 Major, a more luxurious version of the 8 with different front and rear styling, was released, replacing the 8 Major. In 1967, the R8 Gordini received a facelift including two additional headlights (in effect Cibie Oscar driving lights), and its engine was upgraded to a 1255cc unit rated at 99 hp. The original Gordini cross-flow head design was retained, and twin dual-choke 40mm Weber side-draft carburettors. Both the R8 and the R10 were heavily revised for 1969, with some of the R10’s features being incorporated in the R8, resulting in a new R8 Major which replaced the basic model. The changes also saw the addition of the R8S, a sportier model with a 1108cc engine rated at 59 hp. The R8 Gordini continued largely unchanged until production ceased in 1972, by which time over 11,000 units had been built. The vast majority of surviving R8s are now presented as Gordinis, though many of them are recreations that started out as a more humble model, much as has happened with Mark 1 Escorts and Lotus Cortinas.

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

RENAULT-ALPINE

Successor to the A110 was the A310. Launched in 1971, the four-cylinder car was larger, heavier, and no more powerful than its predecessor, which meant it was generally considered underpowered. The car was first shown at the 1971 Geneva Motor Show. The prototype A310 had louvres across the rear windscreen; these were not carried over to the production model. Early models had a NACA duct mounted near the window atop the left front fender, later four-cylinder cars received two, mounted closer to the front of the car. In 1976, to help flagging sales, the lower-cost A310 SX was presented. This model has a 95 PS version of the Renault 16/17’s 1647 cc inline-four and simplified equipment. The basis of the A310 was a hefty tubular steel backbone chassis, clothed in a fibreglass shell. As for the previous A110 the entire body was moulded in a single piece. Like the ill-fated De Lorean DMC-12, which used the same PRV powertrain, the engine was mounted longitudinally in the rear, driving forward to the wheels through a manual five-speed gearbox. The driving position was low and sporty, although the front wheelwells encroached on the occupants’ feet, pointing them towards the centre of the car. The A310 was labour-intensive, having been developed for small-scale artisanal production – a car took 130 hours to build from start to finish. The front axle also came in for some criticism, although in 1974 the balljoint mountings were replaced by rubber/steel bushings (silent-blocs) which somewhat improved the longevity. While many bits of the A310 came from the Renault parts shelf as expected, others are more surprising – the steering rack is from the Peugeot 504, while the turn signals are Simca 1301 units. In 1976 the A310 was restyled by Robert Opron and fitted with the more powerful and newly developed 90-degree 2664 cc V6 PRV engine, as used in some Renaults, Volvos and Peugeots. The later V6 received a black plastic rear spoiler as well, useful for keeping the tail planted but somewhat marring to purity of the original’s lines. With 150 PS on tap, the A310 PRV V6 was Renault’s performance flagship capable of 220 km/h (137 mph) and acceptable acceleration. The tail-heavy weight distribution gave handling characteristics similar to the contemporary Porsche 911. Beginning with model year 1981 (in late 1980), the rear suspension was shared with the mid-engined Renault 5 Turbo. Rather than the previous three-lug wheels, the A310 also received the alloys used for the 5 Turbo, albeit without the painted elements In the later models (1983-1984) of the A310 a “Pack GT” which was inspired from the Group 4 A310 racing cars would be developed, it gained wheel arches and larger spoilers front and rear. A few Alpine A310 V6 Pack GT Kit Boulogne were built (27 examples), here the PRV V6 was bored out to 2.9 litres and was then further modified by Alpine, fitted with triple Weber 42DCNF carburetors that pushed power to 193 PS. 2340 examples of the 4 cylinder car and 9276 of the V6 were made. It is a rare car these days.

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

ROLLS ROYCE

The introduction of a smaller Rolls-Royce, the 20hp, in 1922 enabled the company to cater for the increasingly important owner-driver market that appreciated the quality of Rolls-Royce engineering but did not need a car as large as a 40/50hp Ghost or Phantom. A development of the 20hp, the 20/25hp debuted in 1929, early chassis, apart from an enlarged and revised engine, being identical to those of the final Twentys. Thus the 20/25 inherited the right-hand gearchange lever and servo-assisted brakes introduced on its predecessor for 1926, as well as Phantom-style vertical radiator shutters. Produced concurrently with the Phantom II, the 20/25 benefited from many of the larger model’s improvements, such as synchromesh gears and centralised chassis lubrication, becoming the best-selling Rolls-Royce of the inter-war period.

This is a Silver Cloud S3. First introduced in 1955, it was, with its later iterations the Cloud II and III, to prove the core of Rolls-Royce production until the arrival of the monocoque Silver Shadow in 1966. Construction of all Cloud models was body-on-frame, which allowed a number of creative coach-builders to work their magic, but over the course of its eleven years of production the vast majority were built with the standard Pressed Steel shell. The Silver Cloud II was notable for introducing a new engine, the essence of which is still used by Bentley today. The Silver Cloud III was the final version and deliveries to customers commenced in mid 1963. External dimensions were slightly altered with a one and a half inch reduction in grille height and by necessity, a slightly more sloping bonnet, but the most distinctive difference was the grouping of the headlights in a four headlamp unit which was sufficiently attractive to be carried over to the new Shadow. The car’s weight was reduced by over 100kg, and performance was improved by fitting 2″ SU carburettors and increasing the compression ratio to 9:1. One of the respected coach-builders who created something different on the Cloud III chassis was H.J.Mulliner (later Mulliner Park Ward), who offered a supremely elegant two door Drophead Coupe. These cars are now very sought after and are few and far between.

When new, the Silver Shadow was considered a big car, but looking at this one, it does not seem quite so massive any more. The Silver Shadow was produced from 1965 to 1976, and the Silver Shadow II from 1977 to 1980. Initially, the model was planned to be called “Silver Mist”, a natural progression from its predecessor Silver Cloud. The name was changed to “Silver Shadow” after realising that “Mist” is the German word for manure, rubbish, or dirt. The design was a major departure from its predecessor, the Silver Cloud; although several styling cues from the Silver Cloud were modified and preserved, as the automobile had sold well. The John Polwhele Blatchley design was the firm’s first single bow model. The original Shadow was 3 1⁄2 inches narrower and 7 inches shorter than the car it replaced, but nevertheless managed to offer increased passenger and luggage space thanks to more efficient packaging made possible by unitary construction. Aside from a more modern appearance and construction, the Silver Shadow introduced many new features such as disc rather than drum brakes, and independent rear suspension, rather than the outdated live axle design of previous cars. The Shadow featured a 172 hp 6.2 litre V8 from 1965 to 1969, and a 189 hp 6.75 ltire V8 from 1970 to 1980. Both powerplants were coupled to a General Motors-sourced Turbo Hydramatic 400 automatic gearbox, except on pre-1970 right-hand-drive models, which used the same 4-speed automatic gearbox as the Silver Cloud (also sourced from General Motors, the Hydramatic). The car’s most innovative feature was a high-pressure hydropneumatic suspension system licensed from Citroën, with dual-circuit braking and hydraulic self-levelling suspension. At first, both the front and rear of the car were controlled by the levelling system; the front levelling was deleted in 1969 as it had been determined that the rear levelling did almost all the work. Rolls-Royce achieved a high degree of ride quality with this arrangement. In 1977, the model was renamed the Silver Shadow II in recognition of several major changes, most notably rack and pinion steering; modifications to the front suspension improved handling markedly. Externally, the bumpers were changed from chrome to alloy and rubber starting with the late 1976 Silver Shadows. These new energy absorbing bumpers had been used in the United States since 1974, as a response to tightening safety standards there. Nonetheless, the bumpers on cars sold outside of North America were still solidly mounted and protruded 2 in less. Also now made standard across the board was the deletion of the small grilles mounted beneath the headlamps. Outside of North America, where tall kerbs and the like demanded more ground clearance, a front skirt was also fitted to the Silver Shadow II and its sister cars. In 1979 75 Silver Shadow II cars were specially fitted to commemorate the 75th anniversary of the company with the original red “RR” badges front and rear, pewter/silver paint, grey leather with red piping, scarlet red carpets, and a silver commemorative placard on the inside of the glove box door. 33 75th anniversary cars were designated for and shipped to the North American market. 8425 examples of the Shadow II were made, which, when added to the total of over 16,000 of the first generation cars made this the biggest selling Rolls Royce of all time.

Development of the Silver Seraph began in the late 1980s, with design work commencing in October 1990. By April 1991, the conceptual design was frozen and approved by the management in June 1991. After several refinements were made, the definitive design was reached in 1994. On 28 July 1995 design patents were filed for both the Rolls-Royce Silver Seraph and Bentley Arnage utilizing production design prototypes as representations. Development concluded after nearly a decade in late 1997, with pilot production models being produced into early 1998 bearing R396 DTU registration plates. The Silver Seraph was launched at the 1998 Geneva Motor Show. Aside from the radiator grille, badges and wheels, the Seraph was externally identical to the contemporary Bentley Arnage, sharing both its platform and body shell. It was powered by a BMW M73 5.4 L aluminium alloy V12 engine coupled to a 5-speed automatic transmission, making it the first twelve-cylinder Rolls-Royce since the 1939 Phantom III. The car conforms to the Euro III emission standards. The body was 65 percent stiffer than that of its predecessor. Standard electronics included digital engine management, adaptive ride control and anti-lock brakes. The exterior was available in one and two-tone finishes. Inside, the Rolls-Royce Silver Seraph and the Bentley Arnage were similar yet distinct. The Seraph’s gear selector was column-mounted, and gauges followed a traditional Rolls-Royce layout. In both cars, the seats and dashboard were upholstered in Connolly Leather, with dashboard trim and folding picnic trays for rear passengers faced with glossy burl walnut veneer. The Seraph was known for its relatively limited acceleration and comfortable handling, in comparison to the Arnage, which had a twin turbocharged V8 of its own design and firmer suspension. However, the Seraph still had a top speed of 225 km/h or 140 mph. The RAC gave the car a rating of 7.6/10, stating “The Silver Seraph marks a new start for Rolls-Royce in their quest to once more be recognised as manufacturers of the world’s best cars. And it’s quite a credible effort. All Seraphs were hand-built at the Rolls-Royce factory in Crewe, England. The car had a base price of £155,175 in the UK and $220,695 in the US. It was second in cost and exclusivity only to the Rolls-Royce Corniche, though it was the cheapest Rolls-Royce per se after the discontinuation of Silver Spur. A total of 1,570 Silver Seraphs were produced before manufacture ceased in 2002.

From the modern production was this example of the Ghost.

ROVER

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

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

SAAB

The Saab 900 is a front-engine, front-wheel-drive mid-size car with a longitudinally mounted, 45-degree slanted, inline four-cylinder engine, double wishbone front suspension and beam-axle rear suspension. It was originally introduced on 12 May 1978, for the 1979 model year. Sales commenced in the fall of 1978. Like its predecessor the 99, the 900 contained a number of unusual design features that distinguish it from most other cars. First, the B-engine, that was installed “backwards”, with power delivered from the crank at the front of the car. Second, the transmission, technically a transaxle, bolted directly to the bottom of the engine to form the oil pan (albeit with separate oil lubrication). Thus, power from the crank would be delivered out of the engine at the front, then transferred down and back to the transmission below, via a set of chain-driven primary gears. In similar fashion, Mini’s also had their gearbox mounted directly below the engine; however, the Mini gearbox and engine shared the same oil, whereas the Saab 900 (and 99) gearboxes contained a separate sump for engine oil. Refined over several decades of two-digit Saab models, the 900’s double wishbone suspension design provided excellent handling and road feel. The rear suspension comprised a typical beam axle design, stabilized with a Panhard rod. However, the attachment points between the axle and chassis made up an unusual configuration that, in essence, consists of two Watt’s linkages at either end of the axle: A lower control arm attaches the axle to the bottom of the vehicle, while an upper link attaches at the top but faces towards the rear, unlike a typical four-link design with both lower and upper links facing forward. Early models did not have sway bars; they began appearing on certain models in 1985, and, in U.S. and possibly other markets, became standard on all trim levels by the late 1980s. The sway bars decreased body roll, but at the expense of some ride comfort and when driven aggressively, increased inside wheel spin. The front and rear bars’ diameters were unchanged throughout the model’s run.The 900 has a deeply curved windshield, providing the best driver visibility. The dashboard was curved to enable easy reach of all controls, and featured gauges lit up from the front.[citation needed] Saab engineers placed all controls and gauges in the dashboard according to their frequency of use and/or importance so that the driver need only divert their gaze from the road for the shortest possible time and by the smallest angle. This is why, for example, the oft-used radio is placed so high in the dashboard. In keeping with the paradigm of its predecessor, the 99 model, the 900 employed a door design unique in automotive manufacturing, with an undercutting sweep to meet the undercarriage, forming a tight, solid unit when the door was closed. This feature also eliminated the stoop in the cabin at the footing of the door, as seen in automobiles of other manufacturers, thereby preventing water and debris from collecting and possibly entering the cabin or initiating corrosion, as well as enabling passengers to enter and exit the cabin without need to step over several inches of ledge. The 900 underwent minor cosmetic design changes for 1987, including restyled front end and bumpers that went from a vertical to a more sloped design. To save money, Saab kept the basic undercarriage more or less unchanged throughout the 900’s production run. The Saab 900 could be ordered with different options. One highly sought-after option was called the Aero or, as it was known in the U.S. “Special Performance Group” (SPG). The Aero/SPG incorporated (depending on the market and model year) a body skirt; a sport-suspension (1987+) that included shorter, stiffer springs, stiffer shocks, and sway bars; leather seats; premium stereo; and air conditioning. Each of these features could also be ordered independently from Saab’s Accessories Catalog for fitment to standard models. The 1979 900 was available in three versions of the B-engine: The GL had the single-carb 100 PS engine, the GLs had twin carburettors for 108 PS, the EMS and GLE had Bosch jetronic fuel injection for 118 PS and the 900 Turbo produced 145 PS. The only bodywork originally available was the three or five-door hatchback style, which was seen as more modern at the time. The EMS was only available with three doors while the automatic-equipped GLE was only offered with five. Saab’s model years were generally introduced in August/September of the preceding year.The Turbo had a different grille from the naturally aspirated models, which received a design with a hexagonal central element. For the 1980 model year, all versions received the sleeker turbo-style grille. The 1980 900 also received larger taillights rather than the earlier 99 units, as well as lower, adjustable head restraints.1980 was also the first year for a five-speed gearbox, originally only available in the EMS and the Turbo. The four-door 900 sedan was introduced in Geneva 1980, as a result of dealer pressure. This introduction corresponded with the phase-out of the old Saab B engine in favor of the lighter Saab H engine. With the introduction of the H-engine, Saab simplified the model designation on the international markets outside Scandinavia: GL for the model with the single carburettor, GLs for the models with the twin carburettor engine, GLi as designation for the models with fuel injection without turbo, and correspondingly “Turbo” for the top models with the corresponding engine. The GLE was now offered only as a better equipped four-door Sedan. Model designations in the USA became just 900 for the base model and 900S for the models with 8V i. The EMS designation was dropped. In the early 1980s, most 900s were produced in Trollhättan. However, coinciding with the introduction of the 9000, more of the 900 production took place elsewhere. The Valmet plant in Finland, referenced below under the 900c, also produced regular 900s, a total of 238,898 examples. The plant in Arlöv (now closed), near Malmö, also produced some 900s. For 1981 all models except for the GL three-door received a considerable boost in equipment, as well as broader side trims, larger luggage compartments and fuel tanks. The spare tire was moved to underneath the floor, rather than standing upright in the luggage compartment. A big change for 1982 was the introduction of Saab’s Automatic Performance Control (APC), a.k.a. boost controller for the Turbo models. The APC employed a knock sensor, allowing the engine to use different grades of gasoline without engine damage. Another new feature that year was the introduction of central locking doors (on the GLE and Turbo). The long-wheelbase 900 CD was also introduced. Asbestos-free brakes were introduced in 1983, an industry first. The front pads were semi-metallic while the rears were made from silica. The GLE model gained a new central console, while the decor strips on the bumpers of all models were made wider (necessitating wider trim pieces on the flanks as well). A new luxury package was made available on Turbo cars. 1985 Saab 900 CD, a limited production version with a longer wheelbase and stretched rear doors. Model year 1984 saw the introduction of the 16-valve DOHC B202 engine in Europe. With a turbocharger and intercooler, it could produce 175 hp in the Turbo 16 model (less for catalyst-equipped engines). The Turbo 16 Aero [designated SPG, Special Performance Group in North American Markets] had a body kit allowing the car to reach 210 km/h (130 mph). A different grille and three-spoke steering wheel appeared across all models. The connection between the side strips and the bumpers was changed, Turbo hatchbacks received a black trim piece between the taillights, and the GLi began replacing the twin-carburetted GLs. At the 1983 Frankfurt Motor Show a two-door sedan was shown; it went on sale in January 1984, initially only as a GLi. The two-door sedan was only ever built at the Valmet plant in Finland. The dual-carburettor model (and “GL” nomenclature) was gone for 1985. Now, the base 900 had the single-carburettor engine, while the 900i added fuel injection. Two turbocharged models were offered: The 900 Turbo had the 8-valve engine, while the Turbo 16 (also Aero) had the 16-valve intercooled unit. Wheel trims (naturally aspirated cars) and alloys (turbos) were redesigned, and the Turbos also received chromed grilles. The 8-valve turbo received an intercooler for 1986, bringing up power to 155 PS while the 16-valve cars had hydraulic engine mounts. The eight-valve Turbo was also available as a two-door. Side marker lights at the rear of the front fenders were also added, while the 900i gained new interior fabrics. The new Saab-Scania badge was introduced, placed in the steering wheel, on the bonnet, and on the bootlid. 1986 also marked the introduction of the 16-valve 900i 16 and 900 convertible, both only for North America initially. A new grille, headlamps, front turn signal lights and so-called “integrated” bumpers freshened the 900’s look for 1987, though the sheetmetal was largely unchanged. Several common parts for the 900 and 9000 were introduced for 1988 model year, including brakes and wheel hubs. This also meant that Saab finally abandoned the use of parking brakes which acted on the front wheels. Power steering was added on the 900i. The base 900, available with two or four doors, kept the pre-facelift appearance for 1987. Also new was the carburetted 900c. The Aero model received slightly bigger fender extensions so as to accommodate larger wheels, while the window trim was blacked out on all models. For 1988 catalytic converters became available with all fuel injected engines in Europe, all with cruise control as standard equipment to further help lower emissions. A water- and oil-cooled turbocharger (replacing the older oil-cooled unit) was also introduced to improve the unit’s durability. In each of the seasons 1987 and 1988, there was a special ‘one-make’ race series, in the UK, called the Saab Turbo Mobil Challenge, sponsored by Saab Great Britain and Mobil. It was run by the BARC. The eight-valve engines were phased out in 1989 and 1990, with the turbo versions having been removed in North American markets by the end of 1984; North American 900S models received the non-turbo 16-valve engine for 1986. A non-turbo 16-valve engine replaced the 8-valve FI unit in the 900i (900S in North America) as well, while the carbureted engines were dropped. In Europe the eight-valve Turbo dropped out with the 1989 model year, with the limited production 900 T8 Special built to celebrate this. 805 were built for Sweden, featuring Aero trim and equipment. The 900i 16 arrived in Europe, with 128 PS. Anti-lock brakes were introduced as well, and were standard on Turbo models. High-mounted rear brake lights appeared during 1988, and power of the catalyzed Turbo 16 Aero jumped from 160 to 175 PS. Larger pinion bearings were fitted to manual gearboxes for 1989 to improve their strength and reliability. For 1990 eight-valve engine were taken out of production while a low pressure turbo engine with 145 PS was available in European markets. ABS brakes and driver’s side airbags were standardized for all North American market cars beginning with the 1990 model year. In the spring of 1990 the naturally aspirated 900i 16 Cabriolet was added. A 2119 cc  (B212) engine was introduced for 1991. This engine was available in the United States until the end of the original 900, but in most of Europe, this engine was replaced a year later with the earlier B202 because of tax regulations in many European countries for engines with a displacement of more than 2000 cc. Front seats from the 9000 were standard from 1991 on and electronically adjustable ones were available as an option. Airbags became available as an option in Europe as well, while there was also an Aero version of the Cabriolet. The Saab 900 no longer offered the mesh wheels. There was also a change in the door locks, which carried over to the 900NG. For 1992 there were mostly equipment adjustments, with ABS brakes finding their way into most of the lineup everywhere. 1993 brought no changes, and “classic” 900 production ended on 26 March 1993, with a new GM2900 platform-based 900 entering production shortly afterwards. The final classic convertibles were still sold as 1994 models, with the Special Edition commanding top dollar in the resale market even today. In all, 908,817 Saab 900s were built, including 48,888 convertibles.

SINGER

The Chamois was the luxury version of the Hillman Imp, added to the range in the autumn of 1964, just over a year after the launch of the Hillman versions. It was updated during the 1960s inline with the Imp versions and was deleted in 1970 when the Singer name was phased out.

STANDARD

The Vanguard Phase III, released to the market for the mid-October 1955 British International Motor Show, was a radical change with the elimination of the separate chassis. There was an overlap in availability of the old model with the Phase II estate continuing into 1956. UK fuel was no longer restricted to the 72 octane “Pool petrol” of the 1940s and early 1950s, and with the modest increases in available octane levels, the Vanguard’s compression ratio was increased to 7.0:1. The 2,088 cc engine with its single Solex downdraught carburettor now produced 68 bhp. The front suspension was independent, using coil springs, and was bolted to a substantial sub-frame which also carried the recirculating ball steering gear. Semi-elliptic leaf springs were used on the rear axle. Lockheed hydraulic brakes with 9 in (229 mm) drums were fitted front and rear. The three-speed gearbox had a column change and the optional overdrive was operated by a switch on the steering column. A four-speed floor change became an option. The new body was lower and had an increased glass area, making it look much more modern, and the old two-piece flat windscreen gave way to a one-piece curved design. The wheelbase increased by 8 in (203 mm), giving much better passenger accommodation. A heater was now a standard fitting. Bench seats were fitted in front and rear with folding centre arm rests. They were covered in Vynide, with leather available as an option. The car was lighter than the superseded model, and the gearing was changed to deliver better economy with performance virtually unchanged. A car with overdrive was tested by the British magazine The Motor in 1956. It had a top speed of 83.7 mph, could accelerate from 0–60 mph in 21.7 seconds and had a fuel consumption of 25.9 miles per imperial gallon (10.9 L/100 km; 21.6 mpg‑US). The test car cost £998 including taxes. For 1957, the Australian-produced Phase III was given a facelift with a new mesh grille. In addition the sedan now sported fins on the rear guards. A performance model, the Vanguard Sportsman, intended to be badged as the Triumph Renown until shortly before launch, was announced in August 1956 with a tuned 90 bhp engine having similar features to the Triumph TR3 sports car. These included an increased compression ratio to 8.0:1, twin SU carburettors, and improved pistons. However, the Sportsman’s inlet manifold and carburettors sat at a different angle from those of the TR3, and its engine had the same 85 mm bore as the Vanguard’s, not the 83 mm bore of the TR3. The final-drive ratio was lowered to 4.55:1 to give better acceleration, and larger 10 in (254 mm) drums fitted to the brakes. The standard version had a bench front seat but separate seats were an option. Although sharing the same basic body shell with the other Vanguard variations, the Sportsman had design variations, including a squarer front grille, which gave the car a slightly higher, squarer appearance than the regular models. Just 901 examples of the Sportsman model were made up to 1958. Sportsmans then became available to special order, and around another fifty (mostly estate cars) were built between 1958 and 1960. A small number were built before the Vignale makeover in 1958. Popular Classics magazine’s test of a Sportsman in 1994 stated that a total of 962 were built. A Sportsman with overdrive was tested by the British magazine The Motor in 1956 and it recorded a top speed of 90.7 mph (146.0 km/h), acceleration from 0–60 mph in 19.2 seconds and a fuel consumption of 25.6 mpg imperial (11.0 L/100 km; 21.3 mpg‑US). The test car cost £1231 including taxes. A face-lift of the Phase III was designed by Italian stylist Giovanni Michelotti and coach-builders Vignale in 1958, and was introduced at the October 1958 Earls Court Motor Show. The windscreen and rear window were deeper, and there was a revised grill and trim. A floor change four-speed manual gearbox was now fitted, and the provision of a three-speed gear box with column change offered as an option. An overdrive was also offered an option, as was an automatic. One automatic car is known to have survived – there may be others. The car had front and rear bench seats, which were covered, as standard, in Vynide. Leather was an option on the home market and cloth for exported models. A heater and (unusual for the time) electric windscreen washers were factory fitted, although a radio remained an option. The car was replaced by the Triumph 2000 in late 1963.

SUNBEAM

In an attempt to interest a wider public when sales figures fell well short of the intended 100,000 cars per annum, several badge-engineered derivatives, such as the luxury Singer Chamois (launched October 1964), and the Sunbeam Sport (launched October 1966), with a more powerful twin-carburettor engine, were offered with varying degrees of success. For marketing reasons the Singer variants were sold as Sunbeams in many export markets, even before May 1970 when the Singer marque was discontinued altogether by Chrysler UK. In some markets, such as France, the “Sunbeam” name was used on all British Rootes products, including the Imp and the Husky. The Sunbeam models lived longer than the Singer versions, being produced well into the 1970s.

SUZUKI

The Cappuccino was a tiny Japanese sports car that found a small niche when offered to UK buyers. Designed to meet the Kei car specifications for lower tax and insurance in Japan, this tiny front mid-engined machine weighed just 725 kg and took its power from a turbocharged, three-cylinder, 12 valve 657 cc DOHC engine which generated 63 bhp. Its dimensions also conformed to Kei car regulations on length and width, being 3,295 mm (129.7 in) long and 1,395 mm (54.9 in) wide. Three removable roof panels meant that the car can be used as a closed coupé; T-top; targa; or, on retraction of the rear window and roll bar, a full convertible. Roof panels stowed in the boot, taking almost all the luggage space), and the rear window/rollcage assembly retracts into the body behind the seats. Unlike many convertibles of the time, the rear window is glass and wraparound, with demisting elements. Production began in 1991 and ceased in 1997. Suzuki UK decided that they wanted to sell the car, and it took 18 months of negotiation and technical co-operation between the Suzuki Motor Corporation and Suzuki GB to get the Cappuccino type approved and homologated for the UK market, with 23 adaptations to the Japanese Cappuccino. Finally, in October 1992 the Cappuccino had its first public viewing outside Japan, at the British International Motor Show. At the show, the Cappuccino won two prestigious IBCAM Design awards: “best sportscar under £20,000” and “best car of the show”. In October 1993 the Cappuccino was officially launched in the UK with a price of £11,995. Due to the car’s initial success in Japan, and the tight import quota of Japanese products to the UK, the original allocation of 1,500 cars was cut to 1,182. Such limited quantities dictated a streamlined colour choice: red and silver in the ratio 80:20. Between 1993–95 a total of 1,110 cars were registered in the UK, with the balance sold to other Suzuki distributors across Europe: Germany, France, the Netherlands and Sweden.

SWALLOW

The Doretti story begins with a transatlantic triumvirate of enterprising minds: Ernest Sanders of Walsall-based engineering firm Helliwells, a subsidiary of the Tube Investments conglomerate, Arthur Andersen of the Rome Cable company in California and Sir John Black, the Managing Director of Standard Triumph. Andersen and Sanders were both involved in manufacturing steel tubes, having met when Andersen devised an improved manufacturing method using the same American-built machines as Sanders used in England. They harboured a desire to market sports cars in the US. Sanders was an old friend of Sir John Black, who wanted to try to stem the sales growth being seen by Austin-Healey, with its 100 model. The three got together to hatch out a plan for a new sports car which they would aim at the West Coast of America. Black would supply the running gear, the TI Group owned the Swallow Coachbuilding Company Ltd – acquired in 1935 from what had evolved separately to become Jaguar Cars – would build it and Andersen would sell it. The task of designing the car fell to another TI staffer, Frank Rainbow. Swallow were making motorcycles at the time, and this new sports car would use up spare production capacity as well as creating publicity for other capabilities of the TI Group. The stage was set, even though none other than Black had any background in making cars. The styling of the new car was a long away from the Triumph TR2 whose mechanicals it would use, and as Andersen and Sanders had a background in steel tubing, it was perhaps not a surprise that the chassis was constructed from Reynolds 50-ton chrome-molybdenum tube produced by Helliwells in Walsall. The stylish body was constructed from 16 gauge aluminium over a 22 gauge steel inner shell, fabricated by Panelcraft of Birmingham. Despite the alloy body, the car was heavier than the TR2, but not by much, and it would proved very strong. Work had begun on the project in January 1953 and the completed first car was put on the Queen Mary and shipped to New York in the autumn of that year, from where it was transferred to Los Angeles. The car was well received, though the American dealers did suggest that wind-up windows rather than perspex sidescreens would be a good idea and they wanted a bigger boot. Sanders, no doubt pressured by his bosses, chose to ignore these suggestions and to put the car into production. The name is derived from Dorothy Deen, daughter of Arthur Andersen. A vivacious blonde, she had a company called Cal Sales Inc which sold the TR2, and would go on to sell the Doretti as well Before moving into that business, she had been involved in another company which sold a range of Italian accessories under the Doretti brand, a sort of Italianised go-faster version of her name. The British firm bought the brand name from her for just $1. The production Doretti proved to be every bit as sporting as the Triumph whose mechanicals it used, with its 90 bhp 2 litre TR2 engine making it capable of 100 mph, with 0-60 mph acceleration time of 12.3 seconds and a fuel consumption of around 28 mpg. Most cars were supplied with Laycock-de Normanville electric epicyclic overdrive, one of the refinements which meant the car was more civilised than the TR2, with another advantage being that the car had an easy to erect hood, which actually did seal the car off from the weather. The Doretti was bigger than the TR2 in every dimension, but that did not translate into any more space inside it. Sir John Black was a staunch supporter of the car and was keen to adopt it as a triumph product, but that was not to be. The first production car was delivered to him in November 1953. Keen to explore the cars performance he went out for a high speed run in it which had a disastrous end when a lorry turned across his path. he was seriously injured and forced to retire from Standard-Triumph as a result. Production of the Doretti continued though, for a while, but at £1107, when a TR2 was only £886, it was costly. That was not the only problem, though. What really sealed its fate was that rival manufacturers, most notably Jaguar, started to get concerned that the car was a threat to them, and they threatened to take away their business from TI as a components supplier. TI got the message and quietly withdrew the car in February 1955, after just 2776 had been made and just as an improved Mark II version was being prepared., with a stiffer chassis and better weight distribution.

TOYOTA

The second-generation Celica was released for the 1978 model year (production began in August 1977) and was again available in both notchback coupé and Liftback forms. It was designed in the United States by Toyota’s Calty Research Design studio in California. The coupe was no longer a true hardtop; both coupé and Liftback had frameless door glass but featured a thick “B” pillar. David Stollery was responsible for its design. The early or pre-facelift second-generation Celica was released with round headlights and chrome bumpers for lower grades. The higher grades such as the Japanese GT and all U.S. models have black rubber bumpers. The facelift was launched in August 1979 came with square headlights and revised tail lights. They came with chrome bumpers with rubber protectors on each corners, or for certain models with all polyurethane black bumpers such on the Japanese GT and all U.S. spec cars. The facelift model front end was not only featured square headlights, but also came with new grille, and revised hood and fenders which were not interchangeable with the parts of pre-facelift model. This generation offered as standard equipment a new windshield wiper and headlight switch installation, with the controls operated by levers attached to the steering column. From 1979 until 1981 the Griffith company in the U.S. offered a Targa-style convertible conversion to the coupé. They were called the Sunchaser and had a removable Targa top and a folding rear roof, much like the ’67 Porsche 911 soft-window Targa. These were Toyota approved and sold through Toyota dealers. Over 2,000 were produced. In Germany, the same Sunchaser version but also a full convertible and a traditional targa with a fixed rear window (called the TX22) were offered. Conversions were Toyota-approved and carried out from mid-1980 by a company called Tropic.

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

TRIUMPH

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.

Standard’s Triumph Roadster was out-dated and under-powered on arrival. Company boss Sir John Black’s attempt to acquire the Morgan Motor Company failed, but he still wanted an affordable sports car, so a prototype two-seater was built on a shortened Standard Eight chassis, powered by the Standard Vanguard’s 2-litre straight-4. The resulting Triumph 20TS prototype was revealed at the 1952 London Motor Show. Black asked BRM development engineer and test driver Ken Richardson to assess the 20TS. After he declared it a “death trap”, a project was undertaken to improve the design; one year later the TR2 was unveiled. It had better looks; a simple ladder chassis; a longer body; and a bigger boot. It was loved by American buyers, and became the best earner for Triumph. “TR” stands for “Triumph Roadster”. Period advertising name the car T.R.2. The TR2 has a 1,991 cc Standard wet liner inline-four engine from the Vanguard, fitted with twin H4 type SU Carburettors and tuned to increase its output to 90 bhp. The body is mounted on a separate chassis with coil-sprung independent suspension at the front and a leaf-sprung live axle at the rear. Either wire or disc wheels could be supplied. The transmission is a four-speed manual unit, with optional top gear overdrive. Lockheed drum brakes are fitted all round.  A total of 8,636 TR2s were produced. In 1955 the more powerful TR3, with a re-designed grille and a GT package that included a factory hard-top, replaced it. As of 2011 there were approximately 377 licensed and 52 SORN TR2s registered with the DVLA in the UK; in the United States 1,800 were known to survive.

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.

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

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

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

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

The Triumph Toledo was introduced in August 1970 as a cheaper version of the Triumph 1300, which was at the same time replaced by the Triumph 1500. The Toledo, like the front-wheel drive 1500, came with a new split grille at the front, but instead of the 1500s twin round headlamps, it had single rectangular units set in a grey plastic grille. The rear end was like that of the 1300 except for the tail lights, which were of a simpler, flat-faced design. The biggest change for the Toledo was a move to rear-wheel drive and live rear axle (still with coil springs), in the interest of simplicity and low production costs. The interior was also cheaper, with wood confined to a dashboard consisting of a simple plank with holes drilled for the quite basic instrumentation but the interior was a cut above most other small cars at a time when black plastic was commonplace. Initially, the Toledo was only available as a two-door saloon with the 1296 cc engine Standard SC engine of 58 bhp. Drum brakes were fitted all round and there was no overdrive or automatic option available. In March 1971 a 4-door “special export” version was launched at the Geneva Motor Show, featuring a 1500 cc engine in single and twin carburettor “TC” form producing 61 and 64 bhp, respectively. From late August 1971 the four-door model was also available on the home market. The four-door Toledo featured the same side body pressings as the Triumph 1300. The interior furnishings were in most respects indistinguishable between the two versions, but buyers of the four-door car received two extra ashtrays in each of the extra doors. Radial ply tyres were specified in place of the cross-plies offered on the two-door car, compensating for the additional 50 kg (approx) of weight involved in installing the extra doors. The two-door model differed very little from the more popular four-door model in overall appearance, the two-door featured non-wraparound front and rear bumpers (although this would change in 1973 to full wraparound bumpers), whilst the four-door featured wraparound bumpers from the start. Two front bumper under-riders were fitted to the two-door model; however these were deleted on later cars from around late 1972 / early 1973. The specification gradually improved over the years. In October 1972 front disc brakes were fitted as standard on both models and a heated rear window became standard equipment by late 1973 / early 1974. In March 1975 the two-door version was dropped: the four-door model continued in production for another year, but in improved specification form. The existing Triumph Herald three-rail type gearbox was replaced with a Triumph Spitfire 1500 type single-rail gearbox and the car was fitted with a new clutch. The new look Toledo was also fitted with side body trims, new look black type front grille (replacing the silver type front grille) and a stainless trim was added to the side roof guttering. The specification again improved; standard equipment now included a rear-view dipping mirror, fasten seat belt warning light, reclining front seats (previously an option), twin reversing lights (also previously an option), cigar lighter, hazard warning lights and a driver’s exterior door mirror. A laminated windscreen, front head rests and brushed nylon seat facings were optional extras. The Toledo was finally replaced by the Dolomite 1300 and 1500 in March 1976. Total production was 119,182 cars, making it one of Triumph’s best-selling small saloon cars.

Displayed with the Triumphs was this, the Vincent Hurricane. This car was the brainchild of brothers Robin and Martin Vincent with later input from another brother Jerry, after visiting a kit and specialist car show at Donington Park when they decided to produce and build a GRP body and fitting for initially a Triumph GT6 or Spitfire donor car. All the available engines from the donor cars will fit, from the 1147 cc  4 cylinder Herald unit, through 1296cc and 1493cc Spitfire units to the 2.0 litre 6 cylinder of the GT6. The first car was produced in December 1982 and road registered in January 1983. It is estimated that about 50 cars survive. The cars were originally built at Stonor Farm, Henley on Thames and are still available from Caburn Engineering.

TURNER

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

TVR

The TVR Grantura is the first production model in a long line of TVR cars. It debuted in 1958 and went through a series of developments leading to the Mark I to Mark IV and 1800S models. The last ones were made in September 1967. These coupés were hand-built at the TVR factory in Blackpool, England with varying mechanical specifications and could be had in kit form. All cars featured a cocktail of Austin-Healey brakes, VW Beetle or Triumph suspension parts and BMC rear axles. The Grantura bodyshell was made from glass-reinforced plastic and made use of a variety of proprietary components. The bonnet was front hinged. There was no opening at the rear but the boot could be accessed from inside the car – the spare wheel had to be removed through the front doors. Buyers could choose from a range of powerplants which, dependant on the model in question, included a choice of side or overhead valve engines from Ford, a Coventry Climax unit, the engine from the MGA and, ultimately, the 1798cc BMC B-series engine. The first of the Granturas used a fibreglass body moulded to a tubular steel backbone chassis and VW Beetle-based front and rear suspension. At the rear, the VW suspension was paired with an inboard MGA differential housing which was fastened to the chassis. The differential was connected by a pair of short driveshafts to each of the independently sprung hubs and road wheels. The differential was closely flanked by the inboard Austin Healy 100M drum brakes on each side, connected to each driveshaft with a Hardy-Spicer universal joint, on each inboard end, of the driveshaft. Each driveshaft extended outward to an independently sprung hub, mated with each unequal length control arm suspension linkage and road wheel, by another Hardy-Spicer universal joint at the outboard end of each driveshaft. This was an advanced feature at a time when most other cars used a solid axle rear suspension. The car was designed around a 1098 cc Coventry Climax type FWA engine but many different makes were fitted from 1172 cc Ford side valve to 1600 cc BMC from the MGA. The drum brakes originated on the Austin-Healey 100 and the windscreen on the Ford Consul . Approximately 100 of the Mark I Grantura were built from 1958 to 1960. The Mark II had MGA engines as standard but again customers could choose from a variety of power units. The Mark IIa used the 1622 cc MGA Mark II or Ford 1340 cc engine. The more expensive Coventry Climax FWA 1216 cc that was also found in the Lotus Elite was also available. Front disc brakes were standard for the Mk IIa. Rack and pinion steering was standardised. Approximately 400 of the Mark II/IIa Grantura were built. The next series of cars had a completely new, longer and stiffer chassis with innovative coil sprung independent suspension. This chassis was designed by John Thurner and would form the basis of the one used by TVR up to the launch of the 2500M cars in 1972. The Mark III also received a new front end design, with the grille mounted higher and featuring some rudimentary chrome trim. The Mark III and the later Mark III 1800 cars used BMC B-series engines, either 1622 or 1798 cc respectively, although Ford or Coventry Climax units were also available for the earlier Mark III model.[5] The larger capacity 1798 cc MG ‘B’ series engine became standard equipment around September 1963 although this more powerful engine appears to have been available as a customer-specified option prior to that date. At some point during 1963 the rear of the car was reprofiled to include a number plate mount. In 1965 the latest version of the car became available as the 1800S with a cut off, square back (called a ‘Manx tail’ after the similarly tailless breed of cat) and round rear light clusters from the Ford Cortina. The 1798cc B-series engine remained but the chassis used for the 1800S and all subsequent Granturas was a modified version that, through an alteration to the line of the top chassis rails, allowed more space for the engine to fit in. This was an alteration made to the Grantura chassis to allow it also to be used as the basis for the new Griffith, a car that sported a V8 engine which was larger both in capacity and physical dimension. After a pause in production during late 1965, under Martin Lilley’s new ownership the 1800S reappeared in early 1966 rebadged as the Mark III 1800S. This was quickly followed by the new Mk IV model. The Mk IV featured a longer wheelbase, more luxurious trim and a larger fuel tank and was the first TVR to benefit from Martin Lilley’s influence. Approximately 300 of the Mark III, Mark III 1800, 1800S and MkIV cars were built (estimated to be 60 of the Mark III, 30 to 35 of the Mark III 1800, 128 of the 1800S / Mark III 1800S and 78 of the Mk IV) before being replaced in 1967 by the Vixen. The larger-engined Mark III 1800 model of the TVR Grantura was first introduced as a road car in September 1963 and subsequently homologated for racing in April 1964. Although it is the rarest variant of the Grantura, it is by far the most popular version for pre-1966 historic competition. The main reasons are that, in addition to the obvious benefits of the more powerful 1798cc BMC ‘B’ engine over the previous 1622cc unit, the 1964 homologation allowed use of a limited slip differential as well as wider wheel rims (5″) than those permitted on the earlier 1962/63 Mk III cars (4″ or 4.5″). Then, in June 1965 an extension of the homologation allowed the car to run on even wider wheels (6″). As a result, the June 1965 specification is the ultimate form of the car for use in pre-1966 racing and the one that almost all racing Granturas are built to conform to in historic competition. As a competition car the TVR Grantura MkIII benefits from being eligible for a wide range of historic racing and, due to its relatively light weight and good handling characteristics, it can be very effective when competing against some of the larger engined cars, especially when, as almost all examples are, it is in the June 1965 homologated Mk III 1800 trim. Although the earlier initial version of the Mark III had its own distinct set of homologation papers dated August 1962, for racing purposes many of the cars that would have originally started on the production line as this 1962/63 model have been since modified to run to the later Mark III 1800 specification from the 1964/65 seasons. Only around 30 to 35 examples of the Grantura are thought to have left the factory in true Mk III 1800 specification in the period between late 1963 and mid-1965. The smaller engined 1622cc Mark III cars built to the August 1962 specification are eligible to run in high profile Pre-63 events including the prestigious bi-annual Classic Le Mans race for cars that competed in period in the Le Mans 24 hours race.

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

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

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

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

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

The Chimaera was originally intended to replace the Griffith but sufficient demand for both of the models led TVR continuing them. In 1994, TVR introduced the Chimaera 500, a high performance derivative of the Chimaera. The BorgWarner T5 manual transmission replaced the Rover LT77 unit on the rest of the range. A new alternator, power steering and a single Vee belt were fitted to improve reliability. The 4.3 litre engine option was replaced by the 4.0 litre High Compression option. The Chimaera was mildly updated in 1996. Updates included a rear bumper shared with the Cerbera, push button doors with the buttons located under the wing mirrors, a boot lid shared with the Cerbera and the replacement of the front mesh grille with a horizontal bar. The GKN differential was also replaced by a BTR unit. A 4.5 litre model was added to the lineup in 1997. It was originally intended to be fitted with the AJP8 V8 engine but due to the engine not being ready on time, a bored version of the Rover V8 was used instead. In 1998, the rear light styling and the number plate mounting angle was updated while the base 4.0 litre model was discontinued. In 2001, the Chimaera was again facelifted and now featured the Griffith’s headlights as well as seats from the Cerbera. The Chimaera was succeeded by the Tamora in 2002.

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

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

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

Taking its name from the Greek name of a lightweight battle-axe used by the Scythians which was feared for its ability to penetrate the armour of their enemies, the final TVR model to be seen here was a Sagaris, a car which made its debut at the MPH03 Auto Show in 2003. The pre-production model was then shown at the 2004 Birmingham Motorshow. In 2005 the production model was released for public sale at TVR dealerships around the world. Based on the TVR T350, the Sagaris was designed with endurance racing in mind. Several design features of the production model lend themselves to TVR’s intentions to use the car for such racing. The multitude of air vents, intake openings and other features on the bodywork allow the car to be driven for extended periods of time on race tracks with no modifications required for cooling and ventilation. The final production model came with several variations from the pre-production show models such as the vents on the wings not being cut out, different wing mirrors, location of the fuel filler and bonnet hinges. As with all modern TVRs the Sagaris ignored the European Union guideline that all new cars should be fitted with ABS and at least front airbags because Peter Wheeler believed that such devices promote overconfidence and risk the life of a driver in the event of a rollover, which TVRs are engineered to resist. It also eschewed electronic driver’s aids (such as traction control or electronic stability control). In 2008, TVR unveiled the Sagaris 2, which was designed to replace the original Sagaris. In the prototype revealed, there were minor changes to the car including a revised rear fascia and exhaust system, and modifications to the interior. Sagaris models. on the rare occasions that they come up for sale, are pricey.

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

ULTIMA

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

VAUXHALL

A coupé version of the HC series Viva, called the Firenza, was introduced in early 1971 to compete with the Ford Capri and forthcoming Morris Marina Coupé. It was available in deluxe and SL forms, with the latter sporting four headlights and finally resurrecting the missing 2.0 twin-carburettor engine from the HB Viva GT. The basic 1,159 cc engine was enlarged to 1,256 cc in late 1971 and with this the 90 version was removed from the line-up. The overhead cam engines were upgraded in early 1972, the 1.6 becoming a 1.8 and the 2.0 twin carburettor became a 2.3 (2,279 cc). At this time, the Viva 2300 SL and Firenza Sport SL did away with the letter-box speedometer and substituted an attractive seven-dial instrument pack. Firenza SLs had a two round-dial pack, though all other Vivas and Firenzas stuck with the original presentation. In September 1973, the Viva range was divided, the entry 1,256 cc models staying as Vivas, with an optional 1.8 litre engine if automatic transmission was chosen. The 1.8 and 2.3 litre models took on more luxurious trim and were rebadged as the Magnum. At the same time, the Firenza coupe was given a radical makeover with an aerodynamic nose and beefed up 2.3 litre twin carb engine mated to a ZF five-speed gearbox, turning it into the HP (High Performance) Firenza. The Viva was again revised in 1975, with trim levels becoming the E (for Economy), L and SL. The E was Vauxhall’s answer to the Ford Popular and was first offered as a promotional edition two-door coupe using surplus Firenza body shells, before becoming a permanent Viva model in two-door saloon form. It was the only Viva to still have the strip speedometer after this as the L and SL adopted the Firenza SL’s two round dial set up. As of the autumn of 1975 the 1800 engine was also upgraded, increasing power from 77 to 88 hp. For 1977, the SL was replaced by the GLS, essentially marrying the plusher Magnum trim and equipment with the base 1,256 cc pushrod ohv engine. These models all had the full seven dial instrument panel, velour seating and Rostyle wheels, among many other upgrades. Viva production was scaled down after the launch of the Chevette in spring 1975. Originally a three-door hatchback, the Chevette offered two- and four-door saloons and a three-door estate in 1976 that all usurped the Viva’s position as Vauxhall’s small car entry. The Chevette hatch was also sold as the Opel Kadett City, but the Viva remained on sale until the later part of 1979, with 640,863 cars having been made. The Viva was effectively replaced by the new Vauxhall Astra, a variant of the front-wheel-drive Opel Kadett. By that time it was dated in comparison with more modern rivals like the Volkswagen Golf.

In 1973, Vauxhall acknowledged that their rather dull model range needed a makeover, and developed a radical version of the Firenza, known officially as the High Performance (HP) Firenza, but known colloquially as the “droopsnoot” after its dramatically styled aerodynamic nose. The nose was moulded from GRP, and featured two pairs of Cibié headlamps behind toughened glass covers. The overall look was somewhat reminiscent of the Renault Alpine A310, and used the same headlamp units. Several prototypes of the HP Firenza were considered with different types of front end treatment, requiring different degrees of change from the standard production front end, including cars known as Black Knight and Daytona, the latter for its resemblance to the Ferrari Daytona, a favourite of Wayne Cherry. At that time, the original flat-fronted Firenza model was rebadged as the Magnum coupé, and the name Firenza was used exclusively for the HP version. This car was an exciting styling departure for Vauxhall, and certainly created something of a buzz. The engine was the 2.3-litre variant of the OHC Slant Four engine, uprated to a very torquey 131 bhp using a variety of parts developed by Blydenstein Racing. It had twin 175 Stromberg carburettors, high-lift camshaft and free-flow tubular exhaust manifold. The car was restyled on the David Jones original by American designer Wayne Cherry and the result was an exceptionally low drag coefficient for its time. Suspension was uprated and lowered, brakes uprated, and a 5-speed ZF dog leg gearbox was installed, a much stronger unit than fitted to the standard model (though rather noisy). Another unusual and unique feature of the car was the alloy Avon Safety Wheels, which were designed to retain the tyre safely in the event of a puncture. This was the first car to use these wheels in production. All production cars were painted in the same colour – Silver Starfire, and featured a largely black interior with silver-grey cloth seats. An unusual interior feature of dubious utility was the passenger grab handle on the dash in place of the standard glovebox. The car was a design triumph for Vauxhall, but a marketing failure. The car was launched to much publicity in a special one-off race at Thruxton circuit in Hampshire, with top drivers of the day taking part including Gerry Marshall and Barry “Whizzo” Williams, who won the race. However, the fuel crisis of the time meant that suddenly it became very hard to sell gas-guzzling cars like this (even though the aerodynamics increased fuel economy greatly, reducing the power needed to attain its top speed by some 30 hp), and coupled with some production line difficulties in actually building the car meant that sales and delivery were slow, and eventually just 204 examples were built, far short of the 30,000 projected. This very low volume was obviously a disaster for Vauxhall, but ironically it has led to the car becoming a very collectible classic, thus ensuring its survival—some of the much more common production cars produced alongside it can be now harder to find. Celebrity owners of droopsnoot Firenzas are footballer Luther Blissett and former sports commentator Stuart Hall. The Firenza was also very successful in saloon car racing in the 1970s, especially in its Old Nail and Baby Bertha versions, piloted to great effect by Gerry Marshall. As well as the HP version, also to be seen here was the earlier car, which was effectively a coupe version of the HC Viva. In the autumn of 1973 these were rebranded as Magnum and offered with the 1800 and 2300cc engines. They never came close to generating the affection that was held by the Capri, their closest rival.

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

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 liters. 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.

By the mid-1980s, General Motors had started developing a new model to replace the J-Car models in Europe (its American, Australian and Japanese divisions would instead be replaced by different designs in due course) by the end of the decade. The new model would retain the Cavalier nameplate for the Vauxhall version on the UK market, but elsewhere in Europe the car would be sold as the Opel Vectra – spelling the end for the long-running Ascona nameplate. Soon afterwards, development also began on a new coupe which would share the same underpinnings as the hatchbacks and saloons, but would use a different nameplate and feature completely different styling. The final generation Cavalier went on sale on 14 October 1988, being Vauxhall’s version of the Opel Vectra “A”, again available as a saloon and hatchback. There was no estate version in the Opel line-up, and as this design was not going to be sold in Australia, there was no prospect of Vauxhall turning to Holden for a replacement. Early plans for an estate model exclusive to Europe to be developed never materialised. During 1989, however, the Cavalier’s floorpan did spawn a new coupe – the Calibra, the first Vauxhall coupe since the original Cavalier coupe was discontinued in 1981. The Calibra was the official replacement for the Opel Manta, which had been discontinued in 1988, and was also sold on continental Europe under the Opel Brand. Plans for the Calibra to be imported to the USA under the Saab brand never materialised. The Vectra name was not adopted at this model change as Vauxhall feared reviving memories of the much-maligned Vauxhall Victor, whereas the Cavalier was a generally well received product and had helped boost Vauxhall’s sales and reputation. Early Victors had been viewed in some quarters as excessively corrosion prone, but the Victor was becoming a very distant memory by this stage: the Vectra name would eventually appear on a Vauxhall in 1995, when the Cavalier was finally replaced. In place of the Mark II Cavalier’s angular exterior was a more rounded appearance, reflecting the change in styling tastes throughout Europe at this time. There was also a new economical 1.4 L petrol engine. The biggest changes to the range were the addition of 2.0 L sixteen valve engines, better known as the “red top” or XE. This was fitted to the GSi 2000 and later SRis. Also made available was a four-wheel drive system, fitted to a 2.0iL model (8 valve SRi spec) and on a version of the GSi 2000. There were two diesels available: a 1.7 L, 60 hp from launch, and an 82 hp 1.7-litre Isuzu-engined lightly blown turbodiesel from 1992. The early SRis were fitted with the 2.0-liter eight-valve engine from the previous Cavalier model, which produced 130 hp. Despite the lack of an estate body style, the Cavalier topped the large medium family car sales charts in Britain in 1990, narrowly outselling the Ford Sierra, while Rover was beginning to phase out its Montego in favour of the new Rover 400 Series and later the more upmarket 600 Series. Other strong contenders in this sector included the long-running Citroën BX and Peugeot’s highly regarded 405. Having first outsold the Sierra in Britain in 1990, it was Britain’s second best selling car behind the Ford Escort in 1992. It did not lose top spot in its sector until it was overtaken by the Sierra’s successor, the Mondeo, in 1994. The Calibra, launched in 1989, was well received, notably for its sporty although cramped interior (largely based on the interior of the Cavalier) and its streamlined styling which in turn enabled the Calibra to have the lowest drag coefficient of the period at 0.26 for the 8v model (0.29 for the rest) – a record it held for the next 10 years. A few variants were made: the 2.0 litre eight valve, 2.0 L sixteen valve (the same engine found in the proven Cavalier GSi 2000), the turbo version (again, the same engine used in the very successful Cavalier Turbo), the 2.5 L V6 (with a top speed of around 145 mph) and finally the 2.0 L 16-valve “Ecotec”. A facelift in the autumn of 1992 for the 1993 model year saw the Cavalier’s 1.4 L engine dropped and the 167 bhp 2.5 L V6 added to the range. At this time the GSi 2000 was replaced by a new four wheel drive version badged simply “Cavalier Turbo”, with a turbocharged version of the sixteen valve engine producing over 200 bhp. The Vauxhall logo was added to the centre of the boot. Most of the range now had airbags and anti-lock brakes as standard (the first car in its class to do so) and all models were fitted with a toughened safety cage, side impact beams (providing additional longitudinal load paths) and front seatbelt pretensioners. This version of the Cavalier was the first Vauxhall to feature a drivers airbag, with a passenger one being optional; this feature soon became available across the rest of the company’s range. The exterior design was also freshened up, with a new look grille, headlights, rear lights and bumper mouldings and an increase in sound insulation, especially in GLS and higher models making the Cavalier a quiet place to travel in. In late 1994, the new 2.0L Ecotec engine was launched replacing both the popular eight valve C20NE and high performance sixteen valve “redtop” engine. The new engine had improved fuel economy and low end torque at the cost of maximum power output, 136 hp compared to 150 hp for the “redtop” that it replaced. After twenty years and three generations, the Cavalier came to an end in October 1995 when it was replaced by the Vectra, though sales continued for about a year afterwards and several P registered versions (August 1996 to July 1997 period) were sold. The third and final incarnation of the Cavalier was a big improvement over its predecessors (and most earlier Vauxhalls) in terms of durability, with the rust problems that had plagued Vauxhall for years finally being conquered. This was reflected by the fact that Mark III Cavaliers were a common sight on British roads for well over a decade after the end of production. The demise of the Cavalier name marked a significant moment for the Luton-based company, as it would be the last of its main models with a distinct name from its Opel counterparts until the rebadging of the Opel Speedster as the Vauxhall VX220 and the Opel Karl as the Vauxhall Viva. All future Vauxhall models would share their names with those of Opel, or in the case of the 2004 Vauxhall Monaro, with Holden. However, the Astra nameplate was chosen by Vauxhall at the beginning of 1980 for its version of the first front-wheel drive Opel Kadett, and from 1991 General Motors decided to sell the Opel version of the car as the Astra. This version of the Cavalier shared its chassis with the Saab 900 that was produced from 1993 until 1998, and continued until 2002 as the Saab 9-3, due to Saab also being within the General Motors combine at the time.

Getting rare now is the Calibra, a model that GM introduced to counter the Japanese sports coupés of the late 1980s and early 1990s. Launched in 1989, it employed the running gear of the first generation Opel Vectra, which had been launched a year earlier in 1988. Calibra production was based in the Opel factory in Rüsselsheim, Germany, and the Valmet Automotive factory in Uusikaupunki, Finland, where production was consolidated in November 1995. Known in Europe as the Opel Calibra and as a Vauxhall in the UK, it was also marketed as the Chevrolet Calibra in South America and the Holden Calibra in Australia and New Zealand. The Calibra was styled by GM’s designer Wayne Cherry and the German designer, Erhard Schnell. and when launched, it was the most aerodynamic production car in the world, with a drag coefficient (Cd) of 0.26. It remained the most aerodynamic mass production car for the next 10 years, until the Honda Insight, along with the Audi A2, were launched both in 1999, with a Cd of 0.25, though the more powerful 16V, V6, 4×4 and turbo models had a worse Cd of 0.29, due to changes in their cooling system, underbody, use of spoked wheels and glass detail. As a front-wheel drive coupé based on the Vectra A chassis, its ride and handling were not significantly better than that of the large family car from which it grew. The 4WD turbo version of the car, which had independent rear suspension, featured the rear axle of the Opel Omega A with some minor alterations to it. Power was initially from 2.0 litre 8-valve 115 bhp and a Cosworth designed 16-valve fuel-injected 150 bhp four-cylinder redtop petrol engines. In 1992 a turbocharged 2.0 litre 16 valve 204 bhp engine was added to the range. With four-wheel drive, a six-speed Getrag manual transmission and a claimed top speed of 152 mph, this flagship model finally gave the Calibra the dynamics to match its looks. The Turbo model was also notable for the 5-stud wheel hubs and the extreme negative camber of its rear wheels, which is apparent even from a cursory visual inspection. In 1993 a 167 hp 2.5 litre V6 (was introduced. Available with both manual and automatic transmissions, the V6 was not as fast as the Turbo, but was rather more civilised, and proved to be more reliable as car than the complex four-wheel drive model. 1995 saw the introduction of the X20XEV Ecotec engine, a new version of the classic C20XE 16-valve or “red top” engine. This marked a reduction in power from 150 bhp to 136 bhp for the 16-valve version, although the Turbo continued with the older C20LET. Throughout the production run, several special edition models were launched. This began with the 1993 SE1, and ran through to the SE9 in 1997. These limited run editions had often unique aspects. For example, solar yellow paint on the SE2, or “Icelandic” blue on the SE6. Neither colours were found on any other Calibra. In September 1995, the Vectra A was replaced, but Calibra production continued until 1997. During its lifetime, the Calibra was much more popular in Europe, and outsold its nearest rival, the Ford Probe, which was considered to be underpowered, and very American for most European drivers, but in the UK, it failed to outsell the Rover 200 Coupé, which offered comparable performance, but without 4WD in the top–of–the–range models.

VOLKSWAGEN

Most stylish of the VWs here was, in my opinion, a splendidly presented Type 1 Karmann Ghia Coupe. This model debuted at the October 1953 Paris Auto Show as a styling concept created for Ghia by Luigi Segre. In the early 1950s, Volkswagen was producing its economy car, the Type 1 (Beetle), but with an increase in post-war standards of living, executives at Volkswagen proposed adding a halo car to its model range, contracting with German coachbuilder Karmann for its manufacture. Karmann in turn contracted the Italian firm Ghia, who adapted styling themes previously explored for Chrysler and Studebaker to a Beetle floorpan widened by 12 in. Virgil Exner claimed that the design was his, based on the 1953 Chrysler D’Elegance. In contrast to the Beetle’s machine-welded body with bolt-on wings, the Karmann Ghia’s body panels were butt-welded, hand-shaped, and smoothed with English pewter in a time-consuming process commensurate with higher-end manufacturers, resulting in the Karmann Ghia’s higher price. The design and prototype were well received by Volkswagen executives, and in August 1955 the first Type 14 was manufactured in Osnabrück, Germany. Public reaction to the Type 14 exceeded expectations, and more than 10,000 were sold in the first year. The Type 14 was marketed as a practical and stylish 2+2 rather than as a true sports car. As they shared engines, the Type 14’s engine displacement grew concurrently with the Type 1 (Beetle), ultimately arriving at a displacement of 1584 cc, producing 60 hp. In August 1957, Volkswagen introduced a convertible version of the Karmann Ghia. Exterior changes in 1961 included wider and finned front grilles, taller and more rounded rear taillights and headlights relocated to a higher position – with previous models and their lower headlight placement called lowlights. The Italian designer Sergio Sartorelli, designer of the larger Type 34 model, oversaw the various restylings of the Type 14. In 1970, larger taillights integrated the reversing lights and larger wrap-around indicators. Still larger and wider taillights increased side visibility. In 1972, large square-section bumpers replaced the smooth round originals. For the USA model only, 1973 modifications mandated by the National Highway Traffic Safety Administration (NHTSA) included energy-absorbing bumpers. A carpeted package shelf replaced the rear seat. In late 1974 the car was superceded by the Porsche 914 and the Golf based Scirocco.

A popular classic now, this was a nice example of the first generation Golf GTi. The model was first seen at the Frankfurt Motor Show in 1975. The idea behind it was rather straightforward – take a basic-transportation economy car and give it a high-performance package, making it practical and sporty. It was one of the first small cars to adopt mechanical fuel injection, which meant that the 1588cc engine put out 110 bhp, a big increase on what was available in the regular Golf models, which, in conjunction with a light weight of just 810 kg, gave it a top speed of aorund 100 mph and a 0 – 60 time of 9 seconds, impressive figures in their day. Volkswagen initially built the GTI only for the home market of West Germany, but launched it onto the British market in 1977 in left-hand drive form, with a right-hand drive version finally becoming available in 1979 as demand and competition increased. Many regard the Golf GTI Mk1 as the first “hot hatch” on the market, it was in fact preceded by the Autobianchi A112 Abarth in 1971, although it would prove to be far more popular than the earlier car in the UK market since the A112 Abarth was never available in RHD. It also competed with a number of quick small saloons including the Ford Escort RS2000. When the Escort switched to front-wheel drive and a hatchback for the third generation model in 1980, Ford launched a quick XR3 model which was comparable to the Golf GTI in design and performance. The Golf GTI was among the first “hot hatch” with mass market appeal, and many other manufacturers since have created special sports models of their regular volume-selling small hatchbacks. Within a few years of its launch, it faced competitors including the Fiat Ritmo, Ford Escort XR3/XR3i, Renault 5 GT Turbo and Vauxhall Astra/Opel Kadett GTE. A five speed gearbox became available in 1981 and in 1982, the engine was enlarged to 1780cc, which increased the available power a little. The car proved popular in the UK from the outset, with over 1500 being sold in 1979. Although the subsequent recession saw new car sales fall considerably during 1980 and 1981, sales of the Golf GTI reached nearly 5,000 in 1981. This also came in spite of the arrival of a popular new British-built competitor – the Ford Escort XR3. By 1983, the GTI accounted for more than 25% of total Golf sales (some 7,000 cars).

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

VW had enjoyed considerable success with the Scirocco, a front wheel drive Hatch that was based on the Golf, and offered a stylish modern alternative to the Ford Capri and Opel Manta. the second generation car did not quite the same favour as the first, but even so there was eager anticipation of what was initially thought would be the third generation car. But as VW looked to push the model further upmarket, they opted for a new name, choosing Corrado for the car, which debuted in 1988. Although the new car’s floorpan was based on that of the Mark 2 Golf/Jetta, there had been a plan that the model would actually replace the Porsche 944. That idea came to nought and the car, built by Karmann, as the Scirocco had been, took its place in the VW range, alongside the Scirocco which remained in production for a further three years. All Corrados were front-wheel drive and featured petrol engines, the car debuting with two engine choices: a 1.8 litre 16-valve inline-four with 136 hp and a troublesome supercharged 1.8 litre eight-valve inline-four, marketed as the G60 and delivering 160 hp. The Corrado G60 was named for the G-Lader with which it was equipped, a scroll supercharger whose interior resembles the letter “G”. Volkswagen introduced two new engines for 1992. The first was a naturally-aspirated 2.0 litre 16-valve 136 bhp inline-four, basically a further development of the 1.8 litre engine; this engine was not made available to the North American market. The second was the 12-valve VR6 engine, which came in two variants: a 2.8 litre 179 bhp model for the US and Canadian markets and a 2.9 litre 187 bhp version for the European market. Upon revising the engine, VW updated the styling with a new front grille and foglamps. With the introduction of the VR6 engine, the G60 engine disappeared from the North American market after 1992 and European market in 1993. The VR6 engine provided a compromise between both V-shaped and straight engines by placing the two cylinder banks at an angle of 15° with a single cylinder head. This design allowed engineers to fit a six-cylinder engine into roughly the same space that was previously occupied by four-cylinder engines, while closely approaching the smoothness of a straight-six design. By the time it was launched, VW had updated the Golf to the Mark 3,and some elements of its A3 platform was introduced on the Corrado with the VR6 announcement, including the suspension components, the rear axle assembly and some parts of the A3’s ‘plus’ type front axle assembly. The subsequent wider front wheel-track of the Corrado VR6 necessitated the fitting of new front wings with wider wheel arches and liners along with a new front bumper assembly. Together with a new raised-style bonnet to accommodate the VR6 engine, these body improvements were carried across the model range. A 2.0 litre eight-valve model with 115 hp was produced in Europe in 1995. A UK-only limited production model, the Corrado Storm, was also sold. Some discreet “Storm” badging, a colour-keyed front grille, an additional Storm badge on the gear gaiter surround (an upgrade from the standard Karmann badge), 15 inch BBS “Solitude” alloy wheels, and standard fitment of some previously optional items (such as the leather heated front seats) were all that differentiated this model from the base Corrado VR6. Only 500 were produced: 250 in Classic Green with a cream leather interior, and 250 in Mystic Blue, a colour unique to the Storm, with a black leather interior. The Storm models are the most desirable of all these days. Production ended in 1995. Although the car was much praised for its handling, and the VR6 engine was sublime, t was costly, Karmann’s build quality was patchy and those who experienced the G60 versions had more than their fair share of reliability issues (A colleague of mine had at least 4 superchargers blow in the first 60,000 miles). All told, 97,521 Corrados were produced.

VOLVO

This is a nice example of the Volvo P1800, a sports car that was manufactured by Volvo Cars between 1961 and 1973. The car was a one-time venture by the usually sober Swedish Volvo, who already had a reputation for building sensible sedans. The project was originally started in 1957 because Volvo wanted a sports car to compete in the US and European markets, despite the fact that their previous attempt, the P1900, had failed to take off with only 68 cars sold. The man behind the project was an engineering consultant to Volvo, Helmer Petterson, who in the 1940s was responsible for the Volvo PV444. The design work was done by Helmer’s son Pelle Petterson, who worked at Pietro Frua at that time. Volvo insisted it was an Italian design by Frua and only officially recognised that it was by Pelle Petterson many years later. The Italian Carrozzeria Pietro Frua design firm (then a recently acquired subsidiary of Ghia) built the first three prototypes between September 1957 and early 1958, later designated by Volvo in September 1958: P958-X1, P958-X2 and P958-X3. In December 1957 Helmer Petterson drove X1, the first hand-built P1800 prototype to Osnabrück, West Germany, headquarters of Karmann. Petterson hoped that Karmann would be able to take on the tooling and building of the P1800. Karmann’s engineers had already been preparing working drawings from the wooden styling buck at Frua. Petterson and Volvo chief engineer Thor Berthelius met there, tested the car and discussed the construction with Karmann. They were ready to build it and this meant that the first cars could hit the market as early as December 1958. But in February, Karmann’s most important customer, Volkswagen forbade Karmann to take on the job, as they feared that the P1800 would compete with the sales of their own cars, and threatened to cancel all their contracts with Karmann if they took on this car. This setback almost caused the project to be abandoned. Other German firms, NSU, Drautz and Hanomag, were contacted but none was chosen because Volvo did not believe they met Volvo’s manufacturing quality-control standards. It began to appear that Volvo might never produce the P1800. This motivated Helmer Petterson to obtain financial backing from two financial firms with the intention of buying the components directly from Volvo and marketing the car himself. At this point Volvo had made no mention of the P1800 and the factory would not comment. Then a press release surfaced with a photo of the car, putting Volvo in a position where they had to acknowledge its existence. These events influenced the company to renew its efforts: the car was presented to the public for the first time at the Brussels Motor Show in January 1960 and Volvo turned to Jensen Motors, whose production lines were under-utilised, and they agreed a contract for 10,000 cars. The Linwood, Scotland, body plant of manufacturer Pressed Steel was in turn sub-contracted by Jensen to create the unibody shells, which were then taken by rail to be assembled at Jensen in West Bromwich. In September 1960, the first production P1800 left Jensen for an eager public. The engine was the B18, an 1800cc petrol engine, with dual SU carburettors, producing 100 hp. This variant (named B18B) had a higher compression ratio than the slightly less powerful twin-carb B18D used in the contemporary Amazon 122S, as well as a different camshaft. The ‘new’ B18 was actually developed from the existing B36 V8 engine used in Volvo trucks at the time. This cut production costs, as well as furnishing the P1800 with a strong engine boasting five main crankshaft bearings. The B18 was matched with the new and more robust M40 manual gearbox through 1963. From 1963 to 1972 the M41 gearbox with electrically actuated overdrive was a popular option. Two overdrive types were used, the D-Type through 1969, and the J-type through 1973. The J-type had a slightly shorter ratio of 0.797:1 as opposed to 0.756:1 for the D-type. The overdrive effectively gave the 1800 series a fifth gear, for improved fuel efficiency and decreased drivetrain wear. Cars without overdrive had a numerically lower-ratio differential, which had the interesting effect of giving them a somewhat higher top speed of just under 120 mph, than the more popular overdrive models. This was because the non-overdrive cars could reach the engine’s redline in top gear, while the overdrive-equipped cars could not, giving them a top speed of roughly 110 mph. As time progressed, Jensen had problems with quality control, so the contract was ended early after 6,000 cars had been built. In 1963 production was moved to Volvo’s Lundby Plant in Gothenburg and the car’s name was changed to 1800S (S standing for Sverige, or in English : Sweden). The engine was improved with an additional 8 hp. In 1966 the four-cylinder engine was updated to 115 PS, which meant the top speed increased to 109 mph. In 1969 the B18 engine was replaced with the 2-litre B20B variant of the B20 giving 118 bhp, though it kept the designation 1800S. For 1970 numerous changes came with the fuel-injected 1800E, which had the B20E engine with Bosch D-Jetronic fuel injection and a revised camshaft, and produced 130 bhp without sacrificing fuel economy. Top speed was around 118 mph and acceleration from 0–62 took 9.5 seconds. In addition, the 1970 model was the first 1800 with four-wheel disc brakes; till then the 1800 series had front discs and rear drums. Volvo introduced its final P1800 variant, the 1800ES, in 1972 as a two-door station wagon with a frameless, all-glass tailgate. The final design was chosen after two prototypes had been built by Sergio Coggiola and Pietro Frua. Frua’s prototype, Raketen (“the Rocket”), is located in the Volvo Museum. Both Italian prototypes were considered too futuristic, and instead in-house designer Jan Wilsgaard’s proposal was accepted. The ES engine was downgraded to 125 bhp by reducing the compression ratio with a thicker head gasket (engine variant B20F); although maximum power was slightly down the engine was less “peaky” and the car’s on-the-road performance was actually improved. The ES’s rear backrest folded down to create a long flat loading area. As an alternative to the usual four-speed plus overdrive manual transmission, a Borg-Warner three-speed automatic was available in the 1800ES. With stricter American safety and emissions standards looming for 1974, Volvo did not see fit to spend the considerable amount that would be necessary to redesign the small-volume 1800 ES. Only 8,077 examples of the ES were built in its two model years.

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

This is a 144, one of a series of cars made between 1966 and 1974. Volvo Cars began manufacturing the Volvo 144 at Torslandaverken in the late summer of 1966[, the first Volvo to use a tri-digit nomenclature, indicating series, number of cylinders and number of doors. Thus, a “144” was a 1st series, 4-cylinder, 4-door sedan. The 144 was the first Volvo to feature a more rectilinear or boxy styling. Compared to the Volvo Amazon, the 140 was a radical departure with minimal exterior and interior carryover, notably a stylised version of the front split grille. The car’s basic shape would survive into the 1990s as the 200 series. Mechanically, the car used many of the same drivetrain components as the Amazon, but also showcased many improvements, including disc brakes on all four wheels. It was named car of the year in 1966 by Swedish magazine Teknikens Värld. The engine in the standard 144 was the same as found in the standard Amazon (121), the 1.8l B18A, but the 144S was given the more powerful B18B from the 123GT and 1800S. Late in the 1967 model year production of the Volvo 142 (2-door sedan) began, in time to build 1500 units for the first year. In 1968 production of the Volvo 145 5-door station wagon began, completing the three body styles used in the 140 range. For the 1969 model year Volvo enlarged the B18 to become the 2.0 litre B20 and replaced the generator with a more modern alternator. It was also in 1969 that Volvo introduced the 164, which shared much of the 140 series structure and styling aft of the windshield while incorporating a 6-cylinder engine, the B30 which was simply a B20 with 2 more cylinders and a few strengthened and enlarged components. In 1970 a flow-through ventilation system, where vents were added towards the rear of the car (on the exterior under the rear window on the 142 and 144 and as a grille next to the right side taillight of the 145) and electrically defrosted rear windows, were introduced. The split rear side window on the 145 became one piece which was no longer possible to open. In 1971 the first of several styling changes were introduced, including a revised black grille which saw the now ubiquitous Volvo diagonal line introduced as well as new wheels. 1971 also saw the introduction of the B20E, which was a high compression version of the B20 which introduced Bosch D-Jetronic electronic fuel injection. These new cars were either given the designation E (the German word Einspritzer, or “injection”) or GL (for Grand Luxe), which was a more upmarket version of the car. A console on the transmission tunnel with a clock was now standard. The styling changes continued in 1972 with the introduction of flush mounted door handles and a slightly revised dashboard with fake woodgrain trim, newly designed switches and a small central panel with a clock. The transmission tunnel was taken from the 164 as was the same short-shifter gear stick and the automatic transmission became controlled by a T-bar mounted on the floor at the same place. The outer 2 rear seats now had the mounting points for retractable seatbelts. A low compression fuel injected engine, the B20F was introduced for the US and certain other markets. In 1973 the 140 series received a major facelift, with a new plastic grille, new larger indicators and a completely revised tail end. Also, the S designation was dropped and the range consisted of 3 trim levels, standard (with no designation, known as L, or “luxe”) de Luxe and the most upmarket, Grand Luxe. The interior also had a completely revised dashboard with a new instrument cluster consisting of dials rather than the strip speedometer previously used, rocker switches replacing the push-pull switches (with the exception of the headlight switch), and vents to direct air towards the person augmenting the defrost and floor vents. In 1974, the B20E/F engine switched from using the Bosch D-Jetronic to the K-Jetronic mechanical fuel injection system. Also, several safety changes were introduced including a fuel tank that was located close to the axle to protect it in the case of a rear-end collision, and larger bumpers that protruded more from the body. The quarter-light windows in the front doors were removed as a result of the improvements in ventilation inside the car, and small anodised aluminium strips were added to the bottom of the side windows. Total Production was 412,986 2-doors sedans, 523,808 4-doors sedans and 268,317 estates.

The Volvo 200 series replaced the 140 and 160 series and was produced by Volvo Cars from 1974 to 1993, with more than 2.8 million units sold worldwide. Like the Volvo 140, it was designed by Jan Wilsgaard. It overlapped production of the Volvo 700 series introduced in 1982. As the 240 remained popular, only the 260 was displaced by the 700 series — which Volvo marketed alongside the 240 for another decade. The 700 series was replaced a year before the 240 was discontinued. Production of the 240 ended on 14 May 1993 after nearly 20 years. The Volvo 240 and 260 series were introduced in the autumn of 1974, and was initially available as six variations of the 240 Series (242L, 242DL, 242GT, 244DL, 244GL, 245L and 245DL) and two variations of the 260 Series (264DL and 264GL). The 240 Series was available in sedan (with two or four doors) or station wagon, however the 260 Series was available as a coupé (262C Bertone), four-door sedan, or station wagon. The 200 looked much like the earlier 140 and 164 Series, for they shared the same body shell and were largely the same from the cowl rearward. However, the 200 incorporated many of the features and design elements tried in the Volvo VESC ESV in 1972, which was a prototype experiment in car safety. The overall safety of the driver and passengers in the event of a crash was greatly improved with very large front and rear end crumple zones. Another main change was to the engines, which were now of an overhead-cam design. The 260 series also received a V6 engine in lieu of the 164’s inline-six. The 200 Series had MacPherson strut type front suspension, which increased room around the engine bay, while the rear suspension was a modified version of that fitted to the 140 Series. The steering was greatly improved with the installation of rack-and-pinion steering, with power steering fitted as standard to the 244GL, 264DL and 264GL, and there were some modifications made to the braking system. The front end of the car was also completely restyled – that being the most obvious change which made the 200 Series distinguishable from the earlier 140 and 160 Series. Other than all the changes mentioned above, the 200 Series was almost identical to the 140 and 160 Series from the bulkhead to the very rear end. In 1978, a facelift meant a redesigned rear end for sedans, with wraparound taillights and a trunk opening with a lower lip. The dashboard was derived from the safety fascia introduced for the 1973 140-series – but was changed again for the 1981 model year with the instrument pod made considerably larger and the radio repositioned near the top of the dashboard. All models were available with a choice of four-speed manual or a three-speed automatic transmission. Overdrive was also optional on the manual 244GL, while a five-speed manual gearbox was optional on the 264GL and 265GL. In the autumn of 1975 (for the 1976 model year in America), the 265 DL estate became available alongside the existing range, and this was the first production Volvo estate to be powered by a six-cylinder engine. The choice of gearbox was also greatly improved, with overdrive now available as an option in all manual models except the base-model 242L and 245L. As before, the 3-speed automatic was optional in every model. The B21A engine gained three horsepower; a new steering wheel and gearknob were also introduced. At the 1976 Paris Motor Show Bertone first showed the stretched 264 TE, a seven-seater limousine on a 3,430 mm (135 in) wheelbase, although it had entered production earlier. The raw bodies were sent from Sweden to Grugliasco for lengthening, reinforcing, and finishing. Carl XVI Gustav of Sweden used one, as did much of East Germany’s political leadership. For 1977 the B19A engine with 90 PS replaced the old B20A in most markets, although it soldiered on for another two years in some places. This is also when the sportier 242 GT arrived. In 1978 the grille was altered, now with a chrome surround. Rear view mirrors were now black, while the front seats were changed as were the emblems, while interval wipers were introduced. 1978s were also the first 240s to receive new paint, unlike the earlier model years which rusted very badly. 1979 brought a full facelift front and rear. The GLE was added while the L was cancelled, and the six-cylinder diesel arrived late in the year. For 1980, the sporty GLT arrived, replacing the GT. For 1981 there was yet another new grille, while the station wagons received new, wraparound taillights. The B21A gained some four horsepower, now 106 PS, while the carburetted B23A with 112 PS was introduced in some markets. The Turbo arrived, while six-cylinder models now had a more powerful 2.8-litre engine. Incremental improvements were made almost every year of the production run. One of the major improvements was the introduction of the oxygen sensor in North America in late 1976, which Volvo called Lambda Sond and developed in conjunction with Bosch. It added a feedback loop to the K-Jetronic fuel injection system already in use, which allowed fine-tuning of the air and fuel mixture and therefore produced superior emissions, driveability and fuel economy. For the 1983 model year, Volvo dropped the DL and GLE labels, selling the cars simply as 240s. Buyers protested and the grades returned for 1984. A new manual gearbox also arrived for 1984, while a four-speed automatic option was available in the GL. GLT and Turbo versions received a taller grille. About one-third of all 240s sold were estate models, which featured very large cargo space of 41 cubic feet. They could be outfitted with a rear-facing foldable jumpseat in the passenger area, making them a seven-passenger vehicle. The last 200 produced was a blue station wagon built to the Italian specification and named the “Polar Italia”, currently displayed at the Volvo World Museum.

The Volvo 262C is a luxury coupé made by Volvo from 1977 (as 1978 model) to 1981). Based on the 264 six-cylinder saloon, the 262C was designed in-house by Volvo’s Jan Wilsgaard, and built mainly by Bertone in Turin, Italy. The drivetrain, suspension, floor pan, and many of the body panels of the 262C were taken directly from the Volvo 260 four-door sedan, with Bertone building the roof pillars, roof pan, windshield surround, cowl, and upper parts of the doors. The roof of the 262C is about 100 mm (3.9 in) lower than that of the 260 sedans. The chopping had the effect of cramping interior space, and the wide C-pillars made for small-sized rear side windows The 262C used the PRV engine, a V6 engine developed jointly by Peugeot, Renault, and Volvo. The engine used a Lambda-sond oxygen sensor system; this was the first use of this system on a production V engine. Standard equipment included power windows and mirrors, central locking, cruise control, air conditioning, heated front seats, leather interior, alloy wheels, and electrically powered radio antenna. The only optional extras were a limited-slip differential, a choice of stereos, and the no-cost option of a Borg-Warner three-speed automatic instead of the four-speed manual with electrically operated overdrive. By 1981, the manual-transmission option had been discontinued for the U.S. market. On the occasion of Volvo’s 25th anniversary in the United States, Volvo North America contracted Newport Conversions of Santa Ana, California, to convert the 262C into a convertible to give as a gift to the company CEO. This version was called the 262C Solaire. Volvo’s Swedish headquarters, however, vetoed the project due to safety concerns. A total of five 262 convertibles were made. Aimed mainly at the United States market, the 262C was Volvo’s first entry into the luxury car segment. About half of the annual production was earmarked for the United States.[5] It competed against the Cadillac Eldorado and the Mercedes-Benz 280 CE and 300 CD. A total of 6,622 cars were produced from 1978 until 1980. The model was available in only one color combination: silver paint with black vinyl-covered roof. One automobile journalist described the 262C as “the strangely proportioned two-door looks like a chopped diesel locomotive” that “evades the classic ideals of beauty, regardless of the stylistic authorship.” For the 1979 model year, the rear-end design was modified with a deeper trunk lid and wrap-around taillights. Upgrades included thermostatic heater controls, and cars with manual transmission included the shift linkage from the 242GT. The 1980 model year featured an engine displacement increase from 2,664 to 2,849 cc as a result of the bore going from 88 to 91 mm. The engine was also reconfigured, with seven main bearings instead of four and an increase in compression ratio from 8.2:1 to 8.8:1. Also, in 1980, the front air dam from the 242GT was added to the 262C. For North America, the 2.8-litre engine was rated at 130 hp. The vinyl roof cover was deleted for the final 1981 model year of production.

In the spring of 1996, Volvo introduced a new high-performance Volvo 850 as a replacement for the hugely successful limited edition T-5R. Volvo decided there should be no direct successor to the T-5R, but due to its success, Volvo decided to develop a new high-performance model. The new car, based on the T-5R, was called the 850 R, which again came in either saloon or sport wagon editions. The only colours available were Bright Red, Black Stone, Dark Grey Pearl, Dark Olive Pearl, Turquoise Pearl and Polar White. In the U.S. market only Bright Red, Polar White and Black Stone were available. Cream yellow was discontinued for the 850 R. The saloon featured a newly designed rear spoiler; spoiler was now standard on the estate. The interior upgrades included bucket style heavily bolstered ‘sport’ front seats (Alcantara centre with leather bolsters), Alcantara door cards, 2-tone leather steering wheel, stainless steel ‘850’ kick plates and R branded over mats. A 200w amplifier was also added to the 8-speaker audio system as was the option to have an SC-805/815 in-dash CD player (some markets). For a limited time in 1996 only, Volvo offered a new heavy duty manual transmission designed specifically for the 850 R (excluding U.S. market), called the M59, which featured a viscous coupling limited slip differential. Furthermore, the M59 equipped cars were fitted with the B5234T4 2.3-litre 5-cylinder engine featuring a larger TD04HL-16T turbo, re-designed turbo manifold & intercooler, unique ecu with Motronic 4.4, uprated fuel pressure sensor and a heavy duty clutch. These modifications enabled the manual transmission cars to produce 250 bhp and 350 Nm (258 lb/ft) versus 240 bhp and 330 Nm (243 lb/ft) for the automatic transmission. Due to encumbrances placed on engine volume by the Italian government, 850 Rs sold in Italy were based on the 2.0 litre 850 Turbo. The transmission was the standard AW/50-42 used in all U.S. 850s, the M59 being available in other countries.

The Volvo S70 is a compact executive car produced by Volvo Cars from 1996 to 2000. The S70 was essentially a facelifted 850 saloon. The S70 was replaced with the Volvo S60. Introduced in Europe in late 1996 for the 1997 model year and later in the U.S. for the 1998 model year, the Volvo S70 was an updated version of the Volvo 850 saloon. The S70’s body style was overall more rounded compared to its predecessor. Changes included a redesigned front end with new lights, fully colour-coded bumpers and side trim, and clear indicator lenses for the rear lights, as well as a redesigned interior. According to Volvo, a total of 1800 changes were made. Standard equipment was improved with remote central locking, heated & electrically adjustable mirrors, 4 airbags, power brakes with ABS and power windows being standard on every car. Trim levels varied for each market as did the equipment levels of the most basic trims. In the United States, the badging denoted the engine variant and to some extent the equipment level, whereas in Europe engine and options could be chosen individually. On all markets more powerful versions usually received better or upgraded standard equipment. The T5 and R were the series high-performance models. For the 1999 model year, a minor facelift was introduced. Apart from very minor cosmetic changes, such as a slightly different Volvo badge on the front grille and US models now being equipped with side markers on the front fenders, most changes were done to the mechanicals. Volvo introduced its second generation side airbag which increased in volume to offer better protection. WHIPS, Volvo’s system to minimize whiplash injuries, was also introduced as part of the standard equipment. New engine management systems with drive-by-wire replaced the mechanical throttle on all turbo engines as well as an upgraded traction control system. Now including throttle as well as brake intervention it was renamed STC. The ABS was upgraded from a three-channel to a four-channel system, all-wheel drive models received thicker rear discs and redesigned rear calipers. All automatic transmissions were now equipped with adaptive shift-logic, replacing the previous 3-mode selection. A starter interlock was added to models with manual transmissions. For the 2000 model year, a new 5-speed automatic transmission with adaptive shift-logic was introduced. It was only available on non turbo front-wheel drive models. The 10V engine variants were dropped and replaced by detuned 20V versions, drive-by-wire throttle was now also introduced for non turbo models. With the S70, Volvo continued to offer a mid-size saloon. With a variety of models and options it was well received but was outsold by its estate variant the V70. With engines choices ranging from 126PS to 250PS, and a diesel engine finally being available for the saloon as well as the Bi-Fuel, there was something for everyone. Market adjustments meant that outside of Europe no TDI or Bi-Fuel models were available. Specialised versions for the fleet market, such as a taxi and police variant, were now available from the factory. Notable uses of police S70’s were by some British highway patrol forces and even some North American police forces.

The 480 was produced in Born, Netherlands, at the factory that built DAF cars, including the DAF 66 based Volvo 66, and later, the Volvo 300 Series. It was the first front-wheel drive car made by the automaker. The 480 was available in only one body style on an automobile platform related to the Volvo 440/460 five door hatchback and four door sedan models. It featured an unusual four seat, three door hatchback body, somewhere between liftback and estate in form, the first Volvo of its style since the P1800ES, and the last until the unveiling of the C30. All of these models featured a frameless glass hatch for cargo access.. Volvo took six years from the time the 480 was conceived, through its development, and finally brought to production readiness. Designed by Volvo’s Dutch subsidiary, the “sporty 480 ES coupe” was introduced to change the automaker’s “frumpy image” and into the “yuppie” market segment. The concept was to market a modern, compact front wheel drive car with a unique low slung design targeting buyers “between 25 and 40, probably with a higher than average education and with a career.” The press launch was on October 15, 1985, but the 480 was first put on public show at Geneva in March 1986, becoming available to the buyers in 1987. It was initially well received, with the press describing it as having a “sleek hatch body” in contrast to Volvo’s traditional “boxcar look”. Because the 480 was originally planned for the North American market (evidenced by its front and rear side markers, not used on European automobiles). it was, Volvo claimed, one of the first cars sold in Europe featuring bumpers designed to comply with United States National Highway Traffic Safety Administration (NHTSA) regulations to withstand a 5 mph front rear impact without damage to the engine, lights, and safety equipment. This was the only Volvo to feature pop up headlamps for better aerodynamics. Volvo highlighted that the car was “well-endowed with advanced electronics” and the automaker’s press release described in detail the numerous features, though some of these would prove to be the cause of the reliability problems that plagued early cars. The 480 had good handling, due in part to its Lotus designed suspension. The normally aspirated Renault engines were reliable. The 1987 models were available with ABS as an optional extra. In 1988, a Turbo version was introduced, the Garrett AiResearch turbocharger increasing the power from 108 bhp to 118 bhp. Maximum torque was 129 lb-ft compared to 103 lb-ft for the naturally aspirated engine. In 1993 new legislation meant that catalytic converters had to be fitted to unleaded petrol engines, power dropped and so the 2.0 litre engine was developed; it was rated at 108 bhp and 122 lb-ft. A four-speed automatic transmission was also offered. In 1991, the 480 received new mirrors, headrests for the back seats, as well as subtle modifications to the trim and body colour bumpers. The 2.0 naturally aspirated engine was also introduced, again based on the Renault F3 engine. Changes between the CEM (Central Electronic Module) are externally apparent with the introduction of a total closure system whereby the key can be held in the lock position to close the windows and (where fitted) sunroof. Earlier CEM modules feature a “passing” function for the wipers, whereby fully depressing the accelerator pedal will switch intermittent wipers to full. Early 1992 saw the first release of special editions such as the “TwoTone”. 1994 saw the United Kingdom release of the “Celebration” limited edition of 480 specially equipped and numbered cars. In 1994, the 480 also received its last light update, and now sported clear front turn signals. Production ended on 7 September 1995. According to the Volvo Museum, 76,375 cars in ES and Turbo versions were made between 1986 and 1995.