The core of the Queen Square (QS) event program remains the monthly Breakfast Club style meets, held on Sundays during the summer months and because of venue availabilities, a Saturday in the winter, and these remain hugely popular. But, as ever, once an event gets popular, many of the regular are eager for more, so one addition to the program, first trialled in 2023, was a mid-week evening event, taking advantage of the extended hours of daylight in the summer months. Starting at around 5pm, with the inevitable early arrivals doing their best pull this forward, the format is exactly the same as the weekend events, with a nice relaxed ambience and a varied, and unpredictable array of cars of all sorts from modern enthusiast and performance machines to true classics, with more than a few surprises thrown in for good measure. The two events in 2023 were well received, so they were planned into the 2024 QS program well in advance. Attendance at the April event was down a bit on what you would expect, especially given that the weather was very much on side, but I enjoyed it very much, and was keen to ensure I attended the August event as well. Once again, the weather was favourable. Here is what piqued my attention and was recorded by the camera.
ABARTH
What is known as the Series 4 version of the familiar 595 reached the markets in the middle of 2016. After rumours had circulated all winter following the launch of the facelifted Fiat 500 last year, Abarth finally unveiled the Series 4 at the end of May 2016. Initially, we were told that the cars would not be available in the UK until September, but that came forward somewhat, with dealers all receiving demo cars in June, and the first customers taking delivery in July. Three regular production versions of both the closed car and the open-topped C were initially available, all badged 595, and called Custom, Turismo and Competizione, as before, though numerous limited edition models have since appeared and in most case disappeared. The most significant changes with the Series 4 are visual, with a couple of new colours, including the much asked for Modena Yellow and a different red, called Abarth Red, which replaces both the non-metallic Officina and – slightly surprisingly – the tri-coat pearlescent Cordolo Red. as well as styling changes front and rear. The jury is still out on these, with many, me included, remaining to be convinced. At the front, the new air intake does apparently allow around 15 – 20 % more air in and out, which will be welcome, as these cars do generate quite a lot of heat under the bonnet. Competizione models for the UK retain the old style headlights, as they have Xenon lights as standard, whereas the Custom and Turismo cars have reshaped units. At the back, there are new light clusters and a new rear bumper and diffuser. Inside, the most notable change is the replacement of the Blue & Me system with a more modern uConnect Audio set up, which brings a new colour screen to the dash. Mechanically, there is an additional 5 bhp on the Custom (now 145) and Turismo (now 165 bhp) and the option of a Limited Slip Diff for the Competizione, which is likely to prove a popular option. Details of the interior trim have changed, with a filled-in glovebox like the US market cars have always had, and electric windows switches that are like the US ones, as well as a part Alcantara trim to the steering wheel in Competizione cars.
ASTON MARTIN
The Aston Martin DB11 is a two-door grand touring car. It was available as both a coupe and a convertible, the latter known as the “Volante”. The British carmaker Aston Martin produced the DB11 from 2016 to 2023 when it was replaced by the DB12. The DB11 succeeded the DB9, which the company made between 2004 and 2016. Designed by Marek Reichman, who became lead designer in May 2005, the DB11 debuted at the Geneva Motor Show in March 2016. The first model of Aston Martin’s “second-century plan”, the DB11—like its predecessor and its platform siblings—incorporates aluminium extensively throughout its body. Official manufacture of the DB11 began at the facility in Gaydon, Warwickshire, in September 2016. Two engine configurations of the DB11 were available: a 4.0-litre V8-engine model produced by Mercedes-AMG and a 5.2-litre V12-engine model produced by Aston Martin. The Volante version of the DB11 was introduced in October 2017. In 2018, Aston Martin and its racing division replaced the DB11 V12 with the DB11 V12 AMR, which included an increased engine output. The V8-powered model also received an enhancement in engine performance in 2021. Aston Martin began producing the DB9—a grand touring car—in January 2004 at the facility in Gaydon, Warwickshire. It was the first car built on the vertical–horizontal platform—a design in which all vehicles that used it extensively incorporated aluminium throughout their construction. This platform formed the basis of the Vantage in 2005, the DBS in 2007, the Rapide in 2010, the Vanquish in 2012 and the Lagonda Taraf in 2014. In 2015, Aston Martin announced that the DB9’s successor would be named the “DB11”. The upcoming range, known as the “second-century plan”, which the DB11 was a part of, was to introduce a refreshed design approach directed by Marek Reichman, whom Aston Martin appointed lead designer in May 2005. Insider reports indicated that this model range aimed to address critiques of the existing lineup by emphasising distinctive differences among the models, aligning them more closely with the prominent Italian luxury automobile manufacturer Ferrari. Manufacture of the DB9 officially ended in July 2016, after a twelve-year production run during which 16,500 units had been made. The DB11 debuted at the Geneva Motor Show in March 2016. Official manufacture of the DB11 began on 28 September 2016 at the facility in Gaydon, Warwickshire. To demonstrate his commitment to quality, Aston Martin’s then-CEO, Andy Palmer, personally inspected the first 1,000 cars. Similar to its predecessor, the DB11 is based upon a platform—which it shares with the 2018 model Vantage and the DBS Superleggera—that extensively incorporates aluminium throughout its construction. The chassis, in comparison to the DB9, is lighter and stiffer. Its body panels are made of both aluminium and composite materials, and the bonnet is a single-piece unit. Together, the car’s flat underbody, rear diffuser and sizable front splitter manage airflow beneath the DB11, minimising lift. The DB11 features an AeroBlade that captures high-speed air at the C-pillars and channels it through ducts under the bodywork, exiting through slots in the boot lid. This system mimics the effects of a large rear spoiler, reducing drag without added bodywork. An extendable active spoiler enhances the AeroBlade’s efficiency at high speeds. The DB11 has been described as both a sports car and a grand tourer. It is a two-door coupe that was available only in a four-passenger seating configuration. The DB11 has a rear-wheel drive layout with a front-mid-engine placement and exclusively uses a rear-mounted, eight-speed automatic transmission made by the technology manufacturing company ZF Friedrichshafen. Each DB11 was handcrafted, involving approximately 600 engineers and taking around 250 hours to complete. The Vanquish features anti-roll bars and double wishbone suspension supported by coil springs. There are three different drive modes available for both the drivetrain and chassis: normal—suitable for daily driving; sport—offering enhanced precision; and Sport+—intensifying the characteristics of the sport mode. The DB11 has a near-perfect weight distribution of 51 per cent at the front and 49 per cent at the rear. According to the magazine Motor Trend, the DB11 has a combined fuel economy figure of 17 miles per US gallon (14 L/100 km; 20 mpg‑imp). According to Auto Express, the car has a CO2 emission rating of 270 g/km. The doors of the DB11, like the DB9, are swan-hinged. The infotainment system operates on an eight-inch liquid-crystal display accessed via a rotary controller or an optional touchpad. Each DB11 comes with a 400-watt audio system, USB playback, SiriusXM satellite radio, and a Wi-Fi hotspot with iPhone integration. Upgrades were available for a 700-watt sound system or a 1,000-watt Bang & Olufsen unit. The DB11 has a boot capacity of 270 litres (9.5 cu ft). The AE31 twin-turbocharged V12 engine, with a 5,204 cc displacement, was featured in the initial version of the DB11. It produces a power output of 600 bhp at 6,500 rpm and a torque output of 700 Nm (520 lb/ft) between 1,500–5,000 rpm, sufficient to give the car a zero to 60 mph (97 km/h) acceleration of 3.6 seconds and a maximum speed of 200 miles per hour (320 km/h). Aston Martin began the development of the V12 engine in the summer of 2012 under the leadership of Brian Fitzsimons. The project progressed quickly; initial test firing began in October 2012, and it received approval for production in January 2013. The new V12 engine continues to use conventional fuel injection rather than direct injection due to concerns about the potential increase in particulate emissions associated with direct injection petrol engines. The DB11 V12 can run the quarter mile in 11.7 seconds. In May 2018, Aston Martin introduced the DB11 Aston Martin Racing (AMR) version, which succeeded the DB11 V12. The DB11 AMR offers enhanced performance capabilities compared to its predecessor. The previous DB11 V12 had been in production for eighteen months. The updated DB11 AMR produces a power output of 630 bhp at 6,500 rpm and a torque output of 700 Nm (520 lb/ft) at 1,500 rpm, sufficient to give the car a zero to 60 mph (97 km/h) acceleration of 3.7 seconds and a maximum speed of 208 mph (335 km/h). Its shift programming has been revised, its rear suspension is firmer and stiffer, and its twenty-inch forged wheels are 3.5 kilograms (7.7 lb) lighter. Aston Martin introduced a limited edition of 100 DB11 AMR Signature Edition cars at the beginning of production, featuring a Stirling Green paint scheme with lime green accents. It has a zero to 60 mph (97 km/h) acceleration of 3.5 seconds—0.2 seconds faster than the base AMR. Deliveries started in the second quarter of 2018. In July 2021, Aston Martin announced that the AMR name would no longer be used for the V12-powered DB11 as part of their updated model lineup. The original V12 model was supplemented by an entry-level V8 version in June 2017. Powered by a 4.0-litre Mercedes-Benz M177 twin-turbocharged V8 engine developed by Mercedes-AMG, this configuration achieves a weight reduction of 115 kilograms (254 lb) compared to the V12 variant, resulting in a total kerb weight of 1,760 kilograms (3,880 lb). In contrast to the V12 model, the DB11 V8 has a weight distribution of 49 per cent at the front and 51 per cent at the rear. The V8 engine delivers 503 bhp and 675 Nm (498 lb/ft), providing the car with a zero to 60 mph (97 km/h) in four seconds and a top speed of 187 mph (301 km/h). In July 2021, Aston Martin revealed an upgraded version of the DB11 V8. The power output was increased to 528 bhp, allowing the car to accelerate from zero to 60 mph (97 km/h) in 3.9 seconds and reach a higher top speed of 192 miles per hour (309 km/h). In October 2017, Aston Martin introduced the DB11 Volante, a convertible version of the DB11. The Volante has a weight distribution of 47 per cent at the front and 53 per cent at the rear, and is powered by the same 4.0-litre twin-turbocharged V8 engine as the DB11 V8 coupe, albeit with more torque, at 696 Nm (513 lb/ft). The DB11 Volante can accelerate from zero to 60 mph (97 km/h) in 4.1 seconds and possesses a maximum speed of 187 mph (301 km/h). The additional lower body strengthening and the electric roof mechanism in this version increase the weight by approximately 110 kilograms (240 lb). The DB11 received mostly positive reviews. Production of the DB11 ended at the end of June 2023. It was replaced by the DB12, which was unveiled at the 2023 Cannes Film Festival.
AUDI
The B5 generation RS4 was a rather special car. This dates from an era when Audi only produced one RS model at a time, meaning that the variant had quite a short production life. Introduced by Audi in late 1999, for main production and sale from 2000, this was effectively the successor to the Porsche / quattro GmbH joint venture-developed Audi RS2 Avant that was sold in the mid 1990s. Like its RS2 predecessor, it was available only as an Avant. Although related to the Audi B5 S4, many of the outer body panels were altered, with wider front and rear wheel arches, to allow for the wider axle track on the RS 4. With unique front and rear bumpers and side sills, and the rear spoiler from the S4 Avant, the aerodynamic modifications achieved a drag coefficient of Cd 0.34 and a very purposeful look, especially when finished in a sober colour such as the two examples seen here. It was the mechanical changes, though, which had the huge difference. The engine was developed from the 2.7 litre V6 ‘biturbo’ used in the B5 S4, and retained the same 2,671 cc capacity, but much was changed. Developed and manufactured in the UK by Cosworth Technology, it featured enlarged intake and smaller exhaust ports on the two Cosworth cast aluminium alloy cylinder heads, two parallel BorgWarner turbochargers, two larger side-mounted intercoolers, dished piston crowns, stronger connecting rods, larger intake ducting, enlarged exhaust system, and a re-calibrated engine management system. The modifications increased the engine’s output from 265 bhp to 375 bhp at 7,000 rpm, and with 325 lb/f·ft of torque. The engine was controlled by a Bosch Motronic ME 7.1 electronic engine control unit (ECU), using a Bosch ‘E-Gas’ electronic drive by wire throttle. The engine had multipoint sequential fuel injection, a MAF, six individual single-spark coils and NGK longlife spark plugs. The engine oil was cooled by a dual oil:water cooler and an oil:air cooler. There was a 6 speed manual transmission and Audi’s Torsen-based quattro system. Even with a kerb weight of 1,620 kilograms (3,571 lb), the RS 4’s powerful engine gave it the performance of a sports car. 100 km/h could be reached from rest in 4.9 seconds, 160 km/h in 11.3 seconds, and 200 km/h in 17.0 seconds. Top speed was electronically limited to 262 km/h(162.8 mph) Audi produced 6,030 units between 1999 and 2001. Many have suggested that these B5 generation Audis are a future classic and maybe that time is now here. Perhaps I should have hung onto mine?
CADILLAC
The Eldorado was radically redesigned for 1967 as a front-wheel drive hardtop coupe, becoming Cadillac’s entry in the era’s burgeoning personal luxury car market. Promoted as a “personal” Cadillac, it shared the E-body with the second-generation Buick Riviera and the first-generation Oldsmobile Toronado, which had been introduced the previous year. To enhance its distinctiveness, Cadillac adapted the Toronado’s front-wheel drive unified powerplant package, mating a Cadillac 429 V8 to a Turbo-Hydramatic 425 automatic transmission. Front disc brakes were optional, and new standard safety equipment included an energy absorbing steering column and generously padded instrument panel. The 1967 Eldorado was a great departure from previous generations, which shared styling with Cadillac’s De Ville and Series 62. GM styling chief Bill Mitchell chose angular, crisp styling for the Eldorado, setting it apart from more streamlined Riviera and Toronado. The rear end design was inspired by the GM-X Stiletto concept car. It was the first and only Cadillac model with the headlamps concealed behind moveable covers; this feature was for two years only (1967 and 1968). Rear passenger windows retracted sideways into the C-pillar instead of down into the side body panel. The Eldorado achieved 0-60 mph (0–97 km/h) acceleration in less than nine seconds, and a top speed of 120 mph (190 km/h). Roadability and neutral handling were highly praised by contemporary reviews, and sales were excellent despite high list prices. Its sales of 17,930 units, nearly three times the previous Eldorado high, helped give Cadillac its best year ever. In 1968, the 429 V8 was replaced by the new 472 (7.7 L) V8 with SAE gross 375 hp and 525 lb/ft (712 Nm) of torque. Despite the larger and more powerful engine, acceleration did not improve due to the reduction in final drive ratio from 3.21 to 3.07. Fuel consumption was 10 mpg (23.5 l/100 km) city and 13 mpg (18 l/100 km) highway. The hood was extended 4.5 inches longer in the rear as to conceal the windshield wipers. The previously optional front disc brakes became standard. The bumper-mounted front turn signal indicators and parking lights were repositioned to the fenders, replacing the end caps. The red side running lamps without retroreflective markers were attached to the rear fenders. The external rear view mirrors were enlarged and became rectangle-shaped with fixed housing and moveable mirror. Sales set another record at 24,528, with Eldorado accounting for nearly 11% of all Cadillac models sold. In 1969, the concealed headlamps were eliminated due to the new federal safety regulations stipulating that the headlamp covers must operate within a specific period of time when entering tunnels or darkened buildings (i.e. parking garages). Side impact protection beams were installed inside the doors. The dashboard and instrument cluster were redesigned: the dash cowl became more pronounced and contained all of the controls, driver’s side vents, and instrument clusters. On the passenger side, the vents were moved to the single horizontal rosewood veneer panel. The instrument clusters had a thin wood veneer panel where the warning lights are located. For 1970, the wood veneer was expanded to cover most of the instrument clusters. In 1970, the Eldorado featured the new Cadillac 500 V8 (8.2 L) V8 engine, putting out SAE gross 400 hp and 550 lb/ft (746 Nm). It was exclusive to the Eldorado until 1975, when it became the standard engine option for all Cadillac models except the Seville. The power sunroof by ASC and rear “Trackmaster” anti-lock braking system were offered as extra-cost options. Styling changes for 1970 included a new grille with scripted “Eldorado” and rectangular “8.2 LITRE” badges, and new taillamp bezels that eliminated the protruding “chrome fins”. The side running lamps included retroreflective markers, amber in the front and red in the rear.
CHEVROLET
The third generation Corvette, which was patterned after the Mako Shark II concept car, and made its debut for the 1968 model year, then staying in production until 1982. C3 coupes featured the first use of T-top removable roof panels. The C3 introduced monikers that were later revived, such as LT-1, ZR-1, Z07 and Collector Edition. In 1978, the Corvette’s 25th anniversary was celebrated with a two-tone Silver Anniversary Edition and an Indy Pace Car replica edition of the C3. This was also the first time that a Corvette was used as a Pace Car for the Indianapolis 500. Engines and chassis components were mostly carried over from the C2, but the body and interior were new. The 350 cu in (5.7 litre) engine replaced the old 327 cu in (5.36 litre) as the base engine in 1969, but power remained at 300 bhp. 1969 was the only year for a C3 to optionally offer either a factory installed side exhaust or normal rear exit with chrome tips. The all-aluminium ZL1 engine was also new for 1969; the special big-block engine was listed at 430-hp but was reported to produce 560 hp and propelled a ZL1 through the 1/4 mile in 10.89 seconds. There was an extended production run for the 1969 model year due a lengthy labour strike, which meant sales were down on the 1970 models, to 17,316. 1970 small-block power peaked with the optional high compression, high-revving LT-1 that produced 370 bhp. The 427 big-block was enlarged to 454 cu in (7.44 litre) with a 390 bhp rating. The ZR-1 special package was an option available on the 1970 through 1972 model years, and included the LT-1 engine combined with special racing equipment. Only 53 ZR-1’s were built. In 1971, to accommodate regular low-lead fuel with lower anti-knock properties, the engine compression ratios were lowered which resulted in reduced power ratings. The power rating for the 350 cu in (5.7 litre) L48 base engine decreased from 300 to 270 hp and the optional special high performance LT1 engine decreased from 370 to 330 hp. The big-block LS6 454 was reduced from 450 to 425 bhp, though it was not used in Corvettes for 1970; it was used in the Chevelle SS. For the 1972 model year, GM moved to the SAE Net measurement which resulted in further reduced, but more realistic, power ratings than the previous SAE Gross standard. Although the 1972 model’s 350 cu in horsepower was actually the same as that for the 1971 model year, the lower net horsepower numbers were used instead of gross horsepower. The L48 base engine was now rated at 200 bhp and the optional LT1 engine was now rated at 270 bhp. 1974 models had the last true dual exhaust system that was dropped on the 1975 models with the introduction of catalytic converters requiring the use of no-lead fuel. Engine power decreased with the base ZQ3 engine producing 165 bhp, the optional L82’s output 250 bhp, while the 454 big-block engine was discontinued. Gradual power increases after 1975 peaked with the 1980 model’s optional L82 producing 230 bhp. Styling changed subtly throughout the generation until 1978 for the car’s 25th anniversary. The Sting Ray nameplate was not used on the 1968 model, but Chevrolet still referred to the Corvette as a Sting Ray; however, the 1969 (through 1976) models used the “Stingray” name as one word, without the space. In 1970, the body design was updated including fender flares, and interiors were refined, which included redesigned seats, and indication lights near the gear shift that were an early use of fibre optics . Due to government regulation, the 1973 Corvette’s chrome front bumper was changed to a 5 mph system with a urethane bumper cover. 1973 Corvettes are unique in that sense, as they are the only year where the front bumper was polyurethane and the rear retained the chrome two-piece bumper set. 1973 was also the last year chrome bumpers were used. The optional wire-spoked wheel covers were offered for the last time in 1973. Only 45 Z07 were built in 1973. From 1974 onwards both the front and rear bumpers were polyurethane. In 1974, a 5-mph rear bumper system with a two-piece, tapering urethane bumper cover replaced the Kamm-tail and chrome bumper blades, and matched the new front design from the previous year. 1975 was the last year for the convertible, (which did not return for 11 years). For the 1976 models the fibreglass floor was replaced with steel panels to provide protection from the catalytic converter’s high operating temperature. 1977 was last year the tunnelled roof treatment with vertical back window was used, in addition leather seats were available at no additional cost for the first time. The 1978 25th Anniversary model introduced the fastback glass rear window and featured a new interior and dashboard. Corvette’s 25th anniversary was celebrated with the Indy 500 Pace Car limited edition and a Silver Anniversary model featuring silver over gray lower body paint. All 1979 models featured the previous year’s pace car seats and offered the front and rear spoilers as optional equipment. 53,807 were produced for the model year, making 1979 the peak production year for all versions of the Corvette. Sales have trended downward since then. In 1980, the Corvette received an integrated aerodynamic redesign that resulted in a significant reduction in drag. After several years of weight increases, 1980 Corvettes were lighter as engineers trimmed both body and chassis weight. In mid-1981, production shifted from St. Louis, Missouri to Bowling Green, Kentucky, and several two-tone paint options were offered. The 1981 models were the last available with a manual transmission until well into the 1984 production run. In 1982, a fuel-injected engine returned, and a final C3 tribute Collectors Edition featured an exclusive, opening rear window hatch.
This is an example of the fourth generation Corvette to bear the name. It was the first complete redesign of the Corvette since 1963. Production was to begin for the 1983 model year but quality issues and part delays resulted in only 43 prototypes for the 1983 model year being produced that were never sold. All of the 1983 prototypes were destroyed or serialised to 1984 except one with a white exterior, medium blue interior, L83 350 ci, 205 bhp V8, and 4-speed automatic transmission. After extensive testing and modifications were completed, it was initially retired as a display sitting in an external wall over the Bowling Green Assembly Plant’s employee entrance. Later this only surviving 1983 prototype was removed, restored and is now on public display at the National Corvette Museum in Bowling Green, Kentucky. It is still owned by GM. On February 12, 2014, it was nearly lost to a sinkhole which opened up under the museum. Regular fourth generation production began on January 3, 1983; the 1984 model year and delivery to customers began in March 1983. The 1984 model carried over the 350 cu in (5.7 litre) L83 slightly more powerful (5 bhp) “Crossfire” V8 engine from the final 1982 third generation model. New chassis features were aluminium brake calipers and an all-aluminium suspension for weight savings and rigidity. The new one piece targa top had no centre reinforcement. A new electronic dashboard with digital liquid crystal displays for the speedometer and tachometer was standard. Beginning in 1985, the 230 bhp L98 engine with tuned port fuel injection became the standard engine. September 1984 through 1988 Corvettes offered a Doug Nash designed “4+3” transmission – a 4-speed manual coupled to an automatic overdrive on the top three gears. It was designed to help the Corvette meet U.S. fuel economy standards. Since 1981, when it was last offered, a manual transmission returned to the Corvette starting with production in late-1984. The transmission proved to be problematic and was replaced by a modern ZF 6-speed manual transmission in 1989. In 1986, the second Corvette Indy Pace Car was released. It was the first convertible Corvette since 1975. A Centre High Mounted Signal Light – a third centre brake light – was added in 1986 to comply with safety regulations. While the colour of the pace car used in the race was yellow, all 1986 convertibles also had an Indy 500 emblem mounted on the console, making any colour a “pace car edition”. In 1987, the B2K twin-turbo option became available from the factory. The Callaway Corvette was a Regular Production Option (RPO B2K). The B2K option coexisted from 1990 to 1991 with the ZR-1 option, which then replaced it. Early B2Ks produced 345 bhp and 450 lb·ft later versions boasted 450 bhp and 613 lb·ft .1988 saw the 35th Anniversary Edition of the Corvette. Each of these featured a special badge with an identification number mounted next to the gear selector, and were finished with a white exterior, wheels, and interior. In 1991, all Corvettes received updates to the body, interior, and wheels. The convex rear fascia that set the 1990 ZR-1 apart from the base model was now included on L98 Corvettes, making the styling of the expensive ZR-1 even closer to that of the base cars. The most obvious difference remaining between the base and ZR-1 models besides the wider rear wheels was the location of the CHMSL, which was integrated into the new rear fascia used on the base model, but remained at the top of the rear-hatch on the ZR-1’s. For the 1992 model year, the 300 bhp LT1 engine was introduced, an increase of 50 bhp over 1991’s L98 engine. This engine featured reverse-flow cooling (the heads were cooled before the block), which allowed for a higher compression ratio of 10.5:1. A new distributor was also debuted. Called “Optispark”, the distributor was driven directly off the front of the camshaft and mounted in front of the timing cover, just above the crankshaft and harmonic balancer. Also new for 1992 was Acceleration Slip Regulation (ASR), a form of traction control which utilised the Corvette’s brakes, spark retard, and throttle close-down to prevent excessive rear wheel spin and possible loss of control. The traction control device could be switched off if desired. A special 40th Anniversary Edition was released in 1993, which featured a commemorative Ruby Red colour, 40th anniversary badges, and embroidered seat backs. The 1993 Corvette also marked the introduction of the Passive Keyless Entry System, making it the first GM car to feature it. Production of the ZR-1 ended in 1995, after 6,939 cars had been built. 1996 was the final year of C4 production, and featured special models and options, including the Grand Sport and Collector Edition, OBD II (On-Board Diagnostics), run flat tyres, and the LT4 engine. The 330 bhp LT4 V8 was available only with a manual transmission, while all 300 bhp LT1 Corvettes used automatic transmissions. Chevrolet released the Grand Sport (GS) version in 1996 to mark the end of production of the C4 Corvette. The Grand Sport moniker was a nod to the original Grand Sport model produced in 1963. A total of 1,000 GS Corvettes were produced, 810 as coupes and 190 as convertibles. The 1996 GS came with the high-performance LT4 V8 engine, producing 330 bhp and 340 lb·ft . The Grand Sport came only in Admiral Blue with a white stripe down the middle, and black wheels and two red stripes on the front left wheel arch.
FERRARI
It was with the 360 Modena that sales of Ferrari models really took off, with unprecedented volumes of the car being sold. The 360 Modena was launched in 1999, named after the town of Modena, the birthplace of Enzo Ferrari. A major innovation in this all new model came from Ferrari’s partnership with Alcoa which resulted in an entirely new all-aluminium space-frame chassis that was 40% stiffer than the F355 which had utilised steel. The design was 28% lighter despite a 10% increase in overall dimensions. Along with a lightweight frame the new Pininfarina body styling deviated from traditions of the previous decade’s sharp angles and flip-up headlights. The new V8 engine, common to all versions, was of 3.6 litre capacity with a flat plane crankshaft, titanium connecting rods and generates 400 bhp Despite what looks like on paper modest gains in reality the power to weight ratio was significantly improved on over the F355, this was due to the combination of both a lighter car and more power. The 0 to 100 km/h acceleration performance improved from 4.6 to 4.3 seconds. The first model to be rolled out was the 360 Modena, available as a manual, or an F1 electrohydraulic manual. Next up was an open car. The 360 was designed with a Spider variant in mind; since removing the roof of a coupe reduces the torsional rigidity, the 360 was built for strength in other areas. Ferrari designers strengthened the sills, stiffened the front of the floorpan and redesigned the windscreen frame. The rear bulkhead had to be stiffened to cut out engine noise from the cabin. The convertible’s necessary dynamic rigidity is provided by additional side reinforcements and a cross brace in front of the engine. Passenger safety is ensured by a strengthened windscreen frame and roll bars. The 360 Spider displays a curvilinear waistline. The fairings imply the start of a roof, and stable roll bars are embedded in these elevations. Due to use of light aluminium construction throughout, the Spider weighs in only 60 kg heavier than the coupé. As with the Modena version, its 3.6 litre V8 with 400 bhp is on display under a glass cover. The engine — confined in space by the convertible’s top’s storage area — acquires additional air supply through especially large side grills. The intake manifolds were moved toward the center of the engine between the air supply conduits in the Spider engine compartment, as opposed to lying apart as with the Modena. In terms of performance, the 0-60 mph time was slightly slower at 4.4 seconds due to the slight weight increase, and the top speed was reduced from 189 to 180 mph. Despite the car’s mid-mounted V8 engine, the electrically operated top is able to stow into the compartment when not in use. The convertible top was available in black, blue, grey and beige. The transformation from a closed top to an open-air convertible is a two-stage folding-action that has been dubbed “a stunning 20 second mechanical symphony”. The interior of the Spider is identical to that of the coupé.
The Ferrari F12berlinetta (Type F152) is a front mid-engine, rear-wheel-drive grand tourer which debuted at the 2012 Geneva Motor Show, and replaces the 599 grand tourer. The naturally aspirated 6.3 litre Ferrari V12 engine used in the F12berlinetta has won the 2013 International Engine of the Year Award in the Best Performance category and Best Engine above 4.0 litres. The F12berlinetta was named “The Supercar of the Year 2012” by car magazine Top Gear. The F12berlinetta was replaced by the 812 Superfast in 2017.
FORD
The Ford Escort RS Cosworth is a sports derivative and rally homologation special of the fifth generation European Ford Escort. It was designed to qualify as a Group A car for the World Rally Championship, in which it competed between 1993 and 1998. It was available as a road car from 1992–96 in very limited numbers. Ford developed the car around the chassis and mechanicals of its spiritual predecessor, the Sierra Cosworth to accommodate the larger Cosworth engine and transmission, whilst clothing it in Escort body panels to make it resemble the standard car. Designed under the guidance of Rod Mansfield and John Wheeler of Ford’s SVO department, the styling was carried out during 1989, a year before the standard Escort was launched, by Stephen Harper at MGA Developments in Coventry. The spoiler was added by Frank Stephenson, who originally proposed a three-deck piece. The body tooling was created by coachbuilders Karmann at their facility in Rheine, Germany, where the cars were manufactured. Changes were made to the engine management system and a new turbocharger was fitted. Permanent four wheel drive with a 34/66% front/rear split came courtesy of an uprated five speed gearbox as used in the Sierra Cosworth. Recaro sports seats came as a standard fitment. Later production models were available without the oversize tail spoiler although by far the majority were still ordered with it. Like its Sierra predecessor, they are commonly nicknamed “Cossie” by enthusiasts. The car’s top speed was 150 mph, which rivalled lower-end supercars including the Audi Quattro, BMW M3, Nissan 300ZX and Toyota Supra, and comfortably outperformed traditional “hot hatchbacks” like the Volkswagen Golf GTI. It was much faster than the 126 mph which the Escort RS2000 and earlier Escort RS Turbo were capable of. Two versions were produced. The initial 2,500 units were “homologation specials” used to get the FIA accreditation for entry into the World Rally Championship. They were fitted with a Garrett T3/T04B turbocharger. Among these initial units, a handful were badged as Motorsport versions, these lacked certain refinements such as a sunroof and sound deadening. The initial cars included features that, although they made the Cosworth a more effective car, did not enhance it as a road vehicle, and once the rules were satisfied Ford attempted to make the car less temperamental and easier to drive under normal conditions. The second generation, starting production from late 1994, were fitted with a Garrett T25 turbocharger, a smaller unit which reduced turbo lag and increased usability in everyday driving situations. With these later models, the ‘whale tail’ spoiler became a delete option. . The Escort Cosworth was a rare car, with 7,145 vehicles produced from the start of production on 19 February 1992 until the last car rolled out of the factory on 12 January 1996.
HYUNDAI
Recently released to market is the Ioniq 5N, a performance version of the family-sized Ioniq 5, and a car that was been praised as a truly fun car to drive. Spectacularly fast, too!
JAGUAR
Few would have guessed that the XJS would run for over 20 years, but eventually it came time for its replacement, and the car charged with so doing was the XK8. Development began in 1992, with design work having starting earlier, in late 1991. By October 1992 a design was chosen and later frozen for production in 1993. Prototypes were built from December 1993 after the X100 was given formal approval and design patents were filed in June 1994. Development concluded in 1996, at which point the car was launched. The first-generation XK series shares its platform with the Aston Martin DB7, and both cars are derived from the Jaguar XJS, though the platform has been extensively changed. One of the revisions is the use of the second generation of Jaguar’s independent rear suspension unit, taken from the XJ40. The XK8 was available in coupé or convertible body styles and with the then new 4.0-litre Jaguar AJ-V8 engine. In 1998 the XKR was introduced with a supercharged version of the engine. 2003 the engines were replaced by the 4.2-litre AJ34 engines in both the normally aspirated and supercharged versions. Equipment levels were generous and there was a high standard of fit and finish. Both models came with all-leather interior, burl walnut trim, and side airbags. Jeremy Clarkson, during a Top Gear test-drive, likened the interior of the original XK8 to sitting inside Blenheim Palace. The model ran for 10 years before being replaced by the X150 model XK.
LOTUS
In 1987, a new version of the mid-engined Esprit was unveiled, incorporating rounder styling cues given by designer Peter Stevens (who later designed the McLaren F1). A new Lotus patented process was introduced to create the new body, called the VARI (Vacuum Assisted Resin Injection) process, which offered more advantages than the previous hand laid process. Kevlar reinforcement was added to the roof and sides for roll-over protection, resulting in an increase of the Esprit’s torsional rigidity by 22 percent. Giugiaro is said to have liked the restyling, claiming it was perhaps too close to his original design. The Stevens styled cars retained the mechanical components of the previous High Compression Esprit and Turbo Esprit, but introduced a stronger Renault transaxle, which necessitated a move to outboard rear brakes. However, the MY 1988 North American Esprit Turbo kept its Citroën SM type transaxle and the Bosch K-Jetronic fuel injection system used in the previous model year. The car’s Type 910 engine retained 215 bhp and 220 lb·ft, but decreased its zero to sixty from 5.6 seconds to a varied time between 5.4 – 5.1 seconds and a top speed of over 150 mph. The exterior style changes were accompanied by a redesign of the interior, allowing a little more space for the occupants. The Stevens styled Esprit is often known by its project code of X180. In 1989, the Esprit was again improved with the GM multi-port, electronic fuel injection system and the addition of a water to air intercooler, which Lotus has named the Chargecooler, producing the SE (Special Equipment). This inline-four engine was known as the Type 910S. Horsepower was pushed up to 264 with 280 available on overboost and zero to sixty miles per hour times reduced to 4.7 seconds with a top speed of over 160 mph. Several modifications were made to the body kit as well, like side skirts which are parallel to the body, five air ducts in the front air dam, wing mirrors from the Citroën CX and the addition of a rear wing. Along with the SE, Lotus produced the little seen Esprit S, a midrange turbocharged car offering fewer appointments and 228 hp, as well as the standard turbo still offering 215 hp . The N/A and lower-powered turbo were cancelled after 1990, and the S in 1991. Another unusual variant was a two-litre “tax special” developed for the Italian market, fitted with an intercooled and turbocharged version of a new 1,994 cc version of the venerable 900-series four-cylinder engine. Equipped with SE trim, this appeared in December 1991 and produced 243 PS at 6,250 rpm. Beginning in the autumn of 1996, this engine became available in other markets as well. The Esprit was a popular and successful addition to the American IMSA Bridgestone Supercar Championship and as a result Lotus produced the SE-based X180R, with horsepower bumped to 300 and with racing appointments. The Sport 300 was a derivative of the X180R sold in Europe, which included many modifications. These are known as the fastest of the four-cylinder Esprits and among the most desirable. In 1993, another exterior and interior revamp of the car resulted in the S4 which was the first model to include power steering. The exterior redesign was done by Julian Thompson, which included a smaller rear spoiler placed halfway up the rear decklid. Other major changes were to the front and rear bumpers, side skirts and valence panels. New five spoke alloy wheels were also included in the redesign. The S4 retained the same horsepower as the SE at 264 hp.The S4 was succeeded in 1994 by the S4s (S4 sport), which upped power to 300 bhp and 290 lb·ft of torque, improving all-around performance while retaining the comfort of the previous version. Top speed was increased to 168 mph, skidpad increased to 0.91g, an increased slalom of 61.7 mph and a 0-60 mph time of 4.6 seconds. Although the engine kept its 2.2-litre capacity, many modifications were added to improve engine performance. Some of the changes were enlarged inlet ports, cylinder head modifications, a re-calibrated ECM and a revised turbocharger. The most visible external styling changes was the addition of a larger rear wing taken from the Sport 300. In 1996 the Esprit V8 used Lotus’ self-developed all-aluminium, twin-turbocharged (Garrett T25/60 turbos) 90-degree V-8, Code-named Type 918, in front of the same Renault transmission as before with no Chargecooler. Derek Bell developed an uprated gearbox that overcame a lot of the gearbox problems with a much thicker single piece input shaft. The Type 918 engine was detuned from a potential 500 bhp to 350 bhp to prevent gearbox damage due to the fragility of the Renault UN-1 transmission. In period tests, zero to sixty miles per hour came in at 4.4 seconds and top speeds of over 175 mph were achieved. Produced alongside V8 models was the GT3, a turbocharged four-cylinder car with the type 920 2.0 litre chargecooled and turbocharged engine which had been used only in Italian market cars previously. In 1998 the V8 range was split into SE and GT specifications, both cars with a much changed interior configuration, both offering similar performance with the SE being the more luxurious of the two. The ultimate incarnation of the Esprit came in 1999 with the Sport 350. Only 50 were made, each offering 350 horsepower (per the name) and various engine, chassis and braking improvements, like the addition of AP Racing brakes, stiffer springs and a revised ECU. Several visual changes were made as well, including the addition of a large carbon fibre rear wing on aluminium uprights in place of the standard fibreglass rear wing. By this time the Esprit could reach 60 mph in 4.3 seconds as well as reaching 0-100 mph in less than 10 seconds, and weighed 1,300 kg (2,866 lb) as a result of many modifications. Thereafter, Lotus made little development aside from minor cosmetic changes including a switch to four round tail lights for the 2002 model year. Esprit production ceased in February 2004 after a 28 year production run. A total of 10,675 Esprits were produced.
MASERATI
Sole Maserati here was my recently acquired Grecale, a car that you still don’t see very often, despite the fact that UK sales started a year ago.
MAZDA
Mazda introduced rotary-powered vehicles in 1971, beginning with the R100 and eventually introduced the RX-2, RX-3, RX-4, RX-5, and three generations of the RX-7 sports car in the US and worldwide markets. However, due to the lack of conveniences and user-friendliness, coupled with the high price tag and declining interest in sports cars and coupés at the time, Mazda decided to withdraw the RX-7 from most major markets except Japan. After 1995, Mazda suffered from a relatively undistinguished and ordinary product line in the US except for the MX-5 Miata. As popular interest in import tuning and performance cars resurged in the late-1990s due in part to various popular cultural influences, Japanese automakers waded back into the performance and sports car market in the US and in worldwide markets. In addition, Mazda endeavoured to rejuvenate itself around this time, partially with financial and management assistance from its new owner Ford, and successfully developed a new product line of high quality cars with desirable styling and superior driving dynamics compared to their competitors, beginning with the Mazda6 and followed by the Mazda3, paving the way for the arrival of Mazda’s next-generation rotary powered sports car. The RX-8 combined two previous products (the internationally sold RX-7, and the Cosmo which was exclusive to Japan), with the exterior dimensions of the RX-8 to be slightly smaller than those of the Cosmo. Mazda chose not to install the 2.0 L three-rotor 20B-REW, which was discontinued in 1996 when the Cosmo ceased production. In Japan, sales were affected by the fact that the RX-8 did not comply with Japanese Government’s dimension regulations, and Japanese buyers were liable for yearly taxes for driving a larger car. The rotary engine had financial advantages to Japanese consumers in that the engine displacement remained below 1.5 litres, a significant determination when paying the Japanese annual road tax which kept the obligation affordable to most buyers, while having more power than the traditional inline engines. The development of the RX-8 can be traced as far back as the 1995 RX-01 concept car, which featured an early iteration of the 13B-MSP engine. Naturally aspirated with side exhaust ports, this engine has a power output of 210 bhp Because of Mazda’s financial position at the time and the growing market interest in SUVs, the RX-01 did not see further development or production. However, a “skunkworks project” engineering team within Mazda kept the development of the 13B-MSP alive using an elongated MX-5 chassis known internally as “gokiburi-ka”, or “cockroach car” translated to English, eventually catching the attention of management, which was by then heavily influenced by Ford. Development of the 13B-MSP advanced and eventually led to the RENESIS name debuting along with the RX-EVOLV concept car which began to bear semblance to the production version of the RX-8 with the “freestyle” rear suicide doors. The styling was further refined, in Mazda tradition, by competition between its design studios in Japan, the US, and Europe. The lead designer was Ikuo Maeda, the son of Matasaburo Maeda (the lead designer of the original RX-7). The project obtained official approval from management under one condition, that the resulting car should have four doors, and eventually the RX-8 concept car (design/engineering model) was produced and shown in 2001, closer resembling the production version. A near-production “reference exhibit” RX-8 was shown shortly thereafter at the 2001 Tokyo Motor Show, pending final approval for production. The production version of the RX-8 closely resembles this vehicle save for minor trim details, and “Job 1” began in February, 2003 at Mazda’s Hiroshima plant in Japan. The RX-8 was designed as a front mid-engine, rear-wheel-drive, four-door, four-seater quad coupé. The car has a near 50:50 front-rear weight distribution and a low polar moment of inertia, achieved by mounting the engine behind the front axle and by placing the fuel tank ahead of the rear axle. The front suspension uses double wishbones and the rear suspension is multi-link. Weight is trimmed through the use of materials such as aluminium and plastic for several body panels. The rest of the body is made of steel, except for the plastic front and rear bumpers. The manual gearbox model uses a carbon fibre composite driveshaft to reduce the rotational mass (momentum of inertia) connected to the engine. Power is sent to the rear wheels through a torque-sensing conical limited-slip differential for improved handling. While under-powered in comparison to the final variant of the RX-7, the RX-8 is considered its successor as Mazda’s rotary engine sports car. A prominent feature of the RX-8 is its rear-hinged “freestyle” doors (similar to suicide doors) that provide easier access to the rear seats. The RX-8 has no B-pillars between the front and rear doors, but the leading edge of the rear door acts as a “virtual pillar” to maintain structural rigidity. Because of the overlapping design, the rear doors can be opened only when the front doors are open. The RX-8’s cabin was designed to allow enough room to house four adults, making it a genuine 4-seater rather than a 2+2. In designing the RX-8, Mazda’s engineers were able to achieve a chassis stiffness rating of 30,000 The earlier models of the RX-8, having chassis codes SE3P, and JM1FE, were produced from the 2003 model year, though the car’s U.S. debut was for the 2004 model year. It is powered by the RENESIS 13B-MSP (2-rotor, multi-side-port) Wankel engine displacing 1.3 L (1,308 cc). The 4-port standard RENESIS was rated at 191 bhp and was coupled with either a 5-speed manual or 4-speed automatic transmission. The 6-port high power RENESIS was only available with a six-speed manual transmission and was rated at 238 bhp. For the North American market, Mazda revised the reported output rating of the standard and high power RENESIS soon after launch to 189 bhp and 237 bhp, respectively.With exhaust ports now located in the side housing, the RENESIS boasted improved fuel efficiency and emissions rating over the 13B-REW employed by the preceding RX-7, thereby making it possible to be sold in North America. At launch, the RX-8 was available in various models in different markets around the world. The variations according to different markets are as follows: 6-speed manual with a claimed output of 232 bhp at 8,250 rpm and 159 lb⋅ft (216 Nm) of torque at 5,500 rpm with a 9,000 rpm (redline limited) (Sold in North America). This model was equivalent to the “Type S” trim in Japan; 5-speed manual with engine tuned to 189 bhp with the redline reduced to 7,500 rpm. This powertrain combination was not available in North America; 6-speed automatic with manual paddle shifting option (introduced in the U.S. for the 2006 model year, replacing the 4-speed automatic transmission of 2004–2005) with the engine rated at 212 bhp and 159 lb/ft (216 Nm) of torque with a redline at 7,500 rpm. This was the revised standard RENESIS, now with two extra intake ports like the high power version. The 2006 automatic RX-8 model also was given a second oil cooler, as was standard in the manual transmission model. Automatic versions all had lower output/lower rpm engines due to the lack of availability of a transmission that would be able to reliably cope with the engine’s high rpm limits. In 2003 Mazda announced a factory Mazdaspeed Version of the RX-8 exclusively in Japan. Based on the Type S and tuned by Mazda’s in-house division Mazdaspeed, the car included both mechanical, suspension, and aerodynamic improvements over the standard RX-8’s. Mazdaspeed RX-8’s were considered the highest performance model of the pre-facelift RX-8. Mechanical and suspension improvements included a new performance exhaust system, upgraded spark plugs, grounding kit, lightweight flywheel, re-balanced eccentric shaft, performance brake pads, stiffer anti roll bars, four point front strut tower brace, rear strut tower brace, as well as a set of height and damping force adjustable coil-overs. Mazdaspeed also redesigned the aerodynamics of the car, giving it a new front bumper, with enlarged venting and oil cooler ducting, as well as side skirts, rear under spoiler, and a rear wing. The Mazdaspeed RX-8 was offered in either Strato Blue Mica, or Sunlight Silver Metallic as exclusive colours. A total of 480 factory Mazdaspeed Version RX-8’s were built, and had a suggested retail price of JP¥3,650,000.00. Mazda also sold Mazdaspeed accessories worldwide through their dealerships. These accessories included both parts that weren’t equipped on factory Mazdaspeed RX-8’s as well as nearly all the parts equipped on the factory Mazdaspeed Version. This allowed standard RX-8’s to be upgraded to Mazdaspeed standards through dealerships around the world. In November 2008, Mazda improved the RX-8 body rigidity through the addition of structural reinforcements, by adding a trapezoidal shock tower brace and enhancing the local rigidity of the front suspension tower areas. The rear suspension geometry was revised for better handling, and the final-drive-gear ratio on manual transmission cars was shortened from 4.444 to 4.777 for improved off-the-line performance. While minimal, these changes gave the updated RX-8 increased acceleration and performance. Mazda engineers claimed that the 2nd generation RX-8 was (slightly) faster than the previous generation due to the lower gearing and improved suspension. The Renesis II engine iteration that was launched in the 2009 model year included a third oil injection port in each rotor housing to feed oil to the middle of the rotor facing, making this their first all-new EMOP (Electric Metering Oil Pump) with a total of 6 lubrication injectors, plus an all-new engine oil pump with higher pressure rating that requires specific oil filter rated for the higher pressure. New catalytic converter was used to reduce clogging that resulted in overheating exhaust stream forward of the catalytic converter and eventual rotor side seal failure, which was responsible for majority of RX-8 engine failures. Ignition coil packs, which suffer reduced performance over time and leads to unburnt fuel and oil that eventually clogs the catalytic converter, was not upgraded from series 1 RX-8. Due to higher usage cycle that is two to three times higher in Wankel compared to Otto cycle, ignition coil packs on RX-8 can degrade much sooner than Piston engines using similar hardware, and cause unburnt fuel to reach the catalytic converter, clogging it and cause engine overheating leading to side seal springs failure. The updated RX-8 also received design enhancements that were meant to freshen the styling and give the RX-8 a new look, without impairing the basic design theme. Refinements for the 2009 model year included a more aggressive restyled front and rear bumper as well as a new front fascia. The updated RX-8 also came with sporty, high-quality finish front and rear headlamps as well as larger exhaust pipes (now measuring 90 mm (3.5 in) across). The 2009 RX-8 also offered a new five-spoke wheel design featuring a symbolic and sporty design reminiscent of the rotary engine, with different arrangements for each wheel size. A rear spoiler was also added dependent on the trim level selected. There were three trims available to consumers from 2009 to 2012: Sport, Grand Touring, and R3. European production ended in 2010 when the car could no longer meet emissions standards.
MERCEDES-BENZ
The R170 Mercedes-Benz SLK-Class is the first generation of the Mercedes-Benz SLK-Class range of compact luxury roadsters produced by Mercedes-Benz between 1996 and 2004. SLK stands for the company’s design mission to create a sportlich (sporty), leicht (light) and kurz (compact) roadster, and is based on a shortened platform of the W202 Mercedes C-Class. The R170 Mercedes SLK is based on the SLK I Concept and SLK II Concept, which is a two-seater roadster concept car that features a folding metal electro-hydraulic roof, dubbed ‘vario-roof’ by Mercedes, and takes 25 seconds to operate. A German design patent was filed on 30 September 1993, with the final production version of the SLK introduced at the Turin Motor Show on 22 April 1996. The R170 SLK is based on the W202 C-Class platform, sharing many drivetrain and chassis components, as well as using a shortened version of the floor pan. The wheelbase is also identical to the wheelbase of the 190SL and 300SL, at 2,400 mm (94 in). The platform of the R170 Mercedes SLK is also used by the Chrysler Crossfire, which shares 80% of its components with the car. The SLK 200 was exported and sold exclusively to Italy, Netherlands, Portugal, Turkey, and Greece, and was only available with the Getrag five-speed manual transmission in most countries. After the 2000 facelift, the SLK 200 Kompressor was introduced to the worldwide market, replacing the SLK 200. The SLK 32 AMG was introduced in 2001, designed to rival the BMW M Roadster and Porsche Boxster S. The car featured the same M112 engine as in the SLK 320, but has a helical twin-screw supercharger and water-to-air intercooler. The SLK 32 AMG introduced Mercedes’ new ‘SpeedShift’ 5G-Tronic (automatic) transmission, that allow for manual shifting of the gears, and faster automatic downshifts before overtaking. There was no manual transmission option available for the SLK 32 AMG. The SLK 32 AMG features a more angular steering wheel, AMG instrument dials, an updated front and rear bumper with larger air intakes, and larger brakes; from 300 mm (12 in), upgraded to 334 mm (13 in) in diameter. SLK 32 production started from January 2001, to March 2004. A total of 4,333 were produced; 979 were sold in Germany, 2,056 were imported to the US, and 263 to the UK. It was replaced by the Mercedes R171 SLK in 2004.
MG
In mid 2001, an MG version of the 45 had been launched, called the ZS, which gave MG a range of 3 different models as well as the TF sports car. The view of the press was that the suspension and steering alterations completely transformed the car, but this model was in a difficult part of the market, compared to the smaller ZR and is found fewer buyers. Those who did sample the ZS, especially in ZS 180 guise with the 2.5 litre KV6 got an absolutely cracking car though. It sported a V6 with all the aural benefits when all its rivals had 4 cylinder turbo engines. Later cars were facelifted to distinguish them more clearly from the Rover 45, with elements of the X Power bodykit being made standard.
MITSUBISHI
This is a Lancer Evo VI, of the type which was produced between January 1999 and February 2001. Based on the Lancer saloon, the Evo kept pace with changes to that model, so the Evo IV, seen in 1996 had been a new model compared to the first three Evo generations. Evo IV, V and VI were all broadly similar with detailed changes coming with each new iteration. The Evolution VI’s changes mainly focused on cooling and engine durability. It received a larger intercooler, larger oil cooler, and new pistons, along with a titanium-aluminide turbine wheel for the RS model, which was a first in a production car. The Evolution VI received new bodywork yet again, with the most easily noticeable change being within the front bumper where the huge fog lights were reduced in size and moved to the corners for better airflow. A new model was added to the GSR and RS lineup; known as the RS2, it was an RS with a few of the GSR’s options. Another limited-edition RS was known as the RS Sprint, an RS tuned by Ralliart in the UK to be lighter and more powerful with 330 hp. Yet another special edition Evolution VI was released in December 1999: the Tommi Mäkinen Edition, named after Finnish rally driver Tommi Mäkinen who had won Mitsubishi four WRC drivers championships. It featured a different front bumper, Red/Black Recaro seats (with embossed T. Mäkinen logo), 17″ Enkei white wheels, a leather Momo steering wheel and shift knob, a titanium turbine that spooled up more quickly, front upper strut brace, lowered ride height (with tarmac stages in mind), and a quicker steering ratio. Amongst other colours, the Evo VI came in either red (Tommi Mäkinen Edition only), white, blue, black or silver with optional special decals, replicating Tommi Mäkinen’s rally car’s colour scheme. This car is also sometimes referred to as an Evolution 6½, Evolution 6.5, or TME for short. There were two “standard” models. The RS – “rally sport” had a close-ratio 5-speed, minimal interior, rally suspension, Rear 1.5 Way LSD as opposed to AYC, (Shortened close-ratio 5-speed transmission, Optional Enkei Wheels, Optional Recaro Seats, Optional Air Conditioner, Optional Brembo brakes, Optional power windows). The GSR came with a 5-speed, gauge pack, AYC (Active Yaw Control), Anti-Lock Braking System, Recaro front bucket and rear seat, auto air-conditioner, double-din audio, power windows, Brembo brakes. The Tommi Mäkinen Edition Models also came in RS and GSR guise. The RS was the same as the standard RS with close-ratio 5-speed, lowered ride height, Tommi Mäkinen Edition front bumper, and titanium turbine (same option with standard RS) and the GSR was the same as the standard GSR with lowered ride height, Tommi Mäkinen Edition front bumper, Red/Black Recaro seats (with embossed T. Mäkinen logo), 17″ Enkei white wheels and titanium turbine. These cars were fearsomely expensive to run, and as such, you don’t see them very often any more.
PORSCHE
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.
SHELBY
This is a replica Shelby Daytona Coupe, an American sports-coupé, related to the Shelby Cobra roadster, loosely based on its chassis and drive-train developed and built as an advanced evolution. It was engineered and purpose built for auto racing, specifically to take on Ferrari and its 250 GTO in the GT class. The original project had six Shelby Daytona Coupes built for racing purposes between 1964 and 1965, as Carroll Shelby was reassigned to the Ford GT40 project to compete at the 24 Hours of Le Mans, again to beat Ferrari in the highest level prototype class. With the Shelby Daytona, Shelby became the first American constructor to win a title on the international scene in the FIA International Championship for GT Manufacturers in 1965. In 2014, the first Cobra Daytona Coupe became the first vehicle recorded under a U.S. federal program for documenting historically important national treasures. During 1964 and 1965, Ford entered their six Shelby Daytona Coupes in numerous races through the British Alan Mann Racing Ford factory team, as well as temporarily selling or leasing to other racing teams such as “Tri-Colore” of France and Scuderia Filipinetti of Switzerland. Just the six cars were built, but in 2015, Shelby announced that they would build a continuation series of a further 50 cars. Even these are exceedingly rare, so when you see one, it is almost certainly going to be a replica model, like this one.
SUBARU
Now heading towards 30 years old are the first generation Impreza Turbo models. There have been seven noted versions of the WRX dating back from Subaru’s original World Rally Cross staging vehicles. Subaru adopted the name “WRX” to stand for “World Rally eXperimental” as all WRX versions (1992 to present) feature rally inspired technology, including all wheel drive, stiffened suspensions and turbocharged four cylinder engines. The STi versions were marketed with consecutive numbers. Another way to determine the version of a WRX was to look at the chassis code. All WRX sold between 1992 and 2000 have the beginning chassis code of GC8 2/4 door sedan or GF8 hatchback; this is followed by a letter from A to G. Coupe versions share the “GC” code with sedans, except in the US, where they have a separate chassis code of “GM”. In 1994, Subaru introduced Subaru Tecnica International (STi badged) versions of the WRX in Japan. These models were upgraded from the standard WRX in many categories, including blueprinted performance-tuned engines, transmissions, and suspensions. The STi versions of the WRX were immensely successful in rallies and popular among street racers but were only sold in the Japanese market. Compared to the WRX, the STi had mostly mechanical modifications. (STi prepped Subaru rally cars since 1988 including the Legacy RS, the WRX STi Version was just the first car with an actual STi badge, though with handcrafted tuning). The WRX debuted in November 1992 with 240 PS. The centre differential was a viscous coupling type, the rear limited slip differential was a viscous type. The WRX Type RA is a stripped down version of the WRX that was available in the Japanese market for people to purchase for motorsports and tuning. Targeted for race and rally, the RA versions were generally lighter in weight; featuring reduced soundproofing, manual windows, car horn delete, no air conditioning, no anti-lock brakes, and added racing features such as more robust engines, 5th injection, intercooler water spray and shorter gearing. The WRX Type RA uses a closer ratio gearbox and a three-spoke leather steering wheel from Nardi. The ra model chassis code between GC8-(000000 to 005000) are only sold to the race team by order. Close ratio transmission is anticipated race use, the gap between each gear is brought closer together and a specific close ratio transmission is used. In Europe, the WRX was introduced as the Impreza GT, and as the Impreza Turbo 2000 (UK). It came with 208 hp. A bewildering array of different versions would follow until the release of the second generation Impreza in 2000. This is one of those, an RB5. To celebrate the return of British driver Richard Burns to the rally team, a limited edition of 444 Turbo 2000 “RB5” models in grey were created in 1999 for the UK. The basic model had little more than cosmetic differences, but most had the WR Sport Performance Pack, an option consisting of a new ECU and exhaust for 240 PS (237 bhp) and 350 Nm (258 lb/ft) torque. There was also an optional Prodrive suspension pack.
TOYOTA
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 Nm (137 lb/ft) 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.
The third-generation MR2 was marketed as the Toyota MR-S in Japan, Toyota MR2 Spyder in the US, and the Toyota MR2 Roadster in Europe. Also known as the Midship Runabout-Sports, the newest MR2 took a different approach than its predecessor, most obviously becoming a convertible and receiving the ‘Spyder’ marketing nomenclature. The first prototype of MR-S appeared in 1997 at the Tokyo Motor Show. The MR2 Spyder chief engineer Harunori Shiratori said, “First, we wanted true driver enjoyment, blending good movement, low inertia and light weight. Then, a long wheelbase to achieve high stability and fresh new styling; a mid-engine design to create excellent handling and steering without the weight of the engine up front; a body structure as simple as possible to allow for easy customizing, and low cost to the consumer.” The only engine available for the ZZW30 was the all-aluminium alloy 1ZZ-FED, a 1.8 litre Inline-four engine. Like its predecessors, it used DOHC and 4 valves per cylinder. The intake camshaft timing was adjustable via the VVT-i system, which was introduced earlier on the 1998 MR2 in some markets. Unlike its predecessors, however, the engine was placed onto the car the other way round, with the exhaust manifold towards the rear of the car instead of towards the front. The maximum power of 138 bhp at 6,400 rpm and 126 lb/ft (171 Nm) of torque at 4,400 rpm was quite a drop from the previous generation, but thanks to the lightness of the car it could still move quite quickly, accelerating from 0 to 100 km/h (62 mph) in 6.8 to 8.7 seconds depending on the transmission option, the Sequential Manual being unable to launch and shift as quickly as the clutch operated manual. Curb weight is 996 kg (2,195 lb) for manual transmission models. In addition to the 5-speed manual transmission, a 6-speed manual or 5-speed Sequential Manual Transmission (SMT) was also available starting in 2002. The SMT was a standard feature in Australian market; however, air conditioning was optional. After 2003, a 6-speed SMT was an option. The SMT had no conventional H-pattern shift lever or clutch pedal. The driver could shift gears by tapping the shift lever forward or backward or by pressing steering-wheel mounted buttons. Clutch engagement is automatic, and the car will automatically shift to second and then first gear when stopping. Cruise control was never offered with the manual transmission, but was standard for SMT-equipped cars. The MR2 Spyder featured a heated glass rear window. A hard top was also available from Toyota in Japan and Europe. Production ended in 2007 and there was no direct successor.
This Supra is from the fourth generation of the model, known as the A80. Design work began in February 1989 under various teams for design, product planning, and engineering. By the middle of 1990, a final A80 design concept from Toyota Technical Centre Aichi was approved and frozen for production in late 1990. The first test mules were hand-built in A70 bodies during late 1990, followed by the first A80 prototypes being hand-assembled in 1991. Again using subframe, suspension, and drivetrain assemblies from the Z30 Soarer (Lexus SC300/400), test model pre-production started in December 1992 with 20 models, and official mass production began in April 1993. This redesign saw Toyota placing great emphasis on a more serious high-performance car. The new Supra was completely redesigned, with rounded body styling and featured two new engines: a naturally aspirated Toyota 2JZ-GE producing 220 hp at 5800 rpm and 210 lb/ft at 4800 rpm of torque and a twin turbocharged Toyota 2JZ-GTE making 276 hp and 318 lb·ft of torque for the Japanese version. The styling, while modern, does seem to borrow some elements from Toyota’s first grand touring sports car, the Toyota 2000GT. For the export model (America/Europe) Toyota upgraded the Supra turbo’s engine which increased the power output to 320 hp at 5600 rpm and 315 lb/ft at 4000 rpm. The turbocharged variant could achieve 0–60 mph in as low as 4.6 seconds and 1/4-mile in 13.1 seconds at 109 mph. The turbo version was tested to reach over 285 km/h (177 mph), but the cars were restricted to just 180 km/h (112 mph) in Japan and 250 km/h (155 mph) elsewhere. The twin turbos operated in sequential mode, not parallel. Initially, all of the exhaust is routed to the first turbine for reduced lag. This resulted in boost and enhanced torque as early as 1800 rpm, where it already produced 300 lb/ft (410 Nm) of torque. At 3500 rpm, some of the exhaust is routed to the second turbine for a “pre-boost” mode, although none of the compressor output is used by the engine at this point. At 4000 rpm, the second turbo’s output is used to augment the first turbo’s output. Compared to the parallel mode, sequential mode turbos provide quicker low RPM response and increased high RPM boost. This high RPM boost was also aided with technology originally present in the 7M-GE in the form of the Acoustic Control Induction System (ACIS) which is a way of managing the air compression pulses within the intake piping as to increase power. For this generation, the Supra received a new 6-speed Getrag/Toyota V160 gearbox on the turbo models while the naturally aspirated models made do with a 5-speed manual W58, revised from the previous version. Each model was offered with a 4-speed automatic with manual shifting mode. All vehicles were equipped with 5-spoke aluminium alloy wheels, the naturally aspirated model had 16″ rims and the turbo models were 17″. The difference in wheel size was to accommodate the larger brakes equipped as standard onto the turbo model, but in Japan were optional extras. Both models had a space saver spare tire on a steel rim to save both space and weight. Toyota took measures to reduce the weight of this new model. Aluminium was used for the hood, targa top (when fitted), front crossmember, oil and transmission pans, and the suspension upper A-arms. Other measures included hollow carpet fibres, magnesium-alloy steering wheel, plastic gas tank and lid, gas injected rear spoiler, and a single pipe exhaust. Despite having more features such as dual airbags, traction control, larger brakes, wheels, tyres, and an additional turbo, the car was at least 200 lb lighter than its predecessor. The base model with a manual transmission had a curb weight of 3,210 lb (1,460 kg). The Sport Roof added 40 lb while the automatic transmission added 55 lb. It had a 51:49 (front:rear) weight distribution. The turbo model weighed 3,450 lb (1,560 kg) for the manual, automatic added another 10 lb (4.5 kg). Weight distribution was 53% front/47% rear. The Supra was heavier than the spartan Mazda RX-7 and all aluminium bodied Acura/Honda NSX, but it was lighter than the Mitsubishi 3000GT VR-4. The Supra soon became something of a legend, establishing itself as an effective platform for drifting in Japan, and for roadracing, with several top 20 and top 10 One Lap of America finishes in the SSGT1 class. Despite its curb weight, in 1994 the A80 managed remarkable skidpad ratings of 0.95 lateral g’s (200 ft) and 0.98 lateral g’s (300 ft), and the car has proved popular even as it ages in the UK, with several “grey market” cars having been brought here over the years.
TVR
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 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.
VOLKSWAGEN
Needing no introduction, all these years later, is this example of the classic Beetle.
This is “Eeyore”, an example of the Type 2 “Bus”, the second generation of VW’s versatile van range, first seen in late 1967. It was built in Germany until 1979. In Mexico, the Volkswagen Kombi and Panel were produced from 1970 to 1994. Models before 1971 are often called the T2a (or “Early Bay”), while models after 1972 are called the T2b (or “Late Bay”). This second-generation Type 2 lost its distinctive split front windshield, and was slightly larger and considerably heavier than its predecessor. Its common nicknames are Breadloaf and Bay-window, or Loaf and Bay for short. At 1.6 litres and 47 bhp DIN, the engine was also slightly larger. The battery and electrical system was upgraded to 12 volts, making it incompatible with electric accessories from the previous generation. The new model also did away with the swing axle rear suspension and transfer boxes previously used to raise ride height. Instead, half-shaft axles fitted with constant velocity joints raised ride height without the wild changes in camber of the Beetle-based swing axle suspension. The updated Bus transaxle is usually sought after by off-road racers using air-cooled Volkswagen components. The T2b was introduced by way of gradual change over three years. The first models featured rounded bumpers incorporating a step for use when the door was open (replaced by indented bumpers without steps on later models), front doors that opened to 90° from the body, no lip on the front guards, unique engine hatches, and crescent air intakes in the D-pillars (later models after the Type 4 engine option was offered, have squared off intakes). The 1971 Type 2 featured a new, 1.6 litre engine with dual intake ports on each cylinder head and was DIN-rated at 50 bhp. An important change came with the introduction of front disc brakes and new roadwheels with brake ventilation holes and flatter hubcaps. Up until 1972, front indicators are set low on the nose rather than high on either side of the fresh air grille – giving rise to their being nicknamed “Low Lights”. 1972’s most prominent change was a bigger engine compartment to fit the larger 1.7- to 2.0-litre engines from the Volkswagen Type 4, and a redesigned rear end which eliminated the removable rear apron and introduced the larger late tail lights. The air inlets were also enlarged to accommodate the increased cooling air needs of the larger engines. In 1971 the 1600cc Type 1 engine as used in the Beetle, was supplemented with the 1700cc Type 4 engine – as it was originally designed for the Type 4 (411 and 412) models. European vans kept the option of upright fan Type 1 1600 engine but the 1700 Type 4 became standard for US spec models. In the Type 2, the Type 4 engine, or “pancake engine”, was an option for the 1972 model year onward. This engine was standard in models destined for the US and Canada. Only with the Type 4 engine did an automatic transmission become available for the first time in the 1973 model year. Both engines were 1.7 L, DIN-rated at 66 bhp with the manual transmission and 62 bhp with the automatic. The Type 4 engine was enlarged to 1.8 L and 67 bhp DIN for the 1974 model year and again to 2.0 L and 70 bhp DIN for the 1976 model year. The two-litre option appeared in South African manufactured models during 1976, originally only in a comparably well-equipped “Executive” model. The 1978 2.0 L now featured hydraulic valve lifters, eliminating the need to periodically adjust the valve clearances as on earlier models. The 1975 and later U.S. model years received Bosch L-Jetronic electronic fuel injection as standard equipment; 1978 was the first year for electronic ignition, utilising a hall effect sensor and digital controller, eliminating maintenance-requiring contact-breaker points. As with all Transporter engines, the focus in development was not on power, but on low-end torque. The Type 4 engines were considerably more robust and durable than the Type 1 engines, particularly in Transporter service. In 1972, exterior revisions included relocated front turn indicators, squared off and set higher in the valance, above the headlights. Also, square-profiled bumpers, which became standard until the end of the T2 in 1979, were introduced in 1973. Crash safety improved with this change because of a compressible structure behind the front bumper. This meant that the T2b was capable of meeting US safety standards for passenger cars of the time, though not required of vans. The “VW” emblem on the front valance became slightly smaller. Later model changes were primarily mechanical. By 1974, the T2 had gained its final shape. Very late in the T2’s design life, during the late 1970s, the first prototypes of Type 2 vans with four-wheel drive (4WD) were built and tested.
Conceived as a replacement for the popular Beetle Cabrio, and at the time unique in the market place, a convertible version of the Golf was presented to Volkswagen’s management by coachbuilder Wilhelm Karmann GmbH as early as 1976. This early prototype lacked the roll-over bar of the later version, and had a flat body line in the rear, where the soft top folded down below the sill level. The production version of the convertible Golf was designated Type 155. In Europe and Canada it was called the Golf Cabriolet, while in the United States it was sold as the Rabbit Convertible until 1985, when it was also renamed “Cabriolet”. The Cabriolet was sold from 1980 to 1993. It had a reinforced body, a transverse roll-over bar, and a high level of trim. From stamping to final assembly the Mk1 Cabriolet was built entirely at the Karmann factory. Volkswagen supplied engines, suspension, and interior trim for Karmann to install. The tops, of vinyl or cloth, were heavily insulated, with a heated glass rear window. The top was raised and lowered manually until 1991, when it became electrically operated. The body of the Cabriolet did not change through the entire production run except for a larger fuel tank. It kept the pre-1980 style of rear lamp clusters. A space saver spare wheel was fitted from the outset, including 1978 pre-production models, unlike the saloon which did not adopt this until 1984. All Cabriolets from 1988 on left the factory fitted with a “Clipper” bodykit that featured smooth body-coloured bumpers, wheel-arch extensions, and side skirts. Prior to the 1984 model year the highest standard specification Cabriolet was the GLI, which was essentially a GTI in all but name. It was only in late 1983 with the introduction of the 1984 model that an officially badged GTI version of the cabriolet finally became available.
For reasons no-one could really work out, numbers were down on expectation for this event, which was a little disappointing, but is always more likely to happen mid-week than at weekends. But that did not detract from the enjoyment of the evening, as there were plenty of interesting cars to look at and more than enough people to talk to, so it really did not feel like I had been there for three hours, or so, even though I had, when the light started to fade and the cars had mostly gone. Let’s hope that there are evening events included in the 2025 QS program.
