The Jaguar XJ220 is a two-seat sports car produced by British luxury car manufacturer Jaguar from 1992 until 1994, in collaboration with the specialist automotive and race engineering company Tom Walkinshaw Racing. The XJ220 officially recorded a top speed of 212.3 mph (341.7 km/h) during testing by Jaguar at the Nardo test track in Italy. This made it the fastest production car from 1992 to 1993. According to Jaguar, an XJ220 prototype managed a Nürburgring lap time of 7:46:36 in 1991 which was lower than any production car lap time before it.
The XJ220 was developed from a V12-engined 4-wheel drive concept car designed by an informal group of Jaguar employees working in their spare time. The group wished to create a modern version of the successful Jaguar 24 Hours of Le Mans racing cars of the 1950s and '60s that could be entered into FIA Group B competitions. The XJ220 made use of engineering work undertaken for Jaguar's then current racing car family.
The initial XJ220 concept car was unveiled to the public at the 1988 British International Motor Show, held in Birmingham, England. Its positive reception prompted Jaguar to put the car into production; some 1500 deposits of £50,000 each were taken, and deliveries were planned for 1992.
Engineering requirements resulted in significant changes to the specification of the XJ220, most notably replacement of the Jaguar V12 engine by a turbocharged V6 engine. The changes to the specification and a collapse in the price of collectible cars brought about by the early 1990s recession resulted in many buyers choosing not to exercise their purchase options. A total of just 275 cars were produced by the time production ended, each with a retail price of £470,000 in 1992 making it one of the most expensive cars at that time.
Video Jaguar XJ220
Conception
Racing team owner Tom Walkinshaw approached Jaguar executives and encouraged to enter the Jaguar XJS into the 1981 European Touring Car Championship; they succeeded in winning the competition in 1984. Jaguar had started to provide factory support to racing team Group 44 Racing, who were using the Jaguar-engined XJR-5 in the IMSA GT Championship, supplying V12 engines from 1983 onwards and supporting a Le Mans entry in 1984. Tom Walkinshaw and Jaguar agreed to entering the FIA Group C World Sportscar Championship and developed the XJR-6, which was powered by the Jaguar V12 engine; the car was launched during the 1985 season.
TWR took over the IMSA GT Championship operation in 1988 and one model - Jaguar XJR-9 - was launched to compete in both series. The XJR-9, which retained the Jaguar V12 engine, went on to win the 1988 24 Hours of Le Mans and World Sportscar Championship in the same year. The poor fuel consumption of the Jaguar V12 combined with new rules restricting refueling during races forced the replacement of the V12 engine in the XJR-9s successors, the XJR-10 and XJR-11. The normally-aspirated Austin Rover V64V engine, designed for the MG Metro 6R4 had recently been made redundant thanks to the Group B rally ban in 1987, and the design rights were for sale. The compact, lightweight and fuel efficient nature of the small-displacement, turbocharged engine was investigated by TWR, who considered it an ideal basis for a new engine to power the XJR-10 and purchased the design rights from Austin Rover Group.
Jaguar and their Director of Engineering, Jim Randle, felt these racing cars were too far removed from the product available to the general public, especially with the rule changes that mandated the replacement of the Jaguar V12 engine in the forthcoming XJR-10 and XJR-11 racing cars. Therefore, a project was initiated to design and build a car capable of winning Le Mans "in house", just as the Jaguar C-Type and D-Type had done. The groundwork for the project was undertaken by Randle over Christmas 1987, when he produced a 1:4 scale cardboard model of a potential Group B racing car.
The cardboard model was taken into the Jaguar styling studio and two mock-ups were produced. One was said to be reminiscent of the Porsche 956, the other took elements of the then current Jaguar XJ41 project and Malcolm Sayer's work on the stillborn Jaguar XJ13 racing car. The second design, by Keith Helfet, was chosen as it was "more obviously Jaguar in its look".
The project still had no official support, leaving Randle no option but to put together a team of volunteers to work evenings and weekends in their own time. The team came to be known as "The Saturday Club", and consisted of twelve volunteers. To justify the resources consumed by the project, the XJ220 needed to provide meaningful data to the engineers on handling, aerodynamics - particularly at high speeds - and aluminium structures. These requirements, together with FIA racing regulations and various government regulations governing car design and safety influenced the overall design and engineering direction of the car.
Maps Jaguar XJ220
Concept car
The FIA Group B regulations steered the concept towards a mid-engine, all-wheel-drive layout, with a Jaguar V12 engine as the power source. The concept car was designed and built at very little cost to Jaguar, as Randle called in favours from component suppliers and engineering companies he and Jaguar had worked with in the past. In return he offered public recognition for their assistance and dangled the possibility of future contracts from Jaguar.
The name XJ220 was chosen as a continuation of the naming of the Jaguar XK120, which referred to the top speed of the model in miles per hour. The concept car had a targeted top speed of 220 mph (350 km/h) so became the XJ220. The XK120, like the XJ220, was an aluminium-bodied sports car, and when launched was the fastest production car in the world.
Engine and transmission
Jaguar's engine designer Walter Hassan had previously created a 48-valve variant of their V12 engine specifically for motorsport use. It featured a double overhead camshaft layout with four valves per cylinder, compared with the single overhead camshaft and two valves per cylinder of the production engine, which was used in the Jaguar XJ and Jaguar XJS models at the time.
TWR had manufactured a number of these racing V12 engines during the 1980s and they had been raced competitively, with a 7-litre version of this engine featuring in the Le Mans winning Silk Cut Jaguar XJR-9. Five of these engines still existed, all of which were fitted with dry sump lubrication. These engines were chosen and considered to be especially useful as the dry sump would lower the vehicle's centre of gravity. The displacement of the V12 was set at 6.2 litres (6222 cc) for the XJ220. The engine fitted to the XJ220 concept had titanium connecting rods.
Jaguar had little experience with four-wheel drive systems at the time, having previously only produced rear-wheel drive cars. Randle approached Tony Rolt's company, FF Developments to design the transmission and four-wheel drive system for the XJ220, with Rolt's son Stuart running the project. Tony Rolt was the Technical Director of Ferguson Research, where he was heavily involved in the design of the four-wheel drive system used in the Jensen FF, the first sports car to be fitted with such a transmission. Tony Rolt also had a long involvement with Jaguar, winning the 1953 24 Hours of Le Mans with the factory works team driving the Jaguar C-Type.
The mid-engine complicated the design of the four-wheel drive system, and an innovative solution was needed to get drive from the mid-mounted rear engine to the front wheels. The chosen design took the front-wheel drive from the central differential on the rear transaxle and sent it through the V in the centre of the engine using a quill drive, before joining an inverted differential. The clutch was a twin-plate unit designed by AP Racing.
Bodywork and interior
The design brief for the exterior restricted the use of aerodynamic aids, and aimed for a simple yet clean and functional body similar to classic Jaguars such as the E-Type and the D-Type. Drag and lift were limited at the envisioned ground clearance for road use, but the design allowed for additional downforce when the car was set up for racing; the body produced around 3,000 lb (1,400 kg) of downforce at 200 mph (320 km/h). The design was also intended to have a variable rear wing that folded into the bodywork at lower speeds. Aerodynamic work was undertaken at the Motor Industry Research Association wind tunnel using a 1:4 scale model, as the project was unable to budget for a full-scale mock-up.
The bodywork for the concept car displayed in 1988 was hand built from aluminium by Park Sheet Metal, a specialist automotive engineering company that manufactures concept cars and low-volume, niche models for various manufacturers, including Bentley. QCR Motors LTD undertook final painting of the bodyshell in silver. The concept also featured electrically operated scissor doors and a transparent engine cover to show off the V12 engine.
The concept car had a Connolly Leather-trimmed interior produced by Callow & Maddox, and was fitted with front and rear heated windscreens, electric windows, air conditioning, heated electrically adjustable seats with an Alpine CD player. The dashboard was supplied by Veglia.
Chassis
The chassis was manufactured from aluminium using Alcan's bonded aluminium structure vehicle technology (ASVT), and had a wheelbase of 2845 mm. The design for the chassis featured rear wheel steering and packaged the fuel tank behind the centre bulkhead. Suspension design largely focused on road use, but a good compromise for racing use was achieved and the suspension height was adjustable. The concept car was fitted with a four-channel anti-lock braking system.
The concept car was larger than the production model at 5,140 mm (202 in) in length and 2,000 mm (79 in) wide. It weighed 1,560 kg (3,440 lb).
Launch
The concept car was completed in the early hours of 18 October 1988, the day it was due to be unveiled at the British International Motor Show, being held at the National Exhibition Centre, Birmingham. The vehicle was completed at 03:00 GMT, moved to Jaguar's stand at 06:00 GMT and unveiled at 11:00 GMT.
Jaguar's marketing department had allocated space on their stand at the motor show for the XJ220, but had not seen the vehicle until its arrival. Jaguar chairman John Egan and Roger Putnam, who was in charge of Jaguar's racing activities, were shown the vehicle the week before the motor show and signed off on the concept, allowing its unveiling. The car received an overwhelmingly positive reception by public and press, and a number of wealthy Jaguar enthusiasts handed over blank cheques to secure a purchase option should the XJ220 concept go into production. Ferrari's display of their F40 model at the same event was overshadowed; an estimated 90,000 additional visitors came to see the Jaguar XJ220.
The XJ220 was not initially intended to be a production car, but, following the reception of the concept and financial interest from serious buyers, a feasibility study was carried out by teams from TWR and Jaguar. Its conclusion was that such a car would be technically feasible (subject to engineering changes), and that it would be financially viable. The announcement of a limited production run of 220 to 350 cars came on 20 December 1989. The list price on 1 January 1990 was £290,000 exclusive of value added tax, options and delivery charges, but by 1992 that had increased considerably owing to indexation of contracts. The offer was four times oversubscribed, and deposits of £50,000 exclusive of Value Added Tax (VAT) were taken from around 1400 customers; first deliveries were planned for mid-1992.
Production version
Jaguar were unable to develop the XJ220 in house as their engineering resources were committed to working on the Jaguar XJ and Jaguar XJS models; the re-engineered and facelifted XJS was launched in May 1991.
Jaguar and TWR had an existing joint venture, JaguarSport Ltd., formed in 1987 to produce racing cars. Jaguar's board made the decision that subject to contractual agreement, TWR and JaguarSport would be responsible for the XJ220. JaguarSport formed a new company, Project XJ220 Ltd., specifically to develop and build the XJ220.
The team that should determine the necessary engineering work and assess the car's financial viability was put in place during mid-1989, working from the TWR workshops. Mike Moreton headed the team, joining TWR to run the XJ220 project. Moreton came from Ford Motorsports where he led the team responsible for the Ford Sierra RS500 Cosworth, and was a project manager for the Ford RS200 Group B rally car program. Richard Owen was appointed chief designer, and the remainder of the team was made up of Jaguar and TWR staff, including Pete Dodd, the only member of the group of twelve responsible for the XJ220 concept. The exterior and interior designers who had worked on the XJ220 prototype, Keith Helfet and Nick Hull, rejoined the project when it became clear that more design work would be needed.
Development
The development team looked at the two principal competitors, the Ferrari F40 and the Porsche 959. These were powered by compact, lightweight engines; both the Ferrari and the Porsche used forced induction to obtain high power outputs from small-displacement engines. Ferrari used a 2.9-litre twin turbo V8 that produced 478 PS (352 kW; 471 hp) whilst Porsche used a 2.9-litre twin-turbo flat six producing 450 PS (331 kW; 444 hp), resulting in cars that were significantly lighter and smaller than the XJ220 concept: the Ferrari was lighter by 600 kg and 710 mm shorter, whilst the Porsche was 250 kg lighter and 870 mm shorter. The Porsche's specifications were closer to the Jaguar's, with four-wheel drive and a luxurious interior. By comparison the rear-wheel driven Ferrari had a very basic interior, with no carpets, door handles or a stereo.
Engine
The production XJ220 used a 3.5-litre (3498 cc) twin turbocharged V6 engine, which was given the designation Jaguar/TWR JV6. This engine, which replaced the Jaguar V12 engine featured in the concept car, was a heavily redesigned and significantly altered version of the Austin Rover V64V V6 engine. The decision to change the engine was based on engine weight and dimensions, as well as to environmental emission considerations. Use of the shorter V6 engine design allowed the wheelbase of the XJ220 to be shortened and its weight to be reduced; the V12 engine was definitively ruled out when it was determined it would have difficulty at simultaneously meeting emissions legislation and producing the required power and torque.
TWR purchased the rights to the V64V engine from Austin Rover in 1989 and developed a completely new turbocharged engine, codenamed JV6, under the auspices of Allan Scott, with proportions roughly similar to the V64V, and suitable for sports car racing. As the V64V was originally naturally aspirated, TWR needed to redesign all parts of the engine to accommodate forced induction. A few of the changes included increasing the displacement to 3.5 litres, strengthening the internals, and adding two Garrett TO3 turbochargers. The JV6 engine would first be used in the JaguarSport XJR-10 and XJR-11 racing cars; its compact dimensions and low weight made it an ideal candidate for the XJ220. The engine had a 90° bank angle, four valves per cylinder and belt-driven double overhead camshafts. It shares a number of design features with the Cosworth DFV Formula One engine.
The V64V engine chosen had a short but successful career as a purpose-designed racing car engine. It was designed by Cosworth engine designer David Wood for Austin Rover Group's Metro derived Group B rally car, the MG Metro 6R4. The redesign work necessary to create the Jaguar/TWR JV6 engine was undertaken by Andrew Barnes, TWR's Powertrain Manager, and also involved Swiss engine builder Max Heidegger who had designed and built the race engines used in the XJR-10 and XJR-11 racing cars.
The XJ220's engine had a bore and stroke of 94 mm × 84 mm (3.70 by 3.31 inches), dry sump lubrication, Zytek multi point fuel injection with dual injectors and Zytek electronic engine management. The engine was manufactured with an aluminium cylinder block, aluminium cylinder heads with steel connecting rods and crankshaft, and in the standard state of tune, it produced a maximum power of 550 PS (400 kW; 540 hp) at 7200 rpm and torque of 475 lb?ft (644 N?m) at 4500 rpm. The XJ220 can accelerate from 0-60 miles per hour in 3.6 seconds and reach a top speed of 212.3 miles per hour. Road & Track tested a top speed of 210.5 mph, 0-60 mph in 4.8 seconds and 12.4 seconds for the standing quarter mile.
The XJ220's exhaust system consists of two catalytic converters, which reduces the power output of the engine. During testing at the Nardò Ring in Italy one XJ220 had its catalytic converters removed and its rev limiter increased to 7,900rpm; these subtle modifications increased the car's power output by 50 bhp, and the car was then driven by 1990 Le Mans Winner Martin Brundle to a top speed of 217.1 miles per hour ; owing to the circular nature of the track, some (including the British car magazines Top Gear and Autocar) say a speed of 217 mph (349 km/h) is equivalent to 223 mph (359 km/h) on a straight, level road. However, on other tracks it performed differently; when top speed was tested on a straight level road by Road & Track it only reached 210.5 mph (338.9 km/h), it was slower than the Bugatti EB110 at the same event and the Ruf CTR there in 1987. The V64V engine had the additional benefit of being very economical for such a powerful petrol engine, according to Jaguar it was capable of achieving 32 mpg-imp (8.8 L/100 km; 27 mpg-US), in contrast, the smallest-engined Jaguar saloon of the time, the Jaguar XJ6 3.2 could only achieve around 24 mpg-imp (12 L/100 km; 20 mpg-US).
The Engine was manufactured and built at the new purpose built facility in Kidlington Oxford. TWR invested heavily in a state of the art machining facility capable of serviced all of its race and road car projects. The facility was initially setup to produce the XJ220 engine under the watchful eye of Simon Lockwood an Ex March Engineering suspension specialist. After the completion of the XJ220 the machining resources were used on other internal projects such as the Aston Martin DB7 Road Car, Volvo 850 Touring Car Race Series and many others.
Transmission
Four-wheel drive was decided against early in the development process, for a number of reasons. It was thought rear-wheel drive would be adequate in the majority of situations, that the additional complexity of the four-wheel drive system would hinder the development process and potentially be problematic for the customer. FF Developments were contracted to provide the gearbox/transaxle assembly, modifying their four-wheel drive transaxle assembly from the XJ220 concept into a pure rear-wheel drive design for the production car. A five-speed gearbox was fitted; a six-speed gearbox was considered but deemed unnecessary, as the torque characteristics of the engine made a sixth gear redundant. The transaxle featured a viscous coupling limited slip differential to improve traction.
The transmission system featured triple-cone synchromeshing on first and second gears to handle rapid starts, whilst remaining relatively easy for the driver to engage and providing positive feel.
AP Racing provided an 8.5 in (22 cm) diameter clutch.
Exterior
The exterior retained the aluminium body panels of the XJ220 concept, but for the production vehicles, Abbey Panels of Coventry were contracted to provide the exterior panels. The scissor doors were dropped for the production model, and significant redesign work was carried out on the design when the wheelbase and overall length of the car was altered. Geoff Lawson, Design Director at Jaguar took a greater interest in the car and insisted the design had to be seen to be a Jaguar if it was to be successful in promoting the company. Keith Helfet returned to undertake the necessary redesign work mandated by the change in the wheelbase, which was reduced by 200 mm. The turbocharged engine required larger air intakes to feed the two intercoolers. Situated between the doors and the rear wheels, the air intakes were larger on the production version of the XJ220 than on the concept car. A number of small design changes for the body were tested in the wind tunnel; the final version had a drag coefficient of 0.36 with downforce of 3,000 lb (1,400 kg) at 200 mph (320 km/h). The XJ220 was one of the first production cars to intentionally use underbody airflow and the venturi effect to generate downforce. Additionally, some XJ220's could be ordered with optional BBS style rims for improved brake ventilation and aesthetics.
The rear lights used on the production XJ220 were sourced from the Rover 200.
Chassis
The production model utilised the same Alcan bonded honeycomb aluminium structure vehicle technology (ASVT) as the concept car for the chassis. The chassis design featured two box section rails which acted as the suspension mounting points and would provide an energy absorbing structure in the event of a frontal impact, these were successfully tested at speeds up to 30 mph (48 km/h), an integral roll cage formed part of the chassis and monocoque, providing additional structural rigidity for the car and allowing the XJ220 to easily pass stringent crash testing.
The rear-wheel steering was dropped from the production car to save weight and reduce complexity, as was the height adjustable suspension and active aerodynamic technology. The suspension fitted to the production model consisted of front and rear independent suspension, double unequal length wishbones, inboard coil springs and anti-roll bars, with Bilstein gas-filled dampers. The suspension was designed in accordance with the FIA Group C specifications.
The braking system was designed by AP Racing and featured ventilated and cross-drilled discs of 13 in (33 cm) diameter at the front and 11.8 in (30 cm) diameter at the rear. The calipers are four pot aluminium units. JaguarSport designed the handbrake, which are separate calipers acting on the rear brake discs. Feedback from enthusiasts and racing drivers resulted in the decision to drop the anti-lock braking system from the production car. The braking system was installed without a servo, but a number of owners found the brakes to be difficult to judge when cold and subsequently requested a servo to be fitted.
Rack and pinion steering was fitted, with 2.5 turns lock to lock; no power assistance was fitted. The Bridgestone Expedia S.01 asymmetric uni-directional tyres were specially developed for the XJ220 and had to be rateable to a top speed in excess of 220 miles per hour (350 km/h), carry a doubling of load with the exceptionally high downforce at speed and maintain a compliant and comfortable ride. Rally alloy wheel specialists Speedline Corse designed the alloy wheels, these are both wider and have a larger diameter on the rear wheels; 17 inches (43 cm) wheels are fitted to the front and 18 inches (46 cm) are fitted at the rear, with 255/55 ZR17 tyres at the front and 345/35 ZR18 tyres at the rear.
Interior
The interior was designed for two passengers and trimmed in leather. Leather trimmed sports seats are fitted together with electric windows and electrically adjustable heated mirrors. The dashboard unusually curves round and carries onto the drivers door, with a secondary instrument binnacle containing four analogue gauges, including a clock and voltmeter fitted on the front of the drivers door. Air conditioning and green tinted glazing was also fitted.
The luggage space consists of a small boot directly behind and above the rear portion of the engine, also trimmed in leather.
Production
The car was assembled in a purpose-built factory at Wykham Mill, Bloxham near Banbury in Oxfordshire. HRH The Princess of Wales officially opened the factory and unveiled the first production XJ220 in October 1991.
The JV6 engines used in the Jaguar racing cars were produced by Swiss engineer Max Heidegger, but delivering the number of engines required for the XJ220 program was considered beyond his capacity. TWR formed a division, TWR Road Engines, to manage the design, development, construction and testing of the engines for the production cars. The JV6 engine used in the XJ220 featured little commonality with the engines Heidegger built for use in the XJR racing cars, being specifically engineered to meet performance and in particular, the European emissions requirements, which the race engines didn't have to meet.
FF Developments, in addition to their design work on the gearbox and rear axle assembly were given responsibility for their manufacture. The aluminium chassis components and body panels were manufactured and assembled at Abbey Panels factory in Coventry, before the body in white was delivered to the assembly plant at Bloxham. The car, including chassis and body components, consists of approximately 3000 unique parts.
The first customer delivery occurred in June 1992, and production rates averaged one car per day. The last XJ220 rolled off the production line in April 1994; the factory was then transferred to Aston Martin and used for the assembly of the Aston Martin DB7 until 2004.
Guinness World Record
Jaguar had performed high speed testing of the XJ220 at Fort Stockton, Texas and recorded a maximum speed of 212.3 mph (341.7 km/h), which made the XJ220 the fastest production car.
Jaguar hoped to reach 220 mph with the XJ220, mainly for promotional reasons. The decision was made to undertake further high speed testing in June 1992 at the Nardò Ring in Italy, with Jaguar taking journalists from Road & Track and Car magazines together with a film crew from BBC Top Gear. The XJ220 would be driven by Martin Brundle, who had won the 1990 24 Hours of Le Mans driving the Jaguar XJR-12.
The initial high speed runs, with the car configured in production specification (catalytic converters connected, lower rev-limit of 7400rpm) achieved a maximum recorded speed of 212.3 mph (341.7 km/h), the same speed as previously reached at Fort Stockton during testing. Brundle reported that the car was hitting the rev limiter during the run.
The rev limiter was increased to 7900rpm and the catalytic converters were removed for a second series of runs, and it was this attempt which resulted in the maximum recorded speed of 217.1 mph (349.4 km/h). The removal of the catalytic converters, though a modification, was considered acceptable as they were not mandated by environmental legislation in Europe at the time of the test runs; it was estimated that the removal of the catalytic converters increased the power output by around 50 PS (37 kW; 49 hp).
It was all done in an unstructured, unofficial way, more for the hell of it than for any meaningful reason. There were no independent witnesses - no Guinness Book of Records judge, for instance - apart from two journos (self and John Lamm from America's Road & Track), Dawson and a BBC cameraman who was recording the event for Top Gear and posterity. And none of us understood how the testing equipment worked. There was no minimum distance over which the speed had to be held, no attempt to repeat the feat in both directions to compensate for any wind, no hard-and-fast rules, no official laws or regulations. And, of course, taking off the cats instantly made the car non-standard, and thus non-production.
Guinness Book of World Records recorded the 217.1 mph run as the fastest ever attained by a standard production car, this figure was reported in the 1994 to 1999 editions of the Guinness Book of World Records, despite the issues highlighted by Gavin Green. Guinness World Records then recognised the McLaren F1 driven by Andy Wallace which achieved a maximum recorded speed of 240.1 mph (386.4 km/h) in March 1998 (also with rev-limiter increased).
Reception
Press coverage of the concept XJ220 in 1988 was overwhelmingly positive and contributed to the decision in 1989 to put the XJ220 into limited production. The production version of the car was first shown to the public in October 1991, at the Tokyo Motor Show. The first car was released for press review in autumn 1991.
Autocar's Andrew Frankel was the first journalist to road-test the car and reported: "Savage acceleration really is a given here. What's really incredible about the XJ220 is its ability to provide such performance in a way that never, ever intimidates." He was particularly impressed with the throttle response, the driver's ability to control the performance of the car very precisely, and the way in which the engine delivers its power progressively rather than in one short burst.
Performance Car reviewer John Barker was also impressed with the performance as well as the ride and stability of the car, writing "The V6 has a rumbly, loping note which, in league with a remarkably supple ride, belies the speed we are travelling at. I glance to the speedo and have trouble believing that it is indicating 170 mph." Barker was also impressed with the engineering, saying "this car is catalysed, fully homologated and has passed the same tests that a Volvo needs before going on sale," going on to discuss how the vehicle looked at home on the racetrack thanks to the design. Autocar's verdict was "Right now, the XJ220 gives us a standard by which all other fast cars can be compared. For the few who will actually own and, hopefully, use their XJ220s, the fact that they are in command of the most accomplished supercar ever made should suffice."
Ergonomics and ride were also praised by Gavin Green in CAR August 1992: "you sit straight ahead, pedals and four-spoked Nardi wheel beautifully positioned. There's none of the askew nonsense that plagues Italian supercars...forward visibility is panoramic and side vision is good. Rear vision is better than on some other mid-engined monsters." He went on to describe the ride: "The XJ220 rides over knobbly tarmac with extraordinary dexterity...the big Jag rides urban blacktop better than many sports saloons, never mind supercars."
In a comparison test published in the CAR March 1994 issue, the testers liked the "sheer blistering pace, looks and a superb cabin" but its size, the doors not opening far enough and handling were criticised: "If there's a more evil device on our roads, I wouldn't like to find it, for the XJ220 suffers from immense initial understeer followed by violent and snappy pendulous oversteer." Most disappointing was the engine, at idle it sounded "like someone's clanking a bucket of rusty nails together". While its rival, the Bugatti EB 110, impressed the testers, the XJ220 disappointed: "The Jaguar is outmoded and lacks soul: it looks like a cynical marketing exercise and feels it in its lack of purity and coherence."
Motoring journalists have been critical of its size, being too big for a two-seater with virtually no luggage space, too wide to fit through traffic restrictors or to drive comfortably on most roads. The very heavy unassisted steering and pedals, underwhelming brakes without ABS, poor directional stability and "terrible visibility" were also disliked. Most criticised was the behavior at low revs, the engine sound was described with words like "a pail of nuts and bolts being poured through a Magimix", rattling clutch, grinding transmission, crackling chassis, rumbling and groaning body contributing to the impression of imminent breakdown. Driving in the city was sheer torture, worsened by the first gear being far too tall for stop-and-go traffic.
Sales performance was disappointing. Jaguar had intended to produce up to 350 cars, but production ceased in 1994 with 281 production cars produced, not all of which had been sold; some left-hand drive examples were still available in 1997. The recession left many of those who placed a deposit unable to complete the purchase. The index linking of contracts exacerbated the issue, and added almost £200,000 to the purchase price between early 1990 and mid-1992. The McLaren F1 suffered from similarly poor sales performance, with just 71 cars sold against McLaren's target of 300. McLaren's F1 program eventually turned a small profit thanks to the sale and servicing of the 28 GTR racing variants produced.
The price of collectible cars collapsed as a result of the recession over the six-year period from 1989-94; for example, a highly collectible Ferrari 250 GTO sold for just $3.5 million in 1994, an $11.1 million loss from its sale price in 1989. The Jaguar XJ220 had attracted a significant number of speculators who hoped the scarcity of the XJ220 and enthusiasm for the Jaguar marque would push up prices overnight, allowing large profits to be made over a short period of time.
The market for supercars was growing when the production XJ220 was announced, with comparable cars immediately reselling after delivery for three and four times the list price. The Ferrari F40 had been selling for more than £800,000 in 1990, but like the XJ220 it was adversely affected by the recession, and by 1992 prices had dropped to between £100,000 to £150,000.
Further complicating the sales situation was the announcement by JaguarSport of a road-going version of the Jaguar XJR-9, the last of the racing cars to feature the Jaguar V12 engine. The Jaguar XJR-15 was developed by TWR and styled by Peter Stevens whilst the XJ220 was being developed at Jaguar, and featured the V12 engine and a host of other technologies not adopted for the XJ220, including carbon fibre construction and the option of a six-speed racing gearbox. It was considerably rarer and more expensive than the XJ220 when it went on sale; only 50 were built, each with a list price of £600,000 ($1 million) in 1990. It was designed primarily for racing but could be specified as a road-legal vehicle. About half were built as road-going variants, which added £55,000 to the list price.
Jaguar customers attempting to withdraw from their contracted purchases were given the option to buy themselves out of their contracts, but by 1995, the issue had resulted in legal action as buyers claimed the specification changes rendered any contracts void. Jaguar produced evidence clearly demonstrating that the vehicle specification shown in the contract matched the vehicle that was delivered, and the presiding judge, John Donaldson, quickly ruled in Jaguar's favour. The last of the unsold XJ220s were sold for £127,550 plus VAT in 1997. While never officially approved for sale in the United States, the XJ220 was approved under the Show and Display exemption by 2001.
The XJ220 appeared in later motoring press articles; Evo journalist David Vivian, writing a head-to-head test between the XJ220 and the Lamborghini Murcielago in 2009, commented that "going ludicrously fast seems trivially easy", and acknowledged that the decision to change the V12 engine for a turbocharged V6 engine "would garner more acceptance now". The Lamborghini delivered the far better driving experience however: "After the XJ220, it's almost absurdly agile", "the big difference, and it is massive, is how much more exciting, entertaining and accessible the LP640 is to drive."
Racing
A racing version was introduced at the 1993 Autosport International motor show; given the model name XJ220-C, it was built to compete in FISA GT racing. The XJ220-C driven by Win Percy won its first race, a round of the BRDC National Sports GT Challenge at Silverstone.
Three works XJ220-Cs were entered in the 1993 24 Hours of Le Mans race, in the newly created Grand Touring Class. John Nielsen, David Brabham and David Coulthard won the GT class, beating Porsche by two laps; the other two cars retired, both through engine failure. However, the class win was revoked when the Jaguar XJ220-C was controversially disqualified for failing to run with catalytic converters. The Jaguars had passed scrutiny and completed the first day of qualifying when senior steward Alain Bertaut complained that Jaguar were not running catalytic converters. The cars had been entered under the IMSA GT category and Bertaut claimed that they needed to run with catalysts. The cars ran in the race under appeal. International Motor Sports Association (IMSA) officials wrote to the Automobile Club de l'Ouest (ACO) (English: Automobile Club of the West), organisers of the 24 Hours of Le Mans, confirming that the XJ220s had complied with IMSA rules. Jaguar won their appeal (supported by the FIA) but were nevertheless disqualified, as the ACO confirmed that the appeal had not been lodged in time.
Four cars were entered in the GT1 class for the 1995 24 Hours of Le Mans, two by PC Automotive Jaguar and two by Chamberlain Engineering, though the latter did not run their cars. Neither team had Jaguar or TWR backing; both of PC Automotive's cars were outpaced by the new McLaren F1 GTR. Richard Piper, Tiff Needell and James Weaver were holding fourth position until an engine failure during the night, ending their race, whilst the second XJ220 retired after leaving the road.
An XJ220 was also used in the Italian GT Championship, although without factory support; it raced in Martini livery. The XJ220C was promoted in the United States in the-made-for-TV "Fast Masters" racing series at Indianapolis Raceway Park, airing on ESPN in the summer of 1993 and featuring invited drivers over 50 years old in an elimination format.
TWR developed a further six XJ220-S road cars, featuring one-piece carbon-fibre-reinforced polymer front and rear bodywork; the engine was tuned to 700 PS (510 kW; 690 hp). The XJ220-S models did away with the hidden headlamps of the original and instead opted for perspex covered lights. The S models were essentially road-going versions of the XJ220-C racer, and as a result featured a much simpler race-orientated interior with kevlar seats and the removal of the leather trim. Colin Goodwin, a writer for Autocar, tested an XJ220-S in June 1995 at Millbrook Proving Ground and set the lap record at an average speed of 180.4 mph (290.3 km/h).
Jaguar XJ220 Pininfarina
The Jaguar XJ220 Pininfarina is a special XJ220 built in 1995 for the Sultan of Brunei and his brother Prince Jefri, who commissioned a number of rare and one-off heavily modified cars based on expensive luxury cars. This car was modified by Pininfarina, with modifications including fixed headlights, new rear lights with a redesigned double-vane rear wing, and a new interior package. The car also comes with dark green exterior paint.
References
Notes
Citations
Bibliography
External links
- EVO documentary of XJ220 at the Nurburgring
- Autocar re-visits the XJ220 20 years after launch
Source of article : Wikipedia