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Tag: LaFerrari

IN THE NEWS: Ferrari Unveils FXX K at Ferrari Finale Mondiali

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Maranello, 3rd December 2014 – Ferrari’s new FXX K research and development programme receives its world premiere next weekend at the Yas Marina Circuit in Abu Dhabi. The laboratory-car is based on Maranello’s first hybrid model and will grace the world’s tracks from next year onwards. The K in its moniker is a reference to the “KERS” kinetic energy recovery system it adopts in maximising its track performance.

Unfettered by homologation and racing regulations, the FXX K will never be used in competition. It was, in fact, developed to be completely uncompromising, incorporating technological innovations that will guarantee an unprecedented driving experience to the exclusive group of Client-Test Drivers with whom the Prancing Horse will roll out a test programme over the coming two years.

The car’s enormous potential is attested to by two significant figures:  a total power output of 1050 cv (860 cv delivered by its conventional V12 engine and 190 by its electric motor) and maximum torque in excess of 900 Nm.

The FXX K’s 6262 cc V12 features new camshafts and a modified valve train with mechanical rather than hydraulic tappets. The intake manifolds have been redesigned and given a special type of polishing treatment. The exhaust system has been modified as its silencers have been eliminated.

The HY-KERS system has been evolved specifically for pure performance with the result that the driver can control the function logics from the specific 4-setting Manettino on the centre console: Qualify, for maximum performance within a limited number of laps; Long Run to optimise performance consistency; Manual Boost for instant maximum torque delivery; and Fast Charge, for a fast recharge of the car’s battery.

A focus on delivering maximum efficiency at every stage of every track lap has resulted in extensive but integrated work on the entire car body in terms of both active and passive aerodynamics.

The front of the car is dominated by a twin-profile spoiler and a larger splitter, which is 30 mm lower, with a gap in its centre. This design is an application of the concepts developed to improve aero balance in the GT category of the WEC, which Ferrari has won for three consecutive years.  Two pairs of vertical elements, an endplate and, externally, a dive plane, together with vertical fins channel the air towards the car’s flanks, generating a longitudinal vortex that creates a localised depression. This in turn sucks the wake from the wheels to the outside of the aerodynamic underbody. Along with the side skirts that extend out from the sills, the vortex helps isolate the airflow from the underbody to boost its efficiency.

The solutions on the rear of the car are highly sophisticated, too. The tail section is now higher and the mobile spoiler extends further for a total increase in extension of 60mm when fully deployed. A vertical fin and a small wing each side of the tail act as guide vanes in the low drag configuration and boost the spoiler’s efficiency in the high downforce one. This system also creates considerable downforce at the rear of the car, allowing the use of an extreme diffusion volume for the rear diffuser which optimises air extraction from the underbody.  The section of the flat underbody just ahead of the rear wheels is also exploited to the full to generate downforce thanks to the reduced pressure in the wheel arch guaranteed by the direct connection to the rear of the car by a by-pass duct.

The result is a 50% improvement in downforce in the low drag configuration and a 30% improvement in the more aggressive downforce configuration, resulting in a figure of 540 kg at 200 km/h.

Vehicle dynamics are further improved by the adoption of Pirelli slicks complete with sensors that monitor longitudinal, lateral and radial acceleration, as well as temperature and pressure. This ensures an accurate analysis of the interaction between the tyre and track surface, providing even more vital data to enable the traction control system to guarantee maximum performance.

The intervention level of the E-Diff electronic differential, F1-Trac traction control, Racing SSC (Side Slip Angle Control) – now specially calibrated to suit the car’s slick tyres – and the high-performance ABS can be controlled using the five-position Manettino on the steering wheel.

IN THE NEWS: Porsche Unveils Pre-Production 918 Spyder

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Atlanta.The 918 Spyder embodies the essence of the Porsche idea: it combines pedigree motor racing technology with excellent everyday utility, and maximum performance with minimum consumption. The task faced by the development team was to create the super sports car for the next decade with a highly efficient and powerful hybrid drive. Developing the car from scratch, appropriately beginning with a sheet of white paper, allowed the team to come up with a no-compromise concept. The entire car was designed around the hybrid drive. The 918 Spyder therefore demonstrates the potential of the hybrid drive to a degree never seen before: the parallel improvement of both efficiency and performance without one being at the cost of the other. This is the idea that has made the Porsche 911 the most successful sports car in the world for 50 years. In short, the 918 Spyder will act as the gene pool for the Porsche sports cars of the future.

The 918 Spyder reveals its close links to motorsport in a variety of ways. It has been designed, developed and produced by Porsche engineers who build race cars, in cooperation with series production specialists. A great deal of insight gained from the development of Porsche race cars for the 24 hours race in Le Mans in 2014 is thus integrated into the 918 Spyder – and vice versa. The structural concept of the 918 Spyder with a rolling chassis as its basis – a basic vehicle that can be driven even without a body – is race car tradition at Porsche. The concept of the V8 engine originates from the LMP2 RS Spyder race car. The load-bearing structures, the monocoque and subframe, are made of carbon fiber reinforced polymer. Porsche has many years of experience with this high-strength, lightweight construction material and has again achieved top results with the development of the series production 918 Spyder. Many parts of the super sports car come from manufacturers who have a proven record as suppliers for motorsport vehicles.

Hybrid drive brings advantages in terms of driving dynamics

A key message of the 918 Spyder is that the hybrid drive from Porsche is a plus for no-compromise driving dynamics. Drivers can experience this thanks to the unique all-wheel drive concept with a combination of combustion engine and electric motor on the rear axle and the second electric motor on the front axle. It is based on knowledge gained by Porsche during motor races with the successful 911 GT3 R Hybrid. Due to the additional, individually controllable front drive, new driving strategies for extremely high, safe cornering speeds can be implemented, especially for bends. Furthermore, the advanced “boost” strategy manages the energy of the electric drive so intelligently that, for every sprint with maximum acceleration, the full power of the 918 Spyder can be tapped into by simply pressing the accelerator down fully. In short, the 918 Spyder allows even drivers without motorsport training to experience the potential of advanced longitudinal and transverse dynamics.

The Porsche 918 Spyder also has the potential to break many records. The current lap time for the North Loop of the Nürburgring is 7:14 minutes. This time was achieved in the presence of international journalists during test drives in September 2012 – more than a year before start of production. The 918 Spyder prototype was therefore approximately 20 seconds quicker than the Porsche Carrera GT. More test drives on the Nürburgring North Loop will follow. An even more important factor is that the 918 Spyder surpasses previous models and competitors by far in its efficiency as well. As a plug-in hybrid vehicle, it systematically combines the dynamic performance of a racing machine with low fuel consumption. To sum it up: maximum driving fun with minimal fuel consumption.

Carbon monocoque guarantees lightweight design with a low center of gravity

The 918 Spyder utilizes the best state-of-the-art technologies, taken straight from motor racing, to achieve its top performance. The entire load-bearing structure is made of carbon fiber reinforced polymer (CFRP) for extreme torsional rigidity. Additional crash elements at the front and rear absorb and reduce the energy of a collision. The car’s unladen weight of approximately 3,715 lbs. (3,616 lbs. with “Weissach” package), an excellent low weight for a hybrid vehicle of this performance class, is largely attributable to this concept.

The drivetrain components and all components weighing over 110 lbs. are located as low and as centrally as possible within the vehicle. This results in a slightly rear end biased axle load distribution of 57 percent on the rear axle and 43 percent on the front axle, combined with an extremely low center of gravity at approximately the height of the wheel hubs, which is ideal for driving dynamics. The central and low position of the traction battery directly behind the driver not only supports efforts to concentrate masses and lower the center of gravity; it also provides the best temperature conditions for optimum battery power capacity.

Chassis with race car genes and rear-axle steering

The multi-link chassis of the Porsche 918 Spyder is inspired by motorsport design, complemented by additional systems such as the PASM adaptive shock-absorber system and rear-axle steering. Basically, this incorporates an electro-mechanical adjustment system at each rear wheel. The adjustment is speed-sensitive and executes steering angles of up to three degrees in each direction. The rear axle can therefore be steered in the same direction as the front wheels or in opposition to them. At low speeds, the system steers the rear wheels in a direction opposite to that of the front wheels. This makes cornering even more direct, faster and more precise, and it reduces the turning circle. At higher speeds, the system steers the rear wheels in the same direction as the front wheels. This significantly improves the stability of the rear end when changing lanes quickly. The result is very secure and stable handling.

Porsche Active Aerodynamic (PAA) for different driving modes

Porsche Active Aerodynamic (PAA), a system of adjustable aerodynamic elements, ensures unique and variable aerodynamics; its layout is automatically varied over three modes ranging from optimal efficiency to maximum downforce and is tuned to the operating modes of the hybrid drive system. In “Race” mode, the retractable rear wing is set to a steep angle to generate high downforce at the rear axle. The spoiler positioned between the two wing supports near the trailing edge of the airflow also extends. In addition, two adjustable air flaps are opened in the underfloor in front of the front axle, and they direct a portion of the air into the diffuser channels of the underbody structure. This also produces a “ground effect” at the front axle.

In “Sport” mode, the aerodynamic control system reduces the attack angle of the rear wing somewhat, which enables a higher top speed. The spoiler remains extended. The aerodynamic flaps in the underfloor area close, which also reduces aerodynamic drag and increases attainable vehicle speeds. In “E” mode, the control is configured entirely for low aerodynamic drag; the rear wing and spoiler are retracted and the underfloor flaps are closed.

Adjustable air inlets under the main headlights round off the adaptive aerodynamic system. When the vehicle is stationary and in “Race” and “Sport” mode, they are opened for maximum cooling air intake. In “E-Power” and “Hybrid” modes, they close immediately after the car is driven off in order to keep aerodynamic drag to a minimum. They are not opened until the car reaches speeds of approximately 81 mph or when cooling requirements are higher.

From comfortable to race-ready: five modes for three motors

The core of the 918 Spyder concept is its distribution of propulsive power among the three power units; their cooperation is controlled by an intelligent management system. To best exploit these different approaches, the Porsche developers defined five operating modes that can be activated via a “map switch” on the steering wheel, just like in motorsport cars. On the basis of this pre-selection, the 918 Spyder applies the most suitable operating and boost strategy without driver intervention, thus allowing the driver to concentrate fully on the road.

Quiet and elegant: “E-Power”

When the vehicle is started up, the “E-Power” mode is the default operating mode as long as the battery is sufficiently charged. In ideal conditions, the 918 Spyder can cover approximately 18 miles on purely electric power. Even in pure electric mode, the 918 Spyder accelerates from 0 to 62 mph in seven seconds and can reach speeds of up to 93 mph. In this mode, the combustion engine is only used when needed. If the battery’s charge state drops below a set minimum value, the vehicle automatically switches to hybrid mode.

Efficient and comfortable: “Hybrid”

In “Hybrid” mode, the electric motors and combustion engine work alternately with a focus on maximum efficiency and minimum fuel consumption. The use of individual drive components is modified as a function of the current driving situation and the desired performance. The Hybrid mode is typically used for a fuel economy-oriented driving style.

Sporty and dynamic: “Sport Hybrid”

In more dynamic situations, the 918 Spyder selects the “Sport Hybrid” mode for its power sources. The combustion engine now operates continuously and provides the main propulsive force. In addition, the electric motors provide support in the form of electric boosting or when the operating point of the combustion engine can be optimized for greater efficiency. The focus of this mode is on performance and a sporty driving style at top speed.

For fast laps: “Race Hybrid”

“Race Hybrid” is the mode for maximum performance and an especially sporty driving style. The combustion engine is chiefly used under high load, and charges the battery when the driver is not utilizing its maximum output. Again, the electric motors provide additional support in the form of boosting. Furthermore, the gear-shifting program of the PDK is set up for even sportier driving. The electric motors are used up to the maximum power output limit to deliver the best possible performance for the race track. In this mode, the battery charge state is not kept constant, rather it fluctuates over the entire charge range. In contrast to Sport Hybrid mode, the electric motors run at their maximum power output limit for a short time for better boosting. This increased output is balanced by the combustion engine charging the battery more intensively. Electric power is thus available even with several very fast laps.

For pole position: “Hot Lap”

The “Hot Lap” button in the middle of the map switch releases the final reserves of the 918 Spyder and can only be activated in “Race Hybrid” mode. Similar to a qualification mode, this pushes the traction battery to its maximum power output limits for a few fast laps. This mode uses all of the available energy in the battery.

Main propulsion: the race car’s eight cylinder engine

The main source of propulsion is the 4.6-liter, eight cylinder engine that produces 608 hp of power. The engine is derived directly from the power unit of the successful RS Spyder, which explains why it can deliver engine speeds of up to 9,150 rpm. Like the race engine of the RS Spyder, the 918 Spyder power unit features dry-sump lubrication with a separate oil tank and oil extraction. To save weight, components such as the oil tank, the air filter box integrated into the subframe and the air induction are made of carbon fiber reinforced polymer. Further extensive lightweight design measures have resulted in such features as titanium connecting rods, thin-wall, low-pressure casting on the crank case and the cylinder heads, a high-strength, lightweight steel crankshaft with 180 degrees crankpin offset and the extremely thin-walled alloy steel/nickel exhaust system. Striking features of the V8 are that it no longer supports any auxiliary systems, there are no external belt drives and the engine is therefore particularly compact. Weight and performance optimizations achieve a power output per liter of approx. 133 hp/l – the highest power output per liter of a Porsche naturally aspirated engine – which is significantly higher than that of the Carrera GT (106 hp/l) and outstanding for a naturally aspirated engine.

Unique race car design heritage: top pipes

It isn’t just this engine’s performance but also the sound it makes that stokes the emotionality of the 918 Spyder. This is attributable first and foremost to the so-called top pipes: the tailpipes terminate in the upper part of the rear end immediately above the engine. No other production vehicle uses this solution. The top pipes’ greatest benefit is optimal heat removal, because the hot exhaust gases are released via the shortest possible route, and exhaust gas back pressure remains low. This design requires a new thermodynamic air channeling concept. With the HSI engine, the hot side is located inside the cylinder V, the intake channels are on the outside. There is another benefit as well: the engine compartment remains cooler. This is especially beneficial to the lithium-ion traction battery, as it provides optimum performance at temperatures between 68 and 104 degrees Fahrenheit. Consequently, less energy needs to be used for active cooling of the battery.

In parallel in the drivetrain: hybrid module

The V8 engine is coupled to the hybrid module, since the 918 Spyder is designed as a parallel hybrid like the current hybrid models from Porsche. Essentially, the hybrid module comprises a 115 kW electric motor and a decoupler that serves as the connection with the combustion engine. Because of its parallel hybrid configuration, the 918 Spyder can be powered at the rear axle either individually by the combustion engine or electric motor or via both drives jointly. As is typical for a Porsche super sports car, the power pack in the 918 Spyder has been placed in front of the rear axle, and does not have any direct mechanical connection to the front axle.

Upside-down for a low center of gravity: Doppelkupplung

A seven-speed Doppelkupplung (PDK) transmission handles power transmission to the rear axle. The high-performance transmission is the sportiest version of the successful PDK; it has undergone a complete redesign for the 918 Spyder and has been further optimized for high performance. To ensure a low mounting position for a low center of gravity of the entire vehicle, the gear unit was turned “upside down” by rotating it 180 degrees about its longitudinal axis, in contrast to other Porsche series. If no power is required on the rear axle, the two motors can be decoupled by opening the decoupler and PDK clutches. This is the action behind the Porsche hybrid drive’s typical “coasting” with the combustion engine switched off.

Independent all-wheel drive: front axle with electric motor

On the front axle, there is another independent electric motor with an output of approximately 95 kW. The front electric drive unit drives the wheels at a fixed ratio. A decoupler decouples the electric motor at high speeds to prevent the motor from over-revving. Drive torque is independently controlled for each axle. This makes for very responsive all-wheel drive functionality that offers great potential in terms of traction and driving dynamics.

Lithium-ion battery with plug-in charging system

The electric energy for the electric motors is stored by a liquid-cooled lithium-ion battery comprising 312 individual cells with an energy content of about seven kilowatt hours. The battery of the 918 Spyder has a performance-oriented design in terms of both power charging and output, so that it can fulfill the performance requirements of the electric motor. The power capacity and the operating life of the lithium-ion traction battery depend on several factors, including thermal conditions. That is why the battery of the 918 Spyder is liquid-cooled by a dedicated cooling circuit. The global warranty period for the traction battery is seven years.

To supply it with energy, Porsche developed a new system with a plug-in vehicle charge port and improved recuperation potential. This vehicle charge port in the B-pillar on the front passenger side lets users connect the storage battery to an electrical supply at home to charge it. The charge port is standardized for the country of purchase. The on-board charger is located close to the traction battery. It converts the alternating current of the household electric supply into direct current with a maximum charge output of 3.6 kW. Using the supplied Porsche Universal Charger (AC), the traction battery can be charged with a conventional wall plug in seven hours from a ten ampere rated, fused power socket a US 110 Volt household electrical supply, for example. Furthermore, the Porsche Universal Charger (AC) can be installed at home in the garage using the Charging Dock. It enables rapid and convenient charging within approximately two hours, irrespective of regional conditions. The Porsche Speed Charging Station (DC) is available as an optional extra. It can fully charge the high-voltage battery of the 918 Spyder in just 25 minutes.

Pioneering control concept: clear organization of the cockpit

The driver is the focus of all technology in the future Porsche super sports car. A cockpit was created for the driver that is typical of the brand and pioneering in its clarity. It is partitioned into two basic areas. First, there are the controls that are important for driving, which are grouped around the multifunction steering wheel, combined with driver information displayed on three large round instruments. Second, there is the infotainment block that is housed in the lifted center console, which was introduced in the Carrera GT. Control functions, e.g. for the automatic climate control system, wing adjustment, lighting and Porsche Communication Management (PCM), including a Burmester high-end sound system, can be intuitively operated by multitouch with a new type of black panel technology.

For even higher performance: the Weissach package

For very performance-oriented customers of the 918 Spyder, Porsche offers the “Weissach” package. These modified super sports cars can be recognized at first glance by special colors and designs that are based on legendary Porsche race cars. The roof, rear wings, rear-view mirrors and frames of the windscreen are made of visible carbon. Parts of the interior are upholstered with Alcantara instead of leather, and visible carbon replaces much of the aluminum. Sound insulation has been reduced. The emphasis on performance is not just visual: very lightweight magnesium wheels reduce unsprung masses; gross weight was reduced by about 77 lbs. The benefits are experienced in further improved dynamic performance. Other references from motorsport are six-point seatbelts for driver and front passenger, optional film-coating instead of body paint, as well as additional aerodynamic body parts in visible carbon.

Porsche redefined: a new super sports car for a new decade

The 918 Spyder continues a long tradition of super sports cars at Porsche; as technology platforms, as the driving force behind both car emotion and car evolution and as the ultimate sports cars of their decades: the Carrera GTS, the first Porsche Turbo, the 959, the 911 GT1, the Carrera GT. More than any of its predecessors, the 918 Spyder is providing key impetus for developing technologies for future vehicle concepts. It offers a complete package of components that reflect Porsche DNA – more concentrated than ever before.

Technical Specifications – Porsche 918 Spyder

Body: Two-seat Spyder; carbon fiber reinforced plastics (CFRP) monocoque interlocked with CFRP unit carrier; two-piece Targa roof; fixed roll-over protection system.

Drivetrain: Parallel full hybrid; 4.6-liter V8 mid-engine with dry-sump lubrication; hybrid module with electric motor and decoupler; electric motor with decoupler and gear unit on front axle; auto start/stop function; electrical system recuperation; four cooling circuits for motors, transmission and battery; thermal management.

Engine power: 608 hp at 8,600/min (V8 engine)

154 hp (hybrid module on rear axle)

127 hp (electric motor on front axle)

887 hp (combined)

Max. torque: 390 lb.-ft. at 6,600/min (V8 engine)

940 lb.-ft. (equivalent torque calculated on the crankshaft, complete system in 7th gear)

787 lb.-ft. (complete system, 3rd gear)

> 590 lb.-ft. (800/min – 5,000/min)

Maximum Revs: 9,150 rpm

Power output per l: 133 hp/l (V8 engine)

Power transmission: Combustion engine with hybrid module and transmission bolted together to form a single drive unit; seven-speed Doppelkupplungsgetriebe (PDK); rear-wheel drive; front electric motor with gearbox for driving the front wheels (decoupled from 146 mph); five pre-selectable operating modes for optimum coordination of all drive units.

Gear ratios PDK

1st gear 3.91

2nd gear 2.29

3rd gear 1.58

4th gear 1.19

5th gear 0.97

6th gear 0.83

7th gear 0.67

R gear 3.55

Final drive ratio 3.09

Clutch diameter 8.7 in. / 6.5 in.

Chassis and Suspension: Double-wishbone front axle; optional electro-pneumatic lift system on front axle; electro-mechanical power steering; multilink rear axle with adaptive electro-mechanical system for individual rear wheel steering; electronically controlled twin-tube gas-pressure dampers in the front and rear with Porsche Active Suspension Management (PASM).

Brake system: High-performance hybrid brake system with adaptive recuperation; internally ventilated and perforated front ceramic brake discs (PCCB), 16 in. in diameter and 1.4 in. thick; rear discs 15.4 in diameter and 1.3 in. thick.

Wheels and tires: 918 Spyder wheels

(Weissach package: 918 Spyder magnesium wheels)

front 9.5 J x 20 with 265/35 ZR 20

rear 12.5 J x 21 with 325/30 ZR 21

Weights: Curb weight 3,715 lbs.

3,616 lbs. (Weissach package)

Dimensions: Length 182.8 in.

Width 76.4 in.

Height 45.9 in.

Wheelbase 107.5 in.

Track width front 65.5 in.

rear 63.5 in.

Luggage compartment capacity, VDA ~ 110 l

Fuel tank capacity 18.5 gal

Energy supply: Lithium-ion battery with 6.8 kWh capacity (BOL nominal), 220 kW maximum power and mains-compatible plug-in charger.

Performance: Top speed > 211 mph

purely electric 93 mph

Acceleration:

0-62 mph 2.8 s

0-60 mph less than 2.8 s

0-62 mph (in electric mode) 7.0 s

0-124 mph (0-200 km/h) 7.9 s

0-186 mph (0-300 km/h) 23.0 s

Range: Purely electric approx. 18 mi.

Warranty: Vehicle (Battery) 4 years (7 years)

Charging times:

AC charging on a household socket (110 V, 10 A): less than 7 hours

AC charging on an industrial socket (240 V, 30 A): less than 2 hours

DC charging on an industrial socket (400 V, 32 A): less than 0.5 hours.

IN EXHIBITION: Ferrari Supercar: Technology. Design. Myth.

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Maranello, 8th March 2013 – Today saw the official inauguration at the Ferrari Museum in Maranello of the “Ferrari Supercar. Technology. Design. Myth” exhibition which includes the new LaFerrari, unveiled just a couple of days ago at the Geneva Motor Show, as well as all of the other limited edition special series cars that helped establish the Prancing Horse legend.

Opened by Chairman Luca di Montezemolo, “Ferrari Supercar. Technology. Design. Myth” retraces the story of all of the limited edition special series models built by Ferrari, starting with the 250 GTO, including an example of the 1964 version, and continuing with the 1984 GTO, the F40, the F50 and the Enzo, all the way up to the new model which has been named the LaFerrari as it epitomises the sweeping excellence for which the Maranello marque is renowned.

Parallel to the limited edition road cars will be the Formula 1 cars that inspired Ferrari’s design in various eras, as well as special track and competition-oriented models, such as the GTO Evoluzione, the F40 Competizione, the 599XX and the FXX.

A large section of the exhibition is devoted to the development of the LaFerrari, illustrating both its technical content and styling. The entire process from the car’s initial conception to the approval of the final car is traced, in fact, and visitors also have the opportunity to see two full-scale models in addition to the various stages the car went through in its design and development.

Information

The exhibition runs until September 30th. The Museum is open to the public between the hours of 9.30 and 18.00 until May 1st after which date it closes at 19.00. Tickets can be booked online at www.museoferrari.com, as can guided tours at museo@ferrari.com.

Special evenings at the Museum can also be booked by private and corporate groups on request at: eventimuseo@ferrari.com. The Skira publisher has created a large and wonderfully rich catalogue especially for the exhibition. It is on sale in the Museum in

Maranello.

THE LIMITED EDITION SPECIAL SERIES CARS

250 GTO

Probably the most famous of all Ferrari cars, the 250 GTO was built from 1962 to 1964.

With just 36 vehicles produced – all of which are still extant – the 250 GTO ruled on the track and on the road, winning the GT Manufacturers’ International Championship three years in a row. GTO stands for the category it raced in: in order to compete, a minimum of

100 vehicles had to be built in a year. When the Federation granted homologation as an evolution of the short-wheelbase 250 GT, it automatically became the 250 GTO, i.e., the homologated GT (GT Omologata).

It proved to be invincible with its 2953 cc V12, an evolution of the Colombo engine. It featured 300 hp, high torque even at low rpm and a 5-speed transmission, which represented a major innovation for the period. Another two key factors that contributed to the success of the 250 GTO was its dry weight of just 880 kg, and its superior agility.

Today its value has rocketed to over $20 million.

GTO

Designed for “Group B” races, the GTO project dates back to 1983. The 308 was used as the starting point for the project. The steel chassis was reinforced and work was done on thewheelbase, tracks and wheel size. A radical approach was taken for the twin-turbo V8 engine, with two heat exchangers, just like a F1 car, and the aerodynamics were improved by adding large spoilers. The car was unveiled in 1984 as a road-going vehicle as, in themeantime, the FIA had abandoned Group B racing. It was a resounding success, and instead of the planned 200 vehicles, production reached 272 units (which is nonetheless a small volume). This makes it rare and valuable today.

F40

The unexpected success of the GTO revealed the huge potential for on-road cars built using avant-garde technologies developed for racing. Unveiled at the 1987 Frankfurt Motor Show, the car’s minimalist passenger compartment features only what is strictly needed for driving.

The chassis is made from steel incorporating composite materials and Kevlar. Characterised by the large rear spoiler, the bodywork is made from composite materials. The 478 hp twinturbo engine – 80 hp more than the GTO – allows the car to accelerate from 0 to 100 km/h in 4.1 seconds, with a maximum speed of 324 km/h – simply phenomenal for the time. Although it was announced that only 400 vehicles would be produced, the success was so overwhelming that Ferrari had to build 1315 cars over five years!

F50

The 50 in the name of this model represents the 50th anniversary of Ferrari, which fell in 1997. The model was unveiled at the Geneva Motor Show in 1995 and was designed at the same time as the last Ferrari sport prototype to be built in Maranello: the 333 SP. The inspiration for this new milestone in Ferrari technology came once again from the world of F1: a perfect combination of a carbon-fibre bodyshell and a V12 engine, just like a singleseater. In addition, just like a F1 car, the chassis integrated the engine as a stressed member. The vehicle’s design was extremely original for the time, and features a removable hardtop that can be lodged on board. With only 349 vehicles produced, the F50 is much sought-after by collectors.

Enzo Ferrari

The Enzo dates back to the years of consecutive victories in the Drivers’ and Constructors’ F1 World Championships. It was 2002, and the name of the new model served as a promise of excellence. Even the styling was inspired by F1 and the Enzo was the first road car with a manettino selector on the steering wheel to adjust the handling depending on the use of the car and road conditions. The lightweight and compact V12 engine and the vehicle dynamics systems react to inputs from the manettino, just like on the single-seaters. The system was developed from the technique used by Schumacher to change the car setup in every bend, requiring commands capable of adjusting car setup several times during the same lap. This is how the modern F1 steering wheel and the manettino, as the team and driver called it, were developed.

THE OTHER CARS IN THE EXHIBITION

599XX Evo

The 599 is not officially a supercar, but the XX version definitely belongs to this elite category, for both technical and symbolic reasons. Ferrari has an extraordinary tradition of creating high-performance front-engine vehicles. The 250 GTO is the most significant of these, but it is not the only one. It is interesting to see two berlinettas – both so technologically advanced and with outstanding track performance – side by side, separated by 50 years. At its debut, the 599XX broke the lap record on the famous and challenging Nordschleife, the 22.8 km version of the Nürgburgring track.

Technically speaking, the 599XX is an example of excellence, featuring a 730 hp aspirated V12 engine, with exceptional handling thanks to the weight distribution – 47% on the front and 53% on the rear – and to the sophisticated electronic dynamic controls system. The aerodynamic shape enhanced by the mobile rear spoiler contributes to achieving this outstanding performance. It was built specifically for track use.

GTO Evoluzione

The extraordinary commercial success enjoyed by the GTO instantly revealed to Ferrari the huge opportunities afforded by placing an extremely sporty road car at its clients’ disposal. This planted the seed for the concept of the F40, the GTO Evoluzione which, however, never actually raced and remained a development model.

F40 Competizione

The F40’s design and characteristics absolutely begged for a track version to be developed. The Ferrari importers that traditionally took part in endurance racing found the answer to their dreams in the evolution mooted by specialist Michelotto which had already made important contributions on the racing development of the likes of the 308 GTB, for instance. The car first saw the light of day in 1989 but its development continued until the end of the1990s yielding record results.

FXX

Ferrari launched a uniquely innovative technical collaboration programme for its most loyal and enthusiastic clients centring around the prototype FXX. The latter car was the most advanced GT ever created by Maranello and its mission was to involve the marque’s most valued owners as Client-Test Drivers.

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