The first running prototype wears a fiberglass body and a strategically placed prancing horse badge on its front flanks. The production car's body panels will be aluminum and composite.

Issue: Jan 2003


Class Clone



Ford engineers take a blast from the past, infuse it with Ferrari DNA and create the ultimate supercar.

by John Peter






 
The first running prototype wears a fiberglass body and a strategically placed prancing horse badge on its front flanks. The production car's body panels will be aluminum and composite.
As the story goes, Henry Ford II became upset with Enzo Ferrari when he refused to sell his company to Ford. He sent out an edict to his engineering staff that they would build a race car capable of beating Ferrari at his own game, the 24 Hours of LeMans, the most prestigious race in Europe. They succeeded, finishing 1, 2 and 3 in 1966 and going on to win for four consecutive years. It's hard to ignore the historical significance of Ford's new GT supercar. Not just because designer Camilo Pardo has created a near spitting image of the historic racer, but because the first running prototype is sitting within spitting distance of a bright red Ferrari 360 Modena --the benchmark for the Ford GT, and the car these engineers set out to better.

"What better way to celebrate the centennial than looking backward and looking forward," says Chris Theodore, vice president of product development. "It's a great way to celebrate one of the greatest racing cars of all time, but actually take it forward into a road car."

Theodore says that secondly it's a halo product. "We wanted to have a product that's kind of a lightning rod. Imagine one of these sitting in the dealer showroom. It certainly polishes the Ford oval and establishes an icon of all icons."

But the last reason may just be the most valuable. Ford is using the GT program as a technological proving ground for how new product programs will be done in the future. SVT Program Director John Colletti says, "Everything we're doing on this car is unprecedented --the way we assemble the car, the way we're pursuing the project, the timing of the project, the cost of the project, the investment and the engineering." Chief Program Engineer Neil Hannemann knows about halo cars.' He was the lead product development engineer for the Dodge Viper program, before coming over to Ford to head up the GT team.

The GT program got the okay from Ford executives Bill Ford and Nick Scheele in January, after the concept car made its debut at the North American International Auto Show in Detroit. It was decided that a production version of the GT would go on sale in the summer of 2004. The timing was quite an undertaking for a car of this magnitude.

"We spent the better part of a week going through and trying to figure out everything we could do using the current technology," Hannemann says. "The ways you could cut corners --the ways you could save time."

Hannemann says that a lot of time was taken out of the beginning of the program by doing all of the design, engineering and analysis virtually. This is the first totally virtual program that Ford has done. "We needed to compress the virtual time," Hannemann adds. "The design had to happen simultaneously with the engineering. So that determined how we set the team up."

Though the decision was made in January, actual work on the project didn't begin until May 1, when the hand-picked team of engineers was assembled. Everyone working on the project was put into the same room.

We started design reviews immediately on sight, Hannemann says. He adds that there were weekly reviews where the whole team came together to go over the entire car as well as many adhoc meetings held around CAD terminals, with engineers, designers and suppliers interacting in real time making onthe- spot decisions.

The supply base was linked to the same CAE system allowing them to look on in realtime during the main table review. Ford carefully picked the supply base, signing on suppliers with experience in doing low volume vehicles and doing them quickly. This will be the first program for Ford CAE-wise that we only had one level of prototype for crash testing.

Six months ago, Hannemann says, we had a frame and an engine, and we started working on the car from there. Our designs are firming up, were building prototypes and were to the point of starting production tooling. Whats happened between May and where we are now is a model of the continuous transformation were going to be making in creating product in the future.

Everything were doing on this car is unprecedented. The way we assemble the car, the way were pursuing the project, the timing and cost of the project, the investment and the engineering. John Colletti, SVT Program Director

Chassis











 
The GT space-frame is all aluminum, made up of extrusions, castings and a few stampings. Four large castings create the mounting points for the suspension. New technologies include the first automotive use of roll-bonding on the floor panels and friction stir welding on the center tunnel.

 
The double wishbone suspension and coil-over shocks are mounted to large aluminum castings. Front crash-beams are also bolted to the castings and can be easily replaced if damaged by a minor frontal impact. Brembo will supply the entire braking system.
We had some extremely aggressive stiffness targets for this frame, says Huibert Mees, supervisor, chassis systems. In order to make a high-performance vehicle, you have to have a very strong backbone and structure.

Ford developed them first using modeling techniques, then the team convinced Ford management that if they let them buy a $140,000 Ferrari 360 Modena, theyd take very good care of it. We wanted to know how well this car performed, Mees says, and the only way to do that was to measure it. In order to measure the torsional stiffness, you have to disassemble most of the vehicle. So thats what we did.

Without the blessings of upper management, the Ferrari was disassembled and chassis was twisted. After measuring the Ferrari 360 they found that the Ferraris torsional stiffness was right where they had set their targets. The Ferrari measured just under 16,000 ft. per degree of torsion. The GT design exceeded those targets by 40 percent. If you have the stiffness in the chassis, Mees says, you can fine tune the suspension and NVH will follow.

The chassis is an aluminum tubular space-frame made up of extrusions (with castings in key nodes and areas for strength) and a number of stampings. We knew that this was going to be a light and stiff structure, Mees says. We have a lot of experience with it, a lot of lessons learned which we have applied, with the aid of the Ford research lab.

The A-pillar, header-beam and rear-support for the clamshell are bent extrusions, and the whole structure is welded together. Some bonding is done in the floors and the rear bulkhead. Four main aluminum castings serve as mounting points for the suspension.

We did this to maximize the stiffness of the attachment points, Mees says. It also gave us flexible geometry for those attachment points.

The engine is not a stressed member of the chassis due to the NVH concerns, a lesson learned from Ferraris F-40. Another casting connects the tunnel to the bulkhead and to the rest of the vehicle.

The Ford GTs floor panels utilize the first automotive application of roll-bonding. Two thin sheets are rolled into each other. In between the two sheets is a silk-screened pattern of graphite. As the sheets are rolled with high pressure and heat, they bond to each other except in the areas where the graphite sits. Compressed air is blown into an opening and the two sheets inflate. What you have is a very strong lightweight construction.

The tunnel is constructed in several pieces. The top of the tunnel is done on a press brake and the flat side panels are Everything were doing welded to the tunnel using friction stir welding, another aircraft technology. The two panels overlap and something that looks like a drill bit with a small nipple on the end spins at 10,000 rpm. The heat from the friction melts the aluminum and the little nipple stirs the molten aluminum together creating a very clean and very strong weld.

Crush rails are bolted to the four main castings allowing for ease of replacement. Low-speed impacts will only damage the crush rails and not the rest of the car.







 
A blow molded 18.5 gal. fuel tank runs down the middle of the car. Two internally mounted fuel pumps feed the two injectors per cylinder. Fuel mileage is estimated at a combined 17.5 mpg. The cooling module includes a 3 in. thick radiator followed by an intercooler radiator and condensor. A water air intercooler is mounted right underneath the supercharger and driven by electric pump, continually circulating water.
The suspension is an all-aluminum double-wishbone. Components are cast aluminum including the knuckle. Architecture for the front and rear are very similar. In the front, coil over shocks are attached to the lower control arm. In the rear they attach to the knuckle. There are anti-roll bars both front and rear, and a ZF steering gear is hard-mounted to the frame, forward of the center of the axle. Brembo supplies the entire braking system while Bosch supplies the four-channel ABS system.

235x45x18 Goodyear tires mount on 9 in. rims on the front and 315x40x19 Goodyears mount on 11.5 in. rims out back.

Body
The Ford GTs aluminum body panels will manufactured by Mayflower Vehicle Systems of Farmington Hills, Mich. Body Structure Supervisor, Bill Clarke says that they chose aluminum over composites, like SMC, for weight savings. They were also able to rely heavily on the technological expertise used by Jaguar and Aston Martin. The aluminum quarter panels, fenders and doors are made using a super plastic forming process, where the sheet of aluminum is heated to near melting and slowly formed to a one-sided die. The space frame will have attachment points for the body panels to hang from in a manner that allow for precise fit and finish.

The forward-tilting hood is made of carbon fiber because of the need to form the very deep air scoops. They were made deeper than the concept car, says Clarke, because CAE modeling showed that it helped with engine cooling.







 
The undercarriage is completely sealed. The rear splitter was designed and tested in the computer before a 4/5- size model was made and tested in the wind tunnel.
The rear clamshell tilts rearward like the original car. The outside is aluminum and the inner is composite. All of the openings are functional. One side scoop is for the transmission cooler and the other allows air to the engine. Engine intake scoops on each side 52 lead to a large air box in the engine compartment and vents on either side of the back window and on the engine cover allow hot air to escape. Clark says that the cantilevered-styled doors are a very important element of the original Ford GT. There was a concern that with the doors, the car would lose a lot of stiffness. Reinforcement was recovered in the Y shaped extrusions that tie the bulkhead into the hefty A-pillars. It was decided that the doors would have to go all of the way in. If they were only done halfway the structure would travel right over the occupants head, creating a safety concern.

The doors are made from a one-piece outer and one-piece inner with pins at the top to hold the doors down at high speeds. One of challenges that engineers faced was how to design the side windows so they would go down.

The original car had flush glass riveted to the body. They solved the dilemma by depressing the window surface into the car slightly and adding a molding around the edge. The side scoops were also pulled out.

Interior







 
 Care was taken to create a historically correct interior, complete with offset speedometer. Lear-designed racing seats are still under development.
The interior, done by Lear, carefully mimics the original. The interior will consist of exposed space frame down in the floor area. What wont be exposed aluminum will be covered with a material called AZDEL, a black plastic composite made of fiberglass and plastic formed into thin sheets, like a vinyl wrap. The material, developed by GE, is about half the weight of conventional materials. This is the first automotive application of AZDEL. The IP has a magnesium crossbar that also comes down to the console. The headliner and top of the console are stamped aluminum. The IP will feature full instrumentation including a speedometer, off-set to the center and angled toward the driver, a tachometer, voltage meter, water temperature gauge, oil pressure gauge, boost gauge, fuel gauge and toggle switches. Lear is developing the racing-style bucket seats. Climate controls are in the console. While packaging the interior, engineers had to determine if they needed to change the specific dimensions of the car. A seating buck was built to help them come up with a seating package and a mechanical package that was feasible within the appearance theme of the vehicle. It was also used to fine-tune the final shape of the doors. Control placement and range of adjustment were all done in a CAD environment.

The team used a lot of advanced CAD tools to develop 3-D models of the interior. A virtual digital occupant tool allowed them to adjust the positioning of interior components. The software could also be programmed to adjust parameters for height and size of occupants.

With this immersable tool, an engineer wearing a headset with stereo screens and target locators on his body can virtually sit inside an interior buck.

Engine
The GT will be powered by an all-new supercharged overhead cam 4-valve 5.4 L V-8, derived from the modular architecture. Rated at 500 hp and 500 lb.ft. of torque, it's mated to a Ricardo short-throw gateless six-speed transaxle. The Romeo, Mich.- built engine will have an all-new aluminum block and new heads modeled after the Cobra R heads for high flow. The supercharger is an Eaton screw-type compressor. Ford considered a twin-turbo setup, but short development time left no room for powertrain development, not to mention packaging and thermal issues.

The engine uses a dry sump oil system to allow for the engine to sit lower in the chassis. An oil tank is mounted to the passenger side of the engine compartment.

The aluminum block will be unique to the GT for now, but Colletti sees lots of potential for the aftermarket. Coletti says that the block is an exact swap for the iron block in the Lightning pickup and could possibly find its way into some future SVT products. Air will be fed to a dual-element air filter that is built into the back of the body. The exhaust manifolds are cast iron and "as header-like as we can get" says Powertrain Engineering Supervisor Curt Hill.

"We're paying a lot of attention to make sure we get enough flow," Hill continues. We have an active muffler system to give us the sound quality we're looking for." The muffler has an internal by-pass that opens at a certain pressure level and allows for the drive-by. "There's a lot of modeling done," Hill says, "because it's hard to get the sound quality you want on this short of a run."

The Ford GT will be assembled at Wixom's prototype build center, on the grounds of Wixom Assembly in Wixom, Mich. They should easily handle the 1,000 copies that Ford plans to build in the first year. Mayflower Vehicle Systems will supply the chassis and body panels -- Saleen Inc. will deliver painted body panels and interior modules. About 15 percent of the vehicle will consist of carryover parts such as the hood latch and airbags from Volvo.

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