Actively Variable Camber Angle
The main attraction in the F 400 Carving is a new system that varies the camber angle on the outer wheels between 0 and 20 degrees, depending on the road situation. Used in conjunction with newly-developed tyres, it provides 30 percent more lateral stability than a conventional system with a fixed camber setting and standard tyres. This considerably enhances active safety, since better lateral stability equals improved road adhesion and greater cornering stability.
Active camber control boosts the research vehicle's maximum lateral acceleration to 1.28g, meaning that the concept study outperforms current sports cars by some 28 percent.
The active camber control in the F 400 Carving paves the way for an equally new asymmetrical-tread tyre concept. When the two-seater car is cornering, the outer wheels tilt inwards, leaving only the inner area of these tyres in contact with the road. This area of the tread is slightly rounded off. Meanwhile both the tread pattern and the rubber blend have been specially selected to ensure highly dynamic and extremely safe cornering.
When driving straight ahead, however, it is the outer areas of the tyres that are in contact with the road. These areas have a tried-and-tested car tread pattern, offering excellent high-speed and low-noise performance. Two different concepts therefore come to fruition in a single tyre, thanks to active camber control.
The F 400 Carving is something of a mobile research laboratory for the Stuttgart-based automotive engineers. They will be using it to investigate the undoubted further potential of this new chassis technology: besides offering excellent directional stability during cornering, the new technology ensures a much higher level of active safety in the event of an emergency. By way of example, if there is a risk of skidding, the wheel camber is increased by an appropriate degree.
The resultant gain in lateral stability significantly enhances the effect of ESP?, the Electronic Stability Program. If the research car needs to be braked in an emergency, all four of its wheels can be tilted in "next to no time", thus shortening the stopping distance from 100 km/h by a good five metres.
Electronic Steering, Active Hydropneumatic System and Light From Glass Fibres
In addition to active camber control, the F 400 Carving research car is fitted with other forward-looking steering and chassis systems, including a steer-by-wire system. Sensors pick up the driver's steering inputs and send this information to two microcomputers which, in turn, control an electrically-driven steering gear. The DaimlerChrysler engineers also charted new territory when it came to the suspension tuning, and introduced a first: an active hydropneumatic system that optimises the suspension and shock absorption in line with the changing situation on the road, all at lightning speed.
The F 400 Carving is also the showcase for a totally new form of lighting technology developed by the Stuttgart-based researchers: fibre-optic lines are used to transmit light from xenon lamps beneath the bonnet to the main headlamps. This technology stands out by virtue of its high performance and extremely space-saving design. Additional headlamps positioned on the sides also come on when the car is cornering.