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A Cd equal to 1 would be obtained in a case where all of the fluid approaching the object is brought to rest, building up Stagnation Pressure over the whole front surface. The top figure shows a flat plate with the fluid coming from the right and stopping at the plate. The graph to the left of it shows equal pressure across the surface. In a real flat plate the fluid must turn around the sides, and full stagnation pressure is found only at the center, dropping off toward the edges as in the lower figure and graph. The Cd of a real flat plate would be less than 1, except that there will be a negative pressure (relative to ambient) on the back surface. The overall Cd of a real square flat plate is often given as 1.17. Flow patterns and therefore Cd for some shapes can change with the Reynolds Number and the roughness of the surfaces. C<SUB>D</SUB> IN AUTOMOBILES The drag coefficient is a common metric in Automotive Design , where designers strive to achieve a low coefficient. Minimizing drag is done to improve Fuel Efficiency at highway speeds, where Aerodynamic effects represent a substantial fraction of the energy needed to keep the car moving. Indeed, aerodynamic drag increases with the square of speed. Aerodynamics are also of increasing concern to Truck designers, where a lower drag coefficient translates directly into lower fuel costs. About 60% of the power required to cruise at highway speeds is taken up overcoming air drag, and this increases very quickly at high speed. Therefore, a vehicle with substantially better aerodynamics will be much more fuel efficient. CdA While designers pay attention to the overall shape of the automobile, they also bear in mind that reducing the frontal area of the shape helps reduce the drag. The combination of drag coefficient and area is CdA (or '''CxA'''), a multiplication of the Cd value by the area. The product of the drag coefficient and area, called drag area, was introduced in 2003 by '' Car And Driver '' as a more accurate way to compare the aerodynamic efficiency of various automobiles. Average full-size passenger cars have a drag area of roughly 8.5 ft² (.79 m²). Reported drag area ranges from the 2005 Chevrolet Corvette at 6.1 ft² (.57 m²) to the 2006 Hummer H3 at 16.8 ft² (1.56 m²). More examples: from
Drag in sports and racing cars Reducing drag is also a factor in ). For best cornering and racing performance, as required in Formula 1 cars, downforce and stability are crucial and these cars have very high Cd values. Typical values and examples The typical modern automobile achieves a drag coefficient of between 0.30 and 0.35. SUV s, with their flatter shapes, typically achieve a Cd of 0.35–0.45. Notably, certain cars can achieve figures of 0.25-0.30, although sometimes designers deliberately increase drag, in favour of reducing Lift . Some notable examples:
Figures given are generally for the basic model. Faster and more luxurious models often have higher drag, thanks to wider Tire s and extra Spoiler s. SEE ALSO EXTERNAL LINKS
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