초록 ▼

An improved method and device for the reduction of aerodynamic drag and for increased fuel economy of ground vehicles by increasing the pressure on the rear surface of the vehicle with a plurality of vortices generated along the top and side surfaces of the ground vehicle that flow in to the base wa

An improved method and device for the reduction of aerodynamic drag and for increased fuel economy of ground vehicles by increasing the pressure on the rear surface of the vehicle with a plurality of vortices generated along the top and side surfaces of the ground vehicle that flow in to the base wake region of the vehicle. The invention is comprised of a minimum number of small surfaces that attach to the side and top exterior surfaces of a ground vehicle. The spacing and orientation of the small surfaces, comprising the device, are dependent upon the vehicle geometry and vehicle operating conditions. The plurality of small surfaces are located forward of the vehicle base area. The plurality of adjacent small surfaces and are distributed circumferentially over the side and top surfaces of the ground vehicle.

대표청구항 ▼

I claim: 1. An aerodynamic drag reduction device for use on a vehicle comprising: a plurality of small surfaces attached to the aft exterior surface of said vehicle, a means for attaching said small surfaces to said vehicle, said plurality of small surfaces are symmetrically positioned about said v

I claim: 1. An aerodynamic drag reduction device for use on a vehicle comprising: a plurality of small surfaces attached to the aft exterior surface of said vehicle, a means for attaching said small surfaces to said vehicle, said plurality of small surfaces are symmetrically positioned about said vehicle's principle longitudinal axis, said plurality of small surfaces are approximately equally spaced around the majority of the circumference of said vehicle, each of said small surfaces are positioned at approximately the same longitudinal position on said vehicle, each of said small surfaces extends outward from the exterior surface of said vehicle a distance equal to the local boundary layer thickness on said vehicle in the region of said small surfaces, each of said small surfaces extends an equivalent distance perpendicularly outward from the exterior surface of said vehicle, each of said small surfaces that are adjacent to one another on either the right or left side of said vehicle are substantially parallel to one another, each of said small surfaces has a forward most edge that is pointed, each of said small surfaces are thin with a maximum thickness of 1.0 inches, each of said small surfaces has a minimum length that is equal to 5 times the local boundary layer thickness on said vehicle in the region of said small surfaces, each of said small surfaces is inclined a minimum of 10째 to the local flow direction measured on said vehicle surface in the region of said small surfaces, each of said small surfaces being separated from and substantially parallel to one another allow each said small surfaces to generate a vortex of equivalent strength thereby the flow passing along the external surface of said vehicle in the region of and aft of said small surfaces is energized and thereby the external trailing wake flow of the vehicle is changed to a substantially steady symmetric wake flow field. 2. An aerodynamic drag reduction device of claim 1 wherein said small surfaces are rigid. 3. An aerodynamic drag reduction device of claim 1 wherein said small surfaces are flexible. 4. An aerodynamic drag reduction device of claim 1 wherein said small surfaces may be inflatable. 5. An aerodynamic drag reduction device of claim 1 wherein each said small surface is constructed as a single element and attached to said vehicle. 6. An aerodynamic drag reduction device of claim 1 wherein two or more said small surfaces are constructed as a single assembly and attached to said vehicle. 7. An aerodynamic drag reduction device as specified in claim 1 wherein said vehicle is an air vehicle. 8. An aerodynamic drag reduction device as specified in claim 1 wherein said vehicle is a ground vehicle. 9. An aerodynamic drag reduction device for a vehicle comprising: a plurality of small surfaces on the aft exterior surface of said vehicle, said plurality of said small surfaces are symmetrically positioned about said vehicle principle longitudinal axis, said plurality of said small surfaces are separated by an approximately equally space around the majority of the circumference of said vehicle, each of said small surfaces are at approximately the same longitudinal position on said vehicle, each of said small surfaces extends outward from the exterior surface of said vehicle a distance equal to the local boundary layer thickness on said vehicle in the region of said small surfaces, each of said small surfaces extends an equivalent distance perpendicularly outward from the exterior surface of said vehicle, each of said small surfaces that are adjacent to one another on either the right or left side of said vehicle are substantially parallel to one another, each of said small surfaces has a forward most edge that is pointed, each of said small surfaces are thin with a maximum thickness of 1.0 inches, each of said small surfaces has a minimum length equal to 5 times the local boundary layer thickness on said vehicle in the region of said small surfaces, each of said small surfaces is inclined a minimum of 10째 to the local flow direction measured on said vehicle surface in the region of said small surfaces, each of said small surfaces being separated from and substantially parallel to one another allow each said small surface to generate a vortex of equivalent strength thereby the flow passing along the external surface of said vehicle in the region of and aft of said small surface is energized and thereby the external trailing wake flow of the vehicle is changed to a substantially steady symmetric wake flow field and drag is reduced. 10. An aerodynamic drag reduction device of claim 9 wherein said small surfaces are rigid. 11. An aerodynamic drag reduction device of claim 9 wherein said small surfaces are flexible. 12. An aerodynamic drag reduction device of claim 9 wherein said small surfaces may be inflatable. 13. An aerodynamic drag reduction device as specified in claim 9 wherein said vehicle is an air vehicle. 14. An aerodynamic drag reduction device as specified in claim 9 wherein said vehicle is a ground vehicle. 15. An aerodynamic drag reduction device for use on a vehicle comprising: a plurality of surfaces attached to top and side exterior surfaces of the vehicle and toward the aft of the vehicle; wherein the surfaces are substantially equally spaced apart from each other and positioned about a principle longitudinal axis of the vehicle; wherein the surfaces each extend outward from the surface of the vehicle at a length substantially equal to the local boundary layer thickness on the vehicle in the region of the surfaces; and wherein the surfaces are substantially parallel to each other and are positioned at an angle of at least 10째 to the airflow so that the surfaces generate a vortex of sufficient strength to energize the airflow passing along the external surface of the vehicle in the region of and aft to the surfaces to such a degree that the vehicle has a substantially steady symmetric wake flow field. 16. The aerodynamic drag reduction device of claim 15, wherein the surfaces have a thickness of up to 1 inch and a length of at least 5 times the local boundary layer thickness on the vehicle in the region of the surfaces. 17. The aerodynamic drag reduction device of claim 15, wherein the leading edges of the surfaces are aerodynamically sharp. 18. The aerodynamic drag reduction device of claim 15, wherein each of the surfaces is a separate element and is attached to the vehicle separately from the other surfaces. 19. The aerodynamic drag reduction device of claim 15, further comprising a base plate, wherein two or more of the surfaces are affixed to the base plate and the base plate is attached to the vehicle. 20. The aerodynamic drag reduction device of claim 15, wherein the surfaces are integrally attached to the surface of the vehicle. 21. The aerodynamic drag reduction device of claim 15, wherein the surfaces attached to the side surfaces of the vehicle are oriented such that the leading edge of the surfaces is above the trailing edge of the surfaces. 22. The aerodynamic drag reduction device of claim 15, wherein the surfaces attached to the side surfaces of the vehicle are oriented such that the leading edge of the surfaces is below the trailing edge of the surfaces. 23. The aerodynamic drag reduction device of claim 15, wherein the surfaces attached to the top surface of the vehicle are oriented such that the leading edge of the surfaces is inboard of the trailing edge of the surfaces. 24. The aerodynamic drag reduction device of claim 15, wherein the surfaces attached to the top surface of the vehicle are oriented such that the trailing edge of the surfaces is inboard of the leading edge of the surfaces. 25. The aerodynamic drag reduction device of claim 15, wherein the trailing edge of the surface located nearest the lowest edge of the side surface of the vehicle is approximately coincident with the lowest edge of the side surface of the vehicle and the leading edge of the surface located nearest the highest edge of the side surface of the vehicle is approximately coincident with the highest edge of the side surface of the vehicle; and wherein the trailing edge of the surface located nearest the outer edge of the top surface of the vehicle is coincident with the outer edge of the top surface of the vehicle and the centermost surfaces located on the top surface of the vehicle will have leading edges at lateral positions coincident with the vehicle centerline. 26. The aerodynamic drag reduction device of claim 15, wherein for the surfaces attached to the side surfaces of the vehicle, the vertical position of the next adjacent surface in increasing vertical position is oriented such that the trailing edge of the adjacent surface is located at a vertical position that is equal to or less than the vertical position of the leading edge of the previous surface. 27. The aerodynamic drag reduction device of claim 15, wherein for the surfaces attached to the top surface of the vehicle, the position of the next adjacent surface on the top of the vehicle is such that the trailing edge is located at a lateral position that is equal to or greater than the lateral position of the leading edge of the previous surface. 28. The aerodynamic drag reduction device of claim 15, wherein the surfaces are oriented at an angle of up to 30째 to the airflow.