The disclosed system and method for improving aerodynamic stability of aeronautic vehicles generally includes an ejectable grid fin adapted for releasable engagement with aeronautic vehicles. The grid fin is generally configured to optimize the flight performance characteristics of the aeronautic ve
The disclosed system and method for improving aerodynamic stability of aeronautic vehicles generally includes an ejectable grid fin adapted for releasable engagement with aeronautic vehicles. The grid fin is generally configured to optimize the flight performance characteristics of the aeronautic vehicle taken in engaged combination with the grid fin as compared with the flight performance of the aeronautic vehicle taken alone. Disclosed features and specifications may be controlled, adapted or otherwise optionally modified to improve the aerodynamic stability and/or control of a variety of deployed aeronautic vehicles. Exemplary embodiments of the present invention generally provide ejectable grid fins that may be used in conjunction with missiles mounted on an eject rail of an aircraft.
대표청구항▼
We claim: 1. A grid fin device for use with an aeronautic vehicle, said device comprising: a grid array structure suitably adapted for releasable engagement with said aeronautic vehicle; wherein said grid array is configured to provide control forces for modifying the flight performance characteris
We claim: 1. A grid fin device for use with an aeronautic vehicle, said device comprising: a grid array structure suitably adapted for releasable engagement with said aeronautic vehicle; wherein said grid array is configured to provide control forces for modifying the flight performance characteristics of the engaged combination of said grid fin with said aeronautic vehicle as compared with the flight performance characteristics of said aeronautic vehicle alone; wherein said grid array comprises a lobed configuration corresponding to a C2v point group with laterally disposed occlusion areas, non-textured areas, and a central aperture; and said grid array is configured to maintain its aerodynamic disposition with respect to the longitudinal axis of said aeronautic vehicle when engaged to said aeronautic vehicle. 2. The grid fin device of claim 1, wherein said grid array structure is further configured for release from said aeronautic vehicle subsequent to deployment of the engaged combination of said grid fin and said aeronautic vehicle. 3. The grid fin device of claim 1, wherein said control forces are suitable for modifying at least one of pitch, yaw and roll of the engaged combination of said grid fin and said aeronautic vehicle. 4. The grid fin device of claim 1, wherein said control forces are suitable for modifying at least one of drag and lift of the engaged combination of said grid fin and said aeronautic vehicle. 5. The grid fin device of claim 1, wherein said grid array structure substantially conforms to a geometry comprising at least one of: a regular solid; an irregular solid; a regular polygon; an irregular polygon; a non-planar geometry having at least one of a point, line and plane of symmetry; and a planar geometry having at least one of a point, line and plane of symmetry. 6. The grid fin device of claim 1, wherein said releasable engagement is accomplished with at least one of a ball-lock and an exploding bolt. 7. The grid fin device of claim 6, wherein release is actuated by at least one of baric pressure, relative orientation of said aeronautic vehicle, relative orientation of said grid array structure, timing sequence, GPS and remote control. 8. The grid fin device of claim 1, wherein said aeronautic vehicle comprises at least one of a missile, a bomb, a munition, a sub-munition, a rocket, a pod and a sub-vehicle. 9. A method for stabilizing an aeronautic vehicle, said method comprising the step of providing a grid array structure suitably adapted for releasable engagement with said aeronautic vehicle; wherein said grid array is configured to provide control forces for modifying the flight performance characteristics of the engaged combination of said grid fin with said aeronautic vehicle as compared with the flight performance characteristics of said aeronautic vehicle alone; wherein said grid array comprises a lobed configuration corresponding to a C2v point group with laterally disposed occlusion areas, non-textured areas, and a central aperture; and said grid array is configured to maintain its aerodynamic disposition with respect to the longitudinal axis of said aeronautic vehicle when engaged to said aeronautic vehicle. 10. The method of claim 9, further comprising the step of releasing said grid array structure from said aeronautic vehicle subsequent to deployment of the engaged combination of said grid fin and said aeronautic vehicle. 11. The method of claim 10, wherein the step of releasing is accomplished with at least one of a ball-lock and an exploding bolt. 12. The method of claim 11, wherein said release is actuated by at least one of baric pressure, relative orientation of said aeronautic vehicle, relative orientation of said grid array structure, timing sequence, GPS and remote control. 13. The method of claim 9, further comprising the step of altering at least one of pitch, yaw and roll of the engaged combination of said grid fin and said aeronautic vehicle. 14. The method of claim 9, further comprising the step of altering at least one of drag and lift of the engaged combination of said grid fin and said aeronautic vehicle. 15. The method of claim 9, wherein the step of providing a grid array structure comprises the step of providing a geometry for the grid array that substantially conforms to at least one of: a regular solid; an irregular solid; a regular polygon; an irregular polygon; a non-planar geometry having at least one of a point, line and plane of symmetry; and a planar geometry having at least one of a point, line and plane of symmetry. 16. The method of claim 9, wherein said aeronautic vehicle comprises at least one of a missile, a bomb, a munition, a sub-munition, a rocket, a pod and a sub-vehicle. 17. A grid fin device for use with an aeronautic vehicle, said grid fin device comprising: a grid array structure suitably adapted for releasable engagement with said aeronautic vehicle; said grid array structure configured to provide control forces for modifying the flight performance characteristics of the engaged combination of said grid fin with said aeronautic vehicle as compared with the flight performance characteristics of said aeronautic vehicle alone; said grid array structure configured to maintain its aerodynamic disposition with respect to the longitudinal axis of said aeronautic vehicle when engaged to said aeronautic vehicle; wherein said grid array comprises a lobed configuration corresponding to a C2v point group with laterally disposed occlusion areas, non-textured areas, and a central aperture; and said grid array structure further comprising an optimized geometry for aggregation of a plurality of aeronautic vehicles in relative close proximity to each other. 18. The grid fin device of claim 17, wherein said grid array geometry comprises at least one of an indentation and an occluded area suitably configured for permitting stored disposition of said plurality of aeronautic vehicles in relative proximity to each other without substantially impeding the subsequent deployment of any of said proximately disposed aeronautic vehicles. 19. The grid fin device of claim 18, further comprising a mounting assembly for providing at least one of aggregation and stored disposition of said plurality of aeronautic vehicles. 20. The grid fin device of claim 19, wherein at least one of: at least one of said plurality of aeronautic vehicles comprises a missile; and said mounting assembly comprises an eject rail of an aircraft. 21. The grid fin device of claim 20, wherein said optimized grid array geometry comprises a snow angel shape generally configured not to occlude the fins of a trio of missiles mounted on a fighter/bomber aircraft triple eject rail.
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이 특허에 인용된 특허 (6)
Klestadt Ralph H. (Tucson AZ), Aerodynamic lifting and control surface and control system using same.
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