Extendable joined wing system for a fluid-born body
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F42B-010/12
F42B-010/00
출원번호
US-0698580
(2003-10-31)
발명자
/ 주소
Fanucci,Jerome P.
King,Michael J.
Maass,David P.
Bystricky,Pavel
출원인 / 주소
Kazak Composites, Incorporated
대리인 / 주소
Weingarten, Schurgin, Gagnebin &
인용정보
피인용 횟수 :
10인용 특허 :
10
초록▼
An extendable wing system for a fluid-born body has a forward wing and an aft wing pivotably coupled together at a location outward of their wing roots. A linkage mechanism mounted on the body provides both pivoting of the wing roots about a pivot point and translation of the wing roots and their pi
An extendable wing system for a fluid-born body has a forward wing and an aft wing pivotably coupled together at a location outward of their wing roots. A linkage mechanism mounted on the body provides both pivoting of the wing roots about a pivot point and translation of the wing roots and their pivot points to extend the joined wings from a stowed position to a deployed position. Translation of the forward wing root pivot point allows the stowed wing system to occupy additional space toward the nose of the body, thereby allowing use of wings having a longer wingspan and greater aspect ratio. The linkage mechanism can also be used to incorporate flight control, such as roll and pitch control, directly into the wing system. In another embodiment, the wings can incorporate actuator elements on or within the wings to effect flight control by deformation of the wing structure.
대표청구항▼
What is claimed is: 1. An extendable wing system for a fluid-born body, comprising: a forward wing extending from a forward wing root to a forward wing tip, the forward wing having an airfoil profile in cross-section; an aft wing extending from an aft wing root to an aft wing tip, the aft wing havi
What is claimed is: 1. An extendable wing system for a fluid-born body, comprising: a forward wing extending from a forward wing root to a forward wing tip, the forward wing having an airfoil profile in cross-section; an aft wing extending from an aft wing root to an aft wing tip, the aft wing having an airfoil profile in cross-section; the forward wing and the aft wing pivotably coupled together at a location outward of the forward wing root end the aft wing root; and a linkage mechanism translationally and rotationally coupled to the forward wing root and the aft wing root and configured to effect extension of the forward wing and the aft wing from a stowed position to a deployed position by translation of the forward wing root and the aft wing root in a same direction along a path, the forward wing root end the aft wing root located closer to a nose of the fluid-born body in the stowed position than in the deployed position. 2. The extendable wing system of claim 1, further comprising an actuating mechanism operatively coupled to the linkage mechanism to drive translation of at least one wing root, and rotation of the wing roots follows translation of the wing roots. 3. The extendable wing system of claim 2, wherein the actuating mechanism is operatively coupled to the linkage mechanism to drive the aft wing root. 4. The extendable wing system of claim 1, wherein the linkage mechanism is disposed to provide a determined ratio of translation of one wing root relative to translation of the other wing root. 5. The extendable wing system of claim 1, wherein the linkage mechanism further comprises a linear rail, the forward wing root and the aft wing root each mounted to a block disposed for travel along the rail. 6. The extendable wing system of claim 5, wherein the linkage mechanism further comprises a pivoting mechanism mounted on each block, the forward wing root and the aft wing root mounted via the pivoting mechanism to the block. 7. The extendable wing system of claim 5, wherein a pivot point of the aft wing root is laterally displaced with respect to the rail from a pivot point of the forward wing root. 8. The extendable wing system off claim 5, further comprising an actuating mechanism operative to actuate translation off the blocks. 9. The extendable wing system of claim 5, further comprising an actuating mechanism operative to actuate translation of one of the blocks, and the other of the blocks is coupled to the one of the blocks for translation therewith. 10. The extendable wing system of claim 5 wherein the linkage mechanism further comprises a pulley system coupling the forward wing root and the aft wing root. 11. The extendable wing system of claim 1, further comprising an actuator element on or within at least one of the forward wing and the aft wing, the actuator element operative to deform the associated wing in response to a control signal. 12. The extendable wing system of claim 11, wherein the actuator element comprises a piezoelectric element. 13. The extendable wing system of claim 11, wherein the actuator element comprises a shape-memory alloy, a ferroelectric material, or a ferromagnetic material. 14. The extendable wing system of claim 11, wherein the actuator element is disposed on a pressure face of the associated wing. 15. The extendable wing system of claim 11, wherein the actuator element is disposed to generate a torsional deformation of the associated wing. 16. The extendable wing system of claim 11, further comprising a plurality of actuator elements distributed along at least a portion of one of the wings. 17. The extendable wing system of claim 11, wherein the actuator element is located at a discrete location along one of the wings. 18. The extendable wing system of claim 11, wherein the actuator element is disposed adjacent a trailing edge at the wing root of one of the wings. 19. The extendable wing system of claim 18, wherein the actuator element comprises a piezoelectric element. 20. The extendable wing system of claim 1, wherein the forward wing and the aft wing comprise composite pultrusions. 21. The extendable wing system of claim 1, wherein the forward wing and the aft wing comprise fiber-reinforced, resin matrix composites having at least a portion of fibers extending continuously in a longitudinal direction extending between the wing root and the wing tip. 22. The extendable wing system of claim 21, wherein a further portion of the fibers extends at an acute angle to the longitudinal direction. 23. The extendable wing system of claim 22, wherein the further portion of the fibers extends at generally 짹45째 to the longitudinal direction. 24. The extendable wing system of claim 21, further comprising a core within the portion of the fibers. 25. The extendable wing system of claim 24, wherein the core comprises fibers or a foam material. 26. The extendable wing system of claim 21, wherein the forward wing and the aft wing are hollow. 27. The extendable wing system of claim 1, wherein the forward wing and the aft wing are comprised of metal. 28. The extendable wing system of claim 1, wherein at least one of the forward wing and the aft wing has a spanwise twist distribution. 29. An air-born body comprising: a fuselage; a first extendable wing system and a second extendable wing system according to claim 1, the first and second extendable wing systems mounted to the fuselage to extend on opposite sides of the fuselage in the deployed position and to store against the fuselage in the stowed position. 30. The air-born body of claim 29, wherein a center of pressure of each of the first and second wing systems is disposed further aft than a center of gravity of the air-born body with the first and second wing systems in the deployed position. 31. The air-born body of claim 29, wherein a center of pressure of at least one of the first and second wing systems is disposed further aft than a center of gravity of the air-born body with the first and second wing systems in the deployed position. 32. The air-born body of claim 29, wherein a center of pressure of each of the first and second wing systems is disposed further forward than a center of gravity of the air-born body with the first and second wing systems in the deployed position. 33. The air-born body of claim 29, wherein a center of pressure of at least one of the first and second wing systems is disposed further forward than a center of gravity of the air-born body with the first and second wing systems in the deployed position. 34. The air-born body of claim 29, wherein the forward wing of the first wing system and the forward wing of the second wing system are coupled for simultaneously translation by the linkage system. 35. The air-born body of claim 29, wherein the aft wing of the first wing system and the aft wing of the second wing system are coupled for simultaneously translation by the linkage system. 36. The air-born body of claim 29, wherein the forward wing root of the first wing system and the forward wing root of the second wing system are coupled by the linkage mechanism for simultaneous motion. 37. The air-born body of claim 29, wherein the rear wing root of the first wing system end the rear wing root of the second wing system are coupled by the linkage mechanism for simultaneous motion. 38. The air-born body of claim 29, wherein the forward wing root of the first wing system and the forward wing root of the second wing system are coupled by the linkage mechanism for simultaneous motion; and the rear wing root of the first wing system and the rear wing root of the second wing system are coupled by the linkage mechanism for simultaneous motion. 39. The air-born body of claim 29, wherein the forward wing root of the first wing system and the forward wing root of the second wing system are independently coupled to the linkage mechanism. 40. The air-born body of claim 29, wherein the rear wing root of the first wing system and the rear wing root of the second wing system are independently coupled to the linkage mechanism. 41. The air-born body of claim 29, wherein the forward wing root of the first wing system and the forward wing root of the second wing system are independently coupled to the linkage mechanism; and the rear wing root of the first wing system and the rear wing root of the second wing system are independently coupled to the linkage mechanism.
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