Spindle mounted tiltrotor pylon with fixed engine arrangement
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B64C-029/00
B64C-027/26
출원번호
US-0801674
(2013-03-13)
등록번호
US-9126678
(2015-09-08)
발명자
/ 주소
Ross, Brent C.
Bockmiller, David R.
Isaac, Mark L.
Cox, Brian J.
출원인 / 주소
Bell Helicopter Textron Inc.
대리인 / 주소
Fish & Richardson P.C.
인용정보
피인용 횟수 :
11인용 특허 :
19
초록▼
A rotor system for tilt rotor aircraft comprises an engine disposed at a first fixed location on a wing member; a prop-rotor pylon mechanically coupled to the engine along a drive path, and a gearbox disposed in the drive path. The prop-rotor pylon is rotatably mounted on a spindle, and the prop-rot
A rotor system for tilt rotor aircraft comprises an engine disposed at a first fixed location on a wing member; a prop-rotor pylon mechanically coupled to the engine along a drive path, and a gearbox disposed in the drive path. The prop-rotor pylon is rotatably mounted on a spindle, and the prop-rotor pylon is configured to selectively rotate about a rotational axis of the spindle between a vertical position and a horizontal position. The gearbox comprises a rotational axis aligned with the rotational axis of the spindle.
대표청구항▼
1. A rotor system for tilt rotor aircraft, the rotor system comprising: an engine disposed at a first fixed location on a wing member;a prop-rotor pylon mechanically coupled to the engine along a first drive path, wherein the prop-rotor pylon is rotatably mounted on a spindle, wherein the prop-rotor
1. A rotor system for tilt rotor aircraft, the rotor system comprising: an engine disposed at a first fixed location on a wing member;a prop-rotor pylon mechanically coupled to the engine along a first drive path, wherein the prop-rotor pylon is rotatably mounted on a spindle, wherein the prop-rotor pylon is configured to selectively rotate about a rotational axis of the spindle between a vertical position and a horizontal position;a gearbox disposed in the first drive path, wherein the gearbox comprises a rotational shaft configured to at least partially transmit a rotation of the engine to the prop-rotor pylon, wherein a rotational axis of the rotational shaft is aligned with the rotational axis of the spindle; andan interconnect drive shaft passing through the wing member, wherein the prop-rotor pylon is mechanically coupled to the interconnect drive shaft along a second drive path, wherein a rotational axis of the interconnect drive shaft is aligned with the rotational axis of the spindle;wherein the interconnect drive shaft is disconnected from the rotational shaft included in the gearbox causing the first drive path and the second drive path to independently engage a prop-rotor gearset. 2. The rotor system of claim 1, wherein the gearbox comprises a spiral bevel gear set. 3. The rotor system of claim 2, wherein the spiral bevel gear set is configured to selectively rotate along an axis of the spindle with the prop-rotor pylon. 4. The rotor system of claim 1, wherein the first drive path comprises an input shaft coupled to the engine and the gearbox and an output shaft coupled to the gearbox, and wherein the output shaft is configured to selectively rotate about the rotational axis of the spindle with the prop-rotor pylon between the vertical position and the horizontal position. 5. The rotor system of claim 4, wherein the input shaft is directly coupled to the engine without any intervening gears. 6. The rotor system of claim 4, wherein the first drive path further comprises at least one planetary gearset coupled to the output shaft between the gearbox and a prop-rotor. 7. The rotor system of claim 4, wherein the first drive path further comprises at least one helical gearset coupled to the output shaft between the gearbox and a prop-rotor. 8. The rotor system of claim 1, wherein the gearbox is coupled to the spindle. 9. The rotor system of claim 1, wherein the engine is disposed in-line with the prop-rotor pylon. 10. The rotor system of claim 1, wherein the engine is disposed outboard of the prop-rotor pylon. 11. The rotor system of claim 1, wherein the engine comprises an air intake, and wherein the air intake is located below the wing member. 12. The rotor system of claim 1, further comprising a conversion actuator coupled to the wing member and the prop-rotor pylon, wherein the conversion actuator is configured to selectively rotate the prop-rotor pylon between the vertical position and the horizontal position. 13. The rotor system of claim 1, wherein the gearbox is a first gearbox comprising: a drive shaft from the engine;a first conical input gear coupled to the drive shaft from the engine;a first conical output gear engaging the first conical input gear and coupled to the rotational shaft;a second conical input gear coupled to the rotational shaft;a second conical output gear engaging the second conical input gear; anda first output shaft coupled to the second conical input gear and coupled to the prop-rotor gearset; andwherein the system further comprises a second gearbox mechanically coupling the interconnect drive shaft and the prop-rotor pylon in the second drive path, the second gearbox comprising:a third conical input gear coupled to the interconnect drive shaft;a third conical output gear engaging the third conical input gear; anda second output shaft coupled to the third conical output gear and coupled to the prop-rotor gearset. 14. A rotor system for tilt rotor aircraft, the rotor system comprising: an engine disposed at a first fixed location on a wing member;an interconnect drive shaft passing through the wing member;a prop-rotor pylon mechanically coupled to the engine along a first drive path and the interconnect drive shaft along a second drive path;a spindle, wherein the prop-rotor pylon is rotatably mounted on the spindle, and wherein the prop-rotor pylon is configured to selectively rotate about a rotational axis of the spindle between a vertical position and a horizontal position;a first gearbox disposed in the first drive path, wherein the first gearbox comprises a rotational shaft configured to mechanically couple the engine and the prop-rotor pylon to at least partially transmit a rotation of the engine to the prop-rotor pylon, wherein a rotational axis of the rotational shaft is aligned with the rotational axis of the spindle; anda second gearbox disposed in the second drive path, wherein the second gearbox is configured to mechanically couple the interconnect drive shaft and the spindle to the prop-rotor pylon, and wherein a rotational axis of the interconnect drive shaft is aligned with the rotational axis of the spindle;wherein the interconnect drive shaft is disconnected from the rotational shaft included in the first gearbox causing the first drive path and the second drive path to independently engage a prop-rotor gearset. 15. The rotor system of claim 14, wherein the first gearbox and the second gearbox each comprise spiral bevel gear sets. 16. The rotor system of claim 15, wherein each of the spiral bevel gearsets are configured to selectively rotate along an axis of the spindle with the prop-rotor pylon. 17. The rotor system of claim 14, wherein the first drive path comprises: a first input shaft coupled to the engine and the first gearbox; anda first output shaft coupled to the first gearbox,wherein the second drive path comprises:a second input shaft coupled to the interconnect drive shaft and the second gearbox; anda second output shaft coupled to the second gearbox, andwherein the first output shaft and the second output shaft are configured to selectively rotate about the rotational axis of the spindle with the prop-rotor pylon between the vertical position and the horizontal position. 18. The rotor system of claim 17, wherein the first output shaft and the second output shaft are mechanically coupled to at least one of a planetary gearset or a helical gearset, and wherein the at least one planetary gearset or helical gearset is coupled to a prop-rotor. 19. An aircraft comprising: a fuselage;a wing member;an engine disposed at a first fixed location on the wing member;a prop-rotor pylon mechanically coupled to the engine along a first drive path; wherein the prop-rotor pylon is configured to selectively rotate about a rotational axis between a vertical position and a horizontal position;a first gearbox comprising a first spiral bevel gearset disposed in the first drive path, wherein the first spiral bevel gearset comprises rotational shaft configured to at least partially transmit a rotation of the engine to the prop-rotor pylon, wherein a rotational axis of the rotational shaft is aligned with the rotational axis of the prop-rotor pylon; andan interconnect drive shaft passing through the wing member, wherein the prop-rotor pylon is mechanically coupled to the interconnect drive shaft along a second drive path, wherein a rotational axis of the interconnect drive shaft is aligned with the rotational axis of the prop-rotor pylon;wherein the interconnect drive shaft is disconnected from the rotational shaft included in the first gearbox causing the first drive path and the second drive path to independently engage a prop-rotor gearset. 20. The aircraft of claim 19, wherein the prop-rotor pylon is rotatably mounted on a spindle, and wherein the spindle is aligned with the rotational axis of the prop-rotor pylon. 21. The aircraft of claim 19, further comprising a second gearbox mechanically coupling the interconnect drive shaft and the prop-rotor pylon in the second drive path, wherein the second gearbox comprises a rotational axis aligned with the rotational axis of the prop-rotor pylon.
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이 특허에 인용된 특허 (19)
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