A variable camber system for an aircraft may include a variable camber trim unit (VCTU) positioned between an inboard device and an outboard device. The inboard device and the outboard device may be mounted to at least one of a leading edge and a trailing edge of a wing. The VCTU may include a speed
A variable camber system for an aircraft may include a variable camber trim unit (VCTU) positioned between an inboard device and an outboard device. The inboard device and the outboard device may be mounted to at least one of a leading edge and a trailing edge of a wing. The VCTU may include a speed sum gearbox having an inboard shaft coupled to the inboard device and an outboard shaft coupled to the outboard device. The VCTU may additionally include a VCTU electric motor engaged to the speed sum gearbox. The VCTU electric motor may be selectively operable in conjunction with the speed sum gearbox to rotate the outboard shaft independent of the inboard shaft in a manner causing the outboard device to be actuated independent of the inboard device.
대표청구항▼
1. A variable camber system for an aircraft, comprising: a variable camber trim unit (VCTU) positioned between an inboard device and an outboard device mounted to at least one of a leading edge and a trailing edge of a wing, and including: a speed sum gearbox including: a sun gear coupled to an inbo
1. A variable camber system for an aircraft, comprising: a variable camber trim unit (VCTU) positioned between an inboard device and an outboard device mounted to at least one of a leading edge and a trailing edge of a wing, and including: a speed sum gearbox including: a sun gear coupled to an inboard shaft and surrounded by a plurality of planet gears, the planet gear supported on a carrier coupled to an outboard shaft, the planet gears engaged to an internal side of a ring gear, an external side of the ring gear engaged to a motor shaft, the inboard shaft coupled to the inboard device, the outboard shaft coupled to the outboard device, the speed sum gearbox configured such that if one of the inboard shaft, the outboard shaft, and the motor shaft is held stationary and prevented from rotating, the remaining pair of shafts rotate under the driving force of one of the remaining shafts of the pair;a VCTU electric motor engaged via the motor shaft to the speed sum gearbox and being selectively operable in conjunction with the speed sum gearbox to rotate the outboard shaft independent of the inboard shaft in a manner causing the outboard device to be actuated independent of the inboard device;a central motor coupled to the inboard device; andthe speed sum gearbox is configured such that when the outboard device is stationary and the central motor drives the inboard device, the VCTU electric motor is back-driven. 2. The variable camber system of claim 1, further comprising: a power-off brake coupled to the VCTU electric motor; andthe speed sum gearbox being configured such that when the power-off brake is applied, the outboard shaft is driven by the inboard shaft causing the inboard device and the outboard device to be actuated in unison. 3. The variable camber system of claim 2, wherein: the central motor is coupled to a central brake preventing movement of the inboard device when the central brake is applied. 4. The variable camber system of claim 1, further comprising: an outboard brake included with the VCTU and configured to prevent movement of the outboard device when the outboard brake is applied; andthe speed sum gearbox being configured such that when the outboard brake is applied, the outboard device is stationary and the inboard device is independently driven by the central motor. 5. The variable camber system of claim 1, wherein at least one of the inboard device and the outboard device comprises at least one of the following: a leading edge device configured as one of a leading edge slat and a Krueger flap; anda trailing edge device configured as a trailing edge flap. 6. The variable camber system of claim 1, wherein: the inboard device is coupled to the inboard shaft by an inboard torque tube; andthe outboard device being coupled to the outboard shaft by an outboard torque tube. 7. An aircraft, comprising: a wing having a leading edge and a trailing edge;an inboard device and an outboard device mounted to at least one of the leading edge and the trailing edge;a variable camber trim unit (VCTU) positioned between the inboard device and the outboard device, and including: a speed sum gearbox including: a sun gear coupled to an inboard shaft and surrounded by a plurality of planet gears, the planet gear supported on a carrier coupled to an outboard shaft, the planet gears engaged to an internal side of a ring gear, an external side of the ring gear engaged to a motor shaft, the inboard shaft coupled to the inboard device, the outboard shaft coupled to the outboard device, the speed sum gearbox configured such that if one of the inboard shaft, the outboard shaft, and the motor shaft is held stationary and prevented from rotating, the remaining pair of shafts rotate under the driving force of one of the remaining shafts of the pair;a VCTU electric motor engaged via the motor shaft to the speed sum gearbox and being selectively operable in conjunction with the speed sum gearbox to rotate the outboard shaft independent of the inboard shaft in a manner causing the outboard device to be actuated independent of the inboard device;a central motor coupled to the inboard device; andthe speed sum gearbox is configured such that when the outboard device is stationary and the central motor drives the inboard device, the VCTU electric motor is back-driven. 8. A method of actuating high-lift devices of an aircraft wing, comprising: operating a variable camber system to actuate an inboard device, an outboard device, or both, wherein the inboard device and the outboard device are mounted to at least one of a leading edge and a trailing edge of a wing, wherein the variable camber system includes a variable camber trim unit (VCTU) positioned between the inboard device and the outboard device, the VCTU including a speed sum gearbox having a sun gear coupled to an inboard shaft and surrounded by a plurality of planet gears, the planet gear supported on a carrier coupled to an outboard shaft, the planet gears engaged to an internal side of a ring gear, an external side of the ring gear engaged to a motor shaft, the inboard shaft coupled to the inboard device, the outboard shaft coupled to the outboard device, the VCTU including a VCTU electric motor engaged via the motor shaft to the speed sum gearbox, the inboard device drivingly coupled to a central motor having a central brake and the outboard device drivingly coupled to the VCTU; andpreventing rotation of one of the inboard shaft, the outboard shaft, and the motor shaft while rotating a remaining pair of shafts under the driving force of one of the remaining shafts of the pair; andwherein the operating the variable camber system includes at least one of actuating, the inboard device independent of the outboard device, actuating the outboard device independent of the inboard device, and actuating the inboard and outboard devices in unison. 9. The method of claim 8, further comprising applying the outboard brake to prevent rotation of an outboard torque tube coupled to the outboard device. 10. The method of claim 8, wherein the operating of the variable camber system includes actuating the outboard device independent of the inboard device by driving an outboard torque tube coupled to the outboard device using the VCTU electric motor while preventing movement of the inboard device. 11. The method of claim 10, further comprising applying the central brake to prevent rotation of an inboard torque tube coupled to the inboard device. 12. The method of claim 8, wherein the operating of the variable camber system includes actuating the inboard and outboard devices in unison by driving inboard and outboard torque tubes using the central motor, the inboard and outboard torque tubes coupled to the inboard and outboard devices, respectively. 13. The method of claim 12, further comprising applying the power-off brake to prevent rotation of the VCTU electric motor. 14. The method of claim 8, wherein at least one of the inboard device and the outboard device comprises at least one of the following: a leading edge device configured as at least one of a leading edge slat and a Krueger flap; anda trailing edge device configured as a trailing edge flap. 15. The method of claim 8, further comprising: differentially deploying the inboard device and the outboard device; andvarying a wing camber along a spanwise direction in response to differentially deploying the inboard device and the outboard device.
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이 특허에 인용된 특허 (13)
Borzachillo Angelo (San Marcos CA), Aeroelastic control flap.
Good,Mark S.; Viigen,Paul M.; Gitnes,Seth E.; Thomas,Glynn Michael, Aircraft wing systems for providing differential motion to deployable lift devices.
Onu, Dan; Winter, John D.; Carr, Candy L.; Vijgen, Paul M.; Emch, Gary A.; Renzelmann, Michael E., Dynamic adjustment of wing surfaces for variable camber.
Good, Mark S.; Vijgen, Paul M.; Gitnes, Seth E.; Thomas, Glynn Michael, Systems and methods for providing differential motion to wing high lift device.
Pachikara, Abraham J.; Moser, Matthew A.; Carpenter, Paul H.; Finn, Michael R.; Koch, Thomas S.; Bieniawski, Stefan R.; Whitehead, Brian T., Closed loop control of aircraft control surfaces.
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