An active wing extension includes a body portion substantially parallel to a wing of an aircraft, as if it were an extension of the wing. The body portion is attachable to an aircraft wing and includes multiple controllable airflow modification devices coupled thereto. By virtue of having multiple c
An active wing extension includes a body portion substantially parallel to a wing of an aircraft, as if it were an extension of the wing. The body portion is attachable to an aircraft wing and includes multiple controllable airflow modification devices coupled thereto. By virtue of having multiple controllable airflow modification devices, the wing extension is capable of adjusting control surfaces of the multiple controllable airflow modification devices in response to in-flight conditions, to reduce wing loads, improve wing fatigue characteristics, increase range, and/or increase efficiency.
대표청구항▼
1. A wing of an aircraft comprising: an angled portion coupled to the wing outboard of an aileron; anda plurality of controllable airflow modification devices (CAMDs) coupled to the wing inboard of the angled portion and outboard of the aileron, the plurality of CAMDs controllable independently of t
1. A wing of an aircraft comprising: an angled portion coupled to the wing outboard of an aileron; anda plurality of controllable airflow modification devices (CAMDs) coupled to the wing inboard of the angled portion and outboard of the aileron, the plurality of CAMDs controllable independently of the aileron, a first CAMD of the plurality of CAMDs comprising a portion of a control surface having an edge substantially adjacent to and parallel with an edge of the wing, a second CAMD of the plurality of CAMDs comprising a portion of a control surface having an edge substantially adjacent to and parallel with the edge of the control surface of the first CAMD, and the plurality of CAMDs configured to reduce a load on the wing. 2. The wing of claim 1, the load comprising stress in the wing caused at least in part by an aerodynamic load exerted on the angled portion. 3. The wing of claim 1, the plurality of CAMDs configured to reduce the load on the wing below a design load. 4. The wing of claim 1, the plurality of CAMDs configured to reduce a spanwise section load to a level at or below a design value for an analogous wing without an angled portion. 5. The wing of claim 1, the plurality of CAMDs being configured to adjust the control surfaces of the plurality of CAMDs at least one of electronically, mechanically, hydraulically, pneumatically, or a combination thereof. 6. The wing of claim 1, the plurality of CAMDs coupled to a control system for controlling the control surfaces of the plurality of CAMDs. 7. The wing of claim 6, the control system comprising a control device with control logic, the control device being communicatively coupled to a sensor located on the aircraft. 8. The wing of claim 7, the control device being configured to receive a signal from the sensor located on the aircraft to indicate at least one of in-flight load factors of the aircraft and flight conditions of the aircraft. 9. The wing of claim 8, the control device being further configured to adjust the plurality of CAMDs at least partly based on the signal from the sensor located on the aircraft. 10. The wing of claim 1, the control system configured to control the control surface of the first CAMD of the plurality of CAMDs independent of the control surface of the second CAMD of the plurality of CAMDs. 11. The wing of claim 1, the control system configured to control the control surface of the first CAMD of the plurality of CAMDs in coordination with the second CAMD of the plurality of CAMDs. 12. The wing of claim 1, further comprising a control system to actively control the controllable airflow modification device to at least one of alleviate loads affecting the wing of the aircraft or to reduce fatigue of the aircraft. 13. The wing of claim 1, wherein the edge of the wing comprises a trailing edge of the wing. 14. A method comprising: receiving in-flight load factor data from a sensor located on an aircraft; andadjusting a plurality of controllable airflow modification devices (CAMDs) coupled to a wing of the aircraft based at least in part on the received in-flight load factor data, the plurality of CAMDs configured to reduce a load on a wing and controllable independently of an aileron of the aircraft, the load comprising a stress in the wing caused at least in part by an aerodynamic load exerted on an angled portion, the angled portion coupled to the wing and located outboard of the aileron, the plurality of CAMDs coupled to the wing outboard of the aileron, a first CAMD the plurality of CAMDs comprising a first control surface with an edge substantially in line with an edge of the wing, and a second CAMD of the plurality of CAMDs comprising a second control surface with an edge substantially in line with the edge of the wing. 15. The method of claim 14, the load comprising a spanwise section load, and the plurality of CAMDs configured to reduce the spanwise section load to a level at or below a design value for an analogous wing without an angled portion. 16. The method of claim 14, the edge of the wing comprising a trailing edge. 17. The method of claim 14, the first CAMD comprising one edge or portion of the first control surface coupled to a hinge; and the adjusting of the first CAMD comprising rotating the first control surface at the hinge along a horizontal axis such that an edge of the control surface other than the one edge coupled to the hinge moves up or down in relation to the horizontal portion of the aircraft. 18. The method of claim 14, the adjusting of the plurality of CAMDs configured to at least one of reduce a wing load of a wing of the aircraft by moving a center of pressure of the wing inboard or reduce an impact of a winglet on a fatigue life of a wing of the aircraft, the wing load comprising at least one of a bending moment or a torsion moment of the wing. 19. The method of claim 14, the adjusting of the plurality of CAMDs comprising adjusting the first CAMD of the plurality of CAMDs independent of the second CAMD of the plurality of CAMDs. 20. The method of claim 14, the adjusting of the plurality of CAMDs comprising: adjusting the first CAMD of the plurality of CAMDs to provide a first control response; andadjusting the second CAMD of the plurality of CAMDs to provide a second control response, a magnitude of the second control response being greater than a magnitude of the first control response. 21. The method of claim 20, the adjusting of the plurality of CAMDs further comprising: adjusting the first CAMD of the plurality of CAMDs while the second CAMD of the plurality of CAMDs is adjusted to provide the second control response. 22. The method of claim 20, wherein the magnitude of the first control response is zero and the magnitude of the second control response is greater than zero. 23. The method of claim 14, the adjusting of the plurality of CAMDs comprising: adjusting a first CAMD of the plurality of CAMDs to provide a first control response; andadjusting a second CAMD of the plurality of CAMDs to provide a second control response synchronously with the first CAMD of the plurality of CAMDs, a magnitude of the second control response being equal to a magnitude of the first control response.
Liu, Danny D.; Chen, Ping-Chih; Sarhaddi, Darius, Apparatus and methods for variable sweep body conformal wing with application to projectiles, missiles, and unmanned air vehicles.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.