Radiator and duct configuration on an airborne wind turbine for maximum effectiveness
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F03D-011/00
F03D-080/00
F03D-080/60
출원번호
US-0202971
(2014-03-10)
등록번호
US-9835139
(2017-12-05)
발명자
/ 주소
Vander Lind, Damon
출원인 / 주소
X Development LLC
대리인 / 주소
McDonnell Boehnen Hulbert & Berghoff LLP
인용정보
피인용 횟수 :
0인용 특허 :
4
초록▼
In order to maximize cooling while minimizing drag in aerial vehicles of airborne wind turbines, it may be preferable to dissipate the cooling energy of the motors via a radiator in a region with advantageous airflow parameters. Aerial vehicle rotors operating in thrust mode may produce relatively m
In order to maximize cooling while minimizing drag in aerial vehicles of airborne wind turbines, it may be preferable to dissipate the cooling energy of the motors via a radiator in a region with advantageous airflow parameters. Aerial vehicle rotors operating in thrust mode may produce relatively more airflow velocity in certain regions further away from the center of the rotor blades, both radially and longitudinally. Placing a radiator in a rotor-supporting pylon and offset from the center of the rotor blades and aft of the rotor blades may allow for greater cooling while the aerial vehicle while in thrust mode.
대표청구항▼
1. An airborne wind turbine aerial vehicle comprising, a main wing;a pylon fixed to the main wing;a rotor assembly comprising a motor and a plurality of rotor blades, wherein the rotor assembly is fixed to the pylon, and wherein the rotor assembly is configured to operate in at least a thrust mode,
1. An airborne wind turbine aerial vehicle comprising, a main wing;a pylon fixed to the main wing;a rotor assembly comprising a motor and a plurality of rotor blades, wherein the rotor assembly is fixed to the pylon, and wherein the rotor assembly is configured to operate in at least a thrust mode, and wherein an airflow wake created by the rotor blades while operating in thrust mode exhibits, in a longitudinal cross section corresponding to a plane of the pylon, an airflow velocity profile comprising increased airflow velocity (“Δv”) that varies as a function of radial distance (“R”) from a longitudinal centerline of the rotor assembly, and wherein the profile includes a local increased velocity maximum (“Δvmax”) at a distance (“Rmax_flow”) from the longitudinal centerline of the rotor assembly, and wherein the rotor blades have a maximum length (“Rrotor”) measured from the longitudinal centerline of the rotor assembly;a radiator coupled to the motor and configured to cool the motor, wherein the radiator is fixed to the pylon aft of the rotor blades, and wherein a portion of the radiator is located within the plane corresponding to the pylon and at the distance (“Rmax_flow”) from the longitudinal centerline of the rotor assembly. 2. The aerial vehicle of claim 1, wherein the value of Rmax_flow is between 50 percent and 80 percent of the value of Rrotor. 3. The aerial vehicle of claim 1, wherein a portion of the radiator is located at a distance (“L”) aft of the rotor blades, and wherein L≧Rrotor. 4. The aerial vehicle of claim 1, wherein the pylon is configured as a lift-generating airfoil comprising a high pressure surface and an opposing low-pressure surface. 5. The aerial vehicle of claim 4, wherein the radiator is subject to airflow along the high pressure surface of the pylon. 6. The aerial vehicle of claim 1, further comprising a radiator duct, the radiator duct comprising (i) an internal duct surface located at least partially internal to the pylon; (ii) an external duct cover opposite the internal duct surface; (iii) an air inlet; (iv) an air outlet; and (v) an air passage defined, at least in part, by the internal duct surface and the external duct cover, wherein the radiator is located within the air passage, and wherein the air passage is configured to direct airflow from the wake through the radiator. 7. The aerial vehicle of claim 6, wherein the pylon is configured as a lift-generating airfoil comprising a high pressure surface and an opposing low-pressure surface, and wherein the internal duct surface interrupts the high pressure surface. 8. An airborne wind turbine aerial vehicle comprising, a main wing;a pylon fixed to the wing;a rotor assembly fixed to the pylon and comprising a generator and a plurality of rotor blades, wherein the rotor assembly is configured to operate in at least a drag mode, and wherein an airflow wake created by the rotor blades while operating in drag mode exhibits, in a longitudinal cross section corresponding to a plane of the pylon, an airflow velocity profile comprising decreased airflow velocity (“−Δv”) that varies as a function of radial distance (“R”) from a longitudinal centerline of the rotor assembly, and wherein the profile includes a local decreased airflow velocity maximum (“−Δvmax”) at a distance (“Rmin_flow”) from the longitudinal centerline of the rotor assembly, and wherein the rotor blades have a maximum length (“Rrotor”) measured from the longitudinal centerline of the rotor assembly;a radiator coupled to the generator and configured to cool the generator, wherein the radiator is fixed to the pylon aft of the rotor blades, and wherein a portion of the radiator is located within the plane corresponding to the pylon and at the distance (“Rmax_flow”) from the longitudinal centerline of the rotor assembly. 9. The aerial vehicle of claim 8, wherein the value of Rmin_flow is between 50 percent and 80 percent of the value of Rrotor. 10. The aerial vehicle of claim 8, wherein a portion of the radiator is located at a distance (“L”) aft of the rotor blades, and wherein L≧Rrotor. 11. The aerial vehicle of claim 8, wherein the pylon is configured as a lift-generating airfoil comprising a high pressure surface and an opposing low-pressure surface. 12. The aerial vehicle of claim 11, wherein the radiator is subject to airflow along the high pressure surface of the pylon. 13. The aerial vehicle of claim 8, further comprising a radiator duct, the radiator duct comprising (i) an internal duct surface located at least partially internal to the pylon; (ii) an external duct cover opposite the internal duct surface; (iii) an air inlet; (iv) an air outlet; and (v) an air passage defined, at least in part, by the internal duct surface and the external duct cover, wherein the radiator is located within the air passage, and wherein the air passage is configured to direct airflow from the wake through the radiator. 14. The aerial vehicle of claim 13, wherein the pylon is configured as a lift-generating airfoil comprising a high pressure surface and an opposing low-pressure surface, and wherein the internal duct surface interrupts the high pressure surface. 15. An airborne wind turbine aerial vehicle comprising, a main wing;a pylon fixed to the main wing;a rotor assembly fixed to the pylon and comprising a motor and a plurality of rotor blades, wherein the rotor assembly is configured to operate in at least a thrust mode, and wherein an airflow wake created by the rotor blades while operating in thrust mode exhibits, in a longitudinal cross section corresponding to a plane of the pylon, an airflow velocity profile comprising an increased airflow velocity (“Δv”) that varies as a function of radial distance (“R”) from a longitudinal centerline of the rotor assembly, and wherein the rotor blades have a maximum length (“Rrotor”) measured from the longitudinal centerline of the rotor assembly;a radiator coupled to the motor and configured to cool the motor, wherein the radiator is fixed to the pylon aft of the rotor blades, and wherein a portion of the radiator is located within the increased airflow profile and at a distance (“Rradiator”) from a longitudinal centerline of the rotor assembly. 16. The aerial vehicle of claim 15, wherein the value of Rradiator is between 50 percent and 80 percent of the value of Rrotor. 17. The aerial vehicle of claim 15, wherein a portion of the radiator is located at a distance (“L”) aft of the rotor blades, and wherein L≧Rrotor. 18. The aerial vehicle of claim 15, wherein the pylon is configured as a lift-generating airfoil comprising a high pressure surface and an opposing low-pressure surface. 19. The aerial vehicle of claim 18, wherein the radiator is subject to airflow along the high pressure surface of the pylon. 20. The aerial vehicle of claim 15, further comprising a radiator duct, the radiator duct comprising (i) an internal duct surface located at least partially internal to the pylon; (ii) an external duct cover opposite the internal duct surface; (iii) an air inlet; (iv) an air outlet; and (v) an air passage defined, at least in part, by the internal duct surface and the external duct cover, wherein the radiator is located within the air passage, and wherein the air passage is configured to direct airflow from the wake through the radiator.
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이 특허에 인용된 특허 (4)
Carlson Robert B. (Tukwila WA) Cosgrove Barbara J. (Kirkland WA) Meredith Paul T. (Renton WA), Aircraft configuration with aft mounted engines.
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