Kinetic hydropower generation system and intake therefore
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F03B-017/06
F03B-015/20
F03B-013/10
F03B-013/12
F03B-013/26
F03D-007/04
F03D-011/04
출원번호
US-0466840
(2009-05-15)
등록번호
US-8651798
(2014-02-18)
발명자
/ 주소
Allaei, Daryoush
출원인 / 주소
Sheer Wind, Inc.
대리인 / 주소
Leffert Jay & Polglaze, P.A.
인용정보
피인용 횟수 :
1인용 특허 :
8
초록▼
A kinetic hydropower generation system has a turbine and a generator coupled to the turbine. An underwater intake nozzle assembly is fluidly coupled to the turbine. For one embodiment, an underwater tower nozzle may be fluidly coupled between the turbine and the underwater intake nozzle assembly. Th
A kinetic hydropower generation system has a turbine and a generator coupled to the turbine. An underwater intake nozzle assembly is fluidly coupled to the turbine. For one embodiment, an underwater tower nozzle may be fluidly coupled between the turbine and the underwater intake nozzle assembly. The underwater intake nozzle assembly may include a collector and a converging nozzle.
대표청구항▼
1. A kinetic hydropower generation system, comprising: a turbine;a generator coupled to the turbine; andone or more underwater intake nozzle assemblies, each underwater intake nozzle assembly comprising: a collector and an integral converging nozzle, the collector configured to collect water current
1. A kinetic hydropower generation system, comprising: a turbine;a generator coupled to the turbine; andone or more underwater intake nozzle assemblies, each underwater intake nozzle assembly comprising: a collector and an integral converging nozzle, the collector configured to collect water current and to deliver the collected water current to the converging nozzle, the converging nozzle configured to accelerate the water current delivered thereto and to deliver the accelerated the water current to the turbine;a controller;one or more actuators coupled in direct physical contact with an outer surface of at least one of the collector and the converging nozzle and electrically coupled to the controller;wherein the one or more actuators are configured to receive electrical signals from the controller and to exert forces on the outer surface of the at least one of the collector and the converging nozzle in response to receiving the electrical signals from the controller; andwherein the forces exerted on the outer surface of the at least one of the collector and the converging nozzle in response to receiving the electrical signals from the controller change a shape of the at least one of the collector and the converging nozzle;wherein the turbine is configured to receive the accelerated flow in a direction that is substantially parallel to a rotational axis of the turbine. 2. The kinetic hydropower generation system of claim 1, wherein the turbine and the generator are located under water, on land, or on a platform floating on the water. 3. The kinetic hydropower generation system of claim 1, wherein the forces exerted on the outer surface of the at least one of the collector and the converging nozzle by the one or more actuators are based on a velocity of the water current. 4. The kinetic hydropower generation system of claim 1, further comprising a water-velocity sensor electrically coupled to the controller for sensing and providing a velocity of the water current to the controller. 5. A kinetic hydropower generation system, comprising: a turbine;a generator coupled to the turbine; andone or more underwater turbine-intake towers, each underwater turbine intake tower comprising: a substantially horizontal intake nozzle assembly located at a vertical level above an outlet of the turbine-intake tower;a substantially vertical tower nozzle fluidly coupled to the intake nozzle assembly and the turbine and extending substantially vertically between the intake nozzle assembly and the outlet of the turbine-intake tower;a controller; andone or more actuators coupled in direct physical contact with an outer surface of the intake nozzle assembly and electrically coupled to the controller, wherein the one or more actuators are configured to receive electrical signals from the controller that cause the one or more actuators to exert forces on the outer surface of the intake nozzle assembly that change a shape of the intake nozzle assembly. 6. The kinetic hydropower generation system of claim 5, further comprising; a hollow support column;wherein the intake nozzle assembly is rotatably coupled to the hollow support column; andwherein the tower nozzle is disposed within the hollow support column. 7. The kinetic hydropower generation system of claim 6, further comprising a flow-direction sensor coupled to the intake nozzle assembly and configured to catch a water current flow such that the water current flow rotates the intake nozzle assembly relative to the support column so that the intake nozzle assembly is directed into the water current flow. 8. The kinetic hydropower generation system of claim 5, wherein the intake nozzle assembly comprises a collector and an integral converging nozzle. 9. The kinetic hydropower generation system of claim 8, wherein the one or more actuators coupled in direct physical contact with the outer surface of the intake nozzle assembly comprise one or more first actuators coupled in direct physical contact with an outer surface of the collector and one or more second actuators coupled in direct physical contact with an outer surface of the integral converging nozzle. 10. The kinetic hydropower generation system of claim 5, wherein the turbine and the generator are located under water, on land, or on a platform floating on the water. 11. The kinetic hydropower generation system of claim 5, wherein the turbine is a vertical-axis turbine and receives a fluid flow directly from the tower nozzle or a horizontal-axis turbine that is configured to receive a substantially horizontal flow from a substantially horizontal outlet duct of the turbine-intake tower that is fluidly coupled to the tower nozzle and the turbine. 12. The kinetic hydropower generation system of claim 5, wherein the kinetic hydropower generation system is part of an underwater kinetic-hydropower-generation farm comprising a plurality of the kinetic hydropower generation systems. 13. The kinetic hydropower generation system of claim 5, wherein the signals from the controller that cause the one or more actuators to exert the forces on the outer surface of the intake nozzle assembly that change a shape of the intake nozzle assembly are based on a velocity of a water current. 14. The kinetic hydropower generation system of claim 5, further comprising a water-velocity sensor electrically coupled to the controller for sensing and providing a velocity of a water current to the controller. 15. The kinetic hydropower generation system of claim 14, wherein the controller is configured to determine a voltage to be applied to an actuator of the one or more actuators to adjust a diameter of the intake nozzle assembly in order to produce a certain water velocity at an outlet of the turbine-intake tower for the velocity of the water current provided to the controller by the water-velocity sensor. 16. The kinetic hydropower generation system of claim 5, wherein the controller is configured to determine a required water velocity at an outlet of the turbine-intake tower to produce a certain power. 17. A method of delivering water current to a turbine, comprising: accelerating the water current within a first underwater nozzle facing into the water current;further accelerating the water current within a second underwater nozzle that is substantially perpendicular to the first nozzle;adjusting a shape of the first underwater nozzle using one or more actuators coupled in direct physical contact with an outer surface of the first underwater nozzle, wherein adjusting the shape of the first underwater nozzle using the one or more actuators comprises the one or more actuators exerting forces on the outer surface of the first nozzle in response to the one or more actuators receiving electrical signals from a controller electrically coupled to the one or more actuators; andafter further accelerating the water current in the second underwater nozzle, directing the water current onto blades of the turbine. 18. The method of claim 17, wherein the electrical signals received by the one or more actuators from the controller are based on a velocity of the water current external to the first and second underwater nozzles. 19. The method of claim 17, further comprising, before accelerating the water current within the first underwater nozzle: collecting the water current in an underwater collector; anddirecting the water current to the first underwater nozzle from the collector. 20. The method of claim 19, wherein the one or more actuators are one or more first actuators, and further comprising adjusting a shape of the underwater collector using one or more second actuators coupled in direct physical contact with an outer surface of the underwater collector, wherein adjusting the shape of the underwater collector using the one or more second actuators comprises the one or more second actuators exerting forces on the outer surface of the collector in response to the one or more second actuators receiving electrical signals from the controller. 21. The method of claim 17, further comprising bleeding off a portion of the water current between the first and second underwater nozzles and/or between the second underwater nozzle and the turbine. 22. The method of claim 21, further comprising directing the bled-off water current to another turbine. 23. The method of claim 17, further comprising, before accelerating the water current within the first underwater nozzle, catching the water current flow with a flow-direction sensor such that the water current flow rotates the first underwater nozzle relative to the second underwater nozzle so that the first underwater nozzle is directed into the water current.
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이 특허에 인용된 특허 (8)
Gilson James (Rte. 6 ; Box 236 Tennessee Dr. Seymour TN 37865), Airflow converter.
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