A wind turbine is provided. The turbine includes a support having an axis of rotation, a generator, a plurality of blades rotatably mounted on the support about the axis of rotation, the blades being moveable between a retracted position generally parallel with the axis of rotation and a fully deplo
A wind turbine is provided. The turbine includes a support having an axis of rotation, a generator, a plurality of blades rotatably mounted on the support about the axis of rotation, the blades being moveable between a retracted position generally parallel with the axis of rotation and a fully deployed position generally perpendicular with the axis of rotation, the blades being connected to the generator such that rotation of the blades in a direction induced by wind causes the generator to produce electricity, and the provision of electricity to the generator rotates the blades, and a controller connected to the generator and configured to deliver a flow of current to the generator that is sufficient to move the blades from the retracted position toward the fully deployed position and insufficient to move the blades all the way to the fully deployed position. The flow of current induces rotation of the blades in the direction induced by wind, which creates a centrifugal force that moves the blades from the retracted position toward the fully deployed position. As the blades move from the retracted position, the blades have increasing exposure to ambient wind to receive additional rotational force from ambient wind, and the additional rotational force being sufficient to, either alone or in combination with the flow of current, move the blades into the fully deployed position.
대표청구항▼
1. A wind turbine, comprising: a support having an axis of rotation;a generator;a plurality of blades rotatably mounted on the support about the axis of rotation, the blades being moveable between a retracted position generally parallel with the axis of rotation and a fully deployed position general
1. A wind turbine, comprising: a support having an axis of rotation;a generator;a plurality of blades rotatably mounted on the support about the axis of rotation, the blades being moveable between a retracted position generally parallel with the axis of rotation and a fully deployed position generally perpendicular with the axis of rotation;the blades being connected to the generator such that rotation of the blades in a direction induced by wind causes the generator to produce electricity, and the provision of electricity to the generator rotates the blades;a controller connected to the generator and configured to deliver a flow of current to the generator that is sufficient to move the blades from the retracted position toward the fully deployed position and insufficient to move the blades all the way to the fully deployed position;wherein the flow of current induces rotation of the blades in the direction induced by wind, which creates a centrifugal force that moves the blades from the retracted position toward the fully deployed position;wherein, as the blades move from the retracted position, the blades have increasing exposure to ambient wind to receive additional rotational force from ambient wind, and the additional rotational force being sufficient to, either alone or in combination with the flow of current, move the blades into the fully deployed position;the turbine being adapted to execute first and second retraction protocols, the first retraction protocol being a slowing of the rotation of the blades and the second retraction protocol being rotating the blades in an opposite direction to that induced by ambient wind;said controller is configured to execute the first or second retraction protocol. 2. The turbine of claim 1, wherein based on ambient wind speed a transitional intermediate position of partial deployment exists between the retracted position and the fully deployed position, and at the transitional intermediate position the ambient wind contributes sufficient rotational force on the blades to move the blades into the fully deployed position. 3. The turbine of claim 2, wherein the controller reduces the flow of the current after the blades move from the retracted position to the transitional intermediate position. 4. The turbine of claim 2, wherein the controller is configured to identify the transitional intermediate position based on when the rotating speed of the blades exceeds what is induced by the flow of the current. 5. The turbine of claim 4, wherein the controller reduces the flow of the current after the blades move from the retracted position to the transitional intermediate position. 6. The turbine of claim 1, wherein said controller is configured to move the blades out of the fully deployed position by slowing the rotation of the blades, such that force from ambient wind that biases the blades toward the retracted position overcomes the centrifugal force of the rotating blades that biases the blades toward the fully deployed position. 7. The turbine of claim 1, further comprising: the first and second retraction protocols are stored in a memory;said controller being configured to execute the first or second retraction protocol comprises the controller being configured to (a) select the first or second retraction protocol, and (b) implemented the selection. 8. The turbine of claim 1, further comprising the controller being configured to move the blades from the fully deployed position to a partially deployed position and to maintain the partially deployed position by slowing the rotation of the blades. 9. The turbine of claim 1, further comprising: a support hub rotatably mounted relative to the axis of rotation;each of the blades being pivotally mounted to the support hub;a support rod coaxial with the axis of rotation;a sliding ring mounted on the support rod; anda plurality of braces, each pivotally connecting one of the blades to the sliding ring;wherein the sliding ring moves toward and away from the support hub as the blades open and close, respectively. 10. The turbine of claim 1, wherein the support includes a nacelle. 11. A method for moving the blades of a wind turbine, comprising: providing the wind turbine, the wind turbine comprising: a support having an axis of rotation;a generator;a plurality of blades rotatably mounted on the support about the axis of rotation, the blades being moveable between a retracted position generally parallel with the axis of rotation and a fully deployed position generally perpendicular with the axis of rotation;the blades being connected to the generator such that rotation of the blades in a direction induced by wind causes the generator to produce electricity, and the provision of electricity to the generator rotates the blades;delivering a flow of current to the generator that is sufficient to move the blades from the retracted position toward the fully deployed position and insufficient to move the blades all the way to the fully deployed position;wherein the flow of current induces rotation of the blades in the direction induced by wind, which creates a centrifugal force that moves the blades from the retracted position toward the fully deployed position;wherein, as the blades move from the retracted position, the blades have increasing exposure to ambient wind to receive additional rotational force from ambient wind, and the additional rotational force being sufficient to, either alone or in combination with the flow of current, move the blades into the fully deployed position;the turbine being adapted to execute first and second retraction protocols, the first retraction protocol being a slowing of the rotation of the blades and the second retraction protocol being rotating the blades in an opposite direction to that induced by ambient wind; andimplementing the first or second retraction protocol. 12. The method of claim 11, wherein based on ambient wind speed a transitional intermediate position of partial deployment exists between the retracted position and the fully deployed position, and at the transitional intermediate position the ambient wind contributes sufficient rotational force on the blades to move the blades into the fully deployed position. 13. The method of claim 12, further comprising reducing the flow of the current after the blades move from the retracted position to the transitional intermediate position. 14. The method of claim 12, further comprising identifying when to commence the reducing the current based on when the rotating speed of the blades exceeds what is induced by the flow of the current. 15. The method of claim 14, further comprising reducing the flow of the current after the blades move from the retracted position to the transitional intermediate position. 16. The method of claim 11, further comprising moving the blades out of the fully deployed position by slowing the rotation of the blades, such that force from ambient wind that biases the blades toward the retracted position overcomes the centrifugal force of the rotating blades that biases the blades toward the fully deployed position. 17. The method of claim 11, further comprising: storing first and second retraction protocols in a memory;selecting the first or second retraction protocol based on system parameters of the turbine; andthe implementing comprises implementing the selection. 18. The method of claim 11, further comprising: moving the blades from the fully deployed position to a partially deployed position; and maintaining the partially deployed position by slowing the rotation of the blades.
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이 특허에 인용된 특허 (4)
Ducker William L. (Lubbock TX), Adjustable vane windmills.
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