A wind turbine blade is situated on a wind turbine and includes a side and a tip. The blade is configured to rotate about an axis upon an impact of a wind flow on the blade. An active flow modification device is disposed on the blade. The active flow modification device is configured to receive acti
A wind turbine blade is situated on a wind turbine and includes a side and a tip. The blade is configured to rotate about an axis upon an impact of a wind flow on the blade. An active flow modification device is disposed on the blade. The active flow modification device is configured to receive active flow instructions and to modify the wind flow proximate to the blade. The resulting wind turbine blade uses these active flow modifications to achieve reduced loads, reduced aerodynamic losses, reduced noise, enhanced energy capture, or combinations thereof.
대표청구항▼
The invention claimed is: 1. A wind turbine comprising: a wind turbine blade situated on the wind turbine and being configured to rotate about an axis upon an impact of a wind flow on the blade; a plurality of active flow modification devices comprising a plurality of synthetic jets disposed on the
The invention claimed is: 1. A wind turbine comprising: a wind turbine blade situated on the wind turbine and being configured to rotate about an axis upon an impact of a wind flow on the blade; a plurality of active flow modification devices comprising a plurality of synthetic jets disposed on the blade at a plurality of locations, the active flow modification devices configured to receive active flow instructions and introduce a jet flow to modify the wind flow proximate to the blade; and a controller configured for providing the active flow instructions to the active flow modification devices based on a response strategy to modify the jet flow introduced by the active flow modification devices, wherein the response strategy is selected from the group consisting of modifying a velocity of the synthetic jet, modifying a frequency of the synthetic jet, selectively activating the synthetic jet based on the location of the synthetic jet on the blade, an angle of the synthetic jet, a size of the synthetic jet exit, a shape of the synthetic jet exit, and combinations thereof. 2. The wind turbine of claim 1, wherein the active flow modification device is configured for modifying a load on the wind turbine by reducing the load on the wind turbine. 3. The wind turbine of claim 1, wherein the active flow modification device is disposed on the side, and wherein the active flow modification device is configured for modifying flow separation. 4. The wind turbine of claim 3, wherein the active flow modification device is configured for inhibiting flow separation by introducing an unsteady jet flow with a large component of momentum and vorticity substantially along the wind flow proximate to the blade. 5. The wind turbine of claim 3, wherein the active flow modification device is configured for promoting flow separation by introducing an unsteady jet flow with a large component of momentum substantially disruptive to the wind flow proximate to the blade. 6. The wind turbine blade of claim 1, wherein the at least one active flow modification device comprises a dual bimorph synthetic jet device. 7. A wind turbine comprising: a wind turbine blade situated on the wind turbine comprising a side and a tip, the blade being configured to rotate about an axis upon an impact of a wind flow on the blade; and an active flow modification device disposed on the blade, the active flow modification device configured to receive active flow instructions and introduce a jet flow to modify the wind flow proximate to the blade, wherein the active flow modification device is disposed on the tip, and wherein the active flow modification device is configured for modifying a tip vortex. 8. The wind turbine of claim 7, wherein the active flow modification device is configured for modifying the tip vortex by weakening, destroying, displacing, or combinations thereof. 9. The wind turbine of claim 7, wherein the active flow modification device is configured to introduce an unsteady jet flow in the wind flow proximate to the tip. 10. The wind turbine of claim 7, wherein the active flow modification device introduces an unsteady jet flow in the wind flow proximate to the tip, and further comprising a controller configured for providing the active flow instructions to the active flow modification device to modify a characteristic of the introduced jet flow, wherein the active flow modification device comprises a synthetic jet, and wherein the characteristic is gone of a velocity of the synthetic jet and a frequency of the synthetic jet, an angle of the synthetic jet, a size of the synthetic jet exit, a shape of the synthetic jet exit, and combinations thereof. 11. The wind turbine blade of claim 7, wherein the at least one active flow modification device comprises a dual bimorph synthetic jet device. 12. A method of operating a wind turbine comprising a blade rotatable about an axis upon an impact of a wind flow on the blade, the method comprising: obtaining a current state of at least one operating condition of the wind turbine; and actively modifying the wind flow proximate to the blade in response to the current state of the at least one operating condition, wherein said actively modifying the wind flow comprises using a dual bimorph synthetic jet device, and wherein the at least one operating condition is selected from the group consisting of a wind flow velocity, a wind flow direction, a turbine rotation speed, a pitch angle, a yaw angle and combinations thereof. 13. The method of claim 12, wherein said actively modifying the wind flow is performed in a manner to reduce a load on the wind turbine. 14. The method of claim 12, wherein said actively modifying the wind flow comprises modifying a flow separation in the wind flow proximate to the blade. 15. The method of claim 12, wherein said actively modifying the wind flow comprises inhibiting a flow separation in the wind flow proximate to the blade by introducing an unsteady jet flow having a large component of momentum and vorticity substantially along the wind flow proximate to the blade. 16. The method of claim 15, wherein said inhibiting the flow separation occurs in response to a lower than desired level of wind lift to the wind turbine. 17. The method of claim 12, wherein said actively modifying the wind flow comprises initiating a flow separation in the wind flow proximate to the blade by introducing an unsteady jet flow having a large component of momentum substantially disruptive to the wind flow proximate to the blade. 18. The method of claim 17, wherein said initiating a flow separation occurs in response to a higher than desired level of wind lift generated by the wind flow. 19. A method of operating a wind turbine comprising a blade rotatable about an axis upon an impact of a wind flow on the blade, the method comprising: obtaining a current state of at least one operating condition of the wind turbine; and actively modifying the wind flow proximate to the blade in response to the current state of the at least one operating condition, wherein said actively modifying the wind flow comprises using a dual bimorph synthetic jet device, and wherein said actively modifying comprises attenuating an aerodynamic noise generated proximate to a tip of the blade by introducing a jet flow proximate to the tip. 20. The method of claim 19, wherein said introducing the jet flow modifies a tip vortex. 21. A wind turbine blade assembly comprising: a wind turbine blade comprising a side and a tip, the blade being configured to rotate about an axis upon an impact of a wind flow on the blade; and a plurality of active flow modification devices disposed on the blade at a plurality of locations, the active flow modification device configured to receive active flow instructions and introduce a jet flow to modify the wind flow proximate to the blade; and a controller configured for providing the active flow instructions to the active flow modification device based on a response strategy to modify the jet flow introduced by the active flow modification device. 22. The wind turbine blade assembly of claim 21, wherein the active flow modification device is configured for modifying a load on the wind turbine. 23. The wind turbine blade assembly of claim 21, wherein the active flow modification device is disposed on the side, and wherein the active flow modification device is configured for modifying a flow separation of the wind flow proximate to the blade. 24. The wind turbine blade assembly of claim 23, wherein the active flow modification device is configured to introduce an unsteady jet flow with a large component of momentum and vorticity substantially along the wind flow proximate to the blade. 25. The wind turbine blade assembly of claim 23, wherein the active flow modification device is configured to introduce an unsteady jet flow with a large component of momentum substantially disruptive to the wind flow proximate to the blade. 26. The wind turbine blade assembly of claim 21, wherein the active flow modification device is disposed on the tip, and the active flow modification device is configured for modifying a tip vortex. 27. The wind turbine blade of claim 21, wherein the at least one active flow modification device comprises a dual bimorph synthetic jet device. 28. The wind turbine blade of claim 21, wherein the response strategy is selected from the group consisting of modifying a velocity of the synthetic jet, modifying a frequency of the synthetic jet, selectively activating the synthetic jet based on a location of the synthetic jet on the blade, an angle of the synthetic jet, a size of the synthetic jet exit, a shape of the synthetic jet exit, and combinations thereof. 29. A wind turbine blade comprising at least one active flow modification device disposed on the blade, the at least one active flow modification device receiving active flow instructions from a controller based on an operating condition of the wind turbine blade, and introducing in a time-dependent fashion, jets of selected strengths and selected frequencies proximate to the wind turbine blade to control flow separation proximate to the wind turbine blade based on a response strategy to modify the jet flow introduced by the at least one active flow modification device, wherein the operating condition is selected from the group consisting of a wind flow velocity, a wind flow direction, a turbine rotation speed, a pitch angle, a yaw angle and combinations thereof, thereby modifying a loading of the wind turbine blade. 30. The wind turbine blade of claim 29, wherein the at least one active flow modification device comprises a dual bimorph synthetic jet device. 31. The wind turbine blade of claim 29, wherein the at least one active flow modification device comprises a dual bimorph synthetic jet device. 32. The wind turbine blade of claim 29, wherein the response strategy is selected from the group consisting of modifying a velocity of the synthetic jet, modifying a frequency of the synthetic jet, selectively activating the synthetic jet based on a location of the synthetic jet on the blade, an angle of the synthetic jet, a size of the synthetic jet exit, a shape of the synthetic jet exit, and combinations thereof.
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