Wind turbine having a HTS generator with a plurality of phases
First Claim
1. A method of operating a wind turbine comprising:
- providing;
a wind turbine tower having a top and a bottom,a nacelle arranged on top of the wind turbine tower,a rotor hub rotatably mounted to the nacelle,one or more wind turbine blades mounted to the rotor hub, wherein the wind turbine blades define a rotor plane, and wherein a pitching mechanism is coupled to at least a part of one of the wind turbine blades,a shaft coupled to the rotor hub,a generator coupled to the shaft, the generator having a rotor rotatably arranged in relation to a stator, the rotor comprising at least one superconducting rotor coil and the stator comprises at least one conductive stator coil, wherein the superconducting rotor coils and the stator coils have interacting magnetic fields inducing a current in the stator coil when the rotor is rotated,at least one converter is electrically coupled to the generator, the at least one converter having a power grid side electrically connected to a generator side, the power grid side electrically coupled to a power grid having a predetermined grid code, and the generator side electrically coupled to the generator, wherein the at least one converter is configured to convert the power output from the generator so that it matches the power of the power grid,wherein the stator coils in the generator form at least two sets of stator coils for reducing a transient of an electromagnetic brake torque relative to a nominal electromagnetic torque of the generator, and wherein each set of stator coils forms a predetermined number of phases, and wherein the at least one converter includes at least two converter modules each having a generator side and a power grid side, wherein the generator side of each converter module comprises a plurality of rectifying circuits electrically coupled to one of the sets of stator coils arranged in the generator,wherein at least one controller is electrically coupled to at least one measuring unit and to switching means which are electrically coupled to each of the at least two converter modules, wherein the at least one controller is configured to control the operation of the switching means so that the power output is distributed over said at least two converter modules in a normal operation mode;
detecting an error in the wind turbine via the at least one measuring unit;
activating the switching means via the at least one controller so that the at least one converter is disconnected from the power grid;
activating the pitching mechanism so that said at least a part of one of the wind turbine blades is pitched out of a wind direction;
wherein the at least one controller selectively switches off a part of the at least one converter in which the error is detected;
further activating the pitching mechanism so that said at least a part of one of the wind turbine blades is pitched into the wind direction,wherein the at least one controller switches in any remaining parts of the at least one converter in which no error is detected so that the at least one converter is reconnected to the power grid; and
wherein the at least one controller further changes at least a power reference used to control the operation of the wind turbine in the normal operation mode to another predetermined value which is between 40% to 60% of the power output during the normal operation mode.
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Accused Products
Abstract
The present invention relates to a wind turbine having a wind turbine tower with a nacelle provided on the top to which a rotor hub with one or more wind turbine blades is rotatably mounted by a rotor shaft. A generator is arranged in the nacelle, wherein the superconducting rotor coils induce a current in the stator coils when the rotor is rotated, and wherein the stator coils are arranged in at least four phases. One or more converter modules convert the power output from the generator so that it matches the power of a power grid. The generator side of the converter modules comprises a number of rectifying circuits equal to the phases in the generator, while the power grid side comprises a number of inverting circuits equal to the phases of the power grid. This allows the transient of the electromagnetic brake torque relative to the nominal electromagnetic torque of the generator to be reduced. The ripples of the electromagnetic torque are also reduced since the switching frequency of the converter is increased. This in turn reduces the mechanical stresses occurring in the drive train in the event of a failure or error occurring in one of the converter modules. The present invention also relates to a method of operation of such a wind turbine where the defective converter module is selectively switched off and the wind turbine is put into operation again at a lower operation level.
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Citations
6 Claims
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1. A method of operating a wind turbine comprising:
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providing; a wind turbine tower having a top and a bottom, a nacelle arranged on top of the wind turbine tower, a rotor hub rotatably mounted to the nacelle, one or more wind turbine blades mounted to the rotor hub, wherein the wind turbine blades define a rotor plane, and wherein a pitching mechanism is coupled to at least a part of one of the wind turbine blades, a shaft coupled to the rotor hub, a generator coupled to the shaft, the generator having a rotor rotatably arranged in relation to a stator, the rotor comprising at least one superconducting rotor coil and the stator comprises at least one conductive stator coil, wherein the superconducting rotor coils and the stator coils have interacting magnetic fields inducing a current in the stator coil when the rotor is rotated, at least one converter is electrically coupled to the generator, the at least one converter having a power grid side electrically connected to a generator side, the power grid side electrically coupled to a power grid having a predetermined grid code, and the generator side electrically coupled to the generator, wherein the at least one converter is configured to convert the power output from the generator so that it matches the power of the power grid, wherein the stator coils in the generator form at least two sets of stator coils for reducing a transient of an electromagnetic brake torque relative to a nominal electromagnetic torque of the generator, and wherein each set of stator coils forms a predetermined number of phases, and wherein the at least one converter includes at least two converter modules each having a generator side and a power grid side, wherein the generator side of each converter module comprises a plurality of rectifying circuits electrically coupled to one of the sets of stator coils arranged in the generator, wherein at least one controller is electrically coupled to at least one measuring unit and to switching means which are electrically coupled to each of the at least two converter modules, wherein the at least one controller is configured to control the operation of the switching means so that the power output is distributed over said at least two converter modules in a normal operation mode; detecting an error in the wind turbine via the at least one measuring unit; activating the switching means via the at least one controller so that the at least one converter is disconnected from the power grid; activating the pitching mechanism so that said at least a part of one of the wind turbine blades is pitched out of a wind direction; wherein the at least one controller selectively switches off a part of the at least one converter in which the error is detected; further activating the pitching mechanism so that said at least a part of one of the wind turbine blades is pitched into the wind direction, wherein the at least one controller switches in any remaining parts of the at least one converter in which no error is detected so that the at least one converter is reconnected to the power grid; and wherein the at least one controller further changes at least a power reference used to control the operation of the wind turbine in the normal operation mode to another predetermined value which is between 40% to 60% of the power output during the normal operation mode. - View Dependent Claims (2, 3, 4, 5, 6)
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Specification