A wind power station comprises a wind rotor; a transmission mechanically coupled to the wind rotor; an asynchronous generator having a generator rotor mechanically coupled to the transmission, and a generator stator electrically coupled to a power grid; and a protection unit protecting the generator
A wind power station comprises a wind rotor; a transmission mechanically coupled to the wind rotor; an asynchronous generator having a generator rotor mechanically coupled to the transmission, and a generator stator electrically coupled to a power grid; and a protection unit protecting the generator and the transmission against accidental breakdowns of an alternating voltage provided by the power grid. The Protection unit includes at least one choke electrically arranged between the power grid and the generator stator, and a synchronous electrical machine electrically coupled to the choke.
대표청구항▼
We claim: 1. A wind power station comprising: a wind rotor including at least one blade mounted to a rotatable shaft; a transmission having an input shaft mechanically coupled to the rotatable shaft for rotation therewith at a variable input speed, and an output shaft rotating at a variable output
We claim: 1. A wind power station comprising: a wind rotor including at least one blade mounted to a rotatable shaft; a transmission having an input shaft mechanically coupled to the rotatable shaft for rotation therewith at a variable input speed, and an output shaft rotating at a variable output speed which is increased at a fixed ratio as compared to the input speed; and an asynchronous generator having a generator rotor mechanically coupled to the output shaft of the transmission for rotation therewith, and a generator stator electrically coupled to a power grid which provides at least one alternating voltage having a grid frequency to the generator, the generator supplying at least one alternating current to the power grid at the grid frequency; wherein a protection unit protecting the generator and the transmission against accidental breakdowns of the at least one alternating voltage provided by the power grid includes: at least one choke electrically arranged between the power grid and the generator stator, and a synchronous electrical machine electrically coupled to the choke. 2. The wind power station of claim 1, wherein the generator is an asynchronous double fed generator, the generator being electrically coupled to the power grid via at least one power converter, the at least one power converter being electrically arranged on the same side of the choke as the generator stator. 3. The wind power station of claim 1, wherein a nominal capacity of the electrical machine is between 20 and 100% of a nominal capacity of the generator. 4. The wind power station of claim 1, wherein a nominal capacity of the electrical machine is between 30 and 80% of a nominal capacity of the generator. 5. The wind power station of claim 1, wherein a partial inductance of the choke between the power grid and a coupling point of the electrical machine to the choke is about 50% of a nominal reactance of the asynchronous generator under its actual operation conditions. 6. The wind power station of claim 5, wherein a partial inductance of the choke between the coupling point of the electrical machine to the choke and the generator stator is about (L")2/L 1, wherein L1 is the partial inductance of the choke between the power grid and the coupling point of the electrical machine to the choke, and wherein L" is a subtransient reactance of the electrical machine. 7. The wind power station of claim 1, wherein the generator is a multiphase generator, one choke being provided for each phase of the generator. 8. The wind power station of claim 6, wherein the synchronous electrical machine is a multiphase machine having one phase per phase of the asynchronous generator, each phase being coupled to one of the chokes. 9. The wind power station of claim 2, wherein a sensor is provided for surveying the alternating voltage provided by the power grid on the power grid side of the choke, the sensor signaling a breakdown of the voltage to a control unit controlling the at least one power converter. 10. The wind power station of claim 1, wherein a sensor is provided for surveying a phase angle between the at least one alternating voltage provided by the power grid and the at least one alternating current supplied by the generator, the sensor signaling the phase angle to a control unit controlling the phase angle within predetermined threshold values by supplying electrical quantities to the electrical machine. 11. The wind power station of claim 1, wherein a transformer is electrically arranged between the choke and the power grid. 12. A wind power station comprising: a wind rotor including at least one blade mounted to a rotatable shaft; a transmission having an input shaft mechanically coupled to the rotatable shaft for rotation therewith at a variable input speed, and an output shaft rotating at a variable output speed which is increased at a fixed ratio as compared to the input speed; and an asynchronous double fed three phase generator having a generator rotor mechanically coupled to the output shaft of the transmission for rotation therewith and electrically coupled to a three phase power grid via at least one power converter per phase of the power grid, and a generator stator electrically coupled to a power grid which provides a rotary voltage having a grid frequency to the generator, the generator supplying a rotary current to the power grid at the grid frequency; wherein a protection unit protecting the generator, the power converters and the transmission against accidental breakdowns of the rotary voltage provided by the power grid includes: one choke per phase of the power grid electrically arranged between the power grid on the one hand, and the generator stator and at least one of the power converters of the generator rotor on the other hand, and a three phase synchronous electrical machine electrically coupled to the chokes. 13. A protection unit for a wind power station comprising: a wind rotor including at least one blade mounted to a rotatable shaft; a transmission having an input shaft mechanically coupled to the rotatable shaft for rotation therewith at a variable input speed, and an output shaft rotating at a variable output speed which is increased at a fixed ratio as compared to the input speed; and an asynchronous double fed three phase generator having a generator rotor mechanically coupled to the output shaft of the transmission for rotation therewith and electrically coupled to a three phase power grid via at least one power converter per phase of the power grid, and a generator stator electrically coupled to a power grid which provides a rotary voltage having a grid frequency to the generator, the generator supplying a rotary current to the power grid at the grid frequency; wherein the protection unit protects the generator, the power converters and the transmission against accidental breakdowns of the rotary voltage provided by the power grid, and includes: one choke per phase of the power grid electrically arranged between the power grid on the one hand, and the generator stator and at least one of the power converters of the generator rotor on the other hand, and a three phase synchronous electrical machine electrically coupled to the chokes.
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