초록 ▼

A controller (28) for a doubly fed induction generator (12,20) adjusts control signals to a rotor side converter (24) and line side converter (22) to adjust rotor current when a voltage transient on a utility grid (10) occurs, so that the doubly fed induction generator can ride through the transient

A controller (28) for a doubly fed induction generator (12,20) adjusts control signals to a rotor side converter (24) and line side converter (22) to adjust rotor current when a voltage transient on a utility grid (10) occurs, so that the doubly fed induction generator can ride through the transient. The controller can also turn off the transistors of the rotor side converter (24) to reduce rotor current and/or activate a crowbar (42) to reduce the voltage of the DC link (26) connecting the converters (22, 24) when significant voltage transients occur on the grid (10). This permits continued operation of the DFIG system without disconnecting from the grid.

대표청구항 ▼

The embodiments of the invention in which an exclusive property or privilege is claimed are defined as follows: 1. A method of controlling a doubly fed induction generator (DFIG) system, such DFIG system having a generator with a stator energized by a grid having a voltage with a nominal value, a d

The embodiments of the invention in which an exclusive property or privilege is claimed are defined as follows: 1. A method of controlling a doubly fed induction generator (DFIG) system, such DFIG system having a generator with a stator energized by a grid having a voltage with a nominal value, a driven rotor coupled with the stator, a grid side converter electrically connected to the grid, a rotor side converter electrically connected to the rotor, a DC link connecting the converters, a controller supplying control signals to the converters for control of the torque and reactive power from the DFIG system, which method comprises: providing rotor current command signals from the controller; monitoring the voltage of the grid for transients from nominal; and if a transient greater than a first predetermined transient occurs, adjusting the rotor current command signals to permit continued operation of the DFIG system without disconnecting the DFIG from the grid. 2. The method defined in claim 1, including, if a grid transient greater than a second predetermined transient (different from the first predetermined transient) occurs, automatically reducing the rotor current to a minimum value. 3. The method defined in claim 2, in which the rotor side converter has switching transistors, and including turning off the switching transistors to reduce rotor current to a minimum level if a transient greater than the second predetermined transient occurs. 4. The method defined in claim 2 or claim 3, including, if a grid transient greater than a third predetermined transient (different from both of the first and second predetermined transients) occurs, activating a crowbar to reduce the voltage of the DC link. 5. The method defined in claim 1, including monitoring the voltage of the grid for a voltage sag from nominal, and if a voltage sag greater than a first predetermined sag occurs, adjusting the rotor current command signals to reduce rotor torque and reactive power, whereby the DFIG system rides through the transient. 6. The method defined in claim 1 or claim 5, in which the torque producing component of the rotor current is adjusted. 7. The method defined in claim 1 or claim 5, in which the flux producing component of the rotor current is adjusted. 8. The method defined in claim 1 or claim 5, in which both the torque producing and flux producing components of the rotor current are adjusted. 9. The method defined in claim 1 or claim 5, in which the rotor current is reduced progressively during the transient. 10. The method defined in claim 9 in which the rotor current is increased progressively following the transient. 11. The method defined in claim 1, including, if a grid transient greater than a second predetermined transient (different from the first predetermined transient) occurs, automatically activating a crowbar to reduce the voltage of the DC link. 12. The method defined in claim 11, including monitoring the voltage of the grid for transients greater than the second predetermined transient by monitoring the voltage of the DC link. 13. A method of controlling a doubly fed induction generator (DFIG) system, such DFIG system having a generator with a stator energized by a grid having a voltage with a nominal value, a driven rotor coupled with the stator, a grid side converter electrically connected to the grid, a rotor side converter electrically connected to the rotor, a DC link connecting the converters, a controller supplying control signals to the converters for control of the torque and reactive power from the DFIG system, which method comprises: monitoring the voltage of the grid for transients from nominal; and if a grid transient greater than a predetermined transient occurs, activating a crowbar to reduce the voltage of the DC link connecting the converters, without disconnecting the DFIG system from the grid. 14. The method defined in claim 13, including monitoring the voltage of the grid for transients greater than the predetermined transient by monitoring the voltage of the DC link, and activating the crowbar if the DC link voltage increases above a predetermined voltage, without disconnecting the DFIG system from the grid. 15. A method of controlling a DFIG system, such DFIG system having a generator with a stator energized by an AC utility grid having a voltage with a nominal value, a variable speed wind driven rotor coupled with the stator, a grid side AC-DC converter electrically connected to the grid at the AC side, a rotor side AC-DC converter electrically connected to the rotor at the AC side, a DC link connecting the DC sides of the converters, a controller supplying control signals to the converters for controlling operation of switching transistors thereof, which method comprises: calculating rotor current command signals to control the converter switching transistors to maintain a desired rotor current; monitoring the voltage of the utility grid for transients from nominal; and if a grid transient greater than a first predetermined transient occurs, adjusting the rotor current command signals to reduce rotor current and thereby reduce rotor torque and reactive power to permit continued rotation of the rotor without disconnecting the DFIG system from the grid, whereby the DFIG system rides through the transient; and following the transient, returning the rotor current command signals to operate as before occurrence of the grid transient. 16. The method defined in claim 15, including reducing the rotor current progressively during the transient. 17. The method defined in claim 15 including, if a grid transient greater than the first predetermined transient occurs, automatically turning off the rotor side converter to reduce rotor current to minimum. 18. The method defined in claim 17 including, if a grid transient greater than a second predetermined transient (different from the first predetermined transient) occurs, automatically activating a crowbar to reduce the voltage of the DC link. 19. The method defined in claim 18, including monitoring the voltage of the utility grid for transients greater than the second predetermined transient by monitoring the voltage of the DC link. 20. A controller for a doubly fed induction generator (DFIG) system, such DFIG system having a generator with a stator energized by a grid having a voltage with a nominal value, a driven rotor coupled with the stator, a grid side converter electrically connected to the grid, a rotor side converter electrically connected to the rotor, a DC link connecting the converters, said controller comprising means for supplying control signals to the converters for control of the torque and reactive power from the DFIG system, said controller further comprising: means for providing rotor current command signals from the controller; means for monitoring the voltage of the grid for transients from nominal; and means for adjusting the rotor current command signals to permit continued operation of the DFIG system without disconnecting the DFIG system from the grid if a transient greater than a first predetermined transient occurs. 21. A controller for a doubly fed induction generator (DFIG) system, such DFIG system having a generator with stator energized by a grid having a voltage with a nominal value, a driven rotor coupled with the stator, a grid side converter electrically connected to the grid, a rotor side converter electrically connected to the rotor, a DC link connecting the converters, said controller comprising means for supplying control signals to the converters for control of the torque and reactive power from the DFIG system, said controller further comprising: means for monitoring the voltage of the grid for transients from nominal; and means for activating a crowbar to reduce the voltage of the DC link connecting the converters if a grid transient greater than a predetermined transient occurs, without disconnecting the DFIG system from the grid. 22. A controller for a DFIG system, such DFIG system having a generator with a stator energized by an AC utility grid having a voltage with a nominal value, a variable speed wind driven rotor coupled with the stator, a grid side AC-DC converter electrically connected to the grid at the AC side, a rotor side AC-DC converter electrically connected to the rotor at the AC side, a DC link connecting the DC sides of the converters, said controller comprising means for supplying control signals to the converters for controlling operation of switching transistors thereof, said controller further comprising: means for calculating rotor current command signals to control the converter switching transistors to maintain a desired rotor current; means for monitoring the voltage of the utility grid for transients from nominal; and means for adjusting the rotor current command signals to reduce rotor current and thereby reduce rotor torque and reactive power to permit continued rotation of the rotor without disconnecting the DFIG system from the grid if a grid transient greater than a first predetermined transient occurs, whereby the DFIG system rides through the transient; and means for returning the rotor current command signals to operate as before occurrence of the grid transient following the transient. 23. A doubly fed induction generator (DFIG) system comprising: a generator with a stator energized by a grid having a voltage with a nominal value; a driven rotor coupled with the stator; a grid side converter electrically connected to the grid; a rotor side converter electrically connected to the rotor; a DC link connecting the converters; and a controller supplying control signals to the converters for control of the torque and reactive power from the DFIG system; means for providing rotor current command signals from the controller; means for monitoring the voltage of the grid for transients from nominal; and means for adjusting the rotor current command signals to permit continued operation of the DFIG system without disconnecting the DFIG system from the grid if a transient greater than a first predetermined transient occurs. 24. A doubly fed induction generator (DFIG) system comprising: a generator with a stator energized by a grid having a voltage with a nominal value; a driven rotor coupled with the stator, a grid side converter electrically connected to the grid; a rotor side converter electrically connected to the rotor; a DC link connecting the converters; a controller supplying control signals to the converters for control of the torque and reactive power from the DFIG system; means for monitoring the voltage of the grid for transients from nominal; a crowbar constructed and arranged to reduce the voltage of the DC link; and means for activating a crowbar to reduce the voltage of the DC link connecting the converters if a grid transient greater than a predetermined transient occurs. 25. A DFIG system comprising: a generator with a stator energized by an AC utility grid having a voltage with a nominal value; a variable speed wind driven rotor coupled with the stator; a grid side AC-DC converter electrically connected to the grid at the AC side; a rotor side AC-DC converter electrically connected to the rotor at the AC side; a DC link connecting the DC sides of the converters; a controller supplying control signals to the converters for controlling operation of switching transistors thereof; means for calculating rotor current command signals to control the converter switching transistors to maintain a desired rotor current; means for monitoring the voltage of the utility grid for transients from nominal; and means for adjusting the rotor current command signals to reduce rotor current and thereby reduce rotor torque and reactive power to permit continued rotation of the rotor without disconnecting the DFIG system from the grid if a grid transient greater than a first predetermined transient occurs, whereby the DFIG system rides through the transient; and means for returning the rotor current command signals to operate as before occurrence of the grid transient following the transient.