IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
UP-0598773
(2004-03-12)
|
등록번호 |
US-7605487
(2009-11-10)
|
국제출원번호 |
PCT/EP04/002588
(2004-03-12)
|
§371/§102 date |
20061030
(20061030)
|
국제공개번호 |
WO05/099063
(2005-10-20)
|
발명자
/ 주소 |
- Barton, Werner
- Buecker, Andreas
|
출원인 / 주소 |
|
대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
27 인용 특허 :
5 |
초록
▼
The method for operating a frequency converter (26) of a generator (14) in particular of a wind energy turbine (10), in the event of a substantial grid voltage drop, wherein the frequency converter (26) comprises a generator-side power converter (32), to be connected to the generator (14), a grid-si
The method for operating a frequency converter (26) of a generator (14) in particular of a wind energy turbine (10), in the event of a substantial grid voltage drop, wherein the frequency converter (26) comprises a generator-side power converter (32), to be connected to the generator (14), a grid-side power converter (28) to be connected to the voltage grid (18), and a DC link circuit (30) for connecting the generator-side power converter (32) to the grid-side power converter (28), comprises the step of generating the amount of reactive current to be supplied to the grid (18) by controlling the frequency converter (26).
대표청구항
▼
The invention claimed is: 1. Method for operating a frequency converter (26,26',26") of a generator (14,14',14"), in the event of a substantial grid voltage drop in a grid, wherein the frequency converter (26,26',26") comprises a generator-side power converter (32,32',32"), to be connected to the g
The invention claimed is: 1. Method for operating a frequency converter (26,26',26") of a generator (14,14',14"), in the event of a substantial grid voltage drop in a grid, wherein the frequency converter (26,26',26") comprises a generator-side power converter (32,32',32"), to be connected to the generator (14,14',14"), a grid-side power converter (28,28',28") to be connected to the grid (18,18',18"), and a DC link circuit (30,30',30") for connecting the generator-side power converter (32,32',32") to the grid-side power converter (28,28',28"), the method comprising the step of generating an amount of reactive current to be supplied to the grid (18,18',18") by controlling the frequency converter (26,26',26") so as to generate reactive current. 2. Method according to claim 1, wherein the generator (14) is a double fed asynchronous machine and wherein generating the amount of reactive current to be supplied to the grid (18) is performed by controlling at least one of the generator-side power converter (32) and the grid-side power converter (28). 3. Method according to claim 2, wherein, if the generator (141 is not in its operating state for generating power, the reactive current to be supplied to the grid (18) is generated by controlling the grid-side power converter (28). 4. Method according to claim 1, wherein the generator (14',14") is an asynchronous machine and wherein generating the amount of reactive current to be supplied to the grid (18,18',18") is performed by controlling the grid-side power converter (28,28',28"). 5. Method according to claim 1, wherein the generator (14',14") is a synchronous machine and wherein generating the amount of reactive current to be supplied to the grid (18',18") is performed by controlling the grid-side power converter (28',28"). 6. Method according to claim 4, wherein, if the generator (14',14") is not in its operating state for generating power, the reactive current to be supplied to the grid (18',18") is generated by controlling the grid-side power converter (28',28"). 7. Method according to claim 1, wherein for generating reactive current through the frequency converter (26,26',26") the performance factor is controlled. 8. Method according to claim 1, wherein the step is performed when, for period of time of a few milliseconds up to a few seconds, the grid voltage is decreased to at least about 40% of its normal value. 9. Method according to claim 1, wherein the step is terminated when, after a grid voltage drop, for a few seconds the grid voltage is increased to at least about 70% of its normal value. 10. Method for operating a frequency converter (26,26',26") of a generator (14,14',14") under substantially normal grid condition and with the generator (14,14',14") not being in its operating state, wherein the frequency converter (26,26',26") comprises a generator-side power converter (32,32',32"), to be connected to the generator (14,14',14"), a grid-side power converter (28,28',28") to be connected to the voltage grid (18,18',18"), and a DC link circuit (30,30',30") for connecting the generator-side power converter (32,32',32") to the grid-side power converter (28,28',28"), the method comprising the step of controlling an amount of reactive current to be supplied to the grid (18,18',18") by controlling the grid-side power converter (28,28',28"). 11. Method according to claim 10, wherein the generator (14,14',14") is an asynchronous machine, a double fed asynchronous machine, or a synchronous machine. 12. Method according to claim 10, wherein for controlling reactive current through the frequency converter (26,26',26"), the performance factor of the grid-side power converter (28,28',28") is controlled. 13. Method according to claim 1, wherein the control of the frequency converter (26,26',26") is supervised by a utility (44,44',44") or a power management control (40,40',40",42,42',42") of the generator (14,14',14") or of a group of generators (14,14',14") at least one of which is operatively connected to the grid (18,18',18"). 14. Wind energy turbine (10,10',10") for generating power to be supplied to a grid (18,18',18"), comprising a rotor (12,12'12"), a generator (14,14',14") operatively connected to the rotor (12,12',12"), a frequency converter (26,26',26") electrically connectable to the generator (14,14',14") and the grid (18,18',18") and comprising a generator-side power converter (32,32',32") operatively connectable to the generator (14,14',14"), a grid-side power converter (28,28',28") operatively connectable to the grid (18,18',18"), and a DC link circuit (30,30',30") for connecting the generator-side power converter (32,32',32") to the grid-side power converter (28,28',28"), and a control unit (38,38',38") for controlling the frequency converter (26,26',26") for generating reactive current to be supplied to the grid, wherein in the event of a substantial grid voltage drop, the control unit (38,38',38") controls the frequency converter (26,26',26") for generating an amount of reactive current to be supplied to the grid (18,18',18"). 15. Wind energy turbine according to claim 14, wherein the generator (14) is a double fed asynchronous machine and wherein generating the amount of reactive current to be supplied to the grid (18) is performed by controlling at least one of the generator-side power converter (32) and the grid-side power converter (28). 16. Wind energy turbine according to claim 15, wherein, if the generator (14) is not in its operating state for generating power, the amount of reactive current to be supplied to the grid (18) is generated by controlling the grid-side power converter (28). 17. Wind energy turbine according to claim 14, wherein the generator (14',14") is an asynchronous machine and wherein generating the amount of reactive current to be supplied to the grid (18',18") is performed by controlling the grid-side power converter (28',28"). 18. Wind energy turbine according to claim 14, wherein the generator (14',14") is a synchronous machine and wherein generating the amount of reactive current to be supplied to the grid (18',18") is performed by controlling the grid-side power converter (28',28"). 19. Wind energy turbine according to claim 17, wherein, if the generator (14',14") is not in its operating state for generating power, the amount of reactive current to be supplied to the grid (18',18") is generated by controlling the grid-side power converter (28',28"). 20. Wind energy turbine according to claim 14, wherein for generating reactive current through the frequency converter (26,26',26") the performance factor is controlled. 21. Wind energy turbine for generating power to be supplied to a grid, comprising a rotor (12,12',12"), a generator (14,14',14") operatively connected to the rotor (12,12',12"), a frequency converter (26,26',26") electrically connectable to the generator (14,14',14") and the grid (18,18',18") and comprising a generator-side power converter (32,32',32") operatively connectable to the generator (14,14',14"), a grid-side power converter (28,28',28") operatively connectable to the grid (18,18',18,18"), and a DC link circuit (30,30',30") for connecting the generator-side power converter (32,32',32") to the grid-side power converter (28,28',28"), and a control unit (38,38',38") for controlling the frequency converter (26,26',26") for generating reactive current to be supplied to the grid (18,18',18"), wherein under normal grid condition but with the generator (14,14',14") not in its operating state, the control unit (38,38',38") controls the grid-side power converter (28,28',28") of the frequency converter (26,26',26") for controlling an amount of reactive current to be supplied to the grid (18,18',18"). 22. Wind energy turbine according to claim 21, wherein the generator (14) is an asynchronous machine, a double fed asynchronous machine, or a synchronous machine. 23. Wind energy turbine according to claim 21, wherein for controlling reactive current through the frequency converter (26,26',26"), the performance factor of the grid-side power converter (28,28',28") is controlled. 24. Wind energy turbine according to claim 14, wherein the control of the frequency converter (26,26',26") is supervised by a utility (44,44',44") or a power management control (42,42',42") of the wind energy turbine (10,10',10") or of a wind park comprising a plurality of wind energy turbines (10,10',10") at least one of which is operatively connected to the grid (18,18',18").
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