JP4773850B2 - Wind power generation system and emergency power supply method for wind power generation system - Google Patents

Description

  The present invention relates to a wind power generation system, and more particularly to a technique for making a wind power generation system respond to an abnormal decrease in voltage (system voltage) of a power system.

  Recent wind power generation systems are required to supply power to a power system stably and with high reliability. One particularly important requirement is the LVRT capability (low voltage ride through), that is, the property that the wind power generation system does not disconnect from the power system even when a system fault occurs and the system voltage drops. The earliest wind power generation system is configured such that a control device and various auxiliary machines (for example, a pitch drive mechanism) are operated by electric power supplied from an electric power system. However, with such a configuration, the operation of the wind power generation system cannot be maintained when the system voltage decreases. A particularly important problem is that when the system voltage is lowered, the load on the generator is reduced, so that the rotational speed of the wind turbine rotor is increased. An increase in the rotational speed of the wind turbine rotor is not preferable from the viewpoint of safety, and causes excessive voltage to be applied to the power converter connected to the generator. In order to avoid such a situation, the wind power generation system must be stopped and disconnected from the power system.

  One way to provide LVRT capability is to use an uninterruptible power supply (UPS) as disclosed in US Pat. No. 6,921,985. In the technology disclosed in this publication, when a drop in system voltage is detected, an uninterruptible power supply is supplied to necessary equipment (for example, a power converter, a turbine controller, a blade pitch control system, a crowbar circuit, etc.). Power is supplied from the device. Power is not supplied to unnecessary equipment. By supplying power to the blade pitch control system, the pitch angle of the blades of the wind turbine rotor is controlled, thereby controlling the speed of the wind turbine rotor. In addition, the power converter is protected by supplying power to the crowbar circuit.

  One problem with using an uninterruptible power supply is that the uninterruptible power supply requires a lot of maintenance. Since the battery used for the uninterruptible power supply is likely to deteriorate with aging, it is necessary to replace the battery periodically in order to maintain the function of the uninterruptible power supply. This undesirably increases the labor and cost required for maintenance of the wind power generation system.

  Japanese Patent Application Laid-Open No. 2004-140971 discloses a mechanism for supplying power in a non-contact manner to a device mounted on a rotating body that rotates together with a wind turbine rotor. This mechanism uses a rotary transformer or an induction machine to transmit electric power in a non-contact manner, thereby reducing the need for maintenance. However, this publication makes no mention of dealing with an abnormal drop in system voltage.

Therefore, there is a technical need to provide LVRT capability to a wind power system through a mechanism that does not require much maintenance.
US Pat. No. 6,921,985 JP 2004-140971 A

  Accordingly, an object of the present invention is to provide a technique for providing LVRT capability to a wind power generation system by a mechanism that does not require much maintenance.

  In order to achieve the above object, the present invention employs the means described below. In the description of the means, in order to clarify the correspondence between the description of [Claims] and the description of [Best Mode for Carrying Out the Invention], [Best Mode for Carrying Out the Invention] ] Is added with the numbers and symbols used in []. However, the added number / symbol should not be used to limit the technical scope of the invention described in [Claims].

  The wind power generation system according to the present invention includes a windmill rotor (2) including a blade (5) having a variable pitch angle, a pitch control mechanism (22) that drives the blade (5) to control the pitch angle, An emergency power supply mechanism (29) for supplying power generated from the rotation of the wind turbine rotor (2) to the pitch control mechanism (22) in response to the occurrence of an abnormality in which the system voltage of the system (13) decreases. It has. The emergency power supply mechanism (29, 29A-29C) supplies power to the pitch control mechanism (22) in response to the occurrence of an abnormality in which the system voltage of the power system (13) decreases, and thereby the wind power generation Provides LVRT capability to the system. Since the emergency power supply mechanism (29) generates power from the rotation of the wind turbine rotor (2), it does not require a battery unlike the uninterruptible power supply. This is effective for reducing maintenance.

  In one embodiment, the emergency power supply mechanism (29, 29A-29C) generates power when the power generation mechanism (31, 32) driven by the wind turbine rotor (2) and an abnormality in which the system voltage decreases are detected. An emergency changeover switch (33) for electrically connecting the mechanisms (31, 32) to the pitch control mechanism (22) is provided. The emergency changeover switch (33) preferably disconnects the power generation mechanism (31, 32) from the pitch control mechanism (22) and opens the output terminal of the power generation mechanism (31, 32) when the system voltage is normal. .

  In one embodiment, the wind power generation system further includes a shaft (8) mechanically connected to the wind turbine rotor (2), and a rotating body (11) integrally connected to the shaft (8). I have. In this case, the emergency power supply mechanism (29) includes an emergency generator (31) and a power transmission mechanism (30) that transmits the rotation of the rotating body (11) to the rotor of the emergency generator (31). I have. The emergency generator (31) is driven by the power received through the power transmission mechanism (30) to generate the electric power.

  The rotating body (11) is preferably a brake disc.

  In a preferred embodiment, the emergency power supply mechanism (29) is mechanically coupled to the wind turbine rotor (2) and is also configured to function as an electric motor; A switch (34) for connecting the power system (13) to the emergency generator (31).

  The wind power generation system further includes a control device (27) that generates a pitch command indicating the pitch angle of the blade (5), and the pitch control mechanism (22) is responsive to the pitch command, When controlling the pitch angle, the emergency power supply mechanism (29, 29A-29C) is generated from the rotation of the wind turbine rotor (2) in response to the occurrence of an abnormality in which the system voltage of the power system (13) decreases. It is preferable to supply the electric power to the control device (27).

The wind power generation system is further connected to a winding induction generator (4) driven by a wind turbine rotor (2) and a rotor winding of the winding induction generator (4) and is responsive to a control signal. When the protection circuit (18) that consumes the power received from the rotor winding is provided, the emergency power supply mechanism (29, 29A-29C) reduces the system voltage of the power system (13). In response to the occurrence of an abnormality, it is preferable to supply the electric power generated from the rotation of the wind turbine rotor (2) to the protection circuit (18).
Wind power generation system.

  When the wind power generation system further includes a shaft (8) mechanically connected to the wind turbine rotor (2), the emergency power supply mechanism (29A-29C) is integrally connected to the shaft (8). The rotating body (11A-11C) is provided, and it is preferable to generate electric power by electromagnetic induction accompanying the rotation of the rotating body (11A-11C).

  In a preferred embodiment, the emergency power supply mechanism (29A) further includes a coil (42) provided close to the rotating body (11A), and the rotating body (11A) is a permanent magnet (43). The emergency power supply mechanism (29A) generates power by the coil (42) and supplies it to the pitch control mechanism (22) when an abnormality in which the system voltage decreases is detected.

  In another preferred embodiment, the emergency power supply mechanism (29B) further includes a coil (42) provided close to the rotating body (11B), and a permanent magnet ( 41A), and the rotating body (11B) is provided with an opening (44). The emergency power supply mechanism (29B) generates power by the coil (42) and supplies it to the pitch control mechanism (22) when an abnormality in which the system voltage decreases is detected.

  In still another preferred embodiment, the emergency power supply mechanism (29C) further presses against the outer periphery of the rotating body (11C) and the permanent magnet (45) provided close to the rotating body (11C). And a second brush (47) pressed against the shaft (8). The emergency power supply mechanism (29C) takes out power from the first brush (46) and the second brush (46) and supplies it to the pitch control mechanism (22) when an abnormality in which the system voltage decreases is detected.

The emergency power supply method according to the present invention provides an emergency power supply for a wind power generation system including a windmill rotor (2) including a blade (5) having a variable pitch angle and a pitch control mechanism (22) for controlling the pitch angle. Is the method. The emergency power supply method is
Detecting an abnormality in which the system voltage of the power system (13) decreases;
Supplying power generated from the rotation of the wind turbine rotor (2) to the pitch control mechanism (22) in response to the occurrence of the abnormality.

  According to the present invention, a technique for providing LVRT capability to a wind power generation system by a mechanism that does not require much maintenance is provided.

  FIG. 1 is a block diagram showing a configuration of a wind power generation system 1 according to an embodiment of the present invention. The wind power generation system 1 includes a windmill rotor 2, a drive train 3, and a winding induction generator 4. The windmill rotor 2 is mechanically connected to the rotor of the winding induction generator 4 via the drive train 3. The rotational power of the wind turbine rotor 2 is transmitted to the winding induction generator 4 via the drive train 3, and thereby the winding induction generator 4 is driven.

  The windmill rotor 2 includes a blade 5 and a hub 6 that supports the blade 5. The blade 5 is supported so that its pitch angle is variable.

  The drive train 3 includes a gear box 7, a windmill side shaft 8, a generator side shaft 9, and a clutch mechanism 10. The hub 6 of the wind turbine rotor 2 is connected to the wind turbine side shaft 8 via the gear box 7, and the wind turbine side shaft 8 is connected to the generator side shaft 9 via the coupling mechanism 10. The coupling mechanism 10 mechanically and elastically connects the windmill side shaft 8 and the generator side shaft 9, thereby absorbing the difference between the displacement of the windmill side shaft 8 and the displacement of the generator side shaft 9. To do. The generator side shaft 9 is fixedly connected to the rotor of the winding induction generator 4.

  A brake disk 11 is joined to the windmill side shaft 8. The brake disk 11 is a rotating body used for decelerating or stopping the windmill rotor 2. A brake caliper 12 is provided in the vicinity of the brake disc 11, and when the brake disc 11 is sandwiched between the brake calipers 12, the wind turbine rotor 2 is decelerated or stopped.

  The winding induction generator 4 is configured to output power to the power system 13 from both the stator winding and the rotor winding. That is, the stator winding of the winding induction generator 4 is directly connected to the power system 13, and the rotor winding is connected to the power system 13 via the power converter 14. The power converter 14 is for converting AC power received from the rotor windings into AC power adapted to the frequency of the power system 13. The power converter 14 includes an active rectifier 15, a DC bus 16, and an inverter 17. The active rectifier 15 converts AC power generated in the rotor winding into DC power and outputs the DC power to the DC bus 16. The inverter 17 converts the DC power received from the DC bus 16 into AC power having the same frequency as that of the power system 13 and outputs the AC power to the power system 13.

  The rotor winding of the winding induction generator 4 is further connected to a crowbar circuit 18. The crowbar circuit 18 is a circuit used for protecting the rotor winding from an overcurrent, and includes a rectifier 19, a switch 20, and a load resistor 21. The rectifier 19 converts AC power received from the rotor winding into DC power. The switch 20 electrically connects or disconnects the rectifier 19 and the load resistor 21 in response to a control signal supplied from the outside. When the operation of protecting the rotor winding is performed, the switch 20 of the crowbar circuit 18 is turned on. When the switch 20 is turned on, the AC power generated in the rotor winding is converted to DC power by the rectifier 19 and consumed by the load resistor 21. This reduces the current flowing through the rotor winding and protects the rotor winding.

  The pitch angle of the blade 5 of the wind turbine rotor 2 is controlled by the pitch control mechanism 22. In FIG. 1, it is shown that the blades 5 are separately connected to the pitch control mechanism 22 and the hub 6, but this is only for convenience of explanation; The blade 5 connected to the pitch control mechanism 22 and the blade 5 connected to the hub 6 are the same. The pitch control mechanism 22 includes a hydraulic cylinder 23, an oil amount adjustment valve 24, a hydraulic pressure source 25a, an accumulator 25b, and a pitch control device 26. The hydraulic cylinder 23 operates by the working fluid supplied from the hydraulic source 25a to drive the blade 5. The hydraulic source 25 a is driven by the electric power supplied from the electric power system 13 and supplies pressure energy to the working fluid supplied to the hydraulic cylinder 23. An oil pump is preferably used as the hydraulic pressure source 25a. An oil tank may be used as the hydraulic source 25a instead of or in addition to the oil pump. The accumulator 25b accumulates pressure energy supplied to the working fluid. The accumulator 25b also has a role of supplying pressure energy to the working fluid when electric power is no longer supplied from the power system 13 to the hydraulic current 25a. The oil amount adjusting valve 24 adjusts the amount of working fluid supplied to the hydraulic cylinder 23 from the hydraulic source 25a and the accumulator 25b. The pitch control device 26 supplies a direct current drive current to the oil amount adjusting valve 24 and controls the opening degree of the oil amount adjusting valve 24 according to the magnitude of the drive current. The amount of the working fluid supplied to the hydraulic cylinder 23 is adjusted by the opening degree of the oil amount adjusting valve 24, whereby the blade 5 is controlled to a desired pitch angle. The entire pitch control mechanism 22 may be accommodated in the hub 6, and only a part thereof (for example, the hydraulic cylinder 23, the accumulator 25, and the oil amount adjustment valve 24) may be accommodated in the hub 6. .

  The entire wind power generation system 1 is controlled by the main controller 27. First, the main controller 27 generates a pitch command that indicates the pitch angle of the blade 5 and supplies it to the pitch controller 26. In response to this pitch command, the pitch control device 26 supplies a drive current to the oil amount adjusting valve 24. Second, the main controller 27 generates a crowbar circuit control signal and supplies it to the crowbar circuit 18. When the crowbar circuit control signal is activated, the crowbar circuit 18 performs an operation of turning on the switch 20 and consuming the AC power generated in the rotor winding by the load resistor 21. The main controller 27 further performs various controls such as control of the power converter 14.

  During normal operation, power for operating the pitch control mechanism 22, the crowbar circuit 18, and the main control device 27 is supplied from the power system 13. Specifically, a rectifier 28 is connected to the power line between the winding induction generator 4 and the power system 13, and the pitch control mechanism 22, the crowbar circuit 18, and the main controller 27 are operated by the rectifier 28. DC power is generated.

  On the other hand, the wind power generation system 1 includes a wind power generation system 1 so that the pitch control mechanism 22, the crowbar circuit 18, and the main control device 27 can operate even when an abnormality occurs in which the system voltage (voltage of the power system 13) is reduced. An emergency power supply system 29 is provided. The emergency power supply system 29 includes a power transmission mechanism 30, an emergency generator 31, a rectifier 32, and an emergency changeover switch 33.

  The power transmission mechanism 30 transmits the rotation of the windmill rotor 2 to the emergency generator 31. In one embodiment, the power transmission mechanism 30 transmits the rotation of the brake disk 11 to drive the rotor of the emergency generator 31. For example, a gear can be used as the brake disk 11 and a gear connected to the rotor of the emergency generator 31 can be used as the power transmission mechanism 30. Instead, a belt that transmits the rotation of the brake disk 11 to the emergency generator 31 may be used as the power transmission mechanism 30. Further, the power transmission mechanism 30 may be connected not to the brake disc 11 but to other mechanical elements that rotate integrally with the windmill side shaft 8. However, the configuration in which the power transmission mechanism 30 is mechanically coupled to the brake disk 11 is suitable for reducing the number of components constituting the wind power generation system 1.

  The emergency generator 31 and the rectifier 32 function as a power generation mechanism that generates electric power from the rotation of the wind turbine rotor 2. Specifically, the emergency generator 31 generates AC power from the rotation of the wind turbine rotor 2 and supplies it to the rectifier 32. The rectifier 32 converts AC power received from the emergency generator 31 into DC power.

  The emergency changeover switch 33 connects one of the rectifier 28 connected to the power system 13 and the rectifier 32 of the emergency power supply system 29 to the pitch control mechanism 22, the crowbar circuit 18, and the main controller 27.

  During normal operation (that is, when the system voltage is normal), the emergency changeover switch 33 connects the pitch control mechanism 22, the crowbar circuit 18, and the main controller 27 to the rectifier 28 connected to the power system 13. Power is supplied from the power system 13 to the pitch control mechanism 22, the crowbar circuit 18, and the main control device 27. In this embodiment, the emergency generator 31 is set to a no-load state during normal operation. That is, the output terminal of the rectifier 32 connected to the emergency generator 31 is opened by the emergency changeover switch 33 during normal operation. This is effective for reducing the influence on the drive train 3 during normal operation, for example, torque pulsation due to non-uniformity of the magnetic flux distribution of the emergency generator 31.

  On the other hand, when an abnormality occurs in which the system voltage decreases, the emergency changeover switch 33 connects the pitch control mechanism 22, the main controller 27, and the crowbar circuit 18 to the rectifier 32 of the emergency power supply system 29. The emergency power supply system 29 supplies power to the pitch control mechanism 22, the main control device 27, and the crowbar circuit 18, and maintains the operations of the pitch control mechanism 22, the crowbar circuit 18, and the main control device 27. By maintaining the operations of the pitch control mechanism 22 and the main controller 27, it is not necessary to disconnect the wind power generation system 1 from the power system 13, and the LVRT capability can be provided to the wind power generation system 1. In addition, by maintaining the operations of the pitch control mechanism 22 and the main controller 27, the pitch angle of the blade 5 is controlled, and an excessive increase in the rotation of the wind turbine rotor 2 is suppressed. Further, the operation of the crowbar circuit 18 is maintained, so that the protection of the rotor winding can be maintained. When an abnormality that reduces the system voltage occurs, an overcurrent is generated in the rotor winding of the winding induction generator 4. However, the switch 20 of the crowbar circuit 18 is turned on by the power supplied from the emergency power supply system 29, and the generated overcurrent is quickly attenuated by the load resistor 21. Thereby, the rotor winding is protected.

  One advantage of the emergency power supply system 29 having such a configuration is that less labor is required for maintenance. Unlike the uninterruptible power supply, the emergency power supply system 29 including the emergency generator 31 does not require a battery. Eliminating the battery is effective for reducing maintenance labor.

  Another advantage is that the emergency power supply system 29 itself has a function of reducing the rotational speed of the wind turbine rotor 2 when an abnormality occurs in which the system voltage decreases. As described above, when an abnormality in which the system voltage is reduced occurs, the load on the winding induction generator 4 is reduced, so that the rotational speed of the wind turbine rotor 2 is increased. However, in this embodiment, when an abnormality occurs in which the system voltage decreases, the emergency generator 31 is driven by the rotation of the windmill rotor 2 to supply power to the pitch control mechanism 22, the crowbar circuit 18, and the main controller 27. Begin to. Therefore, the rotational energy of the windmill rotor 2 is lost, and the rotational speed of the windmill rotor 2 is limited. This is preferable in order to prevent an excessive increase in the rotational speed of the wind turbine rotor 2.

  When the emergency generator 31 is configured to be usable as an electric motor, the emergency generator 31 is a rotor turning motor for manually rotating the wind turbine rotor 2 during maintenance of the wind power generation system 1. You may combine. In this case, as shown in FIG. 2, the stator winding of the emergency generator 31 is connected to the switch 34. The switch 34 connects the stator winding of the emergency generator 31 to one of the rectifier 32 and the power system 13. When the emergency generator 31 is used as a rotor turning motor, the stator winding of the emergency generator 31 is connected to the power system 13. The emergency generator 31 drives the windmill side shaft 8 with the electric power supplied from the power system 13, thereby rotating the windmill rotor 2.

  Instead of mechanically connecting the brake disc to the emergency generator 31 by means of the power transmission mechanism 30, the brake disc itself can be used as part of the generator. In this case, electromagnetic induction is induced by the rotation of the brake disk, and electric power generated by the electromagnetic induction is supplied to the pitch control mechanism 22, the crowbar circuit 18, and the main controller 27.

  In one embodiment, as shown in FIG. 3, an emergency power supply system 29A includes a brake disk 11A that rotates integrally with the windmill side shaft 8, an iron core 41, and a coil 42 in which the iron core 41 is inserted. It is configured with. The coil 42 is connected to the rectifier 32 and is disposed in the vicinity of the brake disk 11A. A permanent magnet 43 is embedded in the brake disk 11A. The iron core 41 inserted into the coil 42 serves to collect the magnetic flux generated by the permanent magnet 43 in the coil 42.

  According to such a configuration, the windmill side shaft 8 and the brake disk 11A function as a rotor of the generator, and the iron core 41 and the coil 42 function as a stator of the generator, and thus can generate electric power. When the brake disk 11 </ b> A rotates, the magnetic flux interlinking with the coil 42 changes, and thereby AC power is generated in the coil 42. The generated AC power is converted into DC power by the rectifier 32. When an abnormality occurs in which the system voltage decreases, DC power generated by the rectifier 32 is supplied to the pitch control mechanism 22, the crowbar circuit 18, and the main controller 27 via the emergency changeover switch 33.

  The advantage of the configuration of FIG. 3 is that the power transmission mechanism 30 that mechanically connects the power generation mechanism (emergency generator 31) and the windmill side shaft 8 can be eliminated. Since the power transmission mechanism 30 is driven as the wind turbine rotor 2 rotates, a certain amount of loss must be generated. Eliminating the power transmission mechanism 30 is suitable for reducing the loss of the wind power generation system 1.

  Instead of the brake disk 11A, a disk that rotates integrally with the windmill side shaft 8 may be provided separately from the brake disk 11A, and the permanent magnet 43 may be embedded in the disk. In this case, the coil 42 is disposed in the vicinity of the disk.

  In another embodiment, as shown in FIG. 4, the emergency power supply system 29B includes a brake disk 11B that rotates integrally with the windmill-side shaft 8, a permanent magnet 41A, and a permanent magnet 41A. And a coil 42. The coil 42 is connected to the rectifier 32 and is provided to face the brake disk 11B. A plurality of openings 44 are provided in the brake disc 11B. The opening 44 is formed so as to pass in front of the coil 42 and penetrate the brake disc 11B in the thickness direction.

  According to such a configuration, the windmill side shaft 8 and the brake disk 11B function as a rotor of the generator, and the permanent magnet 41A and the coil 42 function as a stator of the generator, and thus can generate electric power. When the brake disk 11 </ b> B rotates, the opening 44 passes in front of the coil 42, and the magnetic flux distribution of the magnetic flux interlinking with the coil 42 changes, whereby AC power is generated in the coil 42. The generated AC power is converted into DC power by the rectifier 32. When an abnormality occurs in which the system voltage decreases, DC power generated by the rectifier 32 is supplied to the pitch control mechanism 22, the crowbar circuit 18, and the main controller 27 via the emergency changeover switch 33. In the configuration of FIG. 4 as well, the power transmission mechanism 30 can be eliminated, and thereby the loss of the wind power generation system 1 can be reduced.

  Instead of the brake disk 11B, a metal disk that rotates integrally with the windmill side shaft 8 may be provided separately from the brake disk 11B, and an opening 44 may be formed in the disk. In this case, the coil 42 is disposed in the vicinity of the disk.

  In still another embodiment, as shown in FIG. 5, an emergency power supply system 29C is provided so as to face the brake disc 11C and the brake disc 11C that rotates integrally with the windmill-side shaft 8. A permanent magnet 45 and brushes 46 and 47 are provided. The brake disc 11C is joined to the windmill side shaft 8 at the center thereof. The permanent magnet 45 is arranged so that the magnetic flux is linked to the brake disk 11C uniformly in the circumferential direction. The side surface of the brake disc 11C is processed smoothly, and the brush 46 is pressed against the side surface. In addition, the brush 47 is pressed against the side surface of the windmill side shaft 8. The brushes 46 and 47 are connected to the DC-DC converter 32A, and the output terminal of the DC-DC converter 32A is connected to the emergency changeover switch 33.

  According to such a configuration, electric power can be generated by unipolar induction. When the brake disc 11C rotates, a DC voltage is induced between the center and the side surface of the brake disc 11C by unipolar induction. This DC voltage is extracted by the brushes 46 and 47 and supplied to the DC-DC converter 32A. The DC-DC converter 32A converts the DC voltage supplied from the brushes 46 and 47 into a DC voltage having a desired voltage level. When an abnormality occurs in which the system voltage decreases, DC power generated by the DC-DC converter 32A is supplied to the pitch control mechanism 22, the crowbar circuit 18, and the main controller 27 via the emergency changeover switch 33. Even in the configuration of FIG. 5, the power transmission mechanism 30 can be eliminated, and thereby the loss of the wind power generation system 1 can be reduced.

  Instead of the brake disk 11C, a metal disk that rotates integrally with the windmill side shaft 8 may be provided separately from the brake disk 11C, and the disk may be disposed in the vicinity of the permanent magnet 45.

FIG. 1 is a block diagram showing a configuration of a wind power generation system according to an embodiment of the present invention. FIG. 2 is a block diagram showing a configuration of a wind power generation system according to another embodiment of the present invention. FIG. 3 is a block diagram showing a configuration of a wind power generation system according to still another embodiment of the present invention. FIG. 4 is a block diagram showing a configuration of a wind power generation system according to still another embodiment of the present invention. FIG. 5 is a block diagram showing a configuration of a wind power generation system according to still another embodiment of the present invention.

Explanation of symbols

1: Wind power generation system 2: Wind turbine rotor 3: Drive train 4: Winding induction generator 5: Blade 6: Hub 7: Gear box 8: Wind turbine side shaft 9: Generator side shaft 10: Clutch mechanism 11, 11A, 11B 11C: Brake disc 12: Brake caliper 13: Power system 14: Power converter 15: Active rectifier 16: DC bus 17: Inverter 18: Clover circuit 19: Rectifier 20: Switch 21: Load resistance 22: Pitch control mechanism 23: Hydraulic cylinder 24: Oil amount adjustment valve 25: Accumulator 26: Pitch control device 27: Main control device 28: Rectifier 29, 29A, 29B, 29C: Emergency power supply system 30: Power transmission mechanism 31: Emergency generator 32: Rectifier 32A: DC-DC converter 33: Emergency switch 34: Switch 41: Iron core 41A: Permanent magnet 42: Coil 43: Permanent magnet 44: Opening 45: Permanent magnet 46, 47: Brush

Claims (12)

A windmill rotor having blades with variable pitch angles;
A pitch control mechanism for controlling the pitch angle by driving the blade;
A winding induction generator driven by the windmill rotor;
An emergency generator driven by the wind turbine rotor;
A protection circuit connected to the rotor winding of the winding induction generator and consuming power received from the rotor winding in response to a control signal;
A wind power generation system comprising: an emergency power supply mechanism that supplies power generated from the emergency generator to the pitch control mechanism and the protection circuit in response to occurrence of an abnormality in which the system voltage of the power system decreases. . The wind power generation system according to claim 1,
A power transmission belt or a power transmission gear for transmitting the rotation of the wind turbine rotor to the rotor of the emergency generator is provided.
Wind power generation system. The wind power generation system according to claim 1,
The emergency power supply mechanism, before SL when the system voltage is detected abnormal decrease, wind power generation system comprising a emergency switch which electrically connects the emergency generator to the pitch control mechanism. The wind power generation system according to claim 3 ,
The emergency changeover switch disconnects the power generation mechanism from the pitch control mechanism and opens the output terminal of the emergency generator when the system voltage is normal. The wind power generation system according to claim 1,
Furthermore,
A shaft mechanically connected to the windmill rotor;
A rotating body integrally connected to the shaft ;
A power transmission mechanism for transmitting the rotation of the rotating body to the rotor of the emergency generator,
The emergency generator is driven by the power received through the power transmission mechanism to generate the electric power.
Wind power generation system. The wind power generation system according to claim 5 ,
The rotating body is a brake disk. The wind power generation system according to claim 1,
The emergency generator is configured to function as an electric motor ,
The emergency power supply mechanism, wind power generation system comprising a switch for connecting the power system to the emergency generator said. The wind power generation system according to claim 1,
Furthermore,
A control device for generating a pitch command indicating the pitch angle of the blade;
The pitch control mechanism controls the pitch angle in response to the pitch command,
The said emergency power supply mechanism supplies the said electric power generated from rotation of the said windmill rotor to the said control apparatus in response to generation | occurrence | production of abnormality which the system voltage of the said electric power grid falls. Wind power generation system. The wind power generation system according to claim 1,
Furthermore,
Comprising a shaft mechanically connected to the wind turbine rotor;
The emergency generator includes a rotating body integrally connected to the shaft, and generates the electric power by electromagnetic induction accompanying the rotation of the rotating body. The wind power generation system according to claim 9,
The emergency generator further includes a coil provided close to the rotating body,
The rotating body includes a permanent magnet,
The emergency generator, when said system voltage is detected abnormal decrease, wind power generation system for supplying to said pitch control mechanism to generate the power by the coil. The wind power generation system according to claim 9,
The emergency generator further includes:
A coil provided close to the rotating body;
A permanent magnet inserted into the coil,
The rotating body is provided with an opening,
The emergency generator, when said system voltage is detected abnormal decrease, wind power generation system for supplying to said pitch control mechanism to generate the power by the coil. The wind power generation system according to claim 9,
The emergency generator is
Furthermore,
A permanent magnet provided close to the rotating body;
A first brush pressed against the outer periphery of the rotating body;
A second brush pressed against the shaft,
A wind power generation system in which the emergency generator extracts the power from the first brush and the second brush and supplies the power to the pitch control mechanism when an abnormality in which the system voltage decreases is detected.

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