KR20160012032A - Method and system for controlling low-voltage ride through of a wind farm - Google Patents

Abstract

According to the present invention, a method for controlling a low-voltage ride through of a wind farm comprises the following steps: detecting low-voltage occurring by monitoring system voltage; a complex control unit determining a magnetic flux interlinkage follower gain according to a driving status of an individual wind power generator when the low-voltage is occurred by the detection result; the complex control unit transferring the determined magnetic flux interlinkage to the individual wind power generator; and controlling the individual wind power generator according to the transferred magnetic flux interlinkage when a current of a rotor of the individual wind power generator exceeds a preset current.

Description

METHOD AND SYSTEM FOR CONTROLLING LOW-VOLTAGE RIDE THROUGH OF A WIND FARM BACKGROUND OF THE INVENTION [0001]

The present invention relates to a method for compensating a low voltage of a wind turbine generator, and more particularly, it relates to a wind turbine generator for a wind turbine generator which detects a low voltage in a wind turbine generator and determines a cross- And more particularly to a method and system for controlling an individual wind power generator according to the transmitted flux-link following gain when the current exceeds a predetermined current.

According to the increase of the acceptance rate of wind energy, the rate of acceptance of wind energy by the development of wind power generation technology is increasing in the world. While maintaining the linkage with the grid and contributing to the recovery of the grid voltage. In order for wind farms to meet such requirements, it is necessary to cooperate with the restoration of the grid voltage by providing the reactive power supply function by suppressing the overcurrent generated in the wind power generator during the power grid accident and continuing the linkage operation.

In the prior art, a crowbar was used to suppress the overcurrent generated in the rotor winding during a power grid accident. However, since the rotor side converter (RSC) of the wind power generator is separated from the wind power generator during the operation of the crow bar , The wind turbine during that time loses control over the active power and the reactive power. Also, by using the method that does not use the crow bar, the flux-link follow-up gain is determined as a fixed value in consideration of the terminal voltage of the wind-power generator and the maximum permissible current before the occurrence of the accident, so that the same flux- It is not effective to suppress the overcurrent, and there is a problem that the reactive power can not be supplied until the flux-link-following control is converted into the voltage control.

Public number: 10-2013-0061995 (2013.06.12)

Accordingly, it is an object of the present invention to provide a wind turbine low-voltage power source capable of effectively recovering voltage and continuously supplying reactive power when a low-voltage accident occurs in a wind power generation complex, and preventing the operation of a crow bar by suppressing an over- And to provide a compensation control method.

A method for compensating a low voltage of a wind power generation plant according to an embodiment of the present invention includes the steps of monitoring generation of a low voltage by monitoring a grid voltage (PU), determining a cross-link magnetic flux following gain according to an operation state of an individual wind power generator Controlling the individual wind turbine generators according to the transmitted flux-link follow-up gain when the rotor current of the individual wind turbine generator exceeds a predetermined current, transmitting the determined cross-link magnetic flux following gain to the individual wind turbine generator . ≪ / RTI >

The step of determining the cross-link magnetic flux following gain may use a cross-link magnetic flux follow-up gain in consideration of the slip value of the individual wind turbine generator.

In addition, the wind power generation system low voltage compensation control method can supply the reactive power to the grid connection point (PCC) during the low voltage accident period.

Meanwhile, the wind power generation system low voltage compensation control system according to another embodiment of the present invention includes a system sensing unit for monitoring generation of a low voltage by monitoring the system voltage PU, And controls the individual wind turbine generators according to the transmitted flux-link follow-up gain when the rotor current of the control unit and the individual wind turbine generator, which determines the flux-link follow-up gain according to the state, is transmitted to the individual wind turbine generators And a wind turbine generator control unit.

Further, the control unit may determine the linkage magnetic flux following gain by using the linkage magnetic flux following addition gain considering the slip value of the individual wind turbine generator.

According to the present invention, even if a low-voltage accident occurs in a wind power generation plant, the system voltage is prevented from dropping rapidly, and the system voltage can be recovered quickly.

Further, it is possible to prevent the overcurrent from being generated in the rotor after the low-voltage fault period and after recovery by judging the control input time as the rotor current, and also to prevent the operation of the crow bar for suppressing the overcurrent.

In addition, since the control input time is determined as the rotor current, the operation time of the flux linkage tracking control is reduced, and the wind power generator can supply the reactive power during the low voltage accident period.

Further, in determining the flux-link follow-up gain, an effective cross-link magnetic flux follow-up control is possible in consideration of the operating state of the individual wind power generators by using the cross-link magnetic flux follow-up gain in consideration of the slip value of the individual wind power generators.

The effects of the present invention are not limited to the above-mentioned effects, and various effects can be included within the range that is obvious to a person skilled in the art from the following description.

1 is a view showing a wind turbine plant to which a low voltage compensation control method for a wind turbine according to an embodiment of the present invention is applied.
FIG. 2 is a flowchart illustrating a method for compensating a low voltage in a wind turbine according to an embodiment of the present invention. Referring to FIG.
3 is a graph showing voltage of a grid connection point (PCC) according to a method for compensating a low voltage of a wind power generation plant according to an embodiment of the present invention.
FIG. 4 is a graph illustrating the reactive power supply according to the low voltage compensation method of the wind power generation complex according to the embodiment of the present invention.
FIG. 5 is a graph illustrating a time point of control input according to a conventional method and a low voltage compensation control method of a wind power plant according to an embodiment of the present invention.
FIG. 6 is a graph showing rotor currents of a method for compensating a low voltage of a wind turbine according to an embodiment of the present invention.
FIG. 7 is a graph illustrating the operation of a crowbar according to a method of compensating a low voltage of a wind power generation system according to an embodiment of the present invention and an existing control method.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a method and system for compensating a low voltage in a wind power generation system according to the present invention will be described in detail with reference to the accompanying drawings. The embodiments are provided so that those skilled in the art can easily understand the technical spirit of the present invention, and thus the present invention is not limited thereto. In addition, the matters described in the attached drawings may be different from those actually implemented by the schematic drawings to easily describe the embodiments of the present invention.

On the other hand, the expression " comprising " is intended to merely denote the presence of the corresponding elements as an " open expression ", and should not be construed as excluding any additional elements.

1 is a view showing a wind turbine plant to which a low voltage compensation control method for a wind turbine according to an embodiment of the present invention is applied.

In this specification, for convenience of description, the wind turbine complex composed of 20 wind turbine generators (Doubly-Fed Induction Generators, 5 MW class) is connected to the power network through the connection line with the substation as shown in FIG. 1, Was set to a sinusoidal power source including the internal impedance. In addition, the input wind speed of the wind turbine is 12 m / s, the wind direction is 0 degree, and the rated current of the individual wind turbine generator is 1 PU. If the rotor current exceeds 1.1 PU, . It is assumed that a system fault occurs in the presence of a three-phase short-circuit fault at the front of the sine power supply.

FIG. 2 is a flowchart illustrating a method for compensating a low voltage in a wind turbine according to an embodiment of the present invention. Referring to FIG.

First, the system voltage at the grid connection point (PCC) point is monitored to detect the occurrence of undervoltage. Specifically, a configuration such as a system detection unit or a system measurement unit is connected to a grid connection point to monitor the system voltage and detect a low voltage. When the system is normally operated, the system voltage is maintained at 1 PU. If a system voltage is low due to a problem in the system, the system voltage rapidly decreases instantaneously. Therefore, it is preferable to monitor the system voltage in real time to detect occurrence of a low voltage.

Thereafter, when a low voltage is detected in the system voltage as a result of detection, only the control section determines the flux-link follow-up gain. The flux-linking follow-up gain is for suppressing the overcurrent of the rotor windings by causing the flux linkage of the rotor windings to follow the flux linkage of the stator windings. Specifically, only the control unit controls the flux linkage gain . The linkage flux follow - up gain is determined by the following equation using the flux linkage follow - up gain considering the slip value.

K _a ^* = | slip _max / slip ^WGi

K _T ^* = K _T * K _a ^* (0? K _T ^*? 1)

here, K _a ^* Slip _max is the slip value of the wind turbine with the largest slip in the wind power ^plant , slip ^WGi is the slip value of the wind turbine with K _a ^* only from the control section, K _T ^* is the flux linkage gain controlling the individual wind turbine, The slip value of the assigned wind turbine. Also, slip value of the rotating magnetic field and rotor angular velocity and calculates a ratio of the angular velocity of the rotating magnetic field of the order of the electron angular velocity as _{(W s -W r) / W} s. (W s is the angular velocity the rotating magnetic _field, W _r is the rotor The rotor speed of the individual wind turbine generator can be taken into consideration by using the flux-linking follow-up gain K _a ^* considering the slip value in determining the flux-link follow-up gain K _T ^* for controlling the individual wind turbine generators . On the other hand, K _T Is calculated by multiplying the minimum flux-link following gain for suppressing the overcurrent in the individual wind turbine generator by a tuning value between 1.2 and 1.5.

In the past, in order to follow the flux linkage, the linkage flux gain was determined as a fixed value considering the terminal voltage of the wind turbine before the accident and the maximum permissible current, and since the same flux linkage follow-up gain is uniformly applied to all wind turbines And it was not effective in suppressing the overcurrent generated in a power grid accident. However, in this embodiment, since the rotor speed of the individual wind turbine generators is taken into account by using the flux-link follower addition gain considering the slip value in determining the flux linkage follow-up gain, the individual wind turbine generators are different from each other, The follow-up gain is determined, and it is possible to effectively suppress the overcurrent generated in the power network accident. Therefore, a large flux-link follow-up gain will be determined for the wind turbine operating near the synchronous speed, and a relatively small flux-link follow-up gain will be determined for the wind turbine operating from the synchronous speed.

When the flux-link follow-up gain is determined, the control unit only transfers the determined flux-link follow-up gain to the individual wind turbine generator. Since the flux-link tracking gain is transmitted to the individual wind turbine generators to control the output of each wind turbine generators, it is preferable to transmit them to a configuration such as a wind turbine generator controller.

As a final step, the individual wind turbine generator is controlled according to the flux linkage follow-up gain received from the control unit only. Here, the control of the individual wind turbine generators will be performed by a configuration such as a wind turbine generator controller (for example, a VSC controller), and control starts when the rotor current of the individual wind turbine generator exceeds a predetermined current. The flux-flux control input set current can be varied according to the specification of the individual wind turbine generator. In the conventional control method of flux - flux tracking, it is impossible to compensate the reactive power during the low - voltage fault period until the terminal voltage is restored by setting the control input reference of the individual wind power generator to the terminal voltage. When the voltage is restored, And the overcurrent of the rotor could not be suppressed. However, in this embodiment, by setting the input reference of the flux-link follow-up control to the rotor current, it is possible to continuously compensate for reactive power through voltage control and control switching during the fault period, , It is possible to suppress the overcurrent generated in the rotor after an accident.

On the other hand, in the control, the linkage magnetic flux following control is performed so that the rotor linkage flux of the individual wind turbine generator tracks the stator linkage flux. Specifically, the difference between the stator flux linkage and the rotor linkage flux is calculated, , Calculates the flux linkage using each stator and the rotor current, calculates the target flux linkage using the calculated flux linkage, and finally commands the rotor voltage Thereby controlling the rotor flux linkage.

According to the above-described low voltage compensation control method, it is possible to shorten the time required for recovery of the system voltage by judging the control input time as the rotor current, and at the same time, it is possible to prevent the system voltage from drastically falling. In addition, it is possible to continuously supply reactive power during the accident period, and it is possible to prevent an overcurrent from being generated in the rotor. Hereinafter, the effects of the conventional control method will be described in detail with reference to FIG. 3 to FIG.

FIG. 3 is a graph showing a voltage of a grid connection point (PCC) according to a method for compensating a low voltage of a wind power generation plant according to an embodiment of the present invention. FIG. 4 is a graph illustrating reactive power supply, Fig. Also, the solid line is a graph to which the low voltage compensation method of the wind power generation complex according to the present invention is applied, and the one-dot chain line is a graph of the conventional control method.

Referring to FIG. 3, the system voltage before the accident was maintained at 1PU, but the system voltage suddenly dropped due to the occurrence of an accident near 7.025 seconds, and the accident was terminated near 7.325 seconds. It can be seen that the graph according to the present invention is located at a higher position than the graph of the conventional control method during the accident period and the time required for recovering the system voltage to 1 PU is also shortened. This is due to the low voltage compensation control method of the present invention. The flux-link follow-up control of the proposed method suppresses the rotor current so that the flux-link follow-up control is switched to control with the voltage control, It is possible to prevent the system voltage from dropping sharply, and the time required for recovery of the system voltage can be shortened. 5, which shows the control input time point, in the present invention, it is confirmed that the control input signal is generated in the vicinity of 7.025 seconds in which the low voltage accident occurs, and the control input signal is not generated in the vicinity of 7.05 seconds after the occurrence of the low voltage accident. This is because the rotor current exceeded the critical current from about 7.025 sec to about 7.05 sec. However, according to the existing control method, the control input point is similar, but since the flux-link follow-up control is continuously maintained during the low-voltage accident period, the reactive power can not be supplied to the grid connection point (PCC) And it takes more time to restore grid voltage.

In addition, referring to FIG. 4 showing the reactive power supply, the low voltage compensation control method of the present invention can continuously supply reactive power to the grid connection point (PCC) during an accident period. However, the conventional control method can not supply the reactive power during the accident period because the reactive power can not be supplied until the flux-link follow-up control is switched to the voltage control after the occurrence of the accident. Referring to FIG. 5 showing the control input timing, the control input signal is generated in the vicinity of 7.025 seconds in the present invention, and no control input signal is generated in the vicinity of 7.05 seconds. Therefore, the flux-link follow-up control is switched to the voltage control from around 7.05 seconds, and it is possible to continuously supply the reactive power to around 7.325 seconds when the accident is over (during the accident period). However, in the conventional control method, the control input signal is continuously generated from the vicinity of about 7.025 seconds to about 7.35 seconds, and the flux-link follow-up control is switched to the voltage control after about 7.35 seconds when the grid voltage is restored. Therefore, reactive power can not be supplied up to around 7.325 seconds (during the accident period) when the accident is over.

FIG. 6 is a graph showing the rotor current, and FIG. 7 is a graph showing the operation of the Crowbar. Similarly, the solid line is a graph to which the low voltage compensation control method of the present invention is applied, and the one-dot chain line is a graph of the conventional control method.

When the accident period and the rotor current at the end of the accident are examined, it can be seen that the graph of the present invention has fewer sections exceeding 1 PU which is the rated current of the individual wind turbine generator. This is also based on the low voltage compensation control method of the present invention. If you look at the graph, you can see that the rotor current suddenly increases (around 7.025 seconds) immediately after the accident, but it drops immediately below the rated current. This is because the current exceeded the preset current of 1.1 PU during the surge, so that the control was immediately turned on and the rotor current dropped below the predetermined current. As in the case of the grid voltage, in the case of the present invention, the flux-link follow-up control is applied in the vicinity of 7.025 seconds to suppress the generation of the overcurrent exceeding the rated current in the rotor, but according to the existing control method, However, when the terminal voltage is restored after the end of the accident, the control is terminated, thereby making it impossible to suppress the overcurrent of the rotor, and an overcurrent may be generated in the rotor. Therefore, in the case of the present invention, the crowbar is operated only for a short time immediately after the occurrence of the low-voltage accident, and when the overcurrent is generated, Since the overcurrent exceeding the rated current is prevented from being generated in the former, the crowbar does not operate after the end of the accident. However, in the conventional control method, in order to suppress the overcurrent generated not only immediately after the occurrence of the low- The crow bar is operated again.

The wind power generation system low voltage compensation control method according to the present invention can be applied to a wind power generation system low voltage compensation control system including the wind power generation system low voltage compensation control method which includes the same feature as the wind power generation system low voltage compensation control method in one embodiment of the present invention, . Therefore, although not described in detail in order to prevent redundancy, the above-described features relating to the low-voltage compensation control method can be applied to the low-voltage compensation control system as a matter of course.

The embodiments of the present invention described above are disclosed for the purpose of illustration, and the present invention is not limited thereto. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention.

110:
120: Individual wind turbine generator

Claims (5)

Monitoring a system voltage to detect occurrence of a low voltage;
Determining a flux-link follow-up gain according to an operating state of the individual wind turbine generator when a low voltage is detected;
Transmitting the determined flux-link following gain to an individual wind turbine generator; And
Controlling an individual wind power generator according to the transmitted flux-link following gain when the rotor current of the individual wind power generator exceeds a predetermined current;
≪ / RTI >
The method according to claim 1,
The step of determining the cross-link magnetic flux following gain includes:
A method of compensating a low voltage of a wind turbine using a flux-tracking additional gain in consideration of a slip value of an individual wind turbine generator
The method according to claim 1,
The wind power generation system low voltage compensation control method includes:
And the reactive power is supplied to the grid connection point (PCC) during the low-voltage accident period.
A system detecting unit for monitoring the system voltage to detect occurrence of a low voltage;
A complex controller for determining a flux-link follow-up gain according to the operation state of the individual wind turbine generator when the low voltage is generated as a result of the detection by the system sensing unit and transmitting the determined gain to the individual wind turbine generators; And
A wind turbine generator control unit for controlling the individual wind turbine generators according to the received flux linkage following gain when the rotor current of the individual wind turbine generator exceeds a predetermined current;
Wind power generation complex low voltage compensation control system
5. The method of claim 4,
The merely-
Wherein the gain of the flux linkage is determined by using a flux-linking additional gain in consideration of the slip value of the individual wind turbine generator.

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