JP5190050B2 - Wind power generation system, wind power generation control device, and wind power generation control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce generated electrical power reduction by reducing the number of wind turbine generators to be stopped. <P>SOLUTION: This wind turbine generator system includes: a transmission/reception section 51 receiving operation information including information on wind speed received by each wind turbine generator in a wind farm through a network 5; a wind speed threshold determination means 52 determining whether or not wind speed is higher than a predetermined threshold; a correlation coefficient calculation means 53 calculating the correlation coefficient of the wind speed between the wind turbine generators; a stop determination means 54 selecting such a wind turbine generator that it is determined by the wind speed threshold determination means that the wind speed is higher than the threshold and it is determined that an operation result calculated by the correlation coefficient calculation means is higher than a predetermined value; and a stop command means 55 transmitting a stop command to the wind turbine generator selected by the stop determination means. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a wind power generation system, a wind power generation control apparatus, and a wind power generation control method using a plurality of wind power generation apparatuses, and more particularly to a wind farm system that supplies power generated using wind energy to an electric power system. .

  In recent years, wind power generation has been widely introduced worldwide as one of the measures against global warming. From the viewpoint of cost effectiveness, wind power generation is often installed as a wind farm in which a plurality of wind power generation devices are provided in a certain area and a large number of wind power generation device groups are operated in a lump.

Since the power generation output of a wind turbine generator fluctuates depending on weather conditions, there is a concern about the effect of maintaining the voltage and frequency of the power system when the introduction to the power system further increases.
Generally, a wind turbine generator is configured to control the power generation output to be constant by changing the pitch angle of the blades to keep the rotation frequency constant or by changing the excitation current of the generator. As a result, the wind turbine generator is configured so that the output increases as the wind speed increases until the wind speed reaches the rated wind speed, and when the wind speed further increases, the wind power generator is operated at the rated output until the cutoff value. This cut-off value is generally set to a wind speed at which a mechanical component reaches a fatigue limit value due to a mechanical load acting on the blades of the wind turbine generator.
In many cases, the wind turbine generator is provided with a safety function for stopping the device for protecting the device at a wind speed higher than the cutoff wind speed. At the time of this stop, the output of the wind turbine generator changes rapidly from the rated output to the output zero. In the wind farm, when a plurality of wind power generators reach the cutout wind speed and stop at the same time, the output fluctuation of the entire wind farm becomes extremely large.

On the other hand, an electric power system in which a plurality of wind turbine generators are connected to each other needs to secure a sufficient capacity of a power plant or the like so that supply and demand adjustment is not hindered even if the output of the wind turbine generator fluctuates. . However, as the amount of wind power generators increases and the size of the wind farm increases, there is a problem that the equipment burden on the power company that maintains the power system increases. For this reason, electric power companies have come to require wind power generation operators to limit fluctuations so that the number of wind power generators connected to each other is limited and the output fluctuations of the wind farm fall within a predetermined range. ing.
Up to now, various proposals have been made as methods for mitigating fluctuations in wind farm output during strong winds. For example, in Patent Document 1, the wind speed of each wind power generation facility is monitored, and when the average value of the wind speed exceeds a threshold value, the output of the entire wind farm is reduced by a certain slope (ramp rate), thereby rapidly increasing the wind speed. A technique for preventing a significant output fluctuation is disclosed.

JP 2006-170208 A

  However, in the technique disclosed in Patent Document 1, it is assumed that the wind power generation system exceeding the wind speed threshold reaches the cutout wind speed at the same time. For this reason, it is not certain whether the wind speed reaches the cutout value as it is, and the timing of reaching the cutout value is not always the same. Therefore, when the wind speed does not reach the cutout value after the stop command and falls below the threshold value, there is a problem that the generated power is reduced due to an unnecessary stop process that does not need to be stopped.

In addition, the electric power company defines the output fluctuation range of the entire wind farm as the difference between the maximum value and the minimum value during the predetermined evaluation time for the wind power generation company, and this output fluctuation range is within a predetermined range. In some cases, it is required to operate the wind farm so that it falls within the range. Even in this case, in the case of a large-scale wind farm, even if a plurality of stops due to cutouts during strong winds occur at the same time, the output variation within the predetermined range as a whole wind farm is less likely to cause a problem.
Even in this case, in the method described in Patent Document 1, the wind power generation system is stopped according to the ramp rate, so that there is a problem that generated power is reduced due to unnecessary stop processing.

  The present invention has been made to achieve the above-described problem, and can reduce the number of wind power generation devices to be stopped and reduce the decrease in generated power, a wind power generation control device, and wind power generation. An object is to provide a control method.

  To achieve the above object, the present invention is a wind power generation system (200) comprising a plurality of wind power generation devices (11, 12, 13) connected to an electric power system (7) and capable of controlling output power. A plurality of individual control devices (31, 32, 33) that transmit operation information including information on wind speed received by each wind turbine generator via the communication network (5), and the individual control device via the communication network. And a centralized control device (41) that receives the operation information of the plurality of wind turbine generators and calculates the output fluctuations of the plurality of wind turbine generators, and the centralized controller transmits the operation information sent from each wind turbine generator. The wind speed correlation coefficient is calculated between the wind power generator and the transmission / reception unit (51) that receives the wind speed, the wind speed threshold determination means (52) that determines whether or not the wind speed is higher than a predetermined threshold. Correlation coefficient The means (53) and the wind speed threshold value determining means determine that the wind speed is faster than the threshold value, and stop selecting the wind turbine generator that determines that the calculation result calculated by the correlation coefficient calculation means is higher than a predetermined value. A determination unit (54), and a stop command unit (55) for transmitting a stop command to the wind turbine generator selected by the stop determination unit, wherein the individual control device is a stop command transmitted from the centralized control device. In response to this, the operation of the wind turbine generator is stopped. The numbers in parentheses are examples.

  ADVANTAGE OF THE INVENTION According to this invention, the number of the wind power generators to stop can be reduced and the fall of generated electric power can be reduced.

It is a block diagram of the wind power generation system which is one Embodiment of this invention. It is a characteristic view showing the relationship between the wind speed and output of a general wind power generator. It is a block diagram which shows the structure of the centralized control apparatus which is one Embodiment of this invention. It is a block diagram which shows the connection relation of the separate control apparatus which is one Embodiment of this invention. It is a schematic diagram showing the process of the correlation coefficient calculating means of a centralized control apparatus. It is a flowchart which shows the process of the stop determination means of a centralized control apparatus. It is a table | surface which shows the calculation result of the correlation coefficient of the windmills exceeding the wind speed threshold value. It is a figure for demonstrating the change of the wind farm output by a centralized control apparatus. It is a graph for demonstrating stop operation | movement of the stop process by a centralized control apparatus.

(First embodiment)
FIG. 1 is a configuration diagram of a wind power generation system according to an embodiment of the present invention.
The wind power generation system 200 includes a wind farm 100 including a plurality of wind power generation apparatuses 11, 12, 13 and a wind power generation facility 14, a central control device 41 that controls the wind farm 100, a storage device 42, The power system 7 connected to the wind farm 100 and the customer 8 are included.

In the wind farm 100, the wind power generators 11, 12, 13 and the wind power generation facility 14 are connected to the power system 7 including the power plant at one location via the transmission line 9, and the wind system 100 and the wind farm 100 are connected. Both supply power to the customer 8.
The wind turbine generator 14 has a plurality of wind turbines d, e, f, g,... Similar to the wind turbines a, b, c of the wind turbine generators 11, 12, 13. Wind turbines a, b, c, d, e, f, g,... Of each wind turbine generator can vary the pitch angle of the blades and can control the rotation frequency.

The wind power generators 11, 12, and 13 are connected to meteorometers 21, 22, and 23 and individual control devices 31, 32, and 33, respectively. The meteorometers 21, 22, and 23 are set in the vicinity of the wind turbine generators 11, 12, 13, and 14 and measure the wind direction, wind speed, and atmospheric pressure received by the wind turbine generators 11, 12, 13, and 14.
The individual control devices 31, 32, 33 and the individual control device of the wind power generation facility 14 are connected to each other via the communication network 5 and to the central control device 41. The storage device 42 is connected to the centralized control device 41 and sequentially stores operation information such as output characteristic data of the wind power generators 11, 12, 13 and the wind power generation facility 14.

FIG. 2 is a characteristic diagram showing a relationship between wind speed [m / s] and output [%] of a general wind power generator. In general,
Wind kinetic energy = (1/2) x "mass of wind [kg]" x "square of wind speed"
Wind mass per unit time [kg / s] = cross-sectional area [m ² ] × air density [kg / m ³ ] × wind speed [m / s]
So
Wind power [W] = (1/2) × “cross-sectional area [m ² ] ד air density [kg / m ³ ] ”ד wind velocity [m / s] to the third power ”
It becomes. Therefore, the output of the wind power generators 11, 12, 13 and the like increases so that the wind speed is proportional to the cube of the wind speed until the wind speed reaches the rated wind speed of the wind power generator.

When the wind speed further increases, the wind power generators 11, 12, 13 and the like are configured to operate (rated operation) at the rated output (100%) up to the cutoff value because the rotation frequency can be controlled. Specifically, the wind speed at the start of power generation (cut-in) at which the windmill begins to rotate is 3 m / s, the rated wind speed is 12 m / s, and the stop wind speed (cutout) is 25 m / s. Note that the cutoff value of a wind turbine generator is generally the wind speed at which a mechanical component reaches a fatigue limit value due to a mechanical load acting on the wind turbine generator. The rated operation may be substantially constant with respect to the wind speed even if there is a variation within a predetermined range. As a safety function, in many cases, at a wind speed (stop wind speed) faster than a wind speed that is a cut-off value, the wind turbine generator is stopped for equipment protection.
This characteristic is stored for each wind power generator in the wind farm, and a wind speed threshold value described later is set to a value that is larger than the rated wind speed and lower than the stop wind speed (cutout wind speed).

  FIG. 3 is a block diagram showing the configuration of the central control apparatus. In FIG. 3, the centralized control device 41 includes a transmission / reception unit 51 connected to the communication network 5 and a control unit 50 connected to the storage device 42. The control unit 50 includes a wind speed threshold value determination unit 52, Correlation coefficient calculation means 53, stop determination means 54, and stop command means 55 are provided. Each means 52, 53, 54, 55 is realized by a CPU (Central Processing Unit) executing a program. The storage device 42 stores a wind speed threshold value, an allowable output fluctuation range, and an evaluation time. The wind speed threshold value determination unit 52 and the stop command unit 55 refer to the storage device 42.

  The wind direction and wind speed data of each wind turbine generator obtained from the communication network 5 is input to the wind speed threshold determination means 52 via the transmission / reception unit 51. The wind speed threshold determination means 52 determines whether or not the wind speed received by each wind turbine generator has reached the threshold. The threshold data is stored in the storage device 42, and can be set in advance as a value between the rated wind speed and the stop wind speed, or can be dynamically changed. Since the wind speed repeatedly fluctuates in a short time, it is possible to determine whether or not the wind speed has reached the threshold based on data smoothed using a statistical method such as moving average. The determination result is input to the correlation coefficient calculation unit 53, and the correlation coefficient calculation unit 53 calculates the correlation coefficient between the wind speed and the wind direction between the plurality of wind turbine generators whose wind speed has reached the threshold value. Thereby, about the several wind power generator with a high correlation coefficient, it is considered that the probability which reaches | attains cutout wind speed simultaneously is high.

  The calculation result of the correlation coefficient is input to the stop determination unit 54. The stop determination unit 54 has a probability of reaching the cutout wind speed at the same time as the “variable range allowable value” of the wind farm output stored in the storage device 42. Compare the value of output fluctuation when high wind power generators are stopped at the same time, and if the value of output fluctuation exceeds the allowable value, cut at least one of the multiple wind power generators with high correlation coefficient It is determined that the wind turbine generator actively stops before reaching the out wind speed.

  The determination result of the stop determination unit 54 is input to the stop command unit 55, and the stop command unit 55 transmits a stop command to the wind turbine generator that actively stops using the transmission / reception unit 51. When there are a plurality of wind turbine generators or a plurality of wind turbine generators to be stopped, the stop determination unit 54 can also shift the stop timing by at least an evaluation time for evaluating an allowable value of output fluctuation. Further, the latest wind speed value in the wind power generation system in the stop process, which is input to the wind speed threshold determination means 52 during the process of stopping by shifting the stop timing by the “evaluation time” stored in the storage device 42, If it is below the threshold value, the stop command means 55 can also stop the stop process to prevent a decrease in generated power.

FIG. 4 is a block diagram of the individual control device and a configuration diagram showing a connection relationship thereof.
In FIG. 4, the individual control devices 31, 32, and 33 include at least an input unit 34, a communication unit 35, a pitch angle control circuit 36, and a power conversion circuit 37. The input means 34 sequentially inputs the wind speed / wind direction data of the meteorometers 21, 22 and 23, and inputs the output value of the wind power generator using the power sensor 25 provided in each wind power generator. . The communication means 35 outputs wind speed / wind direction data and output data output from the input means 34 to the communication network.
The pitch angle control circuit 36 is a circuit that varies the pitch angle of the blades of the windmill and controls the blade rotation frequency to be constant (rated rotation frequency). The power conversion circuit 37 converts the AC output of an arbitrary frequency of a generator (not shown) included in the wind power generator into power and converts it into an AC output of commercial voltage and commercial frequency.

  FIG. 5 is a diagram schematically showing the processing of the correlation coefficient calculating means 52 (FIG. 3). In FIG. 5, it is assumed that the wind turbines A, B, and C (indicating any one of the wind turbines a, b, c,...) Of the three wind turbine generators have reached the wind speed threshold value. For B and C, and C and A), the correlation between measured values of wind speed and direction is obtained. The left column is a diagram showing the time change of the wind speed measurement values (thin lines), wind speed average values (thick lines), and wind direction measurement values (arrows) of the windmills A, B, and C used in the wind turbine generator. The upper row shows the correlation coefficient between the wind speed average value (thick line) of windmill A and the wind speed average value (thin line) of windmill B, and the middle row on the right column shows the wind speed average value (solid line) of windmill B and windmill C. Is a diagram showing a correlation coefficient between the wind speed average value (dashed line) of the wind turbine A, and the lower column in the right column shows a correlation coefficient between the wind speed average value of the wind turbine A (thick line) and the wind speed average value of the wind turbine C (dashed line). It is.

  These correlation coefficients are calculated from time-series data obtained by averaging the measured values from the previous predetermined time (for example, 30 minutes) to the current time as the wind speed and direction. Has been. Thereby, the calculated correlation coefficient excludes the influence of short-term random fluctuations with a period of several seconds. Note that the correlation coefficient is similarly obtained for the wind direction in which the azimuth is digitized (for example, 16 azimuths are 01: NNE, 02: NE to 15: NNW, 16: N). The stop determination means 54 (FIG. 3) can use one or both of the correlation coefficient of the wind speed and the correlation coefficient of the wind direction.

FIG. 6 is a flowchart showing in detail the processing of the stop determination means.
This flow is started after the correlation coefficient calculation means 53 calculates the mutual coefficient. The stop determination unit 54 reads the calculation result of the correlation coefficient of both the wind speed and the wind direction of the wind turbine generator that exceeds the threshold, which is obtained by the correlation coefficient calculation unit 53 (S1). In the example of FIG. 7, among the plurality of wind turbine generators a, b, c,..., Q, r, s, six wind turbine generators a, c, g, k, n, r exceed the wind speed threshold. I'm trying.
Next, the stop determination unit 54 reads the allowable value of the output fluctuation range of the wind farm 100 and the set value of the evaluation time (S3). Next, from the read correlation coefficient, the stop determination unit 54 extracts a wind turbine generator having a correlation coefficient higher than a predetermined value (S5). In the example of FIG. 7, it is determined that the correlation coefficient of the two machines c-k that are shaded and the three machines gn-r is high. That is, the correlation coefficient of c−k is 0.9, the correlation coefficient of g−n is 0.8, the correlation coefficient of n−r is 0.8, and the phase relationship of g−r The number is 0.9, and these correlation coefficients are the highest.

  Note that the predetermined value of the correlation coefficient can be dynamically changed based on the operation results of the wind farm 100. Next, the stop determination means 54 calculates the output fluctuation that occurs when it is assumed that the wind turbine generator that has been determined to have a high correlation coefficient is stopped at the same time by the cutout, and the calculated output fluctuation and the output fluctuation are calculated. The allowable width is compared (S7). Since the output fluctuation is the amount of change from the rated output to the stop, it can be obtained as the sum of the rated outputs of the wind turbine generators to be stopped. That is, the output fluctuation increases as the number of wind turbine generators to be stopped increases. Therefore, in the example of the drawing, the evaluation is less than the allowable value when the two machines ck are stopped simultaneously, and exceeds the allowable value when the three machines gn-r are simultaneously stopped.

  Next, the stop determination means 54 performs stop determination with respect to the wind turbine generator that exceeds the load fluctuation tolerance (S9). With respect to one or a plurality of wind turbine generators in which the processing of the stop determination unit 54 has been completed and the stop command unit 55 has been determined to stop. Issue a stop command.

  It should be noted that, for the two aircrafts ck that are less than the allowable value by comparing the output fluctuation with the allowable value (S7), even if the wind speed reaches the cutout value and stops at the same time, the output fluctuation This is less than the farm's overall tolerance, so this is not a problem. Therefore, the stop determination unit 54 does not perform active stop processing for the two aircrafts ck. On the other hand, for the three gn-r aircraft that exceeded the allowable value, if the wind speed reaches the cutout value and stops at the same time, output fluctuations exceeding the allowable value occur. Therefore, the stop determination unit 54 determines to actively stop one of the three wind turbine generators g.

At this time, the stop determination unit 54 does not perform the stop process for the remaining two rn machines, because the output fluctuation falls below the allowable value even if the two ck machines are stopped at the same time. That is, the purpose is achieved by stopping g. Which of the three wind turbine generators is to be given priority to stop is determined by a simple numbering priority order, or in order to average the operating rate of each wind turbine generator, A method of stopping with priority from the power generator is also possible.
In another modification, it is also possible to reduce the output in a slope shape over a predetermined time with respect to the wind turbine generator that has been determined to be actively stopped. In yet another embodiment, it is possible to reduce the output to a predetermined value for the wind turbine generator determined to perform the active stop.

FIG. 8 is a graph for explaining how the output of the entire wind farm changes, and describes the processing of the stop determination means 54. In order from the top, a diagram showing a time change in the output of the windmill g, a diagram showing a time change in the output of the windmill n, a diagram showing a time change in the output of the windmill r, and the bottom row other than the windmills g, n, r. It is a figure which shows the time change of the total output of the wind farm 100 also including a wind power generator.
When the control according to the present embodiment is not performed, the wind turbine g moves in a broken line “no control”, reaches the cut-out wind speed almost simultaneously with the wind turbines n and r, and stops. As a result, the total output of the wind farm becomes the operation of the broken line “no control” in the lowermost stage, and when the three aircrafts are stopped simultaneously, the wind farm output fluctuation allowable value shown in the figure (double-headed arrow) is exceeded. Variations will occur.

  On the other hand, by the stop determination process, the windmill g is stopped by a stop command when the wind speed exceeds the threshold value, that is, before the wind speed reaches the cutout value and actually stops. As a result, the total output of the wind farm 100 is the operation indicated by the solid line “with control” in the lowermost stage, and the output fluctuation in the evaluation time width shown in the figure falls below the fluctuation allowable value (double-headed arrow). . As a result, the output fluctuation of the entire wind farm 100 falls within the allowable fluctuation value. In addition, since it is only necessary to give a stop command to one of the wind turbines (wind power generators) whose wind speed exceeds the threshold value, it is possible to prevent the generated power of the wind farm 100 from being unnecessarily reduced.

  FIG. 9 is a graph showing the operation when the latest wind speed measurement value falls below the threshold value in the stop command means 55 during the stop process of the stop determination means 54. The upper part of FIG. 9 is a graph obtained by averaging the measured value of the wind speed and the measured value of the wind speed in the wind turbine generator during the stop process. The lower part of FIG. 9 is a graph showing the total output of the wind farm 100. In the upper graph, when the wind speed average value exceeds the threshold value at time t1 and the stop processing is performed by the stop determination unit 54 in the lower graph, the operation of the broken line “continuation of stop processing” is performed.

  On the other hand, at the time of “continuation of stop process”, the wind speed average value of the wind turbine generator during the stop process is below the threshold value that requires the stop process at time t2 (upper part of FIG. 9). If the wind speed decreases, the stop process is not necessary, so the stop process is stopped. As a result, an operation such as “stop processing stop” in the lower stage is performed, and a restart command is also output to the wind turbine generator that has been stopped at time t1 to restart power generation. As a result, it is possible to prevent unnecessary reduction in generated power when the stop process is continued.

  As described above, according to the wind power generation system 200 of the present embodiment, the individual control devices 31, 32, 33 provided in the respective wind power generation devices 11, 12, 13,. A centralized control device 41 that performs an output prediction calculation based on the operation information included, and the centralized control device 41 determines the rated wind speed and the stop wind speed (cut) from the measured values of wind speed and wind direction measured by each wind power generator in the wind farm 100. Select a wind turbine generator in a rated operating state that receives a wind speed that is equal to or higher than a threshold value set between Then, the central control device 41 stops at least one of the wind turbine generators whose wind speed correlation coefficient is higher than a predetermined value via the individual control devices 31, 32, 33. Thereby, the fall of generated electric power can be prevented, maintaining the required output fluctuation range.

Further, the central control device 41 determines that the overall output fluctuation range of the plurality of wind turbine generators when the plurality of wind turbine generators determined that the calculation result of the correlation coefficient is higher than the predetermined value stops simultaneously is an allowable value. By stopping the surplus wind power generator, the output fluctuation of the wind farm 100 during a strong wind is maintained within a predetermined allowable range.
Further, when there are a plurality of wind turbine generators to be stopped, an evaluation time for determining whether or not the overall output fluctuation range exceeds the allowable value is set in advance, and the stop command timing is set for the set evaluation time. Is preferably shifted.

(Modification)
The present invention is not limited to the above-described embodiment, and various modifications such as the following are possible, for example.
(1) Although the said embodiment determined the wind power generator to stop based on the information of a wind speed, the information of a wind direction can also be utilized. That is, the operation information includes not only the wind speed but also the wind direction information, the correlation coefficient calculating means 53 calculates the wind speed and the wind direction correlation coefficient, and the stop determining means 54 has the first correlation coefficient of the wind speed. When a plurality of wind turbine generators higher than a predetermined value are selected, a wind turbine generator having a wind direction correlation coefficient higher than a second predetermined value is selected, and the output fluctuation range of the selected wind turbine generator is It is determined whether or not the allowable value is exceeded.
(2) In the above embodiment, the wind speed threshold determination means 52 determines whether the wind speed is equal to or higher than the threshold, and the correlation coefficient calculation means 53 calculates the correlation coefficient between the wind power generators determined to have a high wind speed. It is also possible to select a wind power generator with a high wind speed after calculating correlation coefficients between all the wind power generators. That is, when the wind speed threshold determination means 52 determines that the wind speed is faster than the threshold, the stop determination means 54 selects a wind turbine generator that determines that the calculation result calculated by the correlation coefficient calculation means 53 is higher than a predetermined value. The stop command means 55 transmits a stop command to the selected wind turbine generator.
(3) In the above embodiment, the individual control devices 31, 32, 33 including the pitch angle control circuit 36 and the power conversion circuit 37 are installed in the vicinity of the wind power generators 11, 12, 13, and the communication network 5 is used. The individual control device connected to the central control device 41 but not having the pitch angle control circuit 36 and the power conversion circuit 37 and the central control device are provided in the same hardware, and this control device is provided in the pitch angle control circuit 36. And a wind power generator provided with the power conversion circuit 37.

DESCRIPTION OF SYMBOLS 5 Communication network 7 Electric power system 8 Customer 9 Transmission line 11, 12, 13 Wind power generator 14 Wind power generation equipment 21, 22, 23 Meteorometer 25 Electric power sensor 31, 32, 33 Individual control apparatus 34 Input means 35 Communication means 36 Pitch Angle control circuit 37 Power conversion circuit 41 Centralized control device (control device)
42 Storage Device 50 Control Unit 51 Transmission / Reception Unit 52 Wind Speed Threshold Determination Unit 53 Correlation Coefficient Calculation Unit 54 Stop Determination Unit 55 Stop Command Unit 100 Wind Farm 200 Wind Power Generation System a, b, c, d, g, k, n, r Windmill

Claims (9)

A wind power generation system including a plurality of wind power generation devices connected to an electric power system and capable of controlling output power,
A plurality of individual control devices for transmitting operation information including information on wind speed received by each wind turbine generator via a communication network;
A centralized control device that receives the operation information from the individual control device via the communication network, and calculates the overall output fluctuation of the plurality of wind turbine generators;
The central control device is:
A transmission / reception unit that receives operation information sent from each wind power generator, a wind speed threshold determination unit that determines whether or not the wind speed is faster than a predetermined threshold, and a wind speed correlation between the wind power generators Wind power generation that determines that the calculation result calculated by the correlation coefficient calculating means is higher than a predetermined value by the correlation coefficient calculating means for calculating the number and the wind speed threshold determining means determining that the wind speed is faster than the threshold A stop determining means for selecting a device, and a stop command means for transmitting a stop command to the wind turbine generator selected by the stop determining means,
The said individual control apparatus stops the driving | operation of the said wind power generator according to the stop command transmitted from the said centralized control apparatus, The wind power generation system characterized by the above-mentioned.   The stop determination means has a total output fluctuation range of the plurality of wind power generators when a plurality of wind power generators determined that the calculation result of the correlation coefficient calculation means is higher than the predetermined value are simultaneously stopped, The wind power generation system according to claim 1, wherein it is further determined whether or not the allowable value is exceeded, and the wind power generation device that exceeds the allowable value is selected.   The stop determination means presets an evaluation time for determining whether or not the overall output fluctuation range of the plurality of wind turbine generators exceeds an allowable value, and the stop instruction means is supplied to the stop command means only for the set evaluation time. The wind power generation system according to claim 2, wherein the command timing is shifted. The driving information includes wind direction information,
The correlation coefficient calculating means further calculates a correlation coefficient of the wind direction,
The stop determination means selects a wind turbine generator whose wind direction correlation coefficient is higher than another predetermined value when a plurality of wind turbine generators whose wind speed correlation coefficient is higher than the predetermined value is selected. The wind power generation system according to claim 3, wherein it is determined whether an output fluctuation range of the selected wind power generator exceeds the allowable value. The output power control is to control at the rated output from the rated wind speed of each wind turbine generator to the stop wind speed,
The wind power generation system according to any one of claims 1 to 4, wherein the predetermined threshold value is set to an intermediate value from the rated wind speed to the stop wind speed.   The wind power generation system according to any one of claims 1 to 5, wherein the output power control is performed by changing a pitch angle of blades of the wind power generation device.   The wind power generation system according to any one of claims 1 to 6, wherein the central control device and the individual control device are provided in the same hardware. A wind power generation control device that controls a plurality of wind power generation devices capable of controlling output power,
A transmission / reception unit that receives operation information including wind speed information received by each wind power generator, a wind speed threshold determination unit that determines whether or not the wind speed is faster than a predetermined threshold, and a wind power generator The correlation coefficient calculation means for calculating the correlation coefficient of the wind speed and the wind speed threshold value determination means determine that the wind speed is faster than the threshold value, and the calculation result calculated by the correlation coefficient calculation means is higher than a predetermined value. A wind power generation control device comprising: a stop determination unit that selects a wind power generation device that is determined to be; and a stop command unit that transmits a stop command to the wind power generation device selected by the stop determination unit. A wind power generation control method executed by a wind power generation control device that controls a plurality of wind power generation devices capable of controlling output power,
A transmission / reception step for receiving operation information including information on wind speed received by each wind turbine generator; and
A wind speed threshold value determining step for determining whether or not the wind speed is faster than a predetermined threshold value;
A correlation coefficient calculating step for calculating a correlation coefficient of wind speed between the wind turbine generators;
The wind speed threshold determination step determines that the wind speed is faster than the threshold, and the stop determination step of selecting a wind power generator that determines that the calculation result calculated by the correlation coefficient calculation step is higher than a predetermined value;
A wind power generation control method comprising: a stop command step for transmitting a stop command to the wind power generator selected by the stop determination step.

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