JP5501183B2 - Natural energy power plant with power storage device - Google Patents

Description

  The present invention relates to a natural energy power plant including a power storage device, and in particular, includes a natural energy power generation device such as a wind power generation device and a solar power generation device and a power storage device. A power storage device is provided in the DC part between the generator-side converter that converts AC power into DC power and the system-side converter that converts DC power into AC power of commercial frequency and supplies it to the power system. The present invention relates to a natural energy power plant that reduces output fluctuations.

  Wind power generators and solar power generators are used as means for converting renewable energy existing in nature to electric power energy. Since the energy source of a wind power generator or a solar power generator is wind energy or solar energy that varies with time, the power generated by the power generator also varies with time.

  The electric power system maintains the balance of power supply and demand by adjusting the generated power of thermal power plants, hydroelectric power plants, pumped-storage power plants, etc. according to the magnitude of power demand. For this reason, when power sources with large fluctuations, such as wind power generators and solar power generators, are connected to the power system in large quantities, there is a concern that supply / demand balance adjustment will be insufficient and frequency fluctuations will increase.

  In order to mitigate the negative effects of power fluctuations of wind power generators on the power grid, power that is output to the power grid by using the power storage device and charging / discharging the power generated by the wind power generator to charge / discharge Means such as mitigating fluctuations are necessary.

  In a wind power generator that is one of natural energy power generators, Patent Document 1 discloses a stator of a synchronous generator as one that suppresses fluctuations in output power due to fluctuations in the output of a windmill while improving the utilization rate of the windmill. A forward converter, a reverse converter connected to the forward converter and connected to the power system, and a chargeable / dischargeable secondary battery directly connected between the forward converter and the reverse converter. The converter converts the generated power at the variable frequency of the synchronous generator into DC power, converts the DC power into AC power at a fixed frequency with the reverse converter, and outputs the active power to the power system through charge / discharge control of the secondary battery. It is described to suppress fluctuations.

  Patent Document 2 describes a wind turbine power generation control method in which a storage battery provided with a charger / discharger is provided in addition to a wind turbine power generation apparatus so as to suppress output fluctuation. Patent Document 2 describes a wind power generation system in which a plurality of wind turbine power generation devices including a storage battery are connected in parallel to supply a large amount of power to an electric power system.

  In Patent Document 3, in a wind power generation system that predicts the wind condition in front of the wind power generator and suppresses or smooths the output fluctuation of the wind power generator, the generated power fluctuation of a plurality of wind power generators in the wind farm is In order to suppress this, it is described that a capacitor and a power converter that performs power input / output of the capacitor are installed, and a plurality of wind power generators and power converters are controlled based on a wind condition analysis.

JP 2003-333752 A JP 2002-27679 A Japanese Patent Application No. 2004-289896

  When charging / discharging the secondary battery, storage battery, or capacitor constituting the power storage means, loss of charge / discharge power occurs due to internal resistance or chemical reaction of the secondary battery or the like. For this reason, compared with the wind power generator which does not have an electric power storage means, electric power generation amount reduces and the utilization amount of natural energy reduces. In order to make maximum use of natural energy, it is necessary to reduce the amount of charge / discharge power charged and discharged by the power storage means.

  Further, in Patent Documents 2 and 3, as described in Patent Document 1, a secondary battery that performs charging / discharging is provided in the direct current portion of the power converter (forward converter and reverse converter) of the wind power generator itself. Unlike a battery, when charging / discharging a storage battery and a capacitor | condenser, the charger / discharger and power converter which comprise an electric power storage means with a storage battery and a capacitor | condenser generate | occur | produce a loss.

  An object of the present invention is to reduce the amount of charge and discharge of a power storage device and generate the power storage device in a natural energy power plant having a power storage device in a direct current portion of a power converter constituting a natural energy power generation device such as a wind power generation device. Another object of the present invention is to provide a renewable energy power plant that can reduce the loss caused.

  The present invention comprises a natural energy utilization power plant comprising a plurality of natural energy utilization power generation devices having a power storage device in a direct current portion of a power converter constituting a natural energy utilization power generation device such as a wind power generation device, and uses a plurality of natural energy utilization The smoothing effect of the power generator is used.

  More specifically, when a wind power generation device is used as the natural energy-use power generation device, the natural energy-use power plant (wind power plant) of the present invention is configured by a plurality of wind power generation devices and a controller. The wind power generator includes a wind turbine that rotates by wind energy, a generator that converts the rotational energy of the wind turbine into AC power, a generator-side converter that converts AC power into DC power, and AC power at commercial frequency. Wind power generation further comprising: a system-side converter that converts power into electric power and supplies it to the power system; and a power storage device that is connected to a DC unit between the generator-side converter and the system-side converter and charges and discharges DC power. This is because the detection device that detects the inflow generated power flowing into the generator-side converter from each generator and the amount of energy accumulated by each power storage device (or the accumulated energy amount). The controller has a detection device for detecting the corresponding physical quantity), and the controller determines the power command to be charged / discharged by each system-side converter from the inflow power detection value and the stored energy quantity (or the physical quantity corresponding to the stored energy quantity) or The power correction command of the system side converter is calculated and output to each system side converter, and each system side converter receives power or DC that is input / output by the system side converter according to the power command or power correction command. The voltage is controlled.

  According to the present invention, it is possible to use the smoothing effect of a plurality of natural energy utilizing power generation devices (wind power generation devices, etc.), and the charge / discharge power amount of the power storage device constituting the natural energy utilization power generation devices (wind power generation devices, etc.) Can be reduced. By reducing the charge / discharge power amount of the power storage device, loss generated by the power storage device can be reduced, and natural energy can be effectively used.

The whole block diagram of the wind power plant in the 1st Example of this invention. The block diagram of the wind power generator in 1st Example of this invention. The block diagram of the generator side converter in the 1st Example of this invention. The lineblock diagram of the system side converter in the 1st example of the present invention. The block diagram of the controller in the 1st Example of this invention. The figure which shows the structural example of the power plant output target value calculator of this invention. The figure which shows the structural example of the charging rate correction | amendment calculator of this invention. The figure which shows the structural example of the charging / discharging range calculator of this invention. The figure which shows the operation example of the wind power plant in 1st Example of this invention. The figure which shows an example of the display apparatus in 1st Example of this invention. The figure which shows the structural example of the power plant output target value calculator of this invention. The figure which shows the structural example of the controller in 1st Example of this invention. The figure which shows the structural example of the power plant output target value calculator of this invention. The whole block diagram of the wind power plant in the 2nd Example of this invention. The block diagram of the controller in the 2nd Example of this invention. The block diagram of the wind power generator in 2nd Example of this invention. The block diagram of the wind power generator in 2nd Example of this invention. The block diagram of the wind power generator in 2nd Example of this invention. The figure which showed the control method of the DC voltage in the 2nd Example of this invention. The block diagram of the wind power plant in the 3rd Example of this invention. The block diagram of the wind power generator in the 3rd Example of this invention. The block diagram of the controller in the 3rd Example of this invention. The block diagram of the solar power plant in the 4th Example of this invention. The block diagram of the solar power generation device in the 4th Example of this invention. The block diagram of the DC-DC converter in the 4th Example of this invention. The block diagram of the controller in the 4th Example of this invention. The figure which shows an example of the display apparatus in the 4th Example of this invention.

  Before specifically describing the embodiments of the present invention, the background to the present invention will be described.

  In the case of a wind power plant configured by connecting a plurality of wind power generators having a power storage device, the wind energy received by each wind power generator is not uniform in time due to the topography of the point where the wind power generator is installed. For this reason, the generated power output from each wind power generator differs in time, and the total generated power may be smoothed as a whole of the plurality of wind power generators. By utilizing the smoothing effect of the plurality of wind turbine generators, it is possible to reduce the charge / discharge power amount of the storage battery. However, as described in Patent Document 1, in a wind power plant having a power storage device in a DC portion of a power converter that constitutes a wind power generator, only output fluctuation in a single wind power generator is considered, It has not been studied to use a smoothing effect by connecting a plurality of power generators. In Patent Documents 2 and 3, it is described that a plurality of wind power generators are connected. However, unlike Patent Document 1, a power storage device is not provided in the DC portion of the power converter of the wind power generator. However, a mechanism that actively uses the smoothing effect of a plurality of wind turbine generators has not been studied. The present inventors effectively use the smoothing effect by connecting a plurality of wind power generators while maintaining the advantages of a wind power plant having a power storage device in the direct current portion of the power converter constituting the wind power generator. The system has been studied and the present invention has been achieved.

  Embodiments of the present invention will be described below with reference to the drawings.

  A first embodiment of the present invention will be described with reference to FIGS. In the present embodiment, the present invention is applied to a wind power plant using a wind power generator as a natural energy-utilizing power generator.

  FIG. 1 is a diagram showing an overall configuration of a wind power plant according to a first embodiment of the present invention. The wind power plant of the present invention is mainly composed of a plurality of wind power generators 1-1, 1-2,..., 1-n (n is the number of wind power generators), a controller 4, and a display device 5. . The wind turbine generators 1-1, 1-2,..., 1-n and the controller 4 are connected to each other by wired or wireless means capable of transmitting information. Command can be transmitted. As specific information transmission means, LAN communication using an optical fiber or 4-20 mA communication using an electric line can be used in the case of a wired means, and wireless LAN communication or the like can be used in the case of a wireless means. The wind power plant of the present invention is connected to the power system 3 and transmits its total output power to the power system. The wind power plant includes a power detector 2 that detects the total output power Psys of the wind power plant at a connection point with the power system 3, and has means for transmitting the detected total output power value to the controller 4. Below, the element which comprises a wind power plant is demonstrated in detail.

  FIG. 2 is a diagram illustrating the wind power generator 1-1 according to the present invention. The wind power plant of the present invention includes a plurality of wind power generators 1-1, 1-2,..., 1-n, all of which have the same configuration as that of the wind power generator 1-1. The wind turbine generator 1-1 receives wind by the blade 1-1-1, and converts the energy of the wind into the rotational energy of the rotating body including the blade 1-1-1. The rotational energy is transmitted to the generator 1-1-3 by the speed increaser 1-1-2. The generator 1-1-3 plays a role of converting rotational energy into alternating electrical energy. As the generator 1-1-3, a permanent magnet generator, a DC excitation type synchronous generator, an induction generator, or the like can be used. The energy generated by the generator 1-1-3 is supplied to the generator-side converter 1-1-7, the system-side converter 1-1-8, and the grid-connected transformer 1-1-15 that are power converters. The power is transmitted to the power system 3 via the power system 3. The generator side converter 1-1-7 has a role of converting the AC power generated by the generator 1-1-3 into DC power, and the system side converter 1-1-8 converts the DC power into the power system. It has the role of converting to AC power that matches the frequency. A DC capacitor 1-1-9 is provided between the generator-side converter 1-1-7 and the system-side converter 1-1-8, and plays a role of relaxing fluctuations in the DC voltage of the DC unit.

  The wind power generators 1-1, 1-2,..., 1-n of the present invention are connected to a DC voltage portion connecting the generator side converter 1-1-7 and the system side converter 1-1-8. And a secondary battery 1-1-10 as a power storage device. The secondary battery 1-1-10 realizes a necessary DC voltage or stored energy by connecting the unit cells of the secondary battery in series, in parallel, or a combination thereof. Examples of the battery constituting the secondary battery include a lead storage battery, a lithium ion battery, a sodium sulfur battery, a nickel metal hydride battery, and a lithium ion capacitor, and any secondary battery can be used. The effect is realizable.

  The wind power generator 1-1 of the present invention has a controller called a windmill controller 1-1c, and controls the operation of the wind power generator 1-1. The windmill controller 1-1c is configured by a microcomputer or a CPU. The windmill controller 1-1c calculates the active power command of the generator side converter 1-1-7 from the wind speed information measured by the anemometer 1-1-4. The active power command is adjusted so that the rotational speed of the blade 1-1-1 of the wind turbine generator 1-1 is the rotational speed at which the wind energy is received most efficiently. At the same time, from the three-phase AC generator terminal voltage detected by the voltage detector 1-1-5 and the three-phase AC generator output current detected by the current detector 1-1-6, an active / reactive power calculator. In 1-1c-2, the active / reactive power output by the generator 1-1-3 is calculated. The windmill controller 1-1c is based on the calculated active power command and the detected active / reactive power command, and includes a power controller 1-1c-5, a current controller 1-1c-4, a pulse width modulation pulse generator (PWM1- 1c-3) is used to calculate the gate pulse signal of the generator-side converter 1-1-7. The detailed calculation method of the active power command and the gate pulse signal is described in detail in Japanese Patent Application Laid-Open No. 2003-120504, and the detailed description thereof is omitted here. In the present embodiment, the power control method has been described as the operation of the generator-side converter 1-1-7. However, the generator-side converter 1-1-7 uses other conventional techniques such as torque control. Even if it operates, the effect of the present invention can be realized. Furthermore, the wind turbine generator 1-1 of the present invention transmits the detected active power value (inflow power detection value PW1) to the controller 4.

  The DC voltage and input / output current of the secondary battery 1-1-10 connected to the DC section of the wind turbine generator 1-1 are measured by the voltage detector 1-1-12 and the current detector 1-1-11, respectively. . The wind turbine controller 1-1c calculates the SOC (charge rate) of the secondary battery 1-1-10 in the SOC calculator 1-1C-6 based on the detected DC voltage and DC current. The calculated SOC is transmitted to the controller 4 of the power plant. Note that the value to be calculated may be a value representing the amount of energy accumulated in the secondary battery. For this reason, the effect of the present invention can be exhibited even if the DC voltage of the secondary battery 1-1-10, the internal resistance value of the secondary battery 1-1-10, or the like is used instead of the SOC.

  The windmill controller 1-1C also has a role of controlling the amount of power output from the system side converter 1-1-8. Specifically, the output voltage and output current of the system side converter 1-1-8 are detected by the voltage detector 1-1-14 and the current detector 1-1-13, respectively. Based on the detected voltage value and current value, the active / reactive power calculator 1-1c-10 calculates the active power / reactive power output from the system side converter 1-1-8. In this embodiment, the system side converter power command value PGT1 to be output by the system side converter 1-1-8 is transmitted from the controller 4. The wind turbine controller 1-1 C has a power controller 1-1 C-9, a current controller 1-1 C-8, and a pulse width modulation pulse generator (PWM 1-1 c-7) so as to follow the received active power command value. And control the system side converter 1-1-8.

  An example of the generator side converter 1-1-7 will be described in detail with reference to FIG. One of the generator side converters 1-1-7 is connected to the generator 1-1-3 through an electric circuit called a filter. For example, the filter includes a capacitor 1-1-7-1 and a reactor 1-1-7-2 as shown in FIG. One of the filters is connected to an IGBT 1-1-7-3 which is a semiconductor element. The IGBT 1-1-7-3 is either in a normal conduction state or a non-conduction state according to a gate pulse signal transmitted from the wind turbine controller 1-1C. In this way, the generator-side converter 1-1-7 controls the power by operating the IGBT 1-1-7-3 in accordance with the gate pulse signal of the wind turbine controller 1-1C. Generator side converter 1-1-7 connects the other output terminal to the direct-current part of wind power generator 1-1. In this embodiment, the generator-side converter 1-1-7 is connected to the secondary battery 1-1-9.

  Next, a detailed configuration of the system side converter 1-1-8 will be described with reference to FIG. One output terminal of the system side converter 1-1-8 is connected to a DC capacitor 1-1-9 in the DC section of the wind turbine generator 1-1. The DC capacitor is connected to an electric circuit composed of IGBT 1-1-8-2 which is a semiconductor element. In accordance with the gate pulse signal, the IGBT 1-1-8-2 itself enters a normal state or a non-conductive state. The other side of the system side converter 1-1-8 is connected to the interconnection transformer 1-1-15 via an electric circuit called a filter. For example, the filter includes a reactor 1-1-8-2, a capacitor 1-1-8-3, and a reactor 1-1-8-4. Thus, the system side converter 1-1-8 controls the electric power by operating the IGBT 1-1-8-1 according to the gate pulse signal of the wind turbine controller 1-1C.

  Next, operation | movement of the controller 4 which comprises the wind power plant of a present Example is demonstrated using FIG. In FIG. 5 and subsequent figures, description will be made assuming that the number of wind turbine generators constituting the present invention is three (n = 3). However, the effect of the present invention is not limited to three wind power generators, and the effect of the present invention can be obtained if the number of wind power generators is two or more. In order to obtain the total generated power generated by the plurality of wind turbine generators 1-1, 1-2, 1-3, the controller 4 adds the detected inflow power detection values PW1, PW2,..., PWn to the adder 4-1. Is added to calculate the total generated power PW of the wind power plant. In the power plant output target value calculator 4-2, the controller 4 calculates the target value PSysT of the power output from the power plant. The power plant output target value PSysT is a value obtained by relaxing fluctuations in the total generated power PW. As a specific operation example of the power plant output target value calculator 4-2, a value obtained by performing a first-order lag calculation on the total generated power PW as shown in FIG. 6 is set as a power plant output target value PSysT. In FIG. 6, the first-order lag time constant is represented by Tm.

  The controller 4 calculates a charge / discharge power command PBT1 necessary for fluctuation mitigation by subtracting the total generated power PW from the calculated power plant output target value PSysT using the subtractor 4-4. The charge / discharge power command PBT1 is charged / discharged by the direct current section of each of the wind turbine generators 1-1, 1-2,. Specifically, the divider 4-5, which is a distributor, divides PBT1 by the number of operating wind turbine generators (n = 3) and distributes it evenly.

  The secondary batteries 1-1-10, 1-2-10, 1-3-10 constituting the wind power generators 1-1, 1-2,..., 1-n are charged power in a state where the SOC is high. In contrast, when the SOC is low, the discharge power tends to be limited. In order to prevent such a bias in SOC, the SOC correction power calculator 4-3 constituting the controller 4 corrects the charge / discharge power command of each wind turbine generator.

  A specific operation of the SOC correction power calculator 4-3 will be described with reference to FIG. The SOC correction power calculator 4-3 subtracts the detected SOC1, SOC2, SOC3 and SOC target value of each power storage device by the subtractor 4-3-1, and multiplies the result of the subtraction by the gain Kp, thereby obtaining the SOC. The corrected power command is calculated. The SOC target value is a fixed value. When a lead storage battery is used as the secondary battery 1-1-10, 1-2-10, 1-3-10, about 70%, when lithium ions are used. Is a fixed value of about 50%. The controller 4 adds the SOC correction power commands PBH1, PBH2, and PBH3 calculated as shown in FIG. 5 to the charge / discharge power commands PBTa1, PBTa2, and PBTa3 in the adder 4-7, respectively. Intermediate values PBTb1, PBTb2, and PBTb3 are calculated.

  Secondary batteries generally have a range of charge / discharge power that can be operated, and excessive charge power and excessive discharge power exceeding this range may accelerate the deterioration of the secondary battery. For this reason, the wind power plant of the present invention uses the charge / discharge power of the secondary batteries 1-1-10, 1-2-10, 1-3-10 as the secondary batteries 1-1-10, 1-2-10, 1-3-10 is limited to an operable range. Specifically, in the chargeable / dischargeable range calculator 4-6 shown in FIG. 5, the secondary batteries 1-1-10, 1-2 constituting the wind power generators 1-1, 1-2, 1-3. The range in which −10, 1-3-10 can be operated is calculated. As shown in FIG. 8, the SOC detection values SOC1, SOC2, SOC3 of the secondary batteries 1-1-10, 1-2-10, 1-3-10, and the secondary batteries 1-1-10, 1-2. From the temperature detection values BTe1, BTe2 and BTe3 of 10, 1-3-10, the maximum charge power values PBCM1, which can be operated by the respective secondary batteries 1-1-10, 1-2-10 and 1-3-10. PBCM2, PBCM3 and maximum discharge power values PBDM1, PBDM2, PBDM3 that can be operated are calculated. For example, as shown in FIG. 8, the calculation stores map data 4-6-1-1 indicating the SOC dependency of the charge / discharge operation range for each predetermined temperature section, and the detected temperature detection values BTe1, BTe2 are stored. , BTe3 and the SOC detection values SOC1, SOC2, and SOC3, respectively, corresponding operation ranges are obtained. As shown in FIG. 5, the controller 4 uses the calculated maximum charging power values PBCM1, PBCM2, PBCM3 and the maximum discharging power values PBDM1, PBDM2, PBDM3, and the limiter 4-8 uses the intermediate value PBTb1, PBTb2 and PBTb3 are limited, and new charge / discharge power command intermediate values PBTc1, PBTc2, and PBTc3 are calculated. The operation of limiting the charge / discharge power command to such an operation charge / discharge range enables the long-life operation of the secondary batteries 1-1-10, 1-2-10, 1-3-10.

  The controller 4 adds the detected inflow power detected values PW1, PW2, and PW3 to the charge / discharge power command intermediate values PBTc1, PBTc2, and PBTc3 calculated as shown in FIG. 1-1, 1-2, 1-3 The system side converter power command PGT1, PGT2, which the system side converter 1-1-8, 1-2-8, 1-3-8 should charge / discharge. PGT3 is calculated.

  Next, the effect of the present invention will be described with reference to FIG. FIG. 9 is an example showing the operation of the wind power plant of the present invention. FIG. 9A shows the inflow power detection value PW1 of the generator-side converters 1-1-7, 1-2-7, 1-3-7 of the wind power generators 1-1, 1-2, 1-3. , PW2 and PW3. In the example of FIG. 9, before time 2 (hour), PW1 and PW2 change in opposite phases, and PW3 is constant in time. However, as shown in FIG. 9B, the total generated power PW of the entire power plant is constant over time, and the secondary batteries 1-1-10, 1-2-10, 1 for reducing fluctuations. -3-10 charge / discharge is not necessary. As shown in FIG. 9C, the intermediate value of the charge / discharge power is 0 (MW) before time 2 (hour), and there is no need for charge / discharge, and each secondary battery 1- 1 shown in FIG. The charge / discharge power commands PBTc1, PBTC2, and PBTc3 of 1-10, 1-2-10, and 1-3-10 are also 0 (MW). Note that the SOC of each of the secondary batteries 1-1-10, 1-2-10, and 1-3-10 is assumed to be consistent with the SOC target value of 70%, so that the SOC is corrected. The SOC correction power commands PBH1, PBH2, and PBH3 are 0 (MW). Prior to time 2 (hour), as shown in FIG. 9E, PGT1, PGT2, and PGT3 coincide with the inflow power detection values PW1, PW2, and PW3, respectively. This means that in each wind power generator 1-1, 1-2, 1-3, the power flowing from the generator-side converter matches the power flowing out from the system-side converter, and each secondary battery 1- There is no power input / output to 1-10, 1-2-10, 1-3-10. In this way, the wind power plant of the present invention utilizes the smoothing effect of the plurality of wind power generators, and the secondary batteries 1-1-10, 1-2-10, The amount of charge and discharge of 1-3-10 is reduced, and as a result, the loss generated in each secondary battery 1-1-10, 1-2-10, 1-3-10 is reduced. Since time 2 (hour) in FIG. 9 and thereafter, the total generated power PW fluctuates with time as shown in FIG. 9B for the entire power plant, charging / discharging power is required to mitigate fluctuations. As shown in (d), power input / output occurs in each of the storage batteries 1-1-10, 1-2-10, and 1-3-10.

  In the wind power plant of the present invention, it is necessary to monitor the flow of power passing through each component and the state quantity of each secondary battery 1-1-10, 1-2-10, 1-3-10. . This is to confirm whether the operation of the power plant is normal, and by confirming whether the operation of each secondary battery 1-1-10, 1-2-10, 1-3-10 is normal, This is for early detection of failures of the devices constituting the power plant and for preventing accidents. Monitoring the power plant visually makes it easier to detect abnormalities in the power plant more reliably. For this purpose, the wind power plant according to the invention has a display device 5 for visually displaying the power plant. A specific example of the display device 5 is shown in FIG. The display device 5 shown in FIG. 10 displays on a liquid crystal monitor or the like installed inside the building in the wind power plant. The display device 5 illustrates the wind power generators 1-1, 1-2, and 1-3 that constitute the wind power plant, and displays the electric power that flows through each component. It is preferable that the power display be visually easy to understand. In the display device 5 shown in FIG. 10, the flow of power is shown in the form of an arrow. For example, an arrow 5-1 in the display device 5 indicates the magnitude and direction of power flowing into the system-side converter of the wind power generator 1-1, and the length of each arrow indicates the magnitude of power. The direction indicates the direction in which power flows. In the arrow 5-3 representing the charge / discharge power of the secondary battery 1-1-10 and the arrow 5-4 representing the power output from the system side converter 1-1-8, the lengths of the arrows are large. The point that the direction of the arrow indicates the direction in which the power flows is the same. Reference numeral 5-2 schematically representing the secondary battery represents the SOC (or accumulated energy amount) of the secondary battery 1-1-10 as an area of the filled portion. By providing the display device 5 shown in FIG. 10, even when an extremely large amount of electric power is generated, it can be relatively easily detected visually, and the failure of the equipment constituting the wind power plant is early. Can lead to discovery. Further, when a malfunction occurs in the control due to a failure of the controller 4, a situation occurs in which the SOC values of the secondary batteries 1-1-10, 1-2-10, and 1-3-10 vary greatly. When the situation where each SOC value greatly varies occurs, it is possible to easily find the variation in the SOC of each of the secondary batteries 1-1-10, 1-2-10, and 1-3-10 from the display device 5. This leads to early detection of failures. Note that the symbol representing the flow of power does not necessarily need to be an arrow, and a similar effect can be obtained if the symbol visually represents the magnitude and direction of power flow, such as a symbol schematically representing an analog meter. . The method of expressing the SOC of the secondary battery is not necessarily expressed by the area of filling, and the effect of the present invention can be realized even if it is expressed by a symbol that schematically represents an analog meter, color shading, or the like. Further, the display device shown in FIG. 10 is not necessarily installed in or near the power plant, and the display device shown in FIG. 10 is displayed on the display device installed at a remote place by wireless or wired signal transmission means. Even if the contents are displayed, the same effect can be obtained.

  In the present embodiment, as a method for calculating the power plant output target value PSysT, the method using the first-order lag as shown in FIG. 6 has been described. However, the effect of the present invention can also be realized by using another calculator that reduces fluctuations in the total generated power PW of the power plant when calculating the power plant output target value PSysT. For example, even when the power plant output target value calculator 4-2a shown in FIG. 11 is used as the power plant output target value calculator, the effect of the present invention can be obtained. The power plant output target value calculator 4-2a shown in FIG. 11 provides an upper limit value and a lower limit value that can be output with respect to the wind turbine generator generated power PW, and sets the value limited by the upper and lower limits to the power plant output target value PSysT. Calculate as The upper limit value and the lower limit value are calculated from the combined power PSys measured in the past. The output range of PSys (upper limit and lower limit) in the next control period (for example, 1 minute) from the output fluctuation range of the output power PSys of the wind turbine generator from a predetermined period (for example, 19 minutes) to the current time. Value). For example, a value obtained by adding 10% to the minimum value of PSys in the past in a predetermined period is set as the upper limit value, and a value obtained by subtracting 10% from the maximum value of PSys in the past in the predetermined period is set as the lower limit value. The calculation method of the upper limit value and the lower limit value in the power plant output target value calculator 4-2a is described in more detail in Japanese Patent Laid-Open No. 2009-079559 previously proposed by the present inventors.

  Another calculation method for calculating the power plant output target value PSysT will be described with reference to FIGS. FIG. 12 is a diagram showing a configuration of the controller 4b of the wind power plant for the purpose of mitigating fluctuations different from those in FIGS. 12 that have the same numbers as those in FIG. 5 represent the same components as those shown in FIG. The difference between the controller 4b of FIG. 12 and FIG. 5 is that the power plant output target value calculator 4-2b uses the power generation predicted value PPrd of the wind power plant. Although not shown in the figure, the generated power predicted value PPrd is data received from a generated power prediction company or the like, and is a predicted value of the output power PSys of the power plant in the future up to several hours ahead. The power generation prediction business operator predicts power generation PPrd in the future from past weather data, terrain data, the current operation status of the wind power plant, and past operation data of the wind power plant.

  A specific operation of the power plant output target value calculator 4-2b will be described with reference to FIG. The purpose of the wind power plant shown in FIGS. 12 and 13 is to reduce fluctuations in the generated power by keeping the output power PSys constant for a predetermined period. In the examples of FIGS. 12 and 13, conditions for keeping the generated power output for 30 minutes constant are described. As shown in FIG. 13, the power plant output target value calculator 4-2b calculates an average value of generated power for 30 minutes in the future from the predicted value PPrd of generated power. The power plant output target value calculator 4-2b sets the predicted value PPrd of the generated power as the power plant output target value PSysT of the power plant output power PSys. The method of operating the wind power plant so that the generated power PSys follows the power plant output target value PSysT is the same as the method described with reference to FIGS. As shown in FIGS. 12 and 13, the effect of the present invention can be realized even with an operation method in which the output power PSys of the power plant is constant for a predetermined period. Further, when calculating the power plant output target value PSysT, the effect of the present invention can be realized by calculating the power plant output target value PSysT after the fluctuation relaxation using another calculator.

  A second embodiment of the present invention will be described with reference to FIGS. In the present embodiment, the present invention is applied to a wind power plant using a wind power generator as a natural energy utilizing power generator.

  Of the components of the wind power plant shown in FIGS. 14 to 19, the components having the same numbers as those of the first embodiment represent the same components, and thus the description thereof is omitted. The difference of the present embodiment from the first embodiment is that the controller 4d transmits system side converter power correction commands PGHT1, PGHT2, and PGHT3, which are correction amounts of charge / discharge power to be performed by the system side converter. is there.

  The configuration and operation of the controller 4d of this embodiment will be described with reference to FIG. The controller 4d detects the inflow power detection values PW1, PW2, PW3 of the generator-side converter, the output power detection value PSys of the power plant, the SOC detection values SOC1, SOC2, SOC3 of the secondary battery 1-1-10, the secondary battery 1 The process until the charge / discharge power command intermediate values PBTb1, PBTb2, and PBTb3 are calculated from the temperature detection values BTe1, BTe2, and BTe3 of -1-10 is the same as that of the first embodiment. The controller 4d of the present embodiment uses the values obtained by limiting the charge / discharge power command intermediate values PBTb1, PBTb2, and PBTb3 by the limiter 4-8 as the system-side converter power correction commands PGHT1, PGHT2, and PGHT3. 1d, 1-2d,..., 1-nd. The system-side converter power correction commands PGHT1, PGHT2, and PGHT3 are used for the secondary batteries 1-1-10, 1-2-10, 1-2-10, which constitute the wind power generators 1-1d, 1-2d,. ·, 1-n-10 is a value representing charge / discharge power to be charged / discharged.

  Next, the configuration and operation of each wind turbine generator 1-1d, 1-2d,..., 1-nd will be described with reference to FIG. FIG. 16 is a diagram showing the configuration of the wind turbine generator 1-1d, but the configurations of the other wind turbine generators 1-2d,..., 1-nd are also the same. The generator 1-1-3 so that the generator-side converter 1-1-7 of the wind turbine generator 1-1d receives the wind energy most efficiently when the blade 1-1-1 is rotated. Since the control configuration and operation for adjusting the output power of the second embodiment are the same as those in the first embodiment, description thereof is omitted. The wind power generator 1-1d of the present embodiment is different from the first embodiment in the method of calculating the active power command of the system side converter 1-1-8. The wind turbine generator 1-1d adds a value obtained by adding the system-side converter power correction command PGHT1 received from the controller 4d and the active power command of the generator-side converter 1-1-7 by the adder 1-1cd-11. The system side converter active power command is used, and the system side converter 1-1-8 is operated so as to follow the system side converter active power command.

  The operation of the wind power plant of the present embodiment is the same as that of the wind power plant shown in the first embodiment. In other words, the wind power plant uses the smoothing effect of the plurality of wind power generators to recharge each of the secondary batteries 1-1-10, 1-2-10, 1-3-10 connected to the DC section of the wind power generator. The amount of charge / discharge can be reduced, and as a result, the loss generated in each of the secondary batteries 1-1-10, 1-2-10, 1-3-10 can be reduced.

  Also, the effect of the present invention can be obtained by using the wind power generator 1-1e shown in FIG. 17 instead of the wind power generator 1-1d shown in FIG. When the wind turbine generator 1-1e of FIG. 17 calculates the grid-side converter active power command, it flows into the generator-side converter 1-1-7 in the grid-side converter power correction command PGHT1 received from the controller 4d. An inflow power detection value that is power is added. Even with the configuration of the wind turbine generator 1-1e shown in FIG. 17, the effect of the wind power plant of the present embodiment can be realized.

  Also, the effect of the present invention can be obtained by using the wind power generator 1-1f shown in FIG. 18 instead of the wind power generator 1-1d shown in FIG. The difference between the wind power generator 1-1f shown in FIG. 18 and FIG. 16 is that the system side converter 1-1-8 is connected to the DC voltage according to the system side converter power correction command PGHT1 received by the wind power generator 1-1f. It is a point to control. The wind turbine generator 1-1f calculates a charge / discharge power value flowing into or out of the secondary battery 1-1-10 according to the charge / discharge power calculator 1-1cf-9. The wind power generator 1-1f calculates a DC voltage command by the power controller 1-1cf-10 according to the calculated charge / discharge power value and the system-side converter power correction command PGHT1. The power controller 1-1cf-10 and the DC voltage controller 1-cf-11 will be described in detail with reference to FIG. The wind turbine generator 1-1f includes a DC voltage value of the secondary battery 1-1-10 detected by the voltage detector 1-1-12 and an input / output current value of the secondary battery detected by the current detector 1-1-11. From IB, the charge / discharge electric power value which the secondary battery is charging / discharging in the charge / discharge electric power calculator 1-1cf-9 is calculated. The wind power generator 1-1f obtains the difference between the received grid-side converter power correction command PGHT1 and the charge / discharge power calculated by the subtractor 1-1f-10-1 constituting the power controller 1-1cf-10, The difference value is subjected to a proportional calculation and an integral calculation in the proportional calculator 1-1cf-10-2 and the integral calculator 1-1cf-10-3, respectively, and further added by the adder 1-1cf-10-4. To calculate the DC voltage command. When the charge / discharge power is on the discharge side from the received system-side converter power correction command PGHT1, the power controller 1-1cf-10 calculates to increase the DC voltage command. Further, when the charge / discharge power is on the charging side from the system side converter power correction command PGHT1, the power controller 1-1cf-10 performs a calculation so as to decrease the DC voltage command. When the secondary battery 1-1-10 increases the DC voltage, the charge / discharge power increases in the charging direction. Conversely, when the DC voltage decreases, the charge / discharge power increases in the discharging direction. Is used. The wind power generator 1-1f calculates the difference between the calculated DC voltage command and the measured value of the DC voltage in the DC voltage controller 1-1cf-11 by the subtractor 1-1cf-11-1. Further, the differential value is proportionally calculated and integrated by the proportional calculator 1-1cf-11-2 and the integrator 1-1cf-11-3, respectively, and further added by the adder 1-1cf-11-4. The effective current command of the converter 1-1-8 is calculated. As described above, even if the system side converter 1-1-8 controls the DC voltage, the effect of the present invention can be realized.

  A third embodiment of the present invention will be described with reference to FIGS. In the present embodiment, the present invention is applied to a wind power plant using a wind power generator as a natural energy utilizing power generator.

  Of the components of the wind power plant shown in FIGS. 20 to 22, the components having the same numbers as those of the first embodiment represent the same components, and thus the description thereof is omitted. The difference of the present embodiment from the first embodiment is that a secondary excitation generator is used as the generator 1-1-3g constituting the wind power generators 1-1g, 1-2g,. It is. Since the wind turbine generator using the secondary excitation generator has a different device configuration from the wind turbine generator using the permanent magnet generator or the induction generator shown in the first embodiment, the wind turbine generator to which the present invention is applied The configuration and operation method are different from the first and second embodiments.

  FIG. 20 is a diagram showing the entire wind power plant according to the third embodiment. Since the wind power plant of the present embodiment uses secondary excitation generators 1-1-3g, 1-2-3g,..., 1-n-3g, secondary excitation generators 1-1-3g, 1- The generator side converters 1-1-7g, 1-2-7g,..., 1-n-7g are electrically connected to the rotors 2-3g,. The system side converters 1-1-3g, 1-2-3g,..., 1-n-3g are connected to the power system 3 by transformers 1-1-15, 1-2-15,. Are connected to the stators of the secondary excitation generators 1-1-3g, 1-2-3g,..., 1-n-3g, respectively. The generator side converters 1-1-7g, 1-2-7g,..., 1-n-7g and the system side converters 1-1-3g, 1-2-3g,. The point that the secondary battery 1-1-10 is connected to the DC part that connects -3g is the same as the wind turbine generator described in the first and second embodiments.

  The configuration and operation of the wind turbine generator 1-1g will be described in detail with reference to FIG. The configuration and operation of other wind power generators 1-2g,..., 1-ng not shown in FIG. The secondary excitation generator 1-1-3g can supply active power / reactive power from both the rotor and the stator. For this reason, the secondary excitation generator 1-1-3g needs to measure the electric power output from each of the rotor and the stator. On the rotor side, the active / reactive power calculator 1-1c-2 uses the three-phase AC power and DC current detected by the voltage detector 1-1-6 and the current detector 1-1-5. Calculates active / reactive power. Note that the rotor-side active power obtained as a result of the calculation is described as PR1 in FIG. 21 for explanation. Similarly, on the stator side, the three-phase AC power and DC current detected by the voltage detector 1-1-17 and the current detector 1-1-18 are detected, and the active / reactive power calculator 1-1c. The active / reactive power is calculated at -11. In FIG. 21, the stator side arithmetic unit is described as PS1 for explanation. The generator active power output PW1, which is the total effective power output from the secondary excitation generator 1-1-3g, is obtained by adding the rotor-side active power PR1 and the stator-side active power PS1 with the adder 1-1c-12. Calculate by adding. The generator-side converter 1-1-3g controls the output power from the secondary excitation generator 1-1-3g based on the calculated generator active power output PW1 and the active power command calculator 1-1c-1. To do. The active power command calculated by the active power command calculator 1-1c-1 is adjusted so that the rotational speed of the blade 1-1-1 of the wind turbine generator 1-1 is the rotational speed at which the wind energy is received most efficiently. To do. The method for controlling the generator-side converter 1-1-7g is the same as that of the prior art, and a detailed description thereof will be omitted. Moreover, even if the control method of the generator side converter 1-1-7g is the torque control which is a prior art, the effect of this invention is realizable. The wind turbine generator 1-1g transmits the rotor side active power PR1 and the generator active power output PW1 to the controller 4g to the controller 4g. Since the control method and operation of the system side converter 1-1-8g constituting the wind power generator 1-1g are the same as those in the first embodiment, the description thereof is omitted.

  Next, the configuration and operation of the controller 4g constituting the wind power plant of the present invention will be described with reference to FIG. The configuration and operation of the controller 4g are the same as those of the controller 4 shown in FIG. 5 of the first embodiment, but the rotor side active powers PR1, PR2,. Different from 1. In the adder 4-9g, the controller 4g adds the rotor side active powers PR1, PR2, and PR3 to the new charge / discharge power command intermediate values PBTc1, PBTc2, and PBTc3, respectively, so that the system side converter power command values PGT1, PGT2 , PGT3 is calculated. This is because, unlike the first embodiment, the power flowing into the DC part of the wind power generators 1-1g,..., 1-ng is the rotor-side active power PR1, PR2, PR3.

  By performing the configuration and operation shown in FIGS. 20 to 22, the present invention can be used even when the secondary excitation generators 1-1-3g, 1-2-3g,..., 1-n-3g are used. The effect of can be realized. Although not shown in the drawing, as described in the second embodiment, the system side converter power correction commands PGHT1, PGHT2, and PGHT3 are used instead of using the system side converter power command values PGT1, PGT2, and PGT3. However, the effect of the present invention can be realized. Moreover, even if the system side converters 1-1-3g, 1-2-3g,..., 1-n-3g control the voltage as described in the second embodiment, the effect of the present invention can be realized.

  A fourth embodiment of the present invention will be described with reference to FIGS.

  The fourth embodiment is an example in which the present invention is applied to a solar power plant using a solar power generator as a natural energy power generator. Of the components of the wind power plant shown in FIG. 23 to FIG. 26, the components having the same numbers as those in the first, second, and third embodiments represent the same components, and thus the description thereof is omitted. To do. FIG. 23 is a diagram showing the overall configuration of the photovoltaic power plant of this example. The solar power plant according to this embodiment includes a plurality of solar power generation devices 6-1, 6-2, 6 -n, a controller 7, a display device 8, and a power detector 2. The solar power generation devices 6-1, 6-2,..., 6-n (n is the number of solar power generation devices) are solar panels 6-1-1, 6-1-2,. 1 to convert solar light energy into electrical energy. The electrical energy is DC / DC converters 6-1-7, 6-2-7,..., 6-n-7, system side converters 6-1-8, 6-2-8,. 8. Generated power is transmitted to the power system 3 through the interconnection transformers 6-1-15, 6-2-15,..., 6-n-15. Between the DC / DC converters 6-1-7, 6-2-7,..., 6-n-7 and the system side converters 6-1-8, 6-2-8,. Each part has a part for transmitting electric power by direct current, and secondary batteries 6-1-10, 6-2-10,..., 6-n-10 are connected to the direct current part.

  The configuration and operation of the solar power generation device 6-1 will be described in detail with reference to FIG. In addition, the structure and operation | movement of the other solar power generation device 6-2, ..., 6-n which are not illustrated are the same as the solar power generation device 6-1. The solar power generation device 6-1 is a PV controller 6-1c and controls the power generation device. The solar power generation device 6-1 measures the voltage and current of the solar panel with a voltage detector 6-1-5 and a current detector 6-1-6, respectively. The maximum power follow-up calculator 6-1c-5 of the PV controller 6-1c calculates a DC voltage command so that the power conversion efficiency of the solar panel is maximized. The DC / DC converter 6-1-7 passes through the voltage controller 6-1c-4 and the pulse width modulation pulse generator 6-1c-3, and the DC voltage of the solar panel 6-1-1 is converted into a DC voltage command. The voltage is controlled to match. The solar power generation device 6-1 of the present embodiment operates so that the power conversion efficiency of the solar panel 6-1-1 is maximized by the control of the DC / DC converter 6-1-7. Note that there are several conventionally known techniques for the maximum power tracking (MPPT) control method, but the effect of the present invention can be realized by applying any method. In addition, although the DC / DC converter 6-1-7 has described the method of performing the maximum power tracking control, the DC / DC converter 6-1-7 performs another control method such as DC voltage constant control. However, the effect of the present invention can be realized. The photovoltaic power generation apparatus 6-1 of the present invention uses the measured values of the voltage and current detected by the voltage detector 6-1-5 and the current detector 6-1-6 to calculate the effective power of the PV controller 6-1c. The generated power PPV1 of the solar panel 6-1-1 is measured by the device 6-1c-1 and transmitted to the controller 7.

  The DC / DC converter 6-1-7 has a function of controlling the direct current voltage, current, or power of the solar panel 6-1-1. FIG. 25 shows a specific example of the DC / DC converter 6-1-7. FIG. 25 shows an example in which the DC / DC converter 6-1-7 is a step-up chopper. The step-up chopper which is the DC / DC converter 6-1-7 shown in FIG. 25 includes DC capacitors 6-1-7-1, 6-1-7-5, a reactor 6-1-7-2, and an IGBT 6-1. It is possible to control the DC voltage of the solar panel 6-1-1. As the DC / DC converter 6-1-7, in addition to the step-up chopper shown in FIG. 25, a conventionally known step-down chopper, high-frequency link DC / DC converter, etc., solar panel 6-1-1. If the converter has a function capable of controlling the direct current voltage, current, or power, the effect of the present invention can be realized.

  The solar power plant of the present invention has a secondary battery 6-1-11 in the direct current section as shown in FIG. The current flowing into the secondary battery 6-1-11 is measured by the current detector 6-1-11, and the DC voltage of the secondary battery 6-1-11 is measured by 6-1-12. Based on the measured voltage and current, the SOC calculator 6-1c-6 measures the charging rate of the secondary battery 6-1-11. Further, the temperature of the secondary battery 6-1-1 is measured using a temperature detector 6-1-16. The detected charging rate and temperature are transmitted to the controller 7. The detection method of the state of the secondary battery 6-1-11 and the configuration for transmission to the controller 7 are the same as those of the secondary battery connected to the DC unit of the wind turbine generator shown in the first, second, and third embodiments. It is.

  The operation of the system side converter 6-1-8 will be described with reference to FIG. The system side converter 6-1-8 performs power control according to the gate pulse signal from the PV controller 6-1c. Specifically, the system side converter 6-1-8 controls the power so as to follow the system side converter power command PGT1 received from the controller 7. About the operation | movement method of a system side converter, it is the same as the operation | movement of the system side converter of the wind power generator shown in Example 1, Example 2, Example 3. FIG.

  The structure and operation | movement of the controller 7 which comprise the solar power plant of this invention are demonstrated using FIG. The configuration and operation of the controller 7 are as follows. The generated power PW1, PW2, PW3 of each wind power generator in the controller 4 of the wind power plant described in FIG. Other operations and configurations are the same only by replacing the solar panel output powers PPV1, PPV2, and PPV3 with n.

  As described above, the solar power plant of the present invention includes a generator as a solar panel and a generator-side converter as DC / DC in the wind power plants described in the first, second, and third embodiments. Other configurations and operations are the same only by replacing with a DC converter. By taking the configuration described above, the solar power plant of the present invention can use the smoothing effect of the plurality of solar power generation devices 6-2,. The amount of charge / discharge power of the secondary battery 6-1-11 is reduced, and as a result, the loss generated in the secondary battery 6-1-11 can be reduced.

  The wind power generator of the present invention preferably has a display device 8 as shown in FIG. The display device 8 has a function illustrated so that the flow of power in the power plant can be visually determined. The details of the display device 8 are the same as those of the wind power plant display device (FIG. 10) described in the first embodiment except that the symbol of the wind power generator is replaced with the symbol of the solar panel.

1-1, 1-2,.., 1-n, 1-1d, 1-2d,..., 1-dn, 1-1f, 1-1g, 1-2g,. 1-1 Blade 1-1-2 Speed increaser 1-1-3 Generator 1-1-4 Anemometer 1-1-5, 1-1-12, 1-1-14, 1-1-17, 6-1-5 Voltage detector 1-1-6, 1-1-11, 1-1-13, 1-1-18, 6-1-6 Current detector 1-1-7 Generator side converter 1-1-7-1, 1-1-8-3, 6-1-7-1, 6-1-7-5 capacitors 1-1-7-2, 1-1-8-2, 1- 1-8-4, 6-1-7-2 Reactor 1-1-7-3, 1-1-8-1, 6-1-7-3 IGBT
1-1-8, 1-2-8, ..., 1-n-8, 1-1-8g, 1-2-8g, ..., 1-n-8g, 6-1-8, 6-2 8, .., 6-n-8 System side converter 1-1-9 DC capacitors 1-1-10, 6-1-10, 6-2-10,..., 6-n-10 Secondary battery 1- 1-15, 6-1-15, 6-2-15,..., 6-n-15 Interconnection transformer 1-1-16 Temperature detector 1-1c, 1-1cd, 1-1cf Wind turbine controller 1- 1c-1 active power command calculator 1-1c-2, 1-1c-10, 1-1c-11, 6-1c-10 active / reactive power calculator 1-1c-3, 1-1c-7, 6 -1c-3, 6-1c-7 Pulse width modulation pulse generator 1-1c-4, 1-1c-8, 6-1c-8 Current controllers 1-1c-5, 1-1c-9, 1- 1cf-10, 6-1c-9 Power controller 1-1c-6, 6-1c-6 SOC calculator 1-1cf-9 Charge / discharge power calculator 1-1cf-10-1, 1-1cf-11-1, 4-4 Subtractor 1- 1cf-10-2, 1-1cf-11-2 proportional computing unit 1-1cf-10-3, 1-1cf-11-3 integral computing unit 1-1cf-10-4, 1-1cd-11, 1- 1ce-11, 1-1cf-11-4, 1-1c-12, 4-1, 4-7, 4-9, 4-9g Adder 1-1cf-11 DC voltage controller 2 Power detector 3 Power System 4, 4g, 7 Controllers 4-2, 4-2a Power plant output target value calculation tree 4-3 SOC corrected power calculator 4-5 Divider 4-6 Charge / discharge range calculator 4-6-1, 4 -6-2, 4-6-3 Chargeable / dischargeable range map data 4-8 Limiters 5, 5g, 8 Display device 5-1, 8- Symbols 5-2 and 8-2 representing power flowing into the generator-side converter Symbols 5-3 and 8-3 representing charge rates of the secondary batteries Symbols 5-4 and 8 representing charge / discharge power of the secondary batteries -4 Symbols representing the output power of the system side converter 5-5, 8-5 Symbols 6-1, 6-2,..., 6-n representing the total output power of the power plant 6-1c PV controller 6-1c-1 Active power control 6-1c-4 Voltage controller 6-1c-5 Maximum power follow-up computing unit 6-1-1, 6-2-1, 6-n-1 Solar panel 6-1-7, 6-2-7, ..., 6-n-7 DC / DC converter 6-1-7-4 Diode

Claims (4)

A wind power plant comprising a plurality of wind power generators and a controller,
Each of the plurality of wind power generators includes a windmill that rotates by wind energy, a generator that converts the rotational energy of the windmill into AC power, a generator-side converter that converts the AC power into DC power, A system-side converter that converts the DC power into AC power having a commercial frequency and supplies the power system, and an electric storage connected between the generator-side converter and the system-side converter for charging and discharging the DC power Equipped with equipment,
The wind power plant has means for measuring a physical quantity of the plurality of generator-side converters and a physical quantity of the power storage device,
A detection device for detecting a total output power value output by the wind power plant at a point where the wind power plant is connected to a power grid, and the controller calculates a total output power target value from the detected total output power value; Means for adding the inflow power detection value that is the generated power flowing into the generator-side converter from each of the generators, calculating the total generated power value, and the calculated total output power target value A subtractor that calculates a total charge / discharge power command value by subtracting the calculated total generated power value from the charge / discharge power command that each wind power generator should charge / discharge by distributing the total charge / discharge power command value A power command calculation means for calculating the power command by adding each detected inflow power value to the charge / discharge power command of each wind power generator, and each grid-side converter Said Wind power plant, characterized in that it comprises means for controlling the power control or DC voltage so as to follow the power instruction. A wind power plant comprising a plurality of wind power generators and a controller,
Each of the plurality of wind power generators includes a windmill that rotates by wind energy, a generator that converts the rotational energy of the windmill into AC power, a generator-side converter that converts the AC power into DC power, A system-side converter that converts the DC power into AC power having a commercial frequency and supplies the power system, and an electric storage connected between the generator-side converter and the system-side converter for charging and discharging the DC power Equipped with equipment,
The wind power plant has means for measuring a physical quantity of the plurality of generator-side converters and a physical quantity of the power storage device,
A detection device for detecting a total output power value output by the wind power plant at a point where the wind power plant is connected to a power grid, and the controller calculates a total output power target value from the detected total output power value; Means for adding the inflow power detection value that is the generated power flowing into the generator-side converter from each of the generators, calculating the total generated power value, and the calculated total output power target value A subtractor that calculates a total charge / discharge power command value by subtracting the calculated total generated power value from the power, and a power correction that calculates a power correction command for each wind turbine generator by distributing the total charge / discharge power command value Having command calculation means,
Each system side converter follows an inflow power target value of each generator side converter or a value obtained by adding each power correction command to each inflow power detection value of each generator side converter. A wind power plant characterized in that the system side converter has means for controlling electric power or DC voltage. A wind power plant comprising a plurality of wind power generators and a controller,
Each of the plurality of wind power generators includes a windmill that rotates by wind energy, a generator that converts the rotational energy of the windmill into AC power, a generator-side converter that converts the AC power into DC power, A system-side converter that converts the DC power into AC power having a commercial frequency and supplies the power system, and an electric storage connected between the generator-side converter and the system-side converter for charging and discharging the DC power Equipped with equipment,
The wind power plant has means for measuring a physical quantity of the plurality of generator-side converters and a physical quantity of the power storage device,
A detection device for detecting a total output power value output by the wind power plant at a point where the wind power plant is connected to a power grid, and the controller calculates a total output power target value from the detected total output power value; Means for adding the inflow power detection value that is the generated power flowing into the generator-side converter from each of the generators, calculating the total generated power value, and the calculated total output power target value A subtractor that calculates a total charge / discharge power command value by subtracting the calculated total generated power value from the power, and a power correction that calculates a power correction command for each wind turbine generator by distributing the total charge / discharge power command value The wind power generator includes means for detecting charging / discharging power of each power storage device, and each grid-side converter is configured so that the detected charging / discharging power of each power storage device is the power Added correction command Wind power plant the mains converter to is characterized in that it comprises means for controlling the power or DC voltage. A photovoltaic power plant comprising a plurality of photovoltaic power generation devices and a controller,
Each of the plurality of photovoltaic power generation devices includes a solar panel that converts solar energy into direct current power, a DC / DC converter connected to the solar panel, and the direct current power that is AC power at a commercial frequency. A system-side converter that converts the power to the power system, and a power storage device that is connected between the DC-DC converter and the system-side converter and charges and discharges the DC power,
The solar power plant has means for measuring a physical quantity of the plurality of DC / DC converters and a physical quantity of the power storage device,
A detection device for detecting a total output power value output by the solar power plant at a point where the solar power plant is connected to a power system, and the controller is configured to determine a total output power target value from the detected total output power value; Means for calculating the total generated power value by adding the inflow power detection value that is the generated power flowing into the DC / DC converter from each of the solar panels, and the calculated total output A subtractor that calculates a total charge / discharge power command value by subtracting the calculated total generated power value from a power target value, and distributes the total charge / discharge power command value to provide a power correction command for each photovoltaic power generation device. Power correction command calculation means for calculating,
Each mains converter to follow the to a value said to adding the power correction command to the each inflow power detection value of each DC · DC converter inflow power target value or the respective DC · DC converter Further, the system-side converter has means for controlling electric power or DC voltage.

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