JP4369450B2 - Power supply system - Google Patents

Description

  The present invention relates to a power supply system, and more particularly to a power supply system between a distributed power supply connected to an independent power supply system and a load.

  Conventionally, a distributed power supply system in this type of power supply system has an automatic frequency control (hereinafter referred to as AFC) device capable of adjusting a target frequency, and self-end AFC control based on the information on the supply and demand balance of the system obtained on its own. Economical operation and supply-demand balance are adjusted by adjusting the target frequency of the device. An inverter circuit that converts DC power into AC power by switching operation is provided, and the target battery is increased or decreased by switching operation of the inverter circuit. Electric power is supplied to the system from a distributed power source combining a power source circuit for charging / discharging and a power source circuit having an AFC such as a diesel generator and a distributed power source not having an AFC such as a solar power generator. (For example, refer to Patent Document 1).

JP 2005-328622 A

  In a conventional power supply system using a distributed power source, even if the frequency is changed by a switching operation of an inverter in a distributed power source having an AFC, the power generation amount of the distributed power source that does not have an AFC such as a photovoltaic power generation facility is controlled. Therefore, when the amount of power generated by solar power generation equipment exceeds the chargeable amount of the storage battery of the distributed power source having AFC, the storage battery voltage rises due to overcharging, and as a result, the storage battery protection device There is a problem that it becomes impossible to continue automatic operation of the power supply system by operating.

  Moreover, before the storage battery is overcharged, a distributed power source consisting of power generation equipment that uses natural energy such as photovoltaic power generation equipment is temporarily detected by detecting changes in the system frequency or detecting an increase in system voltage. When the power supply system is separated and operated, power is temporarily supplied only by the discharge of the storage battery, so that the effective utilization rate of natural energy is reduced when considering the charge / discharge efficiency of the storage battery There was a problem.

  The present invention has been made to solve the above-described problems, and is provided with means for detecting fluctuations in the system frequency in the solar power generation equipment and the like, and the output of the solar power generation equipment and the like is provided by this means. An object of the present invention is to provide an electric power supply system that can effectively use natural energy by preventing overcharge of a storage battery and allowing automatic operation of the electric power supply system to be continued.

The power supply system according to the present invention is connected to the independent power supply system via a first distributed power supply connected to the independent power supply system and not having an automatic frequency control function, and a bidirectional power converter, and charges and discharges the storage battery. And a power supply system including a second distributed power supply having an automatic frequency control function, a means for setting a target frequency of the independent power supply system in the second distributed power supply, and a frequency of the independent power supply system. For controlling the frequency of the independent power source to the first distributed power source, and controlling the output of the first distributed power source based on the detected frequency. and means is provided, the second when battery charging rate in the distributed power supply is equal to or higher than the predetermined value the independent power supply system the target frequency is set to more than the rated frequency output of the first distributed power source When the charging rate of the storage battery in the second distributed power supply becomes other predetermined value or less, the target frequency of the independent power supply system is set to the rated frequency to suppress the output of the first distributed power supply. It is intended to stop .

  The power supply system according to the present invention is provided with means for detecting a system frequency in a distributed power source that does not have an AFC function, such as a solar power generation facility, and controls the output of the solar power generation facility or the like based on the detected frequency. Thus, the battery can be prevented from being overcharged, the automatic operation of the power supply system can be continued, and the natural energy can be used effectively.

Embodiment 1 FIG.
Embodiment 1 of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram illustrating a configuration of a power supply system according to the first embodiment. As shown in this figure, the photovoltaic power generation panel 1 constitutes a photovoltaic power generation facility together with the photovoltaic power conversion device 2 and is connected to an independent power system 6 as a first distributed power source.

  As is well known, the photovoltaic power generation facility does not have an AFC function. Further, the inverter equipment 4 having an AFC function by increasing / decreasing the target frequency by switching operation, and the storage battery 3 and the load 5 that can be charged / discharged by using this inverter equipment as a converter are independent as the second distributed power source. It is connected to the power supply system 6.

  The photovoltaic power conversion device 2 detects the voltage, current, and frequency of the independent power supply system 6 via the transformer 13 and the current transformer 14 inside the device, performs calculations based on the detected information, and performs its own operation. It is comprised by the control apparatus 12 which controls an output, and the power converter 11 which changes the output from the solar power generation panel 1 with the signal from the control apparatus 12. FIG. The voltage and frequency output from the power converter 11 are the same as the voltage and frequency of the independent power supply system 6.

  The inverter facility 4 is mainly configured by a control device 22 and a bidirectional power converter 21 that changes the charge / discharge power of the storage battery 3 and the frequency and voltage of the independent power supply system 6 by a signal from the control device 22. . The control device 22 detects the voltage, current and frequency of the independent power supply system 6 and the voltage and charging current of the storage battery 3 by the transformer 23 and the current transformer 24 inside the device, and performs calculations based on the detected information. The charge amount of the storage battery 3 is calculated, and the charge / discharge output of the storage battery 3 and the frequency and voltage of the independent power supply system 6 are controlled.

  The bidirectional power converter 21 has a function of discharging the storage battery 3 and outputting it to the independent power supply system 6 by a switching operation, and a function of charging the power from the independent power supply system 6 to the storage battery 3, and an independent power supply system. The frequency and voltage of 6 can be changed.

  The rated voltage of the power supply system in FIG. 1 is Va (for example, 380 V), and the rated frequency is Fa (for example, 50 Hz). Moreover, the maximum value of the load 5 and the maximum value of the output of the photovoltaic power generation facilities 1 and 2 shall not exceed the rated charge / discharge power of the inverter facility 4 and the storage battery 3.

  Next, the operation of the first embodiment will be described with reference to FIG. 2, FIG. 3, and FIG. FIG. 2 is a flowchart for explaining a control operation of the control device 12 in the photovoltaic power conversion device 2.

  First, in step 201, it is determined whether or not the frequency F of the independent power supply system 6 is in a range of Fc (for example, 51 Hz) ± α (for example, 0.05 Hz). If the frequency is within the range of Fc ± α, the control device 12 controls the power converter 11 in step 202 to gradually decrease the target output of the photovoltaic power conversion device 2.

  If the frequency is outside the range of Fc ± α in step 201, it is determined in step 203 whether the frequency F is higher than Fb (for example, 50.5 Hz) −β (for example, 0.05 Hz). If the frequency F is higher than Fb-β, the previous target output is maintained in step 204 and the next cycle is started. If the frequency F is equal to or lower than Fb-β, the photovoltaic power conversion apparatus is also used in step 204. The target output is gradually increased so that the output of 2 becomes the maximum output.

  Since the amount of power generated by the photovoltaic power generation panel 1 varies depending on the illumination state of the solar power, the photovoltaic power conversion device 2 has the current photovoltaic power generation when the target output exceeds the amount of power generated by the current photovoltaic power generation panel 1. A planned output operation is performed using the power generation amount of panel 1 as an output.

  FIG. 3 is a flowchart for explaining the control operation of the control device 22 in the inverter equipment 4. First, in step 301, it is determined how much the charge amount of the storage battery 3 integrated in the control device 22 is currently 100% as a full charge.

  If the amount of charge is greater than Ca% (for example, 90%), the remaining charge capacity is small, and therefore, in step 302, a mode for suppressing the output of the photovoltaic power generation facility is entered, and the output suppression flag is turned on. Next, in step 304, it is determined whether or not the charge amount is smaller than Cb% (for example, 85%). This is because once the output suppression flag is turned ON, the ON state is continued unless the charge amount is Cb% or less, and it is turned OFF when it is Cb% or less. If the charge amount is larger than Cb% in step 304, the output suppression flag of the photovoltaic power generation facility is turned OFF in step 308.

  If the output suppression flag is turned ON in step 302 and the charge amount is Cb% or more in step 304, it is determined in step 305 whether the current output of the inverter equipment 4 is positive. When the output is zero or more, that is, when the storage battery 3 is in a discharged state, the target frequency is set to Fb in step 307, and when the output is negative, that is, the storage battery 3 is in a charged state, the target frequency is set to Fc.

  On the other hand, if the charge amount is smaller than Ca% in step 301, it is checked in step 303 whether the output suppression flag is ON. If the output suppression flag is not ON, that is, is OFF, or if the output suppression flag is OFF in step 308, the target frequency is set to Fa (rated frequency) in step 309.

  When the target frequency is set, next, in step 310, the system voltage is determined. If the system voltage is smaller than the rated voltage Va, the system voltage is kept at Va by increasing the target output of the inverter equipment 4 in step 311. If the system voltage is not smaller than the rated voltage Va in step 310, step 312 is performed. Judge whether it is greater than the rated voltage Va. If the voltage is larger than the rated voltage, the system voltage is kept at Va by reducing the target output in step 313.

  Next, the control operation performed according to the flowcharts of FIGS. 2 and 3 will be described with reference to FIG. When the target frequency is set in steps 306, 307, and 309, the power conversion device 21 of the inverter facility 4 performs a switching operation so that the system frequency becomes the target frequency.

  Since the load 5 is smaller than the rated charge / discharge power of the inverter facility 4, the target frequency and the system frequency match. That is, the frequency of the independent power supply system matches one of the frequencies Fa, Fb, and Fc in FIG.

  When the system frequency F is the rated frequency Fa, the system frequency is equal to or lower than Fb−β, and therefore enters the region 401 in FIG. 4. In this case, since the control device 12 in the photovoltaic power conversion device 2 gradually increases the target output in step 204 and is set to the maximum output at the end, the photovoltaic power conversion device 2 performs the expected output operation. Will be performed.

  When the system frequency F is Fb, the system frequency F is higher than Fb−β and out of the range of Fc−α <F <Fc + α, and therefore enters the region 402 in FIG. 4. In this case, in step 203, the target output of the control device 12 in the photovoltaic power conversion device 2 remains unchanged from the previous target output.

  When the system frequency is Fc, since it falls within the range of Fc−α <F <Fc + α, it enters the region 403 in FIG. In this case, in step 202, the target output of the control device 12 in the photovoltaic power conversion device 2 is gradually decreased, and the output of the photovoltaic power conversion device 2 is also gradually decreased.

  When the output of the photovoltaic power conversion device 2 is smaller than the load 5, the system voltage is lowered. Therefore, the output of the inverter facility 4 is increased by Step 310 and Step 311, and the system voltage is kept constant at Va. Further, when the output of the photovoltaic power conversion device 2 is larger than the load 5, the system voltage rises. Therefore, the output of the inverter equipment 4 is decreased by steps 312 and 313, and the system voltage is kept constant at Va. .

  An example of the control cycle will be described. It is assumed that the photovoltaic power conversion device 2 outputs at its rated power (for example, 60 kW), and the system load 5 is equal to or lower than the output of the photovoltaic power conversion device 2 (for example, 40 kW). In this case, the output of the inverter facility 4 is −20 kW, and the storage battery is charged with 20 kW of power.

  If the charge amount is greater than Ca% in this state, step 301 is YES, and in step 302, the output suppression flag of the photovoltaic power conversion device 2 is turned ON. Since the amount of charge is greater than Ca%, it is naturally Cb% or more, and step 304 is NO. If the charge amount is greater than Ca%, that is, since the storage battery 3 is in a charged state, the output of the inverter equipment 4 is less than zero, so step 305 is NO and the target frequency is determined in step 306. Set to Fc, the output frequency of the inverter equipment 4 is Fc, and the system frequency is also Fc.

  When the system frequency becomes Fc, step 201 becomes YES, and in step 202, the target output of the photovoltaic power converter 2 is gradually reduced, and the actual output of the photovoltaic power converter 2 is also gradually reduced.

  When the actual output of the photovoltaic power conversion device 2 is 40 kW, the load 5 is also 40 kW. Therefore, the output of the inverter equipment 4 becomes zero, and the target frequency is changed from Fc when step 305 becomes YES. By changing to Fb, the output frequency of the inverter equipment 4 is Fb, and the system frequency is also Fb.

  When the system frequency becomes Fb, step 201 is NO and step 203 is YES, so the decrease in the target output of the photovoltaic power conversion device 2 is stopped, and the actual output of the photovoltaic power conversion device 2 remains 40 kW. It becomes.

  Here, for example, it is assumed that the load 5 is increased from 40 kW to 65 kW. Since the output of the photovoltaic power conversion device 2 is 40 kW, a power shortage of 25 kW occurs in the independent power supply system 6, the system voltage decreases, and step 310 becomes YES. Thereby, the output of the inverter equipment 4 increases until it becomes 25 kW.

  When the output of the inverter facility 4 becomes 25 kW, the charging rate of the storage battery 3 gradually decreases and becomes Cb% or less at the end. When the charging rate is equal to or lower than Cb%, step 304 is YES, and the output suppression flag of the photovoltaic power conversion device 2 is turned OFF at step 308. Accordingly, in step 309, the target frequency is changed from Fb to Fa, the output frequency of the inverter equipment 4 becomes Fa, and the system frequency becomes Fa.

  When the system frequency becomes Fa, step 201 becomes NO, and step 203 also becomes NO. The target output and the actual output of the photovoltaic power converter 2 increase, and at the end, the rated operation (60 kW) is performed. Become. Since the current output of the inverter equipment 4 is 25 kW and the system load 5 is 65 kW, the inverter equipment 4 generates 20 kW of surplus power and the system voltage rises. Accordingly, step 312 is YES, and in step 313, the output of the inverter facility 4 decreases until it reaches 5 kW. Thereafter, if the system load 5 becomes 50 kW, the state returns to the initial state of the control cycle.

  Since Embodiment 1 is configured as described above, by varying the output frequency of the inverter facility 4, the output of the photovoltaic power conversion device 2 is optimally increased or decreased, and the storage battery 3 is not overcharged. Thus, it becomes possible to continue automatic control.

  Further, when the charge amount becomes Ca% or more, the charging is stopped by the inverter facility 4 and the photovoltaic power conversion device 2 detects the overvoltage of the independent power system or the frequency is varied by the inverter facility 4. By detecting the variation of the lever, the load from the photovoltaic power conversion device 2 is effectively loaded as compared with the case where the conventional photovoltaic power conversion device 2 is temporarily disconnected from the independent power system and operated. Therefore, the amount of power supplied from the storage battery 3 is reduced, and the utilization efficiency of natural energy can be increased when the charge / discharge efficiency of the storage battery 3 is taken into consideration.

Embodiment 2. FIG.
Next, a second embodiment of the present invention will be described with reference to the drawings. The configuration of the power supply system is the same as that of the first embodiment shown in FIG. FIG. 5 is a control flowchart of the control device 22 in the inverter equipment 4 for explaining the operation of the second embodiment.

  In the first embodiment, the maximum value of the load and the maximum value of the output of the solar power generation facility are set so as not to exceed the rated charge / discharge power of the inverter facility 4 and the storage battery 3. The output of the photovoltaic power generation facility can be applied even when the maximum value (for example, 80 kW) of the solar power generation facility exceeds the rated charge / discharge power (for example, 60 kW) of the inverter facility 4 and the storage battery 3. .

  In FIG. 5, first, in step 314, it is determined whether or not the current output of the inverter equipment 4 is larger than a rated output value Pa (for example, 60 kW). If it is greater than Pa, in step 322, the output suppression flag of the photovoltaic power generation facility is turned OFF. If it is Pa or less, it is determined in step 315 whether or not the output is smaller than a rated charge value Pb (for example, −60 kW).

  If it is smaller than Pb, it is determined that the battery is in an overcharge state. In step 316, the output suppression flag of the photovoltaic power generation facility is turned ON, and in step 317, the target frequency is set to Fc. If the output is greater than or equal to Pb, it is determined in step 318 whether or not the output is within a range greater than or equal to Pb + α (eg, 10 kW) and less than or equal to Pa−α. If the output is in the range of Pb + α or more and Pa−α or less, the output suppression flag is turned OFF in step 322.

If the output is not within the range of Pb + α and Pa−α in step 318, it is checked in step 319 whether the output suppression flag is ON. If the output suppression flag is not ON in step 319, that is, if it is OFF, or if the output suppression flag is OFF in step 322, the target frequency is set to Fa (rated frequency) in step 321.
If the output suppression flag is ON in step 319, the target frequency is set to Fb in step 320.

  In the first embodiment, the maximum value of the output of the photovoltaic power generation facility has to be prevented from exceeding the rated charge / discharge power of the inverter facility 4 and the storage battery 3, but by performing the control as described above, There is no need to consider output limits.

Embodiment 3 FIG.
Next, a third embodiment of the present invention will be described with reference to the drawings. The configuration of the power supply system is the same as that of the first embodiment shown in FIG. FIG. 6 is a control flowchart of the control device 22 in the inverter equipment 4 for explaining the operation of the third embodiment.

In the third embodiment, by combining the control systems of the first embodiment and the second embodiment, the maximum load value and the maximum output power of the photovoltaic power generation facility are the rated charge / discharge of the inverter facility 4 and the storage battery 3. It can be applied even when the power is exceeded.
In addition, the code | symbol of the step in FIG. 6 attaches | subjects the same code | symbol as the corresponding step of FIG.3 and FIG.5.

  In FIG. 6, first, in step 314, it is determined whether or not the current output of the inverter equipment 4 is greater than the rated output value Pa. If it is greater than Pa, in step 308, the output suppression flag of the photovoltaic power generation facility is turned OFF. If it is Pa or less, it is determined in step 315 whether the output is smaller than the rated charge value Pb. If it is smaller than Pb, it is determined that the battery is in an overcharged state. In step 316, the output suppression flag of the photovoltaic power generation facility is turned ON, and in step 306, the target frequency is set to Fc.

  If the output is greater than or equal to Pb in step 315, it is determined in step 301 what percentage the charge amount accumulated inside the control device 22 is currently 100%. If the amount of charge is greater than Ca%, the output suppression flag is turned on in step 302, and in step 304, it is determined whether the amount of charge is smaller than Cb%. If the charge amount is smaller than Ca% in step 301, it is determined in step 318 whether the output is in the range of Pb + α or more and Pa−α or less. If the output is in the range of Pb + α or more and Pa−α or less, the output suppression flag is turned OFF in Step 308.

  If the output is not in the range of not less than Pb + α and not more than Pa−α in step 318, it is checked in step 303 whether the output suppression flag is ON. If the output suppression flag is ON, it is determined in step 304 whether the charge amount is Cb% or less. If the amount of charge is equal to or greater than Cb%, it is determined in step 305 whether the current output of the inverter equipment 4 is positive.

If the output is greater than or equal to zero, that is, in the discharging state, the target frequency is set to Fb in step 307, and if the output is negative, that is, in the charging state, the target frequency is set to Fc in step 306.
If the output suppression flag is not ON in step 303, that is, if it is OFF, or if the output suppression flag is OFF in step 308, the target frequency is set to Fa (rated frequency) in step 309.

Embodiment 4 FIG.
Next, a fourth embodiment of the present invention will be described with reference to the drawings. FIG. 7 is a block diagram illustrating a configuration of a power supply system according to the fourth embodiment. In this embodiment, the first distributed power supply in the third embodiment is configured by the photovoltaic power conversion device 2 and the diesel power generation facility 7. The diesel power generation facility 7 includes a diesel generator 30 and a control device 31.

  Since the control system of the diesel power generation facility 7 is described in detail in Patent Document 1, description thereof is omitted. In the fourth embodiment, as shown in FIG. 8, the minimum starting frequency Fd (for example, 50.25 Hz) of the diesel generator shown in Patent Document 1 is added to the control frequency range so that the diesel generator can be used efficiently. Control is performed.

  According to the fourth embodiment, countermeasures against overcharging / discharging the storage battery and high-efficiency use of solar power generation, which have not been taken into consideration in Patent Document 1, are possible.

Embodiment 5 FIG.
Next, a fifth embodiment of the present invention will be described with reference to the drawings. FIG. 9 is a block diagram illustrating a configuration of a power supply system according to the fifth embodiment. In this embodiment, wind power generation facilities 9 and 2 are used instead of the solar power generation facilities 1 and 2 in FIG. Since the control of the outputs of the wind power generation facilities 9 and 2 is the same as that of the solar power generation facility, description thereof is omitted.
This embodiment has a feature that even if it is difficult to install the photovoltaic power generation facility, it can be carried out if it is easy to use wind power.

Embodiment 6 FIG.
Next, a sixth embodiment of the present invention will be described. Since the configuration of the power supply system is the same as that of the fifth embodiment shown in FIG. 9, illustration and description thereof are omitted. In the power supply system of the fifth embodiment, this embodiment can be applied even when the maximum value of the output of the wind power generation facilities 9 and 2 exceeds the rated charge / discharge power of the inverter facility 4 and the storage battery 3. The control is performed in the same manner as in the third embodiment. This eliminates the need to consider the output limits of wind power facilities.

Embodiment 7 FIG.
Next, a seventh embodiment of the present invention will be described with reference to the drawings. In this embodiment, as shown in FIG. 10, instead of the photovoltaic power generation facilities 1 and 2 of the fourth embodiment shown in FIG. 7 in which a load 5 exceeding the rated charge / discharge power of the inverter equipment 4 and the storage battery 3 is connected, the inverter Wind power generation facilities 9 and 2 that exceed the rated charge / discharge power of the facility 4 and the storage battery 3 are provided. Thereby, it is applicable also when the maximum value of a load and the maximum value of the output of a wind power generation facility exceed the rated charge / discharge power of the inverter facility 4 and the storage battery 3.

Embodiment 8 FIG.
Next, an eighth embodiment of the present invention will be described with reference to the drawings. This embodiment incorporates an inverter that converts various natural energy other than sunlight and wind power into electric power as shown in FIG. 11 instead of the photovoltaic power generation facilities 1 and 2 of the fourth embodiment shown in FIG. A natural energy module 10 that is a power generation facility is provided. Thereby, it is possible to add various natural energy modules as necessary without adding control lines and considering the rated charge / discharge power of the inverter equipment 4 and the storage battery 3.

It is a block diagram which shows the structure of the electric power supply system by Embodiment 1 of this invention. 3 is a flowchart for illustrating a control operation of a control device in the photovoltaic power conversion device according to Embodiment 1. 3 is a flowchart for illustrating a control operation of a control device for inverter equipment in the first embodiment. FIG. 6 is an explanatory diagram showing the frequency control operation in the first embodiment. It is a flowchart for demonstrating control operation of the control apparatus in the inverter installation of the electric power supply system by Embodiment 2 of this invention. It is a flowchart for demonstrating control operation of the control apparatus in the inverter installation of the electric power supply system by Embodiment 3 of this invention. It is a block diagram which shows the structure of the electric power supply system by Embodiment 4 of this invention. It is explanatory drawing which shows the frequency control operation | movement in Embodiment 4 on a figure. It is a block diagram which shows the structure of the electric power supply system by Embodiment 5 of this invention. It is a block diagram which shows the structure of the electric power supply system by Embodiment 7 of this invention. It is a block diagram which shows the structure of the electric power supply system by Embodiment 8 of this invention.

Explanation of symbols

1 photovoltaic panel, 2 photovoltaic power converter, 3 storage battery,
4 Inverter equipment, 5 Load, 6 Independent power supply system, 7 Diesel power generation equipment, 9 Wind power generation equipment, 10 Natural energy module, 11 Power converter,
12 control device, 13, 23 transformer, 14, 24 current transformer,
21 bidirectional power converter, 22 control device, 30 diesel generator,
31 Control device.

Claims (8)

A first distributed power source that does not have an automatic frequency control function connected to the independent power supply system, and is connected to the independent power supply system via a bidirectional power converter to charge and discharge the storage battery and to have an automatic frequency control function In a power supply system comprising a second distributed power supply,
The second distributed power supply is provided with means for setting the target frequency of the independent power supply system, and means for controlling the frequency of the independent power supply system to the target frequency,
The first distributed power supply is provided with means for detecting the frequency of the independent power supply system, and means for controlling the output of the first distributed power supply based on the detected frequency ,
When the charging rate of the storage battery in the second distributed power source is equal to or higher than a predetermined value, the target frequency of the independent power source system is set to a rated frequency or higher to suppress the output of the first distributed power source,
When the charging rate of the storage battery in the second distributed power supply becomes other predetermined value or less, the target frequency of the independent power supply system is set to the rated frequency to stop the suppression of the output of the first distributed power supply. power supply system, characterized in that the. A first distributed power source that does not have an automatic frequency control function connected to the independent power supply system, and is connected to the independent power supply system via a bidirectional power converter to charge and discharge the storage battery and to have an automatic frequency control function In a power supply system comprising a second distributed power supply,
The second distributed power supply is provided with means for setting the target frequency of the independent power supply system, and means for controlling the frequency of the independent power supply system to the target frequency,
The first distributed power supply is provided with means for detecting the frequency of the independent power supply system, and means for controlling the output of the first distributed power supply based on the detected frequency,
When the output of the second distributed power supply is below a predetermined value, the target frequency of the independent power supply system is set to a rated frequency or higher to suppress the output of the first distributed power supply,
When the output of the second distributed power source is equal to or higher than another predetermined value, the target frequency of the independent power source system is set to a rated frequency to stop the suppression of the output of the first distributed power source. And power supply system. A first distributed power source that does not have an automatic frequency control function connected to the independent power supply system, and is connected to the independent power supply system via a bidirectional power converter to charge and discharge the storage battery and to have an automatic frequency control function In a power supply system comprising a second distributed power supply,
The second distributed power supply is provided with means for setting the target frequency of the independent power supply system, and means for controlling the frequency of the independent power supply system to the target frequency,
The first distributed power supply is provided with means for detecting the frequency of the independent power supply system, and means for controlling the output of the first distributed power supply based on the detected frequency,
When the output of the second distributed power source is not more than a predetermined value and the charging rate of the storage battery in the second distributed power source is not less than the predetermined value and the output of the first distributed power source is suppressed, the independent power system The power supply system is characterized in that the target frequency of the independent power supply system is set to the rated frequency when the target frequency of the independent power supply system is set to a rated frequency or higher and the output of the first distributed power supply is not suppressed. . The power supply system according to any one of claims 1 to 3 , wherein the first distributed power supply is a photovoltaic power generation. The power supply system according to any one of claims 1 to 3 , wherein the first distributed power source includes solar power generation and diesel power generation. The power supply system according to any one of claims 1 to 3 , wherein the first distributed power source is wind power generation. The power supply system according to any one of claims 1 to 3 , wherein the first distributed power source includes wind power generation and diesel power generation. The power supply system according to any one of claims 1 to 3 , wherein the first distributed power source includes a natural energy module including an inverter that converts natural energy into electric power and diesel power generation.

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