JP2023128326A - Distributed power supply system - Google Patents

Abstract

To suppress output of a power conditioner from becoming excessive.SOLUTION: A distributed power supply system includes a plurality of power conditioners that converts inputted DC power into AC power and supply it to loads, wherein at least one of the plurality of power conditioners is inputted with the DC power from a solar cell. Upper limits of output command values are determined respectively so that a sum of the upper limit values of the output command values of the plurality of power conditioners is equal to or less than a predetermined limit value during stand-alone operation, and the AC power is supplied to the loads so that output values of the plurality of power conditioners become equal to or less than the upper limits of the output command values respectively during stand-alone operation.SELECTED DRAWING: Figure 1

Description

The present invention relates to a distributed power supply system including a plurality of inverters.

There is a distributed power supply system that includes an electricity storage power conditioner that operates a storage battery unit in connection with the power grid, and a PV power conditioner that operates a PV (solar power generation) unit in connection with the power grid (for example, , see Patent Document 1).

JP 2021-145538 Publication

When the amount of power generated by the solar cells increases due to an increase in the amount of sunlight, the output of the PV power conditioner may become excessive. When the output of a PV power conditioner becomes excessive, the current flowing through components such as terminal blocks and relays exceeds the withstand capacity of the components, which may cause damage to the components.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a technique that can suppress the output of a power conditioner from becoming excessive.

The present invention for solving the above problems includes a plurality of power conditioners that convert input DC power into AC power and supply it to a load, and at least one of the plurality of power conditioners The distributed power supply system receives DC power from solar cells, and the output command is set such that the sum of the upper limit values of the output command values of the plurality of power conditioners becomes equal to or less than a predetermined limit value during self-sustaining operation. An upper limit value is determined, and AC power is supplied to the load so that the output value of the plurality of power conditioners becomes equal to or less than the upper limit value of the output command value during the self-sustaining operation. It is a distributed power system.

In the present invention, AC power is supplied to the load so that the output values of the plurality of power conditioners are equal to or less than the upper limit of the output command value. Since the output of the plurality of power conditioners is limited, even if the amount of power generated by the solar cells becomes excessive, the total output of the plurality of power conditioners is prevented from becoming excessive. This prevents the current flowing through components such as terminal blocks and relays from exceeding the withstand capacity of the components, thereby preventing damage to the components.

Further, in the present invention, the upper limit value of the output command value may be determined individually for each of the plurality of power conditioners. By individually determining the upper limit value of the output command value for each of the plurality of power conditioners, the upper limit value of the output command value of the plurality of power conditioners can be appropriately set according to the output performance of the plurality of power conditioners. I can do it.

Further, in the present invention, each of the upper limit values of the output command values of the plurality of power conditioners is determined based on a ratio to the predetermined limit value set for the plurality of power conditioners. Good too. By determining each upper limit value of the output command value of multiple power conditioners based on the ratio to a predetermined limit value set for multiple power conditioners, it is possible to appropriately supply power to the load with efficiency. It is possible to prevent the total output of the plurality of power conditioners from becoming excessive while maintaining the power conditioner.

Further, in the present invention, each of the plurality of power conditioners may have a single-phase inverter, and single-phase voltages of different phases of the single-phase inverters of each of the plurality of power conditioners are combined. In this way, AC power based on three-phase voltage may be supplied to a three-phase load. Thereby, a three-phase voltage can be generated by combining the single-phase voltages of different phases of the single-phase inverters of each of the plurality of power conditioners, and it is possible to supply AC power using the three-phase voltage to a three-phase load.

Further, in the present invention, the output command value may be an apparent current command value, and the output value may be an apparent current value. In the present invention, AC power is supplied to the load in such a way that the apparent current values of multiple power conditioners are below the upper limit of the apparent current command value, so even if the power generation amount of the solar cells becomes excessive, multiple This prevents the total output of the power conditioners from becoming excessive.

Further, in the present invention, the apparent current command value may include an active current command value and a reactive current command value, and the active current command value is based on the upper limit value of the apparent current command value and the reactive current command value. An upper limit value may be determined. In the present invention, the upper limit value of the active current command value can be determined based on the upper limit value of the apparent current command value and the reactive current command value.

Further, in the present invention, the apparent current command value may include an active current command value and a reactive current command value, and the reactive current command is based on the upper limit value of the apparent current command value and the active current command value. An upper limit value may be determined. In the present invention, the upper limit value of the reactive current command value can be determined based on the upper limit value of the apparent current command value and the active current command value.

Further, in the present invention, the output command value may be an apparent power command value, and the output value may be an apparent power value. In the present invention, AC power is supplied to the load in such a way that the apparent power values of the plurality of power conditioners are below the upper limit of the apparent power command value, so even if the power generation amount of the solar cells becomes excessive, the This prevents the total output of the power conditioners from becoming excessive.

Further, in the present invention, the apparent power command value may include an active power command value and a reactive power command value, and the active power command value is based on the upper limit value of the apparent power command value and the reactive power command value. An upper limit value may be determined. In the present invention, the upper limit value of the active power command value can be determined based on the upper limit value of the apparent power command value and the reactive power command value.

Further, in the present invention, the apparent power command value may include an active power command value and a reactive power command value, and the reactive power command value is based on the upper limit value of the apparent power command value and the active power command value. An upper limit value may be determined. In the present invention, the upper limit value of the reactive power command value can be determined based on the upper limit value of the apparent power command value and the active power command value.

According to the present invention, it is possible to suppress the output of the power conditioner from becoming excessive.

FIG. 1 is a diagram showing a schematic configuration of a distributed power supply system. FIG. 2 is a diagram showing the configuration of a distributed power supply system including a controller. FIGS. 3(1) to 3(3) are diagrams showing examples of changes in the output value of the power conditioner. FIGS. 4(1) to 4(3) are diagrams showing examples of changes in the output value of the power conditioner. FIG. 5 is a diagram showing functional blocks related to processing for generating an apparent current command value (instantaneous value) for the power conditioner.

[Application example]
Application examples of the present invention will be described below with reference to the drawings. As shown in FIG. 1, a distributed power supply system 1 according to this application example includes four single-phase power conditioners 20A, 20B, 20C, and 20D. The power conditioners 20A and 20B are power conditioners for storage batteries, and the power conditioner 20A has a single-phase inverter 10A, and the power conditioner 20B has a single-phase inverter 10B. DC power from storage batteries 7A and 7B is input to single-phase inverters 10A and 10B. The power conditioners 20C and 20D are power conditioners for solar cells, and the power conditioner 20C has a single-phase inverter 10C, and the power conditioner 20D has a single-phase inverter 10D. DC power generated by solar cells 7C and 7D is input to single-phase inverters 10C and 10D. The power conditioners 20A to 20D convert input DC power into AC power and supply it to a load.

The outputs of the single-phase inverters 10A to 10D are connected to a single-phase system 1A and single-phase consumer loads 2 and 3. The single-phase system 1A is, for example, a single-phase commercial power system. Further, the outputs of the single-phase inverters 10A to 10D are connected to a three-phase self-sustaining load 8. The three-phase self-sustaining load 8 is an example of a three-phase load. During grid-connected operation, the single-phase inverters 10A to 10D are connected in parallel, and AC power from the single-phase output voltage of the single-phase inverters 10A to 10D is supplied to the single-phase consumer loads 2 and 3. Ru. Furthermore, during interconnected operation with the grid, the three-phase self-sustaining load 8 is supplied with AC power using three-phase voltage from the three-phase grid 1B. The three-phase system 1B is, for example, a three-phase commercial power system. On the other hand, during self-sustaining operation, AC power from the output voltages of single-phase inverters 10A to 10D is supplied to self-sustaining load 8. During this self-sustaining operation, three-phase voltages are generated based on the output voltages of single-phase inverters 10A to 10D.

The upper limit value of the output command value of the power conditioners 20A to 20D is determined so that the total value of the upper limit value of the output command value of the power conditioners 20A to 20D is less than or equal to a predetermined limit value (threshold value). AC is supplied from the power conditioners 20A to 20D to at least one of the single-phase customer loads 2 and 3 and the self-sustaining load 8 so that the output value of the power conditioners 20A to 20D is equal to or less than the upper limit of the output command value. Power is supplied. Since the outputs of the power conditioners 20A to 20D are limited so that the sum of the upper limit values of the output command values of the power conditioners 20A to 20D is below a predetermined limit value, the outputs of the power conditioners 20C and 20D are It is possible to prevent it from becoming excessive. Thereby, it is possible to prevent the current flowing through components such as the terminal block and the relay from exceeding the withstand capacity of the components, and it is possible to prevent the components from being damaged.

In FIG. 1, the distributed power supply system 1 includes two storage battery power conditioners 20A and 20B, but the number of storage battery power conditioners can be increased or decreased. The number of storage battery power conditioners may be one, or three or more. In FIG. 1, the distributed power supply system 1 includes two solar cell power conditioners 20C and 20D, but the number of solar cell power conditioners can be increased or decreased. The number of solar cell power conditioners may be one, or three or more. Moreover, the number of power conditioners for storage batteries may be zero, and the number of power conditioners for solar cells may be two or more.

<Embodiment>
Next, embodiments of the present invention will be described in detail with reference to the drawings. The distributed power supply system 1 in the embodiment includes two single-phase power conditioners 20A and 20B connected to two storage batteries 7A and 7B, which are examples of power supply devices, respectively. The power conditioner 20A includes a single-phase inverter 10A and a control section 11A. The control unit 11A controls the entire power conditioner 20A and the single-phase inverter 10A. The control unit 11A may be configured by a computer having, for example, a processor such as a CPU, a RAM, a nonvolatile storage device (for example, a ROM, a flash memory, etc.), and the like. The output of the single-phase inverter 10A is connected to the single-phase system 1A and the single-phase consumer loads 2 and 3 at output ends 17, 18, and 19 via relays 5A and 5B. Further, the output of the single-phase inverter 10A is connected to a three-phase self-sustaining load 8 as a second load via relays 5C, 5D and relays SW6A, 6B. Power conditioner 20B includes a single-phase inverter 10B and a control section 11B. The control unit 11B controls the entire power conditioner 20B and the single-phase inverter 10B. The control unit 11B may be configured by a computer including, for example, a processor such as a CPU, a RAM, a nonvolatile storage device (for example, a ROM, a flash memory, etc.), and the like. The output of the single-phase inverter 10B is connected to the single-phase system 1A and the single-phase consumer loads 2 and 3 at output ends 17, 18, and 19 via relays 5E and 5F. Further, the output of the single-phase inverter 10B is connected to a three-phase self-sustaining load 8 via relays 5G, 5H and relays SW6B, 6C.

Then, by connecting the relays 5A, 5B and the relays 5E, 5F, power by the single-phase voltage of the single-phase inverters 10A, 10B is supplied to the single-phase consumer loads 2, 3. Furthermore, by connecting the relays SW6A, 6B, and 6C to the grid side, the output of the three-phase grid 1B is connected to the three-phase self-sustaining load 8. On the other hand, by connecting the relays SW6A, 6B, and 6C to the power conditioner side, the outputs of the single-phase inverters 10A and 10B are connected to the three-phase self-sustaining load 8.

The distributed power supply system 1 also includes two single-phase power conditioners 20C and 20D connected to two solar cells 7C and 7D, which are examples of power supply devices, respectively. The power conditioner 20C includes a single-phase inverter 10C and a control section 11C. The control unit 11C controls the entire power conditioner 20C and the single-phase inverter 10C. The control unit 11C may be configured by a computer having, for example, a processor such as a CPU, a RAM, a nonvolatile storage device (for example, a ROM, a flash memory, etc.), and the like. The output of the single-phase inverter 10C is connected to the single-phase system 1A and single-phase consumer loads 2, 3 at output ends 17, 18, 19 via relays 5I, 5J and relays SW9A, 9B, 9C. There is. Further, the output of the single-phase inverter 10C is connected to a three-phase self-sustaining load 8 via relays 5I, 5J, relays SW9A, 9C, and relays SW6A, 6C.

Power conditioner 20D includes a single-phase inverter 10D and a control section 11D. The control unit 11D controls the entire power conditioner 20D and the single-phase inverter 10D. The control unit 11D may be configured by, for example, a computer having a processor such as a CPU, a RAM, a nonvolatile storage device (for example, a ROM, a flash memory, etc.), and the like. The output of the single-phase inverter 10D is connected to the single-phase system 1A and single-phase consumer loads 2 and 3 at output ends 17, 18, and 19 via relays 5K, 5L, and relays SW9D, 9E, and 9F. There is. Moreover, the output of single-phase inverter 10D is connected to three-phase self-sustaining load 8 via relays 5K, 5L, relays SW9D, 9F, and relays SW6A, 6C. By connecting relays 5I, 5J, relays 5K, 5L, relays SW9A, 9B, 9C, and relays SW9D, 9E, 9F, single-phase inverters 10C, 10
Electric power from the single-phase voltage of D is supplied to single-phase consumer loads 2 and 3.

The case of interconnected operation with the single-phase system 1A will be explained. By connecting relays 5A, 5B and relays 5E, 5F and disconnecting relays 5C, 5D and relays 5G, 5H, the power generated by the single-phase voltage of single-phase inverters 10A, 10B is transferred to the single-phase consumer load 2. , 3. By connecting relays 5I and 5J and connecting relays SW9A, 9B, and 9C to the grid side, electric power from the single-phase voltage of single-phase inverter 10C is supplied to single-phase consumer loads 2 and 3. By connecting relays 5K and 5L and connecting relays SW9D, 9E, and 9F to the grid side, electric power from the single-phase voltage of single-phase inverter 10D is supplied to single-phase consumer loads 2 and 3. As a result, single-phase inverters 10A to 10D are connected in parallel, and power from each single-phase voltage is supplied to single-phase consumer loads 2 and 3.

Single-phase voltage power is supplied from the single-phase system 1A to the single-phase consumer loads 2 and 3. Furthermore, by connecting the relays SW6A, 6B, and 6C to the grid side, the three-phase self-sustaining load 8 is supplied with AC power (three-phase power) based on three-phase voltage from the three-phase grid 1B. In addition to directly connecting the single-phase consumer loads 2 and 3 and the three-phase self-sustaining load 8 to the single-phase inverters 10A to 10D, it is also possible to connect them via a transformer.

Let us explain about autonomous operation. Relays 5A, 5B, relays 5E, 5F are cut off, relays 5C, 5D, relays 5G, 5H, relays 5I, 5J, relays 5K, 5L are connected, and relays SW9A, 9C, relays SW9D, 9F are on the non-grid side. Connected. Relays SW9B and 9E are connected to GND. Relays SW6A, 6B, and 6C are connected to the non-grid side. Then, power conditioner 20A transmits a synchronization signal to power conditioners 20B, 20C, and 20D. The control unit 11A may send a synchronization signal to the control units 11B, 11C, and 11D. The synchronization signal is input to single-phase inverters 10B, 10C, and 10D via control units 11B, 11C, and 11D.

Single-phase inverter 10A outputs a single-phase voltage. Single-phase inverter 10B outputs a single-phase voltage that is delayed by 120 degrees with respect to the single-phase voltage output from single-phase inverter 10A. As a result, a three-phase voltage is generated by combining the single-phase voltages of single-phase inverters 10A and 10B with different phases, and the voltage of the phase to which the outputs of single-phase inverters 10C and 10D are connected is output from the single-phase inverter 10A. The single-phase voltage is delayed by 240 degrees with respect to the single-phase voltage. The single-phase inverters 10C and 10D output currents synchronized with the voltages of the connected phases, and AC power based on three-phase voltages is supplied to the three-phase self-sustaining load 8. During self-sustaining operation, AC power using three-phase voltage may be supplied to the three-phase self-sustaining load 8 . Single-phase inverter 10B may output a single-phase voltage that is delayed by 240 degrees with respect to the single-phase voltage output from single-phase inverter 10A. In addition, three-phase voltage is generated by combining the single-phase voltages output from the single-phase inverters of multiple solar battery power conditioners, and AC power is supplied by three-phase voltage to the three-phase self-sustaining load 8. You may.

During standalone operation, the connection between the single-phase grid 1A and the single-phase consumer loads 2 and 3 is cut off, and the power from the single-phase voltage of the single-phase inverters 10A to 10D is transferred to the single-phase consumer loads 2 and 3. may be supplied. At least one of the storage batteries 7A and 7B may be charged during interconnected operation with the single-phase system 1A and during self-sustaining operation. At least one of the storage batteries 7A and 7B may be charged using at least one of the DC power generated by the solar cell 7C and the DC power generated by the solar cell 7D. At least one of the storage batteries 7A and 7B may be charged using the power supplied from the single-phase system 1A.

Although FIG. 1 shows a configuration in which the power conditioner 20A transmits a synchronization signal to the power conditioners 20B, 20C, and 20D, this embodiment is not limited to the configuration shown in FIG. 1. As shown in FIG. 2, the distributed power supply system 1 may include a controller 21, and the controller 21 may transmit a synchronization signal to the power conditioners 20A to 20D. The controller 21 may be configured by a computer having, for example, a processor such as a CPU, a RAM, a nonvolatile storage device (for example, a ROM, a flash memory, etc.), and the like.

When the amount of sunlight increases and the amount of power generated by the solar cells 7C and 7D increases, the output values of the power conditioners 20C and 20D increase. The output value of the power conditioners 20C, 20D is a value of electric power or a value of current output from the power conditioners 20C, 20D. If the output values of the power conditioners 20C and 20D become excessive and the total value of the output values of the power conditioners 20C and 20D exceeds the threshold, the current flowing from the power conditioners 20C and 20D to components such as terminal blocks and relays will Exceeding the component tolerance may cause damage to the component. Additionally, while charging the storage battery 7A, if the output values of the power conditioners 20C and 20D become excessive and the total value of the output values of the power conditioners 20C and 20D exceeds the threshold, the charging current on the side of the power conditioner 20A increases. There is a possibility that the amount becomes excessive and the distributed power supply system 1 detects an abnormality and stops. If the total value of the output values of the power conditioners 20C and 20D exceeds the threshold while the storage battery 7B is being charged, the charging current on the power conditioner 20B side becomes excessive, and the distributed power supply system 1 may detect an abnormality and stop. There is sex.

In the distributed power supply system 1, the upper limit value of the output command value of the power conditioners 20C, 20D is determined so that the total value of the upper limit value of the output command value of the power conditioners 20C, 20D is equal to or less than a predetermined limit value. . The power conditioner 20C or 20D determines the total value of the upper limit values of the output command values of the power conditioners 20C and 20D, and adjusts the power conditioner based on the total value of the upper limit values of the output command values of the power conditioners 20C and 20D. The upper limit value of the output command value of the buttons 20C and 20D may be determined. Further, the controller 21 determines the total value of the upper limit values of the output command values of the power conditioners 20C and 20D, and determines the total value of the upper limit value of the output command values of the power conditioners 20C and 20D. , 20D may be determined.

In the distributed power supply system 1, AC power is supplied from the power conditioners 20C and 20D to the self-sustaining load 8 so that the output values of the power conditioners 20C and 20D are equal to or less than the upper limit of the output command value of the power conditioners 20C and 20D. is supplied. In addition, the output values of the power conditioners 20C and 20D are set to be below the upper limit of the output command value of the power conditioners 20C and 20D, and the single-phase customer loads 2 and 3 and the independent AC power may be supplied to at least one of the operating loads 8. Since the output of the power conditioners 20C and 20D is limited, even if the amount of power generated by the solar cells 7C and 7D becomes excessive, it is possible to prevent the output of the power conditioners 20C and 20D from becoming excessive. Thereby, it is possible to prevent the current flowing from the power conditioners 20C and 20D to components such as the terminal block and the relay from exceeding the withstand capacity of the components, and it is possible to prevent the components from being damaged. The predetermined limit value may be determined based on the component tolerance of the terminal block or relay, or may be determined by experiment, simulation, or the like.

Since the output of the power conditioners 20C and 20D is limited while the storage battery 7A is being charged, even if the power generation amount of the solar cells 7C and 7D becomes excessive, the charging current on the power conditioner 20A side will become excessive. is suppressed. Furthermore, since the output of the power conditioners 20C and 20D is limited while the storage battery 7B is being charged, even if the power generation amount of the solar cells 7C and 7D becomes excessive, the charging current on the power conditioner 20B side will be excessive. It is prevented from becoming. Thereby, it is possible to avoid stopping the distributed power supply system 1 due to abnormality detection.

Furthermore, during the self-sustaining operation, the output of the power conditioners 20C, 20D may be limited, and AC power may be supplied from the power conditioners 20C, 20D to the self-sustaining load 8. During self-sustaining operation, the output of the power conditioners 20C and 20D may be limited and AC power may be supplied from the power conditioners 20C and 20D to at least one of the single-phase consumer loads 2 and 3 and the self-sustaining load 8. good. For the purpose of cost reduction, the component durability of terminal blocks and relays used during standalone operation may be inferior to the component tolerance of terminal blocks and relays used during grid-connected operation. Therefore, by limiting the output of power conditioners 20C and 20D during self-sustaining operation, it is possible to prevent damage to the terminal blocks and relays used during self-sustaining operation.

FIGS. 3(1) to 3(3) are diagrams showing examples of changes in the output value of the power conditioner. The vertical axes in FIGS. 3(1) to 3(3) indicate output values, and the horizontal axes in FIGS. 3(1) to 3(3) indicate time. FIG. 3(1) shows a change in the total value of the output values of the power conditioners 20C and 20D. FIG. 3(2) shows changes in the output value of the power conditioner 20C. FIG. 3(3) shows changes in the output value of the power conditioner 20D. As the amount of sunlight increases after time t1, the output values of the power conditioners 20C and 20D increase, and the total value of the output values of the power conditioners 20C and 20D increases.

As shown in FIG. 3 (2), by setting the upper limit of the output command value of the power conditioner 20C to be less than or equal to the limit value, even when the amount of sunlight increases, the output value of the power conditioner 20C is set to the individual limit value. Exceeding is prohibited. In addition, as shown in FIG. 3 (3), by setting the upper limit of the output command value of the power conditioner 20D to be below the individual limit value, the output value of the power conditioner 20D can be maintained even when the amount of sunlight increases. Exceeding the individual limit value is suppressed. The individual limit values of the power conditioners 20C and 20D are, for example, the rated output values of the power conditioners 20C and 20D, and the output command values of the power conditioners 20C and 20D are greater than the rated output values of the power conditioners 20C and 20D. It's also small. By preventing the output values of the power conditioners 20C and 20D from exceeding the individual limit values, the total value of the output values of the power conditioners 20C and 20D reaches the predetermined limit value, as shown in FIG. It is as below. Therefore, even if the total value of the output values of the power conditioners 20C and 20D increases due to an increase in the amount of sunlight, the total value of the output values of the power conditioners 20C and 20D will not exceed the predetermined limit value. limited.

FIGS. 4(1) to 4(3) are diagrams showing examples of changes in the output value of the power conditioner. The vertical axes in FIGS. 4(1) to 4(3) indicate output values, and the horizontal axes in FIGS. 4(1) to 4(3) indicate time. FIG. 4(1) shows changes in the total value of the output values of the power conditioners 20C and 20D. FIG. 4(2) shows changes in the output value of the power conditioner 20C. FIG. 4(3) shows changes in the output value of the power conditioner 20D. As the amount of sunlight increases after time t1, the output values of the power conditioners 20C and 20D increase, and the total value of the output values of the power conditioners 20C and 20D increases.

As shown in FIGS. 4(1) to 4(3), when it is detected that the total value of the output values of the power conditioners 20C and 20D exceeds a predetermined limit value, the output of the power conditioners 20C and 20D is When setting a limit on the upper limit value of the command value, it takes time until the total value of the output values of the power conditioners 20C and 20D becomes equal to or less than the predetermined limit value. Therefore, when using the control shown in FIGS. 4(1) to 4(3), the amount by which the total value of the output values of the power conditioners 20C and 20D exceeds the predetermined limit value becomes large. In this embodiment, by using the control shown in FIGS. 3(1) to 3(3), the power condition for a predetermined limit value is better than when using the control shown in FIGS. 4(1) to 4(3). It is possible to reduce the excess amount of the total value of the output values of the sensors 20C and 20D.

The upper limit values of the output command values of the power conditioners 20C and 20D may be the same value. Further, the upper limit of the output command value of the power conditioners 20C and 20D may be determined individually for each of the power conditioners 20C and 20D. Thereby, the upper limit value of the output command value of the power conditioners 20C, 20D can be appropriately set according to the output performance of the power conditioners 20C, 20D. Therefore, it is possible to prevent the output of the power conditioners 20C and 20D from becoming excessive while appropriately maintaining the power supply efficiency to at least one of the single-phase consumer loads 2 and 3 and the self-sustaining load 8. can.

Each of the upper limit values of the output command values of the power conditioners 20C and 20D may be determined based on a ratio to a predetermined limit value set for the power conditioners 20C and 20D. A ratio to a predetermined limit value may be set for the power conditioners 20C, 20D based on the output performance of the power conditioners 20C, 20D. In addition, the ratio to a predetermined limit value is set for the power conditioners 20C and 20D based on various factors such as the usage status of the power conditioners 20C and 20D, the elapsed time from the start of use, the installation position, and the state of deterioration. You may. By determining each of the upper limit values of the output command values of the power conditioners 20C and 20D based on the ratio to the predetermined limit value set for the power conditioners 20C and 20D, the single-phase consumer load 2 , 3 and the self-sustaining load 8 can be appropriately maintained, and the output of the power conditioners 20C and 20D can be prevented from becoming excessive.

The ratio to the predetermined limit value set for the power conditioners 20C and 20D can be changed as appropriate. By changing the ratio to the predetermined limit value set for the power conditioners 20C, 20D, it becomes possible to individually change the upper limit value of the output command value of the power conditioners 20C, 20D. The ratio to the predetermined limit value set for the power conditioners 20C, 20D is determined based on various factors such as the usage status of the power conditioners 20C, 20D, the elapsed time from the start of use, the installation location, and the state of deterioration. May be changed.

The output command values of the power conditioners 20C and 20D may be the apparent current command values of the power conditioners 20C and 20D, and the output values of the power conditioners 20C and 20D are the apparent current values of the power conditioners 20C and 20D. It may be. The apparent current value of the power conditioners 20C, 20D is the value of the apparent current output from the power conditioners 20C, 20D. In the distributed power supply system 1, the apparent current values of the power conditioners 20C and 20D are set to be below the upper limit of the apparent current command value of the power conditioners 20C and 20D, and the power is transferred from the power conditioners 20C and 20D to the self-sustaining load 8. AC power is supplied. In addition, the apparent current values of the power conditioners 20C and 20D are set to be below the upper limit of the apparent current command value of the power conditioners 20C and 20D, and the power conditioners 20C and 20D are connected to the single-phase customer loads 2 and 3. AC power may be supplied to at least one of the self-sustaining load 8 and the self-sustaining load 8. Since the apparent current output from the power conditioners 20C and 20D is limited, even if the power generation amount of the solar cells 7C and 7D becomes excessive, the apparent current output from the power conditioners 20C and 20D will become excessive. This can be prevented. Thereby, it is possible to prevent the current flowing from the power conditioners 20C and 20D to the terminal blocks and relays from exceeding the withstand capacity of the components, and it is possible to prevent the components and equipment from being damaged.

The output command values of the power conditioners 20C and 20D may be the apparent power command values of the power conditioners 20C and 20D, and the output values of the power conditioners 20C and 20D are the apparent power values of the power conditioners 20C and 20D. It may be. The apparent power values of the power conditioners 20C and 20D are the values of the apparent power output from the power conditioners 20C and 20D. In the distributed power supply system 1, the power conditioner 20C,
AC power is supplied from the power conditioners 20C and 20D to the self-sustaining load 8 such that the apparent power value of the power conditioners 20D is equal to or less than the upper limit of the apparent power command value of the power conditioners 20C and 20D. The apparent power values of the power conditioners 20C and 20D are set to be below the upper limit of the apparent power command value of the power conditioners 20C and 20D, and the single-phase consumer loads 2 and 3 and the independent AC power may be supplied to at least one of the operating loads 8. Since the apparent power output from the power conditioners 20C and 20D is limited, even if the power generation amount of the solar cells 7C and 7D becomes excessive, the apparent power output from the power conditioners 20C and 20D will become excessive. This can be prevented. Thereby, it is possible to prevent the current flowing from the power conditioners 20C and 20D to the terminal blocks and relays from exceeding the withstand capacity of the components, and it is possible to prevent the components and equipment from being damaged.

FIG. 5 is a diagram showing functional blocks related to processing for generating an apparent current command value (instantaneous value) for the power conditioner 20C. The control unit 11C may execute a process of generating an apparent current command value (instantaneous value). Further, a processing unit different from the control unit 11C may execute the process of generating the apparent current command value (instantaneous value). Note that the process of generating the apparent current command value (instantaneous value) performed by the power conditioner 20C can also be applied to the process of generating the apparent current command value (instantaneous value) of the power conditioner 20D.

The generation unit 31 generates a reactive current command value (effective value) based on the active current command value (effective value) and various parameters. As the parameters, the active power values of the power conditioners 20A and 20B, the SOC (State of Charge) of the storage batteries 7A and 7B, etc. may be used. The multiplier 32 controls the power conditioners 20C and 20D based on the sum of the upper limit values of the apparent current command values of the power conditioners 20C and 20D and the ratio to a predetermined limit value set for the power conditioners 20C and 20D. The upper limit value of the apparent current command value of 20C is calculated. The determining unit 33 determines the upper limit value of the active current command value of the power conditioner 20C based on the reactive current command value (effective value) and the upper limit value of the apparent current command value of the power conditioner 20C.

The limiting unit 34 as a limiter limits the effective current command value (effective value) using the upper limit value of the effective current command value of the power conditioner 20C. That is, the limiter 34 generates an effective current command value (effective value) limited by the upper limit value of the effective current command value of the power conditioner 20C. The multiplier 35 multiplies the effective current command value (effective value) by Sinθ to generate an effective current command value (instantaneous value). The multiplier 36 multiplies the reactive current command value (effective value) by Cos θ to generate a reactive current command value (instantaneous value). The adder 37 adds the active current command value (instantaneous value) and the reactive current command value (instantaneous value), and multiplies the sum by √2 to generate an apparent current command value (instantaneous value). That is, the adder 37 generates an apparent current command value (instantaneous value) that includes an active current command value (instantaneous value) and a reactive current command value (instantaneous value). The control unit 11C may control the apparent current output from the power conditioner 20C based on the apparent current command value (instantaneous value).

Next, we will explain the process of generating the apparent current command value (instantaneous value) of the power conditioner 20C by limiting the reactive current command value (effective value) using the upper limit value of the reactive current command value of the power conditioner 20C. do. The control unit 11C may execute a process of generating an apparent current command value (instantaneous value). Further, a processing unit different from the control unit 11C may execute the process of generating the apparent current command value (instantaneous value). Note that, similarly to the above, the process of generating the apparent current command value (instantaneous value) performed by the power conditioner 20C can also be applied to the process of generating the apparent current command value (instantaneous value) of the power conditioner 20D. I can do it.

The generation unit 31 generates an active current command value (effective value) based on the reactive current command value (effective value) and various parameters. The multiplier 32 controls the power conditioners 20C and 20D based on the sum of the upper limit values of the apparent current command values of the power conditioners 20C and 20D and the ratio to a predetermined limit value set for the power conditioners 20C and 20D. The upper limit value of the apparent current command value of 20C is calculated. The determining unit 33 determines the upper limit value of the reactive current command value of the power conditioner 20C based on the active current command value (effective value) and the upper limit value of the apparent current command value of the power conditioner 20C.

The limiting unit 34 limits the reactive current command value (effective value) using the upper limit value of the reactive current command value of the power conditioner 20C. That is, the limiter 34 generates a reactive current command value (effective value) limited by the upper limit value of the reactive current command value of the power conditioner 20C. The multiplier 35 multiplies the reactive current command value (effective value) by Cos θ to generate a reactive current command value (instantaneous value). The multiplier 36 multiplies the effective current command value (effective value) by Sinθ to generate an effective current command value (instantaneous value). The adder 37 adds the active current command value (instantaneous value) and the reactive current command value (instantaneous value) to generate an apparent current command value (instantaneous value). That is, the adder 37 generates an apparent current command value (instantaneous value) that includes an active current command value (instantaneous value) and a reactive current command value (instantaneous value). The control unit 11C may control the apparent current output from the power conditioner 20C based on the apparent current command value (instantaneous value).

Next, we will explain the process of generating the apparent power command value (instantaneous value) of the power conditioner 20C by limiting the active power command value (effective value) using the upper limit value of the active power command value of the power conditioner 20C. do. The control unit 11C may execute a process of generating an apparent power command value (instantaneous value). Further, a processing unit different from the control unit 11C may execute the process of generating the apparent power command value (instantaneous value). Note that, similarly to the above, the process of generating the apparent power command value (instantaneous value) performed by the power conditioner 20C can also be applied to the process of generating the apparent power command value (instantaneous value) of the power conditioner 20D. I can do it.

The generation unit 31 generates a reactive power command value (effective value) based on the active power command value (effective value) and various parameters. The multiplier 32 controls the power conditioners based on the sum of the upper limit values of the apparent power command values of the power conditioners 20C and 20D and the ratio to a predetermined limit value set for the power conditioners 20C and 20D. The upper limit value of the apparent power command value of 20C is calculated. The determining unit 33 determines the upper limit value of the active power command value of the power conditioner 20C based on the reactive power command value (effective value) and the upper limit value of the apparent power command value of the power conditioner 20C.

The limiter 34 limits the active power command value (effective value) using the upper limit value of the active power command value of the power conditioner 20C. That is, the limiter 34 generates an active power command value (effective value) limited by the upper limit value of the active power command value of the power conditioner 20C. Multiplier 35 generates an active current command value (instantaneous value) based on the active power command value (effective value). Multiplier 36 generates a reactive power command value (instantaneous value) based on the reactive power command value (effective value). The adder 37 adds the active power command value (instantaneous value) and the reactive power command value (instantaneous value) to generate an apparent power command value (instantaneous value). That is, the adder 37 generates an apparent power command value (instantaneous value) that includes an active power command value (instantaneous value) and a reactive power command value (instantaneous value). The control unit 11C may control the apparent power output from the power conditioner 20C based on the apparent power command value (instantaneous value).

Next, we will explain the process of generating the apparent power command value (instantaneous value) of the power conditioner 20C by limiting the reactive power command value (effective value) using the upper limit value of the reactive power command value of the power conditioner 20C. do. The control unit 11C may execute a process of generating an apparent power command value (instantaneous value). Further, a processing unit different from the control unit 11C may execute the process of generating the apparent power command value (instantaneous value). Note that, similarly to the above, the process of generating the apparent power command value (instantaneous value) performed by the power conditioner 20C can also be applied to the process of generating the apparent power command value (instantaneous value) of the power conditioner 20D. I can do it.

The generation unit 31 generates an active power command value (effective value) based on the reactive power command value (effective value) and various parameters. The multiplier 32 controls the power conditioners based on the sum of the upper limit values of the apparent power command values of the power conditioners 20C and 20D and the ratio to a predetermined limit value set for the power conditioners 20C and 20D. The upper limit value of the apparent power command value of 20C is calculated. The determining unit 33 determines the upper limit value of the reactive power command value of the power conditioner 20C based on the active power command value (effective value) and the upper limit value of the apparent power command value of the power conditioner 20C.

The limiting unit 34 limits the reactive power command value (effective value) using the upper limit value of the reactive power command value of the power conditioner 20C. That is, the limiter 34 generates a reactive power command value (effective value) limited by the upper limit value of the reactive power command value of the power conditioner 20C. Multiplier 35 generates a reactive current command value (instantaneous value) based on the reactive power command value (effective value). Multiplier 36 generates an active power command value (instantaneous value) based on the active power command value (effective value). The adder 37 adds the active power command value (instantaneous value) and the reactive power command value (instantaneous value) to generate an apparent power command value (instantaneous value). That is, the adder 37 generates an apparent power command value (instantaneous value) that includes an active power command value (instantaneous value) and a reactive power command value (instantaneous value). The control unit 11C may control the apparent power output from the power conditioner 20C based on the apparent power command value (instantaneous value).

<Modified example>
A modified example will be explained. In the distributed power supply system 1, the upper limit value of the output command value of the power conditioners 20A to 20D is determined so that the total value of the upper limit value of the output command value of the power conditioners 20A to 20D is less than or equal to a predetermined limit value. Good too. One of the power conditioners 20A to 20D determines the total value of the upper limit values of the output command values of the power conditioners 20A to 20D, and determines the total value of the upper limit values of the output command values of the power conditioners 20A to 20D. Then, the upper limit value of the output command value of the power conditioners 20A to 20D may be determined. Further, the controller 21 determines the total value of the upper limit value of the output command values of the power conditioners 20A to 20D, and determines the total value of the upper limit value of the output command value of the power conditioners 20A to 20D. An upper limit value of the output command value of ~20D may be determined. Further, the process of generating the apparent current command value (instantaneous value) and the process of generating the apparent power command value (instantaneous value) shown in FIG. 5 may be applied to the power conditioners 20A and 20B.

In the distributed power supply system 1, AC power is supplied from the power conditioners 20A to 20D to the self-sustaining load 8 so that the output values of the power conditioners 20A to 20D are equal to or lower than the upper limit of the output command values of the power conditioners 20A to 20D. is supplied. The output values of the power conditioners 20A to 20D are below the upper limit of the output command values of the power conditioners 20A to 20D, and the single-phase customer loads 2 and 3 and the self-sustaining load are transmitted from the power conditioners 20A to 20D. AC power may be supplied to at least one of 8. Since the output of the power conditioners 20A to 20D is limited, even if the power generation amount of the solar cells 7C and 7D becomes excessive, it is possible to prevent the output of the power conditioners 20C and 20D from becoming excessive.

During self-sustaining operation, the output of the power conditioners 20A to 20D may be limited and AC power may be supplied from the power conditioners 20A to 20D to the self-sustaining load 8. During self-sustaining operation, the output of the power conditioners 20A to 20D may be limited and AC power may be supplied from the power conditioners 20A to 20D to at least one of the single-phase consumer loads 2 and 3 and the self-sustaining load 8. good. By limiting the output of the power conditioners 20A to 20D during self-sustaining operation, it is possible to prevent damage to the terminal blocks and relays used during self-sustaining operation.

Moreover, each process explained above may be regarded as a control method of the distributed power supply system 1, etc. Each of the processes described above may be interpreted as a method executed by a computer. A program for causing a computer to execute each of the processes described above may be provided to the computer via a network or from a computer-readable recording medium that holds data non-temporarily. Note that each of the above means and processes can be combined to the extent possible to constitute the present invention.

<Additional notes>
It includes a plurality of power conditioners (20A to 20D) that convert input DC power into AC power and supply it to loads (2, 3, 8), at least one of the plurality of power conditioners A distributed power supply system (1) in which DC power is input from solar cells (7A, 7B),
The upper limit value of the output command value is determined so that the total value of the upper limit value of the output command value of the plurality of power conditioners is equal to or less than a predetermined limit value during self-sustaining operation,
A distributed power supply system characterized in that AC power is supplied to the load in such a manner that the output value of the plurality of power conditioners becomes equal to or less than an upper limit value of the output command value during the self-sustaining operation.

1...Distributed power supply system 1A...Single-phase system 1B...Three-phase system 2, 3...Single-phase consumer load 7A, 7B...Storage battery 7C, 7D...Solar Battery 8... Three-phase independent operation load 10A, 10B, 10C, 10D... Single-phase inverter 20A, 20B, 20C, 20D... Power conditioner 21... Controller

Claims (10)

A distributed power source comprising a plurality of power conditioners that convert input DC power into AC power and supply it to loads, and at least one of the plurality of power conditioners receives DC power from a solar cell. A system,
The upper limit value of the output command value is determined so that the total value of the upper limit value of the output command value of the plurality of power conditioners is equal to or less than a predetermined limit value during self-sustaining operation,
A distributed power supply system characterized in that AC power is supplied to the load in such a manner that the output value of the plurality of power conditioners becomes equal to or less than an upper limit value of the output command value during the self-sustaining operation. The distributed power supply system according to claim 1, wherein the upper limit value of the output command value is individually determined for each of the plurality of power conditioners. Each of the upper limit values of the output command values of the plurality of power conditioners is determined based on a ratio to the predetermined limit value set for the plurality of power conditioners. Distributed power system. Each of the plurality of power conditioners has a single-phase inverter,
4. The power conditioner according to claim 1, wherein the AC power of the three-phase voltage is supplied to the three-phase load by combining single-phase voltages of different phases of the single-phase inverters of each of the plurality of power conditioners. Distributed power supply system according to any one of the items. The output command value is an apparent current command value,
5. The distributed power supply system according to claim 1, wherein the output value is an apparent current value. The apparent current command value includes an active current command value and a reactive current command value,
The distributed power supply system according to claim 5, wherein the upper limit value of the active current command value is determined based on the upper limit value of the apparent current command value and the reactive current command value. The apparent current command value includes an active current command value and a reactive current command value,
The distributed power supply system according to claim 5, wherein the upper limit value of the reactive current command value is determined based on the upper limit value of the apparent current command value and the active current command value. The output command value is an apparent power command value,
The distributed power supply system according to any one of claims 1 to 4, wherein the output value is an apparent power value. The apparent power command value includes an active power command value and a reactive power command value,
The distributed power supply system according to claim 8, wherein the upper limit value of the active power command value is determined based on the upper limit value of the apparent power command value and the reactive power command value. The apparent power command value includes an active power command value and a reactive power command value,
The distributed power supply system according to claim 8, wherein the upper limit value of the reactive power command value is determined based on the upper limit value of the apparent power command value and the active power command value.

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