JP2016158337A - Power supply system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power supply system in which supply of power to a load is not completely blocked even in a case where an output from a photovoltaic power generation device is reduced in a state where a load greater or equal to the rating of a power storage device is connected.SOLUTION: A power supply system 1 comprises a supply circuit 317 that distributes and supplies power from a power storage device 3 and a photovoltaic power generation device 2 to a plurality of loads 6 and 7a. The supply circuit 317 changes a distribution supply pattern to the plurality of loads 6 and 7a depending on a power amount supplied from the photovoltaic power generation device 2.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a power supply system that supplies power to a plurality of loads.

  As this type of power supply system, there is a system described in Patent Document 1. The power supply system described in Patent Document 1 includes a main power line for supplying power from a system power source to a load, and a photovoltaic power generation device (hereinafter referred to as a distributed power source) connected to the main power line. It is also called a PV device (PV is an abbreviation for photovoltaics) and a power storage device as a power storage device that is also connected to the main power line.

  The PV device includes a solar cell, a PV power conditioner, and a PV power monitor current transformer. The PV power conditioner is connected to the main power line by a PV power line. The PV power conditioner converts the generated power of the solar cell into a state that can be supplied to the load, and supplies the converted power to the load via the PV power line and the main power line. The PV power monitor current transformer detects a current flowing through the PV power line, that is, an output current of the PV power conditioner.

  The power storage device includes a storage battery, a current transformer for power storage control, and a power storage power conditioner. The current transformer for power storage control detects a system current supplied to the load from both the main power line and the PV device. The power storage power conditioner calculates a difference value between the grid current detected by the current transformer for power storage control and the output current of the PV power conditioner detected by the current transformer for PV power monitoring, and based on the difference value, the storage battery Charge / discharge control. Specifically, when the difference value is greater than or equal to zero, the power storage power conditioner executes discharge control of the power storage device so that the difference value becomes zero. In addition, when the difference value is less than zero, the storage power conditioner executes charge control of the storage battery so that the difference value becomes zero.

JP 2012-55059 A

  By the way, in the power supply system described in Patent Document 1, for example, when a power failure occurs in the system power supply, the power supply from the main power line stops, so that the power supply to the load is performed only from the PV device and the power storage device. become. In addition, when the power supply system includes, for example, a PV device and a power storage device that are independent from the system power supply, power supply to the load is performed only from the PV device and the power storage device.

  In such a case, when the output from the PV device is reduced in a state where a load exceeding the rating of the power storage device is connected, all power supply to the load is interrupted.

  The present invention has been made in view of such a problem, and its purpose is to load even if the output from the solar power generation device is reduced in a state where a load exceeding the rating of the power storage device is connected. It is an object of the present invention to provide a power supply system in which power supply to all is not interrupted.

  In order to solve the above-described problem, a power supply system according to the present invention is a power supply system (1, 1A) that supplies power to a plurality of loads (6, 7a, 7b, 7c), and is stable. A first power supply device (3) capable of supplying power to a load; a second power supply device (2) in which power supply to the load is unstable compared to the first power supply device; And a supply circuit (317, 317A) for supplying and distributing power from the first power supply device and the second power supply device to the plurality of loads, the supply circuit according to the amount of power supplied from the second power supply device Then, the distributed supply pattern to the plurality of loads is changed.

  According to the present invention, the distributed supply pattern of power to a plurality of loads is changed in accordance with the amount of power supplied from the second power supply device in which the power supply to the load is unstable compared to the first power supply device. Therefore, even when the power supplied from the second power supply device fluctuates, it is possible to supply power using a distributed supply pattern corresponding to the fluctuation. Therefore, even when the power supplied from the second power supply device is reduced, a distributed supply pattern according to the degree of reduction can be obtained.

  According to the present invention, even when the output from the photovoltaic power generation apparatus is reduced in a state where a load exceeding the rating of the power storage device is connected, the power supply that does not block all the power supply to the load. A system can be provided.

It is a block diagram which shows the functional structure about the electric power supply system which is 1st Embodiment of this invention. It is a flowchart for demonstrating the switching aspect of the electric power supplied to load via the supply circuit shown by FIG. It is a block diagram which shows the functional structure about the electric power supply system which is 2nd Embodiment of this invention. It is a flowchart for demonstrating the switching aspect of the electric power supplied to load via the supply circuit shown by FIG.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. In order to facilitate the understanding of the description, the same constituent elements in the drawings will be denoted by the same reference numerals as much as possible, and redundant description will be omitted.

  A power supply system 1 according to a first embodiment will be described with reference to FIG. As shown in FIG. 1, the power supply system 1 of the present embodiment includes a solar power generation device 2, a power storage device 3, a distribution board 4, a single-phase three-wire system power supply 5, and loads 6 and 7 a. And have. The power supply system 1 is set to a house, for example. The loads 6 and 7a are various electric devices connected through, for example, an outlet in a house.

  The solar power generation device 2 functions as a distributed power source. The solar power generation device 2 includes a solar cell module 20 and a PV power conditioner 21. Since the amount of power generation of the solar power generation device 2 changes depending on the state in which the solar cell module 20 is irradiated with sunlight, in the present embodiment, the solar power generation device 2 is a second type in which power supply to the load is unstable. Used as a power supply.

  The solar cell module 20 is obtained by modularizing a plurality of solar cells, and generates DC power corresponding to the amount of solar radiation. The solar cell module 20 outputs the generated DC power to the PV power conditioner 21.

  The PV power conditioner 21 includes an inverter (not shown) and the like, and converts DC power output from the solar cell module 20 into AC power having a predetermined reference voltage and a predetermined reference frequency. The predetermined reference voltage is set to 100 [V] as an effective value, for example. The predetermined reference frequency is set to, for example, a commercial frequency of 50 [Hz] or 60 [Hz].

  The PV power conditioner 21 can supply the converted AC power to the loads 6 and 7a via the PV power line Wac1. The PV power conditioner 21 can also supply the generated power to the loads 6 and 7 a and the system power supply 5 via the distribution board 4.

  The power storage device 3 functions as a power storage device. The power storage device 3 includes a chargeable / dischargeable storage battery 30 and a power storage power conditioner 31. The power storage power conditioner 31 includes a converter 310 and an inverter 311. Since the storage battery 30 has a stable power supply to the load if the amount of stored electricity is ensured, in the present embodiment, the first power supply that can supply the storage battery 30 to the load stably. It is used as a device.

  The storage battery 30, the converter 310, the inverter 311 and the system power supply 5 are connected in series in this order. Converter 310 is connected to storage battery 30 via DC power line Wdc1, and is also connected to inverter 311 via DC power line Wdc2. Inverter 311 is connected to system power supply 5 via power storage power line Wac2.

  The PV power line Wac1 and the power storage power line Wac2 are connected via a connecting power line Wac3. That is, the solar power generation device 2, the system power supply 5, and the storage battery 30 are connected in parallel to the load 6. In FIG. 1, a first connection point between the PV power line Wac1 and the connection power line Wac3 is indicated by a symbol P1, and a second connection point between the storage power line Wac2 and the connection power line Wac3 is indicated by a symbol P2. Has been.

  The first connection point P1, the load 6, and the load 7a are connected by a supply circuit 317. The supply circuit 317 is a circuit that distributes and supplies power supplied from the storage battery 30 and the solar power generation device 2 to the load 6 and the load 7a. A semiconductor relay 316a is provided on the power line connected from the supply circuit 317 to the load 7a. The semiconductor relay 316a is opened and disconnected in accordance with an instruction from the control unit 312.

  Converter 310 can boost the DC power supplied from storage battery 30 and perform a boosting operation to supply the boosted DC power to inverter 311. Converter 310 can also step down the DC power supplied from inverter 311 and perform the step-down operation of supplying the DC power after the step-down to storage battery 30.

  Inverter 311 converts the DC power supplied from converter 310 into AC power, and can perform a DC / AC conversion operation for supplying the converted AC power to load 6 via power lines Wac1 to Wac3. It has become. Further, the inverter 311 can convert AC power supplied from the system power supply 5 or the photovoltaic power generator 2 into DC power, and can also perform AC / DC conversion operation for supplying the converted DC power to the converter 310. It has become.

  The power storage device 3 includes a voltage sensor 313 and switching elements 314 and 315. The voltage sensor 313 detects the voltage at the position P3 between the PV power conditioner 21 and the first connection point P1 in the PV power line Wac1, that is, the PV output voltage V output from the solar power generation device 2 to the load 6. . The voltage sensor 313 outputs an electrical signal corresponding to the PV output voltage V to the control unit 312.

  The switching elements 314 and 315 are composed of relays, for example. The switching element 314 is disposed between the voltage detection position P3 of the voltage sensor 313 and the first connection point P1 in the PV power line Wac1. The switching element 314 electrically connects the solar power generation device 2 and the load 6 by the closing operation. Moreover, the switching element 314 interrupts | blocks the electrical connection of the solar power generation device 2 and the load 6 by the opening operation | movement.

  Switching element 315 is arranged in a portion closer to system power supply 5 than second connection point P2 in power storage power line Wac2. Switching element 315 electrically connects system power supply 5 and power storage device 3 and electrically connects system power supply 5 and load 6 by its closing operation. Moreover, switching element 315 cuts off the electrical connection between system power supply 5 and power storage device 3 and the electrical connection between system power supply 5 and load 6 by the opening operation.

  The control unit 312 detects the PV output voltage V based on the detection signal output from the voltage sensor 313. The control unit 312 controls the operations of the converter 310, the inverter 311, the switching elements 314, 315, and the semiconductor relay 316a. The control unit 312 outputs a notification instruction to the notification unit 8. The notification unit 8 is a part that performs voice notification and display notification based on the notification instruction.

  The control unit 312 opens the switching element 314 and closes the switching element 315 during normal operation when no power failure occurs in the system power supply 5. Control unit 312 causes inverter 311 to perform an AC / DC conversion operation and causes converter 310 to perform a step-down operation. As a result, AC power supplied from the system power supply 5 is converted into DC power and stepped down, and the storage battery 30 is charged with the stepped-down DC power.

  In addition, an operating power supply for the load 6 is secured by the AC power supplied from the system power supply 5 to the load 6. Furthermore, the generated power of the photovoltaic power generation apparatus is supplied to the load 6 via the distribution board 4, and surplus generated power exceeding the power consumption of the load 6 is reversely flowed to the system power supply 5.

  When a power failure occurs in the system power supply 5, the control unit 312 performs a so-called self-sustained operation in which power is supplied to the load 6 using only the solar power generation device 2 and the power storage device 3 independently from the system power supply 5. The control unit 312 disconnects the electrical connection between the system power supply 5 and the power storage device 3 by opening the switching element 315 during the self-sustained operation, and between the system power supply 5 and the load 6. Break electrical connection. At this time, the PV power conditioner 21 stops supplying power to the distribution board 4.

  In addition, the control unit 312 enables power supply from the solar power generation device 2 to the load 6 and the storage battery 30 by closing the switching element 314. Control unit 312 controls charging / discharging of power storage device 3 based on PV output voltage V detected by voltage sensor 313.

  Next, the distributed supply of power by the supply circuit 317 will be described with reference to FIG. In step S01, the total value of the generated power of the photovoltaic power generation device 2 and the rated power of the storage battery 30 is larger than the combined power consumption of the load 6 and the load 7a, and the combined power consumption of the load 6 and the load 7a is the rating of the storage battery 30. It is determined whether or not the state is greater than the power.

  If it is in this state, the power required for the load 6 and the load 7a cannot be supplied by the storage battery 30 alone, so the process proceeds to step S02. If it is not in this state, the power required for the load 6 and the load 7a can be covered only by the storage battery 30, so the process of step S02 does not proceed and the determination of step S01 is continued.

  In step S02, the parallel discharge which performs the discharge from the solar power generation device 2 and the discharge from the storage battery 30 in parallel is executed.

  In step S03 following step S02, it is determined whether the solar power generation device 2 has stopped. Since the control unit 312 detects the PV output voltage V based on the detection signal output from the voltage sensor 313, when the PV output voltage V falls below the threshold, it is determined that the photovoltaic power generation device 2 has stopped. ing. If it is determined that the solar power generation device 2 has stopped, the process proceeds to step S04. If it is determined that the solar power generation device 2 has not stopped, the process returns to step S02.

  In step S04, the control unit 312 disconnects the semiconductor relay 316a. Thereby, the power supply to the load 7a is stopped. The control unit 312 outputs a notification instruction to the notification unit 8 prior to disconnection of the semiconductor relay 316a. The notification unit 8 notifies that the power supply to the load 7a is stopped.

  Next, the power supply system 1A according to the second embodiment will be described with reference to FIG. As shown in FIG. 3, the power supply system 1A of the present embodiment includes a solar power generation device 2, a power storage device 3, a distribution board 4, a single-phase three-wire system power supply 5, and loads 6, 7a. , 7b, 7c. Since the configurations and functions of the solar power generation device 2, the distribution board 4, and the system power supply 5 are the same as those in the first embodiment, description thereof will be omitted.

  The power storage device 3 functions as a power storage device. The power storage device 3 includes a rechargeable storage battery 30 and a storage power conditioner 31A. The power storage power conditioner 31 </ b> A includes a converter 310 and an inverter 311.

  The storage battery 30, the converter 310, the inverter 311 and the system power supply 5 are connected in series in this order. Converter 310 is connected to storage battery 30 via DC power line Wdc1, and is also connected to inverter 311 via DC power line Wdc2. Inverter 311 is connected to system power supply 5 via power storage power line Wac2.

  The PV power line Wac1 and the power storage power line Wac2 are connected via a connecting power line Wac3. That is, the solar power generation device 2, the system power supply 5, and the storage battery 30 are connected in parallel to the load 6. In FIG. 3, a first connection point between the PV power line Wac1 and the connection power line Wac3 is indicated by a symbol P1, and a second connection point between the storage power line Wac2 and the connection power line Wac3 is indicated by a symbol P2. Has been.

  The first connection point P1 and the loads 6, 7a, 7b, 7c are connected by a supply circuit 317A. The supply circuit 317A is a circuit that distributes and supplies the power supplied from the storage battery 30 and the solar power generation device 2 to the loads 6, 7a, 7b, and 7c. A semiconductor relay 316a is provided on the power line connecting the supply circuit 317A to the load 7a. Similarly, a semiconductor relay 316b is provided on the power line connected from the supply circuit 317A to the load 7b, and a semiconductor relay 316c is provided on the power line connected from the supply circuit 317A to the load 7c.

  The semiconductor relays 316a, 316b, and 316c are opened in accordance with instructions from the control unit 312 and disconnected individually. In this embodiment, the semiconductor relays 316a, 316b, and 316c are ordered, the semiconductor relay 316a is provided as the first semiconductor relay, the semiconductor relay 316b is provided as the second semiconductor relay, and the semiconductor is provided as the third semiconductor relay. A relay 316c is provided.

  Next, distributed supply of power by the supply circuit 317A will be described with reference to FIG. In step S11, the total value of the generated power of the photovoltaic power generation device 2 and the rated power of the storage battery 30 is larger than the combined power consumption of the loads 6, 7a, 7b, 7c, and the combined consumption of the loads 6, 7a, 7b, 7c. It is determined whether or not the power is larger than the rated power of the storage battery 30.

  In this state, the power required for the loads 6, 7a, 7b, and 7c cannot be supplied by the storage battery 30 alone, and the process proceeds to step S12. If it is not in this state, the power required for the loads 6, 7a, 7b, and 7c can be provided only by the storage battery 30, so the process of step S12 does not proceed and the determination of step S11 is continued.

  In step S12, the parallel discharge which performs the discharge from the solar power generation device 2 and the discharge from the storage battery 30 in parallel is executed.

  In step S13 following step S12, it is determined whether the solar power generation device 2 has stopped. Since the control unit 312 detects the PV output voltage V based on the detection signal output from the voltage sensor 313, when the PV output voltage V falls below the threshold, it is determined that the photovoltaic power generation device 2 has stopped. ing. If it is determined that the solar power generation device 2 has stopped, the process proceeds to step S14. If it is determined that the solar power generation device 2 has not stopped, the process returns to step S12.

  In step S14, the control unit 312 disconnects the semiconductor relay 316a. Thereby, the power supply to the load 7a is stopped. The control unit 312 outputs a notification instruction to the notification unit 8 prior to disconnection of the semiconductor relay 316a. The notification unit 8 notifies that the power supply to the load 7a is stopped.

  In step S15 following step S14, it is determined whether or not the combined power consumption of the loads 6, 7b and 7c is greater than the rated power of the storage battery 30. In this state, the power required for the loads 6, 7b, and 7c cannot be supplied by the storage battery 30 alone, and the process proceeds to step S16. If it is not in this state, the power required for the loads 6, 7b, 7c can be supplied only by the storage battery 30, so the process returns to step S16 without proceeding.

  In step S16, the control unit 312 disconnects the semiconductor relay 316b. Thereby, the power supply to the load 7b is stopped. The control unit 312 outputs a notification instruction to the notification unit 8 prior to disconnection of the semiconductor relay 316b. The alerting | reporting part 8 alert | reports that the electric power feeding to the load 7b is stopped.

  In step S17 following step S16, it is determined whether or not the combined power consumption of the loads 6 and 7c is larger than the rated power of the storage battery 30. In this state, the power required for the loads 6 and 7c cannot be supplied by the storage battery 30 alone, and the process proceeds to step S18. If it is not in this state, the power required for the loads 6 and 7c can be supplied only by the storage battery 30, so the process returns to step S18.

  In step S18, the control unit 312 disconnects the semiconductor relay 316c. Thereby, the power supply to the load 7c is stopped. The control unit 312 outputs a notification instruction to the notification unit 8 prior to disconnection of the semiconductor relay 316c. The notification unit 8 notifies that the power supply to the load 7c is stopped.

  The present invention is not limited to the specific examples described above. That is, the above-described specific examples that are appropriately modified by those skilled in the art are also included in the scope of the present invention as long as they have the characteristics of the present invention. For example, the elements included in each of the specific examples described above, their arrangement, conditions, and the like are not limited to those illustrated, and can be changed as appropriate. Moreover, each element with which embodiment mentioned above is provided can be combined as long as it is technically possible, and the combination of these is also included in the scope of the present invention as long as it includes the features of the present invention.

1, 1A: Power supply system 2: Solar power generation device (distributed power supply device)
3: Power storage device (power storage device)
6, 7a, 7b, 7c: Loads 317, 317A: Supply circuit

Claims (7)

A power supply system (1, 1A) for supplying power to a plurality of loads (6, 7a, 7b, 7c),
A first power supply device (3) capable of stably supplying power to the load;
A second power supply device (2) in which power supply to the load is unstable compared to the first power supply device;
A supply circuit (317, 317A) that distributes and supplies power from the first power supply device and the second power supply device to the plurality of loads,
The power supply system, wherein the supply circuit changes a distributed supply pattern to the plurality of loads in accordance with an amount of power supplied from the second power supply device. The plurality of loads include a first load (6) and a second load (7a, 7b, 7c),
2. The power supply system according to claim 1, wherein the power supply system cuts off power supply to the second load when an amount of power supplied from the second power supply device falls below a threshold value. 3. . A plurality of the second loads are provided,
The said supply circuit performs the interruption | blocking of the electric power supply to a said 2nd load in steps, when the electric energy supplied from a said 2nd power supply device is less than a threshold value. The power supply system described.   The power supply system according to any one of claims 1 to 3, wherein the first power supply device is a power storage device, and the second power supply device is a distributed power supply device.   The power supply system according to claim 4, wherein the distributed power supply device is a solar power generation device.   The power supply system according to claim 4, wherein the power storage device is a storage battery.   The power supply system according to claim 1, wherein the supply circuit executes the change of the distributed supply pattern when grid distribution is not performed.

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