JP2017118736A - Power supply system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power supply system capable of avoiding electric energy reducing at the time of outage, the electric energy being supplied to a load.SOLUTION: A power supply system comprises: a first unit capable of performing autonomous operation; a cross board that switches a supply source of power to be supplied to a load to a commercial power supply or the first unit; second and third units; a fourth sensor capable of detecting outage; and an EMS 80 that is capable of acquiring a detection results of the fourth sensor and controls a second and third power conditioners of the second and third units to make the second and third power conditioners perform charge/discharge of a second and third storage devices while controlling a first power conditioner of the first unit to make the first power conditioner perform charge/discharge of a first storage device. The power supply system, when the fourth sensor detects outage of the commercial power supply, executes a first pseudo interconnection mode and a second pseudo interconnection mode for controlling the second and third power conditioners depending on a state of the first unit.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a technology of a power supply system including a plurality of units including a power storage device and a transformer capable of boosting the voltage of power from the power storage device.

  2. Description of the Related Art Conventionally, a technology of a power supply system including a plurality of units including a power storage device and a transformer capable of boosting the voltage of power from the power storage device has been publicly known. For example, as described in Patent Document 1.

  The power supply system (solar power generation system) described in Patent Literature 1 includes a plurality of units each having a solar power generation facility, a power storage device, and a transformer (distribution transformer). The solar power generation facility and the power storage device are connected to the middle part of the distribution line via a transformer. The distribution line connects the power system and the load. In such an electric power supply system, electric power can be supplied to all loads at the time of a power outage by distributing the electric power from the photovoltaic power generation facility and the power storage device to a distribution line via a transformer at the time of the power outage.

JP 2012-10536 A

  However, if power is distributed to the distribution line via a transformer during a power failure, the power storage device of the downstream (load side) unit may be charged. This may reduce the amount of power supplied to the load during a power failure.

  The present invention has been made in view of the situation as described above, and the problem to be solved is a power supply system capable of avoiding a situation in which the amount of power supplied to a load is reduced during a power failure. It is to provide.

  The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.

  That is, a distribution board capable of supplying power from a commercial power source to a load, a power generation device capable of generating power using natural energy, the power generation device, and a first power storage device capable of charging / discharging power from the commercial power source And a first power conditioner that controls charging / discharging of the first power storage device, and connected to the commercial power source to supply power to the distribution board, and independent from the commercial power source. A first unit capable of performing self-sustaining operation for supplying power to the distribution board, and switching for switching a supply source of power supplied to the load to the commercial power source or the first unit A panel, a transformer that boosts the voltage of power supplied from the first unit to the distribution board during the independent operation, a second power storage device that can charge and discharge power from the commercial power source, and the first Charging / discharging of the second power storage device A second unit that includes a second power conditioner to be controlled, is disposed closer to the load than the switching panel and supplies power to the distribution panel; and a power failure detection unit capable of detecting a power failure of the commercial power source; The power failure detection unit can acquire the detection result, and controls the first power conditioner of the first unit to charge and discharge the first power storage device, and the second unit. A control unit that controls the second power conditioner to charge and discharge the second power storage device, and the control unit detects the power failure of the commercial power source when the power failure detection unit detects the power failure. The power failure mode for controlling the second power conditioner of the second unit is executed according to the state of the first unit.

When the power failure mode is executed, the second unit may be preferentially discharged from the first and second units.
With such a configuration, power can be supplied from a plurality of units to the load in an appropriate order.

When the power failure mode is executed, the control unit performs the first operation when the first power storage device is fully charged and the second power storage device of the second unit can be charged. Electric power generated by the power generation device of one unit may be charged to the second power storage device of the second unit.
With such a configuration, the power generated by the power generator can be used effectively without wasting it.

A plurality of the second units are arranged on an electric circuit connecting the commercial power source and the load, and the control unit generates power generated by the power generation device of the first unit in the second unit. When charging the second power storage device, it is possible to preferentially charge the unit placed on the first unit side among the plurality of second units.
With such a configuration, when output is performed from a plurality of units, it is possible to prevent the output from being inhibited.

When the power failure of the commercial power source is resolved, the control unit may end the power failure mode, and the first unit may perform the interconnection operation.
With such a configuration, power can be appropriately supplied to the load during normal times.

  As effects of the present invention, the following effects can be obtained.

  It is possible to avoid a situation in which the amount of power supplied to the load during a power failure is reduced.

The block diagram which showed the structure of the electric power supply system which concerns on 1st embodiment. The block diagram which showed the structure of the electrical connection of an energy management system (EMS) and another apparatus. The flowchart shown about the supply aspect of electric power in case a power failure mode is performed. Similarly, the block diagram which showed the state by which the independent operation was started in the 1st unit. Similarly, the block diagram which showed the state by which the load following operation was started in the 2nd and 3rd unit. Similarly, the second pseudo power failure mode is executed, and a block diagram showing a state where power is input to the second unit. Similarly, the block diagram which showed the state by which 2nd pseudo | simulation blackout mode is performed and electric power is input into a 3rd unit. The block diagram which showed the structure of the electric power supply system which concerns on 2nd embodiment.

  Below, the electric power supply system 1 which concerns on 1st embodiment of implementation of this invention is demonstrated using FIG.1 and FIG.2.

  A power supply system 1 shown in FIGS. 1 and 2 is provided in a factory and supplies power to a load of the factory. The power supply system 1 includes a distribution board 10, a sensor unit 20, a first unit 30, a transformer 40, a switching board 50, a second unit 60, a third unit 70, an energy management system 80, and the like.

  A distribution board 10 shown in FIG. 1 distributes power supplied from a power supply source to a load. The distribution board 10 is supplied with power according to the power consumption of the load from a power supply source (commercial power supply 90, first unit 30 described later, etc.). The distribution board 10 includes an earth leakage breaker, a wiring breaker, a control unit, and the like. A general circuit 11 connected to a load is provided in the distribution board 10. The general circuit 11 is connected to the commercial power supply 90 via the distribution line L1.

  The sensor part 20 shown in FIG.1 and FIG.2 detects the electric power which flows through the distribution line L1 in the distribution board 10. FIG. The sensor unit 20 includes a first sensor 21, a second sensor 22, a third sensor 23, a fourth sensor 24, and the like.

  Each of the sensors 21 to 24 detects electric power at an arrangement location. Each of the sensors 21 to 24 is disposed in the middle of the distribution line L1 (in the distribution board 10). The sensors 21 to 24 are arranged in the distribution board 10 from the commercial power supply 90 side of the distribution line L1 toward the general circuit 11 side, the first sensor 21, the fourth sensor 24, the second sensor 22, The three sensors 23 are arranged in the order. Each of the sensors 21 to 24 is configured to be able to transmit a signal related to the detection result.

  The first unit 30 shown in FIGS. 1 and 2 is one of the supply sources of power to the load. The first unit 30 includes a first solar power generation device 31, a first power storage device 32, a first power conditioner 33, and the like.

  The first solar power generation device 31 is a device that generates power using sunlight. The first solar power generation device 31 includes a solar cell panel and the like. The first solar power generation device 31 is configured to be capable of generating power when sunlight hits the solar cell panel.

  The first power storage device 32 is a device capable of charging and discharging electric power. The first power storage device 32 includes a storage battery that can charge and discharge power, a charger that rectifies supplied AC power and charges the storage battery. The 1st electrical storage apparatus 32 is comprised so that charging / discharging of the electric power from the 1st photovoltaic power generation apparatus 31 and the commercial power supply 90 is possible.

  The first power conditioner 33 is a hybrid power conditioner that controls input and output of electric power. The first power conditioner 33 includes a converter that converts DC power into a predetermined voltage, an inverter that converts DC power into AC power, a control unit that controls the operation, and the like. The first power conditioner 33 is connected to the first solar power generation device 31 and the first power storage device 32 via two different distribution lines. The first power conditioner 33 is electrically connected to the first sensor 21. As a result, the first power conditioner 33 receives the signal transmitted from the first sensor 21 and acquires information related to the detection result of the first sensor 21. Further, the first power conditioner 33 can perform a load following operation for adjusting the amount of electric power to be output based on the detection result of the first sensor 21. Moreover, the 1st power conditioner 33 can perform an interconnection operation and a self-supporting operation.

  The interconnection operation of the first power conditioner 33 is to operate the first solar power generation device 31 and the first power storage device 32 in linkage with the commercial power supply 90 in a normal time (non-power failure). Thus, the first power conditioner 33 outputs the power generated by the first solar power generation device 31 or the power discharged from the first power storage device 32 in a state of being linked to the commercial power supply 90 at normal times. The electric power generated by the first solar power generation device 31 and the electric power from the commercial power supply 90 can be input (charged) to the first power storage device 32.

  The self-sustained operation of the first power conditioner 33 is to operate the first solar power generation device 31 and the first power storage device 32 independently of the commercial power supply 90 at the time of a power failure. Thus, the first power conditioner 33 outputs the power generated by the first solar power generation device 31 or the power discharged from the first power storage device 32 in an independent state from the commercial power supply 90 in an emergency. The electric power generated by the first solar power generation device 31 can be input (charged) to the first power storage device 32. In addition, in the self-sustained operation of the first power conditioner 33, the output and input (charging) of the power generated by the first solar power generation device 31 can be performed simultaneously.

  The 1st unit 30 comprised in this way is connected with the distribution board 10 via the distribution line L2 and the distribution line L3.

  More specifically, in the first unit 30, the first power conditioner 33 is connected to the distribution line L1 in the distribution board 10 via the distribution line L2 (between the fourth sensor 24 and a switching panel 50 described later). Connected. In this way, the first power conditioner 33 is connected to the commercial power supply 90 and the general circuit 11 (load) in the distribution board 10 via the distribution lines L2 and L1. In addition, the distribution line L2 is a distribution line used at the normal time (that is, at the time of the interconnection operation of the first power conditioner 33).

  In the first unit 30, the first power conditioner 33 is connected to the switching board 50 in the distribution board 10 via the distribution line L3. In this way, the first power conditioner 33 is connected to the general circuit 11 (load) in the distribution board 10 via the distribution lines L3 and L1. In addition, the distribution line L3 is a distribution line used at the time of a power failure (that is, at the time of the independent operation of the first power conditioner 33).

  The transformer 40 shown in FIG. 1 boosts electric power. The transformer 40 is provided in the middle of the distribution line L3. Thereby, the electric power output from the first unit 30 during the self-sustaining operation can be boosted and consumed by the load.

  The switch board 50 shown in FIG.1 and FIG.2 switches the supply source of the electric power which flows into the general circuit 11 side via the said switch board 50 suitably. The switching board 50 is provided in the middle of the distribution line L1 (between the connection part of the distribution lines L1 and L2 and the second sensor 22 in the distribution board 10). The switching board 50 is provided with a relay (not shown). The switching board 50 controls the relay to connect the downstream side of the switching board 50 of the distribution line L1 to either the upstream side of the switching board 50 of the distribution line L1 or the distribution line L3. Can do.

  Thus, at the normal time, the switching board 50 connects the upstream side and the downstream side of the switching board 50 of the distribution line L1. As described above, when the upstream side and the downstream side of the switching board 50 of the distribution line L1 are connected, the general circuit 11 is connected to the commercial power supply 90 via the distribution line L1, and the distribution lines L1 and L2 are connected. Via the first unit 30. Thereby, the supply source of the electric power flowing to the general circuit 11 side via the switching board 50 is switched to the commercial power supply 90 or the first unit 30 (more specifically, the first unit 30 during the interconnection operation). be able to.

  Further, at the time of a power failure, the switching board 50 connects the downstream side of the distribution line L1 to the distribution line L3 and the distribution line L3. As described above, when the downstream side of the switching board 50 of the distribution line L1 and the distribution line L3 are connected, the general circuit 11 is connected to the first unit 30 via the distribution lines L1 and L3. Thereby, the supply source of the electric power flowing to the general circuit 11 side via the switching board 50 can be switched to the first unit 30 (more specifically, the first unit 30 during the self-sustaining operation).

  The second unit 60 shown in FIGS. 1 and 2 is one of the sources of power to the load. The second unit 60 includes a second power storage device 62, a second power conditioner 63, and the like.

  Note that the configurations of the second power storage device 62 and the second power conditioner 63 (specifically, their own configurations and configurations related to each other) are the same as those of the first power storage device 32 and the first power conditioner 33. Since it is substantially the same as the configuration, a description will be given focusing on different points.

  Second power conditioner 63 is connected to second power storage device 62 through a predetermined wiring line. The second power conditioner 63 is electrically connected to the second sensor 22. Accordingly, the second power conditioner 63 receives the signal transmitted from the second sensor 22 and acquires information related to the detection result of the second sensor 22. Further, the second power conditioner 63 can perform a load following operation that adjusts the amount of electric power to be output based on the detection result of the second sensor 22. Further, the second power conditioner 63 can perform the interconnection operation and the independent operation. In addition, when the interconnection operation is performed in the second power conditioner 63, one of a pseudo interconnection mode and a normal interconnection mode described later is selected.

  Thus, the second power conditioner 63 outputs the electric power discharged from the second power storage device 62 via the distribution line L4 in a state of being connected to the commercial power supply 90 at the normal time, The power from the unit 30 can be input (charged) to the second power storage device 62.

  In addition, the second power conditioner 63 can output the electric power discharged from the second power storage device 62 via a distribution line (not shown) used during the self-sustaining operation in a state independent of the commercial power supply 90 in an emergency. it can.

  Further, the second power conditioner 63 is in a state independent of the commercial power supply 90 in an emergency, and a second power storage device is connected via the distribution line L4 in a state where a first pseudo interconnection mode described later is executed. The electric power discharged from 62 can be output.

  Further, the second power conditioner 63 is in a state independent of the commercial power supply 90 in an emergency, and in a state in which a second pseudo interconnection mode described later is executed, the second power storage device 63 is connected via the distribution line L4. The power discharged from 62 can be output, or the power from the first unit 30 can be input (charged) to the second power storage device 62.

  The second unit 60 configured in this way is connected to the distribution board 10 via the distribution line L4 as described above.

  More specifically, in the second unit 60, the second power conditioner 63 is connected to the distribution line L1 in the distribution board 10 via the distribution line L4 (between the second sensor 22 and the third sensor 23). Connected. In this way, the second power conditioner 63 is connected to the commercial power supply 90 and the general circuit 11 (load) in the distribution board 10 via the distribution lines L4 and L1. The second power conditioner 63 is connected to the first unit 30 (more specifically, the first power conditioner 33) via the distribution lines L4, L1, and L2 (or distribution lines L4, L1, and L3). The In addition, the distribution line L4 is a distribution line used at the normal time (that is, during the interconnection operation of the second power conditioner 63).

  The third unit 70 shown in FIGS. 1 and 2 is one of the supply sources of power to the load. The third unit 70 includes a third power storage device 72, a third power conditioner 73, and the like.

  The configuration of the third power storage device 72 and the third power conditioner 73 (specifically, the configuration of each of the third power storage device 72 and the third power conditioner 73) Since it is substantially the same as the configuration, a description will be given focusing on different points.

  Third power conditioner 73 is connected to third power storage device 72 through a predetermined wiring line. Further, the third power conditioner 73 is electrically connected to the third sensor 23. As a result, the third power conditioner 73 receives the signal transmitted from the third sensor 23 and acquires information related to the detection result of the third sensor 23. Further, the third power conditioner 73 can perform a load following operation for adjusting the amount of electric power to be output based on the detection result of the third sensor 23. Moreover, the 3rd power conditioner 73 can perform an interconnection operation and a self-supporting operation. In addition, when the interconnection operation is performed in the third power conditioner 73, one of a pseudo interconnection mode and a normal interconnection mode described later is selected.

  In this way, the third power conditioner 73 outputs power discharged from the third power storage device 72 via the distribution line L5 in a state of being connected to the commercial power supply 90 at the normal time, The power from the unit 30 can be input (charged) to the third power storage device 72.

  Further, the third power conditioner 73 can output the electric power discharged from the third power storage device 72 via a distribution line (not shown) used during the self-sustaining operation in a state independent of the commercial power supply 90 in an emergency. it can.

  In addition, the third power conditioner 73 is independent from the commercial power supply 90 in an emergency, and is in a state in which a first pseudo interconnection mode to be described later is executed, and is connected to the third power storage device via the distribution line L5. The electric power discharged from 72 can be output.

  In addition, the third power conditioner 73 is independent from the commercial power supply 90 in an emergency, and is in a state in which a second pseudo interconnection mode to be described later is executed, and is connected to the third power storage device via the distribution line L5. The power discharged from 72 can be output, or the power from the first unit 30 can be input (charged) to the third power storage device 72.

  The third unit 70 configured in this manner is connected to the distribution board 10 via the distribution line L5 as described above.

  More specifically, in the third unit 70, the third power converter 73 is connected to the distribution line L1 (between the third sensor 23 and the general circuit 11) in the distribution board 10 via the distribution line L5. Is done. Thus, the third power conditioner 73 is connected to the commercial power supply 90 and the general circuit 11 (load) in the distribution board 10 via the distribution lines L5 and L1. The third power conditioner 73 is connected to the first unit 30 (more specifically, the first power conditioner 33) via the distribution lines L5, L1, and L2 (or distribution lines L5, L1, and L3). The In addition, the distribution line L5 is a distribution line used at the normal time (namely, at the time of the interconnection operation of the 3rd power conditioner 73).

  An energy management system (Energy Management System, hereinafter referred to as “EMS”) 80 shown in FIG. 2 manages the operation of the power supply system 1. The EMS 80 includes a storage unit such as a RAM and a ROM, an arithmetic processing unit such as a CPU, an input / output device such as an I / O, and the like. The EMS 80 can perform predetermined arithmetic processing, storage processing, and the like. The EMS 80 stores in advance various information, programs, and the like that are used when controlling the operation of the power supply system 1.

  The EMS 80 is electrically connected to the first unit 30 (more specifically, the first power conditioner 33). The EMS 80 can transmit a predetermined signal to the first unit 30 to control the operation of the first unit 30 (for example, charging / discharging of the first power storage device 32, etc.). Further, the EMS 80 receives a signal related to the operation status of the first unit 30. In this way, the EMS 80 can acquire information regarding the operation status of the first unit 30.

  For example, the EMS 80 acquires information related to the output of power from the first unit 30 (first power conditioner 33). Specifically, the EMS 80 charges the first power storage device 32 of the first solar power generation device 31 and the first power storage device 32 with the output from the first power conditioner 33 of the first unit 30. Information regarding whether or not the output is only the power that has been generated is acquired. Further, the EMS 80 is configured so that the output from the first power converter 33 of the first unit 30 is output from both the first solar power generation device 31 and the first power storage device 32 (first solar power generation). Information regarding whether or not the power generated by the device 31 and the power stored in the first power storage device 32 are output). In addition, the EMS 80 acquires information regarding whether or not the output from the first power conditioner 33 of the first unit 30 is the maximum output (for example, 2000 W).

  In addition, the EMS 80 acquires information regarding whether or not the first power storage device 32 of the first unit 30 cannot be discharged (whether or not the amount of power that can be discharged is charged).

  The EMS 80 is electrically connected to the second unit 60 (more specifically, the second power conditioner 63). The EMS 80 can transmit a predetermined signal to the second unit 60 and control the operation of the second unit 60 (for example, charge / discharge of the second power storage device 62). The EMS 80 receives a signal related to the operation status of the second unit 60. In this way, the EMS 80 can acquire information related to the operation status of the second unit 60.

  For example, the EMS 80 acquires information regarding whether or not the second power storage device 62 of the second unit 60 needs to be discharged (the second power storage device 62 is fully charged).

  The EMS 80 is electrically connected to the third unit 70 (more specifically, the third power conditioner 73). The EMS 80 can transmit a predetermined signal to the third unit 70 to control the operation of the third unit 70 (for example, charge / discharge of the third power storage device 72). The EMS 80 receives a signal related to the operation status of the third unit 70. In this way, the EMS 80 can acquire information regarding the operation status of the third unit 70.

  For example, the EMS 80 acquires information regarding whether or not the third power storage device 72 of the third unit 70 needs to be discharged (whether the third power storage device 72 is fully charged).

  The EMS 80 is electrically connected to the fourth sensor 24. The EMS 80 receives a signal related to the detection result of the fourth sensor 24. In this way, the EMS 80 acquires information regarding the detection result of the fourth sensor 24. For example, the EMS 80 acquires information related to the occurrence or cancellation of a power failure based on the detection result of the fourth sensor 24.

  The EMS 80 is electrically connected to the switching board 50. The EMS 80 acquires information regarding the operation status of the switching board 50. The EMS 80 can transmit a predetermined signal to the switching board 50 and control the switching board 50 (more specifically, a relay provided in the switching board 50).

  The power supply system 1 configured as described above has a plurality of different modes for the power supply mode. The plurality of modes include two types of modes, that is, a normal mode selected at normal time and a power failure mode executed at power failure.

  Hereinafter, in the power supply system 1, a power supply mode when the normal mode is executed (that is, in the normal time) will be described.

  When the normal mode is executed (when normal), the upstream side and the downstream side of the distribution line L1 are connected in the switching panel 50.

  In the normal mode, power from the commercial power supply 90 is supplied to the distribution board 10 (and thus the general circuit 11) via the distribution line L1. Thus, the power from the commercial power supply 90 is supplied to the load via the distribution line L1. In this case, in the third unit 70, the third power conditioner 73 performs the load following operation based on the detection result of the third sensor 23, and the third power conditioner 73 receives electric power (third power storage device). The electric power discharged from 72) is output. Thus, the electric power output from the third unit 70 (third power conditioner 73) is supplied to the general circuit 11 via the distribution lines L5 and L1. When power is output from the third unit 70, the amount of power supplied from the commercial power supply 90 to the general circuit 11 decreases.

  If the power consumption of the load cannot be covered only by the power from the third unit 70, the insufficient power is supplied from the commercial power supply 90 to the general circuit 11. That is, the electric power from the commercial power supply 90 is supplied to the load via the distribution line L1. In this case, in the second unit 60, the second power conditioner 63 performs load following operation based on the detection result of the second sensor 22, and the second power conditioner 63 receives electric power (second power storage device). The electric power discharged from 62 is output. Thus, the electric power output from the second unit 60 (second power conditioner 63) is supplied to the general circuit 11 via the distribution lines L4 and L1. When power is output from the second unit 60, the amount of power supplied from the commercial power supply 90 to the general circuit 11 further decreases.

  In addition, when the power consumption of the load cannot be covered only by the power from the third unit 70 and the second unit 60, the insufficient power is supplied from the commercial power supply 90 to the general circuit 11. That is, the electric power from the commercial power supply 90 is supplied to the load via the distribution line L1. In this case, in the first unit 30, the first power conditioner 33 performs the load following operation based on the detection result of the first sensor 21, and the first power conditioner 33 generates electric power (first sunlight). The power generated by the power generation device 31 and the power discharged from the first power storage device 32) are output. Thus, the electric power output from the first unit 30 (first power conditioner 33) is supplied to the general circuit 11 via the distribution lines L2 and L1. When power is output from the first unit 30, the amount of power supplied from the commercial power supply 90 to the general circuit 11 further decreases.

  In this manner, in the normal mode, the power from the third unit 70, the second unit 60, and the first unit 30 can be sequentially output with respect to the power consumption of the load. The amount of power supplied to 11 (load) (the amount of power purchased from the commercial power supply 90) can be reduced.

  Further, for example, the first solar power generation device of the first unit 30 with respect to the power consumption of the load in a state where the power from the third unit 70, the second unit 60, and the first unit 30 is sequentially output. When surplus occurs in the power generated by 31, the surplus power can be charged to the first power storage device 32 of the first unit 30. Further, when the power consumption of the load is covered only by the power from the third unit 70 (when surplus occurs in the power generated by the first solar power generation device 31 of the first unit 30). Can charge the second power storage device 62 of the second unit 60 with the surplus power. Accordingly, the first power storage device 32 and the second power storage device 62 are charged with the power generated by the first solar power generation device 31 as the power output from the first unit 30 and the second unit 60. As a result, the amount of power purchased from the commercial power supply 90 can be reduced.

  Further, for example, at a predetermined timing (for example, a midnight time zone in which the power consumption of the factory is low), the power from the relatively inexpensive commercial power supply 90 to which the midnight charge is applied is supplied to the first unit 30 and the second unit. The first power storage device 32, the second power storage device 62, and the third power storage device 72 can be charged as power to be output from the 60 and the third unit 70, respectively. In this way, the amount of power purchased from the relatively expensive commercial power supply 90 is reduced by discharging the power charged in the power storage devices 32, 62, and 72 in the daytime (no late-night charge is applied). be able to.

  Hereinafter, a power supply mode when the power failure mode is executed in the power supply system 1 (that is, when there is a power failure) will be described with reference to the flowchart of FIG. 3 and FIGS. 4 to 7.

  In the flowchart of FIG. 3, for convenience of explanation, the power storage device is described as “Lib” and the solar power generation device is described as “PV”.

  First, in a normal time (normal mode), the EMS 80 receives a signal transmitted from the fourth sensor 24 and acquires information on a detection result of the fourth sensor 24. In this way, the EMS 80 acquires information related to the power from the commercial power supply 90 flowing through the distribution line L1 (that is, information related to the occurrence of a power failure).

  When a power failure occurs, the fourth sensor 24 stops detecting power from the commercial power supply 90. Thus, the EMS 80 acquires information related to the occurrence of a power failure based on the detection result of the fourth sensor 24 (step S11).

  Moreover, EMS80 will control the switch board 50, if the information regarding generation | occurrence | production of a power failure is acquired, and will connect the downstream with respect to the switch board 50 of the distribution line L1, and the distribution line L3. As a result, the EMS 80 uses the commercial power supply 90 and the first unit 30 (more specifically, the first unit 30 during the interconnection operation) as the supply source of the electric power flowing to the general circuit 11 side via the switching panel 50. ) To the first unit 30 (more specifically, the first unit 30 during the autonomous operation).

  Further, when a power failure occurs, the first power conditioner 33 of the first unit 30 acquires information related to the occurrence of the power failure based on the detection result of the first sensor 21. When the first power conditioner 33 acquires information related to the occurrence of a power failure, the first power conditioner 33 ends the interconnection operation and starts a self-sustaining operation after a predetermined period of time (step S12). When the self-sustained operation is thus started, as shown in FIG. 4, the power output from the first unit 30 (first power conditioner 33) is supplied to the distribution board 10 via the distribution lines L3 and L1. It is supplied to the general circuit 11.

  Further, when a power failure occurs, the power conditioners 63 and 73 of the units 60 and 70 acquire information related to the occurrence of the power failure based on the detection results of the sensors 22 and 23, respectively. When each of the power conditioners 63 and 73 acquires information related to the occurrence of a power failure, the connected operation is terminated.

  In addition, when the electric power output from the 1st power conditioner 33 by the independent operation is supplied to the general circuit 11 in the distribution board 10 through the distribution lines L3 and L1, the distribution line on the downstream side of the switching board 50 The electric power will flow through L1. When power flows in the distribution line L1 in this way, the power conditioners 63 and 73 of the units 60 and 70, based on the detection results of the sensors 22 and 23, are actually in the event of a power failure. Get information about resolution. Thus, when the information regarding the cancellation of the power failure is acquired, each of the power conditioners 63 and 73 starts the interconnection operation.

  Thereby, each power conditioner 63 and 73 regards the first unit 30 at the time of self-sustained operation as the commercial power supply 90 and is in a state of being connected to the commercial power supply 90 in a pseudo manner. That is, each of the power conditioners 63 and 73 performs load follow-up operation based on the detection results of the sensors 22 and 23, respectively. In this way, as shown in FIG. 5, the electric power output from the 3rd unit 70 (3rd power conditioner 73) is supplied to the general circuit 11 via the distribution line L5 * L1. Moreover, the electric power output from the 2nd unit 60 (2nd power conditioner 63) is supplied to the general circuit 11 via the distribution line L4 * L1.

  In step S13, the EMS 80 controls the power conditioners 63 and 73 to discharge only the power storage devices 62 and 72 when the power conditioners 63 and 73 are pseudo-connected to the commercial power supply 90 (charging). Is prohibited). Specifically, for example, even if a power failure occurs in the midnight time zone (which causes each power storage device 62 or 72 to be charged with power from a relatively inexpensive commercial power supply 90), each power storage device 62. 72 is not charged.

Hereinafter, in each power conditioner 63/73, a mode in which a connected operation in which charging of each power storage device 62/72 is prohibited during a power failure is referred to as a “first pseudo-connected mode”. Further, as will be described later, a mode in which each power conditioner 63 and 73 performs a linked operation in which charging of each power storage device 62 and 72 is not prohibited (permitted) at the time of a power failure is referred to as a “second pseudo-linked mode”.
On the other hand, in each power conditioner 63/73, a mode in which a connected operation in which charging of each power storage device 62/72 is not prohibited (permitted) at normal time is referred to as a “normal connected mode”.

In addition, when the electric power which flows through the distribution line L1 once stops and flows again, it is the electric power from the commercial power supply 90 (because the power failure was eliminated) or the self-sustained operation (because the power failure is continued). The power conditioners 63 and 73 cannot determine whether the power is from one unit 30 based on the detection results of the sensors 22 and 23. However, the EMS 80 acquires information related to the occurrence of a power failure based on the detection result of the fourth sensor 24 and appropriately determines whether the power failure has been eliminated or continued, and then determines each power conditioner 63 and 73 (first or second). ) It can be a pseudo-interconnection mode or an interconnection mode.

  In this way, when each power conditioner 63 and 73 is in a state of being virtually linked to the commercial power supply 90, each power conditioner 63 and 73 is set to the first pseudo linked mode by the EMS 80. As a result, when the first power conditioner 33 of the first unit 30 performs a self-sustained operation at the time of a power failure, the power output from the first unit 30 is transferred to other units (the second unit 60 and the third unit 30). It can be supplied to the general circuit 11 without being taken away by the unit 70). That is, it is possible to avoid a situation where the amount of power supplied to the load during a power failure decreases.

  Further, when each of the power conditioners 63 and 73 is artificially linked to the commercial power supply 90, the third unit 70, the second The power from the unit 60 and the first unit 30 can be sequentially output.

  In step S <b> 14, the EMS 80 determines whether or not the power failure has been eliminated (recovered from the power failure) based on the detection result of the fourth sensor 24.

  Thus, when the EMS 80 determines that the power failure has been resolved (“YES” in step S14), the mode relating to the power supply mode is switched from the power failure mode to the normal mode (step S15). Specifically, the EMS 80 controls the switching board 50 to connect the upstream side and the downstream side of the switching board 50 of the distribution line L1. Thereby, the EMS 80 changes the supply source of the electric power flowing to the general circuit 11 side via the switching panel 50 from the first unit 30 (more specifically, the first unit 30 during the self-sustaining operation) from the commercial power supply. 90 and the first unit 30 (more specifically, the first unit 30 during the interconnection operation).

  When the power failure is eliminated, the first power conditioner 33 of the first unit 30 acquires information related to the elimination of the power failure based on the detection result of the first sensor 21. If the 1st power conditioner 33 acquires the information regarding the cancellation of a power failure, it will complete | finish independent operation and will start a grid connection operation | movement after progress for a predetermined period. Thus, when the grid connection operation is started, the electric power output from the first unit 30 (the first power conditioner 33) is supplied from the commercial power source 90 (with the power failure eliminated) via the distribution lines L2 and L1. The power is supplied to the general circuit 11 in the distribution board 10 together with the power.

  Further, when the electric power output from the first power conditioner 33 by the interconnection operation is supplied to the general circuit 11, since the pseudo connection with the commercial power supply 90 is changed to the actual connection state, each power conditioner The state of being connected to the commercial power supply 90 in a pseudo manner at 63 and 73 is eliminated. In such a case, the EMS 80 switches each of the power conditioners 63 and 73 from the first pseudo interconnection mode to the normal interconnection mode. As a result, the power conditioners 63 and 73 can perform the interconnection operation without being prohibited from charging the power storage devices 62 and 72 in the normal time. Thus, when the interconnection operation of each of the power conditioners 33, 63, and 73 is started, the power supply mode when the power failure mode is executed is temporarily terminated.

  On the other hand, when the EMS 80 determines that the power failure has not been resolved (“NO” in step S14), the EMS 80 performs the process of step S16.

  In step S <b> 16, the EMS 80 receives a predetermined signal from the first power conditioner 33 of the first unit 30, so that the first power storage device 32 is empty (the amount of power that can be discharged is charged). Whether or not) is determined.

  Thus, if the EMS 80 determines that the first power storage device 32 is empty (the amount of power that can be discharged is not charged) (“YES” in step S16), the EMS 80 The autonomous operation of the first power conditioner 33 is stopped (step S17). When the self-sustained operation of the first power conditioner 33 is stopped in this way, the power supply mode when the power failure mode is executed is temporarily terminated.

  On the other hand, when the EMS 80 determines that the first power storage device 32 is not empty (the amount of electric power that can be discharged is charged) (“NO” in step S16), the process proceeds to step S18. Process.

  In step S <b> 18, the EMS 80 charges the first power storage device 32 among the first solar power generation device 31 and the first power storage device 32 with the output from the first power conditioner 33 of the first unit 30. It is determined whether or not the output is only electric power.

  In this way, the EMS 80 is configured such that the output from the first power converter 33 of the first unit 30 is the electric power charged in the first power storage device 32 of the first solar power generation device 31 and the first power storage device 32. If it is determined that the output is only the output ("YES" in step S18), the process of step S14 is performed again. In addition, the case where it determines in this way is the case where the 1st unit 30 does not generate electric power with the 1st solar power generation device 31, or the electric power generated with the 1st solar power generation device 31 Is not output because the first power storage device 32 is charged.

  On the other hand, the EMS 80 charges the first power storage device 32 of the first solar power generation device 31 and the first power storage device 32 with the output from the first power conditioner 33 of the first unit 30. If it is determined that the output is not only the power that has been output (“NO” in step S18), the process of step S19 is performed. In addition, in the case where it determines in this way, in the 1st unit 30, not only the electric power charged by the 1st electrical storage apparatus 32 but the electric power generated by the 1st photovoltaic power generation apparatus 31 is output. It is a case.

  In step S <b> 19, the EMS 80 outputs from the first solar power generation device 31 and the first power storage device 32 (the first solar power generator 32). It is determined whether or not the electric power generated by the photovoltaic power generation device 31 and the output of the power charged in the first power storage device 32).

  Thus, when the EMS 80 determines that the output from the first power converter 33 of the first unit 30 is the output from both of the first solar power generation device 31 and the first power storage device 32 ( If “YES” in the step S19), the process of the step S14 is performed again.

  In contrast, the EMS 80 determines that the output from the first power conditioner 33 of the first unit 30 is not the output from both of the first solar power generation device 31 and the first power storage device 32. If so ("NO" in step S19), the process of step S20 is performed. In addition, the case where it determines in this way is a case where in the 1st unit 30, only the electric power generated with the 1st solar power generation device 31 is output.

  In step S20, the EMS 80 controls the first power conditioner 33 of the first unit 30, and continues the output from the first power conditioner 33 while generating the electric power generated by the first photovoltaic power generation apparatus 31. The first power storage device 32 is charged. EMS80 will perform the process of step S21, if the 1st electrical storage apparatus 32 is made to charge the electric power generated with the 1st photovoltaic power generation apparatus 31. FIG.

  In step S21, the EMS 80 determines whether or not the output from the first power conditioner 33 of the first unit 30 is the maximum output (for example, 2000 W).

  Thus, when the EMS 80 determines that the output from the first power conditioner 33 of the first unit 30 is not the maximum output (“NO” in step S21), the process of step S22 is performed. In this case, it is assumed that there is no shortage of power output from each unit 30, 60, and 70 with respect to the power consumption of the load (that is, surplus power is generated). The In such a state, even when the power from the first unit 30 is charged in the power storage devices 62 and 72 of the units 60 and 70, there is no insufficient power for the power consumption of the load. There is a case. Therefore, when it determines in this way, EMS80 performs control which makes the electrical storage apparatus 62 * 72 of each unit 60 * 70 charge the electric power from the 1st unit 30. FIG.

  On the other hand, when the EMS 80 determines that the output from the first power conditioner 33 of the first unit 30 is the maximum output (“YES” in step S21), the process of step S14 is performed again. In this case, it is assumed that the power output from each unit 30, 60, and 70 is insufficient with respect to the power consumption of the load. In such a state, when the power from the first unit 30 is charged in the power storage devices 62 and 72 of the units 60 and 70, the output of the power from the units to be charged is stopped, so the power consumption of the load However, it is not desirable because the power shortage increases. Therefore, when it determines in this way, EMS80 performs control which does not charge the electrical storage apparatus 62 * 72 of each unit 60 * 70 with the electric power from the 1st unit 30. FIG.

  In addition, the process of EMS80 assumes the case where it transfers to step S14 from step S21 again, and then transfers to step S16 * S18 * S19 * S20. In such a case, the EMS 80 increases the power output from the third unit 70 in order to charge the first power storage device 32 with the power generated by the first solar power generation device 31. Control can be performed. That is, when the power output from the third unit 70 increases, the proportion of power consumed by the load covered by the power from the first unit 30 can be reduced. Thereby, the electric power output from the first unit 30 can be reduced, and the electric power charged in the first power storage device 32 by the electric power generated by the first solar power generation device 31 can be increased.

  In addition, after step S22, it is during a power failure, but the power storage devices 62 and 72 of the units 60 and 70 are output from the first unit 30 (generated by the first solar power generation device 31). A process of charging using (electric power) is performed. Therefore, the EMS 80 performs the second simulation from the first pseudo interconnection mode in order to perform the interconnection operation in which the charging of the power storage devices 62 and 72 is not prohibited (permitted) at the time of a power failure. Switch the mode to the connected mode.

  In step S <b> 22, the EMS 80 receives a predetermined signal from the second power conditioner 63 of the second unit 60 to determine whether or not the second power storage device 62 of the second unit 60 can be charged. judge. Whether the second power storage device 62 of the second unit 60 can be charged is determined based on information acquired by the EMS 80 (specifically, whether the second power storage device 62 is fully charged). , Based on information such as whether the power consumption of the load can be covered by the power output from the units 30 and 70).

  Thus, when the EMS 80 determines that the second power storage device 62 of the second unit 60 can be charged (“YES” in step S22), the process of step S23 is performed.

  On the other hand, when the EMS 80 determines that the second power storage device 62 of the second unit 60 is not chargeable (“NO” in step S22), the EMS 80 performs the process of step S25.

  In step S25, the EMS 80 receives the predetermined signal from the third power converter 73 of the third unit 70, thereby determining whether or not the third power storage device 72 of the third unit 70 can be charged. judge. Whether or not the third power storage device 72 of the third unit 70 can be charged is determined based on the information acquired by the EMS 80 (specifically, whether the third power storage device 72 is fully charged). , Based on information such as whether the power consumption of the load can be covered by the power output from the units 30 and 60).

  Thus, when the EMS 80 determines that the third power storage device 72 of the third unit 70 can be charged (“YES” in step S25), the process of step S26 is performed.

  On the other hand, when the EMS 80 determines that the third power storage device 72 of the third unit 70 is not chargeable (“NO” in step S25), the process of step S14 is performed again.

  In step S23 transferred from step S22, as shown in FIG. 6, the EMS 80 uses the power output from the first unit 30 (power generated by the first solar power generation device 31) to use the second power. The second power storage device 62 of the unit 60 is charged. Specifically, the EMS 80 adjusts the amount of power to be charged in the second power storage device 62 of the second unit 60 by adjusting the amount of power output from the units 30 and 70.

  For example, the EMS 80 instructs the second power storage 63 of the second unit 60 so that the second power storage device 62 charges a predetermined amount of power. As a result, the amount of electric power output from the second unit 60 becomes zero, so that the EMS 80 has the units 30 and 70 to cover the shortage with respect to the power consumption of the load with the electric power from the units 30 and 70. Instruct the 70 to increase the amount of power output. When the amount of power charged by the second power storage device 62 of the second unit 60 is the same as the amount of power output from the first unit 30, the power consumption of the load is the third Covered by the power output from the unit 70.

  As described above, in step S23, the second pseudo interconnection mode is executed and the second power storage device 62 of the second unit 60 is charged at the time of a power failure, but is output from the units 30 and 70. By adjusting the amount of power, it is possible to avoid a situation where the amount of power supplied to the load decreases.

  In step S24, the EMS 80 determines whether or not the second power storage device 62 of the second unit 60 needs to be discharged.

  Thus, when the EMS 80 determines that the second power storage device 62 of the second unit 60 needs to be discharged (“YES” in step S24), the process of step S13 is performed again. That is, when the second power storage device 62 of the second unit 60 is fully charged, the EMS 80 discharges the power charged in the second power storage device 62 to thereby generate the first sunlight. The power generated by the power generation device 31 is efficiently used without being wasted. In this case, the EMS 80 uses the first pseudo interconnection mode from the second pseudo interconnection mode in order to perform the interconnection operation in which the charging of the power storage devices 62 and 72 is prohibited at the time of a power failure. Switch mode to mode.

  On the other hand, when the EMS 80 determines that the second power storage device 62 of the second unit 60 is not required to be discharged (“NO” in step S24), the process of step S23 is performed again. .

  In step S26 transferred from step S25, as shown in FIG. 7, the EMS 80 uses the power output from the first unit 30 (power generated by the first solar power generation device 31) to The third power storage device 72 of the unit 70 is charged. Specifically, the EMS 80 adjusts the amount of power to be charged in the third power storage device 72 of the third unit 70 by adjusting the amount of power output from the units 30 and 60.

  For example, the EMS 80 instructs the third power conditioner 73 of the third unit 70 so that the third power storage device 72 charges a predetermined amount of power. As a result, the amount of electric power output from the third unit 70 becomes zero, so that the EMS 80 has the units 30 and 60 to cover the shortage with respect to the power consumption of the load. Instruct 60 to increase the amount of power to be output. If the amount of power charged by the third power storage device 72 of the third unit 70 is the same as the amount of power output from the first unit 30, the power consumption of the load is Covered by power output from unit 60.

  In this way, in step S26, the second pseudo interconnection mode is executed and the third power storage device 72 of the third unit 70 is charged at the time of a power failure, but is output from the units 30 and 60. By adjusting the amount of power, it is possible to avoid a situation where the amount of power supplied to the load decreases.

  In step S27, the EMS 80 determines whether or not the third power storage device 72 of the third unit 70 needs to be discharged.

  Thus, when the EMS 80 determines that the second power storage device 62 of the second unit 60 needs to be discharged (“YES” in step S24), the process of step S13 is performed again. That is, when the second power storage device 62 of the second unit 60 is fully charged, the EMS 80 discharges the power charged in the second power storage device 62 to thereby generate the first sunlight. The power generated by the power generation device 31 is efficiently used without being wasted. In this case, the EMS 80 uses the first pseudo interconnection mode from the second pseudo interconnection mode in order to perform the interconnection operation in which the charging of the power storage devices 62 and 72 is prohibited at the time of a power failure. Switch mode to mode.

  On the other hand, when the EMS 80 determines that the third power storage device 72 of the third unit 70 does not need to be discharged (“NO” in step S27), the process of step S26 is performed again. .

As described above, the power supply system 1 according to the first embodiment
A distribution board 10 capable of supplying power from a commercial power supply 90 to a load;
Charge and discharge power from the first solar power generation device 31 (power generation device) capable of generating power using sunlight (natural energy), the first solar power generation device 31 (power generation device), and the commercial power supply 90 A first power storage device 32 that is possible, and a first power conditioner 33 (first power conditioner) that controls charging / discharging of the first power storage device 32, and is connected to the commercial power source 90 to provide the power distribution A first unit 30 capable of performing an interconnection operation for supplying power to the panel 10 and a self-sustaining operation for supplying power to the distribution board 10 independently of the commercial power supply 90;
A switching board 50 for switching the supply source of power supplied to the load to the commercial power supply 90 or the first unit 30;
A transformer 40 that boosts the voltage of power supplied from the first unit 30 to the distribution board 10 during the independent operation;
A second power storage device 62 / third power storage device 72 capable of charging / discharging electric power from the commercial power supply 90, and a second power source controlling the charge / discharge of the second power storage device 62 / third power storage device 72. Power unit 63 and third power conditioner 73 (second power conditioner) are arranged on the load side of the switching panel 50 to supply power to the distribution panel 10. Unit 70 (second unit);
A fourth sensor 24 (power failure detection unit) capable of detecting a power failure of the commercial power supply 90;
The detection result of the fourth sensor 24 (power failure detection unit) can be obtained, and the first power conditioner 33 (first power conditioner) of the first unit 30 is controlled to control the first power storage. The device 32 is charged and discharged, and the second power conditioner 63 and the third power conditioner 73 (second power conditioner) of the second unit 60 and the third unit 70 (second unit) are controlled. EMS 80 (control unit) for charging / discharging the second power storage device 62 and the third power storage device 72;
Comprising
When the fourth sensor 24 (power failure detection unit) detects a power failure of the commercial power supply 90, the EMS 80 (control unit) detects the second unit 60 and the second unit 60 according to the state of the first unit 30. Power failure mode (first pseudo interconnection mode and second pseudo interconnection) for controlling the second power conditioner 63 and the third power conditioner 73 (second power conditioner) of the third unit 70 (second unit) Mode).

  With such a configuration, when the first pseudo interconnection mode is executed in the event of a power failure, an interconnection operation in which charging of the power storage devices 62 and 72 is prohibited is performed. When the second pseudo interconnection mode is executed during a power failure, the second power storage device 62 of the second unit 60 (or the third power storage device 72 of the third unit 70) Although charging is performed, it is possible to avoid a situation where the amount of power supplied to the load decreases by adjusting the amount of power output from each unit 30 or 70 (or each unit 30 or 60). .

In addition, when the power failure mode (first pseudo interconnection mode and second pseudo interconnection mode) is executed,
Of the first unit 30, second unit 60, and third unit 70 (first and second units), from the second unit 60 and third unit 70 (second unit) The discharge is preferentially performed.

With such a configuration, power can be supplied from a plurality of units to the load in an appropriate order.
Specifically, when discharge is performed with priority from the first unit 30 among the first unit 30, the second unit 60, and the third unit 70, the second unit 60. The third unit 70 cannot appropriately perform the load following operation. On the other hand, when the discharge is performed preferentially from the second unit 60 and the third unit 70 among the first unit 30, the second unit 60, and the third unit 70, The second unit 60 and the third unit 70 can appropriately perform the load following operation. Thus, power can be supplied from a plurality of units to the load in an appropriate order.

In addition, when the power failure mode (first pseudo interconnection mode and second pseudo interconnection mode) is executed,
The EMS 80 (control unit)
The first power storage device 32 is fully charged, and the second power storage device 62 and the third power storage device 72 of the second unit 60 and the third unit 70 (second unit) are charged. When possible
Electric power generated by the first solar power generation device 31 (power generation device) of the first unit 30 is used as the second power storage of the second unit 60 and the third unit 70 (second unit). The device 62 and the third power storage device 72 are charged.

  With such a configuration, the power generated by the first solar power generation device 31 (power generation device) can be effectively used without being wasted.

The second unit 60 and the third unit 70 (second unit) are:
A plurality of distribution lines L1 (electric circuit) connecting the commercial power supply 90 and the load are arranged,
The EMS 80 (control unit)
Electric power generated by the first solar power generation device 31 (power generation device) of the first unit 30 is used as the second power storage of the second unit 60 and the third unit 70 (second unit). When charging the device 62 and the third power storage device 72,
Among the plurality of the second units 60 and the third unit 70 (second unit), charging is performed preferentially from the units arranged on the first unit 30 side.

With such a configuration, when output is performed from a plurality of units, it is possible to prevent the output from being inhibited.
Specifically, for example, when the output from the second unit 60 and the third unit 70 covers the power consumption of the load, the third unit 70 (unit placed on the load side) is given priority. When charging is performed, the output from the second unit 60 (unit arranged on the first unit 30 side) is hindered. On the other hand, it is possible to prevent the output from being inhibited by preferentially charging the second unit 60 (unit disposed on the first unit 30 side).

In addition, when the power failure of the commercial power supply 90 is resolved,
The EMS 80 (control unit) ends the power failure mode,
The first unit 30 performs the interconnection operation.

  With such a configuration, power can be appropriately supplied to the load during normal times.

  In step S21, the EMS 80 is arranged on the load side of the first unit 30 in order to determine whether or not the output from the first power converter 33 of the first unit 30 is the maximum output. It is possible to cause the units 60 and 70 to perform a mode in which only the power storage devices 62 and 72 are discharged and a mode in which no reverse power flow is performed. In other words, the EMS 80 can adjust the amount of power output from the units 60 and 70 and the amount of power input to the units 60 and 70 to obtain a desired power supply mode during a power failure.

In addition, the 1st solar power generation device 31 which concerns on this embodiment is one Embodiment of the power generation device which concerns on this invention.
The second unit 60 and the third unit 70 according to the present embodiment are an embodiment of the second unit according to the present invention.
The second power storage device 62 and the third power storage device 72 according to the present embodiment are an embodiment of the second power storage device according to the present invention.
Moreover, the 2nd power conditioner 63 and the 3rd power conditioner 73 which concern on this embodiment are one Embodiment of the 2nd power conditioner which concerns on this invention.
Moreover, EMS80 which concerns on this embodiment is one Embodiment of the control part which concerns on this invention.
Further, the first pseudo interconnection mode and the second pseudo interconnection mode according to the present embodiment are an embodiment of the power failure mode according to the present invention.

  As mentioned above, although 1st embodiment of this invention was described, this invention is not limited to the said structure, A various change is possible within the range of the invention described in the claim.

  For example, the application target of the power supply system 1 is not limited to a factory as in this embodiment. That is, the power supply system 1 can be applied to places other than the factory. Specifically, it can be applied to establishments and apartment houses.

  Moreover, EMS80 which concerns on this embodiment is a home server which is not shown in figure, the control part of the 1st power conditioner 33, the control part of the 1st electrical storage apparatus 32 (when the application object of the power supply system 1 is a house, for example) B) It may be configured by HEMS or the like provided in a house.

  The EMS 80 according to the present embodiment acquires information related to the occurrence of a power failure based on the detection result of the fourth sensor 24. For example, the EMS 80 is illustrated based on the detection result of the first sensor 21. Information related to the occurrence of a power outage may be acquired based on detection results of other sensors and information held by devices other than the sensors.

  In the present embodiment, the fourth sensor 24 is disposed on the upstream side of the connection portion of the distribution lines L1 and L2. As a result, the fourth sensor 24 can acquire information on the occurrence of a power failure by detecting the power at one location (not at the power at multiple locations). That is, in this embodiment, since it is not necessary to provide a plurality of sensors in order to acquire information related to the occurrence of a power failure, cost reduction can be achieved.

  Moreover, although the 1st solar power generation device 31 which concerns on this embodiment shall use sunlight as natural energy, you may utilize hydropower, a wind force, tidal power, etc.

  Moreover, although the switch board 50 which concerns on this embodiment was controlled by EMS80, you may control by other control parts (apparatus), such as the 1st power conditioner 33 of the 1st unit 30, for example.

  Further, the second unit 60 and the third unit 70 according to the present embodiment (that is, units other than the first unit 30 disposed on the most upstream side (commercial power supply 90 side)) are not only two. Three or four or more may be provided.

  Further, the second unit 60 and the third unit 70 according to the present embodiment (that is, units other than the first unit 30 disposed on the most upstream side (commercial power supply 90 side)) use natural energy. A power generating device capable of generating power may be provided. In the following, a power supply system having such a configuration (the power supply system 100 according to the second embodiment) will be described with reference to FIG.

  The configuration of the power supply system 100 according to the second embodiment shown in FIG. 8 is different from the configuration of the power supply system 1 according to the first embodiment in that the second unit 160 and the third unit according to the second embodiment are the same. The unit 170 is different from the second unit 60 and the third unit 70 according to the first embodiment in that it includes a solar power generation device.

  The second unit 160 is one of the sources of power to the load. The second unit 160 includes a second solar power generation device 61, a second power storage device 62, a second power conditioner 63, and the like. The second solar power generation device 61 is a device that generates power using sunlight. The second power conditioner 63 is connected to the second solar power generation device 61 and the second power storage device 62 through two different distribution lines. The configuration (how to move) of the second unit 160 is substantially the same as that of the first unit 30 according to the first embodiment.

  The third unit 170 is one of the sources of power to the load. The third unit 170 includes a third solar power generation device 71, a third power storage device 72, a third power conditioner 73, and the like. The third solar power generation device 71 is a device that generates power using sunlight. The third power conditioner 73 is connected to the third solar power generation device 71 and the third power storage device 72 via two different distribution lines. The configuration (how to move) of the third unit 170 is substantially the same as that of the first unit 30 according to the first embodiment.

  With such a configuration, in the power supply mode when the power failure mode is executed (that is, when there is a power failure), the situation where the amount of power supplied to the load at the time of the power failure decreases more reliably. be able to.

  Specifically, since the electric power generated by the second solar power generation device 61 and the third solar power generation device 71 can be used at the time of a power failure, for example, only the output from the first unit 30 is loaded. Even if a shortage occurs in the power consumption of the second solar power generation device 61 and the third solar power generation device 71 (or the second solar power generation device 61 and the first The electric power from the third solar power generation device 71 can be supplied to the load from the second power storage device 62 and the third power storage device 72) charged.

  In addition, for example, when the power consumption of the load is covered only by the power from the third unit 170 and surplus power is generated, the distribution line L1 flows to the commercial power supply 90 side. By charging the second power storage device 62 of the second unit 160 with the EMS 80, reverse power flow can be prevented. Similarly, for example, when the power consumption of the load is covered only by the power from the second unit 160 and the third unit 170 and surplus power is generated, the distribution line The reverse power flow can be prevented by charging the first power storage device 32 of the first unit 30 with the EMS 80 using the electric power flowing through the L1 to the commercial power supply 90 side.

DESCRIPTION OF SYMBOLS 1 Power supply system 10 Distribution board 30 1st unit 31 1st solar power generation device 32 1st electrical storage apparatus 33 1st power conditioner 40 transformer 60 2nd unit 62 2nd electrical storage apparatus 63 2nd power conditioner 70 Third unit 72 Third power storage device 73 Third power conditioner 80 EMS
90 Commercial power supply

Claims (5)

A distribution board that can supply power from a commercial power source to the load;
A power generation device capable of generating power using natural energy, a first power storage device capable of charging / discharging power from the power generation device and the commercial power source, and a first power for controlling charge / discharge of the first power storage device Including a conditioner, and performing an interconnected operation for supplying power to the distribution board in connection with the commercial power supply, and a self-sustaining operation for supplying power to the distribution board independently of the commercial power supply. The first unit that can
A switching board for switching the supply source of power supplied to the load to the commercial power source or the first unit;
A transformer that boosts the voltage of power supplied from the first unit to the distribution board during the independent operation;
Including a second power storage device capable of charging / discharging power from the commercial power source, and a second power conditioner for controlling charging / discharging of the second power storage device, and disposed on the load side of the switching board. A second unit for supplying power to the distribution board;
A power failure detection unit capable of detecting a power failure of the commercial power supply;
The detection result of the power failure detection unit can be acquired, the first power conditioner of the first unit is controlled to charge / discharge the first power storage device, and the second unit A controller that controls the second power conditioner to charge and discharge the second power storage device;
Comprising
When the power failure detection unit detects a power failure of the commercial power supply, the control unit executes a power failure mode for controlling the second power conditioner of the second unit according to the state of the first unit. ,
Power supply system. When the power failure mode is executed,
Among the first and second units, discharging is performed in preference to the second unit.
The power supply system according to claim 1. When the power failure mode is executed,
The controller is
When the first power storage device is fully charged and the second power storage device of the second unit can be charged,
Charging the second power storage device of the second unit with the power generated by the power generation device of the first unit;
The power supply system according to claim 1 or 2. The second unit is
A plurality of electric lines arranged between the commercial power source and the load,
The controller is
When charging the second power storage device of the second unit with the power generated by the power generation device of the first unit,
Among the plurality of second units, charging is performed preferentially from the units arranged on the first unit side.
The power supply system according to claim 1. When the commercial power supply blackout is resolved,
The control unit ends the power failure mode,
The first unit performs the interconnection operation.
The power supply system according to claim 1.

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