JP2022092693A - Power storage system - Google Patents

Abstract

To provide a power storage system that can reduce the number of signal lines connecting a power conditioner from which a switchgear is separated and a distribution board in which the switchgear is located.SOLUTION: A power storage system 1 has a current sensor unit 20 that detects reverse power flow, a function separation type distribution board 100 with a switchgear, and a power conditioner 200 from which the switchgear is separated. The current sensor unit 20 includes a current sensor 21 that monitors the U-phase current of the commercial power system, and a current sensor 22 that monitors the W-phase current of the commercial power system. The function separation type distribution board 100 includes a resistor 23 for terminating the current sensor 21 and a resistor 24 for terminating the current sensor 22. A ground-side terminal of the resistor 23 and a ground-side terminal of the resistor 24 are connected to a common ground line, and the common ground line is connected to the ground of the power conditioner 200.SELECTED DRAWING: Figure 2

Description

The present invention relates to a power storage system.

Generally, the power storage system is provided with a current sensor for monitoring reverse power flow and a switch for disconnecting the power conditioner from the commercial power system.
For example, a CT (Current Transformer) sensor is used as the current sensor, and the CT sensor is clamped to an electric wire of a commercial power system near an indoor distribution board. Then, the detection signal of the CT sensor is transmitted to the power conditioner, and the power conditioner monitors the reverse power flow.
Further, the switch is arranged inside the power conditioner. Then, in the event of a power failure or abnormality in the commercial power system, the power conditioner is disconnected from the commercial power system by this switch. (See, for example, Patent Documents 1 and 2).
On the other hand, a power storage system in which a switch is separated from the power conditioner and the switch is arranged in a distribution board has also been proposed.
In this type of power storage system, the opening / closing control of the switch is performed by connecting the control signal output from the power conditioner to the switch provided in the distribution board.
When constructing this type of power storage system, the distribution board is treated as one element that constitutes the power conditioner, so it is necessary to use a distribution board and a power conditioner with a predetermined combination. ..

Japanese Unexamined Patent Publication No. 2020-61848 Japanese Unexamined Patent Publication No. 2019-198203

However, in a power storage system that uses a power conditioner with a separate switch (function-separated power conditioner), a new signal line is provided to connect the function-separated power conditioner and the distribution board. There is a problem that the cost of the entire power storage system increases.
In addition, there are problems that the construction of the power storage system becomes complicated and construction mistakes increase due to the arrangement of new signal lines.

Therefore, the present invention has been made in view of the above-mentioned problems, and in a power storage system in which a power conditioner in which a switch is separated and a distribution board in which the switch is arranged are connected, cost reduction and construction are performed. It is an object of the present invention to provide a power storage system capable of facilitating the above.

Embodiment 1; One or more embodiments of the present invention is a power storage system including a current sensor unit, a distribution board, and a power conditioner, wherein the current sensor unit is a U phase of a commercial power system. The distribution board includes a first current sensor that detects a current flowing through the electric wire of the commercial power system and a second current sensor that detects a current flowing through the W-phase electric wire of the commercial power system. Opening and closing that connects the commercial power system and the power conditioner when interconnected with the commercial power system, while disconnecting the power conditioner from the commercial power system during non-grid interconnection that is not connected to the commercial power system. A unit, a first termination resistor for terminating the first current sensor, and a second termination resistor for terminating the second current sensor, the ground-side terminal of the first termination resistor and the said. We propose a power storage system characterized in that the ground side terminal of the second termination resistor is connected to a common ground line and the common ground line is connected to the ground of the power conditioner. ..

According to this configuration, since the first and second terminating resistors are arranged in the distribution board, the ground side terminals of the first and second current sensors can be shared by a common ground line. .. Then, since the common ground line is connected to the ground of the power conditioner, when the first and second terminating resistors are arranged in the power conditioner (in this case, the first and second in the distribution board). It is necessary to route at least two ground lines from the second current sensor toward the power conditioner), and the number of signal lines connecting the distribution board and the power conditioner can be reduced.
Therefore, the cost of the power storage system can be reduced and the construction can be facilitated.

Form 2; The power conditioner includes a current monitoring unit to which a detection signal of the current sensor unit is input and monitors the reverse current, and the common ground line is connected to the ground of the current monitoring unit. The detection signals of the first and second current sensors are input to the ground side terminals of the first and second termination resistors via one common ground line connecting the distribution board and the power conditioner. It can be connected to the ground of the current monitoring unit.

Form 3; During the non-grid interconnection, power is supplied from the self-sustaining output of the power conditioner to all the loads regardless of the important load and the general load other than the important load via the distribution board. It is supposed to be. According to this configuration, in the event of an abnormality such as a power failure of a commercial power system, power can be supplied to all loads without distinguishing between a critical load and a load other than the critical load.

Form 4; By disposing the current sensor unit in the distribution board, it is possible to prevent the occurrence of mounting errors during construction. That is, if the current sensor unit is outside the distribution board, the contractor needs to install the current sensor, but if the current sensor unit is incorporated in the distribution board as a product in advance, it eliminates enforcement mistakes during construction. be able to.

Form 5; The ground-side terminal of the opening / closing portion is connected to the common ground line. Therefore, the ground line of the opening / closing section and the ground line of the current sensor section can be shared. Therefore, it is possible to reduce the number of signal lines connecting the distribution board and the power conditioner, and reduce the cost of the power storage system.

In the power storage system where the switch is separated from the power conditioner and arranged in the distribution board, the number of signal lines connecting the distribution board and the power conditioner is reduced, and the cost of the power storage system is reduced and construction is easy. Can be.

It is a system block diagram of the power storage system which concerns on 1st Embodiment of this invention. It is a circuit diagram of the current sensor and the current monitoring unit of the power storage system which concerns on 1st Embodiment of this invention. It is a figure which shows the relationship between the arrangement position of the terminating resistor which terminates the current sensor of the electricity storage system which concerns on 1st Embodiment of this invention, and the current detection value. It is a system block diagram of the power storage system which concerns on the 2nd Embodiment of this invention. It is a circuit diagram of the current sensor unit and the current monitoring unit of the power storage system according to the second embodiment of the present invention.

[First Embodiment]
Hereinafter, the power storage system 1 according to the first embodiment will be described with reference to FIGS. 1 to 3.

<System configuration of power storage system 1>
As shown in FIG. 1, the power storage system 1 includes a multifunctional power storage system (a solar power conditioner connected to a solar cell module, a power storage power conditioner connected to a storage battery unit, and an electric vehicle such as an electric vehicle. It is a power storage system that integrates a connected charge / discharge power conditioner), and is a function-separated distribution board 100, a power conditioner 200, a storage battery unit 300, a solar cell module 350, and an electric vehicle 410. It is configured to include a V2H (Vehicle to Home) stand 400 connected to a general distribution board 500 and a general distribution board 500.

The function-separated distribution board 100 switches between the system power from the commercial power system and the power output from the power conditioner 200 (hereinafter referred to as “PCS output power”), and the important load is passed through the general distribution board 500. Power all household loads without distinguishing between and general loads other than critical loads.
Here, the grid power includes only commercial power, or includes commercial power and power from equipment connected to the commercial power.
Further, the PCS output power is applied to the DC power stored in the storage battery unit 300 by the power conditioner 200, the DC power (generated power) based on the power generated by the solar cell module 350, and / or the electric vehicle 410 when the commercial power system is abnormal. This is the power that converts the stored DC power into AC power and outputs it to the function-separated distribution board 100.

The power conditioner 200 can be connected to a storage battery unit 300, a solar cell module 350 that generates electricity by sunlight, and an electric vehicle 410 that has a function of supplying power to the outside via a V2H stand 400.
The power conditioner 200 controls the grid power by executing grid interconnection protection, maximum power tracking control, and the like.
Further, when the commercial power system is abnormal, the DC power stored in the storage battery unit 300, the DC power based on the power generated by the solar cell module 350 (generated power), and / or the DC power stored in the storage battery of the electric vehicle 410 are used as AC power. And supplies AC power to the function-separated distribution board 100 as an independent output.

For example, a lithium ion battery is used in the storage battery unit 300, and electric power is charged and discharged under the control of the power conditioner 200.
The solar cell module 350 has a plurality of solar cell cells arranged and protected by glass, resin, or a frame, and is generally called a solar panel or a solar cell panel.

The V2H stand 400 includes a converter unit 401.
The converter unit 401 is a bidirectional converter that converts the DC power from the in-vehicle storage battery mounted on the electric vehicle 410 into voltage and supplies the DC power to the inverter unit 220, while the DC power supplied from the inverter unit 220. Is supplied as charging power to the in-vehicle storage battery.
As the bidirectional converter, for example, a buck-boost chopper type converter can be exemplified.

The general distribution board 500 supplies the electric power supplied from the function-separated distribution board 100 to all the loads without distinguishing between the important load and the general load other than the important load.

The function-separated distribution board 100 includes a current sensor unit 20, an earth leakage breaker 30, an opening / closing unit 40, and an automatic changeover switch 50. When a contract breaker or the like (not shown) is installed in the system wiring connected to the commercial power system, the contract breaker or the like is arranged on the upstream side of the current sensor unit 20. In this case, the contract breaker or the like may be provided inside the function-separated distribution board 100, or may be provided outside the function-separated distribution board 100.

The current sensor unit 20 is a sensor that detects the direction and the current value of the current flowing through the system wiring.
The details of monitoring the reverse power flow including the current sensor unit 20 will be described later.

The earth leakage breaker 30 is connected to a commercial power system via system wiring, operates when an earth leakage, an overcurrent, or the like is detected, and opens an electric circuit.

The opening / closing unit 40 is connected to the commercial power system via the earth leakage breaker 30 and the system wiring.
The switching unit 40 connects the commercial power system and the power conditioner 200 when the system is connected to the commercial power system, while the power conditioner 200 is used for commercial use when the power conditioner 200 is not connected to the commercial power system. Disconnect from the power system.
Specifically, when the power conditioner 200 detects a power failure in the commercial power system, the switching unit 40 is controlled by a control signal output from the power conditioner 200, and the power conditioner 200 is disconnected from the commercial power system. Then, electric power (PCS output electric power) is supplied from the power conditioner 200 toward the function-separated distribution board 100 (further load) as an independent output.

Further, when the power conditioner 200 detects that the commercial power system has been restored, the power conditioner 200 stops the PCS output power. Then, the opening / closing unit 40 is controlled by the control signal, and the power conditioner 200 is connected to the commercial power system.
Here, as the opening / closing unit 40, for example, an electromagnetic switch can be exemplified, but if the opening / closing unit 40 can be controlled by the power conditioner 200, a relay or the like may be used instead.

The automatic changeover switch 50 is a switch that switches the power supplied to the general distribution board 500 to either system power or PCS output power. The switch is automatically switched to the grid power side at the time of grid interconnection and to the PCS output power side at the time of non-grid cooperation such as a power failure.

The power conditioner 200 includes a PCS control unit 210, an inverter unit 220, a converter unit 230, 231 and a current monitoring unit 240. Further, the storage battery unit 300, the solar cell module 350, and the V2H stand 400 are connected to the power conditioner 200.
The configuration of the power conditioner 200 described below is an example, and other configurations may be used as long as they can perform the same function.

The PCS control unit 210 includes a monitoring unit 270 and an open / close control unit 280.
Here, the PCS control unit 210 is a part of the CPU function, and controls the entire power conditioner 200 according to a control program stored in a ROM (Read Only Memory) or the like.
For example, the PCS control unit 210 executes control for charging the storage battery unit 300 with the power generated by the solar cell module 350, reverse power flow control for outputting AC power to the commercial power system, and the like.
Further, in the event of an abnormality in the commercial power system, the PCS control unit 210 uses the power stored in the storage battery unit 300, the power generated from the solar cell module 350, and / or the power stored in the in-vehicle storage battery mounted on the electric vehicle 410. Execute the self-sustaining output control used.

The inverter unit 220 converts the generated power of the solar cell module 350 into AC power, and also converts the DC power of the in-vehicle storage battery arranged in the storage battery unit 300 or the electric vehicle 410 into AC power. Further, in order to charge the in-vehicle storage battery arranged in the storage battery unit 300 and / or the electric vehicle 410, commercial power is converted into DC power.
The converter unit 230 converts the DC power from the solar cell module 350 into boosted DC power.
The converter unit 231 converts the DC power from the storage battery unit 300 into boosted DC power.
The converter unit 231 charges the DC power obtained by converting the commercial power converted into DC power by the inverter unit 220 into a predetermined DC voltage, and the DC power from other sources such as the solar cell module 350 and the electric vehicle 410. It is a bidirectional converter that supplies electric power to the storage battery unit 300.

The current monitoring unit 240 includes an amplification unit 250 and a monitoring unit 270.
The amplification unit 250 amplifies the detection signal of the current sensor unit 20 and outputs it to the monitoring unit 270.
The monitoring unit 270 is a part of the function of the PCS control unit 210, and monitors the state of reverse power flow of the power storage system 1 based on the detection signal input from the amplification unit 250.
Then, the PCS control unit 210 controls the entire power conditioner 200 based on the current state detected by the monitoring unit 270.
The detailed circuit of the current monitoring unit 240 will be described later.

The open / close control unit 280 is a part of the function of the PCS control unit 210, and executes control to disconnect the power conditioner 200 from the commercial power system when the PCS control unit 210 detects a power failure of the commercial power. Further, when the PCS control unit 210 detects the recovery of the commercial power, the power conditioner 200 is controlled to be connected to the commercial power system.
Specifically, the open / close section 40 is controlled to open / close by the control signal output from the open / close control unit 280, and the commercial power system and the power conditioner 200 are connected during grid interconnection, while the power conditioner is connected during non-grid interconnection. The Na 200 is disconnected from the commercial power system.

The general distribution board 500 includes a main circuit breaker 510 and a branch circuit breaker 520.
The system power or PCS output power supplied from the function-separated distribution board 100 is input to the main breaker 510, and for example, a circuit on the secondary side (load, electric circuit, etc.) due to factors such as electric leakage, overload, and short circuit. It operates when an abnormal overcurrent flows to open the electric circuit.
The branch breaker 520 branches the system power or the PCS output power supplied through the main breaker 510, and supplies power to household loads such as lighting, refrigerators, and washing machines.
Further, the branch breaker 520 operates when an abnormal overcurrent flows due to a failure of the connected household load or the like to open the electric circuit.

<Circuit configuration of current sensor unit 20 and current monitoring unit 240>
Hereinafter, the circuit configuration of the current sensor unit 20 and the current monitoring unit 240 will be described with reference to FIG.
<Circuit configuration of current sensor unit 20>

The current sensor unit 20 includes a current sensor 21 (first current sensor) and a current sensor 22 (second current sensor).

The current sensor 21 is attached to a U-phase electric wire of a commercial power system and is connected to a resistor 23 (first terminating resistor) that terminates the current sensor 21.
The current sensor 22 is attached to a W-phase electric wire of a commercial power system and is connected to a resistor 24 (second terminating resistor) that terminates the current sensor 22.
Here, as the current sensor 21 and the current sensor 22, for example, a CT sensor can be exemplified.
The current sensor 21, the current sensor 22, the resistor 23, and the resistor 24 are arranged inside the housing of the function-separated distribution board 100.

One end of the resistor 23 is connected to the current monitoring unit 240 provided in the power conditioner 200 via a cable 150 connecting the function-separated distribution board 100 and the power conditioner 200.
One end of the resistor 24 is connected to the current monitoring unit 240 provided in the power conditioner 200 via a cable 150 connecting the function-separated distribution board 100 and the power conditioner 200.
The other end of the resistor 23 (ground side terminal) and the other end of the resistor 24 (ground side terminal) are connected, and are also connected to the ground of the current monitoring unit 240 in the power conditioner 200 via the cable 150. ..
The cable 150 is a multi-core cable that connects the detection signal of the current sensor unit 20 to the current monitoring unit 240. A signal line other than the detection signal of the current sensor unit 20 may be added to the cable 150 to connect the function-separated distribution board 100 and the power conditioner 200.
For example, since the opening / closing control signal, the welding detection signal, and the like of the opening / closing unit 40 need to be connected to the power conditioner 200, they may be connected via the cable 150.

<Circuit configuration of current monitoring unit 240>
The current monitoring unit 240 includes an amplification unit 250 and a monitoring unit 270.
The amplification unit 250 amplifies the detection signals of the current sensor 21 (first current sensor) and the current sensor 22 (second current sensor), and outputs the signals to the monitoring unit 270.
One end of the resistor 23 (first terminating resistor) is connected to one end of the resistor 253 via a cable 150.
The other end of the resistor 23 is connected to one end of the resistor 251 and the ground line of the monitoring unit 270 via the cable 150.
One end of the resistor 24 (second terminating resistor) is connected to one end of the resistor 258 via a cable 150.
The other end of the resistor 24 is connected to one end of the resistor 256 and the ground line of the monitoring unit 270 via the cable 150.

The resistors 251 to 254 and the operational amplifier 255 are components constituting a differential amplifier circuit that amplifies the detection signal of the current sensor 21 (first current sensor).
The other end of the resistor 251 is connected to one end of the resistor 252 and the negative input terminal of the operational amplifier 255.
The other end of the resistor 252 is connected to the output terminal of the operational amplifier 255 and the monitoring unit 270.
The other end of the resistor 253 is connected to one end of the resistor 254 and the positive input terminal of the operational amplifier 255.
The other end of the resistor 254 is connected to the operating reference voltage (REF voltage) of the operational amplifier 255.

The resistors 256 to 259 and the operational amplifier 260 are components constituting a differential amplifier circuit that amplifies the detection signal of the current sensor 22 (second current sensor unit).
The other end of the resistor 256 is connected to one end of the resistor 257 and the negative input terminal of the operational amplifier 260.
The other end of the resistor 257 is connected to the output terminal of the operational amplifier 260 and the monitoring unit 270.
The other end of the resistor 258 is connected to one end of the resistor 259 and the positive input terminal of the operational amplifier 260.
The other end of the resistor 259 is connected to the operation reference voltage (REF voltage) of the operational amplifier 260.
Here, the differential amplifier circuit has been described as an example as a circuit for amplifying the detection signal of the current sensor, but a configuration using an inverting amplifier circuit, a non-inverting amplifier circuit, or the like may be used.

The monitoring unit 270 performs A / D conversion of the detection signal amplified by the amplification unit 250 to capture a voltage value, and monitors the state of reverse power flow based on the captured voltage value.
<Relationship between the arrangement position of the current sensor and the current detection value>

Hereinafter, the relationship between the arrangement position of the current sensor unit 20 and the detected current value of the monitoring unit 270 will be described with reference to FIG.

FIG. 3A shows a cable of 10 m between the function-separated distribution board 100 in which the current sensor 21 (first current sensor) and the current sensor 22 (second current sensor) are arranged and the power conditioner 200. The current detected by the monitoring unit 270 when the resistor 23 (first termination resistor) and the resistor 24 (second termination resistor) are arranged in the function-separated distribution board 100 or the power conditioner 200. It is a graph showing the value.

The solid line in FIG. 3A shows the current value detected by the monitoring unit 270 when the resistance 23 and the resistance 24 are arranged on the function-separated distribution board 100 and the power consumption of the load is changed. It is a graph.
The broken line in FIG. 3A is a graph showing the current value detected by the monitoring unit 270 when the resistor 23 and the resistor 24 are arranged in the power conditioner 200 and the power consumption of the load is changed. ..
As shown in FIG. 3A, it can be seen that the current value detected by the monitoring unit 270 does not change even if the positions where the resistors 23 and the resistors 24 are arranged change.

FIG. 3B shows a monitoring unit when the length of the cable connecting the function-separated distribution board 100 in which the current sensor 21 and the current sensor 22 are arranged and the power conditioner 200 is changed. It is a graph which showed the current value detected by 270. At this time, in order to confirm the influence of the power consumption of the load as well, the power consumption of the load is changed from 1 kW to 6 kW, and the current value is detected.
As shown in FIG. 3B, the length of the cable was changed from 10 m to 40 m, but it can be seen that the current value detected by the monitoring unit 270 is constant without being affected by the length of the cable. It can also be seen that even if the power consumption of the load changes, the current value detected by the monitoring unit 270 is constant without being affected by the length of the cable.

This indicates that the impedance of the cable is sufficiently small with respect to the impedance of the input unit of the amplification unit 250, so that the detected current value is not affected.
Therefore, it can be seen that there is no problem in the current detection performance of the monitoring unit 270 even if the resistance 23 and the resistance 24 are arranged in the function-separated distribution board 100.

(Action effect)
As described above, the power storage system 1 according to the present embodiment includes a function-separated distribution board 100 provided with an opening / closing portion and a power conditioner 200 having an opening / closing portion separated. The function-separated distribution board 100 includes a current sensor unit 20 for detecting reverse power flow. Further, the current sensor unit 20 includes a current sensor 21 (first current sensor) that monitors the U-phase current of the commercial power system, and a current sensor 22 (second current) that monitors the W-phase current of the commercial power system. Sensor) and. Further, the function-separated distribution board 100 has a resistor 23 (first termination resistor) for terminating the current sensor 21 (first current sensor) and a resistor 24 (second current sensor) for terminating the current sensor 22 (second current sensor). A second terminating resistor). Then, the ground-side terminal of the resistor 23 (first terminating resistor) and the ground-side terminal of the resistor 24 (second terminating resistor) are the same connected to the ground of the current monitoring unit 240 provided in the power conditioner 200. It is connected to the ground line.

Here, in a general power storage system, the terminating resistance of the current sensor is arranged on the power conditioner side. In the power storage system in which the terminating resistor is arranged on the power conditioner side in this way, the detection signals of the two current sensors that detect the U-phase and W-phase currents are transmitted to the power conditioner by four signal lines. To.

On the other hand, in the present invention, the resistor 23 (first terminating resistor) and the resistor 24 (second terminating resistor) are arranged in the function-separated distribution board 100.

According to the power storage system 1 in which the resistor 23 (first terminating resistor) and the resistor 24 (second terminating resistor) are arranged in the function-separated distribution board 100, the resistor 23 (first terminating resistor) is provided. ) And the ground side terminal of the resistor 24 (second terminating resistor) can be connected to the same ground line connected to the ground of the current monitoring unit 240 provided in the power conditioner 200.
As a result, the number of signal lines connecting the function-separated distribution board 100 and the power conditioner 200 can be reduced to three, so that the number of signal lines can be reduced by one as compared with the above-mentioned general power storage system. can.
Therefore, the number of signal lines connecting the distribution board and the power conditioner can be reduced.

Further, since one long electric wire connecting the function-separated distribution board 100 installed in the home and the power conditioner 200 installed outside the home can be deleted, the cost of the cable 150 is reduced. can do.
Further, by reducing the number of signal lines, the number of connection terminals of the connector for connecting the function-separated distribution board 100 and the power conditioner 200 can be reduced, so that the function-separated distribution board 100 and The cost of the power conditioner 200 can be reduced.
By reducing the number of signal lines, the cable can be made thinner, so that the cost of the cable can be reduced. Further, since the cable can be made thinner and lighter, the cable laying work in the construction of the power storage system can be performed more easily.

Further, in the present embodiment, the current sensor 21 (first current sensor) and the current sensor 22 (second current sensor) can be arranged inside the housing of the function-separated distribution board 100, so that the function-separated type can be arranged. In the production process of the distribution board 100, the current sensor 21 (first current sensor) and the current sensor 22 (second current sensor) can be attached.
That is, at the time of factory shipment of the function-separated distribution board 100, the current sensor 21 (first current sensor) and the current sensor 22 (second current sensor) are attached.
Therefore, since the work of mounting the current sensor does not occur at the time of construction of the power storage system, it is possible to eliminate construction defects such as an error in the mounting direction of the current sensor and an error in the installation location of the current sensor.

[Second Embodiment]
Hereinafter, the power storage system 1A according to the second embodiment will be described with reference to FIGS. 4 and 5.
The power storage system 1A is a power storage system in which the function-separated distribution board 100 of the power storage system 1 according to the first embodiment is modified.
The function-separated distribution board 100 of the power storage system 1 supplied power to all household loads without distinguishing between important loads and general loads other than important loads in the event of an abnormality such as a power failure in the commercial power system. The function-separated distribution board 100a of the power storage system 1A supplies electric power only to important loads.
In the second embodiment, the same components or substantially the same components as the components of the power storage system 1 according to the first embodiment are designated by the same reference numerals, and duplicate description will be omitted. ..

<System configuration of power storage system 1A>
As shown in FIG. 4, the power storage system 1A includes a current sensor unit 20a, a function-separated distribution board 100a, a switching switch 70, an earth leakage breaker 80, a branch breaker 90, a power conditioner 200a, and a storage battery. It includes a unit 300, a solar cell module 350, a V2H stand 400 connected to an electric vehicle 410, and a general distribution board 500a.
The function-separated distribution board 100a includes an earth leakage breaker 30 and an opening / closing portion 40.
Further, the general distribution board 500a includes a main breaker 510a and a branch breaker 520a.

The commercial power system is connected to the earth leakage breaker 30 of the function-separated distribution board 100a and the main breaker 510a of the general distribution board 500a via system wiring.
The current sensor unit 20a is a sensor that detects the direction and the current value of the current flowing through the system wiring.
The details of the reverse power flow monitoring circuit including the current sensor unit 20a will be described later.

In the switching switch 70, system power or PCS output power is supplied from the function-separated distribution board 100a to supply power to an important load.
Here, the switching switch 70 is a switch that can be switched when the power conditioner 200a is maintained. Therefore, during maintenance of the power conditioner 200a, system power is supplied to the critical load via the general distribution board 500a.

The earth leakage breaker 80 operates when power is supplied from the switching switch 70 and an overcurrent due to an earth leakage or the like is detected, and the electric circuit is opened.
The branch breaker 90 branches the system power or the PCS output power supplied through the earth leakage breaker 80 to supply power to the critical load.
Further, the branch breaker 90 operates when an abnormal overcurrent flows due to a failure of the connected critical load or the like to open the electric circuit.

A commercial power system is connected to the general distribution board 500a to supply power to a general load. Therefore, in the event of a power failure in the commercial power system, power is not supplied to the general load.
The main circuit breaker 510a is connected to a commercial power system and operates when an abnormal overcurrent flows through a secondary circuit (load, electric circuit, etc.) due to factors such as electric leakage, overload, or short circuit, and the electric circuit is operated. To open.

The system power supplied via the main breaker 510a is connected to the switching switch 70 and the branch breaker 520a.
The branch breaker 520a branches the system power supplied via the main breaker 510a, and supplies power to a general load other than the important load.
Further, the branch breaker 520a operates when an abnormal overcurrent flows due to a failure of a general load other than the connected important load, and opens the electric circuit.

<Circuit configuration of current sensor unit 20a>
Hereinafter, the circuit configuration of the current sensor unit 20a will be described with reference to FIG.

In the power storage system 1A, since the power supply path to the important load and the power supply path to the general load are different, the current sensor unit 20a cannot be arranged in the function-separated distribution board 100a.
Therefore, the current sensor unit 20 of the power storage system 1 described above is arranged in the function-separated distribution board 100, but the current sensor unit 20a of the power storage system 1A is, for example, an electric wire (system wiring) near the commercial power system. It is arranged in.

The current sensor unit 20a includes a current sensor 21a (first current sensor) and a current sensor 22a (second current sensor).
The current sensor unit 20a is connected to the function-separated distribution board 100a by a cable 160 including four signal lines.

The current sensor 21a is attached to a U-phase electric wire of a commercial power system and is connected to a resistor 23 (first terminating resistor) that terminates the current sensor 21a.
The current sensor 22a is attached to a W-phase electric wire of a commercial power system and is connected to a resistor 24 (second terminating resistor) that terminates the current sensor 22a.
The resistance 23 and the resistance 24 are arranged on the function-separated distribution board 100a.

One end of the resistor 23 is connected to the current monitoring unit 240 provided in the power conditioner 200a via a cable 150a connecting the function-separated distribution board 100a and the power conditioner 200a.
One end of the resistor 24 is connected to the current monitoring unit 240 provided in the power conditioner 200a via a cable 150a connecting the function-separated distribution board 100a and the power conditioner 200a.
The other end of the resistor 23 and the other end of the resistor 24 are connected, and are also connected to the ground of the current monitoring unit 240 in the power conditioner 200a via the cable 150a.

(Action effect)
As described above, the power storage system 1A according to the present embodiment has a current sensor unit 20a for detecting reverse power flow, a function-separated distribution board 100a provided with an opening / closing unit, and a power with the opening / closing unit separated. It is equipped with a conditioner 200a. Further, the current sensor unit 20a includes a current sensor 21a (first current sensor) that monitors the U-phase current of the commercial power system and a current sensor 22a (second current) that monitors the W-phase current of the commercial power system. Sensor) and. Further, the function-separated distribution board 100a has a resistor 23 (first termination resistor) that terminates the current sensor 21a (first current sensor) and a resistor 24 (second current sensor) that terminates the current sensor 22a (second current sensor). A second terminating resistor). Then, the ground-side terminal of the resistor 23 (first terminating resistor) and the ground-side terminal of the resistor 24 (second terminating resistor) are the same connected to the ground of the current monitoring unit 240 provided in the power conditioner 200a. It is connected to the ground line.

According to the power storage system 1A in which the resistor 23 (first terminating resistor) and the resistor 24 (second terminating resistor) are arranged in the function-separated distribution board 100a, the resistor 23 (first terminating resistor) is provided. ) And the ground side terminal of the resistor 24 (second terminating resistor) can be connected to the same ground line connected to the ground of the current monitoring unit 240 provided in the power conditioner 200a.
As a result, the number of signal lines connecting the function-separated distribution board 100a and the power conditioner 200a can be reduced to three, so that the number of signal lines can be reduced by one.
Therefore, the number of signal lines connecting the distribution board and the power conditioner can be reduced.

Further, since one long electric wire connecting the function-separated distribution board 100a installed in the home and the power conditioner 200a installed outside the home can be deleted, the cost of the cable 150a is reduced. can do.
Further, by reducing the number of signal lines, the number of connection terminals of the connector connecting the function-separated distribution board 100a and the power conditioner 200a can be reduced. Therefore, the function-separated distribution board 100a and The cost of the power conditioner 200a can be reduced.
By reducing the number of signal lines, the cable can be made thinner and the cost of the cable can be reduced. Further, since the cable can be made thinner and lighter, the cable laying work in the construction of the power storage system can be performed more easily.

As shown in FIGS. 2 and 5, the ground side terminal of the switching portion 40, the ground side terminal of the resistor 23 (first terminating resistor), and the ground side terminal of the resistor 24 (second terminating resistor) are connected. There is. Further, the ground of the current monitoring unit 240 and the ground line of the open / close control unit 280 are connected.
As a result, the ground side terminal of the resistor 23, the ground side terminal of the resistor 24, and the ground side terminal of the switching unit 40 are shared, and the number of signal lines connecting the distribution board and the power conditioner is reduced by one. can do.
Therefore, the number of signal lines connecting the distribution board and the power conditioner can be reduced.
As a result, the number of connection terminals of the connector for connecting the distribution board and the power conditioner can be reduced, so that the cost of the power storage system can be further reduced.

[Other embodiments]
The power storage system 1 and the power storage system 1A described above include a multifunctional power storage system (a solar power conditioner connected to a solar cell module, a power storage power conditioner connected to a storage battery unit, and charging / discharging connected to an electric vehicle. An example of a power storage system that integrates a power conditioner) has been described, but a single-function power storage system (a power storage system that uses only a storage battery with a separate solar power conditioner) and a hybrid power storage system (for a solar cell module). It may be a power storage system that integrates a connected solar power conditioner and a power storage power conditioner connected to the storage battery unit).

In the case of a power storage system in which the solar power conditioner connected to the solar cell module is separated from the multifunctional power storage system and the solar power conditioner is separately disposed, in addition to the current sensor for reverse power flow monitoring. In addition, it is necessary to newly install a current sensor for monitoring the output of the photovoltaic power conditioner.
The termination resistance of the current sensor for output monitoring of the solar power conditioner is arranged in the function-separated distribution board, and the grounding end of the termination resistance of the current sensor for output monitoring and the termination of the current sensor for reverse power flow monitoring. By connecting to the grounded end of the resistor, the number of signal lines connecting the function-separated distribution board and the power conditioner can be reduced by one.
Further, in the case of a power storage system that requires a plurality of current sensors, a terminating resistor connected to each current sensor may be arranged inside the housing of the function-separated distribution board to construct the power storage system. ..
As a result, the number of signal lines connecting the function-separated distribution board and the power conditioner can be reduced, so that the cost of the power storage system can be further reduced.

Although the embodiments of the present invention have been described in detail with reference to the drawings, the specific configuration is not limited to this embodiment, and includes designs and the like within a range that does not deviate from the gist of the present invention.

1,1A; Power storage system 20: Current sensor unit 30; Earth leakage breaker 40; Opening / closing unit 50; Automatic changeover switch 70; Switching switch 80; Earth leakage breaker 90; Branch breaker 100; Function-separated distribution board 200; Power conditioner 210; PCS control unit 220; inverter unit 230; converter unit 231; converter unit 240; current monitoring unit 250; amplification unit 270; monitoring unit 280; switch control unit 300; storage battery unit 350; solar cell module 400; V2H stand 401; Converter section 410; Electric vehicle 500; General distribution board 510; Main breaker 520; Branch breaker

Claims (5)

A power storage system that includes a current sensor, a distribution board, and a power conditioner.
The current sensor unit is
The first current sensor that detects the current flowing through the U-phase electric wire of the commercial power system, and
A second current sensor that detects the current flowing through the W-phase electric wire of the commercial power system, and
Including
The distribution board
While the commercial power system and the power conditioner are connected when the grid is connected to the commercial power system, the power conditioner is connected to the commercial power when the power conditioner is not connected to the commercial power system. The opening and closing part that separates from the system,
The first terminating resistor that terminates the first current sensor,
A second terminating resistor that terminates the second current sensor,
Including
The ground-side terminal of the first terminating resistor and the ground-side terminal of the second terminating resistor are connected to a common ground line, and the common ground line is connected to the ground of the power conditioner. A power storage system characterized by this. The power conditioner includes a current monitoring unit to which a detection signal of the first current sensor and the second current sensor is input and monitors reverse power flow.
The power storage system according to claim 1, wherein the common ground line is connected to the ground of the current monitoring unit. A claim characterized in that, during the non-system interconnection, power is supplied from the self-sustaining output of the power conditioner to all loads regardless of the critical load and the general load other than the critical load via the distribution board. Item 2. The power storage system according to Item 1 or 2. The power storage system according to any one of claims 1 to 3, wherein the current sensor unit is arranged in the distribution board. The power storage system according to any one of claims 1 to 4, wherein the ground-side terminal of the opening / closing portion is connected to the common ground line.

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