JP2017127137A - Switch box and power supply system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a switch box which allows for simplification of the wiring work.SOLUTION: A breaker box 13 includes a main earth leakage breaker 2 connecting the power lead-in wiring for connection with a commercial system 1, a maintenance breaker 3 for connecting or disconnecting the main earth leakage breaker 2 and an EV-PCS6, a switcher 7a connecting the main earth leakage breaker 2 and a home load 30, or connecting the EV-PCS6 and home load 30, a switcher 7b connecting the EV-PCS6 and PV-PCS12, or connecting the PV-PCS12 and home load 30, a PV-PCS breaker 14 connecting the wiring for connection with the PV-PCS12, and an enclosure 18 for housing the main earth leakage breaker 2, maintenance breaker 3, switcher 7a, switcher 7b and PV-PCS breaker 14.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a switch box and a power supply system.

  In recent years, electric power supplied from a solar power generation facility or electric power supplied in a time zone when electricity charges at midnight are cheap are charged to a stationary storage battery or a storage battery mounted on an electric vehicle (EV), A power supply system that supplies electric energy charged in a storage battery to an in-house load during the morning, evening, or daytime when the electricity rate is high is becoming widespread.

  In the power supply system, since the electric power stored in the storage battery is supplied to the home load at the time of a power failure in the commercial system, the home load can be used even at the time of the power failure.

  Patent Document 1 discloses a power supply that supplies power equivalent to the power supplied to the home load when the commercial system is not out of power even during a self-sustained operation that discharges the power stored in the storage battery in the event of a power outage. A device has been proposed.

  The power supply device described in Patent Document 1 supplies power to the home load using power supplied from the commercial system and power stored in the storage battery while being connected to the commercial system, and the commercial system has lost power. In this case, electric power can be continuously supplied from the commercial grid connection to the in-house load in use.

  Moreover, in the power supply device described in Patent Document 1, the first terminal to which the commercial system is connected via the residential distribution board and the second load to which the residential load is connected via the residential distribution board. Charge and discharge to the storage battery connected to the storage battery with a terminal, a commercial system voltage monitoring means for monitoring the voltage of the commercial system, an electromagnetic contactor separating between the first terminal and the second terminal in the event of a power failure Bi-directional power conversion means, a current transformer for detecting a reverse power flow from the bidirectional power conversion means side to the first terminal side, a monitoring result of the commercial system voltage monitoring means and a detection result of the current transformer Based on this, the magnetic contactor and the control means for controlling the bidirectional power conversion means are housed in one housing.

  In the power supply device described in Patent Document 1, a power lead-in wiring connected to a commercial system is connected to a main earth leakage breaker in a residential distribution board.

  Moreover, in the electric power supply apparatus described in Patent Document 1, the main circuit wiring is wired between the load-side terminal of the main leakage breaker in the residential distribution board and the first terminal of the electric power supply apparatus. .

  Further, in the power supply device described in Patent Document 1, main circuit wiring is wired between the second terminal of the power supply device and the power supply side terminal of the branch breaker in the residential distribution board.

Japanese Patent Laying-Open No. 2015-6044

  In the power supply device described in Patent Document 1, the power conditioner is installed outdoors, and the residential distribution board is installed in the house.

  According to Patent Document 1, not only the power lead-in wiring but also two main circuit wirings are connected to the residential distribution board. Therefore, it is necessary to lay three or more wires between the outdoor and indoor. Not only the work for laying these wires, but also the work for creating through holes for drawing these wires in the house may occur. There is sex.

  This invention is made | formed in view of the above, Comprising: It aims at obtaining the switch box which can simplify the construction accompanying wiring.

  In order to solve the above-described problems and achieve the object, a switch box of the present invention includes a first switch for connecting a power lead-in wiring connected to a commercial system, a first switch, and an electric vehicle. A second switch that connects or separates the inverters from the power conditioner, a first switch that connects between the first switch and the house load, or a second switch that connects the power conditioner for the electric vehicle and the house load. 1 switch. Moreover, the switch box of the present invention connects the electric vehicle power conditioner and the solar battery power conditioner, or connects the solar battery power conditioner and the home load, the second switch, A third switch for connecting wires connected to the solar battery power conditioner, a first switch, a second switch, a first switch, a second switch, and a third switch; And a housing for housing.

  According to the present invention, it is possible to simplify the construction associated with wiring.

The figure which shows the structural example of the switch box which concerns on embodiment of this invention, and the electric power supply system provided with the switch box The figure which shows the state which switched the breaker in a breaker box at the time of the maintenance check of EV inverter The figure which shows the internal structure of the breaker box shown in FIG. The figure which shows the comparative example with respect to the electric power supply system which concerns on embodiment of this invention

  Hereinafter, a switch box and a power supply system according to an embodiment of the present invention will be described in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

Embodiment.
FIG. 1 is a diagram illustrating a configuration example of a switch box according to an embodiment of the present invention and a power supply system including the switch box.

  The power supply system 100 includes a breaker box 13 that is a switch box, and a solar cell power conditioner (PV-PCS 12) that supplies the power generated by the solar cell 17 to the breaker box 13. .

  The power supply system 100 includes an electric vehicle power conditioner (EV-PCS6).

  The EV-PCS 6 supplies power to the storage battery mounted on the EV 10 or supplies the power stored in the storage battery to the breaker box 13. The remote controller 9 performs various settings such as the operating conditions of the EV-PCS 6 and can also display the operating status of the EV-PCS 6.

  The home distribution board 8 is connected to the breaker box 13 via a wiring g which is an outdoor wiring.

  The home distribution board 8 includes a main breaker 20 and a plurality of branch breakers 21 connected to the main breaker 20.

  A home load 30 is connected to each of the plurality of branch breakers 21. The home load 30 is a device that is driven by alternating current (AC) power. An example of the home load 30 is a refrigerator, lighting, cooking equipment, a telephone, a television, or audio.

  The breaker box 13 includes a main earth leakage breaker 2 as a first switch, a maintenance breaker 3 as a second switch, a switch 7a as a first switch, and a second switch. A switch 7b and a PV-PCS breaker 14 as a third switch are provided.

  The breaker box 13 includes a casing 18 that houses the main leakage breaker 2, the maintenance breaker 3, the switch 7a, the switch 7b, and the PV-PCS breaker 14.

  The primary side of the main leakage breaker 2 is connected to a wiring a which is a power lead-in wiring connected to the commercial system 1.

  A wiring b is connected to the secondary side of the main leakage breaker 2. The wiring b is an internal wiring of the breaker box 13.

  The secondary side of main leakage breaker 2 is connected to the primary side of maintenance breaker 3 via wiring b.

  The maintenance breaker 3 is an opening / closing means that connects or separates the main leakage breaker 2 and the EV-PCS 6.

  A wiring b and a wiring d are connected to the primary side of the maintenance breaker 3. The wiring d is an internal wiring of the breaker box 13.

  The primary side of the maintenance breaker 3 is connected to the secondary side of the main leakage breaker 2 via the wiring b, and is connected to the terminal I of the switch 7a via the wiring d.

  A wiring c is connected to the secondary side of the maintenance breaker 3. The wiring c is an outdoor wiring laid outside the housing 18.

  The secondary side of the maintenance breaker 3 is connected to the terminal block TB1 of the EV-PCS 6 via the wiring c.

  The maintenance breaker 3 is provided to open a wiring path between the main circuit breaker 2 and the EV-PCS 6 when the wiring c is removed from the terminal block TB1 for maintenance and inspection of the EV-PCS 6. That is, the maintenance breaker 3 is provided in order to prevent the voltage of the commercial system 1 from being applied to the terminal block TB1.

  The switch 7 a is a switching opening / closing means for connecting the main leakage breaker 2 and the home load 30 or connecting the EV-PCS 6 and the home load 30.

  The switch 7a includes a terminal I to which the wiring d is connected, a terminal II to which the wiring e is connected, a common terminal C to which the wiring f is connected, and a contact 7a1.

  The wiring e is an outdoor wiring laid outside the housing 18. The wiring e connects the terminal II of the switch 7a and the terminal block TB2 of the EV-PCS 6.

  The wiring f is an internal wiring of the breaker box 13. The wiring f connects the common terminal C of the switch 7a and the terminal I of the switch 7b.

  The switch 7a is configured such that the contact 7a1 can be switched so that the common terminal C is connected to the terminal I or the terminal II.

  When power is supplied from the commercial system 1 and the EV-PCS 6 is operating normally, the terminal I of the switch 7a is opened from the common terminal C, and the terminal II of the switch 7a is connected to the common terminal C. ing.

  The switch 7b is a switching opening / closing means for connecting the PV-PCS 12 and the EV-PCS 6 or connecting the PV-PCS 12 and the home load 30.

  The switch 7b includes a terminal I to which the wiring f and the wiring g are connected, a terminal II to which the wiring h is connected, a common terminal C to which the wiring i is connected, and a contact 7b1.

  The wiring g is an outdoor wiring laid outside the housing 18.

  One end side of the wiring g is drawn into the breaker box 13 and connected to the terminal I.

  The other end side of the wiring g is drawn into the home distribution board 8 and connected to the main breaker 20 of the home distribution board 8.

  Thereby, the common terminal C of the switch 7a is connected to the terminal I of the switch 7b, and is connected to the main breaker 20 of the home distribution board 8.

  The wiring h is an outdoor wiring provided to connect the terminal II of the switch 7b and the terminal block TB3 of the EV-PCS 6.

  One end side of the wiring h is drawn into the breaker box 13 and connected to the terminal II of the switch 7b.

  The other end side of the wiring h is connected to the terminal block TB3 of the EV-PCS 6.

  The wiring i connects the common terminal C of the switch 7b and the primary side of the PV-PCS breaker 14.

  The switch 7b is configured such that the contact 7b1 can be switched so that the common terminal C is connected to the terminal I or the terminal II.

  When power is supplied from the commercial system 1 and the EV-PCS 6 is operating normally, the terminal I of the switch 7b is released from the common terminal C, and the terminal II of the switch 7b is connected to the common terminal C. Has been.

  The common terminal C of the switch 7b is connected to the PV-PCS breaker 14 through the wiring i.

  The PV-PCS breaker 14 is an opening / closing means for connecting the PV-PCS 12 to the breaker box 13.

  A wiring j is connected to the secondary side of the PV-PCS breaker 14. The wiring j is an outdoor wiring laid outside the housing 18.

  Next, the configuration of the EV-PCS 6 will be described.

  The EV-PCS 6 includes a disconnecting switch 15, a current transformer 16 connected to the disconnecting switch 15, a power converter 4 connected to the current transformer 16, and a control circuit 5.

  The EV-PCS 6 includes a terminal block TB1 connected to the disconnection switch 15, a terminal block TB2 connected to the current transformer 16 and the power converter 4, a disconnect switch 15 and the current transformer 16. And a terminal block TB3 connected to the power converter 4.

  The disconnect switch 15 is an opening / closing means for disconnecting the connection between the commercial system 1 and the EV-PCS 6 when the user selects the shift to the self-sustained operation at the time of a power failure of the commercial system 1. The disconnecting switch 15 is controlled by the control circuit 5.

  The current transformer 16 is provided to prevent the power supplied from the EV 10 from flowing backward to the commercial system 1. The power stored in the storage battery mounted on the EV 10 cannot normally be sold to the commercial system 1. Therefore, a current transformer 16 is provided to prevent AC power output from the power converter 4 from flowing into the commercial system 1 side, that is, the terminal block TB1.

  The power converter 4 is a bidirectional power conversion means. The power converter 4 converts the AC power supplied from the commercial system 1 or the solar battery 17 into direct current (DC) power and outputs it, and converts the DC power supplied from the EV 10 into AC power. Output function.

  The AC terminal side of the power converter 4 is connected to the disconnecting switch 15, the terminal block TB3, and the terminal block TB2 through the current transformer 16.

  A wiring h is connected to the terminal block TB3. Thereby, the terminal block TB3 is connected to the switch 7b via the wiring h.

  A wiring e is connected to the terminal block TB2. As a result, the terminal block TB2 is connected to the switch 7a via the wiring e.

  The terminal block TB3 of the EV-PCS 6 is connected to the terminal block TB2.

  With this configuration, in the power supply system 100, the generated power of the solar cell 17 is changed to the wiring j, the PV-PCS breaker 14, the wiring i, the switch 7b, the wiring h, the terminal block TB3, the terminal block TB2, the wiring e, and the switching. It can also be supplied to the in-house load 30 via the device 7a, the wiring g, the main breaker 20, and the branch breaker 21.

  The DC terminal side of the power converter 4 is connected to the connector terminal 19. A connector attached to the cable 11 is connected to the connector terminal 19. The connector attached to the cable 11 is a dedicated connector for connecting the EV 10 to the EV-PCS 6.

  The operation of the power supply system 100 will be described below.

(Commercial grid operation)
The operation at the time of commercial system interconnection operation when the commercial system 1 is not out of power and the EV-PCS 6 is operating normally will be described.

When the commercial system 1 is not out of power and the EV-PCS 6 is operating normally, the main leakage breaker 2, the maintenance breaker 3, the switch 7a, the switch 7b, the PV-PCS breaker 14 and The state of the disconnection switch 15 is as follows.
(1) The main leakage breaker 2 is closed.
(2) The maintenance breaker 3 is closed.
(3) The terminal II of the switch 7a is connected to the common terminal C.
(4) The terminal II of the switch 7b is connected to the common terminal C.
(5) The PV-PCS breaker 14 is closed.
(6) The disconnection switch 15 is closed.

  In such a state, the AC power supplied from the commercial system 1 is the main leakage breaker 2, the maintenance breaker 3, the terminal block TB1, the disconnecting switch 15, the terminal block TB2, the switch 7a, the wiring g, It is supplied to the home load 30 via the main breaker 20 and the branch breaker 21.

  At this time, the voltage of the commercial system 1 is applied to the AC output side of the PV-PCS 12 via the terminal block TB3, the switch 7b, and the PV-PCS breaker 14. The PV-PCS 12 that has detected the voltage of the commercial system 1 performs commercial system interconnection operation.

  On the other hand, the AC power supplied from the commercial system 1 is also supplied to the power converter 4 via the main leakage breaker 2, the maintenance breaker 3, the terminal block TB1, and the disconnecting switch 15.

  In the power converter 4, AC power supplied from the commercial system 1 is converted into DC power. The converted DC power is supplied to the storage battery mounted on the EV 10 via the cable 11 connected to the connector terminal 19. Thereby, the storage battery mounted in EV10 is charged.

(Independent operation)
The operation at the time of the independent operation when the commercial system 1 is interrupted and the EV-PCS 6 is operating normally will be described.

When commercial system 1 fails and EV-PCS 6 is operating normally, main leakage breaker 2, maintenance breaker 3, switch 7a, switch 7b, PV-PCS breaker 14 and disconnection The state of the switch 15 is as follows.
(1) The main leakage breaker 2 is closed.
(2) The maintenance breaker 3 is closed.
(3) The terminal II of the switch 7a is connected to the common terminal C.
(4) The terminal II of the switch 7b is connected to the common terminal C.
(5) The PV-PCS breaker 14 is closed.
(6) The disconnecting switch 15 is opened when the commercial system 1 has a power failure.

  When the control circuit 5 in the EV-PCS 6 detects that the commercial system 1 has lost power, the control circuit 5 transmits message information for confirming the transition to the independent operation to the remote controller 9. On the remote controller 9 that has received the message information, information for confirming the transition to the independent operation is displayed to the user.

  The control circuit 5 outputs a command to open the disconnection switch 15 when the user performs an operation of selecting the transition to the self-sustained operation with the remote controller 9. Thereby, the connection between the EV-PCS 6 and the commercial system 1 is released.

  Thereafter, in the power converter 4 in which a power failure is detected, the DC power of the storage battery mounted on the EV 10 is converted into AC power.

  The converted AC power is supplied to the in-home load 30 via the terminal block TB2, the switch 7a, the switch 7b, the wiring g, the main breaker 20, and the branch breaker 21.

  The in-home load 30 is supplied with the same power as that supplied during a non-power failure even during a power failure. As described above, the power supply system 100 can perform a self-sustained operation in which AC power is supplied to the home load 30 to continue the operation.

  Note that the AC power voltage output from the power converter 4 during the self-sustained operation is also applied to the AC output side of the PV-PCS 12 via the terminal block TB3, the switch 7b, and the PV-PCS breaker 14.

  The PV-PCS 12 that has detected the voltage of the AC power determines that the commercial system 1 has been restored, and outputs the AC power in cooperation with the AC voltage output from the power converter 4.

  Thereby, the electric power generated by the solar battery 17 can be supplied to the in-home load 30 at the time of a power failure.

  Next, the operation of the power supply system 100 when performing maintenance inspection on the EV-PCS 6 will be described.

  FIG. 2 is a diagram illustrating a state in which the breaker in the breaker box is switched during maintenance and inspection of the EV power conditioner.

  During maintenance and inspection of the EV-PCS 6, the maintenance breaker 3 in the breaker box 13 is opened. Further, the respective contacts 7a1 and 7b1 of the switches 7a and 7b are switched to the terminal I side.

  Thereby, the voltage of the AC power supplied from the commercial system 1 is not applied to the terminal block TB1, the terminal block TB2, and the terminal block TB3 of the EV-PCS 6.

  Therefore, when removing the wirings c, e, h from the terminal block TB1, the terminal block TB2, and the terminal block TB3, it is not a live work and the wirings c, e, h can be safely removed.

  Further, by switching the contact 7a1 of the switch 7a to the terminal I side, the AC power of the commercial system 1 is supplied to the home load 30 via the main leakage breaker 2 and the switch 7a.

  Further, by switching the contact 7b1 of the switch 7b to the terminal I side, the voltage of the AC power supplied from the commercial system 1 is changed between the main leakage breaker 2, the switch 7a, the switch 7b, and the PV-PCS breaker 14. To the PV-PCS 12.

  Thereby, PV-PCS12 which detected the voltage of commercial system 1 can perform commercial system interconnection operation.

  That is, AC power of the commercial grid 1 can be supplied to the in-house load 30 and the commercial grid interconnection operation can be continuously performed during maintenance and inspection of the EV-PCS 6.

  Next, the internal configuration of the breaker box 13 shown in FIG. 1 will be described in detail with reference to FIG.

  FIG. 3 is a diagram showing an internal configuration of the breaker box shown in FIG.

  In the casing 18 of the breaker box 13, the main leakage breaker 2, the maintenance breaker 3, the switch 7 a, the switch 7 b and the PV-PCS breaker 14 are installed.

  In the illustrated example, the casing 18 is formed in a rectangular shape.

  The main leakage breaker 2, the maintenance breaker 3, the switch 7a, the switch 7b, and the PV-PCS breaker 14 are the main leakage breaker 2, the maintenance breaker 3, the switch 7a, and the switch from the left side of the casing 18. 7b and PV-PCS breaker 14 are arranged in this order.

  Wirings indicated by broken lines are outdoor wirings laid outside the casing 18 of the breaker box 13. The wiring indicated by the solid line is the internal wiring of the breaker box 13.

  The wiring a is connected to the primary side of the main leakage breaker 2.

  One end of the wiring b is connected to the secondary side of the main leakage breaker 2, and the other end of the wiring b is connected to the primary side of the maintenance breaker 3.

  One end of the wiring c is connected to the secondary side of the maintenance breaker 3, and the other end of the wiring c is connected to the terminal block TB1 of the EV-PCS 6 shown in FIG.

  One end of the wiring d is connected to the primary side of the maintenance breaker 3, and the other end of the wiring d is connected to the terminal I of the switch 7a.

  One end of the wiring e is connected to the terminal II of the switch 7a, and the other end of the wiring e is connected to the terminal block TB2 of the EV-PCS 6 shown in FIG.

  One end of the wiring f is connected to the common terminal C of the switch 7a, and the other end of the wiring f is connected to the terminal I of the switch 7b.

  One end of the wiring g is connected to the terminal I of the switch 7b, and the other end of the wiring g is connected to the main breaker 20 in the home distribution board 8 shown in FIG.

  One end of the wiring h is connected to the terminal II of the switch 7b, and the other end of the wiring h is connected to the terminal block TB3 of the EV-PCS 6 shown in FIG.

  One end of the wiring i is connected to the common terminal C of the switch 7b, and the other end of the wiring i is connected to the primary side of the PV-PCS breaker 14.

  One end of the wiring j is connected to the secondary side of the PV-PCS breaker 14, and the other end of the wiring j is connected to the PV-PCS 12 shown in FIG.

  In the example of FIG. 3, the wiring g which is an outdoor wiring is connected to the terminal I of the switch 7b in consideration of the ease of wiring work to the home distribution board 8. However, the connection location of the wiring g is not limited to this, and may be the common terminal C of the switch 7a or may be connected in the middle of the wiring f.

  FIG. 4 is a diagram showing a comparative example for the power supply system according to the embodiment of the present invention.

The power supply system 100A shown in FIG. 4 is configured as follows.
(1) The power lead-in wiring connected to the commercial system 1 is connected to the main leakage breaker 2.
(2) The secondary side of the main leakage breaker 2 is connected to the primary side of the maintenance breaker 3.
(3) The secondary side of the maintenance breaker 3 is connected to the terminal block TB1 of the EV-PCS 6 via an outdoor wiring.
(4) The terminal block TB2 of the EV-PCS 6 installed outdoors is connected to the home distribution board 8 installed indoors via the outdoor wiring.
(5) The terminal block TB3 of the EV-PCS 6 is connected to the PV-PCS 12 installed indoors via the outdoor wiring and the PV-PCS breaker 14.
(6) The solar cell 17 installed outdoors is connected to the PV-PCS 12 via the connection box 24.

  In the power supply system 100 </ b> A shown in FIG. 4, the power lead-in wiring is connected to the main leakage breaker 2.

  The maintenance breaker 3 and the terminal block TB1 are connected by outdoor wiring, the terminal block TB2 and the home distribution board 8 are connected by outdoor wiring, and the terminal block TB3 and the PV-PCS breaker 14 are connected by outdoor wiring. Connected.

  In the power supply system 100A, it is necessary to draw four or more outdoor wirings into the house. Therefore, there is a possibility that construction for providing a through hole for drawing these wires into the house may occur. Therefore, not only a large construction cost but also a long construction period may be required.

  On the other hand, since the main line from the commercial system 1 to the home distribution board 8 passes through the inside of the EV-PCS 6, when the wiring connected to the EV-PCS 6 is removed during the maintenance inspection of the EV-PCS 6, The commercial power of the commercial system 1 cannot be supplied to the home load.

  Further, when the wiring connected to the EV-PCS 6 is removed, the commercial system 1 is not connected to the AC output side of the PV-PCS 12, so that the grid interconnection operation cannot be performed.

  Therefore, in the power supply system 100A, it is necessary to provide the switch 7a during maintenance and inspection of the EV-PCS 6, and to lay the bypass wiring 22 between the main leakage breaker 2 and the switch 7a.

  Further, in the power supply system 100A, it is necessary to provide the switch 7b and lay the bypass wiring 23 between the switch 7b and the home distribution board 8 at the time of maintenance and inspection of the EV-PCS 6.

  On the other hand, the power supply system 100 according to the embodiment of the present invention includes a main leakage breaker 2, a maintenance breaker 3, a switch 7a, a switch 7b, and a PV-PCS breaker 14, and a breaker box 13 housing. The structure is housed in the body 18.

  This simplifies the wiring of breakers and switches that look complicated, and eliminates the work of laying the bypass wirings 22 and 23 and the work of installing the switching switch during maintenance and inspection.

  Further, in the power supply system 100 according to the embodiment of the present invention, it is only necessary to connect the wirings a, c, e, h, j, and g to the breaker box 13, and bypass wirings 22 and 23 during maintenance of the EV-PCS 6. There is no need to lay.

  Therefore, the wiring work can be easily performed as compared with the power supply system 100A.

  In the breaker box 13 according to the embodiment of the present invention, a casing 18 having a waterproof structure that can be installed outdoors is used.

  Therefore, it is possible to connect to the main leakage breaker 2 for receiving power in the breaker box 13 installed outdoors without drawing the lead-in wiring a wired by the power company indoors.

  Moreover, since the breaker box 13 and the EV-PCS 6 are installed outdoors, the wiring work of the wirings c, e, and h connected to the EV-PCS 6 can be performed outdoors. Further, as for wiring to be drawn indoors, only one wiring g is required for wiring work from the breaker box 13 to the home distribution board 8.

  Accordingly, since the through-hole provided in the wall of the house only needs to have a size corresponding to one wiring g, wiring work that penetrates the indoor and the outdoor can be performed at low cost.

  In addition, in the power supply system 100A shown in FIG. 4, the indoor PV-PCS 12 is used, and the wiring connecting the solar cell 17 and the PV-PCS 12 needs to penetrate the wall of the house.

  In the power supply system 100 according to the embodiment of the present invention, an outdoor specification PV-PCS 12 is used. Therefore, the AC output of the PV-PCS 12 and the PV-PCS breaker 14 can be connected by the wiring j that is an outdoor wiring.

  Therefore, wiring work that penetrates indoors and outdoors like the power supply system 100A shown in FIG. 4 is unnecessary, and wiring work can be performed at low cost.

  The configuration described in the above embodiment shows an example of the contents of the present invention, and can be combined with another known technique, and can be combined with other configurations without departing from the gist of the present invention. It is also possible to omit or change the part.

  DESCRIPTION OF SYMBOLS 1 Commercial system, 2 Main circuit leakage breaker, 3 Maintenance breaker, 4 Power converter, 5 Control circuit, 6 EV-PCS, 7a, 7b Switch, 7a1, 7b1 Contact, 8 Home distribution board, 9 Remote control, 11 Cable, 12 PV-PCS, 13 Breaker box, 14 PV-PCS breaker, 15 Disconnection switch, 16 Current transformer, 17 Solar cell, 18 Housing, 19 Connector terminal, 20 Master breaker, 21 Branch breaker, 22, 23 Bypass wiring, 24 junction box, 30 residential load, 100, 100A power supply system.

Claims (3)

A first switch for connecting a power lead-in wiring connected to a commercial system;
A second switch for connecting or separating between the first switch and the electric vehicle power conditioner;
A first switch for connecting between the first switch and the home load, or for connecting between a power conditioner for an electric vehicle and the home load;
A second switch for connecting between the electric vehicle power conditioner and the solar battery power conditioner, or connecting between the solar battery power conditioner and the residential load;
A third switch for connecting a wiring connected to the solar battery power conditioner;
A housing for housing the first switch, the second switch, the first switch, the second switch, and the third switch;
A switch box characterized by comprising:   The switch box according to claim 1, wherein the casing has a waterproof structure. The switch box according to claim 1 or 2,
The solar cell power conditioner having a waterproof structure;
A power supply system comprising:

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