JP2018120740A - Power storage device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power storage device capable of preventing current from flowing to a load during charging, and being charged even when using one of two connectors provided in the power storage device.SOLUTION: A power storage device 1 comprises a first connector 3a, a second connector 3b, and a conduction unit D1(or SW1). When the first connector 3a and a first charge connector 5a connected to the first connector 3a are connected, a second terminal 2p of the first connector 3a is connected to one terminal of the first charge connector 5a and a third terminal 3p of the first connector 3a is connected to the other terminal of the first charge connector 5a. When the second connector 3b and a second charge connector 5b connected to the second connector 3b are connected, a fifth terminal 5p of the second connector 3b is connected to one terminal of the second charge connector 5b, and a sixth terminal 6p of the second connector 3b is connected to the other terminal of the second charge connector 5b.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a power storage device.

  When the charging current supplied from the charging device to the power storage device is increased, the diameter of the charging cable that connects the charging device and the power storage device increases as the charging current increases. If it does so, since it will become difficult to bend a charging cable and weight will increase, workability | operativity of a user will fall. Therefore, the charging cables are divided into two, and the charging current flowing through each charging cable is reduced, so that the diameter of each charging cable is reduced, each charging cable is made easier to bend and the weight is reduced. Prevents workability from decreasing.

  As a related technique, there is Patent Document 1 or the like.

JP 2014-176126 A

  However, if the charging cable is divided into two, the power storage device needs two connectors to connect to the charging connector provided in each charging cable. Therefore, even when two connectors are provided in the power storage device, when the connector provided in the power storage device and the charging connector are connected (during charging), the current is prevented from flowing to the load and is provided in the power storage device. I want to be able to charge using only one of the two connectors.

  An object of one aspect of the present invention is to provide a power storage device that prevents charging of a current from flowing to a load during charging and that can be charged using only one of two connectors provided in the power storage device. That is.

  A power storage device according to one embodiment of the present invention includes a first connector, a second connector, and a conduction portion. The first connector has a first terminal, a second terminal, and a third terminal, and the second connector has a fourth terminal, a fifth terminal, and a sixth terminal.

  The first terminal is connected to one terminal of the load, the second terminal is connected to one terminal and the fourth terminal of the conduction part, and the third terminal is connected to one terminal of the battery and the load. The other terminal of the battery and the sixth terminal are connected to each other, and the fifth terminal is connected to the other terminal of the battery and the other terminal of the conducting portion.

  When the first connector and the first charging connector connected to the first connector are connected, the second terminal is connected to one terminal of the first charging connector, and the third terminal is Connected to the other terminal of the first charging connector. Further, when the second connector and the second charging connector connected to the second connector are connected, the fifth terminal is connected to one terminal of the second charging connector, and the sixth terminal Is connected to the other terminal of the second charging connector.

When the first connector and the first jumper plug connected to the first connector are connected, the first terminal and the second terminal are short-circuited by the jumper wire of the first jumper plug.
When the second connector and the second jumper plug connected to the second connector are connected, the fourth terminal and the fifth terminal are short-circuited by the jumper wire of the second jumper plug.

When one terminal of the load is a positive terminal and the other terminal is a negative terminal, one terminal of the battery is a negative terminal and the other terminal is a positive terminal, and the conduction part is a diode, one terminal of the diode is The anode terminal and the other terminal the cathode terminal,
Or, if one terminal of the load is a negative terminal and the other terminal is a positive terminal, one terminal of the battery is a positive terminal and the other terminal is a negative terminal, and the conduction part is a diode, one terminal of the diode is The cathode terminal is used and the other terminal is an anode terminal.

  Moreover, when a conduction | electrical_connection part is a switch, if a 1st charge connector is connected to a 1st connector, a switch will transfer from a cutoff state to a conduction | electrical_connection state.

  During charging, current can be prevented from flowing to the load, and charging can be performed using only one of the two connectors provided in the power storage device.

3 is a diagram illustrating an example of the power storage device of Embodiment 1. FIG. It is a figure which shows one Example of the electrical storage apparatus of the modification 1. 6 is a diagram illustrating an example of a power storage device according to Embodiment 2. FIG. It is a figure which shows one Example of the electrical storage apparatus of the modification 2.

Hereinafter, embodiments will be described in detail with reference to the drawings.
<Embodiment 1>
FIG. 1 is a diagram illustrating an example of the power storage device 1 according to the first embodiment. Power storage device 1 of Embodiment 1 is connected to charging device 2 and motor MG (load). The power storage device 1 includes a connector 3a (first connector), a connector 3b (second connector), a diode D1 (conduction part), and a battery B1.

  The connector 3a has a terminal 1p (first terminal), a terminal 2p (second terminal), and a terminal 3p (third terminal). Connector 3a is connected to jumper plug 4a when power is supplied from battery B1 to motor MG to drive motor MG (when discharging). The connector 3a is connected to the charging connector 5a (first charging connector) when charging is performed by supplying power from the charging device 2 to the battery B1 (during charging).

  The connector 3b has a terminal 4p (fourth terminal), a terminal 5p (fifth terminal), and a terminal 6p (sixth terminal). The connector 3b is connected to the jumper plug 4b when power is supplied from the battery B1 to the motor MG to drive the motor MG (during discharging). The connector 3b is connected to the charging connector 5b (second charging connector) when charging is performed by supplying power from the charging device 2 to the battery B1 (during charging).

The battery B1 is, for example, a secondary battery such as a nickel metal hydride battery or a lithium ion battery, or a storage element.
A circuit of the power storage device 1 in FIG. 1 will be described.

  Terminal 1p of connector 3a is connected to the positive terminal (+) of motor MG. The terminal 2p of the connector 3a is connected to the anode terminal of the diode D1 and the terminal 4p of the connector 3b. The terminal 3p of the connector 3a is connected to the negative terminal (−) of the battery B1, the negative terminal (−) of the motor MG, and the terminal 6p of the connector 3b. The terminal 5p of the connector 3b is connected to the positive terminal (+) of the battery B1 and the cathode terminal of the diode D1.

  When the connector 3a and the charging connector 5a connected to the connector 3a are connected (when charging), the terminal 2p of the connector 3a is connected to the terminal 2p of the charging connector 5a, and the terminal 3p of the connector 3a is connected to the charging connector 5a. To the terminal 3p.

  The terminal 2p of the charging connector 5a is connected to the positive terminal (+) of the charging device 2 through the positive wiring of the charging cable 7a, and the terminal 3p of the charging connector 5a is charged through the negative wiring of the charging cable 7a. It is connected to the negative terminal (−) of the device 2.

  When the connector 3b and the charging connector 5b connected to the connector 3b are connected (when charging), the terminal 5p of the connector 3b is connected to the terminal 5p of the charging connector 5b, and the terminal 6p of the connector 3b is connected to the charging connector 5b. To the terminal 6p.

  The terminal 5p of the charging connector 5b is connected to the positive terminal (+) of the charging device 2 through the positive wiring of the charging cable 7b, and the terminal 6p of the charging connector 5b is charged through the negative wiring of the charging cable 7b. It is connected to the negative terminal (−) of the device 2.

  When the connector 3a and the jumper plug 4a connected to the connector 3a are connected, the terminal 1p of the connector 3a and the terminal 2p of the connector 3a are short-circuited by the jumper wire 6a of the jumper plug 4a.

  When the connector 3b and the jumper plug 4b connected to the connector 3b are connected, the terminal 4p of the connector 3b and the terminal 5p of the connector 3b are short-circuited by the jumper wire 6b of the jumper plug 4b.

An operation of charging the power storage device 1 in FIG. 1 will be described.
(1) When charging is performed by connecting the connector 3a and the charging connector 5a and charging the connector 3b and the charging connector 5b (when charging is performed using the two connectors 3a and 3b), the charging of the charging device 2 is performed. The positive terminal (+) connected to the positive wiring of the cable 7a is connected to the positive wiring of the charging cable 7a, the terminal 2p of the charging connector 5a, the terminal 2p of the connector 3a, the anode terminal of the diode D1, and the cathode terminal of the diode D1. Connected to the positive terminal (+) of battery B1.

  The negative terminal (−) connected to the negative wiring of the charging cable 7a of the charging device 2 is connected to the negative terminal of the battery B1 via the negative wiring of the charging cable 7a, the terminal 3p of the charging connector 5a, and the terminal 3p of the connector 3a. Connected to (-).

  The positive terminal (+) connected to the positive wiring of the charging cable 7b of the charging device 2 is connected to the positive terminal of the battery B1 via the positive wiring of the charging cable 7b, the terminal 5p of the charging connector 5b, and the terminal 5p of the connector 3b. Connected to (+).

  The negative terminal (−) connected to the negative wiring of the charging cable 7b of the charging device 2 is connected to the negative terminal of the battery B1 via the negative wiring of the charging cable 7b, the terminal 6p of the charging connector 5b, and the terminal 6p of the connector 3b. Connected to (-).

  In this way, even when charging is performed using the two connectors 3a and 3b, the battery B1 can be charged from the charging device 2 via the diode D1. Further, since the positive terminal (+) of the motor MG connected to the terminal 1p of the connector 3a is in an open state, current can be prevented from flowing to the motor MG.

(2) When charging is performed by connecting the connector 3a and the charging connector 5a in a state where the connector 3b and the jumper plug 4b are not connected (when charging is performed using one connector 3a), the charging device 2 The positive terminal (+) connected to the positive wiring of the charging cable 7a includes the positive wiring of the charging cable 7a, the terminal 2p of the charging connector 5a, the terminal 2p of the connector 3a, the anode terminal of the diode D1, and the cathode terminal of the diode D1. To the positive terminal (+) of the battery B1.

  The negative terminal (−) connected to the negative wiring of the charging cable 7a of the charging device 2 is connected to the negative terminal of the battery B1 via the negative wiring of the charging cable 7a, the terminal 3p of the charging connector 5a, and the terminal 3p of the connector 3a. Connected to (-).

  Thus, even when charging is performed using one connector 3a in a state where the connector 3b and the jumper plug 4b are not connected, the battery B1 can be charged from the charging device 2 via the diode D1. Further, since the positive terminal (+) of the motor MG connected to the terminal 1p of the connector 3a is in an open state, current can be prevented from flowing to the motor MG.

(3) When charging by connecting the connector 3b and the charging connector 5b (when charging using one connector 3b), a positive terminal connected to the positive wiring of the charging cable 7b of the charging device 2 (+ ) Is connected to the positive terminal (+) of the battery B1 through the positive wiring of the charging cable 7b, the terminal 5p of the charging connector 5b, and the terminal 5p of the connector 3b.

  The negative terminal (−) connected to the negative wiring of the charging cable 7b of the charging device 2 is connected to the negative terminal of the battery B1 via the negative wiring of the charging cable 7b, the terminal 6p of the charging connector 5b, and the terminal 6p of the connector 3b. Connected to (-).

  Thus, even when charging is performed using one connector 3b, charging from the charging device 2 to the battery B1 can be performed. When the connector 3a and the jumper plug 4a are not connected, the positive terminal (+) of the motor MG connected to the terminal 4p of the connector 3b is in an open state, so that no current flows to the motor MG. Even when the connector 3a and the jumper plug 4a are connected, the diode D1 is provided, so that no current flows to the motor MG.

  That is, the anode terminal of the diode D1 and the terminal 2p of the connector 3a are connected, and the cathode terminal of the diode D1, the terminal 5p of the connector 3b, and the positive terminal of the battery B1 are connected, so that Charging can be performed using only one of the connectors 3a and 3b. Further, if the jumper plugs 4a and 4b are not connected to the connectors 3a and 3b, current can be prevented from flowing from the battery B1 to the motor MG.

<Modification 1>
FIG. 2 is a diagram illustrating an example of the power storage device 21 according to the first modification. Power storage device 21 of Modification 1 is connected to charging device 2 and motor MG (load). The power storage device 21 includes a connector 3a (first connector), a connector 3b (second connector), a switch SW1 (conduction unit), a battery B1, and a control unit 22. The difference between the first embodiment and the first modification is that the diode D1 shown in FIG. 1 is replaced with a switch SW1 and a control unit 22 as shown in FIG.

For example, a relay or a semiconductor element may be used as the switch SW1.
The control unit 22 may be, for example, a circuit using a CPU (Central Processing Unit), a multi-core CPU, a programmable device (FPGA (Field Programmable Gate Array), PLD (Programmable Logic Device), etc.).

A circuit of the power storage device 21 in FIG. 2 will be described. The description of the same configuration as in FIG. 1 is omitted.
The terminal 2p of the connector 3a is connected to one terminal of the switch SW1 and the terminal 4p of the connector 3b. The terminal 5p of the connector 3b is connected to the positive terminal (+) of the battery B1 and the other terminal of the switch SW1.

Moreover, the control part 22 acquires the connection detection signal which shows that the connector 3a and the charge connector 5a were connected, and makes switch SW1 into a conduction | electrical_connection state from an interruption | blocking state.
An operation of charging the power storage device 21 of FIG. 2 will be described.

(4) When the connector 3a and the charging connector 5a are connected and the connector 3b and the charging connector 5b are connected for charging (when charging is performed using the two connectors 3a and 3b), the switch SW1 is in a conductive state. The positive terminal (+) connected to the positive wiring of the charging cable 7a of the charging device 2 is connected to the battery via the positive wiring of the charging cable 7a, the terminal 2p of the charging connector 5a, the terminal 2p of the connector 3a, and the switch SW1. Connected to the positive terminal (+) of B1.

  The negative terminal (−) connected to the negative wiring of the charging cable 7a of the charging device 2 is connected to the negative terminal of the battery B1 via the negative wiring of the charging cable 7a, the terminal 3p of the charging connector 5a, and the terminal 3p of the connector 3a. Connected to (-).

  The positive terminal (+) connected to the positive wiring of the charging cable 7b of the charging device 2 is connected to the positive terminal of the battery B1 via the positive wiring of the charging cable 7b, the terminal 5p of the charging connector 5b, and the terminal 5p of the connector 3b. Connected to (+).

  The negative terminal (−) connected to the negative wiring of the charging cable 7b of the charging device 2 is connected to the negative terminal of the battery B1 via the negative wiring of the charging cable 7b, the terminal 6p of the charging connector 5b, and the terminal 6p of the connector 3b. Connected to (-).

  As described above, even when charging is performed using the two connectors 3a and 3b, the battery B1 can be charged from the charging device 2 via the switch SW1. Further, since the positive terminal (+) of the motor MG connected to the terminal 1p of the connector 3a is in an open state, current can be prevented from flowing to the motor MG.

(5) When charging is performed by connecting the connector 3a and the charging connector 5a in a state where the connector 3b and the jumper plug 4b are not connected (when charging is performed using one connector 3a), the switch SW1 is The positive terminal (+) connected to the positive wiring of the charging cable 7a of the charging device 2 is connected to the positive wiring of the charging cable 7a, the terminal 2p of the charging connector 5a, the terminal 2p of the connector 3a, and the switch SW1. , Connected to the positive terminal (+) of the battery B1.

  The negative terminal (−) connected to the negative wiring of the charging cable 7a of the charging device 2 is connected to the negative terminal of the battery B1 via the negative wiring of the charging cable 7a, the terminal 3p of the charging connector 5a, and the terminal 3p of the connector 3a. Connected to (-).

  As described above, even when charging is performed using one connector 3a in a state where the connector 3b and the jumper plug 4b are not connected, the battery B1 can be charged from the charging device 2 via the switch SW1. Further, since the positive terminal (+) of the motor MG connected to the terminal 1p of the connector 3a is in an open state, current can be prevented from flowing to the motor MG.

(6) When charging is performed by connecting the connector 3b and the charging connector 5b (when charging is performed by using one connector 3b), the switch SW1 is in a cut-off state and the positive wiring of the charging cable 7b of the charging device 2 is connected. The positive terminal (+) to be connected is connected to the positive terminal (+) of the battery B1 via the positive wiring of the charging cable 7b, the terminal 5p of the charging connector 5b, and the terminal 5p of the connector 3b.

  The negative terminal (−) connected to the negative wiring of the charging cable 7b of the charging device 2 is connected to the negative terminal of the battery B1 via the negative wiring of the charging cable 7b, the terminal 6p of the charging connector 5b, and the terminal 6p of the connector 3b. Connected to (-).

  Thus, even when charging is performed using one connector 3b, charging from the charging device 2 to the battery B1 can be performed. When the connector 3a and the jumper plug 4a are not connected, the positive terminal (+) of the motor MG connected to the terminal 4p of the connector 3b is in an open state, so that no current flows to the motor MG. Further, even when the connector 3a and the jumper plug 4a are connected, since the switch SW1 is in the cut-off state, current can be prevented from flowing to the motor MG.

  That is, one terminal of the switch SW1 is connected to the terminal 2p of the connector 3a, and the other terminal of the switch SW1, the terminal 5p of the connector 3b, and the positive terminal of the battery B1 are connected to provide the power storage device 21. Charging can be performed using only one of the two connectors 3a and 3b. Further, if the jumper plugs 4a and 4b are not connected to the connectors 3a and 3b, current can be prevented from flowing from the battery B1 to the motor MG.

<Embodiment 2>
FIG. 3 is a diagram illustrating an example of the power storage device 31 according to the second embodiment. The power storage device 31 of the second embodiment is connected to the charging device 2 and the motor MG (load). The power storage device 31 includes a connector 3a (first connector), a connector 3b (second connector), a diode D1 (conduction part), and a battery B1.

  The connector 3a has a terminal 1p (first terminal), a terminal 2p (second terminal), and a terminal 3p (third terminal). Connector 3a is connected to jumper plug 4a when power is supplied from battery B1 to motor MG to drive motor MG (when discharging). The connector 3a is connected to the charging connector 5a (first charging connector) when charging is performed by supplying power from the charging device 2 to the battery B1 (during charging).

  The connector 3b has a terminal 4p (fourth terminal), a terminal 5p (fifth terminal), and a terminal 6p (sixth terminal). The connector 3b is connected to the jumper plug 4b when power is supplied from the battery B1 to the motor MG to drive the motor MG (during discharging). The connector 3b is connected to the charging connector 5b (second charging connector) when charging is performed by supplying power from the charging device 2 to the battery B1 (during charging).

A circuit of the power storage device 31 in FIG. 3 will be described.
The terminal 1p of the connector 3a is connected to the negative terminal (−) of the motor MG. The terminal 2p of the connector 3a is connected to the cathode terminal of the diode D1 and the terminal 4p of the connector 3b. The terminal 3p of the connector 3a is connected to the positive terminal (+) of the battery B1, the positive terminal (+) of the motor MG, and the terminal 6p of the connector 3b. The terminal 5p of the connector 3b is connected to the negative terminal (−) of the battery B1 and the anode terminal of the diode D1.

  When the connector 3a and the charging connector 5a connected to the connector 3a are connected (when charging), the terminal 2p of the connector 3a is connected to the terminal 2p of the charging connector 5a, and the terminal 3p of the connector 3a is connected to the charging connector 5a. To the terminal 3p.

  The terminal 2p of the charging connector 5a is connected to the negative terminal (−) of the charging device 2 through the negative wiring of the charging cable 7a, and the terminal 3p of the charging connector 5a is charged through the positive wiring of the charging cable 7a. Connected to the positive terminal (+) of the device 2.

  When the connector 3b and the charging connector 5b connected to the connector 3b are connected (when charging), the terminal 5p of the connector 3b is connected to the terminal 5p of the charging connector 5b, and the terminal 6p of the connector 3b is connected to the charging connector 5b. To the terminal 6p.

  The terminal 5p of the charging connector 5b is connected to the negative terminal (−) of the charging device 2 via the negative wiring of the charging cable 7b, and the terminal 6p of the charging connector 5b is charged via the positive wiring of the charging cable 7b. Connected to the positive terminal (+) of the device 2.

  When the connector 3a and the jumper plug 4a connected to the connector 3a are connected, the terminal 1p of the connector 3a and the terminal 2p of the connector 3a are short-circuited by the jumper wire 6a of the jumper plug 4a.

  When the connector 3b and the jumper plug 4b connected to the connector 3b are connected, the terminal 4p of the connector 3b and the terminal 5p of the connector 3b are short-circuited by the jumper wire 6b of the jumper plug 4b.

An operation of charging the power storage device 31 of FIG. 3 will be described.
(7) When the connector 3a is connected to the charging connector 5a and the connector 3b is connected to the charging connector 5b for charging (when charging is performed using the two connectors 3a and 3b), the negative terminal of the battery B1 (-) Is connected to the anode terminal of the diode D1, the cathode terminal of the diode D1, the terminal 2p of the connector 3a, the terminal 2p of the charging connector 5a, the negative wiring of the charging cable 7a, and the negative wiring of the charging cable 7a of the charging device 2. Connected to the negative terminal (−).

  The positive terminal (+) of the battery B1 is connected to the positive terminal of the charging cable 7a of the charging device 2 via the terminal 3p of the connector 3a, the terminal 3p of the charging connector 5a, and the positive terminal of the charging cable 7a. Connected to (+).

  The negative terminal (−) of the battery B1 is connected to the negative terminal of the charging cable 7b of the charging device 2 via the terminal 5p of the connector 3b, the terminal 5p of the charging connector 5b, and the negative terminal of the charging cable 7b. Connected to (-).

  The positive terminal (+) of the battery B1 is a positive terminal connected to the positive wiring of the charging cable 7b of the charging device 2 via the terminal 6p of the connector 3b, the terminal 6p of the charging connector 5b, and the positive wiring of the charging cable 7b. Connected to (+).

  In this way, even when charging is performed using the two connectors 3a and 3b, the battery B1 can be charged from the charging device 2 via the diode D1. Further, since the positive terminal (+) of the motor MG connected to the terminal 1p of the connector 3a is in an open state, current can be prevented from flowing to the motor MG.

(8) When charging is performed by connecting the connector 3a and the charging connector 5a in a state where the connector 3b and the jumper plug 4b are not connected (when charging is performed using one connector 3a), the battery B1 The negative terminal (−) is the anode terminal of the diode D1, the cathode terminal of the diode D1, the terminal 2p of the connector 3a, the terminal 2p of the charging connector 5a, the negative wiring of the charging cable 7a, and the negative wiring of the charging cable 7a of the charging device 2. Connected to the negative terminal (−) to be connected.

  The positive terminal (+) of the battery B1 is connected to the positive terminal of the charging cable 7a of the charging device 2 via the terminal 3p of the connector 3a, the terminal 3p of the charging connector 5a, and the positive terminal of the charging cable 7a. Connected to (+).

  Thus, even when charging is performed using one connector 3a in a state where the connector 3b and the jumper plug 4b are not connected, the battery B1 can be charged from the charging device 2 via the diode D1. Further, since the positive terminal (+) of the motor MG connected to the terminal 1p of the connector 3a is in an open state, current can be prevented from flowing to the motor MG.

(9) When charging is performed by connecting the connector 3b and the charging connector 5b (when charging is performed using one connector 3b), the negative terminal (−) of the battery B1 is the terminal 5p of the connector 3b, the charging connector. The negative electrode terminal (−) connected to the negative electrode wiring of the charging cable 7b of the charging device 2 is connected via the terminal 5p of 5b and the negative electrode wiring of the charging cable 7b.

  The positive terminal (+) of the battery B1 is a positive terminal connected to the positive wiring of the charging cable 7b of the charging device 2 via the terminal 6p of the connector 3b, the terminal 6p of the charging connector 5b, and the positive wiring of the charging cable 7b. Connected to (+).

  Thus, even when charging is performed using one connector 3b, charging from the charging device 2 to the battery B1 can be performed. When the connector 3a and the jumper plug 4a are not connected, the positive terminal (+) of the motor MG connected to the terminal 4p of the connector 3b is in an open state, so that no current flows to the motor MG. Even when the connector 3a and the jumper plug 4a are connected, the diode D1 is provided, so that no current flows to the motor MG.

  That is, by connecting the cathode terminal of the diode D1 and the terminal 2p of the connector 3a, and connecting the anode terminal of the diode D1, the terminal 5p of the connector 3b, and the negative terminal of the battery B1, the two power storage devices 31 are provided. Charging can be performed using only one of the connectors 3a and 3b. Further, if the jumper plugs 4a and 4b are not connected to the connectors 3a and 3b, current can be prevented from flowing from the battery B1 to the motor MG.

<Modification 2>
FIG. 4 is a diagram illustrating an example of the power storage device 41 according to the second modification. The power storage device 41 of Modification 2 is connected to the charging device 2 and the motor MG (load). The power storage device 41 includes a connector 3a (first connector), a connector 3b (second connector), a switch SW1 (conduction unit), a battery B1, and a control unit 22. The difference between the second embodiment and the second modification is that the diode D1 shown in FIG. 3 is replaced with a switch SW1 and a control unit 22 as shown in FIG.

For example, a relay or a semiconductor element may be used as the switch SW1.
As the control unit 22, for example, a CPU, a multi-core CPU, and a circuit using a programmable device can be considered.

A circuit of the power storage device 41 in FIG. 4 will be described. The description of the same configuration as in FIG. 3 is omitted.
The terminal 2p of the connector 3a is connected to one terminal of the switch SW1 and the terminal 4p of the connector 3b. The terminal 5p of the connector 3b is connected to the negative terminal (−) of the battery B1 and the other terminal of the switch SW1.

Moreover, the control part 22 acquires the connection detection signal which shows that the connector 3a and the charge connector 5a were connected, and makes switch SW1 into a conduction | electrical_connection state from an interruption | blocking state.
An operation of charging the power storage device 41 in FIG. 4 will be described.

(10) When the connector 3a and the charging connector 5a are connected, and the connector 3b and the charging connector 5b are connected for charging (when charging is performed using the two connectors 3a and 3b), the switch SW1 is in a conductive state. The negative terminal (−) of the battery B1 is connected to the switch SW1, the terminal 2p of the connector 3a, the terminal 2p of the charging connector 5a, the negative wiring of the charging cable 7a, and the negative wiring of the charging cable 7a of the charging device 2. Connected to the negative terminal (-).

  The positive terminal (+) of the battery B1 is connected to the positive terminal of the charging cable 7a of the charging device 2 via the terminal 3p of the connector 3a, the terminal 3p of the charging connector 5a, and the positive terminal of the charging cable 7a. Connected to (+).

  The negative terminal (−) of the battery B1 is connected to the negative terminal of the charging cable 7b of the charging device 2 via the terminal 5p of the connector 3b, the terminal 5p of the charging connector 5b, and the negative terminal of the charging cable 7b. Connected to (-).

  The positive terminal (+) of the battery B1 is a positive terminal connected to the positive wiring of the charging cable 7b of the charging device 2 via the terminal 6p of the connector 3b, the terminal 6p of the charging connector 5b, and the positive wiring of the charging cable 7b. Connected to (+).

  As described above, even when charging is performed using the two connectors 3a and 3b, the battery B1 can be charged from the charging device 2 via the switch SW1. Further, since the positive terminal (+) of the motor MG connected to the terminal 1p of the connector 3a is in an open state, current can be prevented from flowing to the motor MG.

(11) When the connector 3b is not connected to the jumper plug 4b and the connector 3a and the charging connector 5a are connected for charging (when charging is performed using one connector 3a), the switch SW1 is The battery B1 becomes conductive and the negative terminal (−) of the battery B1 is connected to the switch SW1, the terminal 2p of the connector 3a, the terminal 2p of the charging connector 5a, the negative wiring of the charging cable 7a, and the negative wiring of the charging cable 7a of the charging device 2. Connected to the negative terminal (−).

  The positive terminal (+) of the battery B1 is connected to the positive terminal of the charging cable 7a of the charging device 2 via the terminal 3p of the connector 3a, the terminal 3p of the charging connector 5a, and the positive terminal of the charging cable 7a. Connected to (+).

  As described above, even when charging is performed using one connector 3a in a state where the connector 3b and the jumper plug 4b are not connected, the battery B1 can be charged from the charging device 2 via the switch SW1. Further, since the positive terminal (+) of the motor MG connected to the terminal 1p of the connector 3a is in an open state, current can be prevented from flowing to the motor MG.

(12) When charging is performed by connecting the connector 3b and the charging connector 5b (when charging is performed using one connector 3b), the switch SW1 is in the cut-off state, and the negative terminal (−) of the battery B1 is the connector. The terminal 5p of 3b, the terminal 5p of the charging connector 5b, and the negative wiring of the charging cable 7b are connected to the negative terminal (−) connected to the negative wiring of the charging cable 7b of the charging device 2.

  The positive terminal (+) of the battery B1 is a positive terminal connected to the positive wiring of the charging cable 7b of the charging device 2 via the terminal 6p of the connector 3b, the terminal 6p of the charging connector 5b, and the positive wiring of the charging cable 7b. Connected to (+).

  Thus, even when charging is performed using one connector 3b, charging from the charging device 2 to the battery B1 can be performed. When the connector 3a and the jumper plug 4a are not connected, the positive terminal (+) of the motor MG connected to the terminal 4p of the connector 3b is in an open state, so that no current flows to the motor MG. Further, even when the connector 3a and the jumper plug 4a are connected, since the switch SW1 is in the cut-off state, current can be prevented from flowing to the motor MG.

  That is, two terminals provided in the power storage device 41 are connected to one terminal of the switch SW1 and the terminal 2p of the connector 3a, and to the other terminal of the switch SW1, the terminal 5p of the connector 3b, and the negative terminal of the battery B1. Charging can be performed using only one of the connectors 3a and 3b. Further, if the jumper plugs 4a and 4b are not connected to the connectors 3a and 3b, current can be prevented from flowing from the battery B1 to the motor MG.

  In the first embodiment, the first modification, the second embodiment, and the second modification, an example in which the charging device 2 is one and the charging device 2 includes the charging cables 7a and 7b has been described. However, two charging devices are used. The power storage device may be charged.

  The present invention is not limited to the above-described embodiment, and various improvements and modifications can be made without departing from the gist of the present invention.

1, 2, 31, 41 Power storage device 2 Charging device 3a, 3b Connector 4a, 4b Jumper plug 5a, 5b Charging connector 6a, 6b Jumper wire 7a, 7b Charging cable 22 Controller B1 Battery D1 Diode MG Motor SW1 Switch

Claims (3)

A first connector, a second connector, and a conductive portion;
The first connector has a first terminal, a second terminal, and a third terminal;
The second connector has a fourth terminal, a fifth terminal, and a sixth terminal;
The first terminal is connected to one terminal of a load;
The second terminal is connected to one terminal of the conductive portion and the fourth terminal,
The third terminal is connected to one terminal of the battery, the other terminal of the load, and the sixth terminal,
The fifth terminal is connected to the other terminal of the battery and the other terminal of the conducting part,
When the first charging connector and the first charging connector connected to the first connector are connected, the second terminal is connected to one terminal of the first charging connector, The three terminals are connected to the other terminal of the first charging connector,
When the second connector and the second charging connector connected to the second connector are connected, the fifth terminal is connected to one terminal of the second charging connector, Six terminals are connected to the other terminal of the second charging connector,
When the first connector and the first jumper plug connected to the first connector are connected, the first terminal and the second terminal are jumper wires of the first jumper plug. Is short-circuited by
When the second jumper plug connected to the second connector and the second connector are connected, the fourth terminal and the fifth terminal are jumper wires of the second jumper plug. Shorted by
A power storage device. The power storage device according to claim 1,
When one terminal of the load is a positive terminal and the other terminal is a negative terminal, one terminal of the battery is a negative terminal and the other terminal is a positive terminal, and the conducting part is a diode, one of the diodes The terminal is the anode terminal and the other terminal is the cathode terminal.
Or, when one terminal of the load is a negative terminal and the other terminal is a positive terminal, one terminal of the battery is a positive terminal and the other terminal is a negative terminal, and the conduction part is a diode, One terminal is the cathode terminal and the other terminal is the anode terminal.
A power storage device. The power storage device according to claim 1,
When the conduction part is a switch, when the first charging connector is connected to the first connector, the switch shifts from a cut-off state to a conduction state.
A power storage device.

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