JP2021121172A - Switching device - Google Patents

Abstract

To provide a switching device enabling more appropriate power feeding to a battery provided in a vehicle.SOLUTION: A switching device is used for power feeding to a battery of a vehicle that has the battery and can travel by using electric power stored in the battery. The switching device includes: a system side connector connectable to an outlet; a vehicle side connector connectable to a plug; a change-over switch enabling switching of connection/disconnection between the system side connector and the vehicle side connector; a communication section performing radio communications with a management device; and a control section for controlling the change-over switch so as to connect or disconnect the system side connector and the vehicle side connector, on the basis of whether or not the communication connection between the switching device and the management device is established within a predetermined time.SELECTED DRAWING: Figure 2

Description

The present invention relates to a switch device.

Conventionally, a technique for supplying electric power to a vehicle that can run by using the electric power stored in a battery has been developed. For example, Japanese Patent Application Laid-Open No. 2013-169869 (Patent Document 1) includes a relay device that relays communication between a vehicle including a power storage unit and a communication unit and a communication device that communicates power supply information regarding power supply to the power storage unit. The communication system is described. The relay device includes a means for communicating power supply information with the vehicle by the first method, a communication device, a means for communicating power supply information by a second method different from the first method, and one of the first method and the second method. A means for generating power supply information to be transmitted by the other method is provided based on the power supply information received by the method of.

Japanese Unexamined Patent Publication No. 2013-169869

Further, in recent years, technologies related to small-scale renewable energy power generation facilities scattered around, facilities such as storage batteries and fuel cells, and VPP (Virtual Power Plant) systems for collectively managing the demand for electric power have been developed. Then, by managing the power supply to the battery provided in the vehicle in a system that can collectively manage the power supply and demand such as the VPP system, there is a technology that can more appropriately supply the power supply to the battery. It has been demanded.

The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to provide a switch device capable of more appropriately supplying power to a battery provided in a vehicle.

(1) In order to solve the above problems, the switch device according to a certain aspect of the present invention is used to supply power to the battery of a vehicle having a battery and capable of traveling using the power stored in the battery. A system-side connector that can be connected to an outlet, a vehicle-side connector that can be connected to a plug, and a changeover switch that can switch between the system-side connector and the vehicle-side connector. The system side connector and the vehicle side connector are connected or disconnected based on the presence or absence of establishment of a communication connection between the communication unit that performs wireless communication with the device and the switch device and the management device within a predetermined time. A control unit for controlling the changeover switch is provided.

The present invention can be realized not only as a switch device provided with such a characteristic processing unit, but also as a charge control method in which the characteristic processing is a step, or to cause a computer to execute such a step. It can be realized as a program of the above, or as a semiconductor integrated circuit that realizes a part or all of the switch device.

According to the present invention, it is possible to more appropriately supply power to the battery provided in the vehicle.

FIG. 1 is a diagram showing a configuration of a charge control system according to the first embodiment of the present invention. FIG. 2 is a diagram showing a configuration of a switch device according to the first embodiment of the present invention. FIG. 3 is a diagram showing an example of a sequence that defines an operating procedure of the charge control system according to the first embodiment of the present invention. FIG. 4 is a diagram showing an example of a flowchart defining an operation procedure of the switch device according to the second embodiment of the present invention.

First, the contents of the embodiments of the present invention will be listed and described.

(1) The switch device according to the embodiment of the present invention is a switch device used to supply power to the battery of a vehicle having a battery and capable of traveling by using the power stored in the battery. A system-side connector that can be connected to an outlet, a vehicle-side connector that can be connected to a plug, a changeover switch that can switch between the system-side connector and the vehicle-side connector, and communication that performs wireless communication with the management device. The changeover switch is connected or disconnected from the system side connector and the vehicle side connector based on the presence or absence of establishment of a communication connection between the unit and its own switch device and the management device within a predetermined time. It is provided with a control unit for controlling.

With such a configuration, the switch device can be notified of the power supply / demand status via the management device from, for example, a renewable energy power generation facility, a storage battery, a fuel cell, or an external device that collectively manages the power demand. Based on the above, it is possible to perform control such as starting and stopping the power supply to the battery. Therefore, it is possible to more appropriately supply power to the battery provided in the vehicle.

(2) Preferably, when the communication connection between the communication unit and the management device is established, the control unit confirms the state of the changeover switch and controls at least one of the changeover switches.

With such a configuration, the switch device can grasp the current state of its own changeover switch and change the state based on the information transmitted from the management device, so that the management device can change the state. It is possible to manage the power supply to the battery and remotely control it.

(3) Preferably, the switch device further includes a measuring unit for measuring the power supplied to the battery, and the control unit is connected to the system side connector when the measurement result by the measuring unit satisfies a predetermined condition. The changeover switch is controlled so that the connection with the vehicle-side connector is disconnected.

With such a configuration, when an abnormality occurs in the power supply to the battery due to, for example, a failure of a device related to power supply, the power supply to the battery can be stopped remotely.

(4) More preferably, the predetermined condition is that the value of the power supply indicated by the measurement result is less than the predetermined value.

With such a configuration, for example, when the charging cable is not connected to the vehicle and the power supply to the battery is zero watt, the risk of electric leakage etc. is avoided by stopping the power supply from the outlet to the plug side. can do.

(5) Preferably, the switch device further includes a detection unit that detects whether or not a charging cable that connects the vehicle-side connector and the vehicle is connected to the vehicle via the plug, and the control unit. When the connection of the charging cable to the vehicle is detected by the detection unit in a state where the connection between the system side connector and the vehicle side connector is disconnected, the system side connector and the vehicle side connector The changeover switch is controlled so that and is connected.

With such a configuration, even if the connection between the system side connector and the vehicle side connector is cut by the changeover switch because the charging cable is not connected to the vehicle, the charging cable is subsequently connected to the vehicle. If this is the case, the system-side connector and the vehicle-side connector are connected via a changeover switch, so that power can be supplied to the battery.

(6) More preferably, the switch device further includes a fuse electrically connected to the system side connector, and the predetermined condition is that the value of the current supplied to the battery indicated by the measurement result is the fuse. It is to reach a predetermined value smaller than the operating current value of.

With such a configuration, it is possible to prevent a current of a predetermined value or more from flowing to the device related to power supply, and to prevent a failure of the device due to an overcurrent. Further, by disconnecting the connection at a value lower than the operating current value of the fuse, it is particularly effective when the device is more vulnerable to overcurrent than general home appliances.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The same or corresponding parts in the drawings are designated by the same reference numerals, and the description thereof will not be repeated. In addition, at least a part of the embodiments described below may be arbitrarily combined.

<First Embodiment>
[Configuration and basic operation]
(Charge control system)
FIG. 1 is a diagram showing a configuration of a charge control system according to the first embodiment of the present invention.

With reference to FIG. 1, the charge control system 201 is a system for supplying power to the battery 61 provided in the vehicle 60, and includes a switch device 101 and a management device 102.

The vehicle 60 is, for example, an EV (Electric Vehicle) or a PHEV (Plug-in Hybrid Electric Vehicle), and can travel using the power stored in the battery 61.

The switch device 101 can be connected to the outlet 121, and in a state of being connected to the outlet 121, operates by receiving the power supplied from the power system via the outlet 121. Further, the plug 131 can be inserted into the switch device 101.

When supplying power to the battery 61, the user inserts the charging cable 141 into the corresponding portion of the vehicle 60. As a result, the charging cable 141 connects the switch device 101 and the vehicle 60 via the plug 131, and the power supplied from the outlet 121 is provided to the vehicle 60 via the switch device 101, the plug 131, and the charging cable 141. It is output to the battery 61.

The management device 102 can perform wireless communication with the switch device 101. The management device 102 is, for example, a HEMS (Home Energy Management System) provided in a facility such as a general household or a factory, and is dotted with small-scale renewable energy power generation facilities, storage batteries, fuel cells, and other facilities, as well as facilities such as storage batteries and fuel cells. It is used in a VPP (Virtual Power Plant) system that collectively manages the demand for electric power.

For example, when the supply and demand of electric power managed in the VPP system is tight, or when the supply and demand of electric power may be tight, the external device that manages a plurality of management devices 102 is instructed to reduce the power consumption. Is transmitted to the management device 102. Then, when the management device 102 receives the power information transmitted from the external device, the management device 102 controls the equipment in the facility so that the power consumption in the facility provided by the management device 102 is suppressed based on the received power information. ..

Specifically, the management device 102 stops the power supply from the power system to the battery 61 by controlling the switch device 101 so that the power supply line L1 inside the switch device 101 is cut off, for example.

(Switch device)
FIG. 2 is a diagram showing a configuration of a switch device according to the first embodiment of the present invention.

With reference to FIG. 2, the switch device 101 includes a system side connector 11, a fuse 12, an AC / DC conversion unit 13, a processing unit 14, a communication unit 15, a sensor (measurement unit) 16, and a changeover switch. 17 and a vehicle-side connector 18.

The processing unit 14 is realized by, for example, a CPU (Central Processing Unit) or a DSP (Digital Signal Processor), and includes a control unit 21 and a detection unit 22.

The system side connector 11 can be connected to the outlet 121. A plug 131 can be inserted into the vehicle-side connector 18. A power supply line L1 for outputting the power supplied from the outlet 121 to the plug 131 side is provided between the system side connector 11 and the vehicle side connector 18.

The fuse 12 is electrically connected to the system side connector 11. More specifically, the fuse 12 is provided between the system side connector 11 and the AC / DC conversion unit 13. When the value of the supply current from the outlet 121 is equal to or greater than the operating current value of the fuse 12, the internal parts of the fuse 12 are blown, so that a current equal to or greater than the operating current value flows to the AC / DC converter 13 side. prevent. The switch device 101 is not limited to the configuration including the fuse 12.

The AC / DC conversion unit 13 converts the AC voltage received from the outlet 121 via the system side connector 11 and the fuse 12 into a DC voltage and outputs the AC voltage to the processing unit 14. The switch device 101 is not limited to the configuration including the AC / DC conversion unit 13.

The sensor 16 measures the power supplied to the battery 61. More specifically, the sensor 16 measures the current or voltage flowing through the power supply line L1 and outputs measurement information indicating the measurement result to the processing unit 14.

The changeover switch 17 is provided on the power supply line L1 and switches the connection between the system side connector 11 and the vehicle side connector 18 by switching to an on state or an off state according to the control by the control unit 21 in the processing unit 14. .. The changeover switch 17 is turned off as an initial state, for example.

When the changeover switch 17 is turned off, the power supply line L1 is cut off, so that the connection between the system side connector 11 and the vehicle side connector 18 is cut off, and the power supply from the outlet 121 to the plug 131 is stopped. do. On the other hand, when the changeover switch 17 is turned on, the power supply line L1 that has been cut off is connected, so that the system side connector 11 and the vehicle side connector 18 are connected, and the system side connector 11 and the vehicle are connected from the outlet 121. Power is supplied to the plug 131 side via the side connector 18.

The control unit 21 in the processing unit 14 outputs the measurement information received from the sensor 16 to the communication unit 15. The communication unit 15 transmits the measurement information received from the control unit 21 to the management device 102 by wireless communication.

The detection unit 22 in the processing unit 14 detects whether or not the charging cable 141 is connected to the vehicle 60. For example, the switch device 101 is provided with a detection line (not shown) connected to the vehicle-side connector 18, and the detection unit 22 monitors the voltage level of the detection line to connect the charging cable 141 to the vehicle 60. The presence / absence of a connection is detected, and the detection information indicating the detection result is transmitted to the management device 102 via the communication unit 15.

The management device 102 transmits control information for controlling the changeover switch 17 in the switch device 101 to the switch device 101 based on the measurement information or the detection information received from the switch device 101.

The communication unit 15 outputs the control information received from the management device 102 to the control unit 14. The control unit 14 turns on or off the changeover switch 17 based on the control information received from the communication unit 15.

The management device 102 is not limited to the case where the measurement information or the detection information is received from the switch device 101, but also in other cases such as when the power information for instructing the suppression of power consumption is received from the external device. The control information for controlling the changeover switch 17 may be transmitted to the switch device 101. A specific example of control of the changeover switch 17 by the management device 102 will be described later.

(Specific example of control of changeover switch)
(A) Example 1
The management device 102 turns on the changeover switch 17 when, for example, a communication connection with the switch device 101 is established within a predetermined time from the activation of the switch device 101.

More specifically, when the switch device 101 is connected to the outlet 121 and is activated by receiving the power supplied from the outlet 121, a connection request for establishing a communication connection with the management device 102 is sent to the management device 102. Send.

Upon receiving the connection request transmitted from the switch device 101, the management device 102 transmits the connection permission for permitting the communication connection to the switch device 101.

When the communication unit 15 in the switch device 101 receives the connection permission transmitted from the management device 102, the communication unit 15 transmits a connection response to the connection permission to the management device 102.

The management device 102 receives, for example, a connection response from the switch device 101 within a predetermined time from the start timing of the switch device 101, that is, the reception timing of the connection request, and when the communication connection with the switch device 101 is established, the changeover switch 17 A request for state information (hereinafter, referred to as "state information request") relating to the state of is transmitted to the switch device 101.

When the switch device 101 receives the status information request transmitted from the management device 102, the switch device 101 transmits, for example, status information indicating that the changeover switch 17 is in the on state or the off state to the management device 102.

For example, when the state information received from the switch device 101 indicates an off state of the changeover switch 17, the management device 102 transmits control information to the effect that the changeover switch 17 is turned on to the switch device 101.

Then, when the communication connection with the switch device 101 is established as described above, the management device 102 gives a predetermined notification. For example, the management device 102 establishes a communication connection with the switch device 101 by lighting an LED (Light Emitting Diode) provided in the management device 102 or remotely lighting an LED provided in the switch device 101. Notify the user that this has been done.

Further, for example, when the state information received from the switch device 101 indicates the on state of the changeover switch 17, the management device 102 may transmit control information to the effect that the changeover switch 17 is turned on to the switch device 101. It is not necessary to transmit the control information.

Further, when the communication connection with the switch device 101 is established, the management device 102 turns on the changeover switch 17 without transmitting the state information request to the switch device 101 and receiving the state information from the switch device 101. Control information to that effect may be transmitted to the switch device 101.

Further, if the management device 102 does not receive the connection response for a predetermined time or more from the reception timing of the connection request, for example, the management device 102 determines that the communication connection with the switch device 101 cannot be established, and does not transmit the state information request and the control information. .. As a result, the initial state, that is, the off state of the changeover switch 17 continues.

Further, for example, after the communication connection with the switch device 101 is established, the management device 102 transmits a connection confirmation request for confirming the communication state with the switch device 101 to the switch device 101 periodically or irregularly.

When the communication unit 15 in the switch device 101 receives the connection confirmation request transmitted from the management device 102, the communication unit 15 transmits a connection confirmation response to the connection confirmation request to the management device 102.

Then, when the management device 102 receives the connection confirmation response from the switch device 101 within a predetermined time from the transmission timing of the connection confirmation request, for example, it determines that the communication state with the switch device 101 is good, and transmits the control information. Do not do. As a result, the on state of the changeover switch 17 continues.

Further, if the management device 102 does not receive the connection confirmation response for a predetermined time or more from the transmission timing of the connection confirmation request, for example, the management device 102 determines that the communication connection with the switch device 101 has been disconnected. Then, the management device 102 waits until, for example, the connection request from the switch device 101 is received again.

Then, when the management device 102 determines that the communication connection with the switch device 101 cannot be established as described above, or when it determines that the communication connection is disconnected, for example, the LED provided in itself is turned off or turned off. By remotely turning off the LED provided in the switch device 101, the user is notified that the communication connection with the switch device 101 cannot be established or that the communication connection is disconnected.

(B) Example 2
When the measurement result by the sensor 16 satisfies the first condition, the management device 102 turns off the changeover switch 17.

More specifically, when the management device 102 receives the measurement information transmitted from the switch device 101, for example, whether or not the value of the power supplied to the battery 61 indicated by the received measurement information is less than the predetermined value Th1. Check. The predetermined value Th1 is, for example, a value of zero watt or more. Then, the management device 102 determines that the measurement result satisfies the first condition when the value of the power supplied to the battery 61 is less than the predetermined value Th1.

For example, when the charging cable 141 is not connected to the vehicle 60, no current flows through the power supply line L1 in the switch device 101, and the power supplied to the battery 61 is zero watts.

In this case, since the value of the power supply indicated by the measurement information is less than the predetermined value Th1, the management device 102 determines that the measurement result satisfies the first condition, and provides control information to the effect that the changeover switch 17 is turned off. Send to 101.

Then, the management device 102 does not supply power to the battery 61 by, for example, blinking the LED provided in itself or remotely blinking the LED provided in the switch device 101. Notify the user.

When the user connects the charging cable 141 to the vehicle 60, for example, the detection unit 22 in the switch device 101 detects the connection of the charging cable 141 to the vehicle 60, and transmits the detection information indicating the detection result via the communication unit 15. Is transmitted to the management device 102.

Upon receiving the detection information transmitted from the switch device 101, the management device 102 transmits control information to the effect that the changeover switch 17 is turned on to the switch device 101. As a result, the changeover switch 17 switches from the off state to the on state.

Then, the management device 102 can supply power to the battery 61 by, for example, lighting the LED provided in itself or remotely lighting the LED provided in the switch device 101. Notify the user.

(C) Example 3
When the measurement result by the sensor 16 satisfies the second condition, the management device 102 determines that an abnormality has occurred in the power supply to the battery 61, and turns off the changeover switch 17.

More specifically, when the management device 102 receives the measurement information from the switch device 101, for example, it confirms whether or not the value of the supply current to the battery 61 indicated by the received measurement information is a predetermined value Th2 or more. .. The predetermined value Th2 is, for example, a value smaller than the operating current value of the fuse 12.

Then, when an overcurrent of a predetermined value Th2 or more flows through the power supply line L1, that is, when the measurement result satisfies the second condition, the management device 102 determines that the power supply to the battery 61 is abnormal and switches. The control information indicating that the switch 17 is turned off is transmitted to the switch device 101.

Then, the management device 102 does not supply power to the battery 61 by, for example, blinking the LED provided in itself or remotely blinking the LED provided in the switch device 101. Notify the user.

The management device 102 is not limited to the case where the value of the supply current measured by the sensor 16 is a predetermined value Th2 or more, and for example, based on the variation in the value of the supply current measured by the sensor 16 at different timings. It may be determined whether or not an abnormality has occurred in the power supply to the battery 61.

(D) Example 4
The charging cable 141 is provided with, for example, a controller capable of switching between the connection state of the outlet 121 and the vehicle 60. The controller can, for example, shut off the power supply line L2 from the outlet 121 to the vehicle 60 inside the charging cable 141 according to the operation of the user.

For example, suppose that the controller shuts off the power supply line L2 while the charging cable 141 is connected to the vehicle 60. In this case, the detection unit 22 in the switch device 101 detects that the power supply line L2 has been cut off from the monitoring result of the voltage level of the detection line (not shown). Then, the detection unit 22 transmits the detection information indicating the detection result to the management device 102 via the communication unit 15.

When the management device 102 receives the detection information transmitted from the switch device 101, the management device 102 transmits, for example, control information to the effect that the changeover switch 17 is turned off to the switch device 101 based on the received detection information.

Further, for example, when the power supply line L2 that has been cut off is connected by the user operating the controller while the charging cable 141 is connected to the vehicle 60, the detection unit 22 is connected to the power supply line L2. Detect that. Then, the detection unit 22 transmits the detection information indicating the detection result to the management device 102 via the communication unit 15.

When the management device 102 receives the detection information transmitted from the switch device 101, the management device 102 transmits, for example, control information to the effect that the changeover switch 17 is turned on to the switch device 101 based on the received detection information.

(E) Example 5
As described above, when the management device 102 receives the power information for instructing the suppression of the power consumption transmitted from the external device, the management device 102 controls the changeover switch 17 based on the received power information.

For example, when the received power information indicates a power consumption suppression period, the management device 102 transmits control information to the effect that the changeover switch 17 is turned off at the start timing of the suppression period to the switch device 101. Further, the management device 102 transmits control information to the effect that the changeover switch 17 is turned on to the switch device 101 at the end timing of the suppression period.

[Operation flow]
Next, the flow of operation by the charge control system 201 according to the first embodiment of the present invention will be described.

Each device in the charge control system 201 includes a computer, and an arithmetic processing unit such as a CPU in the computer reads a program including a part or all of each step of the following sequence or flowchart from a memory (not shown) and executes the program. The programs of these plurality of devices can be installed from the outside. The programs of these plurality of devices are distributed in a state of being stored in a recording medium.

FIG. 3 is a diagram showing an example of a sequence that defines an operating procedure of the charge control system according to the first embodiment of the present invention.

With reference to FIG. 3, first, when the switch device 101 is connected to the outlet 121 (step S11), the switch device 101 is activated by receiving the power supplied from the outlet 121 (step S12). Then, the changeover switch 17 in the switch device 101 is turned off as an initial state (step S13).

Next, the switch device 101 transmits a connection request to the management device 102 (step S14).

Next, when the management device 102 receives the connection request transmitted from the switch device 101, the management device 102 transmits the connection permission to the management device 102 (step S15).

Next, when the switch device 101 receives the connection permission transmitted from the management device 102, the switch device 101 transmits a connection response to the connection permission to the management device 102 (step S16).

Next, the management device 102 determines whether or not the communication connection with the switch device 101 has been established by confirming whether or not the connection response has been received within a predetermined time from the reception timing of the connection request, for example. Step S17).

Then, when the management device 102 cannot receive the connection response, it determines that the communication connection with the switch device 101 could not be established (“NO” in step S17), and turns off the LED provided in itself, for example. Therefore, the user is notified that the communication connection with the switch device 101 could not be established (step S18). Then, the management device 102 waits until the connection response from the switch device 101 is received.

On the other hand, when the management device 102 receives the connection response transmitted from the switch device 101, it determines that the communication connection with the switch device 101 has been established (“YES) in step S17), and transmits the status information request to the switch device 101. (Step S19).

Next, when the switch device 101 receives the state information request transmitted from the management device 102, the switch device 101 transmits the state information indicating the state of its own changeover switch 17 to the management device 102 (step S20).

Next, for example, when the management device 102 receives the state information indicating that the changeover switch 17 is in the off state from the switch device 101, the management device 102 transmits the control information indicating that the changeover switch 17 is turned on to the switch device 101 (step). S21).

Next, when the switch device 101 receives the control information transmitted from the management device 102, the switch device 101 switches its own changeover switch 17 from the off state to the on state according to the received control information (step S22).

Next, the switch device 101 measures the power supplied to the battery 61 (step S23), and transmits the measurement information indicating the measurement result to the management device 102 (step S24).

Next, the management device 102 confirms whether or not the value of the power supplied to the battery 61 is less than the predetermined value Th1 based on the measurement information received from the switch device 101 (step S25), and goes to the battery 61. It is determined whether or not an abnormality has occurred in the power supply of (step S26).

Then, when the value of the supply power indicated by the measurement information received from the switch device 101 is less than the predetermined value Th1 (“YES” in step S25), the management device 102 has the value of the supply power indicated by the measurement information. When it is determined that an abnormality has occurred in the power supply due to the predetermined value Th1 or more and the value of the supply current indicated by the measurement information being the predetermined value Th2 or more (“NO” in step S25 and “NO” in step S26. YES ”), the control information indicating that the changeover switch 17 is turned off is transmitted to the switch device 101 (step S27).

Then, when the switch device 101 receives the control information transmitted from the management device 102, the switch device 101 switches its own changeover switch 17 from the on state to the off state according to the received control information (step S28).

Then, the management device 102 notifies the user that the power supply to the battery 61 is not being performed by blinking its own LED or remotely blinking the LED provided in the switch device 101 (). Step S29).

On the other hand, the management device 102 supplies power because the value of the supply power indicated by the measurement information received from the switch device 101 is a predetermined value Th1 or more and the value of the supply current indicated by the measurement information is less than the predetermined value Th2. When it is determined that no abnormality has occurred (“NO” in step S25 and “NO” in step S26), the control information is not transmitted, and the on state of the changeover switch 17 continues in the switch device 101. Then, the operations after step S23 are performed again.

In the charge control system 201 according to the first embodiment of the present invention described above, the management device 102 gives a predetermined notification when the communication connection with the switch device 101 cannot be established. However, the configuration is not limited to such a configuration, and the management device 102 may be configured not to notify when the communication connection with the switch device 101 cannot be established.

Further, in the charge control system 201 according to the first embodiment of the present invention described above, the management device 102 turns on the changeover switch 17 when the measurement result by the sensor 16 satisfies the first condition or the second condition. Switch to the off state. However, the present invention is not limited to such a configuration, and the management device 102 does not control the changeover switch 17 based on the measurement result by the sensor 16, and the measurement result by the sensor 16 as in the above-mentioned "(e) Example 5". The changeover switch 17 may be controlled based on information other than the above. In such a case, the switch device 101 does not have to include the sensor 16.

Further, whether or not the measurement result by the sensor 16 satisfies the first condition or the second condition is limited to the method of determining based on the magnitude relationship between the value of the power supply indicated by the measurement result and the predetermined value Th1 or the predetermined value Th2. Instead, for example, the determination may be made based on the variation in the value of the supplied power indicated by the measurement result.

Further, the switch device 101 may be configured not to include the detection unit 22. For example, the switch device 101 is configured to continue the ON state of the changeover switch 17 even if the charging cable 141 is not connected to the vehicle 60 and the value of the power supplied to the battery 61 is zero watt. In this case, even if the switch device 101 is not provided with the detection unit 22, power can be supplied to the battery 61 when the charging cable 141 is connected to the vehicle 60.

By the way, in recent years, technologies related to small-scale renewable energy power generation facilities scattered around, facilities such as storage batteries and fuel cells, and VPP systems for collectively managing the demand for electric power have been developed. Then, by managing the power supply to the battery provided in the vehicle in a system that can collectively manage the power supply and demand such as the VPP system, there is a technology that can more appropriately supply the power supply to the battery. It has been demanded.

On the other hand, in the charge control system 201 according to the first embodiment of the present invention, the switch device 101 is used to supply power to the battery 61 of the vehicle 60 that can travel by using the electric power stored in the battery 61. Be done. Further, the system side connector 11 can be connected to the outlet 121, and the vehicle side connector 18 can be connected to the plug 131. Further, the changeover switch 17 can switch whether or not the system side connector 11 and the vehicle side connector 18 are connected. Further, the communication unit 15 wirelessly communicates with the management device 102, and the control unit 21 controls the changeover switch 17. Further, when the communication connection between the management device 102 and the switch device 101 is established, at least the state information regarding the state of the changeover switch 17 and the control information regarding the control of the changeover switch 17 between the control unit 21 and the management device 102. Either one of the information is sent and received.

With such a configuration, the management device 102 can, for example, grasp the current state of the changeover switch 17 in the switch device 101 and transmit control information for changing the state to the switch device 101. , The switch device 101 can manage the power supply to the battery 61 and remotely control the battery 61.

Further, in the charge control system 201 according to the first embodiment of the present invention, when the communication connection between the management device 102 and the switch device 101 is established, the system side connector 11 and the vehicle side connector 18 are connected or disconnected. The changeover switch 17 is controlled via the control unit 21 so as to.

With such a configuration, for example, the management device 102 is based on the power supply / demand status notified from the power generation equipment of the renewable energy, the equipment such as the storage battery and the fuel cell, and the external device that collectively manages the power demand. Controls such as starting and stopping the power supply to the battery 61 can be performed.

Further, in the charge control system 201 according to the first embodiment of the present invention, the management device 102 gives a predetermined notification when the communication connection with the switch device 101 cannot be established.

Here, in the switch device 101, the connection between the system side connector 11 and the vehicle side connector 18 is disconnected by the changeover switch 17 in the initial state, and when the communication connection with the management device 102 is established, the system side connector 11 and the vehicle It is assumed that the side connector 18 is connected to the side connector 18 via the changeover switch 17. In this case, in the situation where the communication connection between the switch device 101 and the management device 102 cannot be established, the switch device 101 remains in the initial state and the battery 61 cannot be supplied with power. However, as described above, the management device 102 By giving a predetermined notification, the user can grasp that the power supply to the battery 61 is not being performed.

Further, in the charge control system 201 according to the first embodiment of the present invention, the switch device 101 includes a sensor 16 for measuring the power supplied to the battery 61. Further, the management device 102 controls the changeover switch 17 via the control unit 21 so that the connection between the system side connector 11 and the vehicle side connector 18 is disconnected when the measurement result by the sensor 16 satisfies a predetermined condition.

With such a configuration, when an abnormality occurs in the power supply to the battery 61 due to, for example, a failure of a device related to the power supply, the power supply to the battery 61 can be stopped remotely.

Further, in the charge control system 201 according to the first embodiment of the present invention, when the value of the power supply indicated by the measurement result by the sensor 16 is less than the predetermined value Th1, the management device 102 has the system side connector 11 and the vehicle. The changeover switch 17 is controlled via the control unit 21 so that the connection with the side connector 18 is disconnected.

With such a configuration, for example, when the charging cable 141 is not connected to the vehicle 61 and the power supplied to the battery 61 is zero watts, the power supply from the outlet 121 to the plug 131 is stopped to cause an electric leakage or the like. Risk can be avoided.

Further, in the charge control system 201 according to the first embodiment of the present invention, the detection unit 22 in the switch device 101 is the vehicle 60 of the charging cable 141 that connects the vehicle side connector 18 and the vehicle 60 via the plug 131. Detects the presence or absence of a connection to. Further, in the management device 102, when the connection between the system side connector 11 and the vehicle side connector 18 is disconnected and the detection unit 22 detects the connection of the charging cable 141 to the vehicle 60, the system side connector 11 The changeover switch 17 is controlled via the control unit 21 so that the connector 18 and the vehicle side connector 18 are connected.

With such a configuration, even if the connection between the system side connector 11 and the vehicle side connector 18 is disconnected by the changeover switch 17 because the charging cable 141 is not connected to the vehicle 60, charging is performed thereafter. When the cable 141 is connected to the vehicle 60, the system-side connector 11 and the vehicle-side connector 18 are connected via the changeover switch 17, so that power can be supplied to the battery 61.

Further, in the charge control system 201 according to the first embodiment of the present invention, the fuse 12 in the switch device 101 is electrically connected to the system side connector 11. Further, when the value of the supply current to the battery 61 indicated by the measurement result by the sensor 16 reaches a predetermined value Th2 which is smaller than the operating current value of the fuse 12, the management device 102 connects the system side connector 11 and the vehicle side connector 18. The changeover switch 17 is controlled via the control unit 21 so that the connection is disconnected.

With such a configuration, it is possible to prevent a current of a predetermined value Th2 or more from flowing through the device related to power supply, and to prevent the device from failing due to an overcurrent. Further, by disconnecting the connection at a value lower than the operating current value of the fuse 12, it is particularly effective when the device is more vulnerable to overcurrent than general home appliances.

Next, other embodiments of the present invention will be described with reference to the drawings. The same or corresponding parts in the drawings are designated by the same reference numerals, and the description thereof will not be repeated.

<Second Embodiment>
In the first embodiment described above, the management device 102 determines whether to turn on or off the changeover switch 17 in the switch device 101. However, the present invention is not limited to such a configuration, and the switch device 101 may determine whether to turn on or off the changeover switch 17.

[Configuration and basic operation]
With reference to FIG. 2 again, for example, when the communication connection between the management device 102 and the switch device 101 is established within a predetermined time from the activation of the switch device 101, the management device 102 indicates that the communication connection has been established, for example. The indicated communication connection completion information is transmitted to the switch device 101. Then, when the control unit 21 in the switch device 101 receives the communication connection completion information from the management device 102 via the communication unit 15, for example, the state of the changeover switch 17 is confirmed. Then, for example, when the changeover switch 17 is in the off state, the control unit 21 turns on the changeover switch 17.

Further, the control unit 21 does not control the changeover switch 17 when, for example, the changeover switch 17 is in the ON state.

The control unit 21 may be configured to control the changeover switch 17 without checking the state of the changeover switch 17 when the communication connection between the management device 102 and the switch device 101 is established.

Further, for example, when the control unit 21 receives the measurement information indicating the measurement result of the power supplied to the battery 61 from the sensor 16, the control unit 21 turns on or off the changeover switch 17 based on the measurement result indicated by the measurement information.

Specifically, when the measurement information received from the sensor 16 indicates that the value of the power supplied to the battery 61 is less than the predetermined value Th1, the control unit 21 satisfies the first condition in the measurement result by the sensor 16. Then, the changeover switch 17 is turned off.

Further, when the measurement information received from the sensor 16 indicates that the value of the current supplied to the battery 61 is a predetermined value Th2 or more, the control unit 21 determines that the measurement result by the sensor 16 satisfies the second condition. Judgment is made, and the changeover switch 17 is turned off.

Further, the control unit 21 is a changeover switch when, for example, the detection unit 22 detects that the charging cable 141 is connected to the vehicle 60, or the detection unit 22 detects that the power supply line L2 is connected. Turn on 17.

Further, when the control unit 21 receives, for example, the power information transmitted from the external device for instructing the suppression of the power consumption via the management device 102 and the communication unit 15, the changeover switch 17 is based on the received power information. On or off.

Specifically, when the received power information indicates a power consumption suppression period, the control unit 21 turns off the changeover switch 17 when the changeover switch 17 is in the ON state at the start timing of the suppression period. Further, the control unit 21 turns on the changeover switch 17 when the changeover switch 17 is in the off state at the end timing of the suppression period.

[Operation flow]
Next, the flow of operation by the switch device 101 according to the second embodiment of the present invention will be described.

FIG. 4 is a diagram showing an example of a flowchart defining an operation procedure of the switch device according to the second embodiment of the present invention.

With reference to FIG. 4, first, when the switch device 101 is connected to the outlet 121 (step S31), the switch device 101 is activated by receiving the power supplied from the outlet 121 (step S32). Then, the changeover switch 17 in the switch device 101 goes into, for example, an off state as an initial state (step S33).

Next, the switch device 101 transmits a connection request to the management device 102 (step S34). Then, when the switch device 101 receives the connection permission for permitting the communication connection from the management device 102, the switch device 101 transmits a connection response to the received connection permission to the management device 102 (step S35).

Then, for example, when the management device 102 receives the connection response within a predetermined time from the reception timing of the connection request, the management device 102 determines that the communication connection with the switch device 101 has been established, and transmits the communication connection completion information to the switch device 101. ..

Next, the switch device 101 confirms whether or not the communication connection with the management device 102 has been established by confirming whether or not the communication connection completion information has been received from, for example, the management device 102 (step S36).

Then, when the switch device 101 cannot receive the communication connection completion information, it determines that the communication connection with the management device 102 could not be established (“NO” in step S36), and receives, for example, the communication connection completion information. Wait until. When the switch device 101 determines that the communication connection with the management device 102 cannot be established, the switch device 101 cannot establish the communication connection with the management device 102, for example, by turning off the LED provided in the switch device 101. The user may be notified.

On the other hand, when the switch device 101 receives, for example, the communication connection completion information from the management device 102, it determines that the communication connection with the management device 102 has been established (“YES” in step S36), and the state of its own changeover switch 17. Is confirmed (step S37).

Then, for example, when the changeover switch 17 is in the off state, the switch device 101 switches the changeover switch 17 from the off state to the on state (step S38).

Next, the switch device 101 measures the power supplied to the battery 61, and based on the measurement result, confirms whether or not the value of the power supplied to the battery 61 is less than the predetermined value Th1 (step S39), and , It is determined whether or not an abnormality has occurred in the power supply to the battery 61 (step S40).

Then, when the measured supply power value is less than the predetermined value Th1 (“YES” in step S39), or the measured supply power value is the predetermined value Th1 or more and the measured supply is measured by the management device 102. When it is determined that an abnormality has occurred in the power supply because the current value is the predetermined value Th2 or more (“NO” in step S39 and “YES” in step S40), the self-switching switch 17 is turned off from the on state. Switch to state.

Then, the switch device 101 notifies the user that the power supply to the battery 61 is not being performed, for example, by blinking its own LED (step S41).

On the other hand, when the switch device 101 determines that an abnormality has not occurred in the power supply because the measured supply power value is the predetermined value Th1 or more and the measured supply current value is less than the predetermined value Th2. (“NO” in step S39 and “NO” in step S40), the on state of the changeover switch 17 is continued, and the operations after step S39 are performed again.

When the changeover switch 17 is switched from the on state to the off state, the LED of the management device 102 may blink instead of the LED of the switch device 101 blinking.

Further, in the charge control system 201 according to the second embodiment of the present invention described above, the switch device 101 turns on the changeover switch 17 when the measurement result by the sensor 16 satisfies the first condition or the second condition. Switch to the off state. However, the configuration is not limited to such a configuration, and the switch device 101 does not control the changeover switch 17 based on the measurement result by the sensor 16, but controls the changeover switch 17 based on information other than the measurement result by the sensor 16. It may be. In such a case, the switch device 101 does not have to include the sensor 16.

Further, whether or not the measurement result by the sensor 16 satisfies the first condition or the second condition is limited to the method of determining based on the magnitude relationship between the value of the power supply indicated by the measurement result and the predetermined value Th1 or the predetermined value Th2. Instead, for example, the determination may be made based on the variation in the value of the supplied power indicated by the measurement result.

Further, the switch device 101 may be configured not to include the detection unit 22. For example, the switch device 101 is configured to continue the ON state of the changeover switch 17 even if the charging cable 141 is not connected to the vehicle 60 and the value of the power supplied to the battery 61 is zero watt. In this case, even if the switch device 101 is not provided with the detection unit 22, power can be supplied to the battery 61 when the charging cable 141 is connected to the vehicle 60.

Since other configurations and operations are the same as those in the first embodiment, detailed description will not be repeated here.

As described above, the switch device 101 according to the second embodiment of the present invention is used to supply power to the battery 61 of the vehicle 60 that can travel by using the electric power stored in the battery 61. Further, the system side connector 11 can be connected to the outlet 121, and the vehicle side connector 18 can be connected to the plug 131. Further, the changeover switch 17 can switch whether or not the system side connector 11 and the vehicle side connector 18 are connected. In addition, the communication unit 15 wirelessly communicates with the management device 102. Further, the control unit 21 connects or disconnects the system side connector 11 and the vehicle side connector 18 based on whether or not a communication connection between the switch device 101 and the management device 102 is established within a predetermined time. Controls the changeover switch 17.

With such a configuration, the switch device 101 is, for example, a power generation facility for renewable energy, a facility such as a storage battery and a fuel cell, and an external device that collectively manages the demand for electric power. Based on the supply and demand situation, it is possible to perform control such as starting and stopping the power supply to the battery 61.

Further, in the switch device 101 according to the second embodiment of the present invention, the control unit 21 confirms the state of the changeover switch 17 and the changeover switch 17 when the communication connection between the communication unit and the management device is established. Control at least one of the above.

With such a configuration, the switch device 101 can, for example, grasp the current state of its own changeover switch 17 and change the state based on the information transmitted from the management device 102. Therefore, the management device 102 However, the switch device 101 can manage the power supply to the battery 61, remotely control the battery 61, and the like.

Further, in the switch device 101 according to the second embodiment of the present invention, the sensor 16 measures the power supplied to the battery 61. Further, the control unit 21 controls the changeover switch 17 so that the connection between the system side connector 11 and the vehicle side connector 18 is disconnected when the measurement result by the sensor 16 satisfies a predetermined condition.

With such a configuration, when an abnormality occurs in the power supply to the battery 61 due to, for example, a failure of a device related to the power supply, the power supply to the battery 61 can be stopped remotely.

Further, in the switch device 101 according to the second embodiment of the present invention, when the value of the power supply indicated by the measurement result by the sensor 16 is less than the predetermined value Th1, the control unit 21 has the system side connector 11 and the vehicle side. The changeover switch 17 is controlled so that the connection with the connector 18 is disconnected.

With such a configuration, for example, when the charging cable 141 is not connected to the vehicle 61 and the power supplied to the battery 61 is zero watts, the power supply from the outlet 121 to the plug 131 is stopped to cause an electric leakage or the like. Risk can be avoided.

Further, in the switch device 101 according to the second embodiment of the present invention, the detection unit 22 is connected to the vehicle 60 by the charging cable 141 that connects the vehicle side connector 18 and the vehicle 60 via the plug 131. Is detected. Further, in the state where the connection between the system side connector 11 and the vehicle side connector 18 is disconnected, the control unit 21 detects the connection of the charging cable 141 to the vehicle 60 by the detection unit 22, the system side connector 11 The changeover switch 17 is controlled so that the connector 18 and the vehicle side connector 18 are connected.

With such a configuration, even if the connection between the system side connector 11 and the vehicle side connector 18 is disconnected by the changeover switch 17 because the charging cable 141 is not connected to the vehicle 60, charging is performed thereafter. When the cable 141 is connected to the vehicle 60, the system-side connector 11 and the vehicle-side connector 18 are connected via the changeover switch 17, so that power can be supplied to the battery 61.

Further, in the switch device 101 according to the second embodiment of the present invention, the fuse 12 is electrically connected to the system side connector 11. Further, when the value of the supply current to the battery 61 indicated by the measurement result by the sensor 16 reaches a predetermined value Th2 which is smaller than the operating current value of the fuse 12, the control unit 21 connects the system side connector 11 and the vehicle side connector 18. The changeover switch 17 is controlled so that the connection is disconnected.

With such a configuration, it is possible to prevent a current of a predetermined value Th2 or more from flowing through the device related to power supply, and to prevent the device from failing due to an overcurrent. By disconnecting the connection at a value lower than the operating current value of the fuse 12, it is particularly effective when the device is more vulnerable to overcurrent than general home appliances.

It is also possible to appropriately combine some or all of the components and operations of the devices according to the first embodiment and the second embodiment of the present invention.

It should be considered that the above embodiments are exemplary in all respects and not restrictive. The scope of the present invention is shown by the scope of claims rather than the above description, and is intended to include all modifications within the meaning and scope equivalent to the scope of claims.

The above description includes the features described below.

[Appendix 1]
A switch device used to supply power to the battery of a vehicle equipped with a battery and capable of traveling using the electric power stored in the battery.
Equipped with a management device
The switch device is
A system side connector that can be connected to an outlet,
Vehicle side connector that can be connected to the plug,
A changeover switch that can switch between the connection between the system side connector and the vehicle side connector, and
A communication unit that performs wireless communication with the management device,
Including a control unit that controls the changeover switch
When the communication connection between the management device and the switch device is established, at least one of the state information regarding the state of the changeover switch and the control information regarding the control of the changeover switch between the control unit and the management device. One of the information is sent and received,
The management device is a HEMS (Home Energy Management System) installed in a general household or factory facility, and is dotted with small-scale renewable energy power generation equipment, equipment such as storage batteries and fuel cells, and demand for electric power. Used in the VPP (Virtual Power Plant) system that collectively manages
When the management device receives power information for instructing the suppression of power consumption from the external device, the management device switches the connection between the system side connector and the vehicle side connector via the control unit so as to be disconnected. A charge control system that controls the switch.

[Appendix 2]
A switch device used to supply power to the battery of a vehicle equipped with a battery and capable of traveling by using the electric power stored in the battery.
A system side connector that can be connected to an outlet,
Vehicle side connector that can be connected to the plug,
A changeover switch that can switch between the connection between the system side connector and the vehicle side connector, and
A communication unit that wirelessly communicates with the management device,
Control to control the changeover switch so that the system side connector and the vehicle side connector are connected or disconnected based on the presence or absence of establishment of a communication connection between the switch device and the management device within a predetermined time. With a part
The management device is a HEMS (Home Energy Management System) installed in a general household or factory facility, and is dotted with small-scale renewable energy power generation equipment, equipment such as storage batteries and fuel cells, and demand for electric power. Used in the VPP (Virtual Power Plant) system that collectively manages
When the control unit receives power information for instructing the suppression of power consumption from an external device via the management device, the control unit cuts the connection between the system side connector and the vehicle side connector. A switch device that controls the changeover switch via a control unit.

11 System side connector 12 Fuse 13 AC / DC conversion unit 14 Processing unit 15 Communication unit 16 Sensor (measurement unit)
17 Changeover switch 18 Vehicle side connector 21 Control unit 22 Detection unit 60 Vehicle 61 Battery 101 Switch device 102 Management device 121 Outlet 131 Plug 141 Charging cable 201 Charging control system

Claims (6)

The system side connector connected to the outlet and
A vehicle-side connector to which a charging cable plug used for charging the battery mounted on a vehicle traveling by the electric power of the battery with the electric power supplied from the outlet is connected.
A changeover switch for switching the presence or absence of an electrical connection between the system side connector and the vehicle side connector,
A communication unit that wirelessly communicates with the management device,
Whether or not a connection request for establishing a communication connection is transmitted to the management device via the communication unit, and a wireless communication connection with the management device is established within a predetermined time from the transmission of the connection request. Based on this, a switch device including a control unit that controls on / off of the changeover switch. The first aspect of the present invention, wherein the control unit further confirms the state of the changeover switch and controls at least one of the changeover switches when the communication connection between the communication unit and the management device is established. Switch device. The switch device further
It is equipped with a measuring unit that measures the power supplied to the battery.
The control unit further controls the changeover switch so that the connection between the system side connector and the vehicle side connector is disconnected when the measurement result by the measurement unit satisfies a predetermined condition, claim 1 or claim. Item 2. The switch device according to item 2. The switch device according to claim 3, wherein the predetermined condition is that the value of the power supply indicated by the measurement result is less than the predetermined value. The switch device further
A detection unit for detecting whether or not the charging cable connecting the vehicle-side connector and the vehicle via the plug is connected to the vehicle is provided.
Further, when the detection unit detects that the charging cable is connected to the vehicle in a state where the connection between the system side connector and the vehicle side connector is disconnected, the control unit further determines the system side connector. The switch device according to claim 3 or 4, wherein the changeover switch is controlled so that and the vehicle-side connector are connected to each other. The switch device further
It has a fuse that is electrically connected to the system side connector.
The switch device according to claim 5, wherein the predetermined condition is that the value of the supply current to the battery indicated by the measurement result reaches a predetermined value smaller than the operating current value of the fuse.

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