KR101437019B1 - Power feed system for electric vehicle - Google Patents

Abstract

The control device 3 generates a switching signal for changing the operation of the bidirectional power supply to either the charging operation or the supplying operation based on both the power supplied from the DC power supply and the power required for the distribution circuit 10 side . The bidirectional power supply device 2 includes a control unit 23 configured to cause the electric vehicle 60 to change its operation to either the charging operation of the battery 62 or the supplying operation of the battery based on the switching signal; A DC-DC converter 21 configured to convert the voltage value of the DC power from the battery DC distribution board 1 and supply it to the battery 62 of the electric vehicle 60; And a DC-DC converter 22 configured to convert the voltage value of the DC power from the battery 62 of the electric vehicle 60 and supply it to the DC distribution board 1

Description

[0001] POWER FEED SYSTEM FOR ELECTRIC VEHICLE [0002]

The present invention generally relates to a power supply system for an electric vehicle.

In recent years, electric vehicles such as a Plug-in Hybrid Vehicle (PHV) or a Battery Electric Vehicle (BEV) have been developed. As a method of charging an electric vehicle, it has been considered to charge the electric vehicle by supplying alternating current power through an outlet of the house to the electric vehicle.

It has also been studied to supply electric power to an electric device of a house by discharging the battery of the electric vehicle when a power failure occurs during the supply of commercial AC power to the electric vehicle for charging the battery (for example, See Publication No. 2006-158084).

In the system disclosed in the patent document, when the electric vehicle is charged, commercial AC power is supplied to the electric vehicle and AC is converted into direct current (DC) in the electric vehicle to charge the battery. Therefore, there is a problem that conversion loss occurs when converting AC to DC. Similarly, when discharging the electric vehicle, the DC power accumulated in the battery is converted into AC power and supplied to the house side. Therefore, there is a problem that conversion loss occurs when DC is converted to AC.

It is an object of the present invention to omit the steps of AC-DC conversion and / or DC-AC conversion when charging the battery of an electric vehicle and / or discharging the battery to supply electric power to the house, And to provide a power supply system for an electric vehicle which can efficiently use the power supply system.

In order to achieve the above object, the present invention provides a DC distribution board including a distribution circuit configured to distribute DC power from one or more DC power supplies to a plurality of outputs; A charging operation for supplying DC power from the DC distribution panel to the battery of the electric vehicle and a feeding operation for supplying DC power from the battery of the electric vehicle to the DC switchboard Bidirectional power supply; And a switching circuit configured to generate a switching signal for changing the operation of the bidirectional power supply to either the charging operation or the supplying operation based on both the power supplied from the one or more DC power supply devices and the power required for the distribution circuit side And a control device. Wherein the bidirectional power supply device is configured to cause the electric vehicle to change its operation to either a charging operation of the battery or a supplying operation of the battery based on a switching signal generated by the control device; A supply unit on the vehicle side configured to supply DC electric power from the DC distributor to the electric vehicle when the electric vehicle is charged; And a supply part on the distribution board side configured to supply DC power from the electric vehicle to the DC distribution board when the electric vehicle discharges.

According to the present invention, when charging the battery of the electric vehicle, the DC electric power is supplied from the DC distribution board through the bidirectional electric power supply to the electric vehicle. Therefore, there is no need to convert AC to DC on the electric vehicle side. For this reason, there is no conversion loss for converting AC to DC. Further, when the battery of the electric vehicle is discharged to supply electric power from the electric vehicle side, the bidirectional electric power supply device directly supplies the DC power accumulated in the battery of the electric vehicle to the DC distribution panel. Therefore, there is no need to convert the DC power supplied from the electric vehicle to AC power. Therefore, no conversion loss occurs for converting DC to AC. Therefore, the power can be used efficiently.

In one embodiment, the DC distribution panel is disposed in a building. The electric vehicle further includes a charge-discharge part for charging and discharging the battery, and a charging / discharging control part for controlling the operation of the charging part. Wherein the bidirectional power supply device is configured to supply DC power supplied from the DC distribution panel to the entire portion of the electric vehicle during the charging operation and to supply DC power to the DC distribution panel from the charging discharge portion of the electric vehicle And is configured to supply the supplied DC power. Wherein the control unit of the bidirectional power supply unit controls the operation of the charging / discharging control unit of the electric vehicle based on the switching signal generated by the control unit through the charging / discharging control unit of the electric vehicle, Supply operation.

In one embodiment, the one or more DC power supplies include a battery, the battery configured to be charged by DC power supplied from another DC power supply, and configured to discharge when the other DC power supply has stopped supplying power do. And the battery is configured to be charged by the DC power supplied from the supply portion of the DC distributing portion when the electric vehicle discharges.

According to this embodiment, the DC power discharged from the battery of the electric vehicle can be reserved in the battery.

The preferred embodiments of the present invention will now be described in more detail. Other features and advantages of the present invention will become better understood with regard to the following detailed description and the accompanying drawings.
1 is a diagram showing a system configuration of an embodiment of the present invention.
2 is a diagram showing a system configuration of another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

An embodiment of a power supply system for an electric vehicle is not only configured to charge a battery of an electric vehicle by supplying DC electric power to the electric vehicle such as a plug-in hybrid vehicle (PHV) or a battery electric vehicle (BEV) And discharges the battery of the electric vehicle when the electricity shortage occurs, thereby supplying power accumulated in the battery of the electric vehicle to the house. In this embodiment, a configuration in which such a power supply system for an electric vehicle is applied to a single-family house will be described. Naturally, however, the electric power supply system for an electric vehicle can be applied to a collective housing, an office or other buildings, and the like.

Figure 1 shows a schematic diagram of a power supply system for an electric vehicle. The power supply system for an electric vehicle includes a DC distribution board 1, a bidirectional power supply 2, a control device 3 and a setting / display device 4. [ The DC distribution board 1 is arranged in the house H and is configured to supply the DC power supplied from the DC power supply unit to a branch circuit installed in the house H. [ The bidirectional power supply 2 has a charging operation for supplying the battery of the electric vehicle with DC power from the DC distribution board 1 and a supplying operation for supplying the DC distribution board 1 with DC power from the battery of the electric vehicle . For example, the bi-directional power supply 2 is configured to perform either a charging operation or a supplying operation. The bidirectional power supply device 2 supplies the DC power supplied from the DC distribution board 1 to the charging and discharging circuit 63 of the electric vehicle 60 in the charging operation. The bidirectional power supply device 2 supplies DC power supplied from the charging / discharging circuit 63 of the electric vehicle 60 to the DC distribution board 1 in the supplying operation.

The electric vehicle 60 includes a connector 61, a battery 62 such as a lithium ion battery, a charge / discharge circuit 63, a communication circuit 64, and a charge / discharge control circuit 65. The connector 21 is configured to be detachably attached to a feed connector 26. Here, the power supply connector 26 is installed at the end of the charging cable CA drawn out from the bidirectional power supply 2. The charge / inversion circuit 63 is configured to charge and discharge the battery 62. The communication circuit 64 is configured to communicate with the bi-directional power supply 2. The charge / discharge control circuit 65 controls the operation of the charge / discharge circuit 63 based on the switching signal supplied from the bidirectional power supply device 2 and received by the communication circuit 64, One.

The DC distribution board (1) is based on a 300 V class DC voltage. The DC distribution board 1 includes a cooperation control unit 11 and a plurality of DC circuit breakers. The cooperative control unit 11 is configured to combine the DC power supplied from the plurality of DC power supply units and supply the combined DC power to the load circuit. The plurality of DC circuit breakers 12 are connected between the output terminal of the cooperative control section 11 and the branch circuits of the plurality of systems, respectively. Each DC circuit breaker 121 has an output terminal to be connected to the branch circuit. In this embodiment, the distribution circuit 10 includes a plurality of DC circuit breakers 12. The DC distribution board 1 includes a DC-DC converter 13, a DC-DC converter 14, a DC-DC converter 15 and an AC-DC converter 16. The DC-DC converter 13 is configured to convert the DC voltage generated by the photovoltaic facility 50 into a DC voltage of a predetermined voltage value. The DC-DC converter 14 is configured to convert the DC voltage generated by the fuel cell 51 into a DC voltage of a predetermined voltage value. The DC-DC converter 15 is configured to convert the DC voltage supplied from the battery 52 to a DC voltage of a predetermined voltage value. Here, the battery 52 is configured to be charged by another DC power supply, and is configured to be discharged when the other DC power supply stops supplying power. The AC-DC converter 16 is configured to convert the AC power supplied from the commercial AC power supply 100 to DC. The respective output terminals of the DC-DC converters 13 to 15 and the AC-DC converter 16 are connected to the cooperative control section 11 via the DC power line L1. In this embodiment, the photovoltaic apparatus 50, the fuel cell 51, the battery 52, the DC-DC converters 13, 14 and 15, which are configured to convert the output of the corresponding DC power source device into a predetermined voltage value, And an AC-DC converter 16 configured to convert the AC input from the commercial AC power supply 100 to DC, are included as one or more DC power supplies.

The bidirectional power supply device 2 includes a DC-DC converter (supply part on the vehicle side) 21, a DC-DC converter (supply part on the distribution side) 22, an interface part 24, a communication part 25, 23). The DC-DC converter 21 converts the DC power supplied from the DC circuit breaker 12 through the DC power line L2 into the DC power of the voltage value corresponding to the electric vehicle 60, Respectively. The DC-DC converter 22 is configured to convert the voltage value of the DC voltage supplied from the electric vehicle 60 and output it to the DC power line L1. The interface unit 24 is configured to transmit signals to the control device 3. [ The communication unit 25 is configured to communicate with the communication circuit 64 of the electric vehicle 60 via the communication line L4. The control unit 23 is configured to control the operation of the DC-DC converters 21 and 22 based on signals supplied from the controller 3 or the electric vehicle 60. [ A signal transmitted between the communication section 25 of the bidirectional power supply apparatus 2 and the communication circuit 64 of the electric vehicle 60 is transmitted through the dedicated communication line L4 included in the charging cable CA Lt; / RTI > However, the signal can be superimposed on power line L3 and transmitted using power line communication. The signal may be transmitted using short range wireless communication.

The control device 3 has a function of controlling the amount of DC power supplied from the DC distribution board 1. [ The control device 3 is configured to individually control each of the powers supplied from the DC-DC converters 13 to 15 and the AC-DC converter 16, and determines a supply ratio between the plurality of DC power supplies. The control device 3 also has a function of providing the bidirectional power supply device 2 with information on the power supply capability of a plurality of DC power supply devices. The bidirectional power supply device 2 is configured to control the DC-DC converter 21 based on the information on the power supply capability supplied from the control device 3 so that the DC power supplied to the electric vehicle 60 So that the DC power supplied to the vehicle 60 does not exceed the power supply capability of the DC power supply.

The setting / display device 4 includes a liquid crystal display monitor having a touch panel. The setting / display device 4 is configured to display the supply condition of the DC power supply device on the screen. Further, by the touch operation of the operation buttons displayed on the screen, various setting conditions can be set in the control device 3 through the setting / display device 4. [

Now, the charging / discharging operation of the electric vehicle 60 by using the present electric power supply system will be described.

The control device 3 compares the power (supply power) from the DC power supply device with the required power (required power) on the branch circuit side. When the power supplied from the DC power supply is higher than the required power, the control device 3 supplies a switching signal for switching the operation of the bidirectional power supply 2 to the charging operation to the bidirectional power supply 2, The control device 3 causes the bi-directional power supply device 2 to supply electric power to the electric vehicle 60. [ Therefore, the control device 3 causes the bi-directional power supply device 2 to charge the battery 62 of the electric vehicle 60. [ After completing the charging of the battery 62, the controller 3 performs charging of the battery 52 using another DC power supply. After completing the charging of the storage battery 52, the control device 3 converts the DC power supplied from the DC power supply device to AC power through a DC-AC converter (not shown) and supplies the AC power to the AC device Lt; / RTI > On the other hand, when the power supply from the DC power supply is lower than the required power, the controller 3 first discharges the capacitor 52. [ After discharging the capacitor 52, the controller 3 supplies a switching signal for switching the operation of the bidirectional power supply 2 to the supply operation to the bidirectional power supply 2 so that the controller 3 , The bidirectional power supply 2 supplies DC power discharged by the battery 62 of the electric vehicle 60 to the DC distribution board 1 side. That is, this embodiment is configured to switch the operation of the bidirectional power supply 2 to the supply operation when the supply power from the DC power supply is lower than the required power.

In this embodiment, the required power is, for example, the total amount of power required for operation of the load connected to the distribution circuit 10. [ The required power can be set in the control device 3 via the external setting device. For example, the required power is set in the control device 3 through the home server configured to manage the operation of the load. In this case, the home server is connected to a plurality of loads respectively connected to the output of the distribution circuit 10. [ Each load is configured to provide the home server with information about the power required for operation of the home server. The home server manages the information provided from the load and calculates the total amount of power required for the load. The home server transmits the total amount to the control device 3 as a necessary power.

When charging the electric vehicle 60, when the power supply connector 26 of the charging cable CA pulled out of the bidirectional power supply apparatus 2 is connected to the connector 61 of the electric vehicle 60, The control unit 23 of the control unit 2 causes the communication unit 25 to supply the charging information transmission request to the electric vehicle 60 side. Here, the request to transmit the charging information is a request to transmit the charging information regarding the charging voltage and the charging current. When the communication circuit 64 of the electric vehicle 60 receives the charging information transmission request transmitted from the bidirectional power supply 2, the charging / discharging control circuit 65 determines that the communication circuit 64 is the bidirectional power supply (2) to supply charging information regarding the charging voltage and the charging current to the vehicle. After the charging information is received by the communication unit 25 of the bidirectional power supply apparatus 2, the control unit 23 of the bidirectional power supply apparatus 2 transmits the charging information received by the communication unit 25 and the charging information received by the interface unit 24, Based on both of the power supply capability of the DC power supply device acquired from the control apparatus 3 via the DC power distribution device 1, Thereafter, the control unit 23 controls the output of the DC-DC converter 21 using the supply current value and the voltage value requested by the electric vehicle 60 side, .

In this embodiment, the DC power supply obtained by converting the AC output from the photovoltaic apparatus 50, the fuel cell 51, the storage battery 52, and the AC power supply apparatus 100 to DC via the AC-DC converter And is used as a DC power supply device for supplying DC power to the DC distribution board 1. [ In this embodiment, the control apparatus 3 automatically performs a selection process of one or more DC power supply devices for supplying power to the electric vehicle 60 among the plurality of DC power supply devices. In this embodiment, the electric power supplied from the AC-DC converter 16 can be set to the control device 3 via the setting / display device 4. [ For example, the upper limit of the power supplied from the AC-DC converter 16 is set in the control device 3 via the setting / display device 4. [

For example, when charging the battery 62 on the electric vehicle 60 side, the electric power supplied from the AC-DC converter 16 configured to convert the AC input of the commercial AC power supply device 100 to DC is supplied to the setting / Is assumed to be zero using the display device 4 and that there is daylight present (i.e., power generation is performed by the photovoltaic installation 50) and that the power stored in the battery 52 is present do. It is also assumed that the electric vehicle 60 transmits charging information in the form of a charging voltage of DC 300 V and a charging current of 20 A to the bidirectional power supply 2 in response to the charging information transmission request. Thereafter, this charging information is transmitted from the bidirectional power supply apparatus 2 to the control apparatus 3 again. Here, the control device 3 is configured to grasp the power supply capability of each DC power supply device. The power generation of the photovoltaic power generation equipment 50 is 2000 VA and the power generation of the fuel cell 51 is 0 VA and the power supply capability of the battery 52 is 1000 VA and the power generation by the other electronic devices in the house H Suppose there is no power consumption. In this case, the control device 3 determines that the electric power that can be supplied to the electric vehicle 60 is 3000 VA. The control device 3 controls the DC-DC converter 13 and the DC-DC converter 15 and uses the photovoltaic device 50 and the battery 52 as a power supply device, The power supply to the electric vehicle 60 is performed under the condition that the electric current is 10 A.

Next, it is assumed that the other conditions are the same as those described above, and that no daylight is present. In this case, the control device 3 determines that the electric power that can be supplied to the electric vehicle 60 is 1000 VA, which corresponds to the electric power supply capability of the battery 52. [ Thereafter, the control device 3 controls the DC-DC converter 15 and uses the battery 52 as a power supply to charge the electric vehicle 60 on the condition that the charging voltage is 300 V and the charging current is 3.3 A And performs power supply for the power supply.

Next, the power supplied from the AC-DC converter 16, which is configured to convert the AC input of the commercial AC power supply 100 to DC, is set to 1000 VA and the power stored in the accumulator 52 Suppose power is present and its power supply capability is 1000 VA. In this case, the control device 3 determines that the electric power that can be supplied to the electric vehicle 60 is 2000 VA. Thereafter, the control device 3 is connected to an AC-DC converter 16, which is configured to control the DC-DC converter 15 and the AC-DC converter 16 and to convert the AC input of the commercial AC power supply 100 to DC ) And the battery 52 as a power source device, electric power is supplied to the electric vehicle 60 under the condition that the charging voltage is 300 V and the charging current is 6.6 A.

Here, the control device 3 is configured to automatically select at least one optimum DC power supply device according to a pre-configured selection rule. However, what kind of DC power supply device is preferably used for power supply can be set in the control device 3 using the setting / display device 4.

DC power is supplied from the DC distribution board 1 to the electric vehicle 60 in the manner described above and the battery 62 is charged through the charging and discharging circuit 63 of the electric vehicle 60. [ Here, when the power supply from the DC power supply unit is interrupted, the control unit 3 transmits the switching signal to the electric vehicle 6 through the bidirectional power supply unit 2. [ Then, the charge / discharge circuit 63 of the electric vehicle 60 discharges the battery 62, and DC power is supplied from the battery 62 to the DC distribution board 1 side.

For example, when the electric vehicle 60 is being charged in the nighttime and the power conversion of the commercial AC power supply device 100 is set to the minimum using the setting / display device 4, Suppose the mileage is set at 50 km. The present electric power supply system uses the fuel cell 51 and the storage battery 52 as a power source to charge the electric vehicle 60 and the electric power to the house H because the electric power generating facility 50 does not generate electric power at night, Lt; RTI ID = 0.0 > load. ≪ / RTI > When the power supply capability of the combination of the fuel cell 51 and the battery 52 is lower than the power required for the load in the house H, the control device 3 controls the operation of the bidirectional power supply device 2 in the electric vehicle 60 To the discharging operation (supplying operation) for discharging the battery 62 in the charging operation for charging the battery 62 of the battery 62 to the bidirectional power supply 2. The bidirectional power supply 2 transmits this switching signal to the electric vehicle 60. Then, the charging / discharging control circuit 65 of the electric vehicle 60

Discharging circuit 63 performs a discharging operation (supplying operation) based on the switching signal received by the communication circuit 64 so that the DC power stored in the battery 62 is transmitted through the power line L3 in both directions And is discharged to the power supply device 2. The control unit 23 not only stops the operation of the DC-DC converter 21 according to the switching signal input from the controller 3, but also controls the operation of the DC-DC converter 22 Converts the DC voltage (for example, 300 V) supplied from the electric vehicle 60 into a transmission voltage value (for example, 350 V) corresponding to the electric power line of the house and outputs it to the DC electric power line L1 do. Therefore, this power supply system can supply DC power to the load in the house H by using the battery 62 of the electric vehicle 60 as a power supply.

By the way, when the planned traveling distance the next day is set by using the setting / display device 4, the control device 3 transmits the setting information about the planned mileage to the electric vehicle 60 through the bidirectional power supply device 2. [ Lt; / RTI > The charge / inversion control circuit 65 of the electric vehicle 60 determines the required battery level required to drive the planned mileage based on the setting information supplied from the bidirectional power supply 2. Discharge control circuit 65 compares the remaining battery level of the battery 62 with the required battery level after starting the discharge of the battery 62 in accordance with the switching signal input from the bidirectional power supply 2. [ When the remaining battery level of the battery 62 is lower than the required battery level, the charge / discharge control circuit 65 automatically controls the charge / discharge circuit 63 so as to stop the discharge of the battery 62. Therefore, the battery level required to drive the planned mileage is guaranteed.

The charging / discharging control circuit 65 causes the communication circuit 64 to transmit a discharge stop signal for reporting the interruption of the discharge to the bidirectional power supply device 2 when the discharge of the battery 62 is stopped . When receiving the discharge stop signal, the bidirectional power supply 2 not only stops the operation of the DC-DC converter 22 but also causes the interface 24 to send the discharge stop signal to the control device 3. [ In order to compensate for the power shortage caused by the discharge stop of the electric vehicle 60 when the control device 3 receives the discharge stop signal, the control device activates the AC-DC converter 16, DC converter 16 causes the AC-DC converter 16 to convert the AC power supplied from the commercial AC power supply unit 100 to DC power, and supplies the DC power to the battery 52 and the load.

In this power supply system, when the battery 62 of the electric vehicle 60 is discharged to supply the discharged electric power to the DC electric distribution system of the house H, excessive current flow and / The load of the house H can be protected by the DC circuit breaker 12 and / or the earth leakage breaker (not shown) disposed in the DC distribution board 1. [

As described above, in the electric power supply system for the electric vehicle, when charging the battery 62 of the electric vehicle 60, the DC electric power is supplied from the DC distribution board 1 through the bidirectional electric power supply device 2 to the electric vehicle . Therefore, there is no need to convert AC to DC on the electric vehicle 60 side. For this reason, there is no conversion loss to convert AC to DC. When the battery 62 of the electric vehicle 60 is discharged to supply electric power from the electric vehicle 60 side, the bidirectional electric power supply device 2 is connected to the DC distribution board 1 via the electric vehicle 60, And supplies the DC power stored in the battery 62 of the battery. Therefore, it is not necessary to convert DC power supplied from the electric vehicle 60 into AC power. For this reason, there is no conversion loss to convert DC to AC. Therefore, the power can be used efficiently.

In the electric power supply system for an electric vehicle described above, the battery 52 can be charged with the DC power discharged by the battery 62 of the electric vehicle 60. In this configuration, the DC power accumulated in the battery 62 of the electric vehicle 60 can be effectively used by the load of the house H.

In the electric power supply system for an electric vehicle described above, the bidirectional power supply device 2 includes two DC-DC converters 21 and 22. The DC-DC converter 21 is configured to perform the voltage conversion of the DC power supplied from the house side during charging and supply it to the electric vehicle 60 side. The DC-DC converter 22 is configured to convert the DC power supplied from the electric vehicle 60 at the time of discharging to supply DC power to the house side. However, as shown in FIG. 2, the bidirectional power supply 2 may include one DC-DC converter 27 that is compatible with both charging from the house side and discharging from the vehicle side. Therefore, the DC-DC converter 27 is configured so that its operation is controlled by a control signal supplied from the control unit 23. [ The DC-DC converter 27 is configured to perform voltage conversion of the DC power supplied through the branch circuit breaker (DC circuit breaker) 12 and supply it to the electric vehicle 60 at the time of charging. The DC-DC converter 27 is also configured to perform the conversion of the voltage value of the DC power supplied from the electric vehicle 60 and supply it to the housing side (cooperative control unit 11) at the time of discharging.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art without departing from the spirit and scope of the invention.

Claims (4)

A DC distribution board comprising a distribution circuit configured to distribute DC power from one or more DC power supplies to a plurality of output stages;
A bi-directional power supply configured to perform a charging operation of supplying DC power from the DC distribution panel to a battery of the electric vehicle, and a supplying operation of supplying DC power from the battery of the electric vehicle to the DC distribution panel; And
Configured to generate a switching signal for changing the operation of the bidirectional power supply to either the charging operation or the supplying operation based on both the power supplied from the one or more DC power supply units and the power required for the distribution circuit side controller
Lt; / RTI >
The bidirectional power supply apparatus includes:
A controller configured to cause the electric vehicle to change its operation to either a charging operation of the battery or a supplying operation of the battery based on the switching signal generated by the controller;
A supply unit on the vehicle side configured to supply DC power from the DC distribution panel to the electric vehicle when the electric vehicle is charged; And
And a supply part on the distribution side which is configured to supply DC power from the electric vehicle to the DC distribution board when the electric vehicle discharges,
Wherein the at least one DC power supply comprises a battery configured to be charged by DC power supplied from another DC power supply while being configured to discharge when the other DC power supply stops feeding,
Wherein the control device is configured to charge the battery after charging the battery of the electric vehicle and to discharge the battery of the electric vehicle after discharging the battery. The method according to claim 1,
The DC distribution panel is disposed in a building,
The electric vehicle further includes a charge / discharge unit for charging / discharging the battery, and a charge / discharge control unit for controlling the operation of the charge / discharge unit,
Wherein the bidirectional power supply device is configured to supply DC power supplied from the DC distribution panel to the entire portion of the electric vehicle during the charging operation, To supply DC power supplied from the DC power supply,
Wherein the control unit of the bidirectional power supply unit controls the charge / discharge control unit of the electric vehicle based on a switching signal generated by the control unit, To the power supply of the electric vehicle. 3. The method of claim 2,
Wherein the battery is configured to be charged by DC power supplied from a supply portion on the side of the DC distribution when the electric vehicle discharges. The method according to claim 1,
Wherein the DC distribution board comprises a DC-DC converter and an AC-DC converter as the one or more DC power supplies,
Wherein the operation of the DC-DC converter and the AC-DC converter is controlled by the control device.

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