JP2014155377A - Electric vehicle charging device and electric vehicle charging method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To automatically start charging a predetermined electric vehicle after surely confirming that an electric vehicle charging device is connected to the electric vehicle.SOLUTION: An electric vehicle charging device comprises: first cut-off means 3 of which one end is connected to one electrode of a battery 31 in a connector connected state; a first DC power supply section 4 which outputs DC power for charging the battery 31; second cut-off means 5 of which one end is connected to a connector terminal 2a; a second DC power supply section 6 which outputs DC power for operating a vehicle control section 32; a current limit section 7 for limiting a current outputted from the second DC power supply section 6 in such a manner that a voltage drop between power supply input terminals 32a, 32b becomes smaller than a working voltage of the vehicle control section 32; and a connector connection detection section 8 for detecting a voltage between connector terminals 2a and 2b. In the case where the detected voltage is settled between a predetermined range, the second cut-off means 5 is shifted to a conducted state, the first cut-off means 3 is then shifted to a conducted state and charging of the battery 31 is started.

Description

  TECHNICAL FIELD The present invention relates to an electric vehicle charging device and an electric vehicle charging method, and more particularly, to an electric vehicle charging device for charging an electric vehicle such as an electric two-wheeled vehicle (two-wheel EV), and the electric vehicle charging method. About.

  Some electric vehicles such as electric motorcycles have a battery that exceeds a safe voltage. When charging such an electric vehicle, in order to ensure safety, the user connects the electric vehicle and the electric vehicle charging device (hereinafter also simply referred to as “charging device”) with a connector, The procedure was to push the switch to start charging.

  However, in order to reduce the labor of the user, it has been demanded that charging of the battery can be started simply by connecting the charging device to the electric vehicle.

  Patent Document 1 discloses a charging device that calculates a charging start time based on a power supply detection signal, a battery voltage signal, and the like, and starts charging the battery at the charging start time.

JP-A-9-19067

  However, in the case of Patent Document 1, the charging device is connected to a predetermined electric vehicle, that is, an electric vehicle suitable for the charging device, because charging control is performed based on a battery voltage or the like whose value largely changes depending on the remaining battery level. There is a problem that it is practically difficult to reliably confirm that this is done.

  Accordingly, the present invention provides an electric vehicle charging device capable of automatically starting charging of an electric vehicle after reliably confirming that the electric vehicle charging device is connected to a predetermined electric vehicle, and An object is to provide a method for charging an electric vehicle.

An electric vehicle charging device according to an aspect of the present invention includes:
An electric vehicle charging device for supplying electric power to an electric vehicle comprising a battery and a vehicle control unit having first and second power input terminals,
A connector having a first connector terminal connectable to the first power input terminal of the vehicle control unit, and a second connector terminal connectable to the second power input terminal of the vehicle control unit;
In a connector connection state in which the connector is connected to the electric vehicle, a first blocking means having one end connected to one electrode of the battery;
A first output terminal is connected to the other end of the first blocking means, a second output terminal is connected to the other electrode of the battery in the connector connected state, and direct current power for charging the battery is obtained. A first DC power supply unit that outputs from the first and second output terminals;
A second blocking means having one end connected to the first connector terminal;
A third output terminal is connected to the other end of the second shut-off means, a fourth output terminal is connected to the second connector terminal, and DC power for operating the vehicle control unit is supplied to the third output terminal. And a second DC power supply unit that outputs from the fourth output terminal;
It is connected in parallel to the second shut-off means, and the voltage drop between the first and second power input terminals of the vehicle control unit is smaller than the operating voltage of the vehicle control unit in the connector connected state. A current limiting unit that limits the current output from the second DC power supply unit to a predetermined current value and outputs the current to the first connector terminal;
One end connected to the first connector terminal, the other end connected to the second connector terminal, and a connector connection detector for detecting a voltage between the first connector terminal and the second connector terminal;
A charging device controller that controls the first and second shut-off means to a conductive state or a shut-off state;
With
When the voltage between the first connector terminal and the second connector terminal detected by the connector connection detection unit is within a predetermined range, the charging device control unit turns on the second blocking means. The electric power operable by the vehicle control unit is output from the first and second connector terminals, and then the first shut-off unit is turned on to turn on the battery by the first DC power supply unit. Charging is started.

In the electric vehicle charging device,
A connection confirmation signal communication unit that receives a connection confirmation signal that is output when the vehicle control unit completes a connection confirmation between the electric vehicle and the connector;
Whether or not the connection confirmation signal communication unit has received the connection confirmation signal after bringing the second shut-off means into a conducting state and before bringing the first shut-off means into a conducting state. If the connection confirmation signal is received, the first shut-off means may be turned on.

In the electric vehicle charging device,
A charge permission signal communication unit for receiving a charge permission signal output when the vehicle control unit permits charging of the battery;
Whether or not the charging permission signal communication unit has received the charging permission signal after setting the second blocking means to a conductive state and before setting the first blocking means to a conductive state. If the charging permission signal is received, the first shut-off means may be turned on.

In the electric vehicle charging device,
The first DC power supply unit includes an AC / DC converter that converts AC power into DC power,
The charging device control unit stops the AC / DC converter until the charging permission signal is received from the vehicle control unit. When the charging permission signal is received, the charging device control unit sets the first blocking means to a conductive state. Alternatively, the AC / DC converter may be operated.

In the electric vehicle charging device,
The first DC power supply unit includes an AC / DC converter that converts AC power into DC power,
The charging device control unit stops the AC / DC converter until the charging permission signal is received from the vehicle control unit. When the charging permission signal is received, the charging device control unit operates the AC / DC converter and then You may make it make a 1st interruption | blocking means into a conduction | electrical_connection state.

In the electric vehicle charging device,
The predetermined range may be determined based on a possible value of a resistance value between the first and second power input terminals in a state where the vehicle control unit is stopped.

In the electric vehicle charging device,
The current limiting unit may be composed of a constant current diode having one end connected to one end of the second blocking means and the other end connected to the other end of the second blocking means.

An electric vehicle charging method according to an aspect of the present invention includes:
An electric vehicle comprising a battery and a vehicle control unit having first and second power input terminals is charged by an electric vehicle charging device,
The electric vehicle charging device includes: a first connector terminal connectable to the first power input terminal of the vehicle control unit; and a second connector terminal connectable to the second power input terminal of the vehicle control unit. A connector having a connector terminal; in a connector connection state where the connector is connected to the electric vehicle; a first blocking means having one end connected to one electrode of the battery; and a first output terminal being the first The second output terminal is connected to the other electrode of the battery in the connector connected state, and direct current power for charging the battery is supplied to the first and second output terminals. A first DC power supply unit that outputs from, a second blocking means having one end connected to the first connector terminal, and a third output terminal connected to the other end of the second blocking means, Fourth out A second DC power supply unit that is connected to the second connector terminal and outputs DC power for operating the vehicle control unit from the third and fourth output terminals; and the second cutoff A current limiter connected in parallel to the means, one end connected to the first connector terminal, the other end connected to the second connector terminal, and between the first connector terminal and the second connector terminal A connector connection detection unit for detecting the voltage of the battery, and a charging device control unit for controlling the first and second blocking means to a conductive state or a blocked state,
The second DC power supply by the current limiting unit so that a voltage drop between the first and second power input terminals of the vehicle control unit is smaller than an operating voltage of the vehicle control unit in the connector connected state. Limiting the current output from the unit to a predetermined current value and outputting to the first connector terminal;
A first step of confirming whether the voltage between the first connector terminal and the second connector terminal detected by the connector connection detection unit is within a predetermined range by the charging device control unit; ,
When the voltage is within the predetermined range, the charging device control unit causes the second shut-off means to be in a conducting state, thereby supplying the electric power operable by the vehicle control unit to the second DC power supply. A second step of supplying the vehicle control unit from the unit;
A third step of starting charging the battery by the first DC power supply unit by bringing the first shut-off means into a conductive state by the charging device control unit;
It is characterized by providing.

In the method for charging the electric vehicle,
Before performing the third step, the charging device control unit confirms whether or not the charging control signal output when the vehicle control unit permits charging of the battery is received from the electric vehicle. Further comprising 4 steps,
The third step may be performed when the charging permission signal is received from the electric vehicle.

  In the electric vehicle charging device according to one aspect of the present invention, the voltage drop between the first and second power input terminals of the vehicle control unit is smaller than the operating voltage of the vehicle control unit when the current limiting unit is in the connector connected state. In addition, the current output from the second DC power supply unit is limited to a predetermined current value and output to the first connector terminal, and the charging device control unit detects the first and the first detected by the connector connection detection unit. When the voltage between the two connector terminals is within a predetermined range, the second shut-off means is turned on to allow the vehicle control unit to output electric power operable from the first and second connector terminals, and then 1 interruption | blocking means is made into a conduction | electrical_connection state, and the charge of the battery by a 1st DC power supply part is started.

  Thus, by measuring the voltage between the power input terminals of the vehicle control unit without activating the vehicle control unit, it is possible to accurately grasp the load of the electric vehicle connected to the charging device for the electric vehicle. It can be surely confirmed that the charging device is connected to a predetermined electric vehicle. When the voltage between the power input terminals of the vehicle control unit is within a predetermined range, it is determined that the electric vehicle charging device is connected to the predetermined electric vehicle, and the first shut-off means is in the conductive state. Then, charging of the battery by the first DC power supply unit is started.

  Therefore, according to the present invention, it is possible to automatically start charging the electric vehicle after reliably confirming that the electric vehicle charging device is connected to the predetermined electric vehicle.

1 is a block diagram illustrating a schematic configuration of a vehicle charging device and an electric vehicle according to a first embodiment of the present invention. It is a flowchart which shows the charging method of the electric vehicle by the 1st Embodiment of this invention. 5 is a flowchart illustrating a method for charging an electric vehicle according to a second embodiment of the present invention.

  Hereinafter, two embodiments according to the present invention will be described with reference to the drawings.

(First embodiment)
FIG. 1 is a block diagram showing a schematic configuration of an electric vehicle charging device 1 and an electric vehicle 30 according to a first embodiment of the present invention. The electric vehicle charging device 1 is a charging device for supplying electric power for charging to the electric vehicle 30. The electric vehicle 30 is an electric motorcycle (two-wheel EV), an electric vehicle (EV), or the like.

  First, the configuration of the electric vehicle 30 will be described.

  As shown in FIG. 1, the electric vehicle 30 includes a battery 31, a vehicle control unit 32, and an inlet 33.

  The battery 31 is a DC power source for operating a motor (not shown) of the electric vehicle 30 and the like.

  The vehicle control unit 32 includes power input terminals 32a and 32b that input operating power from the electric vehicle charging device 1, a signal terminal 32c that outputs a connection confirmation signal, and a signal terminal 32d that outputs a charge permission signal. The vehicle control unit 32 controls the entire process of the electric vehicle 30 and also monitors the charge state of the battery 31.

  Here, the connection confirmation signal is a signal that is output when the vehicle control unit 32 completes the connection confirmation between the electric vehicle 30 and the connector 2 (described later) of the electric vehicle charging device 1. The charge permission signal is a signal that is output when the vehicle control unit 32 permits the electric vehicle charging apparatus 1 to charge the battery 31. For example, when the battery 31 is fully charged, the vehicle control unit 32 does not output a charge permission signal.

The resistance value between the power input terminals 32 a and 32 b (hereinafter, also referred to as “stop state resistance value”) when the vehicle control unit 32 is stopped is a value determined according to the electric vehicle 30. Further, the stop state resistance value (R) has a certain range depending on the specification of the electric vehicle (for example, the specification with respect to temperature), and can take a value of R ₀ ± ΔR.

  The inlet 33 is an insertion port of the connector 2 of the electric vehicle charging device 1 and includes six inlet terminals 33a to 33e. The inlet terminal 33a is a terminal connected to the power input terminal 32a, and the inlet terminal 33b is a terminal connected to the power input terminal 32b. The inlet terminal 33c is a terminal connected to the signal terminal 32c, and the inlet terminal 33d is a terminal connected to the signal terminal 32d. The inlet terminal 33e is a terminal connected to one electrode (for example, positive electrode) of the battery 31, and the inlet terminal 33f is a terminal connected to the other electrode (for example, negative electrode) of the battery 31.

  As can be seen from FIG. 1, in a state where the connector 2 is connected to the electric vehicle 30 (hereinafter, also simply referred to as “connector connection state”), the connector terminals 2a, 2b, 2c, 2d, 2e and 2f are inlet terminals. Connected to 33a, 33b, 33c, 33d, 33e and 33f, respectively.

  Next, the configuration of the electric vehicle charging device 1 according to the present embodiment will be described.

  As shown in FIG. 1, the electric vehicle charging device 1 includes a connector 2, a first cutoff means 3, a first DC power supply unit 4, a second cutoff means 5, and a second DC power. A supply unit 6, a current limiting unit 7, a connector connection detection unit 8, a charging device control unit 9, a connection confirmation signal communication unit 10, and a charge permission signal communication unit 11 are provided.

  Hereinafter, each component of the charging device 1 for electric vehicles is demonstrated in detail.

  The connector 2 is connected to the inlet 33 when charging the electric vehicle 30. The connector 2 has six connector terminals 2a to 2f. The connector terminal 2 a is a terminal that can be connected to the power input terminal 32 a of the vehicle control unit 32, and the connector terminal 2 b is a terminal that can be connected to the power input terminal 32 b of the vehicle control unit 32. The connector terminal 2 c is a terminal that can be connected to the signal terminal 32 c of the vehicle control unit 32, and the connector terminal 2 d is a terminal that can be connected to the signal terminal 32 d of the vehicle control unit 32. The connector terminals 2e and 2f are terminals for outputting charging power to the battery 31. Here, “connectable” means electrically connected in the connector connection state.

  As shown in FIG. 1, the 1st interruption | blocking means 3 is provided between the output terminal 4a of the 1st DC power supply part 4, and the connector terminal 2e. That is, in the connector connection state, the first blocking means 3 has one end (right end) connected to one electrode of the battery 31 and the other end (left end) connected to the output terminal 4a.

  The first DC power supply unit 4 includes an AC / DC converter that converts commercial AC power into predetermined DC power, and outputs DC power for charging the battery 31 from the output terminals 4a and 4b. As shown in FIG. 1, the output terminal 4 a is connected to the other end (left end) of the first blocking means 3. The output terminal 4b is connected to the connector terminal 2f, and is connected to the other electrode of the battery 31 in the connector connected state. The first DC power supply unit 4 operates before the electric vehicle charging device 1 is connected to the electric vehicle 30 and outputs DC power.

  As shown in FIG. 1, the 2nd interruption | blocking means 5 is provided between the output terminal 6a of the 2nd DC power supply part 6, and the connector terminal 2a. That is, one end (right end) of the second blocking means 5 is connected to the connector terminal 2a, and the other end (left end) is connected to the output terminal 6a.

  The first blocking means 3 and the second blocking means 5 are not particularly limited as long as one end and the other end can be controlled to be in a conductive state or a cutoff state. It is composed of semiconductor switches, relays, and contactors.

  The second DC power supply unit 6 includes an AC / DC converter that converts commercial AC power into predetermined DC power, and outputs DC power for operating the vehicle control unit 32 from the output terminals 6a and 6b. . The output terminal 6a is connected to the other end (left end) of the second blocking means 5, and the output terminal 6b is connected to the connector terminal 2b. The second DC power supply unit 6 operates before the electric vehicle charging device 1 is connected to the electric vehicle 30 via a connector, and outputs DC power.

  As shown in FIG. 1, the current limiting unit 7 is connected in parallel to the second interruption means 5. That is, one end (left end) of the current limiting unit 7 is connected to the output terminal 6a, and the other end (right end) is connected to the connector terminal 2a.

  The current limiting unit 7 limits the current output from the second DC power supply unit 6 to a predetermined current value (I) and outputs it to the connector terminal 2a. More specifically, the current limiting unit 7 is connected to the second DC power supply unit 6 so that the voltage drop between the power input terminals 32a and 32b is smaller than the operating voltage (V) of the vehicle control unit 32 in the connector connection state. The output current is limited to a predetermined current value (I). Specifically, the current value I is smaller than the current value obtained by dividing the operating voltage V by the aforementioned stop state resistance value R. Thus, the resistance value (load) between the power input terminals 32a and 32b can be grasped without starting the vehicle control unit 32.

  The current limiting unit 7 is not particularly limited as long as the current can be limited to a predetermined value, but preferably a constant current diode (CRD) is used. In this case, the current limiting unit 7 is composed of a constant current diode having one end connected to one end of the second blocking means 5 and the other end connected to the other end of the second blocking means 5. Thereby, the current limiting unit 7 can be realized with a simple configuration, and the electric vehicle charging device 1 can be downsized.

  As shown in FIG. 1, the connector connection detector 8 has one end connected to the connector terminal 2a and the other end connected to the connector terminal 2b, and detects the voltage between the connector terminal 2a and the connector terminal 2b. The voltage detected in the connector connection state is a value reflecting the resistance value between the power input terminals 32a and 32b of the vehicle control unit 32.

  The charging device control unit 9 controls the entire processing of the electric vehicle charging device 1. The charging device control unit 9 controls the first cutoff means 3 and the second cutoff means 5 to be in a conductive state or a cutoff state. The charging device control unit 9 controls the switching operation of the first DC power supply unit 4 and the second DC power supply unit 6. The charging device control unit 9 confirms whether or not the connection confirmation signal communication unit 10 has received the connection confirmation signal, and confirms whether or not the charge permission signal communication unit 11 has received the charge permission signal.

  The connection confirmation signal communication unit 10 is connected to the connector terminal 2c and receives the connection confirmation signal described above via the connector 2c. When the connection confirmation signal is received, the connection confirmation signal communication unit 10 notifies the charging device control unit 9 to that effect. In addition, after confirming that the vehicle charging device 1 is in the connector connection state, a connection confirmation signal may be transmitted from the connection confirmation signal communication unit 10 to the electric vehicle 30.

  The charging permission signal communication unit 11 is connected to the connector terminal 2d and receives the above-described charging permission signal via the connector 2d. When the charging permission signal is received, the charging permission signal communication unit 11 notifies the charging device control unit 9 to that effect.

  The charging device control unit 9 confirms whether or not the connection confirmation signal (charge permission signal) is received from the electric vehicle 30 by accessing the connection confirmation signal communication unit 10 (charge permission signal communication unit 11). May be.

  When the voltage between the connector terminals 2a and 2b detected by the connector connection detection unit 8 is within a predetermined range, the charging device control unit 9 operates the vehicle control unit 32 with the second blocking means 5 in a conductive state. The possible electric power is output from the connector terminals 2a and 2b, and then the first cutoff means 3 is turned on to start charging the battery 31 by the first DC power supply unit 4.

The predetermined range is determined based on, for example, a value that the above-described stop state resistance value can take. More specifically, when it is assumed that the stop state resistance value can take a value of R ₀ ± ΔR, the predetermined range is I · (R ₀ −ΔR) or more and I · (R ₀ + ΔR) or less. Here, I is a current value limited by the current limiting unit 7 as described above.

  Although the details will be described later with reference to a flowchart, after the second blocking means 5 is turned on, the first blocking means 3 is preferably turned on after receiving the connection confirmation signal and the charge permission signal. To do. Since the charging of the battery 31 is started after confirming the reception of the charging permission signal, charging is not performed when the battery 31 is fully charged or when the battery 31 is out of order. Reliable charging can be performed.

  As described above, in the electric vehicle charging device 1, the constant current limited by the current limiting unit 7 is caused to flow between the power input terminals 32a and 32b so that the vehicle control unit 32 is not activated, and the power input terminal 32a in that state is supplied. And the voltage between 32b is detected. Thereby, the load of the electric vehicle 30 connected to the charging device 1 for electric vehicles can be grasped | ascertained correctly, and it can be determined whether it is in a connector connection state based on the detected voltage. Thus, in order to determine whether or not the electric vehicle charging device 1 is connected to the electric vehicle 30 using the stop state resistance value determined according to the electric vehicle 30, the electric vehicle charging device 1 is predetermined. It can be confirmed reliably that it is connected to the electric vehicle 30.

  And when it is in a connector connection state, the 1st and 2nd interruption | blocking means 3 and 5 are made into a conduction state, the vehicle control part 32 is started, and charge of the battery 31 is started. For this reason, when charging the electric vehicle 30, the user only has to connect the connector 2 to the inlet 33 of the electric vehicle 30, and the user's labor can be reduced.

  Therefore, according to 1st Embodiment, after confirming reliably that the charging device for electric vehicles is connected to the predetermined | prescribed electric vehicle, charge of an electric vehicle can be started automatically.

  Next, a method for charging an electric vehicle by the electric vehicle charging device 1 having the above-described configuration will be described with reference to FIG. FIG. 2 is a flowchart showing a method for charging an electric vehicle according to the first embodiment.

  Due to the current limiting unit 7, the voltage drop between the power input terminal 32 a (first power input terminal) and the power input terminal 32 b (second power input terminal) of the vehicle control unit 32 in the connector connected state is reduced in the vehicle control unit 32. The current output from the second DC power supply unit 6 is limited to a predetermined current value so as to be smaller than the operating voltage, and is output to the connector terminal 2a (first connector terminal) (step S1).

  Next, the charging device control unit 9 confirms whether or not the voltage between the connector terminal 2a and the connector terminal 2b (second connector terminal) detected by the connector connection detection unit 8 is within a predetermined range ( Step S2). If the voltage is within the predetermined range (S2: Yes), the process proceeds to step S3.

  Next, the charging device control unit 9 brings the second shut-off means 5 into a conducting state, thereby supplying electric power at which the vehicle control unit 32 can operate from the second DC power supply unit 6 to the vehicle control unit 32 ( Step S3). That is, the charging device control unit 9 sets the second shut-off means 5 in a conductive state, and outputs power that allows the vehicle control unit 32 to operate from the connector terminals 2a and 2b.

  By setting the second blocking means 5 to the conductive state, the vehicle control unit 32 is activated to check the connection between the electric vehicle 30 and the connector 2, and when the connection check process is completed, the connection check signal is sent to the signal terminal 32c. Output from. Thereafter, the vehicle control unit 32 confirms the state of charge of the battery 31, and outputs a charge permission signal from the signal terminal 32d when charging is possible.

  Next, the charging device control unit 9 confirms whether or not a charging permission signal is received from the electric vehicle 30 (vehicle control unit 32) (step S4). When the charge permission signal is received (S4: Yes), the process proceeds to step S5.

  Next, charging of the battery 31 by the first DC power supply unit 4 is started by setting the first cutoff means 3 to the conducting state by the charging device control unit 9 (step S5).

  As described above, by outputting a limited current from the connector terminal 2a and detecting the voltage between the connector terminals 2a and 2b, the connector is in a connected state without operating the vehicle control unit 32 of the electric vehicle 30. Confirm whether or not. When the connector is in the connected state, the second blocking means 5 is set in the conducting state, the electric power that allows the vehicle control unit 32 to operate is output from the connector terminals 2a and 2b, and the vehicle control unit 32 is operated. Thereafter, the first blocking means 3 is turned on, charging power is supplied from the first DC power supply unit 4 to the electric vehicle 30, and charging of the battery 31 is started. Thereby, after confirming that the charging device 1 for electric vehicles is connected to the predetermined | prescribed electric vehicle 30, charging of the electric vehicle 30 can be started automatically.

  In the description of the above embodiment, the charging device control unit 9 confirms the reception of the connection confirmation signal and the charging permission signal. However, before receiving these signals, the charging device control unit 9 puts the first blocking means 3 into a conducting state. You may do it. Or after confirming reception of either one of a connection confirmation signal and a charge permission signal, you may make it make the 1st interruption | blocking means 3 into a conduction | electrical_connection state.

  For example, the charging device control unit 9 makes the connection confirmation signal communication unit 10 receive the connection confirmation signal after making the second interruption means 5 conductive and before making the first interruption means 3 conductive. If the connection confirmation signal is received, the first blocking means 3 may be brought into a conducting state. Alternatively, the charging device control unit 9 makes the charging permission signal communication unit 11 receive the charging permission signal after setting the second blocking means 5 to the conductive state and before setting the first blocking means 3 to the conductive state. If it is confirmed whether or not the charging permission signal is received, the first blocking means 3 may be brought into a conducting state.

(Second Embodiment)
Next, a second embodiment of the present invention will be described focusing on differences from the first embodiment.

  The configuration of the electric vehicle charging device 1 is substantially the same as that of the first embodiment, but differs in the following points. That is, in the state before the electric vehicle charging device 1 is connected to the electric vehicle 30, the second DC power supply unit 6 performs a switching operation to output DC power, whereas the second DC power supply unit 6 outputs DC power. The power supply unit 4 is not performing a switching operation.

  FIG. 3 is a flowchart showing a method for charging an electric vehicle according to the second embodiment. As shown in FIG. 3, step S1 to step S4 are the same as those in the first embodiment, and thus detailed description thereof is omitted.

  When the charging permission signal is received from the electric vehicle 30 (step S4: Yes), the charging device control unit 9 sets the first cutoff means 3 in the conductive state, and then the AC / DC converter of the first DC power supply unit 4 is turned on. By operating, charging of the battery 31 by the first DC power supply unit 4 is started (step S5A).

  Note that the first cutoff means 3 may be brought into a conducting state after the AC / DC converter of the first DC power supply unit 4 is operated. That is, the charging device control unit 9 stops the AC / DC converter until the charging permission signal is received from the vehicle control unit 32. When the charging permission signal is received, the charging device control unit 9 operates the AC / DC converter and then performs the first operation. The blocking means 3 may be in a conductive state.

  Thus, in 2nd Embodiment, the charging device control part 9 stops the AC / DC converter of the 1st DC power supply part 4 until it receives a charge permission signal from the vehicle control part 32. Then, after receiving the charging permission signal, the charging device control unit 9 operates the AC / DC converter of the first DC power supply unit 4.

  Thereby, according to 2nd Embodiment, the useless switching operation | movement which does not contribute to charge of the battery 31 can be avoided, and the power consumption of the charging device 1 for vehicles can be reduced.

  Further, as in the first embodiment, according to the second embodiment, after confirming that the electric vehicle charging device is connected to a predetermined electric vehicle, the electric vehicle is automatically charged. Can start.

  Based on the above description, those skilled in the art may be able to conceive additional effects and various modifications of the present invention, but the aspects of the present invention are not limited to the individual embodiments described above. . You may combine suitably the component covering different embodiment. Various additions, modifications, and partial deletions can be made without departing from the concept and spirit of the present invention derived from the contents defined in the claims and equivalents thereof.

DESCRIPTION OF SYMBOLS 1 Electric vehicle charging device 2 Connector 2a, 2b, 2c, 2d, 2e, 2f Connector terminal 3 1st interruption | blocking means 4 1st DC power supply part 4a, 4b Output terminal 5 2nd interruption | blocking means 6 2nd DC power supply unit 6a, 6b Output terminal 7 Current limiting unit 8 Connector connection detection unit 9 Charging device control unit 10 Connection confirmation signal communication unit 11 Charging permission signal communication unit 30 Electric vehicle 31 Battery 32 Vehicle control unit 32a, 32b Power input terminal 32c, 32d Signal terminal 33 Inlet 33a, 33b, 33c, 33d, 33e, 33f Inlet terminal

Claims (9)

An electric vehicle charging device for supplying electric power to an electric vehicle comprising a battery and a vehicle control unit having first and second power input terminals,
A connector having a first connector terminal connectable to the first power input terminal of the vehicle control unit, and a second connector terminal connectable to the second power input terminal of the vehicle control unit;
In a connector connection state in which the connector is connected to the electric vehicle, a first blocking means having one end connected to one electrode of the battery;
A first output terminal is connected to the other end of the first blocking means, a second output terminal is connected to the other electrode of the battery in the connector connected state, and direct current power for charging the battery is obtained. A first DC power supply unit that outputs from the first and second output terminals;
A second blocking means having one end connected to the first connector terminal;
A third output terminal is connected to the other end of the second shut-off means, a fourth output terminal is connected to the second connector terminal, and DC power for operating the vehicle control unit is supplied to the third output terminal. And a second DC power supply unit that outputs from the fourth output terminal;
It is connected in parallel to the second shut-off means, and the voltage drop between the first and second power input terminals of the vehicle control unit is smaller than the operating voltage of the vehicle control unit in the connector connected state. A current limiting unit that limits the current output from the second DC power supply unit to a predetermined current value and outputs the current to the first connector terminal;
One end connected to the first connector terminal, the other end connected to the second connector terminal, and a connector connection detector for detecting a voltage between the first connector terminal and the second connector terminal;
A charging device controller that controls the first and second shut-off means to a conductive state or a shut-off state;
With
When the voltage between the first connector terminal and the second connector terminal detected by the connector connection detection unit is within a predetermined range, the charging device control unit turns on the second blocking means. The electric power operable by the vehicle control unit is output from the first and second connector terminals, and then the first shut-off unit is turned on to turn on the battery by the first DC power supply unit. A charging device for an electric vehicle characterized by starting charging. A connection confirmation signal communication unit that receives a connection confirmation signal that is output when the vehicle control unit completes a connection confirmation between the electric vehicle and the connector;
Whether or not the connection confirmation signal communication unit has received the connection confirmation signal after bringing the second shut-off means into a conducting state and before bringing the first shut-off means into a conducting state. And when the connection confirmation signal is received, the first blocking means is made conductive.
The charging device for an electric vehicle according to claim 1. A charge permission signal communication unit for receiving a charge permission signal output when the vehicle control unit permits charging of the battery;
Whether or not the charging permission signal communication unit has received the charging permission signal after setting the second blocking means to a conductive state and before setting the first blocking means to a conductive state. Confirming whether or not the charging permission signal is received, the first blocking means is made conductive.
The charging device for an electric vehicle according to claim 2. The first DC power supply unit includes an AC / DC converter that converts AC power into DC power,
The charging device control unit stops the AC / DC converter until the charging permission signal is received from the vehicle control unit. When the charging permission signal is received, the charging device control unit sets the first blocking means to a conductive state. Operating the AC / DC converter from
The charging device for an electric vehicle according to claim 3. The first DC power supply unit includes an AC / DC converter that converts AC power into DC power,
The charging device control unit stops the AC / DC converter until the charging permission signal is received from the vehicle control unit. When the charging permission signal is received, the charging device control unit operates the AC / DC converter and then Bringing the first blocking means into a conductive state;
The charging device for an electric vehicle according to claim 3.   2. The predetermined range is determined based on a value that can be taken as a resistance value between the first and second power input terminals in a state where the vehicle control unit is stopped. The charging device for electric vehicles in any one of -5.   2. The current limiting unit includes a constant current diode having one end connected to one end of the second blocking means and the other end connected to the other end of the second blocking means. The charging device for electric vehicles in any one of 6. An electric vehicle comprising a battery and a vehicle control unit having first and second power input terminals is charged by an electric vehicle charging device,
The electric vehicle charging device includes: a first connector terminal connectable to the first power input terminal of the vehicle control unit; and a second connector terminal connectable to the second power input terminal of the vehicle control unit. A connector having a connector terminal; in a connector connection state where the connector is connected to the electric vehicle; a first blocking means having one end connected to one electrode of the battery; and a first output terminal being the first The second output terminal is connected to the other electrode of the battery in the connector connected state, and direct current power for charging the battery is supplied to the first and second output terminals. A first DC power supply unit that outputs from, a second blocking means having one end connected to the first connector terminal, and a third output terminal connected to the other end of the second blocking means, Fourth out A second DC power supply unit that is connected to the second connector terminal and outputs DC power for operating the vehicle control unit from the third and fourth output terminals; and the second cutoff A current limiter connected in parallel to the means, one end connected to the first connector terminal, the other end connected to the second connector terminal, and between the first connector terminal and the second connector terminal A connector connection detection unit for detecting the voltage of the battery, and a charging device control unit for controlling the first and second blocking means to a conductive state or a blocked state,
The second DC power supply by the current limiting unit so that a voltage drop between the first and second power input terminals of the vehicle control unit is smaller than an operating voltage of the vehicle control unit in the connector connected state. Limiting the current output from the unit to a predetermined current value and outputting to the first connector terminal;
A first step of confirming whether the voltage between the first connector terminal and the second connector terminal detected by the connector connection detection unit is within a predetermined range by the charging device control unit; ,
When the voltage is within the predetermined range, the charging device control unit causes the second shut-off means to be in a conducting state, thereby supplying the electric power operable by the vehicle control unit to the second DC power supply. A second step of supplying the vehicle control unit from the unit;
A third step of starting charging the battery by the first DC power supply unit by bringing the first shut-off means into a conductive state by the charging device control unit;
A method for charging an electric vehicle, comprising: Before performing the third step, the charging device control unit confirms whether or not the charging control signal output when the vehicle control unit permits charging of the battery is received from the electric vehicle. Further comprising 4 steps,
The method for charging an electric vehicle according to claim 8, wherein the third step is performed when the charging permission signal is received from the electric vehicle.

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