JP2016187257A - Charging apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a charging apparatus enhanced in convenience by preventing unnecessary increase of its weight.SOLUTION: A charging apparatus includes: a DC/DC converter for converting a voltage of a battery provided in a rescue vehicle EV1 and outputting the voltage to a battery of an electricity lost vehicle EV2; a housing for housing at least the DC/DC converter; a rescue side cable 11 which is connected to one end side of the DC/DC converter, extends to the outside of the housing, and includes a connector to be connected to the rescue vehicle EV1 at a tip; and an electricity lost side cable 12 which is connected to the other end side of the DC/DC converter, extends to the outside of the housing, and includes a connector to be connected to the electricity lost vehicle V2 at a tip. A first cable length which is a length of the rescue side cable 11 portion extending from the housing is different from a second cable length which is a length of the electricity lost side cable 12 portion extending from the housing.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a technique for charging a battery of an electric vehicle.

  For example, a charging device that is used between vehicles of an electric vehicle and charges a battery of a power receiving vehicle with a battery voltage of the power feeding vehicle is known (for example, Patent Document 1). A DC / DC converter and a control board are mounted on the charging device. In this case, the vehicle on the power receiving side is, for example, a vehicle in which the battery voltage or the battery capacity is reduced and the travelable distance is short or the vehicle cannot travel by itself (hereinafter, referred to as “electrically deficient vehicle” as appropriate). The vehicle on the power supply side is a rescue vehicle for relieving an electric shortage vehicle using a charging device. By electrically connecting the battery of the rescue vehicle and the battery of the electric-powered vehicle via the charging device, the battery of the electric-powered vehicle is charged.

Japanese Patent Application Laid-Open No. 2014-165943

  When charging the battery of one vehicle between the vehicles of an electric vehicle, the worker who drives the rescue vehicle loads the above-mentioned charging device in the trunk room and rushes to the position where the vehicle with no electricity is stopped for charging work. Can be considered. However, it is inconvenient if the charging device is heavy when loading in the trunk room.

  Therefore, an object of the present invention is to provide a charging device that is reduced in weight and improved in convenience.

One embodiment of the present invention is a charging device that charges a battery of a power receiving vehicle, which is a power receiving vehicle, with electric power of a battery included in the power feeding vehicle.
This charging device
A DC / DC converter that transforms the voltage of the battery of the vehicle on the power supply side and outputs the voltage to the battery of the power receiving vehicle;
A housing that houses at least the DC / DC converter;
A power supply side cable connected to one end side of the DC / DC converter, extending to the outside of the housing, and provided with a connector connected to the vehicle on the power supply side at the tip;
A power receiving side cable connected to the other end side of the DC / DC converter, extending to the outside of the housing, and provided with a connector connected to the power receiving vehicle at a tip;
With
A first cable length that is a length of the portion of the power supply side cable extending from the housing and a second cable length that is a length of the portion of the power receiving side cable extending from the housing. It is characterized by being different.

  According to the present invention, convenience can be enhanced.

The perspective view of the charging device which concerns on embodiment. The front view which shows the holding | maintenance aspect of a cable in the charging device which concerns on embodiment. The block diagram which shows the structure of the charging system which concerns on embodiment. The figure which shows the AA cross section of FIG. 2 schematically. (A), (b) is a figure which shows the aspect which uses the charging device which concerns on embodiment, and charges the battery of an electric shortage vehicle with a rescue vehicle, respectively.

(1) Charging Device Hereinafter, the charging device of the present embodiment will be described with reference to FIGS. 1 and 2. FIG. 1 is a perspective view of a charging device 1 according to the present embodiment. FIG. 2 is a front view showing a cable holding mode in the charging device 1 according to the present embodiment.
A charging device 1 illustrated in FIG. 1 is used between vehicles of an electric vehicle, and is a device that charges a battery of a power receiving vehicle with a battery voltage of a power feeding vehicle. The vehicle on the power receiving side (or the charging side) is an electric shortage vehicle EV2 having a small remaining battery level. The vehicle on the power supply side (or the discharge side) is a rescue vehicle EV1 that has a relatively large battery remaining amount and rescues the electric shortage vehicle EV2.

As shown in FIG. 1, the charging device 1 includes a rescue side cable 11 (an example of a power feeding side cable) and an electric shortage side cable 12 (an example of a power receiving side cable). The rescue side cable 11 is connected to one end side of a DC / DC converter 100 to be described later, extends to the outside of the housing 8, and is provided with a connector 11a connected to the charging port of the rescue vehicle EV1 at the tip. The electricity-less cable 12 is connected to the other end of a DC / DC converter 100, which will be described later, extends to the outside of the housing 8, and is provided with a connector 12a that connects to the charging port of the electricity-free vehicle EV2 at the tip. .
The connector 11a of the rescue side cable 11 is connected to the high power side battery via the charging port of the rescue vehicle EV1, and the connector 12a of the terminal side cable 12 is connected to the high power side battery via the charging port of the power loss vehicle EV2. . The rescue vehicle EV1 is loaded with the charging device 1 and travels to the stop location of the unpowered vehicle EV2 at the request of the user of the unpowered vehicle EV2, for example. Charging is performed by being connected by the rescue side cable 11 and the power loss side cable 12 respectively.
In addition, the weight of the rescue side cable 11 and the electric short side cable 12 is about 0.5 kg / m, respectively. Further, the connectors 11a and 12a are provided with an electromagnetic lock mechanism so that they are not accidentally disconnected during charging, and the lock is released by a main controller described later.

As shown in FIG. 1, the charging device 1 has a rectangular parallelepiped shape, and has a form like a suitcase as a whole. Since charging device 1 includes a DC / DC converter, which will be described later, and is relatively heavy, gripping portions 5 and 6 are provided on the top surface and casters 7 (four wheels) are provided on the bottom surface so that the user can easily carry the device. It has been. It is preferable that the height of the grip portion 5 can be adjusted as illustrated.
The charging device 1 includes a connecting portion 4 that connects open surfaces of a main body 2 (an example of a first member) and a lid 3 (an example of a second member) each having an open surface (not shown) at the periphery of the open surface. The housing 8 having a rectangular parallelepiped shape as a whole is provided.

As shown in FIG. 1, the height of the housing 8 is L1, and the housing 8 is placed so that the housing surface from which the rescue-side cable 11 extends and the housing surface from which the non-cable-side cable 12 extends are horizontally oriented. L3 is preferably smaller than L1 and L2 when the horizontal length of the housing 8 is L2 and the length in the depth direction is L3. In general, the trunk room of an electric vehicle has a short depth. Therefore, by making the depth L3 of the charging device 1 smaller than L1 and L2, the mounting property of the charging device 1 in the trunk room can be improved.
As shown in FIG. 1, the height L <b> 1 of the housing 8 is a height from the flat surface to the upper surface of the housing 8 when the charging device 1 is placed on a flat surface. Includes the minute.

  Relief-side cables 11 and terminal-less cables 12 extend from the through holes 2a and 2b on both side surfaces of the main body 2, respectively. The lengths of the portions where the rescue side cable 11 and the terminal cable 12 extend from the through holes 2a and 2b to the outside of the housing 8 are different, but this point will be described later. The connector 42 is a connector for DC12V (light electricity) input, and is connected to the power cable 13 extending from the cigar socket of the rescue vehicle EV1.

  In the connection part 4, it is preferable to provide the cable holding parts 401 and 402 in the vicinity of the position where the rescue side cable 11 and the electricity-less side cable 12 extend from the main body part 2, respectively. As shown in FIG. 2, the cable holding portion 401 is provided for winding the rescue-side cable 11, and the cable holding portion 402 is provided for winding the electric-absent-side cable 12. By providing the cable holding unit 401 and the cable holding unit 402, the charging device 1 can be easily carried. In addition, as shown in FIG. 1, it is preferable that the cable holding | maintenance parts 401 and 402 are comprised so that it can accommodate in the connection part 4, when not using.

  In order to provide the cable holding portions 401 and 402 for holding the heavy cables in the connecting portion 4 and to provide the gripping portion 6 in the connecting portion 4, the connecting portion 4 is higher in rigidity than the main body portion 2 and the lid portion 3. It is preferable. For example, the material of the main body 2 and the lid 3 is made of plastic such as polycarbonate, and the connecting portion 4 is made of metal such as aluminum. Further, the connecting portion 4 may be made of the same material as that of the main body portion 2 and the lid portion 3. It is preferable to increase the rigidity of the main body part 2 and the lid part 3 by increasing the rigidity.

As shown in FIG. 1, a power button 25, an indicator 26, a start button 34, a stop button 35, a rescue side display panel 37, and an electric charge side display panel 38 are installed on the upper surface of the charging device.
The power button 25 is a button for turning on / off the power of the charging device 1. The indicator 26 is configured to light up when DC12V (light electricity) is input to the connector 42.
The start button 34 is a button for instructing to start charging, and the stop button 35 is a button for instructing to stop charging. The rescue side display panel 37 is a display panel on which the state of the rescue side system (starting up or discharging), the voltage of the battery of the rescue vehicle EV1, and the SOC are displayed. The lack-of-charge display panel 38 is a display panel that displays the state of the charging-side system (starting up or charging), the voltage of the battery of the lack-of-electric vehicle EV2, and the SOC. Each display panel may display a charging current.

(2) System Configuration of Charging System Next, the configuration of the charging system including the charging device 1 will be described with reference to FIG.
FIG. 3 is a block diagram showing a configuration of the charging system according to the present embodiment. In FIG. 3, the solid line indicates the high-power side power line 72, and the two-dot chain line indicates the low-power side power line 71.

  Each of the rescue vehicle EV1 and the shortage vehicle EV2 includes a low-power battery and a high-power battery. The low-power battery is a secondary battery for driving electric components in the vehicle such as an air conditioner and a car navigation system. On the other hand, the high-power battery is a battery that is mainly used as a power source when driving a motor.

  As shown in FIG. 3, the charging device 1 includes a DC / DC converter 100, a main controller 50 including a discharge side main controller 51 and a charge side main controller 52, and converters 61 and 62.

  The charging circuit of the charging device 1 is separated on the discharging side (primary side) and the charging side (secondary side) by the transformer 120 of the DC / DC converter 100. With the coil of the transformer 120 as a boundary, the charging circuit 201 on the discharge side includes the primary coil of the transformer 120, the inverter 110, the ground fault detection circuit 63, the power line 72 on the high power side, the rescue side cable 11, and the rescue vehicle. It is formed by a circuit including a charging port of EV1 (a connection port with the rescue side cable 11). The charging circuit 202 on the charging side includes a secondary coil of the transformer 120, a rectifier circuit 130, a smoothing circuit 140, a ground fault detection circuit 64, a power line 73 on the high power side, a power short side cable 12, and a power short vehicle EV2. Are formed by a circuit including a charging port (a connection port of the cable 12 on the terminal side).

The discharge side main controller 51 is a controller for controlling the discharge side (rescue side) charging circuit 201. The charging side main controller 52 is a controller for controlling the charging circuit 202 on the charging side (on the electric charge side). The discharge side main controller 51 and the charge side main controller 52 are electrically connected to the low power side battery of the rescue vehicle EV1.
In this example, in order to simplify the control sequence, the main controller 50 is separated on the discharge side and the charge side, and the respective charging circuits 201 and 202 are controlled by separate controllers. The discharge side main controller 51 and the charge side main controller 52 exchange signals with each other. The discharge side main controller 51 and the charge side main controller 52 may be configured by a single controller.

  The discharge side main controller 51 has an insulation detection unit 53, and the charge side main controller 52 has an insulation detection unit 54. The insulation detection unit 53 determines whether or not the charging circuit 201 on the discharge side is insulated from the voltage change at a predetermined node of the ground fault detection circuit 63. The insulation detection unit 54 determines whether the charging circuit 202 on the charging side is insulated from the voltage change at a predetermined node of the ground fault detection circuit 64.

  The discharge side main controller 51 is connected to the power line 71 on the low power side. Similarly, the charging-side main controller 52 is connected to the low-power-side power line 71. That is, power for driving the discharge-side main controller 51 and the charge-side main controller 52 is acquired from the low-power-side power line 71.

  The power cable 13 is a part of the wiring on the low power side. One end of the power cable 13 is connected to the connector 42. On the other hand, the other end of the power cable 13 is connected to a cigar socket of the rescue vehicle EV1. The cigar socket is electrically connected to the low-power battery among the low-power battery and the high-power battery mounted on the rescue vehicle EV1. That is, by connecting the power cable 13 between the cigar socket and the connector 42, the power of the low-power battery of the rescue vehicle EV1 can be output. In addition, the power cable 13 may be connected to the cigar socket of the electric shortage vehicle EV2.

  The converter 61 is a conversion circuit for boosting the input voltage from the power line 71 on the low power side and outputting it to the charging circuit 201 on the discharge side. The converter 61 is connected between a weak power side power line 71 and a high power side power line 72.

  The converter 62 is a conversion circuit for boosting the input voltage from the power line 71 on the weak power side and outputting the boosted voltage to the charging circuit 202 on the charging side. The converter 62 is connected between the low power side power line 71 and the high power side power line 73.

  The ground fault detection circuit 63 is a circuit for detecting insulation of the charging circuit 201 on the discharge side including the power line 72 on the high power side, and is formed in the charging circuit 201 on the discharge side. The ground fault detection circuit 64 is a circuit for detecting insulation of the charging circuit 202 including the high-power side power line 73, and is formed in the charging circuit 202 on the charging side.

The DC / DC converter 100 is connected between the relief side connector 31 and the charging side connector 32, and is connected to the power lines 72 and 73 on the high power side. The rescue connector 31 and the charge connector 32 are not shown in FIG. 1 because they are inside the main body 2.
The DC / DC converter 100 is a converter that transforms the voltage of the high-power battery of the rescue vehicle EV1 and outputs the transformed voltage to the high-power battery of the unpowered vehicle EV2. A ground fault detection circuit 63 is connected to the input side of the DC / DC converter 100, and a ground fault detection circuit 64 is connected to the output side of the DC / DC converter 100.

The DC / DC converter 100 includes an inverter 110, a transformer 120, a rectifier circuit 130, and a smoothing circuit 140.
The inverter 110 is configured by a circuit in which a plurality of switching elements are connected in a bridge shape. Then, the inverter 110 converts the DC power input from the rescue connector into AC power by switching on and off the plurality of switching elements based on the switching signal from the main controller 50, and converts the DC power to AC 120. Output.
The transformer 120 includes a primary side coil included in the discharging side charging circuit 201 and a secondary side coil included in the charging side charging circuit 202.
The rectifier circuit 130 is configured by a diode connected in a bridge shape. The rectifier circuit 130 rectifies the alternating current from the secondary coil of the transformer 120 and outputs it to the smoothing circuit 140.
The smoothing circuit 140 is composed of an LC circuit and smoothes the output voltage of the rectifier circuit 130.

(3) Charging Operation of Charging System Next, the charging operation of the charging system including the charging device 1 of the present embodiment will be described.
In the charging operation, data is transmitted between the discharge-side main controller 51 and the battery controller (not shown) of the rescue vehicle EV1, and between the charge-side main controller 52 and the battery controller (not shown) of the non-electric vehicle EV2. Communication takes place. The communication protocol of this data communication is not limited, but is CAN (Controller Area Network), for example.

  When the user presses the start button 34 in a state where the rescue side cable 11, the electric shortage side cable 12, and the power cable 13 are connected to the charging device 1, the rescue vehicle EV1, and the electric shortage vehicle EV2, the main controller 50 Then, the voltage of the low power side battery of the rescue vehicle EV1 is applied via the power line 71 on the low power side to start up.

First, the main controller 50 activates the discharge-side main controller 51.
The discharge-side main controller 51 turns on the discharge-side charging circuit 201 by turning on a relay (not shown) provided in the high-power side power source in the charging circuit 201 from OFF. At this time, there is no power supply to the charging device 1 from the high-power battery of the rescue vehicle EV1.
The discharge-side main controller 51 controls the converter 61 by the insulation detection unit 53 to boost the power (weak voltage) supplied from the low-power side power line 71 and output it to the high-power side power line 72. A test voltage (high voltage) is applied from the converter 61 to the charging circuit 201 on the discharge side.
The insulation detection circuit 53 detects the presence of a ground fault or a short circuit in the charging circuit 201 on the discharge side by detecting the voltage at a predetermined node of the ground fault detection circuit 63 during application of the test voltage. When the discharge-side main controller 51 detects a ground fault or a short circuit, the discharge-side main controller 51 determines that insulation is not secured, and displays a message on the rescue-side display panel 37 that insulation is not secured.

Next, the main controller 50 sets the maximum value of the charging current and activates the charging side main controller 52. The charging-side main controller 52 communicates with the electricity-less vehicle EV2 via the electricity-absent-side cable 12 after activation, and notifies the electricity-less vehicle EV2 of the set maximum value of the charging current.
The charging side main controller 52 controls the converter 62 by the insulation detection circuit 54, boosts the voltage of the power line 71 on the low power side, and applies it to the charging circuit 202 on the charging side. And the insulation detection part 54 detects the presence or absence of a ground fault and a short circuit in the charging circuit 202 on the charging side by detecting the voltage of the ground fault detection circuit 64. When the charging side main controller 52 detects a ground fault or a short circuit, the charging side main controller 52 determines that the insulation is not secured, and displays a message to the effect that the insulation is not secured on the power loss side display panel 38.

  When insulation of the charging circuits 201 and 202 is confirmed, the discharge-side main controller 51 can turn on the discharge-side main relay and output the power of the high-power battery of the rescue vehicle EV1 to the DC / DC converter 100. To make sure Similarly, the charging-side main controller 52 turns on the charging-side main relay so that the electric power from the DC / DC converter 100 can be output to the high-power battery of the lack-of-electric vehicle EV1. Although the main relay is not shown in FIG. 2, the discharge-side main relay is connected between the input side of the DC / DC converter 100 and the rescue-side connector 31, and the charge-side main relay is It is connected between the output side of the DC / DC converter 100 and the non-connector side connector 32.

  The battery controller of the rescue vehicle EV1 sequentially monitors the battery voltage (rescue vehicle BAT voltage) and SOC (power supply side SOC) of the rescue vehicle EV1, and transmits the rescue vehicle BAT voltage and power supply side SOC to the discharge side main controller 51. . In addition, the battery controller of the electric shortage vehicle EV2 sequentially monitors the battery voltage (electric shortage vehicle BAT voltage) and SOC (power reception side SOC) of the electric shortage vehicle EV2, and charges the electric shortage vehicle BAT voltage and the reception side SOC. Transmit to the main controller 52.

  After turning on each main relay, the main controller 50 controls the switching element of the inverter 110 to start the operation of the DC / DC converter 100 and charges the high-power side battery of the electrified vehicle EV2.

  During charging, the battery controller of the non-electric vehicle EV2 notifies the charging side main controller 52 of the command value of the charging current. The battery controller of the electrified vehicle EV2 determines and notifies the charging current command value to be equal to or less than the maximum value of the charging current set and notified in S14.

  While executing the charging, the main controller 50 displays the rescue vehicle BAT voltage and the power supply SOC received from the battery controller of the rescue vehicle EV1 on the rescue display panel 37, and the state of the rescue system (during discharging). Display. In addition, the main controller 50 displays, on the power loss side display panel 38, the power loss side BAT voltage received from the battery controller of the power loss vehicle EV2 and the power reception side SOC, and the state of the rescue side system (during charging). indicate.

  By executing the charging, the rescue vehicle BAT voltage decreases from before the start of charging, and the non-powered vehicle BAT voltage increases from before the start of charging. When the power receiving side SOC exceeds a predetermined value (for example, 90%) or the power feeding side SOC falls below a predetermined value (for example, 30%), the main controller 50 ends the charging.

(4) Preferred Layout in the Housing Next, a preferred layout in the housing of the charging device 1 of the present embodiment will be described with reference to FIG. FIG. 4 is a diagram schematically showing a cross section taken along the line AA of FIG.
As shown in FIG. 4, the inside of the housing 8 of the charging device 1 of the present embodiment has a three-layer structure, and the board on which the DC / DC converter 100 and the converters 61 and 62 are mounted in the order closer to the grip portion 5. 101 (an example of a first layer), a charge side substrate 152 (an example of a second layer), and a discharge side substrate 151 (an example of a third layer) are stacked.
The discharge-side board 151 (an example of a power supply control board) is connected to a high-power battery of the rescue vehicle EV1 (an example of a vehicle on the power supply side) and is mounted with a discharge-side main controller 51 that controls the discharge side (power supply side). It is a substrate. The charging-side board 52 (an example of a power reception control board) is connected to a high-power side battery on the electric-powered vehicle EV2 (an example of a power-receiving vehicle) and is mounted with a charging-side main controller 152 that controls the charging side (power-receiving side). It is a substrate.
The substrate 101 on which the DC / DC converter 100 and the converters 61 and 62 are mounted includes a transformer, and thus is heavier than the discharge side substrate 151 and the charge side substrate 152. Therefore, by setting the substrate 101 as the first layer close to the grip portion 5, it is possible to reduce a burden when the user holds the grip portion 5 and moves the charging device 1.

(5) About the lengths of the rescue side cable and the non-rescue side cable In the charging device 1 of the present embodiment, the first cable length, which is the length of the part of the rescue side cable 11 extending from the housing 8, and the housing The second cable length, which is the length of the portion of the electric-absent cable 12 extending from the body 8, is different. In the charging device 1 of the present embodiment, the first cable length and the second cable length are different from each other for the following reason.
In many cases, the place where the charging operation is performed on the electric shortage vehicle EV2 is on a road where other vehicles come and go, and the rescue vehicle EV1 is stopped before or behind the electric shortage vehicle EV2. Further, when the charging device 1 cannot be placed on the road next to the vehicle due to rain or when other vehicles come and go on the road, the charging device 1 is placed in the trunk room of the rescue vehicle EV1 or the lacking vehicle EV2 for charging. It is possible to work. Furthermore, since the charging port of the electric vehicle is either the front part or the rear part of the vehicle, the rescue vehicle EV1 and the electric vehicle EV2 stop before and after the charging device 1 in the trunk room of any vehicle. When a cable is to be connected to the charging port of both vehicles in a state where the vehicle is arranged, the rescue side cable from the charging device 1 to the charging port of the rescue vehicle EV1 and the charging port of the lacking vehicle EV2 from the charging device 1 When the length of the cable with no charge side is the same, an excess is generated in one of the cables, and the weight of the charging device 1 is increased. This makes it difficult to install a charger when heading for rescue, which impairs convenience. Moreover, the space in the trunk room is wasted by the extra cable, and the convenience of the user of the rescue vehicle EV1 or the lacking vehicle EV2 is impaired. Therefore, in the present embodiment, the first cable length and the second cable length of the charging device 1 are made different so that the rescue vehicle can be stopped only in front of or behind the vehicle with no electricity, and other vehicles can be used in the rain or on the road. Even if the charging device 1 cannot be placed on the road next to the vehicle due to traffic, etc., the weight of the charger for performing charging work on the electric vehicle EV2 can be reduced and convenience To be able to improve. Moreover, since the space of the charging device 1 which occupies in the trunk room of the vehicle (the rescue vehicle EV1 or the electric shortage vehicle EV2) in which the charging device 1 is disposed can be reduced, user convenience can be improved.
Moreover, the charging device to the trunk room of the small rescue vehicle EV1 without affecting the charging performance (that is, without downsizing the housing 8) by changing the first cable length and the second cable length. The loadability of 1 can be improved.

  FIG. 5 shows a cable connection mode in the case of charging the electric shortage vehicle EV2 using the charging device 1 installed in the rescue vehicle EV1 on the road. (A) of FIG. 5 shows the relief when charging is performed using the charging device 1 installed in the trunk room of the rescue vehicle EV1 when both the charging ports of the rescue vehicle EV1 and the lacking vehicle EV2 are in front of the vehicle. The connection mode of the side cable 11 and the non-terminal side cable 12 is shown. FIG. 5B shows a case where charging is performed using the charging device 1 installed in the trunk room of the rescue vehicle EV1 when both the charging ports of the rescue vehicle EV1 and the electric vehicle EV2 are on the rear side of the vehicle. The connection aspect of the rescue side cable 11 and the electric short side cable 12 is shown. In any case, the rescue vehicle EV1 is in front and the electric shortage vehicle EV2 is in rear.

In FIG. 5, the first cable length is the length of the rescue-side cable 11 from the through hole 2 a of the main body 2 of the charging device 1 to the charging port EV1 c of the rescue vehicle EV1. The second cable length is the length of the electric short side cable 12 from the through hole 2b of the main body 2 of the charging device 1 to the charging port EV2c of the electric short vehicle EV2.
FIG. 5A assumes a case where both the rescue vehicle EV1 and the electric shortage vehicle EV2 are vehicles of a normal automobile size. In the case of FIG. 5A, the total length of the rescue vehicle EV1 and the electric shortage vehicle EV2 is 4 to 5 m, the vehicle width is 1.5 to 2 m, and the inter-vehicle distance (that is, the work space) during the charging operation is 2 to 2. When the length is 3 m, the first cable length is 5.5 to 7 m, and the second cable length is 2 to 3 m (that is, the same as the inter-vehicle distance). The first cable length was calculated as the vehicle length plus the vehicle width. Therefore, in the connection mode of FIG. 5A, the longer cable length (in this case, the first cable length) of the first cable length and the second cable length is the shorter cable length (in this case, the second cable length). The length is 1.8 to 3.5 times the cable length.

  On the other hand, FIG. 5B assumes a case where both the rescue vehicle EV1 and the electric shortage vehicle EV2 are light vehicle size vehicles. In the case of FIG. 5B, the total length of the rescue vehicle EV1 and the electric shortage vehicle EV2 is 3.2 to 3.5 m, the vehicle width is 1.3 to 1.5 m, and the inter-vehicle distance (that is, When the working space is 2 to 3 m, the first cable length is 1.3 to 1.5 m (that is, the same as the vehicle width), and the second cable length is 6.5 to 8 m. The second cable length was calculated as the sum of the total length of the vehicle, the vehicle width of the vehicle, and the inter-vehicle distance. Therefore, in the connection mode of FIG. 5B, the longer cable length (in this case, the second cable length) of the first cable length and the second cable length is the shorter cable length (in this case, the first cable length). The length is 4.3 to 6.1 times the cable length.

  The connection mode of the cable shown in FIGS. 5A and 5B is merely an example, and various other modes can be assumed. Then, the size of the vehicle, the position of the charging port, which of the rescue vehicle EV1 and the electric shortage vehicle EV2 is in front, or in which trunk rule of the electric vehicle EV1 or the electric shortage vehicle EV2 When there is no excess portion, the ratio of the longer cable length of the first cable length and the second cable to the shorter cable length varies depending on various factors such as the above. Preferred ratios other than those shown in FIGS. 5A and 5B are as follows. In any case, the charging device 1 is assumed to be in the trunk room of the rescue vehicle EV1.

(i) When the rescue vehicle EV1 and the electric vehicle EV2 are both ordinary vehicles, the charging port is at the front of the vehicle, and the rescue vehicle EV1 stops behind the electric vehicle EV2, the rescue vehicle EV1 and the electric vehicle EV2 The first cable length is 5.5 to 7 m when the total length of the cable is 4 to 5 m, the vehicle width is 1.5 to 2 m, and the inter-vehicle distance (that is, the work space) is 2 to 3 m at the time of charging. The second cable length is 11.5 to 15 m. In addition, the 1st cable length was made into the value which totaled the full length of the rescue vehicle EV1, the full length of the electric shortage vehicle EV2, the distance between vehicles, and a vehicle width. In addition, the second cable length is a value obtained by adding up the total length and the vehicle width of the electroless vehicle EV2.
Therefore, the longer cable length (in this case, the second cable length) of the first cable length and the second cable length is 1.6 to 2 of the shorter cable length (in this case, the first cable length). 7 times longer is good.

(ii) When the rescue vehicle EV1 and the electric vehicle EV2 are both ordinary vehicles, the charging port is at the rear side of the vehicle, and the rescue vehicle EV1 stops in front of the electric vehicle EV2, the rescue vehicle EV1 and the electric vehicle When the EV2 has a total length of 4 to 5 m, a vehicle width of 1.5 to 2 m, and an inter-vehicle distance (that is, a work space) of 2 to 3 m during charging, the first cable length is 1.5 to 2 m. Yes, the second cable length is 6-8 m. The first cable length is the same as the vehicle width of the rescue vehicle EV1. In addition, the second cable length is a value obtained by adding up the total length and the inter-vehicle distance of the electrified vehicle EV2.
Accordingly, the longer cable length (in this case, the second cable length) of the first cable length and the second cable length is 3 to 5.3 times the shorter cable length (in this case, the first cable length). The length of is good.

(iii) When the rescue vehicle EV1 and the electric vehicle EV2 are both ordinary vehicles, the charging port is on the rear side of the vehicle, and the rescue vehicle EV1 stops behind the electric vehicle EV2, the rescue vehicle EV1 and the electric vehicle When the EV2 has a total length of 4 to 5 m, a vehicle width of 1.5 to 2 m, and an inter-vehicle distance (that is, a work space) of 2 to 3 m during charging, the first cable length is 1.5 to 2 m. Yes, the second cable length is 7.5 to 10 m. The first cable length is the same as the vehicle width of the rescue vehicle EV1. In addition, the second cable length is a total value of the total length, the inter-vehicle distance, and the vehicle width of the rescue vehicle EV1.
Accordingly, the longer cable length (in this case, the second cable length) of the first cable length and the second cable length is 3.7 to 6.6 of the shorter cable length (in this case, the first cable length). 6 times the length is good.

(iv) When the rescue vehicle EV1 and the electric vehicle EV2 are both light vehicles, the charging port is in the front of the vehicle, and the rescue vehicle EV1 stops in front of the electric vehicle EV2, the rescue vehicle EV1 and the electric vehicle EV2 The first cable length is 4 when the overall length of the vehicle is 3.2 to 3.5 m, the vehicle width is 1.3 to 1.5 m, and the inter-vehicle distance (that is, the work space) is 2 to 3 m during the charging operation. The second cable length is 2 to 3 m. The first cable length is the sum of the total length and the vehicle width of the rescue vehicle EV1, and the second cable length is the same as the inter-vehicle distance.
Therefore, the longer cable length (in this case, the first cable length) of the first cable length and the second cable length is 1.5 to 2 of the shorter cable length (in this case, the second cable length). Five times as long is good.

(v) When the rescue vehicle EV1 and the electric vehicle EV2 are both light vehicles, the charging port is at the front of the vehicle, and the rescue vehicle EV1 stops behind the electric vehicle EV2, the rescue vehicle EV1 and the electric vehicle EV2 The first cable length is 4 when the overall length of the vehicle is 3.2 to 3.5 m, the vehicle width is 1.3 to 1.5 m, and the inter-vehicle distance (that is, the work space) is 2 to 3 m during the charging operation. The second cable length is 9.7 to 11.5 m. In addition, 1st cable length was made into the sum total of the full length and vehicle width of rescue vehicle EV1. The second cable length was the sum of the total length of the two rescue vehicles EV1 and the electric vehicle EV2, the inter-vehicle distance, and the vehicle width of one vehicle.
Therefore, the longer cable length (in this case, the second cable length) of the first cable length and the second cable length is 1.9 to 2.1 of the shorter cable length (in this case, the first cable length). Five times as long is good.

(vi) When the rescue vehicle EV1 and the electric vehicle EV2 are both light vehicles, the charging port is at the rear side of the vehicle, and the rescue vehicle EV1 stops behind the electric vehicle EV2, the rescue vehicle EV1 and the electric vehicle When the EV2 has a total length of 3.2 to 3.5 m, a vehicle width of 1.3 to 1.5 m, and an inter-vehicle distance during charging (that is, a work space) of 2 to 3 m, the first cable length is It is 1.3 to 1.5 m, and the second cable length is 6.5 to 8 m. The first cable length is the same as the vehicle width of the rescue vehicle EV1. The 2nd cable length was made into the value which totaled the vehicle width of the rescue vehicle EV1, the full length, and the distance between vehicles.
Therefore, the longer cable length (in this case, the second cable length) of the first cable length and the second cable length is 4.3 to 6 of the shorter cable length (in this case, the first cable length). One time is good.

Considering each of the cases of FIGS. 5A, 5B, and (i) to (vi), the longer cable length of the first cable length and the second cable length is one of the shorter cable lengths. It turns out that it is preferable that it is 0.5 to 6.6 times. By setting the cable length at such a ratio, it is possible to realize the charging device 1 that can be applied to many electric vehicles and has a small excess portion of the cable.
In any of the cases described above, it is assumed that the charging device 1 is in the trunk room of the rescue vehicle EV1, but when the charging device 1 is arranged in the trunk room of the electric vehicle EV2, the first cable length Of the second cable lengths, the longer cable length is preferably in the range of 1.5 to 6.6 times the shorter cable length.

(6) Modifications Although the embodiment of the present invention has been described in detail above, the scope of the present invention is not limited to the above-described embodiment. The above-described embodiment can be variously improved and changed without departing from the gist of the present invention. In addition, a plurality of technical matters described in the above embodiments and modifications can be combined as appropriate.

  For example, in the charging system of the above-described embodiment, the case where the connector 11a of the rescue side cable 11 is connected to the charge port of the rescue vehicle EV1 has been described. That is, as an example of the “battery of the vehicle on the power supply side” of the present invention, the battery on the high power side of the rescue vehicle EV1 has been described as an example, but is not limited to this example. The battery of the rescue vehicle EV1 may be any battery, and an independent portable power supply device that is not electrically connected to the battery of the rescue vehicle EV1 is used, and the connector 11a of the rescue cable 11 is connected to the power supply device to generate power. May be obtained.

  In the charging system according to the above-described embodiment, the case where the rescue side cable 11 and the shortage side cable 12 are each one has been described, but each cable is not limited to one. Each cable may be used by connecting two or more cables inside the main body 2 of the charging device 1 or outside the charging device.

  In the above-described embodiment, the case where both the cable holding unit 401 and the cable holding unit 402 are provided has been described, but it is not always necessary to provide both. One cable holding portion that holds a cable corresponding to at least the longer cable length of the first cable length and the second cable length may be provided.

FIG. 4 shows an example in which the charge side substrate 152 is the second layer and the discharge side substrate 151 is the third layer, but the discharge side substrate 151 is the second layer and the charge side substrate 152 is the third layer. Good. The substrate 101 having the heaviest weight may be the first layer (that is, the layer closest to the grip portion 5), and the discharge side substrate 151 and the charge side substrate 152 are both lighter than the substrate 101. It is good also as a 3rd layer.
In the above-described embodiment, an electric vehicle having a driving battery is described as an example of a rescue vehicle. However, a vehicle having a portable storage battery mounted on a trunk may be used even if it does not have a driving battery. That is, it is only necessary that the battery of the power-less vehicle can be charged by the battery of the vehicle on the power feeding side.

EV1 ... rescue vehicle EV2 ... electric shortage vehicle 1 ... charging device 2 ... main body 2a, 2b ... through hole 3 ... lid 4 ... connecting part 5, 6 ... gripper 7 ... caster 8 ... housing 11 ... rescue side cable 11a ... Connector 12 ... Power failure side cable 12a ... Connector 13 ... Power supply cable 25 ... Power button 26 ... Indicator 34 ... Start button 35 ... Stop button 37 ... Relief side display panel 38 ... Electronic absence side display panel 42 ... Connector 401, 402 ... Cable holding unit 50 ... main controller 51 ... discharge side main controller 52 ... charge side main controller 61, 62 ... converter 100 ... DC / DC converter

Claims (5)

A charging device that charges a battery of a power receiving vehicle that is a vehicle on the power receiving side with electric power of a battery that the vehicle on the power feeding side has,
A DC / DC converter that transforms the voltage of the battery of the vehicle on the power supply side and outputs the voltage to the battery of the power receiving vehicle;
A housing that houses at least the DC / DC converter;
A power supply side cable connected to one end side of the DC / DC converter, extending to the outside of the housing, and provided with a connector connected to the vehicle on the power supply side at the tip;
A power receiving side cable connected to the other end side of the DC / DC converter, extending to the outside of the housing, and provided with a connector connected to the power receiving vehicle at a tip;
With
A first cable length that is a length of the portion of the power supply side cable extending from the housing and a second cable length that is a length of the portion of the power receiving side cable extending from the housing. Characterized by being different,
Charging device. The longer cable length of the first cable length and the second cable length is 1.5 to 6.6 times the shorter cable length,
The charging device according to claim 1. The housing is
A first member and a second member each having an open surface;
A connecting portion that connects the open surfaces of the first member and the second member at the periphery of the open surface and has higher rigidity than the first member and the second member;
A holding portion for holding a cable corresponding to at least the longer cable length of the first cable length and the second cable length is provided in the connection portion,
The charging device according to claim 1 or 2. The housing as a whole has a rectangular parallelepiped shape,
The casing when the casing is disposed such that the height of the casing is L1, and the casing surface from which the power supply side cable extends and the casing surface from which the power receiving side cable extends are respectively laterally oriented L3 is smaller than L1 and L2 when the length in the horizontal direction is L2 and the length in the depth direction is L3.
The charging device according to claim 1. The housing further includes a power supply control board that is connected to the battery of the power supply side vehicle and controls the power supply side, and a power reception control board that is connected to the batteries on both sides of the train and performs control of the power reception side. Stow and
The housing is provided with a grip portion for gripping the charging device,
Inside the housing, a first layer on which the DC / DC converter is mounted, a second layer that is one of the power supply control board and the power reception control board, and the other of the power supply control board and the power reception control board. And the third layer is laminated in the order closer to the gripping part,
The charging device according to claim 1.

Images