JP2014165943A - Charging apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a convenient charging apparatus.SOLUTION: The charging apparatus for charging a battery of a receiving side vehicle with power of a battery of a feeding side vehicle includes: transformation means for transforming a voltage of the feeding side battery to output a voltage to the receiving side battery; a casing 10 housing the transformation means by a plurality of surfaces; a feeding side connector connectable with a feeding side cable electrically connected to the feeding side battery; and a charging connector connectable with a receiving side cable electrically connected to the receiving side battery. The feeding side connector and the receiving side connector are arranged on one of the plurality of surfaces.

Description

  The present invention relates to a charging device.

  In an emergency charging system for an electric vehicle, the power supply connection port connected to the power supply side power source of the vehicle on the power supply side and the control box are connected by the first charging cable and connected to the power receiving side battery of the power receiving side electric vehicle. The control box is provided with a DC-DC converter that connects the power receiving connection port and the control box via a second charging cable and transforms the voltage on the power feeding side to a voltage higher than the voltage on the power receiving side by a predetermined value. (Patent Document 1).

JP 2007-267561 A

  However, in the above emergency charging system, a specific form of the control box is not disclosed, and the system is not necessarily easy to use.

  The problem to be solved by the present invention is to provide a user-friendly charging device.

  The present invention is electrically connected to a housing that accommodates transformer means on a plurality of surfaces, a power supply connector that connects a power supply cable that is electrically connected to a power supply battery, and a power reception battery. The above-described problem is solved by providing a charging connector for connecting a power receiving side cable, forming the casing into a polyhedral shape, and disposing the power feeding side connector and the power receiving side connector on one surface of the plurality of surfaces of the casing.

  According to the present invention, the power feeding side connector and the power receiving side connector are arranged on the same surface, and when the user connects the power feeding side cable and the power receiving side cable to the power feeding side connector and the power receiving side connector, respectively, the user Since the connection destination of the cable can be easily confirmed, there is an effect that the usability of the charging device is improved.

It is a schematic diagram of the charging system of the present invention. It is a perspective view of the charging device of FIG. It is a top view of the charging device shown in FIG. It is a front view of the charging device shown in FIG. It is a right view of the charging device shown in FIG. It is a rear view of the charging device shown in FIG. It is a bottom view of the charging device shown in FIG. It is a figure for demonstrating the internal structure of the charging device of FIG. 2, and is a front view of a charging device. It is a perspective view of the main body of the charging device of FIG. It is a perspective view of the DC / DC converter of FIG. 8, and a heat sink. It is a side view of the state which decomposed | disassembled the charging device of FIG. It is a block diagram of the charging system of FIG. It is a flowchart which shows the control procedure of the charging system of FIG. It is a perspective view of the rescue vehicle in the state which mounted the charging device of FIG. 2 on the trunk of the rescue vehicle. FIG. 15 is an arrow view of arrow XV in FIG. 14. It is the figure which showed a mode that the charging device of FIG. 2 was taken out from the trunk of a rescue vehicle. It is the figure which showed a mode that the charging device of FIG. 2 was taken out from the trunk of a rescue vehicle. It is a figure for demonstrating the positional relationship of a trunk and a charging device in the state of FIG. It is the figure which showed a mode that the charging device of FIG. 2 was taken out from the trunk of a rescue vehicle. FIG. 20 is a diagram for explaining the positional relationship between the trunk and the charging device in the state of FIG. 19. It is the figure which showed a mode that the charging device of FIG. 2 was taken out from the trunk of a rescue vehicle. It is a figure for demonstrating the positional relationship of a trunk and a charging device in the state of FIG.

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

  FIG. 1 is a schematic diagram of a charging system including a charging device of the present invention. The charging device 1 of this example is a charging device that charges the battery of the power receiving vehicle with the power of the battery of the power feeding vehicle, and is mainly used as a safety net for relieving an electric vehicle that is lacking electric power. It is a device.

  As shown in FIG. 1, the charging system of this example includes a charging device 1, a rescue vehicle 2 with a high battery charging capacity, an electric shortage vehicle 3 with a low battery charging capacity, a rescue side cable 4, and an electric shortage. And a side cable 5. An electric shortage vehicle is a vehicle that has a low capacity for charging a battery and does not have a capacity necessary for traveling the vehicle. As a usage scene of the charging device 1 of the present example, the rescue vehicle 2 travels to the place of the lacking vehicle 3 with the charging device 1 placed on the trunk in order to rescue the lacking vehicle 3. Then, the user takes out the charging device 1 from the trunk of the rescue vehicle 2, connects the rescue side cable 4 between the charge device 1 and the rescue side vehicle 2, and connects the charge side cable 5 to the charging device 1 and the unpowered vehicle 3. Connect between.

  Assuming such a usage pattern, the charging device 1 needs to be transported by the rescue vehicle 2, and therefore must have an outer shape that can be transported by the vehicle. Further, in order to mount the charging device 1 on the trunk on the power feeding side, it is necessary to have a specification or a form that allows one or two people to carry the charging device 1. Furthermore, since the charging device 1 handles high-voltage power, it is preferable to ensure insulation and further have an insulation detection function.

  The charging device 1 has a DC / DC converter in order to transform the voltage between the battery on the rescue side and the battery on the electricity loss side. Since the DC / DC converter includes a transformer or the like, it becomes heavy. Therefore, the weight of the charging device 1 can be several tens kg or more. Considering that a small number of adults carry a heavy charging device or take it out and out of the trunk, the charging device 1 is easy to carry or, for example, easily exceeds a step such as a trunk. Therefore, it is required for the user to improve usability.

  Furthermore, since the charging device 1 of this example is a device used as an emergency charging system, there is a problem of how to secure a power source for driving the device. For example, a battery such as a dry battery may be mounted on the charging device 1. However, if a battery is mounted on a device that is not frequently used, the battery is left for a long time. Therefore, when the charging device 1 is used due to natural discharge of the battery, the charging device 1 is only activated. There is a possibility that sufficient power cannot be output from the battery.

  In addition, for example, it is conceivable to receive power from a high-power side battery provided in the rescue vehicle 2. However, in a system in which the charging device 1 cannot be driven unless high-voltage power is supplied, a system for confirming the insulation of the charging device 1 before the supply of high power cannot be constructed. That's not true. Furthermore, since the controller for driving the charging device 1 is driven by weak electricity, there is also a problem that when the high-voltage power is supplied to the charging device 1, the voltage displacement is large. Therefore, the charging device 1 of the present example is required to have a configuration that does not have a power source in the device and that can easily acquire the power for driving the controller of the charging device 1 from the outside.

  The present invention realizes a charging device 1 that satisfies the above-mentioned specific specifications as a safety net charging device 1 at a high level. Hereinafter, a specific configuration of the charging device 1 will be described. In this example, an electric vehicle will be described as an example of a rescue vehicle 2 that is a power supply side vehicle and an electric shortage vehicle 3 that is a power reception side vehicle. However, the charging device 1 of this example includes the rescue vehicle 2 and the electric shortage vehicle. You may apply at least any one vehicle of the vehicles 3 as vehicles, such as a plug-in hybrid vehicle or a hybrid vehicle.

  FIG. 2 is a perspective view of the charging device according to the embodiment of the present invention. FIG. 3 is a plan view of the charging apparatus shown in FIG. FIG. 4 is a front view of the charging apparatus shown in FIG. 5 is a right side view of the charging apparatus shown in FIG. FIG. 6 is a rear view of the charging apparatus shown in FIG. FIG. 7 is a bottom view of the charging device shown in FIG.

  The charging device 1 includes a housing 10, a handle 20, a relief-side connector 31, an unplugged side connector 32, a switch 33, a start button 34, a stop button 35, an emergency stop button 36, and a power supply side display. It includes a panel 37, a terminal without electricity display panel 38, a ground connector 41, a power harness connector 42, a slider 43, a roller 44, an intake port 45, and an exhaust port 46.

  The housing 10 is a metal exterior member that houses a DC / DC converter, which will be described later, on a plurality of surfaces. The housing 10 is formed in a polyhedral shape. The housing 10 is composed of a seven-sided body having an upper surface 11, a bottom surface 12, a front side surface 13, a back side surface 14, a right side surface 15, a left side surface 16, and an inclined surface 17. Each surface is constituted by a wall having a certain thickness.

  The front side surface 13, the back side surface 14, the right side surface 15, and the left side surface 16 are formed by surfaces along a direction perpendicular to the direction along the bottom surface 12 (Z direction in FIG. 2) and surround the bottom surface 12. . The front side surface 13, the back side surface 14, the right side surface 15, and the left side surface 16 are formed so as to extend in the vertical direction from each side forming the bottom surface 12. The top surface 11 is disposed at a position parallel to the bottom surface 12 and so as to face a part of the surface of the bottom surface 12. Further, the upper surface 11 is disposed at a position opposite to the bottom surface 12 via the front side surface 13, the back side surface 14, the right side surface 15 and the left side surface 16.

  The inclined surface 17 is inclined with respect to the surface along the front side surface 13, and the surface along the front side surface 13 is bent toward the upper surface 11 (in other words, toward the back side surface 14). The surface to be formed. Therefore, the angle formed between the front side surface 13 and the inclined surface 17 is an obtuse angle.

  The upper surface 11 and the inclined surface 17 are formed of an integrated member, and are formed by bending the member at a side located on the front side among the sides of the upper surface 11. The height (Z direction) of the front side surface 13 is lower than the height (Z direction) of the back side surface 14, and the length of the upper surface (X direction) is shorter than the length of the bottom surface 12 (X direction). Thereby, the opening used as the position of the inclined surface 17 is formed, and the inclined surface 17 has covered the said opening. The front side surface 13 and the inclined surface 17 are one of the plurality of side surfaces of the housing.

  The lid 18 is composed of the upper surface 11 and the inclined surface 17 and is a member for covering the internal space of the housing 10 from above. The lid 18 is fixed to the front side surface 13, the back side surface 14, the right side surface 15, and the left side surface 16 by screwing or the like. Further, the lid 18 is detached from the main body 19 of the charging device 1 by removing the screw. The main body 19 (see FIG. 11) includes a front side surface 13, a back side surface 14, a right side surface 15, a left side surface 16, and a bottom surface 12.

  The handle 20 is a handle for facilitating movement of the charging device 1, and is fixed to the upper part of the housing 10. The handle 20 includes a first handle 21, a second handle 22, a connecting portion 23, and an end portion 24. The diameter of the handle 20 is such a size that a person can easily grip it and apply force. The 1st handle 21, the 2nd handle 22, the connection part 23, and the edge part 24 are comprised by the integrated member. The handle 20 is formed in a columnar shape (or a rod shape).

  The handles 20 are paired and are fixed to both ends of the upper surface 11 and the inclined portion 17 in the Y direction. When the user moves the charging device 1, the user grips the pair of handles 20 with each hand.

  The first handle 21 is a member that allows the user to easily lift the charging device 1 with a portion of one side located on the back side of the housing 10 among the four sides forming the bottom surface 12 as a fulcrum. The first handle 21 has a longitudinal direction (Z direction) as a longitudinal direction with respect to the direction along the bottom surface 12. In other words, the first handle is formed in a column shape so as to extend from the surface of the inclined surface 17 in the Z direction. Considering that the user grasps the first handle 21 with his / her hand, the length of the first handle 21 in the longitudinal direction is at least the size of a fist of a human hand (contacts the first handle 21 in the hand). It is formed to be longer than the length of the portion. The length of the first handle 21 in the longitudinal direction is such that the overall height of the charging device 1 is suppressed.

  The first handle 21 is provided at a position facing a corner portion A (see FIG. 2) formed by the bottom surface 12 and the back side surface 14. The corner portion A is a portion located on the back side and the bottom side of the charging device 1 among the corners included in the housing 10. The corner A becomes a fulcrum when the charging device 1 is lifted upward by rotating the charging device 1 while the user holds the first handle 21. And in the rectangular parallelepiped formed by the top surface 11, the bottom surface 12, the front side surface 13, the back side surface 14, the right side surface 15, and the left side surface 16, the corner corresponding to the corner A among the corners formed by two surfaces. On the other hand, the diagonal position corresponds to a position facing the corner A. That is, the surface of the inclined surface 17 is located as far as possible from the portion serving as a fulcrum of the charging device 10 (the portion on the back side of the bottom surface 12) on the rotation orbit of the charging device 1 around the fulcrum. It is fixed. Thereby, the 1st handle 21 is provided in the position which can rotate the charging device 1 by using the part corresponded to the corner | angular part A as a fulcrum.

  In addition, the position facing the corner A is a diagonal of the corner A in a rectangular parallelepiped formed by the top surface 11, the bottom surface 12, the front side surface 13, the back side surface 14, the right side surface 15, and the left side surface 16. It does not indicate the position itself. The position facing the corner A is determined according to the shape of the casing, the shape of the handle 20, and the position of the center of gravity of the charging device 1, and the charging device 1 is rotated around the corner A as a fulcrum. In this case, the position of the power point that easily lifts the charging device 1 is indicated.

The second handle 22 is a member for lifting the bottom surface 12 from the surface on which the charging device 1 is placed by lifting the charging device 1 in the Z direction by the user. The second handle 22 is parallel to the direction along the bottom surface 12 and is directed from the front to the back of the charging device 1 (in other words, the direction along the right side surface 15 or the left side surface 16: the X direction in FIG. 2). Is the longitudinal direction. The length in the longitudinal direction of the second handle 22 is formed to be longer than at least the size of the gripping fist of a human hand, like the first handle 21. Also,
It is provided at a position where the user can easily lift the charging device 1 upward by grasping the second handle 22. In this example, the second handle 22 has a longitudinal direction along the sides of the right side surface 15 and the left side surface 16 in the X direction so that the user can grip the second handle 22 at various positions in the X direction. The handle 22 is formed. A gap is provided between the first handle 21 and the inclined surface 17 and between the second handle 22 and the upper surface 11 so that the user can put his / her hand when gripping the handle 20.

  The connecting portion 23 is a member for connecting the first handle 21 and the second handle 22. The connecting part 23 is one of the ends of the first handle 21 that are not fixed to the inclined surface 17 and the one of the ends of the second handle 22 that is not fixed to the end 24. One end is connected. The end 24 is a member that changes the direction (X direction) extending in the longitudinal direction of the handle 20 to the vertical direction (Z direction), and is a member for fixing the other end of the second handle 22 to the upper surface 11.

  The rescue side connector 31 is a connection port for connecting to the rescue side cable 4. The rescue side connector 31 is provided with a cover, and a terminal connected to the connection terminal of the rescue side cable 4 appears by opening the cover. In addition, the relief-side connector 31 in a state where the cover is opened is shaped to be fitted to one end of the relief-side cable 4.

  The non-terminal side connector 32 is a connection port for connecting to the non-terminal side cable 5. Similarly to the rescue-side connector 31, the electricity-absent connector 32 has a cover and has a terminal connected to the connection terminal of the electricity-canceling cable 5.

  The switch 33 is a main switch for starting up the charging device 1. The start button 34 is a switch for starting charging. The stop button 35 is a switch for stopping charging. The emergency stop button 36 is a switch that is operated when an emergency stop of charging is made based on the judgment of the user. The rescue side display panel 37 is a display for displaying the state of the charging circuit on the rescue side. The electricity-absent-side display panel 38 is a display for displaying the state of the charging circuit on the electricity-absent side.

  The relief-side connector 31 and the non-power-supply side connector 32 are disposed on the inclined surface 17 that is one of the plurality of surfaces that constitute the housing 10. And the relief side connector 31 and the electric shortage side connector 32 have faced the same direction by arrange | positioning on the same plane. Further, since the inclined surface 17 is formed at a position on the upper surface 11 side in a direction perpendicular to the direction along the upper surface 11 and the bottom surface 12, the positions of the rescue side connector 31 and the terminal without plug 32 are located from the bottom surface 12. Near the top surface 11.

  The switch 33, the start button 34, the stop button 35, the emergency stop button 36, the rescue side panel 37, and the terminal side display panel 38 are provided on the inclined surface 17, and are flush with the side connector 31 and the terminal side connector 32. It is provided above.

  The ground connector 41 is a terminal for connecting a ground wire. The power harness connector is a terminal for connecting a power harness (see the figure). In this example, the controller power is obtained from the power input to the power supply ground connector. The ground connector 41 and the power harness connector 42 are provided on the right side surface 15.

  The slider 43 is a member for sliding the charging device 1 from the back side to the front side or from the front side to the back side (X direction in FIG. 2) on the surface on which the charging device 1 is placed. It is. The slider 43 is a resin member and is formed in a tapered shape. The sliders 43 are paired and provided on the bottom surface 12 in the vicinity of the right side surface 15 and the left side surface 16. The slider 43 has an elongated rectangular shape when viewed from the bottom surface 12 side. The longitudinal direction of the slider 43 is arranged so as to be parallel to the sides of the right side surface 15 and the left side surface 16 among the four sides of the bottom surface 12. Further, as shown in FIG. 5, the height of the slider 43 (the height in the Z direction) gradually decreases from the front side toward the back side.

  The roller 44 is a wheel for making the charging device 1 easy to move on the XY plane. The roller 44 is provided on each of the right side surface 15 and the left side surface 16. The roller 44 is provided at a portion corresponding to the corner portion A. When the user holds the first handle 21 with the hand in a state where the charging device 1 is placed on a plane and lifts the charging device 1 upward, the roller 44 serves as a fulcrum and rotates. The front side of the bottom surface 12 rises upward from the horizontal plane.

  The air inlet 45 has a hole for introducing air into the internal space of the housing 10. Two intake ports 45 are provided. Further, the air inlet 45 is provided on the back side surface 14. In the rear side surface 14, the air inlet 45 is disposed between the upper surface 11 and the bottom surface 12 so as to be closer to the bottom surface 12 in the Z direction, and between the right side surface 15 and the left side surface 16. In the direction, they are arranged closer to the right side surface 15 and the left side surface 16 than to the center of the back side surface 14. The intake port 45 has a plurality of louvers. The louver faces the direction of the bottom surface 12, and prevents rainwater and the like from entering from above and prevents a finger from entering the housing 10.

  The exhaust port 46 has a hole for exhausting air in the internal space of the housing 10. Two exhaust ports 46 are provided corresponding to the intake ports 45. The exhaust port 46 is provided on the front side surface 13. The exhaust port 46 is provided so as to face the corresponding intake port 45. The exhaust port 46 is also provided with a louver in the same manner as the intake port 45.

  The internal configuration of the charging device 1 will be described with reference to FIGS. FIG. 8 is a diagram for explaining the internal configuration of the charging device 1 and corresponds to a front view of the charging device 1. In FIG. 8, the external configuration of the casing 10 and the like among the configurations of the charging device 1 is indicated by a dotted line. FIG. 9 is a perspective view of the main body of the charging device 1. FIG. 10 is a perspective view showing the appearance of the DC / DC converter. 8 to 10 is only a part of the internal configuration of the charging device 1, and the charging device 1 includes other configurations such as a harness. Further, the direction of the DC / DC converter 100 in FIG. 8 and the direction of the DC / DC converter 100 in FIG. 10 are opposite to each other.

  The charging device 1 includes, as an internal configuration, a main controller 50, a board 61, a metal plate 62, a fixing member 63, a heat sink 64, a fan 65, a switching element 101, a transformer 102, a diode 103, and a capacitor. 104.

  The main controller 50 is provided on the back side of the upper surface 11 (the surface facing the internal space side of the housing 10) which is a part of the configuration of the lid 18 of the housing 10. The main controller 50 is a controller that controls the charging device 1.

  The substrate 61 is a substrate on which the switching element 101, the transformer 102, the diode 103, and the capacitor 104, which are circuit elements constituting the DC / DC converter 100, are mounted.

  The metal plate 62 is a plate that divides the internal space of the housing 10 into two parts on the upper surface 11 side and the bottom surface 12 side. The surface of the metal plate 62 is arranged so as to be parallel to the upper surface 11 and the bottom surface 12. Of the two surfaces of the metal plate 62 (surface along the XY plane: see FIG. 8), a substrate is provided on one surface, and the substrate 61 and the metal plate 62 are laminated in layers.

  The fixing member 63 is an L-shaped member and is fixed to the right side surface 15 and the left side surface 16 in pairs. The fixing member 63 also fixes the substrate 61 and the metal plate 62. That is, the substrate 61 and the metal plate 62 are fixed to the right side surface 15 and the left side surface 16 via the fixing member 63, respectively. The fixing member 63 is provided between the top surface 11 and the bottom surface 12 closer to the bottom surface than the top surface. When the substrate 61 and the metal plate 62 are installed in the housing 10, the substrate 61 and the metal plate 62 are fixed to the fixing member 63 so that the substrate 61 faces the bottom surface 12 and the metal plate 62 faces the top surface 11. It is fixed to.

  The heat sink 64 is a member for cooling the heat of the switching element 101, and is configured by arranging a plurality of metal plates in parallel with each other. The heat sink 64 is provided so as to be close to the position of the switching element 101. Specifically, the switching element 101 is positioned via the substrate 61 and the metal plate 62 on the back surface (the surface opposite to the plurality of metal plates) of the plate that supports the plurality of metal plates of the heat sink 64. The heat sink 64 is provided on the surface of the substrate 62. The heat sink 64 is paired with a plurality of switching elements 101 arranged at both ends of the substrate 61.

  The fan 65 is a cooling device for further introducing air from the air inlet 45, and is fixed to the rear side surface 14 so as to be disposed between the air inlet 45 and the heat sink 64. The fan 65 is also paired with the heat sink 64.

  The positions where the air inlet 45, the air outlet 46, the heat sink 64, and the fan 65 are aligned in a direction perpendicular to the direction along the front side surface 13 and the rear side surface 14 (X direction: see FIG. 9). Arranged in relation. Therefore, the intake port 45 and the exhaust port 46 are disposed at positions facing each other via the heat sink 64 and the fan 65. Thereby, in this example, the air on the back side of the charging device 1 is taken into the housing 1 from the air inlet 45 and flows along the plurality of metal plates of the heat sink 64 via the fan 65 to be exhausted. It is discharged from the port 46 to the front side of the charging device 1. This air flow enhances the cooling effect of the heat sink 64.

  As shown in FIG. 10, a plurality of switching elements 101 are arranged in a row in the X direction at both ends in the Y direction on the surface of the substrate 61 and in parallel with the direction along the plurality of metal plates of the heat sink 64. . The plurality of switching elements 101 are elements for converting DC power input from the battery of the rescue-side vehicle 2 into AC power, and are switched on and off based on control of the main controller 50. The switching element 101 generates heat by this switching operation.

  The transformer 102 is composed of a plurality of coils, and is a transformer that transforms an AC voltage input from the switching element 101. Since the DC / DC converter on the high power side in this example uses the transformer 102, the weight increases.

  The diode 103 is a rectifier that rectifies AC power input from the transformer 102 by being connected in a bridge shape. The diodes 103 are arranged in a line at the central portion of the surface of the substrate 61. The capacitor 104 is a smoothing capacitor. The transformer 102 and the capacitor 104 are disposed between the switching element 101 and the diode 103. FIG. 10 only shows an example of the layout of the circuit configuration of the DC / DC converter 100, and other layouts may be used.

  Here, with reference to FIGS. 8-10, the positional relationship of the circuit element which comprises the DC / DC converter 100, the metal plate 62, and the controller 50 is demonstrated. The switching element 101 is provided on one surface of the pair of surfaces of the metal plate 62 via the substrate 61. On the other hand, the main controller 50 is provided at a position away from the surface of the metal plate 62 on the side opposite to the one surface where the switching element 101 is provided with respect to the metal plate 62.

  In order to prevent adverse effects on the main controller 50, heat generated from the switching element 101 should not be transmitted to the main controller 50. In this example, since the main controller 50 and the switching element 101 are separated by a metal plate, the heat of the switching element 101 can be prevented from being transmitted to the main controller 50. Further, the metal plate 62 is provided on the right side surface 15 and the left side surface 16 corresponding to the main body of the housing 10, and the main controller 50 is provided on the lid. Therefore, a space that blocks heat is formed between the metal plate 62 and the main controller 50, so that heat conduction from the metal plate 62 to the main controller 50 can be blocked.

  In addition to the thermal problem of the switching element 101, there is also a problem of noise due to the switching operation. In this example, with respect to a pair of surfaces of the metal plate, a switching element is disposed on one surface side, and a main controller 50 is disposed on the other surface side. Therefore, the metal plate 62 acts as a shielding plate and prevents noise generated by the switching element 101 from leaking to the main controller 50 side.

  Further, the DC / DC converter 100 is disposed between the upper surface 11 and the bottom surface 12 closer to the bottom surface 12 than the upper surface. That is, by placing a heavy configuration like the DC / DC converter 100 further downward, the center of gravity is lowered and the stability is improved.

  Next, a state in which the lid 18 of the charging device 1 is removed from the main body 19 will be described with reference to FIG. FIG. 11 is a right side view of the charging device 1 with the lid of the charging device 1 removed. In FIG. 11, the internal configuration of the charging device 1 is indicated by a dotted line. Further, although the controller 50 and the DC / DC converter 100 are connected by a harness or the like, they are not shown in FIG.

  When the lid 18 is removed from the main body, the controller 50 is fixed to the lid 18 and thus is separated from the main body 19. On the other hand, since the metal plate 62 is fixed to the main body, the DC / DC converter 100 is not separated from the main body. For example, when performing maintenance such as changing the charging sequence, the operator may touch the controller 50. In this example, since the controller 50 can be removed from the main body by removing the lid 18, maintenance workability can be improved.

  Next, a configuration related to control and control of the charging system including the charging device 1 will be described with reference to FIG. FIG. 12 is a block diagram of the charging system of this example. The solid line represents the power line 72 on the high power side, and the two-dot chain line represents the power line 71 on the low power side.

  As shown in FIG. 12, the charging device 1 includes a discharge side main controller 52, a charging side main controller 52, and converters 61 and 62 in addition to the DC / DC converter 100.

  The discharge side main controller 51 is a controller for controlling a discharge side (rescue side) charging circuit connected to the battery of the rescue vehicle 2. The charging side main controller 52 is a controller for controlling a charging side (electricity short side) charging circuit connected to the battery of the electric shortage vehicle 3. 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 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 one controller.

  The discharge side main controller 51 has an insulation detection unit 53, and the charge side main controller 52 has an insulation detection circuit 54. The insulation detection unit 53 detects that the charging circuit on the discharge side is insulated from the voltage change of the ground fault detection circuit 63. The insulation detection unit 54 detects that the charging circuit on the charging side is insulated from the voltage change 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. The electric power for driving the discharge side main controller 51 and the charge side main controller 52 is acquired from the power line 71 on the low power side.

  The power harness 6 is a part of the wiring on the low power side. One end of the power harness 6 is connected to the power harness connector 42. On the other hand, the other end of the power harness 6 is connected to the cigar socket of the rescue vehicle 2. 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 2. That is, by connecting the power harness 6 between the cigar socket and the power harness connector 42, the power of the low-power battery of the rescue vehicle 2 can be output. The power harness 6 may be connected to a cigar socket of the electric vehicle 3.

  The converter 61 is a conversion circuit for boosting the input voltage from the power line 71 on the weak power side and outputting it to the charging circuit 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 that boosts the input voltage from the power line 71 on the low power side and outputs the boosted voltage to the charging circuit 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 confirming insulation of the charging circuit on the discharge side including the power line 72 on the high power side, and is formed in the charging circuit on the discharge side. The ground fault detection circuit 64 is a circuit for confirming the insulation of the charging circuit on the charging side including the power line 73 on the high power side, and is formed in the charging circuit on the charging side.

  The DC / DC converter 100 includes an inverter 110, a transformer 120, a rectifier circuit 130, and a smoothing circuit 140. 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 DC / DC converter 100 is a converter that transforms the voltage of the battery on the high-power side of the rescue vehicle 2 and outputs the voltage to the battery on the high-power side of the non-powered vehicle 3. 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 inverter 110 is configured by a circuit in which a plurality of switching elements 101 are connected in a bridge shape. The inverter 110 converts the DC power input from the rescue side connector into AC power by switching on and off the plurality of switching elements 101 based on the switching signal from the main controller 50, and transforms the transformer 120. Output to.

  The transformer 120 corresponds to the transformer 102. Of the coils constituting the transformer 120, the primary side coil is included in the discharging side charging circuit. On the other hand, the secondary coil is included in the charging circuit.

  The rectifier circuit 130 includes a diode 130 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 130.

  The smoothing circuit 140 is composed of an LC circuit including the capacitor 104 and smoothes the output voltage of the rectifier circuit 130.

  The charging circuit of the charging device 1 is separated by a transformer 120 on the discharging side (primary side) and the charging side (secondary side). With the coil of the transformer 120 as a boundary, the discharge-side charging circuit 201 is connected to the primary coil of the transformer 120, the inverter 110, the ground fault detection circuit 63, the rescue-side cable 4, the high-power-side power line 72, and the rescue vehicle 2. It is formed by a circuit including a charging port (a connection port with the rescue side cable 4). 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 failure side cable 5, a high power side power line 73, and a power loss vehicle 3. It is formed by a circuit including a charging port (a connection port of the electric charge side cable 45).

  Here, in the charging system shown in FIG. 12, the relationship between the low-power side power line 71 and the high-power side power line 72 and the low-power side battery and the charging battery mounted on the vehicle will be described. First, the low power side battery and the high power side battery of the rescue vehicle 2 will be described.

  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. Generally, the voltage of the high voltage side battery is several hundred volts or more. On the other hand, the voltage of the low power side battery is about several tens of volts. However, the voltage of the low-power side battery is lower than the voltage of the high-power side battery, but is higher than the voltage of the battery that can output only about several volts of 1 to 2V.

  As shown in FIG. 12, the power line 71 on the low power side is electrically connected to the battery on the low power side of the rescue vehicle 2. The main controller 50 is designed to operate with the voltage of the battery on the low power side. Therefore, the main controller 50 acquires drive power and becomes a startable state by connecting the low-power side battery of the rescue vehicle 2 to the low-power side power line.

  On the other hand, the power lines 72 and 73 on the high power side are electrically connected to the high power side battery of the rescue vehicle 2 and the high power side battery of the non-powered vehicle 3, and are connected to the DC / DC converter 100. That is, the charging system of the present example separates the low-power side power line 71 and the high-power side power lines 72 and 73 in correspondence with the low-power side battery and the high-power battery mounted on the vehicle. Further, the main controller 50 driven by low power is connected to the low power side power line, and the charging circuit is constituted by the high power side power line. Thereby, this example implement | achieves the system which divided | segmented the system voltage within the charging device 1, without providing the battery in the charging device 1. FIG.

  Next, control of the charging device 1 of this example will be described with reference to FIG. When the user presses the start button 34 in a state where the rescue side cable 4, the electric shortage side cable 5, and the power harness cable 6 are connected to the charging device 1, the rescue vehicle 2, and the electric shortage vehicle 3, the main controller 50 starts and acquires electric power from the low power side battery of the rescue vehicle 2 via the low power side power line.

  The main controller 50 activates the charging side main controller 51 to communicate with the rescue vehicle 2 side via the rescue side cable 4. Up to this point, the discharge side charging circuit is insulated by, for example, turning off a relay (not shown) provided in the high power side power source in the charging circuit.

  Next, the main controller 50 turns on the above-described relay to bring the discharging side charging circuit into a conductive state. At this time, there is no power supply from the high power side battery of the vehicle 2 to the charging device 1.

  The discharge-side main controller 51 controls the converter 61 with 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 or absence of a ground fault or a short circuit in the charging circuit 201 on the discharge side by detecting the voltage of the ground fault detection circuit 63 during application of the test voltage. When the discharge-side main controller 53 detects a ground fault or a short circuit, the discharge-side main controller 53 determines that insulation is not secured, and displays a message indicating that insulation is not secured on the rescue-side display panel 37.

  When it is confirmed that insulation of the discharge side charging circuit 201 is ensured, the main controller 50 activates the charging side main controller 52. Similarly to the discharge side main controller 51, the charging side main controller 52 communicates with the electric vehicle 3 side via the electric side cable 5. In addition, the charge-side main controller 52 controls the converter 62 by the insulation detection circuit 53 to boost the voltage of the power line 71 on the low power side and apply it to the charge circuit 202 on the charge side. And the insulation detection part 54 detects the presence or absence of a ground fault and a short circuit in the charging circuit 201 on the discharge side by detecting the voltage of the ground fault detection circuit 63.

  When insulation of the charging circuit 201 and the charging circuit 202 on the discharge side is confirmed, the main controller 51 on the discharge side turns on the main relay on the discharge side to change the power of the battery on the high power side of the rescue vehicle 2 to DC / DC. The converter 100 can be output. 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 2. Although the main relay is not shown in FIG. 12, 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 DC / Connected between the output side of the DC converter 100 and the non-current side connector 62.

  After turning on the respective main relays, the main controller 100 controls the switching element 101 of the inverter 110 to start charging the high-power battery of the electric vehicle 3.

  During charging, the battery controller (not shown) of the rescue vehicle 2 manages the SOC of the discharged battery, and the battery controller (not shown) of the unpowered vehicle 3 manages the SOC of the charged battery. Yes.

  The main controller 50 acquires the battery information of the battery being discharged and the battery being charged from the battery controller of each of the power supply vehicle 2 and the electric shortage vehicle 3. Then, when the SOC of the battery being charged reaches the target SOC, the main controller 50 stops the charging and displays on the rescue side display panel 37 and the power loss side display panel 38 that the charging is finished.

  When the user presses the stop button 35, the charging-side main controller 52 transmits a signal to the effect that charging is terminated to the battery controller of the unpowered vehicle 3. The charging-side main controller 52 turns off the charging-side main relay after confirming the response signal from the battery controller of the unpowered vehicle 3.

  Similarly, the discharge-side main controller 51 transmits a signal to the effect that charging is terminated to the battery controller of the rescue vehicle 2. When the discharge-side main controller 51 receives a response signal to the signal, the discharge-side main controller 51 turns off the discharge-side main relay. Thereby, the charging device 1 complete | finishes charge.

  Next, the control flow of the charging system of this example will be described. FIG. 13 is a flowchart showing a control procedure of the charging system. In FIG. 13, the control flow shown in the rescue vehicle 2 and the electric shortage vehicle 3 is the control performed by each controller.

  In step S1, the discharge side main controller 51 and the controller of the rescue vehicle 2 establish communication by transmitting and receiving signals. In step S2, the discharge-side main controller 51 controls the converter 61 and the ground fault detection circuit 63 to confirm insulation of the discharge-side charging circuit. In step S3, the discharge-side main controller 51 turns on the discharge-side main relay.

  In step S4, the discharge-side main controller 51 transmits an activation signal to the charging-side main controller 52, and the charging-side main controller 52 is activated by receiving the activation signal.

  In step S5, the charging side main controller 53 and the controller of the unpowered vehicle 3 establish communication by transmitting and receiving signals. In step S6, the charging side main controller 52 controls the converter 62 and the ground fault detection circuit 64 to confirm the insulation of the charging side charging circuit. In step S7, the charging-side main controller 52 turns on the charging-side main relay.

  In step S <b> 8, the controllers of the rescue vehicle 2 and the shortage vehicle 3, the discharge side main controller 51, and the charge side main controller 52 perform charge control.

  When the stop button 35 is pressed by the user, in step S9, the charging side main controller 52 transmits a signal indicating that charging has been completed to the controller of the unpowered vehicle 3, and the controller of the unpowered vehicle 3 Is received to confirm the end of charging and the control is terminated.

  In step S10, the charging-side main controller 52 turns off the charging-side main relay. In step S <b> 11, the charging side main controller 52 transmits a signal indicating that charging has ended to the discharging side main controller 51, and ends the control. The discharge side main controller 51 confirms the end of charging by receiving the signal.

  In step S12, the charging-side main controller 52 transmits a signal indicating that charging has been completed to the controller of the unpowered vehicle 3, and the controller of the unpowered vehicle 3 confirms the completion of charging by receiving the signal. Then, control ends. In step S13, the discharge-side main controller 51 turns off the charge-side main relay and ends the control.

  Next, the state where the charging device 1 is placed on the trunk will be described with reference to FIG. FIG. 14 is a diagram for explaining a state where the charging device 1 is mounted on the rescue vehicle 2 with the trunk opened.

  When the charging device 1 of this example is used in bad weather such as rainy weather, the user charges the battery with the charging device 1 placed on the trunk without taking the charging device 1 out of the trunk. Therefore, as shown in FIG. 14, the charging device 1 has an outer shape that fits in the trunk. Then, in the state of FIG. 14, the power harness 6 is connected to the cigar socket of the rescue vehicle 2 through the vehicle interior, the rescue cable 4 is connected to the charging port of the rescue vehicle 2, and the electric short cable 5 is connected to the electric vehicle 3. Connect to the charging port. Thereby, since wiring as shown in FIG. 12 is constructed, charging can be performed without taking out the charging device 1 from the trunk.

  Furthermore, in this example, in order to improve the usability of the charging device 1, as shown in FIG. 15, the operation parts such as the rescue side connector 31, the terminal without charge side connector 32, and the switch 33 are arranged on the inclined surface at 17. The inclined surface 17 is disposed so as to be higher than the step 210 of the trunk. FIG. 15 is a view as seen from an arrow XV shown in FIG.

  The shape of the trunk differs depending on the vehicle type, and depending on the vehicle type, there is a trunk having a step 210 as shown in FIGS. When the charging device 1 is used in such a trunk, it is easier for the user to operate the charging device 1 when the connecting portion of the cable and the operation surface of the user face the opening side of the trunk.

  In this example, when the charging device 1 is placed in the trunk with the front side of the charging device 1 facing the opening of the trunk, the front side surface 13 of the charging device 1 is set to the step 210 (step 210 of the feeding vehicle 2. The outer shape of the housing is designed to face the surface facing the inside of the trunk. Then, the inclined surface 17 is formed on the upper side of the front side surface 13, and the relief side connector 31 and the switch 33 are arranged on the inclined surface 17, so that the connector and the operation portion face the opening side of the trunk. ing.

  Further, in this example, the front side surface 13 and the step 210 are opposed to each other. For example, when the charging operation is performed while the rescue vehicle 2 is stopped on an uphill, even if the charging device 1 slides toward the opening in the trunk, the front side surface 13 hits the step 210. The movement of the charging device 1 is restricted. As a result, the charging device 1 can be prevented from dropping from the trunk.

  Next, a process when the charging device 1 is taken out from the trunk having the step 210 to the outside of the trunk will be described with reference to FIGS. 16, 18, 20, and 22 show perspective views of the charging device 1, the rescue vehicle 2, and the user. The order of FIGS. 16, 18, 20, and 22 corresponds to the order of steps when taking out the charging device 1 from the rescue vehicle 2. 18, 21, and 23 are diagrams for explaining the states of FIGS. 17, 20, and 22, respectively, and show a right side view of the charging device 1 and a partial cross-sectional view of the trunk.

  First, as shown in FIG. 16, the user moves the charging device 1 to a position where it can be easily taken out by grasping the first handle 21 and sliding the charging device 1 toward the step of the trunk. At this time, since the slider 43 is provided on the bottom surface 12 of the charging device 1 and the roller 44 is provided at the corner A, the charging device 1 can be easily moved (see FIG. 5). .

  Next, as shown in FIG. 17, the user raises the position of the first handle 21 while holding the first handle 21. As shown in FIG. 18, the charging device 1 rotates with the roller 44 rotating as a fulcrum with respect to the upward force applied to the first handle 21. Then, the front side of the charging device 1 is lifted up, and the front side rises to a height that rides on the step 110. Further, the roller 44 moves so as to approach the step 110 in a state where the front side of the charging device 1 is lifted.

  At this time, since the first handle 21 is provided at a position facing the corner A and has the longitudinal direction upward, when rotating the charging device 1, the user applies the force in the rotational direction to the charging device. 1 can be easily added. Moreover, the charging device 1 is easy to rotate by providing a wheel at the corner portion A. Therefore, the user can lift the charging device 1 while rotating the charging device 1 with a small force.

  Further, as shown in FIG. 18, the front end of the slider 43 is brought into contact with the tip of the step 210, and in the next step, the charging device 1 is further lifted using this contacting portion as a fulcrum.

  Next, as shown in FIG. 19, the user slides the slider 43 on the edge portion B by pulling the first handle 21 while placing the slider 43 on the edge portion B of the step 210, thereby charging the charging device 1. Move. Then, the charging device 1 moves the charging device 1 so as to get on the step 210 of the trunk. At this time, since the longitudinal direction of the first handle 21 faces upward, the user grips the handle 20 in the vertical direction. About the operation | movement which pulls the charging device 1 to the front side, it is easier to apply force with respect to the charging device 1 when the handle 20 is gripped by a vertical grip than when the handle 20 is gripped by a horizontal grip. Note that the horizontal grip is a state in which the handle 22 is gripped.

  In addition, as shown in FIG. 20, the structure in which the charging device 1 can easily exceed the step 210 by sliding the slider 43 at the edge portion 43 in response to the user pulling the first handle 21. doing.

  Next, as shown in FIG. 21, the user changes the handle from the first handle 21 to the second handle 22 in a state where the charging device 1 has climbed the step 210. At this time, as shown in FIG. 22, since the step 210 is in contact with the resin slider 43, the step 210 can be prevented from being damaged. Even if the user pulls the charging device 1 too far and the charging device 1 comes into contact with the bumper, the bumper can be prevented from being damaged because it contacts the resin slider 43.

  Then, in the state of FIG. 21, the user lifts the charging device 1 upward while grasping the second handle 22. The longitudinal direction of the second handle 22 faces the lateral direction. When the charging device 1 is lifted from the state of FIG. 21, there is no such fulcrum as described above, and gripping the handle 20 with a horizontal grip is easier than gripping the handle 20 with a vertical grip. However, it is easy to apply force to the charging device 1. Therefore, in this example, the charging device 1 is configured to be easily carried by providing the second handle 22 in addition to the first handle 21.

  Further, when the charging device 1 is lifted to a position directly above the height of the step from the state completely within the trunk of the charging device 1, the user is bent forward (see FIG. 16). Since work is to be done, the waist is burdened. On the other hand, according to the present invention, since the operation of raising the charging device 1 directly above is performed in a state where the charging device 1 rides on the step 210, the user does not perform such work in a forward bending state. Good. As a result, the burden on the waist can be reduced.

  As described above, in this example, the relief-side connector 31 and the electricity-absent-side connector 32 are arranged on one surface among a plurality of surfaces constituting the housing 10. Thereby, since the user can confirm the connection destination of a cable easily, the usability of a charging device can be improved.

  In particular, when the charging device 1 is used in a state in which it is placed in the trunk, when the rescue side connector 31 and the unplugged side connector 32 are arranged on different surfaces, it is easy to connect when connecting the connector and the cable. If it is going to move the charging device 1 so that it may become such a surface, the frequency | count of the movement will increase and usability will be bad. In this example, since the two connectors are arranged on the same surface, even when the charging device 1 is moved in the trunk when connecting the cables, the number of movements can be reduced. As a result, the usability of the charging device can be improved.

  Further, in this example, the switch is directed in one direction among a plurality of directions that are perpendicular to the respective directions along the front side surface 13, the back side surface 14, the right side surface 15, and the left side surface. An operation portion such as 33, a relief side connector 31 and an electric shortage side connector 32 are arranged. As shown in FIG. 14, when the battery 1 is charged with the charging device 1 placed in the trunk, the heat in the charging device 1 is not in the vehicle interior that is the direction of the air intake 45 but in the vehicle. It can be discharged outside. As a result, the heat of the charging device 1 can be prevented from being trapped in the passenger compartment.

  Further, in this example, the relief side connector 31 and the non-terminal side connector 32 are arranged in the same direction and at a position closer to the upper surface 11 than the bottom surface 12. Thereby, since the user can confirm the connection destination of a cable easily, the usability of a charging device can be improved. In particular, when the charging device 1 is placed in the trunk, the direction of the connector faces the opening of the trunk, so that the usability of the charging device can be improved.

  Further, in this example, the relief side connector 31 and the non-terminal side connector 32 are arranged on the inclined surface 17. Thereby, since the user can confirm the connection destination of a cable easily, the usability of a charging device can be improved. In particular, when the charging device 1 is placed in the trunk, the direction of the connector faces the opening of the trunk, so that the usability of the charging device can be improved.

  In the above, the DC / DC converter 100 corresponds to the “transformer” of the present invention, the rescue side connector 31 is the “power supply side connector” of the present invention, the non-current side connector 32 is the “power reception side connector”, the exhaust port 46 corresponds to the “discharge section” of the present invention.

DESCRIPTION OF SYMBOLS 1 ... Charging device 2 ... Rescue vehicle 3 ... Electric shortage vehicle 4 ... Relief side cable 5 ... Electric shortage side cable 6 ... Power supply harness 10 ... Housing 11 ... Upper surface 12 ... Bottom surface 13 ... Front side surface 14 ... Back side surface 15 ... Right side 16 ... Left side 17 ... Inclined surface (front side)
DESCRIPTION OF SYMBOLS 18 ... Lid body 19 ... Main body 20 ... Handle 21 ... 1st handle 22 ... 2nd handle 23 ... Connection part 31 ... Rescue side connector 32 ... Electron-less side connector 33 ... Switch 34 ... Start button 35 ... Stop button 36 ... Emergency stop Button 37 ... Relief side display panel 38 ... Electronic side display panel

Claims (4)

In the charging device that charges the battery of the power receiving vehicle with the power of the battery of the power feeding vehicle,
Transforming means for transforming the voltage of the battery on the power supply side and outputting the voltage to the battery on the power receiving side;
A housing for accommodating the transforming means in a plurality of planes;
A power supply side connector for connecting a power supply side cable electrically connected to the battery on the power supply side;
A charging connector for connecting a power receiving side cable electrically connected to the power receiving side battery;
The power feeding side connector and the power receiving side connector are arranged on one surface among the plurality of surfaces. The charging device according to claim 1,
A discharge part for discharging the air in the housing;
The housing has a bottom surface and a plurality of side surfaces surrounding the bottom surface,
The power supply side connector, the power reception side connector, and the discharge portion are:
The charging device is arranged in one direction among a plurality of directions perpendicular to the direction along the plurality of side surfaces. The charging device according to claim 1 or 2,
The housing has a bottom surface, a plurality of side surfaces surrounding the bottom surface, and a top surface located on the opposite side of the bottom surface via the plurality of side surfaces,
The power supply side connector and the power reception side connector are:
A charging device, wherein the charging device is disposed in the same direction and at a position closer to the top surface than the bottom surface. It is a charging device as described in any one of Claims 1-3,
The housing is
The bottom,
A first surface that is a surface along a vertical direction with respect to a direction along the bottom surface;
A second surface inclined with respect to a surface along the first surface,
The charging device, wherein the power supply side connector and the power reception side connector are arranged on the second surface.

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