JP2009220806A - Drive unit and power distribution device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a drive unit capable of reducing the length of a wire used for driving a load circuit fitted to vehicular electrical equipment. <P>SOLUTION: A load circuit drive unit 1 comprises an ECU 2 and a power distribution box 5. The ECU 2 is provided in each module which is an object of drive control. Based on an input signal from a sensor, a switch and the like provided in the module which is the object of the control, each ECU 2 outputs a control signal controlling the motion of the electrical equipment corresponding to an input signal. The power distribution box 5 is provided in each area which is a part a vehicle comprising the load circuit drive unit 1 is divided to respective portions of the vehicle where the electrical equipment is arranged. Each power distribution box 5 supplies power through a power wire from an IPS to the load circuit whose control is instructed by the ECU 2. Also, a drive control signal is supplied from a CPU through a communication wire. Each load circuit that has received power and the drive control signal performs predetermined motion. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a drive device that drives a load circuit included in an on-vehicle electrical component, and a power distribution device used in the drive device.

  Drive control of vehicle electrical components is performed by an ECU (Electronic Control Unit). As shown in Patent Document 1 below, the ECU is provided for each module including electrical components such as a power window and a door lock. Each ECU is connected to the power distribution BOX by a power line and a GND line, and power is supplied from the vehicle-mounted battery via the power distribution BOX. Load circuits such as motors and lamps provided in each electrical component are a power line and a GND line, and depending on the circuit, the load circuit is further connected to the ECU via a communication line. Each load circuit is driven in accordance with power supplied from the ECU via a power line or a drive control signal supplied via a communication line.

JP 2004-255902 A

  In the above-described conventional drive system, the power supplied from the power distribution box is supplied from the ECU that controls the electrical component including the load circuit regardless of the position of the load circuit. As a whole, the power supply line and the GND line used for the power supply of the power supply become long, resulting in an increase in weight.

  In view of the above-described points, an object of the present invention is to provide a drive device and a power distribution device that can reduce the length of wiring used for driving a load circuit included in a vehicle electrical component.

In order to achieve such an object, the present invention provides a power distribution device that is provided for each of a plurality of areas for dividing a vehicle and distributes power to load circuits installed in each of the areas, and the power distribution device. And a control device for controlling power distribution according to the above.
Further, the present invention is characterized in that the power distribution device performs drive control of the load circuit that distributes power, and the control device controls drive control of the load circuit by the power distribution device.
Further, the present invention is characterized in that the power distribution device includes a semiconductor relay with an overcurrent protection function that shuts off power supply to the load circuit when an overcurrent is detected.
Further, the present invention is characterized in that the control device is driven by distributing power by the power distribution device.
In the present invention, the control device is installed in any one of the areas provided with the power distribution device, and power is distributed by the power distribution device in the installed area or any other area. It is characterized by being driven.
According to the present invention, the power distribution device distributes power to the control device in any other area in addition to the main power circuit for distributing power to the control device in the installation area of the power distribution device. When the semiconductor relay with an overcurrent protection function detects an overcurrent, the control device requests power distribution to a power distribution device in another area, and the control device in another area When the power distribution is requested by the sub power circuit, the sub power circuit distributes the power to the control device in the requested area.

  According to the present invention, since it is not necessary to perform power distribution between the control device and the power distribution device, it is possible to reduce the length of the load circuit drive wiring included in the vehicle electrical component.

It is a figure which shows the outline of a structure of the load circuit drive device of one Embodiment of this invention. It is a figure explaining the wiring aspect in the load circuit drive device of this invention compared with the wiring aspect in the conventional load circuit drive device. It is a figure explaining the modification of the load circuit drive device of this invention.

Hereinafter, the best mode of the present invention will be described with reference to the drawings.
FIG. 1 is a diagram conceptually showing the configuration of the load circuit driving apparatus 1 of the present embodiment. The load circuit drive device 1 is a system that drives a load circuit included in a vehicle electrical component, and includes an electronic control unit (ECU (Electronic Control Unit)) 2 and a power distribution BOX 5.

  The ECU 2 is provided for each module subject to drive control, such as an air conditioner or a power window, and is attached to the electrical junction box 3. Each ECU 2 is a control device that outputs a control signal for controlling the operation of the electrical component corresponding to the input signal based on an input signal from a sensor, a switch, or the like included in a module to be controlled.

  In the example shown in the figure, drive control of three modules: a module MA composed of electrical components D1 such as lighting, a module MB composed of electrical components D2 such as power sheets, and a module MC composed of electrical components D3 and D4 such as power windows. ECUs 2a to 2c used in the above are shown. The ECU 2c controls the operation of the electrical component D3 according to the input signal from the sensor SD3 and the like, and the operation of the electrical component D4 according to the input signal from the sensor SD4 and the switch SWD4 and the like. The ECUs 2a and 2b also control the operations of the electrical components D1 and D2 in response to input signals from sensors and switches (not shown) provided in the electrical components D1 and D2.

  The power distribution BOX 5 is a power distribution device provided in each area where the vehicle on which the load circuit driving device 1 is configured is divided for each part of the vehicle where the electrical components are installed. The vehicle including the load circuit driving device 1 is provided with, for example, a total of six areas in which the engine room, the room, and the trunk room and the areas dividing the vehicle in the front-rear direction are divided into left and right, respectively. A power distribution BOX 5 is installed in the area. Each power distribution BOX 5 includes a CPU (Central Processing Unit) that controls each unit, a ROM (Read Only Memory) (not shown) that stores a control program and various data used for the operation of the CPU, and data processed by the CPU. Is stored in a RAM (Random Access Memory) (not shown). The CPU controls communication with each ECU 2 connected by wiring, power supply to the ECU 2 and each load circuit, and driving of each load circuit. The drive control of each load circuit by the CPU is performed based on a control signal supplied from the ECU 2.

  The power distribution BOX 5 includes a semiconductor relay IPS (intelligent power switch) with a current detection function for supplying power to each load circuit. The IPS supplies power to the load circuit provided in the installation area of the power distribution BOX 5 under the control of the CPU. The power distribution BOX 5 includes a power supply device (not shown) that converts the power supplied from the in-vehicle battery into a predetermined voltage, and the power converted by the power supply device is distributed and supplied by the IPS. In addition, the IPS performs protection operation by detecting overcurrent, overvoltage, and overtemperature rise. Note that the power converted by the power supply device (not shown) is also distributed to the CPU and the ECU 2. When a plurality of power distribution BOXs 5 are provided, power is supplied from any one of the power distribution BOXs 5 to the ECU 2.

  In the example shown in the figure, power distribution boxes 51, 52 provided in two areas, an area A1 in the right room and an area A2 in the left room, are shown. The power distribution BOX 51 installed in the area A1 includes a load circuit D11 such as a lamp of an electrical component D1 such as lighting and a load circuit D21 such as a motor of an electrical component D2 such as a power seat, a power window, etc. The power is supplied from the IPS to the load circuits D31 to D33 such as the motor of the electric component D3 such as the motor and the load circuit D41 such as the motor of the electric component D4 such as the door lock. Further, a drive control signal is supplied from the CPU to the load circuits D32 and D33 of the electrical component D3 and the load circuit D41 of the electrical component D4.

  The power distribution BOX 52 installed in the area A2 includes a load circuit D13 such as a lamp of an electrical component D1 such as an illumination, a load circuit D22 and D23 such as a motor of an electrical component D2 such as a power seat, and the like provided in the area. In addition, power is supplied from the IPS to load circuits D34 and D35 such as a motor of an electrical component D3 such as a power window. The power distribution BOX 51 or 52 supplies power to the ECUs 2a to 2c via the electrical connection box 3.

  The power distribution BOX 5 is connected to the load circuit and the ECU 2 to which power is distributed by the power line and the GND line. Further, the power distribution BOX 5 is connected to each ECU 2 and some load circuits such as a motor to which a drive control signal is supplied through a communication line. Each ECU 2 is connected to a sensor, a switch, or the like included in the control target module through a signal line.

  In the example shown in the figure, the ECUs 2 a to 2 c are connected to the electrical junction box 3 by connectors 41. The electrical junction box 3 is installed in the instrument panel. Signal lines connected to the sensor SD3 of the electrical component D3, the sensor SD4 of the electrical component D4, and the switch SWD4 are connected to the electrical connection box 3 by a connector 42. An internal signal line connecting the connector 41 and the connector 42 is wired inside the electrical junction box 3, and the sensor SD3 of the electrical component D3, the sensor SD4 of the electrical component D4, the switch SWD4, and the ECU 2c are connected to the signal line and It is electrically connected via an internal signal line. In addition, a power line, a GND line, and a communication line connecting the power distribution boxes 51 and 52 are connected to the electrical connection box 3 by a connector 43. An internal power supply line, an internal GND line, and an internal communication line that connect the connector 41 and the connector 43 are wired inside the electrical junction box 3, and the power distribution boxes 51 and 52 and the ECUs 2a to 2c are electrically connected to each other. It is connected to the. Note that a rectifying diode is connected to the internal power supply line of the electrical junction box 3, and the power supplied from the power distribution box 51 or 52 does not flow from the connector 43 to the outside through the internal power supply line.

  In addition, a power supply line, a GND line, and a communication line that connect the electrical connection box 3 are connected to the power distribution boxes 51 and 52 by a connector 61. The power distribution BOX 51 includes a power line and a GND connecting the load circuits D11 and D12 of the electrical component D1, the load circuit D21 of the electrical component D2, the load circuits D31 to D33 of the electrical component D3, and the load circuit D41 of the electrical component D4. The line 62 is connected to the connector 62. In addition, a communication line connecting the load circuits D32 and D33 of the electrical component D3 and the load circuit D41 of the electrical component D4 is also connected to the power distribution BOX 51 by a connector 62. The power distribution BOX 52 is connected by a connector 62 with a wire 62 and a GND wire connecting the load circuit D13 of the electrical component D1, the load circuits D22 and D23 of the electrical component D2, and the load circuits D34 and D35 of the electrical component D3. Has been.

  The power distribution boxes 51 and 52 are connected to the power line connected to the in-vehicle battery and the grounded GND line via the connector 63. Internal power supply lines and internal GND lines connected to the connector 63 are wired inside the power distribution boxes 51 and 52. The internal power supply line is connected to the CPU, IPS, connector 61, and power supply device (not shown). The internal GND line is connected to the CPU, IPS, connector 61, connector 62, and power supply device (not shown).

  Next, an operation of driving and controlling each load circuit included in the vehicle electrical component in the load circuit driving device 1 having such a configuration will be described. When the in-vehicle battery and each power distribution BOX 5 are electrically connected via a power line by an operation of a key switch or the like, the power of the in-vehicle battery is voltage-converted by a power supply device (not shown) of the power distribution BOX 5 and the CPU And IPS. Thereby, CPU and IPS operate | move and the control by power supply distribution BOX5 is started. Further, the power converted by a power supply device (not shown) is supplied to the ECU 2 connected to the power distribution BOX 5 by a power line. As a result, each ECU 2 constituting the load circuit driving device 1 is operated, and thereafter, an operation corresponding to an input signal from a sensor, a switch or the like is performed.

  When there is a signal input from a sensor, switch, or the like via a signal line, the ECU 2 controls each power distribution BOX 5 that performs drive control of the load circuit included in the electrical component including the sensor, etc. according to the input signal. Is supplied via a communication line. The CPU of the power distribution BOX 5 to which this control signal is input supplies power from the IPS via the power line to the load circuit instructed to be controlled by the control signal. Each load circuit that is supplied with the power performs a predetermined operation.

  For example, the ECU 2c that receives a signal from the sensor SD3 supplies a control signal corresponding to the input signal to the power distribution boxes 51 and 52 that perform drive control of the electrical component D3 including the sensor SD3. This control signal is supplied from the connector 43 to the power distribution boxes 51 and 52 via the communication line. The control signal supplied to the power distribution boxes 51 and 52 is input to the CPU via the internal communication line. When the CPU of the power distribution box 51 drives the load circuit D31 included in the electrical component D3 based on the input control signal, the CPU supplies power to the load circuit D31 from IPS. Further, when driving the load circuits D32 and D33, a drive control signal is supplied to the load circuits D32 and D33E, and power is supplied from the IPS. The CPU of the power distribution BOX 52 supplies power from the IPS to the load circuit D34 when driving the load circuit D34 included in the electrical component D3 based on the input control signal.

  In addition, the ECU 2c that receives a signal from the sensor SD4 or the switch SWD4 sends a control signal corresponding to the input signal to the power distribution BOX 51 that controls the driving of the electrical component D4 including the sensor SD4 and the switch SWD4 via a communication line. Supply. The control signal supplied to the power distribution BOX 51 is input to the CPU via the internal communication line. Based on the input control signal, the CPU of the power distribution BOX 51 supplies a drive control signal to the load circuit D41 included in the electrical component D4 and supplies power from the IPS.

  As described above, according to the load circuit driving device 1 of the present embodiment, the power distribution BOX 5 performs power distribution and drive control for each load circuit under the control of the ECU 2 that receives a signal input from a sensor or the like. The BOX 5 and each load circuit can be directly connected via the power line and the GND line without going through the ECU 2, and the load circuit driving power line and the GND line are not arranged between the ECU 2 and the power distribution BOX 5. That's it. For this reason, compared with the case where a power supply line and a GND line are connected to each load circuit from the power distribution box 5 via the ECU 2, the length and the number of wirings of the power supply line and the GND line used for connection to each load circuit are reduced. be able to. In addition, since the length of the wiring can be reduced, the apparatus can be reduced in size and weight.

  In addition, according to the present embodiment, the power distribution BOX 5 is provided for each of a plurality of areas that divide the vehicle, and the driving of the load circuit installed in each area is performed by the power distribution by the power distribution BOX 5 provided in the area and Since it is performed by drive control, the ECU 2 provided for each of the modules MA to MC configured with the vehicle electrical components D1 to D4 as a unit, and each load circuit included in the electrical components D1 to D4 configuring the modules MA to MC Compared with the case where the wiring is performed regardless of the positional relationship, the length and the number of wirings of the signal line, the power supply line, and the GND line can be reduced. In addition, since the wiring connection with the ECU 2 may be performed between the power distribution boxes 5 having a smaller number than the load circuit, the wiring length and the number of wirings as the entire apparatus can be reduced.

  For example, as shown in FIG. 2 (a), when the ECU 2d distributes the power to the load circuits D51 and D52 to be controlled and the ECU 2e to the load circuits D61 and D62 to be controlled, respectively, the area A3 It is necessary to route the power line and the GND line from the installed ECU 2d to the load circuit D52 installed in the area A4, and from the ECU 2e installed in the area A4 to the load circuit D62 installed in the area A3. That is, the power supply line and the GND line for distributing power to the load circuit D52 and the load circuit D62 need to be routed across the areas A3 and A4. On the other hand, as shown in FIG. 2B, from the power distribution BOX 5a installed in the area A3 to the load circuits D51 and D62 also installed in the area A3, from the power distribution BOX 5b installed in the area A4. When distributing power to load circuits D52 and D61 installed in area A4 and controlling power distribution in each power distribution BOX 5a and 5b by ECUs 2d and 2e connected to electrical connection box 3, A power supply line and a GND line for distributing power to the load circuits D51, D52, D61, and D62 can be arranged in the same area. Then, it is sufficient to route only the communication line between the power distribution boxes 5a and 5b having different installation areas via the electrical connection box 3 to which the ECUs 2d and 2e are connected. For this reason, the length of the power supply line and the GND line used for connection with each load circuit D51, D52, D61, D62 can be shortened, and the number of wirings can be reduced.

  Further, the ECU 2 may be connected to a signal line connecting the sensors SD3 and SD4 and the switch SWD4 included in the electrical components D1 to D4, a communication line connecting the power distribution BOX 5, a power supply line, and a GND line. Since it is not necessary to connect the load circuit to the power line and the GND line, the connectors 41 to 43 used for wiring connection to the ECU 2 can be reduced in size, and the power distribution box 5 provided for each area can be reduced. Since the connection object is limited to other ECUs 2 provided for each function provided in the vehicle, and these do not vary greatly depending on the type of vehicle, standardization of the connector is also possible.

  For example, in the case of the configuration shown in FIG. 2A where power is distributed from the ECUs 2d and 2e, it is necessary to provide the ECUs 2d and 2e with connectors 42d and 42e connected to the load circuits D51, D52, D61 and D62. However, in the case of the configuration shown in FIG. 2B in which power is distributed from the power distribution boxes 5a and 5b, only the connector 44 used for connection to the switches SW5 and SW6 is provided in the electrical connection box 3 provided in the ECU 2. It is enough if it is provided. For this reason, the connector 44 can be reduced in size.

  In addition, since power distribution and drive control for the load circuit are performed in units of areas that divide the vehicle, power lines, GND lines, and communication lines that connect the power distribution box 5 and each load circuit are grouped for each line type. The wire harness can be bundled, and the wire harness can be simplified.

  Moreover, the connector 62 for connecting the wiring bundled by the wire harness to the power distribution BOX 5 can be integrated, or the connectors 62 can be connected to each other to be integrally attached and detached. For wiring connection to the power distribution BOX 5 It is possible to reduce the size of the connector 62 used as a whole, and to reduce the installation space for the connector 62.

  For example, in the case of the configuration shown in FIG. 2A in which power is distributed from the ECUs 2d and 2e regardless of the installation areas of the load circuits D51, D52, D61, and D62, the load circuit D51 installed in a different area In FIG. 2B, the load circuit D52 and the power supply line and the GND line connecting the load circuit D61 and the load circuit D62 cannot be bundled and distributed, but the power distribution from the power distribution boxes 5a and 5b is performed in area units. In the case of the configuration shown, the power supply line and the GND line connecting the load circuits D51 and D62 installed in the area A3 and the power supply line and the GND line connecting the load circuits D52 and D61 installed in the area A4 are bundled, respectively. Can be routed. For this reason, a wire harness can be simplified. In addition, the connectors 64a and 64b for connecting the power supply wires and the GND wires bundled with the wire harness can be integrated or connected to be integrally attached and detached.

  Further, according to the load circuit driving device 1 of the present embodiment, since it is not necessary for the ECU 2 to drive the load circuit with large current consumption, the heat generation of the circuit components included in the ECU 2 is suppressed, and the mounting density of each component is reduced. It is possible to reduce the size of the ECU 2 by increasing the number of circuit components for driving the load circuits from the ECU 2.

  In particular, the installation space in the instrument panel is limited, and the storage space of the ECU 2 connected to the electrical connection box 3 is also limited. However, by reducing the size of the ECU 2 and the connectors 41 to 43, a large number of ECUs can be installed. It is possible to connect, and it is possible to cope with an increase in electrical components mounted on the vehicle.

  In addition, according to the present embodiment, since the IPS that supplies power to the load circuit has a current detection function and the use of a fuse can be omitted, the power distribution BOX 5 can be downsized.

  In the description of the above embodiment, the power supply and drive control for the load circuits provided in the two areas A1 and A2 among the plurality of areas dividing the vehicle are the power supplies provided in the areas A1 and A2. The example performed by the distribution boxes 51 and 52 has been described. However, the number of areas that divide the vehicle and the parts of the vehicle that make up each area can be appropriately set according to the type of electrical components provided in the vehicle and the arrangement of the load circuits provided in each electrical component.

  Moreover, how to divide the area where the power distribution BOX 5 is installed is arbitrary. For example, the indoor area described above may be divided into doors, seats, and a roof included in the vehicle. Moreover, the installation position of the electrical junction box 3 is also arbitrary, and is not limited within the instrument panel.

  In the above-described embodiment, the case where power is supplied from any one power distribution BOX 5 to the ECUs 2a to 2c of the electrical junction box 3 installed on the instrument panel has been described. However, the ECU 2 in each area of the vehicle where the power distribution BOX 5 is installed can be supplied with power from the power distribution BOX 5 in the installation area of the ECU 2.

  In this case, each power distribution BOX 5 may supply power to the ECU 2 in the installation area of the power distribution BOX 5 and also supply power to the ECU 2 in other areas.

  Note that it is arbitrary to supply power to any ECU 2 installed in each area from the power distribution BOX 5 in another area.

  When the power distribution BOX 5 also distributes power to the ECU 2 in the adjacent area, the power distribution BOX 5 supplies other areas in addition to the main power supply system that supplies power to the ECU 2 in the installation area of the power distribution BOX 5 by the main power circuit. It is good also as a structure provided with the sub power supply system which distributes power to ECU2 of a sub power supply circuit. For example, when a failure or the like occurs in the main power supply system, the power distribution BOX 5 requests power distribution to the power distribution BOX 5 in the adjacent area, and the power distribution BOX 5 that receives the request sends the request to the ECU 2 in the requested area. On the other hand, power distribution may be performed by the sub power system.

  FIG. 3 is a diagram schematically showing an outline of the configuration of the load circuit driving device 1a that distributes power to the ECU 2 in another area by the sub power supply system. In the load circuit driving device 1a shown in FIG. 3, the power distribution boxes 5f to 5h and the ECUs 2f to 2h are installed for each of the areas A5 to A7. Although not shown, load circuits that are driven by receiving power supply from the power distribution boxes 5f to 5h installed in the areas A5 to A7 are also installed.

  The power distribution BOX 5f in the area A5 distributes power to the ECU 2f installed in the area A5 and the ECU 2 installed in another area (not shown). The power distribution BOX 5g in the area A6 distributes power to the ECU 2g and the ECU 2 in the area A5 that are also installed in the area A6. The power distribution BOX 5h in the area A7 distributes power to the ECU 2h and the ECU 2g in the area A6 that are also installed in the area A7.

  According to this configuration, when an IPS of the power distribution BOX 5 detects an overcurrent due to occurrence of a short circuit or a failure, the CPU of the power distribution BOX 5 shuts off the main power circuit and also supplies power to the power distribution BOX 5 in the adjacent area. Request power distribution via communication line. The CPU of the power distribution BOX 5 in the adjacent area that has received the request operates the sub power circuit and supplies power to the ECU 2 in the installation area of the power distribution BOX 5 that has requested power distribution using the sub power system.

  For example, when a failure occurs in the main power supply system of the power distribution BOX 5g and the IPS of the power distribution BOX 5g detects an overcurrent, the CPU of the power distribution BOX 5g shuts off the main power circuit and requests power distribution from the power distribution BOX 5h. . The CPU of the power distribution BOX 5h that has received the request operates the sub power circuit to supply power to the ECU 2g through the sub power system.

  As described above, when the power distribution BOX 5 supplies power to the ECU 2 in the installation area of the power distribution BOX 5 and also supplies power to the ECU 2 in other areas, the power distribution BOX 5 in any area. Even if an abnormality occurs in the power supply system, the power distribution from the power distribution box 5 in another area is distributed to the ECU 2 so that the operation of the ECU 2 is continued and the entire system of the load circuit driving device 1 does not function. can avoid. As a result, the safety and reliability of the device can be improved.

  In addition, the power distribution to the ECU 2 can use a wiring line thinner than the power distribution line for supplying power to the load circuit with a large current consumption, thereby reducing the size and weight of the apparatus. The safety and reliability of the device can be increased.

  In addition, since the power converted by the power distribution BOX 5 is distributed to the ECU 2, it is not necessary to provide a voltage conversion circuit in the ECU 2, and the ECU 2 can be downsized and the manufacturing cost can be reduced.

  When the power distribution BOX 5 monitors the communication state of the ECU 2 to be supplied with power by the sub power system and detects an open failure in the main power system of the other power distribution BOX 5, power is supplied to the sub power system. The power supply request from the failed power distribution BOX 5 may not be made when an open failure occurs. Further, the other area where power is supplied from the power distribution BOX 5 is not limited to the adjacent area.

  Further, the power distribution BOX 5 may check the operating state of the power supply destination ECU 2 by the main power supply circuit or the sub power supply circuit, and may stop the power supply to the ECU 2 that determines that the power supply is unnecessary. For example, the power distribution BOX 5 may receive the operating state information from the ECU 2 and stop the power supply to the ECU 2 that determines that the power supply is unnecessary. According to this configuration, the power distribution BOX 5 supplies a necessary amount of power to the ECU 2 that requires power supply, and thus power saving can be realized.

1 Load circuit driving device 2, 2a-2c Electronic control unit (ECU)
5, 51, 52 Power distribution BOX
D1 to D4 Electrical components D11 to D13 Load circuits D21 to D23 Load circuits D31 to D35 Load circuit D41 Load circuit

Claims (7)

A power distribution device that is provided for each of a plurality of areas that divide the vehicle, and that distributes power to load circuits installed in the areas;
A control device for controlling power distribution by the power distribution device;
A drive device comprising: The power distribution device performs drive control of the load circuit that distributes power,
The drive device according to claim 1, wherein the control device controls drive control of the load circuit by the power distribution device.   3. The drive device according to claim 1, wherein the power distribution device includes a semiconductor relay with an overcurrent protection function that shuts off power supply to the load circuit when an overcurrent is detected.   The drive device according to any one of claims 1 to 3, wherein the control device is driven by distributing power from the power distribution device.   The control device is installed in any one of the areas provided with the power distribution device, and is driven by distributing power by the power distribution device in the installed area or any other area. The drive device according to claim 4. In addition to the main power supply circuit for distributing power to the control device in the installation area of the power distribution device, the power distribution device includes a sub power supply circuit for distributing power to the control device in any other area; With
When the semiconductor relay with an overcurrent protection function detects an overcurrent, the control device requests power distribution to a power distribution device in another area, and when power distribution is requested from the control device in another area, The drive device according to claim 5, wherein power distribution is performed by the sub power circuit for the control device in a requested area.   The power distribution device according to any one of claims 1 to 6.

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