JP6240516B2 - Power converter - Google Patents

Description

  The present invention relates to a power conversion device including electronic components and the like that constitute a part of a power conversion circuit.

  For vehicles such as electric vehicles and hybrid vehicles, inverters that convert DC power into AC power, converters that convert DC power into DC power with different voltages, electronic components such as current sensors that detect the current value of AC current, etc. A power conversion device including a circuit board electrically connected to the electronic component is mounted.

  For example, in Patent Document 1, a plurality of connectors are provided on a circuit board, and one end of a wire harness (signal harness) connected to a current sensor (current detector) that is an electronic component is connected to the connector on the circuit board. A power conversion device in which a current sensor and a circuit board are electrically connected is disclosed.

JP 2010-183749 A

However, the power converter of Patent Document 1 has the following problems.
That is, in the power converter, the plurality of connectors are provided on the circuit board and are arranged on a predetermined side of the circuit board. Therefore, after the circuit board is disposed in the housing, the wire harness must be connected to the connector on the circuit board from one side of the circuit board. Therefore, an assembly space for connecting the wire harness to the connector on the circuit board is required on one side of the circuit board in the housing, which hinders downsizing of the power conversion device.

  The present invention has been made in view of such a background, and an object of the present invention is to provide a power conversion device that is excellent in assembling of components and can be reduced in size.

One aspect of the present invention is an electronic component that forms part of a power conversion circuit;
A circuit board electrically connected to the electronic component;
A housing for housing the electronic component and the circuit board;
A wire harness having one end connected to the electronic component;
A relay connector having a relay fitting part for fitting the other end of the wire harness and a relay connection part connected to the circuit board;
The relay connector is fixed in the housing with the other end of the wire harness fitted to the relay fitting portion.
The circuit board is assembled to the relay connector fixed in the housing, and is connected to the relay connection portion of the relay connector (Claim 1).

  The power converter includes a relay connector having a relay fitting portion and a relay connection portion between a wire harness whose one end is connected to an electronic component and the circuit board. The relay connector is fixed in the housing with the other end of the wire harness fitted to the relay fitting portion. The circuit board is assembled to the relay connector fixed in the housing and connected to the connection portion of the relay connector.

  Therefore, only by assembling the circuit board to the relay connector, the circuit board is electrically connected to the wire harness via the relay connector. That is, the electrical connection between the electronic component and the circuit board is completed simply by disposing the circuit board in the housing. This eliminates the need for connecting the wire harness to the circuit board disposed in the housing as in the prior art, and eliminates the need for an assembly space. As a result, the assembly of the component parts becomes easy, the productivity can be improved, the cost can be reduced, and the apparatus can be downsized.

  As described above, it is possible to provide a power conversion device that is excellent in assembling of components and can be reduced in size.

Explanatory drawing which shows the structure of the power converter device in Example 1. FIG. Explanatory drawing which shows the connection state of the circuit board and relay connector in Example 1. FIG. Explanatory drawing which shows a mode that the wire connector part of a wire harness is fitted in the relay fitting part of a relay connector in Example 1. FIG. Explanatory drawing which shows a mode that the relay connector in Example 1 is fixed to a filter capacitor. FIG. 3 is an explanatory diagram illustrating a state in which a DC-DC converter and a filter capacitor are disposed in the first housing in the first embodiment. Explanatory drawing which shows a mode that the 2nd housing | casing part which mounts the electronic component group in Example 1 is assembled | attached to a 1st housing | casing part. Explanatory drawing which shows a mode that the circuit board in Example 1 is assembled | attached with respect to a relay connector. Explanatory drawing which shows the structure of the power converter device in Example 2. FIG. The expansion explanatory drawing of the relay connector and its periphery in Example 2. FIG. The top view of the filter capacitor and relay connector in Example 2. FIG.

In the power converter, the relay connector is fixed in the housing. For example, the relay connector may be directly fixed to the casing, or may be fixed to a component or the like disposed in the casing.
The circuit board is assembled to the relay connector fixed in the housing. Therefore, before the circuit board is assembled to the relay connector, the other end of the wire harness is fitted in advance to the relay fitting portion of the relay connector, and the relay connector is fixed in the housing.

Further, the relay connection portion of the relay connector is a pin terminal protruding from the relay fitting portion, and the circuit board has an insertion portion for inserting the relay connection portion of the relay connector. (Claim 2).
In this case, since the relay connection part (pin terminal) of the relay connector is directly inserted into the insertion part of the circuit board, the circuit board can be easily assembled to the relay connector.

The insertion portion of the circuit board may be formed by denting the circuit board in the thickness direction, or may be formed through the circuit board in the thickness direction.
The relay connector and the circuit board can be joined by soldering or the like after the relay connection portion (pin terminal) is inserted into the insertion hole.

Also, the housing is provided with an assembly opening for arranging and assembling the circuit board in the housing, and the circuit board is more open than the relay connector. (Claim 3).
In this case, it is easy to assemble the circuit board from the assembly opening of the casing to the relay connector fixed in the casing. In addition, since the electrical connection between the electronic component and the circuit board is completed by assembling the circuit board to the relay connector, a wasteful space is generated by setting the circuit board and the relay connector in the above positional relationship. Therefore, it is possible to further reduce the size of the apparatus.

The relay connector is fixed to the fixed electronic component fixed to the housing in the relay fitting portion, and the connector fixing portion which is a fixing portion for the fixed electronic component in the relay fitting portion is: It is preferable that the fixed electronic component is closer to the circuit board than a component fixing portion that is a fixing portion for the housing.
In this case, it is possible to improve the positional accuracy of the relay connection portion. That is, the distance between the connector fixing part and the circuit board can be shortened by bringing the connector fixing part closer to the circuit board than the component fixing part. Therefore, the length from the connector fixing portion to the tip of the relay connection portion can be shortened, and the positional accuracy of the relay connection portion can be improved.

In addition, component fixing portions may be formed at both ends in the longitudinal direction of the fixed electronic component as viewed from the normal direction of the circuit board, and the relay connector may be disposed at one of the both ends. Item 5).
In this case, the vibration resistance of the relay connector can be improved. That is, the vibration of the relay connector can be suppressed by disposing the relay connector at either one of the both end portions where the fixed electronic component has the least component fixing portion.

Moreover, as said electronic component, the DC-DC converter etc. which comprise some power conversion circuits are mentioned, for example. Examples of the fixed electronic component include a capacitor.
Moreover, as said circuit board, the circuit board etc. for controlling a DC-DC converter etc. are mentioned, for example.

Example 1
The Example concerning the said power converter device is described using figures.
As shown in FIG. 1, the power conversion device 1 of this example includes an electronic component 21 that forms part of a power conversion circuit, a circuit board 3 that is electrically connected to the electronic component 21, an electronic component 21, and a circuit. A housing 6 that accommodates the board 3, a wire harness 4 having one end connected to the electronic component 21, a relay fitting part 51 that fits the other end of the wire harness 4, and a relay connection connected to the circuit board 3 And a relay connector 5 having a portion 52.

As shown in FIGS. 1 and 2, the relay connector 5 is fixed in the housing 6 with the relay fitting portion 51 fitted to the other end of the wire harness 4.
The circuit board 3 is assembled to the relay connector 5 fixed in the housing 6 and connected to the relay connection portion 52 of the relay connector 5.
This will be described in detail below.

  As shown in FIG. 1, the power conversion device 1 houses an electronic component 21 that constitutes a part of a power conversion circuit and a circuit board 3 electrically connected to the electronic component 21 in a housing 6. . The electronic component 21 is a DC-DC converter that converts direct-current power into direct-current power having a different voltage (hereinafter, referred to as DC-DC converter 21 as appropriate).

  As shown in the figure, the housing 6 is configured by assembling a first housing portion 61 that houses the DC-DC converter 21 and a second housing portion 62 that houses the circuit board 3. The first housing part 61 is provided with a partitioning part 611 that partitions the first housing part 61 and the second housing part 62. The second housing part 62 is provided with an assembly opening 621 for arranging and assembling the circuit board 3 in the second housing part 62. The space in the first housing part 61 and the space in the second housing part 62 communicate with each other via the communication part 60.

In the housing 6, the DC-DC converter 21 is disposed on the first housing portion 61 side of the partition portion 611. In addition, the electronic component group 22 is disposed on the second housing portion 62 side of the partition portion 611.
Although not shown, the electronic component group 22 includes a plurality of semiconductor modules containing semiconductor elements, a current sensor that measures a current flowing through an output terminal of the semiconductor module, a smoothing capacitor for smoothing the boosted voltage, and the like. Have

  The plurality of semiconductor modules are configured to be cooled by circulating a refrigerant in the cooler. Each semiconductor module includes a switching element such as an IGBT and a diode such as an FWD. Each semiconductor module is provided with a control terminal 221 connected to the circuit board 3. A control current for controlling a switching element built in the semiconductor module is input to the control terminal 221.

Further, as shown in the figure, the filter capacitor 23 is arranged in the housing 6 so as to straddle the space in the first housing portion 61 and the space in the second housing portion 62 via the communication portion 60. It is installed. The filter capacitor 23 is for stabilizing the input voltage of the power conversion circuit.
Further, one end of the wire harness 4 is connected to the DC-DC converter 21. A wire connector 41 is provided at the other end of the wire harness 4. A relay connector 5 is disposed between the wire harness 4 and the circuit board 3.

  The relay connector 5 includes a relay fitting part 51 and a relay connection part 52. The relay fitting portion 51 is provided with a concave fitting concave portion 511 (see FIG. 2 described later), and the wire connector portion 41 of the wire harness 4 is fitted into the fitting concave portion 511. The relay fitting part 51 is fixed to the filter capacitor 23 in a state where the wire connector part 41 of the wire harness 4 is fitted. The relay connection part 52 is composed of a plurality of pin terminals, and protrudes from the relay fitting part 51 toward the assembly opening part 621 of the second housing part 62.

  Further, as shown in the figure, in the housing 6, the circuit board 3 is disposed on the assembly opening 621 side of the second housing portion 62. The circuit board 3 is disposed at a position closer to the assembly opening 621 of the second housing part 62 than the relay connector 5. The circuit board 3 is assembled to the relay connector 5 fixed to the filter capacitor 23 and connected to the relay connection portion 52 of the relay connector 5.

Specifically, as shown in FIG. 2, the circuit board 3 is provided with a plurality of insertion portions 31 for inserting the relay connection portions 52 (a plurality of pin terminals) of the relay connector 5. The insertion portion 31 is formed so as to penetrate the circuit board 3 in the thickness direction.
The circuit board 3 is assembled to the relay connector 5 in a state where the relay connection portion 52 of the relay connector 5 is inserted through the insertion portion 31.

As shown in the figure, the circuit board 3 and the relay connection part 52 of the relay connector 5 are joined by soldering in the insertion part 31 of the circuit board 3. Thereby, the circuit board 3 is electrically connected to the wire harness 4 via the relay connector 5. That is, the DC-DC converter 21 and the circuit board 3 are electrically connected.
Further, as shown in FIG. 1, a control terminal 221 of a semiconductor module in the electronic component group 22 is connected to the circuit board 3. Thereby, the circuit board 3 and the semiconductor module of the electronic component group 22 are electrically connected.

Next, a procedure for assembling components in the power conversion device 1 (FIG. 1) of this example will be described.
First, as shown in FIG. 3, the wire connector portion 41 provided at the other end of the wire harness 4 is fitted to the relay fitting portion 51 of the relay connector 5.
Next, as shown in FIG. 4, the relay fitting portion 51 of the relay connector 5 is fixed to the filter capacitor 23 in a state where the wire connector portion 41 of the wire harness 4 is fitted.

  Next, as shown in FIG. 5, the filter capacitor 23 to which the relay connector 5 is fixed is disposed in the first housing portion 61. At this time, a part of the filter capacitor 23 to which the relay connector 5 is fixed protrudes from the communication portion 60 of the first housing portion 61 to the outside of the first housing portion 61. Then, the DC-DC converter 21 is disposed inside the partition part 611 of the first housing part 61. Thereafter, one end of the wire harness 4 is connected to the DC-DC converter 21.

  Next, as shown in FIG. 6, the second housing part 62 on which the electronic component group 22 is mounted is assembled to the first housing part 61. At this time, the relay connection portion 52 (a plurality of pin terminals) of the relay connector 5 and the control terminal 221 of the semiconductor module in the electronic component group 22 protrude toward the assembly opening 621 of the second housing portion 62. It has become.

Next, as shown in FIG. 7A, the circuit board 3 is disposed in the second casing 62 from the assembly opening 621 of the second casing 62, as shown in FIG. 7B. Then, the circuit board 3 is assembled to the relay connector 5. Specifically, the relay connection portions 52 (a plurality of pin terminals) of the relay connector 5 are inserted through the plurality of insertion portions 31 of the circuit board 3. And in the insertion part 31 of the circuit board 3, the circuit board 3 and the relay connection part 52 (a plurality of pin terminals) of the relay connector 5 are joined by soldering (see FIG. 2). Thereby, the circuit board 3 is electrically connected to the wire harness 4 via the relay connector 5. That is, the DC-DC converter 21 and the circuit board 3 are electrically connected.
As described above, the components in the power conversion device 1 (FIG. 1) are assembled.

Next, the effect in the power converter device 1 of this example is demonstrated.
The power conversion device 1 of this example is a relay connector having a relay fitting portion 51 and a relay connection portion 52 between a wire harness 4 whose one end is connected to an electronic component (DC-DC converter) 21 and the circuit board 3. 5 is provided. The relay connector 5 is fixed in the housing 6 with the other end of the wire harness 4 fitted to the relay fitting portion 51. The circuit board 3 is assembled to the relay connector 5 fixed in the housing 6 and connected to the relay connection portion 52 of the relay connector 5.

  Therefore, the circuit board 3 is electrically connected to the wire harness 4 via the relay connector 5 only by assembling the circuit board 3 to the relay connector 5. That is, the electrical connection between the electronic component (DC-DC converter) 21 and the circuit board 3 is completed only by arranging the circuit board 3 in the housing 6. This eliminates the need for connecting the wire harness 4 to the circuit board 3 disposed in the housing 6 as in the prior art, and eliminates the need for an assembly space. As a result, the assembly of the component parts becomes easy, the productivity can be improved, the cost can be reduced, and the apparatus can be downsized.

  In this example, the relay connection portion 52 of the relay connector 5 is a pin terminal protruding from the relay fitting portion 51, and the circuit board 3 is an insertion portion for inserting the relay connection portion 52 of the relay connector 5. 31. As a result, the relay connection portion 52 (pin terminal) of the relay connector 5 is directly inserted into the insertion portion 31 of the circuit board 3, so that the circuit board 3 can be easily assembled to the relay connector 5.

  The housing 6 (second housing portion 62) is provided with an assembly opening 621 for mounting the circuit board 3 in the housing 6 for assembly. The connector 5 is disposed closer to the assembly opening 621 than the connector 5. Therefore, the work of assembling the circuit board 3 from the assembly opening 621 of the housing 6 (second housing portion 62) to the relay connector 5 fixed in the housing 6 is facilitated. Moreover, since the electrical connection between the electronic component (DC-DC converter) 21 and the circuit board 3 is completed by assembling the circuit board 3 to the relay connector 5, the circuit board 3 and the relay connector 5 are connected to each other as described above. By adopting the positional relationship, it is possible to prevent a useless space from being generated, and it is possible to further reduce the size of the apparatus.

  Thus, according to this example, it is possible to provide the power conversion device 1 that is excellent in assembling of components and can be downsized.

(Example 2)
In this example, as shown in FIGS. 8 to 10, the relay connector 5 is fixed to the filter capacitor 23 which is a fixed electronic component fixed to the housing 6 in the relay fitting portion 51. A connector fixing portion 53 that is a fixing portion for the filter capacitor 23 in the relay fitting portion 51 is disposed closer to the circuit board 3 than a component fixing portion 231 that is a fixing portion for the housing 6 in the filter capacitor 23. ing.

  As shown in FIG. 10, the component fixing portions 231 are formed at least at both ends in the longitudinal direction X of the filter capacitor 23 as viewed from the normal direction of the circuit board 3, and the relay connector 5 is connected to one of the both ends. Has been placed.

  In this example, the component fixing portion 231 is also formed at one end portion in the short-side direction Y at the center in the longitudinal direction X in addition to the both end portions. In the plurality of component fixing portions 231, as shown in FIG. 9, the filter capacitor 23 is fixed to the housing 6 with bolts 7.

In addition, the relay fitting portion 51 is fixed to a portion closer to the circuit board 3 than the component fixing portion 231 in the filter capacitor 23 by the bolt 7 in the connector fixing portion 53.
The component fixing portion 231 is disposed near the end of the filter capacitor 23 near the circuit board 3 in the normal direction Z, and the connector fixing portion 53 is located closer to the circuit board 3 than that. It is arranged.

  Others are the same as in the first embodiment. Of the reference numerals used in this example or the drawings relating to this example, the same reference numerals as those used in the first embodiment denote the same components as in the first embodiment unless otherwise specified.

  In the case of this example, the positional accuracy of the relay connection part 52 can be improved. That is, the distance between the connector fixing part 53 and the circuit board 3 can be shortened by bringing the connector fixing part 53 closer to the circuit board 3 than the component fixing part 231. Accordingly, the length of the relay connection unit 52 can be shortened. As a result, the length from the connector fixing portion 53 to the tip of the relay connection portion 52 can be shortened, and the positional accuracy of the relay connection portion 52 can be improved.

Moreover, the component fixing | fixed part 231 is formed in the both ends of the longitudinal direction X of the filter capacitor 23, and the relay connector 5 is arrange | positioned at one of the said both ends. Thereby, the vibration resistance of the relay connector 5 can be improved. That is, the relay connector 5 can be prevented from vibrating by disposing the relay connector 5 at the end of the filter capacitor 23 where the component fixing portion 231 having the least vibration is present.
In addition, the same effects as those of the first embodiment are obtained.

1 Power converter 21 Electronic component (DC-DC converter)
3 Circuit Board 4 Wire Harness 5 Relay Connector 51 Relay Fitting Portion 52 Relay Connection Portion 6 Case

Claims (5)

An electronic component (21) constituting a part of the power conversion circuit;
A circuit board (3) electrically connected to the electronic component (21);
A housing (6) for housing the electronic component (21) and the circuit board (3);
A wire harness (4) having one end connected to the electronic component (21);
A relay connector (5) having a relay fitting part (51) for fitting the other end of the wire harness (4) and a relay connecting part (52) connected to the circuit board (3);
The relay connector (5) is fixed in the housing (6) with the other end of the wire harness (4) fitted to the relay fitting portion (51).
The circuit board (3) is assembled to the relay connector (5) fixed in the housing (6) and connected to the relay connection portion (52) of the relay connector (5). The power converter device (1) characterized by the above-mentioned.   The power conversion device (1) according to claim 1, wherein the relay connection portion (52) of the relay connector (5) is a pin terminal protruding from the relay fitting portion (51), and the circuit board. (3) The power converter (1) having an insertion part (31) for inserting the relay connection part (52) of the relay connector (5).   The power converter (1) according to claim 1 or 2, wherein the circuit board (3) is disposed in the casing (6) and assembled to the casing (6). An opening (621) is provided, and the circuit board (3) is disposed closer to the assembly opening (621) than the relay connector (5). Conversion device (1).   The power converter (1) according to any one of claims 1 to 3, wherein the relay connector (5) is fixed to the casing (6) at the relay fitting portion (51). The connector fixing portion (53) that is fixed to the electronic component (23) and is a fixing portion for the fixed electronic component (23) in the relay fitting portion (51) is the housing in the fixed electronic component (23). A power converter (1) characterized in that it is closer to the circuit board (3) than a component fixing part (231) which is a fixing part to the body (6).   The power conversion device (1) according to any one of claims 1 to 4, wherein the relay connector (5) is fixed to the casing (6) at the relay fitting portion (51). The component fixing portion (231) which is fixed to the electronic component (23) and is a fixing portion for the fixed electronic component (23) with respect to the casing (6) is at least from the normal direction of the circuit board (3). The power conversion device (1), characterized in that it is formed at both ends of the fixed electronic component (23) as viewed, and the relay connector (5) is disposed at one of the both ends.

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