JP2022035666A - Power conversion device - Google Patents

Abstract

To provide a power conversion device in which radiation noise is suppressed from entering a control board.SOLUTION: A power conversion device 300 includes: a switch module 340 and a capacitor case 311 aligned in one direction; a substrate 500 aligned with the switch module in a direction orthogonal to the one direction; a bracket 370 that is provided between the switch module and the substrate, on which the substrate is mounted, and contains a first material having higher permeability than air; a first case 600 and a second case 700 that store a switch module, a capacitor case, a substrate, and a bracket in a storage space 1000 and contain a second material having higher permeability than air; and a projecting portion 730 that extends from an inner surface 710a of a storage space side of the case in a direction orthogonal thereto, and is provided between the substrate and the capacitor case. The bracket and the projecting portion partition the storage space into a first space 1001 in which the substrate is stored and a second space 1002 in which the capacitor case is stored.SELECTED DRAWING: Figure 6

Description

The disclosure described herein relates to a power converter.

Patent Document 1 describes a semiconductor module, a smoothing capacitor unit, a control board, and a power conversion device including a case for accommodating them.

Japanese Unexamined Patent Publication No. 2012-157161

Radiation noise output from each of the semiconductor module and the smoothing capacitor unit may invade the control board.

Therefore, an object of the present disclosure is to provide a power conversion device in which radiation noise is suppressed from entering the substrate.

The power conversion device according to one aspect of the present disclosure is
The first electrical component (340) and the second electrical component (311) lined up in one direction,
A substrate (500) lined up with the first electric component in an orthogonal direction orthogonal to one direction,
A support portion (370) provided between the first electric component and the substrate and containing the first material having a magnetic permeability higher than that of air on which the substrate is mounted.
A case (600, 700) containing a second material having a magnetic permeability higher than that of air, in which the first electric component, the second electric component, the substrate, and the support portion are stored in the storage space (1000).
It has a protrusion (730) extending in an orthogonal direction from the inner surface (710a) on the storage space side of the case and provided between the substrate and the second electric component.
The storage space is divided into a first space (1001) in which the substrate is stored and a second space (1002) in which the first electric component and the second electric component are stored by the support portion and the projecting portion.

According to this, the radiation noise output from the first electric component (340) toward the substrate (500) is suppressed by the support portion (370) and the protrusion portion (730). Especially in the orthogonal direction, the support portion (370) suppresses the radiation noise output from the first electric component (340) toward the substrate (500) from entering the substrate (500).

Further, the radiation noise output from the second electric component (311) toward the substrate (500) is suppressed by the support portion (370) and the protrusion portion (730). In particular, the protrusion (730) suppresses the radiation noise output from the second electric component (311) toward the substrate (500) from entering the substrate (500) in one direction.

It should be noted that the reference numbers in parentheses above merely indicate the correspondence with the configurations described in the embodiments described later, and do not limit the technical scope at all.

It is a circuit diagram explaining an in-vehicle system. It is a top view explaining the power conversion apparatus. It is a top view of the power conversion apparatus excluding the second case shown in FIG. It is a top view of the power conversion apparatus excluding the substrate shown in FIG. It is a top view of the power conversion apparatus excluding the bracket shown in FIG. It is sectional drawing of the power conversion apparatus along the VI-VI line shown in FIG. It is sectional drawing of the power conversion apparatus along the line VII-VII shown in FIG.

Hereinafter, a plurality of embodiments for carrying out the present disclosure will be described with reference to the drawings. In each form, the same reference numerals may be given to the parts corresponding to the matters described in the preceding forms, and duplicate explanations may be omitted. When only a part of the configuration is described in each form, other forms described above can be applied to the other parts of the configuration.

In addition, not only the combinations of the parts that clearly indicate that they can be combined in each embodiment, but also the embodiments and modifications of the embodiments, even if the combinations are not specified, if there is no particular problem in the combination. It is also possible to partially combine the modified examples.

(First Embodiment)
First, an in-vehicle system 100 provided with a power conversion device 300 will be described with reference to FIG. The in-vehicle system 100 constitutes a system for an electric vehicle. The in-vehicle system 100 includes a battery 200, a power conversion device 300, a motor 400, and a substrate 500.

A plurality of ECUs (not shown) are mounted on the substrate 500. These plurality of ECUs send and receive signals to and from each other via bus wiring. A plurality of ECUs cooperate to control an electric vehicle. By controlling the plurality of ECUs, the regeneration and power running of the motor 400 according to the SOC of the battery 200 are controlled. SOC is an abbreviation for state of charge. ECU is an abbreviation for electronic control unit.

The battery 200 has a plurality of secondary batteries. These plurality of secondary batteries form a battery stack connected in series. The SOC of this battery stack corresponds to the SOC of the battery 200. As the secondary battery, a lithium ion secondary battery, a nickel hydrogen secondary battery, an organic radical battery and the like can be adopted.

<Power converter>
The power conversion device 300 performs power conversion between the battery 200 and the motor 400 as an inverter. The power conversion device 300 converts the DC power of the battery 200 into AC power. The power conversion device 300 converts the AC power generated by the power generation (regeneration) of the motor 400 into DC power.

The motor 400 is connected to an output shaft of an electric vehicle (not shown). The rotational energy of the motor 400 is transmitted to the traveling wheels of the electric vehicle via the output shaft. On the contrary, the rotational energy of the traveling wheel is transmitted to the motor 400 via the output shaft.

The motor 400 is powered by AC power supplied from the power converter 300. As a result, propulsive force is imparted to the traveling wheels. Further, the motor 400 is regenerated by the rotational energy transmitted from the traveling wheels. The AC power generated by this regeneration is converted into DC power by the power conversion device 300. This DC power is supplied to the battery 200. DC power is also supplied to various electric loads mounted on electric vehicles.

The power conversion device 300 includes a plurality of semiconductor elements such as a switch described later. A plurality of semiconductor elements are coated on the resin member 360 to form a switch module 340. In this embodiment, an n-channel type IGBT is adopted as a switch. However, as these switches, MOSFETs may be adopted instead of IGBTs. When a MOSFET is used as a switch, the diode does not have to be used. The switch module 340 corresponds to the first electric component.

Further, these semiconductor elements can be manufactured by a semiconductor such as Si and a wide-gap semiconductor such as SiC. The constituent material of the semiconductor element is not particularly limited.

<Electrical connection of power converter>
The power conversion device 300 is electrically connected to the battery 200 via the first power supply bus bar 301 and the second power supply bus bar 302. The power converter 300 has a capacitor 310, a U-phase leg 331, a V-phase leg 332, and a W-phase leg 333. A capacitor 310 and U-phase legs 331 to W-phase legs 333 are connected between the first feeding bus bar 301 and the second feeding bus bar 302, respectively.

The capacitor 310 is a smoothing capacitor that smoothes the pulsating current generated when alternating current is rectified to direct current. The capacitor 310 has two electrodes. One of these two electrodes is connected to the first feeding bus bar 301. The other electrode of these two electrodes is connected to the second feeding bus bar 302.

Each of the U-phase legs 331 to the W-phase leg 333 has two switches connected in series. Each of the U-phase leg 331 to the W-phase leg 333 has a high-side switch 321 and a low-side switch 322 as switches. Further, each of the U-phase leg 331 to the W-phase leg 333 has a high-side diode 321a and a low-side diode 322a as diodes.

As shown in FIG. 1, the collector electrode of the high side switch 321 is connected to the first feeding bus bar 301. The emitter electrode of the high side switch 321 and the collector electrode of the low side switch 322 are connected to each other. The emitter electrode of the low side switch 322 is connected to the second feeding bus bar 302. As a result, the high-side switch 321 and the low-side switch 322 are sequentially connected in series from the first power supply bus bar 301 to the second power supply bus bar 302.

Further, the cathode electrode of the high side diode 321a is connected to the collector electrode of each of these high side switches 321. The anode electrode of the high side diode 321a is connected to the emitter electrode of each of these high side switches 321. As a result, the high-side diode 321a is connected in anti-parallel to the high-side switch 321.

Similarly, the cathode electrode of the low-side diode 322a is connected to the collector electrode of each of these low-side switches 322. The anode electrode of the low-side diode 322a is connected to the emitter electrode of each of these low-side switches 322. As a result, the low-side diode 322a is connected in anti-parallel to the low-side switch 322.

Further, the U-phase bus bar 410 is connected to the midpoint between the high-side switch 321 and the low-side switch 322 included in the U-phase leg 331. The U-phase bus bar 410 is connected to the U-phase stator coil of the motor 400.

The V-phase bus bar 420 is connected to the midpoint between the high-side switch 321 and the low-side switch 322 included in the V-phase leg 332. The V-phase bus bar 420 is connected to the V-phase stator coil of the motor 400.

The W-phase bus bar 430 is connected to the midpoint between the high-side switch 321 and the low-side switch 322 included in the W-phase leg 333. The W-phase bus bar 430 is connected to the W-phase stator coil of the motor 400.

When powering the motor 400, the high-side switch 321 and the low-side switch 322 included in the U-phase legs 331 to W-phase legs 333 are PWM-controlled by a control signal from the ECU. As a result, the power converter 300 generates a three-phase alternating current. When the motor 400 generates (regenerates) power, the ECU stops, for example, the output of a control signal. As a result, the AC power generated by the power generation of the motor 400 passes through the diodes provided in the U-phase legs 331 to the W-phase legs 333. As a result, AC power is converted to DC power.

<Mechanical configuration of power converter>
Next, the mechanical configuration of the power conversion device 300 will be described. In this regard, in the following, the three directions orthogonal to each other will be referred to as the x direction, the y direction, and the z direction. The x direction corresponds to one direction. The y direction corresponds to the alignment direction. The z direction corresponds to the orthogonal direction. The description of "direction" is omitted in the drawings. In the drawings, the battery 200 is abbreviated as "BATT". The substrate 500 is abbreviated as "CB".

As described above, the power conversion device 300 includes a capacitor 310, a U-phase leg 331 to a W-phase leg 333, a first power supply bus bar 301, and a second power supply bus bar 302. Further, the power conversion device 300 has a capacitor case 311, a bracket 370, an urging body 390, a first case 600, and a second case 700 in addition to the above-mentioned components.

The capacitor 310 is housed in the capacitor case 311. The capacitor case 311 corresponds to the second electric component. The bracket 370 corresponds to a support portion.

<Switch module>
Each of the above-mentioned U-phase legs 331 to W-phase legs 333 is resin-sealed by a resin member 360. A part of a collector terminal (not shown) connected to the collector electrode of the high side switch 321 from the resin member 360 is exposed. A part of the emitter terminal (not shown) connected to the emitter electrode of the low side switch 322 from the resin member 360 is exposed. A part of the plurality of signal terminals 351 connected to the gate electrodes of the high side switch 321 and the low side switch 322 is exposed from the resin member 360.

The switch module 340 is composed of a resin member 360, a collector terminal, an emitter terminal, and a plurality of signal terminals 351. The three-phase switch modules 340 are arranged in the order of U phase, V phase, and W phase from the second wall portion 622 to the fourth wall portion 624 of the first case 600, which will be described later. The resin member 360 corresponds to a sealing member.

As shown in FIGS. 6 and 7, the resin member 360 has a flat shape having a thin thickness in the z direction. The resin member 360 has a first resin surface 360a arranged apart from each other in the z direction, a second resin surface 360b on the back side thereof, and a connecting resin surface 360c connecting them.

A part of the plurality of signal terminals 351 is exposed from one of these connecting resin surfaces 360c. The plurality of signal terminals 351 exposed from one of the connecting resin surfaces 360c extend in the x direction in a manner away from the connecting resin surface 360c, and then extend in the z direction toward the first resin surface 360a.

<Power supply bus bar>
As shown in FIG. 6, the first feeding bus bar 301 and the second feeding bus bar 302 are conductive members having a thin thickness in the z direction. The electric power output from the battery 200 by the first power supply bus bar 301 and the second power supply bus bar 302 is supplied to the capacitor 310 and the switch module 340, respectively. In FIGS. 2 to 7, a part of each of the first power supply bus bar 301 and the second power supply bus bar 302 connected to the battery 200 is omitted.

<Board>
As shown in FIGS. 6 and 7, the substrate 500 has a flat shape having a thin thickness in the z direction. The substrate 500 has a first substrate surface 500a arranged apart from each other in the z direction, a second substrate surface 500b on the back side thereof, and a substrate connecting surface 500c connecting them. The substrate 500 is formed with a plurality of substrate holes 510 that open in the first substrate surface 500a and the second substrate surface 500b.

<Capacitor case>
The capacitor case 311 is a housing for accommodating the capacitor 310. As shown in FIG. 6, the capacitor case 311 has a top surface 311a and a bottom surface 311b arranged in the z direction, and a side surface 311c connecting them. The capacitor 310 is housed in the case space partitioned by the top surface 311a, the bottom surface 311b, and the side surface 311c. One end of each of the first feeding bus bar 301 and the second feeding bus bar 302 is connected to the capacitor 310.

Further, the capacitor case 311 is formed with an opening hole that opens in the y direction. The other ends of the first feeding bus bar 301 and the second feeding bus bar 302 are exposed from this opening hole. The other ends of the exposed first feeding bus bar 301 and the second feeding bus bar 302 each extend in the y direction in a manner away from the capacitor case 311.

<Bracket>
The bracket 370 is a support for supporting the substrate 500. Bracket 370 contains a first metal material that has a higher magnetic permeability than air. As shown in FIGS. 6 and 7, the bracket 370 has a flat shape having a thin thickness in the z direction. The bracket 370 has a first bracket surface 370a on the substrate 500 side arranged apart in the z direction, a second bracket surface 370b on the back side thereof, and a bracket connecting surface 370c connecting them. The first metal material corresponds to the first material.

Although not shown, the bracket 370 is formed with a plurality of holes opened in the first bracket surface 370a and the second bracket surface 370b in order to reduce the weight thereof. The first bracket surface 370a corresponds to the first support surface. The second bracket surface 370b corresponds to the second support surface. The bracket connecting surface 370c corresponds to the support connecting surface.

<Burning body>
The urging body 390 is a spring body having a plate-like shape. The urging body 390 contains a third metal material having a higher magnetic permeability than air. The urging body 390 plays a role of applying an urging force toward the bottom 610, which will be described later, to the resin member 360. The third metal material corresponds to the third material.

<First case>
The first case 600 is a housing having a substantially rectangular parallelepiped shape. The first case 600 contains a second metal material having a higher magnetic permeability than air. As shown in FIGS. 6 and 7, the first case 600 has a bottom portion 610 and a first side portion 620 that rises in an annular shape from the inner bottom surface 610a described later. The bottom 610 has a flat shape with a thin thickness in the z direction. The first side portion 620 corresponds to the side wall portion. The second metal material corresponds to the second material.

The bottom portion 610 has an inner bottom surface 610a arranged in the z direction, an outer bottom surface 610b on the back side thereof, and a connecting bottom surface 610c connecting them. In the bottom portion 610, a refrigerant flow path 611 through which a refrigerant supplied from the outside flows is formed in a space partitioned by an inner bottom surface 610a, an outer bottom surface 610b, and a connecting bottom surface 610c.

Further, in the bottom portion 610, in addition to the refrigerant flow path 611, a plurality of fixing portions 630 extending in a manner away from the inner bottom surface 610a are formed. The fixing portion 630 is formed with a recess 637 that is recessed from the tip separated from the inner bottom surface 610a toward the inner bottom surface 610a.

The first side portion 620 has a first wall portion 621 and a third wall portion 623 that are separated from each other in the x direction and face each other, and a second wall portion 622 and a fourth wall portion 624 that are separated from each other in the y direction and face each other. ing.

The first wall portion 621, the second wall portion 622, the third wall portion 623, and the fourth wall portion 624 are connected in an annular direction in the circumferential direction around the z direction. An opening is partitioned at the tip of these four walls separated from the bottom 610.

<Second case>
The second case 700 is a housing having a substantially rectangular parallelepiped shape. The second case 700 contains a second metal material having a higher magnetic permeability than air. As shown in FIGS. 6 and 7, the second case 700 has an upper portion 710 and a second side portion 720 that rises in an annular shape from the inner surface 710a described later. The upper portion 710 has a flat shape having a thin thickness in the z direction.

The upper portion 710 has an inner surface 710a arranged in the z direction and an outer surface 710b on the back side thereof. A protrusion 730 extending from the inner surface 710a is formed on the upper portion 710. The protrusion 730 extends toward the sixth wall portion 722 and the eighth wall portion 724, which will be described later. One end of the protrusion 730 is connected to the sixth wall 722. The other end of the protrusion 730 is connected to the eighth wall 724. The protrusion 730 increases the rigidity of the second case 700. The protrusion 730 may not be formed on the upper portion 710. The protrusion 730 may be connected to the upper portion 710.

The second side portion 720 has a fifth wall portion 721 and a seventh wall portion 723 that are separated from each other in the x direction and face each other, and a sixth wall portion 722 and an eighth wall portion 724 that are separated from each other in the y direction and face each other. ing.

The fifth wall portion 721, the sixth wall portion 722, the seventh wall portion 723, and the eighth wall portion 724 are connected in an annular direction in the circumferential direction around the z direction. An opening is partitioned at the tip of the four walls separated from the upper part 710.

<Case storage form>
As shown in FIGS. 6 and 7, a mode in which a first plane 620a separated from the bottom 610 of the first side portion 620 and a second plane 720a separated from the upper portion 710 of the second side portion 720 face each other in the z direction. Then, the first case 600 and the second case 700 are connected.

The first wall portion 621 and the fifth wall portion 721 are arranged in the z direction. The second wall portion 622 and the sixth wall portion 722 are arranged in the z direction. The third wall portion 623 and the seventh wall portion 723 are arranged in the z direction. The fourth wall portion 624 and the eighth wall portion 724 are arranged in the z direction. As a result, the storage space 1000 is partitioned between the first case 600 and the second case 700.

The capacitor case 311, the switch module 340, the bracket 370, the urging body 390, and the substrate 500 are housed in the storage space 1000.

The capacitor case 311 is provided on the third wall portion 623 side of the bottom portion 610. A resin member 360 of the switch module 340 is provided on the first wall portion 621 side of the bottom portion 610. The capacitor case 311 and the switch module 340 are arranged so as to be separated from each other in the x direction.

The bottom surface 311b of the capacitor case 311 is provided on the inner bottom surface 610a. The second resin surface 360b of the resin member 360 is provided on the inner bottom surface 610a.

As described above, the three-phase switch modules 340 are arranged in the order of U phase, V phase, and W phase from the second wall portion 622 to the fourth wall portion 624 of the first case 600. As shown in FIG. 5, a part of the plurality of signal terminals 351 is exposed from each of these three-phase switch modules 340. The plurality of signal terminals 351 extend in the x direction in a manner away from the connecting resin surface 360c on the first wall portion 621 side, and then extend in the z direction toward the first resin surface 360a. The order of arrangement of each of these three-phase switch modules 340 is not limited.

Further, as shown in FIGS. 2 to 6, the other ends of the first feeding bus bar 301 and the second feeding bus bar 302 each extend from the capacitor case 311 toward the switch module 340 in the x direction. A part of each of the collector terminal and the emitter terminal (not shown) connected to the other ends of the first feeding bus bar 301 and the second feeding bus bar 302 is provided at the end of the resin member 360 on the capacitor case 311 side. The other end of the first power supply bus bar 301 is connected to the collector terminal. The other end of the second feeding bus valve 302 is connected to the emitter terminal.

As shown in FIGS. 5 and 7, the inner bottom surface 610a of the first case 600 is formed with a plurality of fixing portions 630 extending in a manner away from the inner bottom surface 610a as described above. As described above, each of the plurality of fixing portions 630 is formed with a recess 637 that is recessed from the tip separated from the inner bottom surface 610a toward the inner bottom surface 610a.

The plurality of fixing portions 630 have a first fixing portion 631, a second fixing portion 632, a third fixing portion 633, a fourth fixing portion 634, a fifth fixing portion 635, and a sixth fixing portion 636. Each of the first fixed portion 631 to the sixth fixed portion 636 is provided on the inner bottom surface 610a clockwise in the circumferential direction around the z direction. The switch module 340 is surrounded by the first fixed portion 631 to the sixth fixed portion 636 in the circumferential direction.

As shown in FIGS. 6 and 7, an urging body 390 is provided on the first resin surface 360a of the resin member 360. A bracket 370 is provided on the side of the urging body 390 separated from the first resin surface 360a in the z direction. An urging body 390 is provided between the resin member 360 and the bracket 370. The second bracket surface 370b of the bracket 370 is provided on the urging body 390 side.

As shown in FIGS. 4 and 7, the bracket 370 is formed with a plurality of fastening portions 380 extending in a manner away from the bracket connecting surface 370c. Through holes 387 penetrating in the z direction are formed in each of the plurality of fastening portions 380. The plurality of fastening portions 380 have a first fastening portion 381, a second fastening portion 382, a third fastening portion 383, a fourth fastening portion 384, a fifth fastening portion 385, and a sixth fastening portion 386. The first fastening portion 381 to the sixth fastening portion 386 are provided on the bracket connecting surface 370c clockwise in the circumferential direction around the z direction.

Specifically, the first fastening portion 381 and the second fastening portion 382 are provided on the first bracket connecting surface 370d on the first wall portion 621 side of the bracket connecting surface 370c. The third fastening portion 383 is provided on the second bracket connecting surface on the second wall portion 622 side of the bracket connecting surface 370c. The fourth fastening portion 384 and the fifth fastening portion 385 are provided on the third bracket connecting surface 370e on the third wall portion 623 side of the bracket connecting surface 370c. The sixth fastening portion 386 is provided on the fourth bracket connecting surface on the fourth wall portion 624 side of the bracket connecting surface 370c. The first bracket connecting surface 370d corresponds to the second support connecting surface. The third bracket connecting surface 370e corresponds to the first support connecting surface.

As shown in FIGS. 4 and 5, each of the first fastening portion 381 to the sixth fastening portion 386 is aligned with the first fixing portion 631 to the sixth fixing portion 636 in the z direction. As a result, the through hole 387 formed in each of the first fastening portion 381 to the sixth fastening portion 386 and the recess 637 formed in each of the first fixing portion 631 to the sixth fixing portion 636 communicate with each other in the z direction. There is.

As shown in FIG. 7, the shaft portion of the bolt 800 is inserted into these communication holes. The shaft portion of the bolt 800 is fastened to the partition wall that partitions the recess 637. As a result, the bracket 370 is fastened to the fixing portion 630 via the bolt 800. In FIG. 7, the boundary between the first fastening portion 381 and the first bracket connecting surface 370d is shown by a broken line. The boundary between the fifth fastening portion 385 and the third bracket connecting surface 370e is shown by a broken line.

Further, as a result, the urging body 390 is pressed against the resin member 360. Therefore, an urging force toward the bottom 610 is applied to the resin member 360 from the urging body 390. As a result, the plurality of switches included in the resin member 360 are easily cooled by the refrigerant flowing through the refrigerant flow path 611 of the bottom 610.

Further, as shown in FIGS. 6 and 7, a plurality of protrusions 377 extending in the z direction are formed on the first bracket surface 370a of the bracket 370 in a manner away from the first bracket surface 370a. The substrate 500 is provided at the tip of the plurality of protrusions 377 separated from the first bracket surface 370a.

The second substrate surface 500b of the substrate 500 is provided at the tip of the protrusion 377 separated from the first bracket surface 370a. The substrate 500 is provided on the first bracket surface 370a side of the bracket 370.

Further, as shown in FIGS. 2 and 3, the substrate 500 is formed with a plurality of substrate holes 510 penetrating the first substrate surface 500a and the second substrate surface 500b. The plurality of substrate holes 510 are formed in the substrate 500 by arranging them in a row in the y direction at the ends of the first wall portion 621 side.

In this way, the resin member 360, the urging body 390, the bracket 370, and the substrate 500 described so far are in the order of the resin member 360, the urging body 390, the bracket 370, and the substrate 500 from the bottom 610 to the top 710. Have been placed.

Further, a gap is provided between the first bracket connecting surface 370d and the first wall portion 621. A plurality of signal terminals 351 extend in the x direction in a manner away from the connecting resin surface 360c on the first wall portion 621 side in a manner of passing through this gap, and then extend in the z direction toward the substrate 500.

A plurality of signal terminals 351 extending toward the substrate 500 are passed through the plurality of substrate holes 510. The plurality of signal terminals 351 passed through the plurality of substrate holes 510 are electrically and mechanically connected to the substrate 500 by solder or the like (not shown).

<First space and second space>
As described above, the upper portion 710 is formed with a protrusion 730 extending in the z direction in a manner away from the inner surface 710a. The protrusion 730 extends from the sixth wall portion 722 toward the eighth wall portion 724 in the y direction and is connected to the sixth wall portion 722 and the eighth wall portion 724. The protrusion 730 extends in the z direction toward the first feeding bus bar 301 and the second feeding bus bar 302 connecting the switch module 340 and the capacitor 310.

Further, the protrusion 730 is provided between the switch module 340 and the capacitor case 311 as shown in FIGS. 6 and 7. Further, the protruding portion 730 faces the substrate connecting surface 500c located on the protruding portion 730 side of the substrate 500 at a distance in the x direction.

Further, as described above, the bracket 370 is provided between the substrate 500 and the resin member 360.

The storage space 1000 is divided into the first space 1001 and the second space 1002 by the protrusion 730 and the bracket 370. The substrate 500 is housed in the first space 1001. The resin member 360 and the capacitor case 311 are housed in the second space 1002.

The distance between the first bracket connecting surface 370d and the first wall portion 621 in the x direction is larger than the distance between the third bracket connecting surface 370e and the protruding portion 730 in the x direction. There is.

Further, as shown in FIGS. 4 and 7, the x-direction separation distance between the first fastening portion 381 and the second fastening portion 382 and the first wall portion 621 is the distance between the first bracket connecting surface 370d and the first wall portion. It is shorter than the distance from 621 in the x direction.

Further, as shown in FIGS. 2 and 7, each of the fourth fastening portion 384 and the fifth fastening portion 385 faces the protruding portion 730 in the z direction.

<Signal terminal and fastening part>
As described above, the first fastening portion 381 and the second fastening portion 382 are connected to the first bracket connecting surface 370d. A signal terminal 351 connected to the V-phase leg 332 of the plurality of signal terminals 351 is provided between the first fastening portion 381 and the second fastening portion 382.

Further, the first fastening portion 381 is fixed to the first fixing portion 631 via a bolt 800. The second fastening portion 382 is fixed to the second fixing portion 632 via bolts 800. The first case 600 in which these fixing portions 630 are formed is ground-connected to a vehicle body or the like.

<Action effect>
As described above, the storage space 1000 is divided into the first space 1001 and the second space 1002 by the protrusion 730 and the bracket 370. The substrate 500 is housed in the first space 1001. The resin member 360 and the capacitor case 311 are housed in the second space 1002.

Therefore, the radiation noise output from the resin member 360 is suppressed from entering the substrate 500 by the bracket 370 and the protrusion 730. In particular, radiation noise output from the resin member 360 is suppressed from entering the substrate 500 by the bracket 370.

Further, the radiation noise output from the capacitor 310 is suppressed from entering the substrate 500 by the bracket 370 and the protrusion 730. In particular, the radiation noise output from the capacitor 310 is suppressed from entering the substrate 500 by the protrusion 730.

Further, radiation noise output from the first feeding bus bar 301 and the second feeding bus bar 302 connecting the resin member 360 and the capacitor 310 is suppressed from entering the substrate 500 by the bracket 370 and the protrusion 730.

As described above, the capacitor case 311 is provided on the third wall portion 623 side of the bottom portion 610. The switch module 340 is provided on the first wall portion 621 side of the bottom portion 610. A plurality of signal terminals 351 extend toward the substrate 500 through a gap between the first bracket connecting surface 370d and the first wall portion 621. The plurality of signal terminals 351 and the substrate 500 are electrically and mechanically connected.

Therefore, it is possible to prevent radiation noise from entering the plurality of signal terminals 351 from the capacitors 310. Along with this, current noise is suppressed from entering the substrate 500 from the plurality of signal terminals 351.

As described above, the fourth fastening portion 384 and the fifth fastening portion 385 each face the protruding portion 730 in the z direction. Therefore, it is possible to suppress radiation noise from entering the substrate 500 from a plurality of electric components including the resin member 360, the capacitor 310, the first feeding bus bar 301, and the second feeding bus bar 302 housed in the second space 1002.

As described above, the signal terminal 351 connected to the V-phase leg 332 of the plurality of signal terminals 351 is provided between the first fastening portion 381 and the second fastening portion 382.

Therefore, the radiation noise radiated from the above-mentioned plurality of electric components housed in the second space 1002 is generated by the first fastening portion 381, the second fastening portion 382, the first fixing portion 631, and the second fixing portion 632, respectively. Is entered in. Radiation noise radiated from electrical components is suppressed from entering the signal terminal 351 connected to the V-phase leg 332 of the plurality of signal terminals 351.

As described above, the urging body 390 is provided between the bracket 370 and the resin member 360. Therefore, the radiation noise radiated from the resin member 360 is easily input to the urging body 390. Radiation noise is suppressed from entering the substrate 500 from the resin member 360.

(First modification)
In the embodiments described so far, the substrate 500 connected to the plurality of signal terminals 351 is shown, but a control substrate (not shown) for inputting a control signal to the substrate 500 may be provided in the second case 700. The control board may be provided on the first board surface 500a side of the board 500, and the control board and the board 500 may be arranged side by side facing each other in the z direction.

(Second modification)
In the embodiments described so far, the three-phase switch module 340 is cooled by the refrigerant flowing through the refrigerant flow path 611 formed in the bottom 610. However, the switch module 340 may be cooled by a separately provided cooler. The switch module 340 and the cooler may be arranged in a stack to cool the resin member 360.

(Other variants)
In this embodiment, an example is shown in which the power conversion device 300 is included in the in-vehicle system 100 for an electric vehicle. However, the application of the power conversion device 300 is not particularly limited to the above example. For example, a configuration in which a power conversion device 300 is included in a hybrid system including a motor 400 and an internal combustion engine can be adopted.

In this embodiment, an example in which one motor 400 is connected to the power conversion device 300 is shown. However, it is also possible to adopt a configuration in which a plurality of motors 400 are connected to the power conversion device 300. In this case, the power conversion device 300 has a plurality of three-phase switch modules 340 for constituting the inverter.

311 ... Capacitor case, 321 ... High side switch, 322 ... Low side switch, 340 ... Switch module, 351 ... Signal terminal, 360 ... Resin member, 370 ... Bracket, 370a ... First bracket surface, 370b ... Second bracket surface, 370c ... Bracket connecting surface, 370d ... First bracket connecting surface, 370e ... Third bracket connecting surface, 381 ... First fastening portion, 382 ... Second fastening portion, 390 ... Biasing body, 500 ... Board, 600 ... First case , 610 ... bottom, 610a ... inner bottom, 620 ... first side, 631 ... first fixed, 632 ... second fixed, 700 ... second case, 710a ... inner surface, 730 ... protruding, 1000 ... storage space , 1001 ... 1st space, 1002 ... 2nd space

Claims (6)

The first electrical component (340) and the second electrical component (311) lined up in one direction,
A substrate (500) aligned with the first electric component in an orthogonal direction orthogonal to the one direction.
A support portion (370) provided between the first electric component and the substrate and on which the substrate is mounted and containing a first material having a magnetic permeability higher than that of air.
A case (600, 700) containing a second material having a magnetic permeability higher than that of air, in which the first electric component, the second electric component, the substrate, and the support portion are stored in the storage space (1000).
It has a protrusion (730) extending in the orthogonal direction from the inner surface (710a) of the case on the storage space side and provided between the substrate and the second electric component.
By the support portion and the projecting portion, the storage space is divided into a first space (1001) in which the substrate is stored and a second space (1002) in which the first electric component and the second electric component are stored. Separated power converters. The first electric component includes a sealing member (360) to be sealed of a plurality of switches (321, 322), and a plurality of switches having one end connected to the plurality of switches (321, 322) and the other end exposed from the sealing member. With a signal terminal (351),
The support portions are arranged with a first support surface (370a) on the substrate side and a second support surface (370b) on the sealing member side on the back side of the first support surface. It has a support connecting surface (370c) that connects the first support surface and the second support surface.
The support connecting surface includes a first support connecting surface (370e) on the protruding portion side and a second supporting connecting surface (370d) separated from the protruding portion in one direction from the first supporting connecting surface. And
The power conversion device according to claim 1, wherein the plurality of signal terminals extend toward the substrate through a gap between the second support connecting surface and the case, and are connected to the substrate. The power conversion device according to claim 2, wherein the separation distance between the second support connection surface and the case is longer than the separation distance between the first support connection surface and the protrusion. The power conversion device according to claim 2 or 3, wherein a part of the support portion extends in the one direction in a manner away from the first support connecting surface and faces the protruding portion in the orthogonal direction. The support portion has a first fastening portion (381) and a second fastening portion (382) extending in one direction in a manner away from the second support connecting surface.
The case has a bottom portion (610) on which the first electric component and the second electric component are mounted, a side wall portion (620) that rises in the orthogonal direction from the inner bottom surface (610a) of the bottom portion, and the inner bottom surface. It has a first fixing portion (631) to which the first fastening portion is fixed and a second fixing portion (632) to which the second fastening portion is fixed, which stands upright in the orthogonal direction.
One of claims 2 to 4, wherein a part of the plurality of signal terminals is provided between the first fastening portion and the second fastening portion in an arrangement direction orthogonal to each of the one direction and the orthogonal direction. The power converter described in the section. The power conversion according to any one of claims 1 to 5, which has an urging body (390) provided between the support portion and the first electric component and containing a third material having a magnetic permeability higher than that of air. Device.

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