JP2021027173A - Power conversion device - Google Patents

Abstract

To provide a power conversion device in which poor insulation between a first bus bar and a second bus bar which are coated with a coating resin is inhibited.SOLUTION: A power conversion device comprises: a capacitor 306 comprising a first electrode 307 and a second electrode 308; a first bus bar 303 comprising a first connection part 303a and a first extension part 303b; a second bus bar 304 comprising a second connection part 304a and a second extension part 304d; an insulation member 700 positioned between the first extension part and the second extension part; and a coating resin 900 coating the respective components. Each of the first extension part, the second extension part, and the insulation member is exposed from an exposure surface 910. The insulation member is positioned between the exposure surface side of the first extension part and the exposure surface side of the second extension part in the coating resin. In the coating resin, a clearance between the capacitor side of the first extension part and the capacitor side of the second extension part is longer than a clearance between the exposure surface side of the first extension part and the exposure surface side of the second extension part.SELECTED DRAWING: Figure 2

Description

The disclosure described herein relates to a power converter having a capacitor.

The capacitor element of the case-molded capacitor described in Patent Document 1 is provided with electrodes on both end surfaces on the end side. One end of two bus bars formed of a copper plate or the like is connected to each of these two electrodes.

The capacitor element is housed in the storage space of the case with one end of the bus bar connected to each of the two electrodes. The capacitor element stored in the storage space is sealed with an insulating filling resin filled in the storage space.

Each of the two busbars extends from the electrode of the capacitor element toward the opening side of the case. The other end of the case of each of the two bus bars on the opening side is provided with overlapping portions facing each other.

A flat plate-shaped insulating plate is provided between the two overlapping portions facing each other. A part of the overlapping portion facing each other via the insulating plate is covered with the filling resin.

JP-A-2010-251400

However, in the case-molded capacitor described in Patent Document 1, the end portion of the insulating plate on the capacitor side is separated from the capacitor element. Therefore, there is a region in which both the insulating plate and the filling resin are interposed and a region in which only the filling resin is interposed between the two overlapping portions.

When the filling resin located at the route connecting the two bus bars in the region where only the filling resin is interposed contains voids, the thickness of the filling resin interposed between the two bus bars is locally narrowed. This may reduce the insulation between the two bass bars. As a result, insulation failure may occur between the two buses.

Therefore, the disclosure described in the present specification is an object of the present invention to provide a power conversion device in which insulation defects between the first bus bar and the second bus bar covered with a coating resin are suppressed.

One of the disclosures is
A capacitor (306) including a first electrode (307) and a second electrode (308),
A first bus bar (303) having a first connection portion (303a) connected to the first electrode and a first extension portion (303b) extending in the length direction away from the capacitor.
A second bus bar (304) having a second connection portion (304a) connected to the second electrode (308) and a second extension portion (304d) extending in the length direction away from the capacitor.
An insulating member (700) located between the first stretched portion and the second stretched portion and extending in the length direction,
It has a capacitor, a first connection portion, a second connection portion, a first stretched portion, a second stretched portion, and a coating resin (900) having a lower insulating property than the insulating member, which coats each of the insulating member.
A part of each of the first stretched portion, the second stretched portion and the insulating member is exposed from the exposed surface (910) of the coating resin exposed to the outside air.
The insulating member is located between the exposed surface side of the first stretched portion in the coating resin and the exposed surface side of the second stretched portion in the coating resin.
The separation distance between the capacitor side of the first stretched portion and the capacitor side of the second stretched portion in the coating resin is longer than the separation distance between the exposed surface side of the first stretched portion and the exposed surface side of the second stretched portion. It has become.

The insulating member (700) is located in the region between the exposed surface (910) side of the first stretched portion (303b) and the exposed surface (910) side of the second stretched portion (304d) in the coating resin (900). ing. Even if a void is generated in the coating resin (900) in this region, the insulating member (700) is located in the region between the first stretched portion (303b) and the second stretched portion (304d). In the resin (900), the insulating property between the exposed surface (910) side of the first stretched portion (303b) and the exposed surface (910) side of the second stretched portion (304d) is maintained without being destroyed.

The separation distance between the capacitor (306) side of the first stretched portion (303b) and the capacitor (306) side of the second stretched portion (304d) in the coating resin (900) is the first in the coating resin (900). It is longer than the distance between the exposed surface (910) side of the 1 stretched portion (303b) and the exposed surface (910) side of the second stretched portion (304d).

Since there is a void in the coating resin (900) between the capacitor (306) side of the first stretched portion (303b) and the capacitor (306) side of the second stretched portion (304d), the void and the stretched portion (303b, 304d) ), Even if the thickness of the coating resin (900) interposed therein is reduced, it is possible to prevent the insulating properties of the first stretched portion (303b) and the second stretched portion (304d) from being lowered. As a result, the occurrence of insulation failure between the first stretched portion (303b) and the second stretched portion (304d) is suppressed.

Note 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 which shows an in-vehicle system. It is sectional drawing which shows the mechanical structure of the power conversion apparatus. It is sectional drawing for demonstrating the modification. It is sectional drawing for demonstrating the modification. It is sectional drawing for demonstrating the modification. It is sectional drawing for demonstrating the modification. It is sectional drawing for demonstrating the modification. It is sectional drawing for demonstrating the modification. It is sectional drawing for demonstrating the modification. It is sectional drawing for demonstrating the modification. It is a figure for demonstrating the 5th insulation plate. It is sectional drawing for demonstrating the modification.

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

(First Embodiment)
First, the in-vehicle system 100 provided with the 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, and a motor 400.

Further, the in-vehicle system 100 has a plurality of ECUs (not shown). These plurality of ECUs send and receive signals to and from each other via bus wiring. A plurality of ECUs emphasize and control the 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 system 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, or the like can be adopted.

The power conversion device 300 performs power conversion between the battery 200 and the motor 400. The power conversion device 300 converts the DC power of the battery 200 into AC power having a voltage level suitable for the power running of the motor 400. The power conversion device 300 converts the AC power generated by the power generation (regeneration) of the motor 400 into DC power having a voltage level suitable for charging the battery 200.

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 given 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 and is stepped down. This DC power is supplied to the battery 200. DC power is also supplied to various electric loads mounted on electric vehicles.

<Power converter>
Next, the power conversion device 300 will be described. The power conversion device 300 includes a converter 500 and an inverter 600. The converter 500 boosts the DC power of the battery 200 to a voltage level suitable for power running of the motor 400. The inverter 600 converts this DC power into AC power. This AC power is supplied to the motor 400. Further, the inverter 600 converts the AC power generated by the motor 400 into DC power. The converter 500 steps down this DC power to a voltage level suitable for charging the battery 200.

<Circuit configuration of converter>
As shown in FIG. 1, the converter 500 is electrically connected to the battery 200 via the first power supply bus bar 301 and the second power supply bus bar 302. The first power supply bus bar 301 is connected to the positive electrode of the battery 200. The second power supply bus bar 302 is connected to the negative electrode of the battery 200. The converter 500 is electrically connected to the inverter 600 via the third power supply bus bar 303 and the fourth power supply bus bar 304.

The converter 500 has a first capacitor 305, a reactor 510, and an A-phase leg 520. The A-phase leg 520 is connected in series between the third power supply bus bar 303 and the fourth power supply bus bar 304.

One of the two electrodes of the first capacitor 305 is connected to the first feeding bus bar 301. The other of the two electrodes of the first capacitor 305 is connected to the second feeding bus bar 302.

The reactor 510 is connected to the first power supply bus bar 301. The reactor 510 and the A-phase leg 520 are electrically connected via a connecting bus bar 530.

The A-phase leg 520 is connected to the third power supply bus bar 303 and the fourth power supply bus bar 304, respectively. The A-phase leg 520 is driven and controlled by the above-mentioned ECU and gate driver.

The A-phase leg 520 has a first high-side switch 521 and a first low-side switch 522, and a first high-side diode 521a and a first low-side diode 522a as semiconductor elements.

As shown in FIG. 1, the collector electrode of the first high side switch 521 is connected to the third feeding bus bar 303. The emitter electrode of the first high-side switch 521 and the collector electrode of the first low-side switch 522 are connected. The emitter electrode of the first low-side switch 522 is connected to the fourth feeding bus bar 304. As a result, the first high-side switch 521 and the first low-side switch 522 are sequentially connected in series from the third power supply bus bar 303 to the fourth power supply bus bar 304.

Further, the cathode electrode of the first high-side diode 521a is connected to the collector electrode of the first high-side switch 521. The anode electrode of the first high-side diode 521a is connected to the emitter electrode of the first high-side switch 521. As a result, the first high-side diode 521a is connected in antiparallel to the first high-side switch 521.

Similarly, the cathode electrode of the first low-side diode 522a is connected to the collector electrode of the first low-side switch 522. The anode electrode of the first low-side diode 522a is connected to the emitter electrode of the first low-side switch 522. As a result, the first low-side diode 522a is connected in antiparallel to the first low-side switch 522.

The reactor 510 described above is connected to the midpoint between the first high-side switch 521 and the first low-side switch 522 of the A-phase leg 520 via the connecting bus bar 530. As described above, the reactor 510 is connected to the positive electrode of the battery 200 and the midpoint between the first high-side switch 521 and the first low-side switch 522 of the A-phase leg 520.

The first high-side switch 521 and the first low-side switch 522 of the A-phase leg 520 are opened / closed controlled by the ECU and the gate driver. The ECU generates a control signal and outputs it to the gate driver. The gate driver amplifies the control signal and outputs it to the gate electrode of the switch. As a result, the ECU raises and lowers the voltage level of the DC power input to the converter 500.

The ECU generates a pulse signal as a control signal. The ECU adjusts the buck-boost level of DC power by adjusting the on-duty ratio and frequency of this pulse signal.

When boosting the DC power of the battery 200, the ECU alternately opens and closes the first high-side switch 521 and the first low-side switch 522. On the contrary, when the DC power supplied from the inverter 600 is stepped down, the ECU fixes the control signal output to the first low-side switch 522 to a low level. At the same time, the ECU sequentially switches the control signal output to the first high side switch 521 between high level and low level.

<Inverter configuration circuit>
The inverter 600 has a second capacitor 306 and a switch leg group 610. One of the two electrodes of the second capacitor 306 is connected to the third feeding bus bar 303. The other of the two electrodes of the second capacitor 306 is connected to the fourth feeding bus bar 304. The switch leg group 610 is connected to the third power supply bus bar 303 and the fourth power supply bus bar 304, respectively.

The switch leg group 610 has a U-phase leg 613, a V-phase leg 614, and a W-phase leg 615. Each of these three-phase legs has two switch elements connected in series.

Each of the U-phase legs 613 to the W-phase legs 615 has a second high-side switch 611 and a second low-side switch 612 as switch elements. Further, each of the U-phase leg 613 to the W-phase leg 615 has a second high-side diode 611a and a second low-side diode 612a.

As shown in FIG. 1, the collector electrode of the second high side switch 611 is connected to the third feeding bus bar 303. The emitter electrode of the second high-side switch 611 and the collector electrode of the second low-side switch 612 are connected. The emitter electrode of the second low-side switch 612 is connected to the fourth feeding bus bar 304. As a result, the second high-side switch 611 and the second low-side switch 612 are sequentially connected in series from the third power supply bus bar 303 to the fourth power supply bus bar 304.

The midpoint between the second high-side switch 611 and the second low-side switch 612 included in the U-phase leg 613 is connected to the U-phase stator coil of the motor 400. The midpoint between the second high-side switch 611 and the second low-side switch 612 included in the V-phase leg 614 is connected to the V-phase stator coil of the motor 400. The midpoint between the second high-side switch 611 and the second low-side switch 612 included in the W-phase leg 615 is connected to the W-phase stator coil of the motor 400.

Further, the cathode electrode of the second high side diode 611a is connected to the collector electrode of the second high side switch 611. The anode electrode of the second high-side diode 611a is connected to the emitter electrode of the second high-side switch 611. As a result, the second high-side diode 611a is connected in antiparallel to the second high-side switch 611.

Similarly, the cathode electrode of the second low-side diode 612a is connected to the collector electrode of the second low-side switch 612. The anode electrode of the second low-side diode 612a is connected to the emitter electrode of the second low-side switch 612. As a result, the second low-side diode 612a is connected in antiparallel to the second low-side switch 612.

As described above, the inverter 600 has a three-phase leg corresponding to each of the U-phase stator coil to the W-phase stator coil of the motor 400. The control signal of the ECU amplified by the gate driver is input to the gate electrodes of the second high-side switch 611 and the second low-side switch 612 included in these three-phase legs.

When powering the motor 400, the second high-side switch 611 and the second low-side switch 612 of the three-phase leg are PWM-controlled by a control signal from the ECU. As a result, a three-phase alternating current is generated in the inverter 600. When the motor 400 generates electricity (regenerates), 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 diode provided in the three-phase leg. As a result, AC power is converted to DC power.

In this embodiment, an n-channel type IGBT is adopted as the first high-side switch 521 and the first low-side switch 522 of the converter 500, the second high-side switch 611 of the inverter 600, and the second low-side switch 612. doing. It should be noted that MOSFETs may be used instead of IGBTs as these switch elements. When MOSFETs are used as these switch elements, the above diodes may not be necessary.

These switch 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.

Furthermore, the types and constituent materials of the switch elements included in each of the A-phase leg 520 and the U-phase 613 to W-phase leg 615 may be different. For example, the switch element included in the A-phase leg 520 may be a MOSFET made of SiC, and the switch element included in each of the U-phase legs 613 to W-phase leg 615 may be an IGBT composed of Si.

The second capacitor 306 in this embodiment is a film capacitor. A film capacitor is a dielectric film provided with a metal vapor deposition electrode, and the dielectric film is wound so that the metal vapor deposition electrodes face each other. Metal is sprayed on both end faces of the wound, and each of the positive electrode 307 and the negative electrode 308 is formed on the film capacitor. The second capacitor 306 corresponds to the capacitor.

<Configuration of power converter>
Next, the configuration of the power conversion device 300 will be described. In the following, the three orthogonal directions will be referred to as the x direction, the y direction, and the z direction. The z direction corresponds to the length direction.

In addition to the above-mentioned components, the power conversion device 300 includes a case 800, a first insulating plate 700, a second insulating plate 710, and a coating resin 900. The coating resin 900 is insulating. Each of the first insulating plate 700 and the second insulating plate 710 has higher insulating properties than the coating resin 900. The first insulating plate 700 corresponds to an insulating member. The second insulating plate 710 corresponds to a relay insulating member.

As shown in FIG. 2, the case 800 has a bottom portion 810 which is thin in the z direction and a side portion 820 which rises in an annular shape in the z direction from the edge portion of the inner bottom surface 810a of the bottom portion 810. The hollow of the case 800 is partitioned by the bottom 810 and the side 820.

The side portion 820 has a first side wall 821 and a second side wall 822 facing each other in the x direction, and a third side wall and a fourth side wall facing each other in the y direction. The first side wall 821, the third side wall, the second side wall 822, and the fourth side wall are connected in an annular shape in the circumferential direction in the z direction.

The second capacitor 306 is housed in the hollow of the case 800. As shown in FIG. 2, a positive electrode 307 is provided on the upper surface 306a of the second capacitor 306 on the opening side of the case 800. A negative electrode 308 is provided on the lower surface 306b of the second capacitor 306 on the bottom 810 side of the case 800. A part of the third feeding bus bar 303 is connected to the positive electrode 307 by welding or the like. A part of the fourth feeding bus bar 304 is connected to the negative electrode 308 by welding or the like. The positive electrode 307 corresponds to the first electrode. The negative electrode 308 corresponds to the second electrode.

<Power supply bus bar>
The third power feeding bus bar 303 has a first connection portion 303a and a first extension portion 303b. The first connection portion 303a is connected to the positive electrode 307 of the second capacitor 306. The first connection portion 303a extends from the second side wall 822 toward the first side wall 821. The first extension portion 303b is connected to one end of the first connection portion 303a on the first side wall 821 side. The first stretched portion 303b extends in the z direction from one end of the first connecting portion 303a on the first side wall 821 side toward the opening of the case 800. The third power supply bus bar 303 corresponds to the first bus bar.

The fourth power supply bus bar 304 has a second connection portion 304a, a first relay portion 304b, a second relay portion 304c, and a second extension portion 304d. The second connection portion 304a is connected to the negative electrode 308 of the second capacitor 306. The second connection portion 304a extends from the second side wall 822 toward the first side wall 821. One end of the second connection portion 304a on the first side wall 821 side is located closer to the first side wall 821 side than one end of the second capacitor 306 on the first side wall 821 side. The fourth power supply bus bar 304 corresponds to the second bus bar.

The first relay portion 304b is connected to one end of the second connection portion 304a on the first side wall 821 side. The first relay portion 304b extends in the z direction from one end of the second connection portion 304a on the first side wall 821 side toward the opening of the case 800. One end of the first relay portion 304b on the opening side of the case 800 is located on the opening side of the case 800 with respect to the positive electrode 307 of the second capacitor 306.

The second relay portion 304c is connected to one end of the first relay portion 304b on the opening side of the case 800. The second relay portion 304c extends from the first side wall 821 toward the second side wall 822. The second stretched portion 304d is connected to one end of the second relay portion 304c on the second side wall 822 side.

The second stretching portion 304d has an extending portion 304e and a bending portion 304f. The extending portion 304e and the bending portion 304f are aligned and connected in the z direction. The bent portion 304f is located closer to the second capacitor 306 than the extended portion 304e.

A bent portion 304f is connected to one end of the second relay portion 304c on the second side wall 822 side. The bent portion 304f extends in the z direction toward the opening side as it extends from one end of the second relay portion 304c on the second side wall 822 side toward the second side wall 822 side in the x direction. The extension portion 304e is connected to one end of the bending portion 304f on the opening side. The extending portion 304e extends from one end of the bent portion 304f on the opening side of the case 800 so as to be separated from the positive electrode 307 in the z direction.

The first stretched portion 303b and the second stretched portion 304d shown so far are separated from each other in the x direction and face each other. The distance between the bent portion 304f and the first stretched portion 303b in the x direction is longer than the distance between the extended portion 304e and the first stretched portion 303b in the x direction.

<Insulation plate>
The first insulating plate 700 has a flat shape having a thickness in the x direction. As shown in FIG. 2, the first insulating plate 700 extends in the z direction. The distance between the extending portion 304e and the first stretching portion 303b in the x direction is longer than the thickness of the first insulating plate 700 in the x direction. The first insulating plate 700 does not have to be a plate. It may also be paper having insulating properties.

A first insulating plate 700 is interposed between the first stretched portion 303b and the second stretched portion 304d. Specifically, a part of the first insulating plate 700 is interposed between the extending portion 304e and the first stretching portion 303b. The rest of the first insulating plate 700 is interposed between the bent portion 304f and the first stretched portion 303b. The first insulating plate 700 located between the bent portion 304f and the first stretched portion 303b will be described in detail later.

The second insulating plate 710 has a flat shape having a thin thickness in a direction orthogonal to the extending direction. As shown in FIG. 2, the second insulating plate 710 has a third insulating plate 710a extending in the z direction and a fourth insulating plate 710b extending in the x direction. The fourth insulating plate 710b is connected to one end on the opening side of the third insulating plate 710a extending in the z direction. The fourth insulating plate 710b extends in the x direction from one end of the third insulating plate 710a on the opening side toward the second side wall 822. The second insulating plate 710 does not have to be a plate. It may also be paper having insulating properties.

The separation distance between the first relay portion 304b and the second capacitor 306 in the x direction is longer than the thickness of the third insulating plate 710a. The separation distance between the second relay portion 304c and the positive electrode 307 in the z direction is longer than the thickness of the fourth insulating plate 710b.

A second insulating plate 710 is interposed between the first relay portion 304b and the second relay portion 304c and the second capacitor 306. Specifically, a third insulating plate 710a is interposed between the first relay portion 304b and the second capacitor 306. A fourth insulating plate 710b is interposed between the second relay portion 304c and the positive electrode 307.

<Case storage form>
In the above-described embodiment, the second capacitor 306 is housed in the hollow of the case 800. The hollow of the case 800 is filled with the coating resin 900. Therefore, the second capacitor 306, a part of the third feeding bus bar 303, a part of the fourth feeding bus bar 304, a part of the first insulating plate 700, and the second insulating plate 710 are each coated with the coating resin 900. .. These are connected to the case 800 by the coating resin 900.

Specifically, a part of the third power feeding bus bar 303 is a portion of the first connection portion 303a and the first extension portion 303b located on the second capacitor 306 side. Specifically, a part of the fourth power feeding bus bar 304 is a portion located on the second capacitor 306 side of the second connection portion 304a, the first relay portion 304b, the second relay portion 304c, and the bent portion 304f. Specifically, a part of the first insulating plate 700 is a portion located on the second capacitor 306 side.

As shown in FIG. 2, the portion of the first stretched portion 303b on the side of the second capacitor 306 is coated with the coating resin 900. The rest of the opening side of the case 800 in the first stretched portion 303b is exposed from the exposed surface 910 exposed to the outside air in the coating resin 900.

A part of the bent portion 304f on the second capacitor 306 side is covered with the coating resin 900. The rest of the bent portion 304f on the opening side is exposed from the exposed surface 910. The extension portion 304e is connected to one end of the bent portion 304f on the opening side exposed from the exposed surface 910. All of the extending portions 304e are exposed from the exposed surface 910.

The first insulating plate 700 described above is located between the bent portion 304f and the first stretched portion 303b on the exposed surface 910 side covered with the coating resin 900. The region between the bent portion 304f and the first stretched portion 303b on the exposed surface 910 side covered with the coating resin 900 where the first insulating plate 700 is located is referred to as an exposed surface side region 920.

The first insulating plate 700 is not located between the bent portion 304f and the first stretched portion 303b on the second capacitor 306 side covered with the coating resin 900. The region between the bent portion 304f and the first stretched portion 303b on the second capacitor 306 side covered with the coating resin 900, where the first insulating plate 700 is not located, is referred to as a second capacitor side region 930. In FIG. 2, the boundary line for partitioning the second capacitor side region 930 is shown by a broken line.

As described above, the second insulating plate 710 is covered with the coating resin 900. A fourth insulating plate 710b provided by the second insulating plate 710 is connected to one end of the opening side of the third insulating plate 710a provided by the second insulating plate 710. The fourth insulating plate 710b extends in the x direction from one end of the third insulating plate 710a on the opening side toward the second side wall 822. The end of the first insulating plate 700 on the second capacitor 306 side located in the exposed surface side region 920 and the end of the fourth insulating plate 710b on the second side wall 822 side are separated in the x direction and the z direction, respectively. There is.

<First stretching site and second stretching site>
The first stretched portion 303b and the second stretched portion 304d are separated in the x direction. The distance between the bent portion 304f and the first stretched portion 303b on the exposed surface 910 side covered with the coating resin 900 in the x direction is the distance between the bent portion 304f and the bent portion 304f located on the opening side of the case 800 exposed from the coating resin 900. It is longer than the separation distance of the first stretching portion 303b in the x direction.

The distance between the bent portion 304f and the first stretched portion 303b on the exposed surface 910 side covered with the coating resin 900 in the x direction is the distance between the bent portion 304f and the first stretched portion 304f on the second capacitor 306 side covered with the coating resin 900. It is shorter than the separation distance of the stretched portion 303b in the x direction. The distance between the bent portion 304f and the first stretched portion 303b on the side of the second capacitor 306 covered with the coating resin 900 in the x direction is such that the insulating property can be maintained via the coating resin 900.

The area between the first stretched portion 303b and the first insulating plate 700 on the exposed surface 910 is defined as the first exposed area. The area between the bent portion 304f and the first insulating plate 700 on the exposed surface 910 is defined as the second exposed area.

The area orthogonal to the z direction located between the first stretching portion 303b and the first insulating plate 700 at a position away from the second capacitor 306 on the opening side in the z direction from the exposed surface 910 is defined as the first area. .. The separation distance between the first stretched portion 303b and the first insulating plate 700 in the x direction is constant at any position in the z direction.

The area orthogonal to the z direction, which is located between the bent portion 304f and the first insulating plate 700, at a position away from the second capacitor 306 on the opening side in the z direction from the exposed surface 910 is defined as the second area. The area orthogonal to the z direction located between the extension portion 304e and the first insulating plate 700 at a position away from the second capacitor 306 on the opening side in the z direction from the exposed surface 910 is defined as the third area. A position away from the second capacitor 306 on the opening side in the z direction from the exposed surface 910 corresponds to a predetermined position. The first area corresponds to the first cross-sectional area. Each of the second area and the third area corresponds to the second cross-sectional area.

The first total area, which is the sum of the first exposed area and the second exposed area, is larger than the second total area, which is the sum of the first area and the second area. The first total area, which is the sum of the first exposed area and the second exposed area, is larger than the third total area, which is the sum of the first area and the third area. The first total area corresponds to the first total area. Each of the second total area and the third total area corresponds to the second total area.

<Effect>
As shown above, the first insulating plate 700 is located in the exposed surface side region 920 covered with the coating resin 900. Therefore, the insulating property between the bent portion 304f and the first stretched portion 303b on the exposed surface 910 side covered with the coating resin 900 is maintained.

The first insulating plate 700 is not located in the second capacitor side region 930 covered with the coating resin 900, and only the coating resin 900 is present. The distance between the bent portion 304f and the first stretched portion 303b on the side of the second capacitor 306 covered with the coating resin 900 in the x direction is such that the insulating property can be maintained via the coating resin 900. Therefore, the insulating property between the bent portion 304f and the first stretched portion 303b on the second capacitor 306 side covered with the coating resin 900 is maintained.

As described above, the case 800 is filled with the coating resin 900. The coating resin 900 is discharged into the case 800 by a plurality of external nozzles or the like. When the coating resin 900 is discharged into the case 800 from the plurality of nozzles, air is entrained at the confluence of the coating resins 900. As a result, void 940 is generated in the coating resin 900.

The second capacitor 306 coated on the coating resin 900 is a film capacitor around which a dielectric film is wound. Air is contained between the wound dielectric films. Therefore, when the second capacitor 306 is filled in the coating resin 900, the air contained in the second capacitor 306 flows out to the coating resin 900. As a result, voids 940 are likely to occur in the coating resin 900.

The distance between the bent portion 304f and the first stretched portion 303b on the second capacitor 306 side covered with the coating resin 900 in the x direction is the distance between the bent portion 304f and the first stretched portion 303b on the exposed surface 910 side covered with the coating resin 900. It is longer than the separation distance in the x direction from the 1 stretched portion 303b. Therefore, even if the void 940 is located in the second capacitor side region 930, it is possible to prevent the coating resin 900 interposed between the void 940 and the stretched portion from becoming thin. It is suppressed that the shortest separation distance between the void 940 and the stretched portion is shortened.

As a result, the deterioration of the insulating properties of the first stretched portion 303b and the second stretched portion 304d covered with the coating resin 900 is suppressed. The occurrence of insulation failure between the first stretched portion 303b and the second stretched portion 304d is suppressed.

As described above, the first total area in which the first exposed area and the second exposed area are totaled is larger than the second total area in which the first area and the second area are totaled. The first total area, which is the sum of the first exposed area and the second exposed area, is larger than the third total area, which is the sum of the first area and the third area. The first total area is larger than both the second total area and the third total area. Therefore, air can easily escape from the exposed surface 910. As a result, the coating resin 900 is less likely to contain void 940. Poor insulation between the bent portion 304f and the first stretched portion 303b in the coating resin 900 is easily suppressed.

As described above, the separation distance between the first relay portion 304b and the second capacitor 306 in the x direction is longer than the thickness of the third insulating plate 710a. The separation distance between the second relay portion 304c and the positive electrode 307 in the z direction is longer than the thickness of the fourth insulating plate 710b. Therefore, the void 940 may be located in the gap between the second capacitor 306 and the second insulating plate 710 and in the gap between the relay portion and the second insulating plate 710.

As described above, the end of the first insulating plate 700 located in the exposed surface side region 920 on the second capacitor 306 side and the end of the fourth insulating plate 710b on the second side wall 822 side are in the x direction and the z direction, respectively. Are separated from each other. A space is interposed between the fourth insulating plate 710b and the first insulating plate 700. Through this space, the void 940 located in the gap between the second capacitor 306 and the second insulating plate 710 is formed from the coating resin 900 on the second capacitor 306 side with the bent portion 304f in the exposed surface side region 920. 1 It becomes possible to move to the area between the insulating plate 700.

Further, the void 940 located in the gap between the relay portion and the second insulating plate 710 passes through the above-mentioned space from the coating resin 900 on the second capacitor 306 side to the first stretched portion 303b in the exposed surface side region 920. It becomes possible to move to the area between the first insulating plate 700 and the first insulating plate 700.

Therefore, as compared with the configuration in which the first insulating plate 700 and the second insulating plate 710 are connected, the bent portion 304f and the first insulating plate in the exposed surface side region 920 from the coating resin 900 on the second capacitor 306 side The void 940 is easy to move to the area between 700 and 700. The void 940 is easily moved from the coating resin 900 on the second capacitor 306 side to the region between the first stretched portion 303b and the first insulating plate 700 in the exposed surface side region 920. Therefore, air can easily escape from the exposed surface 910. Poor insulation between the first stretched portion 303b and the second stretched portion 304d in the coating resin 900 is likely to be suppressed.

Although the preferred embodiments of the present disclosure have been described above, the present disclosure is not limited to the above-described embodiments, and can be variously modified and implemented without departing from the gist of the present disclosure.

(Modification example)
In the present embodiment, as shown in FIG. 2, the portion of the bent portion 304f and the first stretched portion 303b on the second capacitor 306 side is coated with the coating resin 900, and the bent portion 304f and the first stretched portion 303b are respectively in the z direction. The remaining part was exposed from the exposed surface 910. However, as shown in FIG. 3, all of the bent portion 304f, the extended portion 304e on the bent portion 304f side connected to the bent portion 304f, and a part of the first stretched portion 303b facing each of them in the x direction are respectively. It may be coated with the coating resin 900.

In the present embodiment, as shown in FIG. 2, the first insulating plate 700 is located only between the bent portion 304f and the first stretched portion 303b on the exposed surface 910 side covered with the coating resin 900. It was. However, as shown in FIG. 4, the first insulating plate 700 may be located in the region between the bent portion 304f and the first stretched portion 303b on the second capacitor 306 side covered with the coating resin 900.

In that case, even if the void 940 is located in the coating resin 900 located at the route connecting the bent portion 304f and the first stretching portion 303b, the thickness of the coating resin 900 interposed between the void 940 and the stretching portion. Is suppressed from becoming thin. It is suppressed that the shortest separation distance between the void 940 and the stretched portion is shortened. As a result, the occurrence of insulation failure between the first stretched portion 303b and the second stretched portion 304d is suppressed.

In the present embodiment, as shown in FIG. 2, as the bent portion 304f extends from one end of the second relay portion 304c on the second side wall 822 side toward the second side wall 822 side in the x direction, it extends in the z direction toward the opening side. The configuration extending to is shown. However, the bent portion 304f does not have to extend in the z direction as it extends in the x direction. As shown in FIG. 5, the bent portion 304f may extend in the z direction from one end on the second side wall 822 side toward the opening side.

In that case, as shown in FIG. 5, the portion of the first stretching portion 303b located on the second capacitor 306 side extends in the x direction from one end of the first connecting portion 303a on the first side wall 821 side to the first side wall 821. Along with this, it may extend in the z direction toward the opening side. As shown in FIG. 6, all of the bent portions 304f, the extended portion 304e on the bent portion 304f side connected to the bent portion 304f, and a part of the first stretched portion 303b facing each of them in the x direction are formed. Each may be coated with a coating resin 900.

Further, as shown in FIG. 7, z so that the bending portion 304f and the first stretching portion 303b located on the second capacitor 306 side each extend from the second capacitor 306 side to the opening side and the distance from each other becomes shorter. It may extend in the direction. Specifically, the bent portion 304f may extend in the z direction toward the opening side as the bent portion 304f extends from one end of the second relay portion 304c on the second side wall 822 side toward the second side wall 822 side in the x direction. .. As the portion of the first stretching portion 303b located on the second capacitor 306 side extends from one end of the first connecting portion 303a on the first side wall 821 side to the first side wall 821 in the x direction, z toward the opening side. It may extend in the direction.

In that case, the fourth insulating plate 710b of the second insulating plate 710 extends in the x direction toward the second side wall 822, and is located on the second relay portion 304c, the bent portion 304f, and the second capacitor 306 side. It may be interposed between the stretched portion 303b and the positive electrode 307. As shown in FIG. 8, all of the bent portions 304f, the extended portion 304e on the bent portion 304f side connected to the bent portion 304f, and a part of the first stretched portion 303b facing each of them in the x direction are formed. Each may be coated with a coating resin 900.

In the present embodiment, as shown in FIG. 2, the end portion of the first insulating plate 700 located in the exposed surface side region 920 on the second capacitor 306 side and the second side wall of the fourth insulating plate 710b provided with the second insulating plate 710. The configuration in which the end portion on the 822 side is separated from each other in the x direction and the z direction is shown. However, as shown in FIG. 9, the insulating plate does not have to be provided with the first insulating plate 700 and the second insulating plate 710 separately. The first insulating plate 700 and the second insulating plate 710 may be integrally connected. The integrally connected insulating plate is referred to as a fifth insulating plate 720.

As shown in FIGS. 9 to 11, the fifth insulating plate 720 is voided from the coating resin 900 on the second capacitor 306 side to the coating resin 900 on the exposed surface side region 920 at least at a portion located in the second capacitor side region 930. It suffices to have a communication hole 720a through which the 940 can move. In FIGS. 9 to 11, the communication hole 720a is shown surrounded by a alternate long and short dash line. In FIG. 11, the boundary between the first insulating plate 700 and the fourth insulating plate 710b is shown by a broken line. The boundary between the fourth insulating plate 710b and the third insulating plate 710a is shown by a broken line. As shown in FIG. 10, all of the bent portions 304f, the extended portion 304e on the bent portion 304f side connected to the bent portion 304f, and a part of the first extending portion 303b facing each of them in the x direction are formed. Each may be coated with a coating resin 900.

In the present embodiment, as shown in FIG. 2, a positive electrode 307 is provided on the upper surface 306a of the second capacitor 306, and a negative electrode 308 is provided on the lower surface 306b of the second capacitor 306. However, the positive electrode 307 does not have to be provided on the upper surface 306a. The negative electrode 308 may not be provided on the lower surface 306b. As shown in FIG. 12, the positive electrode 307 may be provided on the second side wall 822 side of the second capacitor 306. The negative electrode 308 may be provided on the first side wall 821 side of the second capacitor 306. In that case, the second insulating plate 710 may not be provided.

303 ... 3rd power supply bus bar, 303a ... 1st connection part, 303b ... 1st extension part, 304 ... 4th power supply bus bar, 304a ... 2nd connection part, 304b ... 1st relay part, 304c ... 2nd relay part, 304d ... second stretched portion, 306 ... second capacitor, 307 ... positive electrode, 308 ... negative electrode, 700 ... first insulating plate, 710 ... second insulating plate, 900 ... coating resin, 910 ... exposed surface

Claims (3)

A capacitor (306) including a first electrode (307) and a second electrode (308),
A first bus bar (303) including a first connection portion (303a) connected to the first electrode and a first extension portion (303b) extending in the length direction away from the capacitor.
A second bus bar (304) having a second connection portion (304a) connected to the second electrode (308) and a second extension portion (304d) extending in the length direction away from the capacitor.
An insulating member (700) located between the first stretched portion and the second stretched portion and extending in the length direction,
A coating resin (900) having a lower insulating property than the insulating member, which covers each of the capacitor, the first connecting portion, the second connecting portion, the first stretched portion, the second stretched portion, and the insulating member. ) And,
A part of each of the first stretched portion, the second stretched portion, and the insulating member is exposed from the exposed surface (910) of the coating resin exposed to the outside air.
The insulating member is located between the exposed surface side of the first stretched portion in the coating resin and the exposed surface side of the second stretched portion in the coating resin.
The distance between the capacitor side of the first stretched portion and the capacitor side of the second stretched portion in the coating resin is such that the exposed surface side of the first stretched portion and the exposed portion of the second stretched portion. A power converter that is longer than the distance from the surface side. The first total of the first exposed area between the first stretched portion and the insulating member on the exposed surface and the second exposed area between the second stretched portion and the insulating member on the exposed surface. At a predetermined position where the area is separated from the capacitor in the length direction from the exposed surface, a first cross-sectional area orthogonal to the length direction between the first stretched portion and the insulating member and the predetermined position. The power conversion device according to claim 1, wherein the power conversion device is larger than the second total area including the second cross-sectional area orthogonal to the length direction between the second stretched portion and the insulating member. It has a relay insulation member (710) located between the capacitor and the second bus bar.
The second bus bar has relay sites (304b, 304c) that connect the second stretching site and the second connecting site.
The relay insulating member is located between the capacitor and the relay portion,
The power conversion device according to claim 1 or 2, wherein there is a space between the insulating member and the relay insulating member for communicating the capacitor side and the exposed surface side of the coating resin.

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