JP7099300B2 - Power conversion unit - Google Patents

Description

The disclosure described herein relates to a power conversion unit.

As shown in Patent Document 1, a power conversion device including a plurality of semiconductor modules and a DC bus bar connected to the plurality of semiconductor modules is known. A plurality of semiconductor modules are laminated in the stacking direction. The DC bus bar extends in the stacking direction.

Japanese Patent No. 5803684

As described above, in the power conversion device shown in Patent Document 1, the DC bus bar extends in the stacking direction. Therefore, there is a possibility that the dimensional variation in the stacking direction of the DC bus bar will increase. This may make it difficult to connect the DC bus bar (conductive portion) to an external connection portion such as a wire.

Therefore, it is an object of the disclosure described in the present specification to provide a power conversion unit in which the connection between the conductive portion and the external connection portion is suppressed from becoming difficult.

One of the disclosures includes a plurality of switches (531 to 534) arranged apart from each other in the arrangement direction, and a switch unit (530) including a holding unit (537) for holding the plurality of switches.
A conductive portion (570) provided with a plurality of divided bus bars (571, 572) connected to each other in a manner extending in the alignment direction, and a conductive portion (570).
Insulating terminal block (590) to which the conductive part is fixed,
It has a switch unit and a housing (580) that supports each of the terminal blocks to which the conductive portion is fixed .
A switch is connected to a split bus bar (571) located at one of the two ends of a plurality of split bus bars connected to each other, and a split located at the other of the two ends of the plurality of split bus bars. An external connection (302) is connected to the bus switch (572) ,
Multiple split bus bars are connected by at least one connecting bolt (573) and
The terminal block is connected to the housing,
The split bus bar located at the other end of the two ends of the plurality of split bus bars has a first bolt hole (574c) into which a connecting bolt is inserted and a fixing bolt (578) for fixing the conductive portion to the terminal block. ) Is inserted into the second bolt hole (576c), and the third bolt hole (577c) into which the connection bolt (579) for connecting the conductive portion and the external connection portion is inserted is formed.
A connection bolt hole (594c) into which the shaft portion of the connection bolt passed through the third bolt hole is inserted is formed in the terminal block.
A power conversion unit in which a second bolt hole is located between a first bolt hole and a third bolt hole in the arrangement direction .

According to this, the extension of each of the plurality of divided bus bars (571, 572) is suppressed. Therefore, an increase in dimensional variation in the length of each of the plurality of divided bus bars (571, 572) is suppressed. This suppresses the difficulty in connecting the conductive portion (570) and the external connection portion (302).

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 which shows the in-vehicle system. It is a top view of the power conversion unit which concerns on 1st Embodiment. It is a bottom view of the power conversion unit which concerns on 1st Embodiment. It is a perspective view which shows the 2nd division bus bar and a terminal block. It is a front view of the 2nd division bus bar and a terminal block. It is sectional drawing which follows the VI-VI line shown in FIG. It is sectional drawing which shows the modification of the terminal block.

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

(First Embodiment)
<In-vehicle system>
First, an in-vehicle system 100 provided with a power conversion unit 520 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. The power conversion device 300 includes a power conversion unit 520.

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 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, 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 applied 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 converter 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.

As shown in FIG. 1, the converter 500 is electrically connected to the battery 200 via the first power line 301 and the second power line 302. The converter 500 is electrically connected to the inverter 600 via the third power line 303 and the fourth power line 304.

The first power line 301 is connected to the positive electrode of the battery 200. The second power line 302 is connected to the negative electrode of the battery 200. A first smoothing capacitor 501 is connected to the first power line 301 and the second power line 302. One of the two electrodes of the first smoothing capacitor 501 is connected to the first power line 301. The other of the two electrodes of the first smoothing capacitor 501 is connected to the second power line 302. The first smoothing capacitor 501 is part of the components of the converter 500. The converter 500 will be described in detail later.

The inverter 600 has three or more phases of legs connected in parallel between the third power line 303 and the fourth power line 304. Each of these three or more phases has two switch elements connected in series. A bus bar is connected to the midpoint between these two switch elements. This bus bar is electrically connected to the stator coil of the motor 400. The description and illustration of the configuration of the inverter 600 will be omitted.

<Circuit configuration of converter>
As shown in FIG. 1, the converter 500 has a reactor 510 and a power conversion unit 520. The power conversion unit 520 has a switch module 530 and a second smoothing capacitor 540. Further, the power conversion unit 520 has a discharge resistance (not shown). Strictly speaking, the second smoothing capacitor 540 is a component of the inverter 600.

The reactor 510 is mechanically and electrically connected to the switch module 530 via a connecting bus bar 550. The switch module 530 is mechanically and electrically connected to the second smoothing capacitor 540 via the P bus bar 560 and the N bus bar 570, respectively.

The reactor 510 has an A-phase reactor 511, a B-phase reactor 512, a C-phase reactor 513, and a D-phase reactor 514. Accordingly, the switch module 530 has an A-phase leg 531 and a B-phase leg 532, a C-phase leg 533, and a D-phase leg 534. The connected bus bar 550 has an A-phase linked bus bar 551, a B-phase linked bus bar 552, a C-phase linked bus bar 553, and a D-phase linked bus bar 554.

As described above, the converter 500 of the present embodiment includes a four-phase reactor, a leg, and a connected bus bar of A phase to D phase. The four-phase legs are driven and controlled independently for each phase by the above-mentioned ECU and gate driver. Alternatively, the four-phase leg is driven and controlled in synchronization with the ECU and the gate driver.

Each of the A-phase leg 531 to the D-phase leg 534 has a high-side switch 535 and a low-side switch 536, and a high-side diode 535a and a low-side diode 536a as semiconductor elements. These semiconductor elements are resin-sealed to form a package. The A-phase leg 531 to the D-phase leg 534 correspond to a switch.

The switch module 530 has a cooler 537 that holds each of the A-phase legs 531 to the D-phase legs 534, as shown in FIGS. 2 and 3. Refrigerant flows inside the cooler 537. As a result, the temperature rise of each of the A-phase leg 531 to the D-phase leg 534 is suppressed. The cooler 537 corresponds to the holding portion. The switch module 530 corresponds to a switch unit.

In this embodiment, an n-channel type IGBT is adopted as the high side switch 535 and the low side switch 536. The tips of the collector electrodes, emitter electrodes, and terminals connected to the gate electrodes of the high-side switch 535 and the low-side switch 536 are exposed outside the above package.

As shown in FIG. 1, the collector electrode of the high side switch 535 is connected to the P bus bar 560. The emitter electrode of the high side switch 535 and the collector electrode of the low side switch 536 are connected. The emitter electrode of the low side switch 536 is connected to the N bus bar 570. As a result, the high-side switch 535 and the low-side switch 536 are sequentially connected in series from the P bus bar 560 to the N bus bar 570. The N bus bar 570 corresponds to the conductive portion.

Further, the cathode electrode of the high side diode 535a is connected to the collector electrode of the high side switch 535. The anode electrode of the high side diode 535a is connected to the emitter electrode of the high side switch 535. As a result, the high-side diode 535a is connected in anti-parallel to the high-side switch 535.

Similarly, the cathode electrode of the low side diode 536a is connected to the collector electrode of the low side switch 536. The anode electrode of the low side diode 536a is connected to the emitter electrode of the low side switch 536. As a result, the low-side diode 536a is connected in anti-parallel to the low-side switch 536.

As these high-side switches 535 and low-side switches 536, MOSFETs can be adopted instead of IGBTs. The type of switch to be used is not particularly limited. However, when MOSFETs are used as these switches, the above diodes may not be necessary.

Further, the semiconductor element constituting the converter 500 can be manufactured by a semiconductor such as Si and a wide-gap semiconductor such as SiC. The material is not particularly limited as a constituent material of the semiconductor device.

Furthermore, the types and constituent materials of the switch elements of each of the A-phase leg 531 to the D-phase leg 534 may be different. For example, the switch element included in the A-phase leg 531 may be a MOSFET composed of SiC, and the switch element included in each of the B-phase legs 532 to the D-phase leg 534 may be an IGBT composed of Si.

As shown in FIG. 1, one end of the A-phase reactor 511 is connected to the first power line 301. The other end of the A-phase reactor 511 is connected to the emitter electrode of the high-side switch 535 of the A-phase leg 531 and the collector electrode of the low-side switch 536 via the A-phase connecting bus bar 551. As described above, the A-phase reactor 511 is connected to the positive electrode of the battery 200 and the midpoint between the high-side switch 535 and the low-side switch 536 of the A-phase leg 531.

Similarly, one end of the B-phase reactor 512 is connected to the first power line 301. The other end of the B-phase reactor 512 is connected to the emitter electrode of the high-side switch 535 of the B-phase leg 532 and the collector electrode of the low-side switch 536 via the B-phase connecting bus bar 552. As described above, the B-phase reactor 512 is connected to the positive electrode of the battery 200 and the midpoint between the high-side switch 535 and the low-side switch 536 of the B-phase leg 532.

One end of the C-phase reactor 513 is connected to the first power line 301. The other end of the C-phase reactor 513 is connected to the emitter electrode of the high-side switch 535 of the C-phase leg 533 and the collector electrode of the low-side switch 536 via the C-phase connecting bus bar 553. As described above, the C-phase reactor 513 is connected to the positive electrode of the battery 200 and the midpoint between the high-side switch 535 and the low-side switch 536 of the C-phase leg 533.

One end of the D-phase reactor 514 is connected to the first power line 301. The other end of the D-phase reactor 514 is connected to the emitter electrode of the high-side switch 535 of the D-phase leg 534 and the collector electrode of the low-side switch 536 via the D-phase connecting bus bar 554. As described above, the D-phase reactor 514 is connected to the positive electrode of the battery 200 and the midpoint between the high-side switch 535 and the low-side switch 536 of the D-phase leg 534.

The high-side switch 535 and the low-side switch 536 provided in each of the A-phase leg 531 to the D-phase leg 534 are controlled to open and close by the above-mentioned ECU and 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 controls the opening and closing of the high-side switch 535 and the low-side switch 536 to raise or lower 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. Further, the ECU adjusts the buck-boost level by selecting the number of legs to be driven from the A-phase leg 531 to the D-phase leg 534. This buck-boost level is determined according to the target torque of the motor 400 and the SOC of the battery 200.

When boosting the DC power of the battery 200, the ECU alternately opens and closes the high-side switch 535 and the low-side switch 536. On the contrary, when the DC power supplied from the inverter 600 is stepped down, the ECU fixes the control signal output to the low side switch 536 to the low level. At the same time, the ECU sequentially switches the control signal output to the high side switch 535 between high level and low level.

<Structure of power conversion unit>
Next, the configuration of the power conversion unit 520 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 the alignment direction. The z direction corresponds to the crossing direction.

As shown in FIGS. 2 and 3, the power conversion unit 520 supports these in addition to the switch module 530, the second smoothing capacitor 540, the connected bus bar 550, the P bus bar 560, and the N bus bar 570 described so far. It has a case 580 to be (stored). The case 580 corresponds to the housing.

The case 580 has an annular frame portion 581 and a support portion 582 integrally connected to the frame portion 581. The frame portion 581 has a first side wall 581a and a second side wall 581b that face each other apart from each other in the x direction, and a third side wall 581c and a fourth side wall 581d that face each other apart from each other in the y direction.

The first side wall 581a and the second side wall 581b extend in the y direction. The third side wall 581c and the fourth side wall 581d extend in the x direction. The first side wall 581a, the third side wall 581c, the second side wall 581b, and the fourth side wall 581d are sequentially connected in an annular direction in the circumferential direction around the z direction. As a result, the frame portion 581 forms an annular shape that opens in the z direction.

The second side wall 581b is formed with two grooves for providing a supply pipe 537a and a discharge pipe 537b, which will be described later. These two grooves are locally recessed from the lower surface side to the upper surface side of the case 580.

The support portion 582 is located in the hollow of the frame portion 581. The support portion 582 is connected to the inner wall surface of the frame portion 581. A part of the opening on the upper surface side of the frame portion 581 is closed by the support portion 582.

The support portion 582 is subdivided into a first support portion 582a connected to the inner wall surface of the third side wall 581c and extending in the x direction, and a second support connected to the inner wall surface of the fourth side wall 581d and extending in the x direction. It has a portion 582b and.

The first support portion 582a and the second support portion 582b are separated from each other in the y direction. The gap between the first support portion 582a and the second support portion 582b communicates with the opening of the frame portion 581 in the z direction. A cooler 537 and a spring portion 538 described later are provided on the first support portion 582a and the second support portion 582b.

The support portion 582 has a third support portion 582c in addition to the first support portion 582a and the second support portion 582b. The third support portion 582c is separated from the first side wall 581a in the x direction. The third support portion 582c is located between the first support portion 582a and the second support portion 582b in the y direction. The third support portion 582c is connected to each of the first support portion 582a, the second support portion 582b, and the second side wall 581b. In FIG. 3, a broken line is provided at the boundary between the third support portion 582c and the second support portion 582b.

The third support portion 582c is formed with a recess 582d that is locally recessed from the lower surface side to the upper surface side of the case 580 along the z direction. A second smoothing capacitor 540 is provided in the recess 582d.

A through hole that opens in the z direction is formed in the bottom wall that partitions a part of the recess 582d. Through this through hole, the first extension bus bar 541 and the second extension bus bar 542, which will be described later, can be connected to the two electrode terminals electrically connected to the two electrodes of the second smoothing capacitor 540. .. The first support portion 582a and the second support portion 582b are each connected to a bottom wall that partitions a part of the recess 582d.

As described above, the switch module 530 has A-phase legs 531 to D-phase legs 534 constituting the package, and a cooler 537 for holding them. As shown in FIG. 3, the cooler 537 has a supply pipe 537a, a discharge pipe 537b, and a plurality of relay pipes 537c. The supply pipe 537a and the discharge pipe 537b are connected via a plurality of relay pipes 537c. Refrigerant flows through these three pipes. Refrigerant flows from the supply pipe 537a to the discharge pipe 537b via the plurality of relay pipes 537c.

The supply pipe 537a and the discharge pipe 537b each extend in the x direction. The supply pipe 537a and the discharge pipe 537b are separated from each other in the y direction. Each of the plurality of relay pipes 537c extends from the supply pipe 537a toward the discharge pipe 537b along the y direction.

The plurality of relay tubes 537c are arranged so as to be separated from each other in the x direction. A gap is formed between two adjacent relay tubes 537c. The cooler 537 is configured with a total of four voids. A-phase legs 531 to D-phase legs 534 constituting the package are individually provided in each of these four voids. As a result, the A-phase legs 531 to the D-phase legs 534 are arranged apart from each other in the x direction.

Each of the A-phase leg 531 to the D-phase leg 534 is in contact with the relay tube 537c in the x direction. As a result, the heat generated in the four-phase leg can be dissipated to the refrigerant via the relay pipe 537c.

As shown in FIG. 3, the cooler 537 (switch module 530) is provided in the first support portion 582a and the second support portion 582b. A supply pipe 537a is provided in the second support portion 582b. A discharge pipe 537b is provided in the first support portion 582a. The plurality of relay tubes 537c and the four-phase leg are provided in the hollow of the frame portion 581 in the region communicating with the gap between the first support portion 582a and the second support portion 582b in the z direction.

The tip of the terminal connected to the collector electrode, the emitter electrode, and the gate electrode of the high side switch 535 and the low side switch 536 provided in each of the four phase legs protrudes out of the opening of the frame portion 581 along the z direction. There is. The tips of the terminals connected to the collector electrode and the emitter electrode each project out of the opening on the upper surface side of the case 580 in the frame portion 581. The tip of the terminal connected to the gate electrode projects out of the opening on the lower surface side of the case 580 in the frame portion 581.

With the cooler 537 provided on the first support 582a and the second support 582b, the plurality of relay tubes 537c and the four-phase legs are aligned with the third support 582c in the x direction. Therefore, the plurality of relay tubes 537c and the four-phase legs are aligned in the x direction with the second smoothing capacitor 540 provided in the recess 582d of the third support portion 582c. Further, a second smoothing capacitor 540 is located between the supply pipe 537a and the discharge pipe 537b. Therefore, the second smoothing capacitor 540 is surrounded by a supply pipe 537a, a discharge pipe 537b, and a relay pipe 537c through which the refrigerant flows.

As shown in FIG. 3, the relay pipes 537c located on the third support portion 582c side of the plurality of relay pipes 537c arranged in the x direction are in contact with each other in a manner facing the third support portion 582c in the x direction. .. The relay pipe 537c located on the first side wall 581a side of the plurality of relay pipes 537c arranged in the x direction is separated from the first side wall 581a in the x direction. The spring portion 538 is press-fitted into the gap between the relay pipe 537c and the first side wall 581a.

By press-fitting the spring portion 538 into the gap, the plurality of relay pipes 537c are compressed in the x direction between the spring portion 538 and the third support portion 582c. The plurality of relay tubes 537c are elastically deformed in the x direction in such a manner that the distance between the plurality of relay tubes 537c is narrowed. As a result, the contact area between each of the four-phase legs provided between the plurality of relay pipes 537c and the relay pipe 537c is increased. The increase in thermal resistance between the leg and the relay tube 537c is suppressed.

As shown above, the switch module 530 has a plurality of relay tubes 537c arranged apart from each other in the x direction, and a four-phase leg provided in a gap between the plurality of relay tubes 537c. Therefore, the switch module 530 is generally long in the x direction. The length of the switch module 530 in the x direction increases as the number of legs included in the switch module 530 increases.

Further, a spring portion 538 is provided between the relay pipe 537c of the switch module 530 and the first side wall 581a. Therefore, the case 580 is generally long in the x direction. The length of the case 580 in the x direction also increases as the number of legs included in the switch module 530 increases.

As described with reference to FIG. 1, the A-phase coupled bus bars 551 to D-phase coupled bus bars 554 are the emitter electrodes and low-side switches of the high-side switch 535 of the corresponding leg of the A-phase legs 531 to D-phase legs 534. It is electrically connected to the collector electrode of 536.

As described above, the tips of the terminals connected to the collector electrodes and the emitter electrodes of the high-side switch 535 and the low-side switch 536 respectively project to the outside of the opening on the upper surface side of the frame portion 581. As shown in FIG. 2, each of the A-phase connecting bus bar 551 to the D-phase connecting bus bar 554 is located on the upper surface side of the frame portion 581 so as to be connected to these terminals. These A-phase connected bus bars 551 to D-phase connected bus bars 554 are arranged so as to be separated in the x direction.

The A-phase connecting bus bar 551 is connected to the tip of a terminal connected to the emitter electrode of the high-side switch 535 included in the A-phase leg 531 and the tip of the terminal connected to the collector electrode of the low-side switch 536. The A-phase connecting bus bar 551 extends along the y direction so as to be separated from the connection portion with these terminals. At the tip of the A-phase connecting bus bar 551, an A-phase bolt hole 551a for bolting to the A-phase reactor 511 is formed.

Similarly, the B-phase connecting bus bar 552 is connected to the tip of the terminal connected to the emitter electrode of the high-side switch 535 of the B-phase leg 532 and the tip of the terminal connected to the collector electrode of the low-side switch 536. .. The B-phase connecting bus bar 552 extends along the y direction so as to be separated from the connection portion with these terminals. A B-phase bolt hole 552a for bolting to the B-phase reactor 512 is formed at the tip of the B-phase connecting bus bar 552.

The C-phase connecting bus bar 553 is connected to the tip of a terminal connected to the emitter electrode of the high-side switch 535 included in the C-phase leg 533 and the tip of the terminal connected to the collector electrode of the low-side switch 536. The C-phase connecting bus bar 553 extends along the y direction so as to be separated from the connection portion with these terminals. At the tip of the C-phase connecting bus bar 553, a C-phase bolt hole 553a for bolting to the C-phase reactor 513 is formed.

The D-phase connecting bus bar 554 is connected to the tip of a terminal connected to the emitter electrode of the high-side switch 535 included in the D-phase leg 534 and the tip of a terminal connected to the collector electrode of the low-side switch 536. The D-phase connecting bus bar 554 extends along the y direction so as to be separated from the connection portion with these terminals. At the tip of the D-phase connecting bus bar 554, a D-phase bolt hole 554a for bolting to the D-phase reactor 514 is formed. The bolt holes of the connecting bus bar shown above are indicated by white circles in FIG.

As described with reference to FIG. 1, one of the emitter electrode of the high side switch 535 of each of the A-phase legs 531 to D-phase leg 534 and one of the two electrodes of the second smoothing capacitor 540 is attached to the P bus bar 560. It is electrically connected. The collector electrode of the low-side switch 536 of each of the A-phase legs 531 to the D-phase leg 534 and the other of the two electrodes of the second smoothing capacitor 540 are electrically connected to the N bus bar 570.

As shown in FIG. 2, the first extension bus bar 541 is connected to one of the two electrode terminals of the second smoothing capacitor 540. The P bus bar 560 is bolted to the first extension bus bar 541. The first extension bus bar 541 is formed with a P-bolt hole 541a for bolting the third power line 303.

A second extension bus bar 542 is connected to the other of the two electrode terminals of the second smoothing capacitor 540. The N bus bar 570 is bolted to the second extension bus bar 542. The second extension bus bar 542 is formed with an N-bolt hole 542a for bolting the fourth power line 304. The bolt holes of the extension bus bar shown above are indicated by white circles in FIG.

As shown in FIG. 2, the P bus bar 560 and the N bus bar 570 overlap each other in the z direction and are provided on the upper surface side of the case 580. An insulating fixing plate (not shown) is provided between the P bus bar 560 and the N bus bar 570.

Each of the P bus bar 560 and the N bus bar 570 is fixed to the fixing plate by a bolt (not shown). The fixing plate is fixed to the case 580 by a bolt (not shown). In this way, the P bus bar 560 and the N bus bar 570 are fixed to the case 580 via the fixing plate. Further, the N bus bar 570 is fixed to the case 580 via a terminal block 590 described later.

The P bus bar 560 has a main body portion 561 extending in the x direction and a plurality of connecting end portions 562 extending from the main body portion 561 in the y direction. The main body 561 is bolted to the first extension bus bar 541. The plurality of connection ends 562 are welded to the tips of terminals connected to the collector electrodes of the high side switches 535 of each of the four phase legs. Next, N Basba 570 will be described in detail.

<Dimensional variation of N bus bar>
As described above, the N-bus bar 570 is connected to each of the A-phase legs 531 to D-phase legs 534 of the switch module 530 and the second smoothing capacitor 540. The switch module 530 and the second smoothing capacitor 540 to be connected to the N bus bar 570 are arranged in the x direction. The switch module 530 has a long shape in the x direction.

Further, the N bus bar 570 is fixed to the case 580 via a fixing plate and a terminal block 590 described later. The case 580 has a long shape in the x direction due to the arrangement of the spring portion 538, the switch module 530, and the second smoothing capacitor 540 in the x direction.

A second power line 302 is mechanically connected to the case 580 via a terminal block 590. The N bus bar 570 is mechanically and electrically connected to the second power line 302. The fixed position of the second power line 302 in the case 580 is aligned with the spring portion 538 via the first side wall 581a so as to be separated from each other in the x direction. This fixed position and the connection position of the second power line 302 in the N bus bar 570 are the same.

Due to the configuration shown above, the N bus bar 570 has a long shape in the x direction. Due to the extension in the x direction, there is a risk that the dimensional variation in the length of the N bus bar 570 in the x direction will increase. This may make it difficult to connect the N bus bar 570 and the second power line 302. In order to solve such a problem, the N bus bar 570 is divided into a plurality of parts.

<Structure of N bus bar>
The N bus bar 570 of the present embodiment is divided into two, a first split bus bar 571 and a second split bus bar 572. The first split bus bar 571 and the second split bus bar 572 are manufactured by pressing a metal plate, respectively. The first split bus bar 571 and the second split bus bar 572 are connected to each other in a manner extending in the x direction. The first split bus bar 571 and the second split bus bar 572 are mechanically and electrically connected to each other via a connecting bolt 573.

<1st division bus bar>
The first divided bus bar 571 has a main body portion 571a, a first connection end portion 571b, a second connection end portion 571c, and a plurality of third connection end portions 571d. The main body portion 571a has a longer length in the extending direction (extending direction) than each of the first connection end portion 571b to the third connection end portion 571d. The main body portion 571a extends in the x direction from the second side wall 581b toward the first side wall 581a on the above-mentioned fixing plate.

The first connection end portion 571b extends in the y direction from the end portion on the second side wall 581b side of the two ends of the main body portion 571a toward the third side wall 581c side. The first connection end 571b is bolted to the second extension bus bar 542.

The second connection end portion 571c extends in the y direction from the end portion on the first side wall 581a side of the two ends of the main body portion 571a toward the third side wall 581c side. The second connection end 571c is bolted to the second split bus bar 572.

As shown in FIG. 2, the first connection end portion 571b and the second connection end portion 571c are arranged so as to be separated from each other in the x direction. A plurality of relay tubes 537c and four-phase legs are located between the first connection end portion 571b and the second connection end portion 571c.

The plurality of third connection end portions 571d extend in the y direction from the central portion of the main body portion 571a toward the third side wall 581c side. In this embodiment, the same number of four third connection end portions 571d as the number of legs are integrally connected to the main body portion 571a. These four third connection end portions 571d are arranged so as to be separated from each other in the x direction between the first connection end portion 571b and the second connection end portion 571c. The four third connection ends 571d are welded to the tips of the terminals connected to the emitter electrodes of the low side switches 536 of each of the four phase legs.

<Second split bus bar and terminal block>
As described above, the second split bus bar 572 is fixed to the terminal block 590. Therefore, in the following, these second division bus bars 572 and the terminal block 590 will be described together with reference to FIGS. 4 to 6. In FIG. 5, the first bolt hole 574c, the second bolt hole 576c, and the support bolt hole 592c, which will be described later, are shown by broken lines. In FIG. 6, in addition to the second split bus bar 572 and the terminal block 590, the connection bolt 573, the fixing bolt 578, the connection bolt 579, the second connection end portion 571c, and the metal terminal 302a of the second power line 302, which will be described later, are shown. Shows.

The second split bus bar 572 extends in the x direction so as to be separated from the second connection end portion 571c. The second split bus bar 572 is connected to the first side wall 581a of the case 580 via a terminal block 590. The second split bus bar 572 has a lower surface located on the first side wall 581a side and an upper surface on the opposite side thereof.

As shown in FIG. 4, the second split bus bar 572 is bent at a plurality of places. Therefore, the upper surface and the lower surface of the second split bus bar 572 face different directions depending on the location. Explaining in detail with the bending portion as a boundary, the second split bus bar 572 has a connecting portion 574, an extending portion 575, a fixing portion 576, and a connecting portion 577.

The connecting portion 574 extends in the x direction. The upper surface and the lower surface of the connecting portion 574 face in the z direction. The connecting portion 574 has a thin flat plate shape between the upper surface and the lower surface in the z direction.

The extension portion 575 extends in the z direction. The upper surface and the lower surface of the extension portion 575 face in the x direction. The extension portion 575 has a thin flat plate shape between the upper surface and the lower surface in the x direction.

The fixing portion 576 extends in the x direction. The upper and lower surfaces of the fixed portion 576 face the z direction. The fixing portion 576 has a thin flat plate shape between the upper surface and the lower surface in the z direction.

The connection portion 577 extends in the z direction. The upper and lower surfaces of the connecting portion 577 face in the x direction. The connection portion 577 has a thin flat plate shape between the upper surface and the lower surface in the x direction.

The connecting portion 574 and the extension portion 575 are integrally connected. The creepage directions of the upper surface of the connecting portion 574 and the upper surface of the extension portion 575 are orthogonal to each other. The creeping directions of the lower surface of the connecting portion 574 and the lower surface of the extending portion 575 are orthogonal to each other. The angle between the upper surface of the connecting portion 574 and the upper surface of the extension portion 575 is 270 °. The angle between the lower surface of the connecting portion 574 and the lower surface of the extension portion 575 is 90 °.

The extension portion 575 and the fixing portion 576 are integrally connected. The creepage directions of the upper surface of the extension portion 575 and the upper surface of the fixed portion 576 are orthogonal to each other. The creeping directions of the lower surface of the extension portion 575 and the lower surface of the fixed portion 576 are orthogonal to each other. The angle between the upper surface of the extension portion 575 and the upper surface of the fixing portion 576 is 90 °. The angle between the lower surface of the extension portion 575 and the lower surface of the fixing portion 576 is 270 °.

The fixed portion 576 and the connecting portion 577 are integrally connected. The creepage directions of the upper surface of the fixed portion 576 and the upper surface of the connecting portion 577 are orthogonal to each other. The creeping directions of the lower surface of the fixed portion 576 and the lower surface of the connecting portion 577 are orthogonal to each other. The angle between the upper surface of the fixed portion 576 and the upper surface of the connecting portion 577 is 270 °. The angle between the lower surface of the fixing portion 576 and the lower surface of the connecting portion 577 is 90 °.

As shown above, the second split bus bar 572 extends in the x direction and also extends in the z direction. As shown in an exploded manner in FIG. 6, the second connection end portion 571c of the first split bus bar 571 is connected to the connecting portion 574. The fixing portion 576 is fixed to the terminal block 590. The metal terminal 302a of the second power line 302 is connected to the connection portion 577. The second power line 302 corresponds to the external connection portion.

As shown in FIG. 6, the connecting portion 574 is formed with a first bolt hole 574c that opens in the z direction. The first bolt hole 574c is open to the upper surface and the lower surface of the connecting portion 574.

A connecting nut 574d is connected to the lower surface of the connecting portion 574. The connecting nut 574d has a tubular shape that opens in the z direction. A thread groove is formed in the connecting nut 574d. The hollow of the connecting nut 574d and the hollow of the first bolt hole 574c communicate with each other in the z direction.

A connecting bolt hole 571e penetrating in the z direction is formed in the second connection end portion 571c of the first split bus bar 571. The second connection end portion 571c of the first split bus bar 571 is superposed on the upper surface of the connecting portion 574 of the second split bus bar 571. At this time, the connecting bolt hole 571e and the first bolt hole 574c are communicated with each other in the z direction.

In this way, with the second connection end portion 571c and the connecting portion 574 overlapping in the z direction, the tip of the shaft portion of the connecting bolt 573 is passed through the hollow of each of the connecting bolt hole 571e and the first bolt hole 574c. The tip of the shaft portion of the connecting bolt 573 that has passed through the hollow of these bolt holes is passed through the hollow of the connecting nut 574d. The tip of the shaft portion of the connecting bolt 573 is fastened to the thread groove of the connecting nut 574d. The second connecting end portion 571c and the connecting portion 574 are sandwiched between the head of the connecting bolt 573 and the connecting nut 574d. As a result, the first split bus bar 571 and the second split bus bar 572 are mechanically and electrically connected.

Needless to say, if the fastening condition between the connecting bolt 573 and the connecting nut 574d is loosened by an action such as an external force, a defect occurs in the mechanical and electrical connection between the first split bus bar 571 and the second split bus bar 572. There is a risk.

A second bolt hole 576c that opens in the z direction is formed in the fixing portion 576. The second bolt hole 576c is open to the upper surface and the lower surface of the fixing portion 576.

The fixing portion 576 (second split bus bar 572) is fixed to a terminal block 590 made of an insulating resin material. The terminal block 590 has a box portion 591 with one opening.

The box portion 591 has a flat bottom portion 593 having a thin thickness in the z direction and a side portion 594 extending in the z direction from the edge portion of the inner bottom surface 593a of the bottom portion 593. The side portion 594 forms an annular shape in the circumferential direction around the z direction. The opening of the box portion 591 is defined by the tip of the side portion 594.

The bottom portion 593 is formed with fixing bolt holes 593c that open in the inner bottom surface 593a and the outer bottom surface 593b on the back side thereof. A tubular fixing nut 593d that opens in the z direction is connected to the inner bottom surface 593a of the bottom portion 593. A thread groove is formed in the fixing nut 593d. The hollow of the fixing nut 593d and the hollow of the fixing bolt hole 593c communicate with each other in the z direction.

The fixing portion 576 is provided on the terminal block 590 in such a manner that the lower surface of the fixing portion 576 faces the outer bottom surface 593b of the bottom portion 593. At this time, the hollow of the second bolt hole 576c and the hollow of the fixing bolt hole 593c are communicated with each other in the z direction.

With the fixing portion 576 provided on the terminal block 590 in this way, the tip of the shaft portion of the fixing bolt 578 is passed through the hollow of each of the second bolt hole 576c and the fixing bolt hole 593c. The tip of the shaft portion of the fixing bolt 578 that has passed through the hollow of these bolt holes is passed through the hollow of the fixing nut 593d. The tip of the shaft portion of the fixing bolt 578 is fastened to the thread groove of the fixing nut 593d. The fixing portion 576 is sandwiched between the head portion and the bottom portion 593 of the fixing bolt 578. As a result, the fixing portion 576 (second split bus bar 572) is fixed to the terminal block 590.

In addition to the box portion 591 described above, the terminal block 590 has two flange portions 592 integrally connected to the side portion 594 of the box portion 591 as shown in FIGS. 4 and 5. These two flange portions 592 extend in the y direction from the side portions 594 in such a manner that they are separated from each other from the hollow of the box portion 591.

The two flange portions 592 each have two main surfaces facing in the z direction. As shown by the broken line in FIG. 5, each of the two flange portions 592 is formed with a support bolt hole 592c that opens in each of the two main surfaces. A fixing bolt hole 593c is located between the two support bolt holes 592c. Therefore, in a state where the second split bus bar 571 is fixed to the terminal block 590, the fixing bolt 578 is located between the two support bolt holes 592c. The two support bolt holes 592c are located between the first bolt hole 574c and the third bolt hole 577c described later in the x direction.

Although not shown, two bolt holes opening in the z direction are formed on the mounting surface of the terminal block 590 on the first side wall 581a of the case 580. A thread groove is formed in each of these two bolt holes. These two bolt holes are arranged so as to be separated from each other in the y direction. The distance between these two bolt holes in the y direction is the same as the distance between the support bolt holes 592c formed in each of the two flange portions 592 in the y direction.

The terminal block 590 is mounted on the first side wall 581a in such a manner that the support bolt hole 592c and the bolt hole formed in the first side wall 581a communicate with each other in the z direction. In this mounted state, the shaft portion of the support bolt 592d is passed through each of the two support bolt holes 592c. The tip of the shaft portion of the support bolt 592d that has passed through the support bolt hole 592c is passed through the bolt hole formed in the first side wall 581a. The tip of the shaft portion of the support bolt 592d is fastened to the bolt hole. The terminal block 590 is sandwiched between the head of the support bolt 592d and the first side wall 581a. As a result, the terminal block 590 is fixed to the case 580. As a result, the N bus bar 570 is fixed to the case 580 via the terminal block 590.

A third bolt hole 577c that opens in the x direction is formed in the connection portion 577. The third bolt hole 577c is open to the upper surface and the lower surface of the connecting portion 577.

As shown in FIG. 5, the first bolt hole 574c, the second bolt hole 576c, and the third bolt hole 577c each have a connecting portion 574, an extension portion 575, a fixing portion 576, and a connection portion constituting the second split bus bar 572, respectively. It is located on the center line CL passing through the center of each portion 577. The first bolt hole 574c, the second bolt hole 576c, and the third bolt hole 577c are arranged in the x direction and the z direction, respectively.

As described above, the fixing portion 576 of the second split bus bar 572 is fixed to the bottom portion 593 of the terminal block 590. In this fixed state, as shown in FIG. 6, the connecting portion 577 faces the side portion 594 of the terminal block 590 in the x direction.

A connection bolt hole 594c that opens in the x direction is formed in the side portion 594 facing the connection portion 577. The connection bolt holes 594c are open to the inner side surface 594a and the outer side surface 594b of the side portion 594. A tubular connection nut 594d that opens in the x direction is provided on the inner side surface 594a of the side portion 594. A thread groove is formed in the connection nut 594d. The hollow of the connection nut 594d and the hollow of the connection bolt hole 594c communicate with each other in the x direction.

The hollows of the third bolt hole 577c, the connection bolt hole 594c, and the connection nut 594d are communicated in the x direction with the lower surface of the connection portion 577 and the outer surface 594b of the side portion 594 facing each other in the x direction. .. One bolt hole is formed by each of the third bolt hole 577c, the connection bolt hole 594c, and the connection nut 594d.

The metal terminal 302a of the second power line 302 is formed with a bolt hole 302b corresponding to one bolt hole composed of the third bolt hole 577c, the connection bolt hole 594c, and the connection nut 594d. With these two bolt holes lined up in the x direction, the shaft portion of the connecting bolt 579 is passed through these two bolt holes. Then, the tip of the shaft portion of the connection bolt 579 is fastened to the connection nut 594d. As a result, the metal terminal 302a of the second power line 302 and the connection portion 577 are sandwiched between the head of the connection bolt 579 and the side portion 594 of the terminal block 590. As a result, the second power line 302 and the N bus bar 570 are mechanically and electrically connected. The power conversion unit 520 and the second power line 302 are mechanically and electrically connected.

The connection bolt hole 594c and the connection nut 594d of the terminal block 590 correspond to the fixed positions of the second power line 302 in the case 580 described above. The third bolt hole 577c of the connecting portion 577 corresponds to the connection position with the second power line 302 in the above-mentioned N bus bar 570.

<Action effect>
As described above, the third bolt hole 577c of the N bus bar 570, the connection bolt hole 594c of the terminal block 590, and the connection nut 594d are arranged in the x direction, and the hollows are communicated with each other in the x direction. Bolt holes are configured. This bolt hole serves as a mechanical and electrical connection portion with the second power line 302 in the power conversion unit 520.

However, when the dimensional variation of the length of the N bus bar 570 in the x direction becomes large due to the extension of the N bus bar 570 in the x direction, the third bolt hole 577c of the N bus bar 570 and the connection bolt hole 594c of the terminal block 590 become in the x direction. There is a risk of separation. As a result, there is a possibility that the communication condition between the third bolt hole 577c and the connection bolt hole 594c in the x direction may fluctuate. It may be difficult to connect the second power line 302 and the N bus bar 570.

On the other hand, the N bus bar 570 of the present embodiment is divided into two, a first split bus bar 571 and a second split bus bar 572. As a result, the extension of each of the first split bus bar 571 and the second split bus bar 572 is suppressed. The increase in dimensional variation in length due to the manufacturing error of each of the first split bus bar 571 and the second split bus bar 572 is suppressed. As a result, it is suppressed that the connection between the N bus bar 570 and the second power line 302 becomes difficult.

The second split bus bar 572 (N bus bar 570) is fixed to the case 580 via the terminal block 590.

According to this, when the case 580 vibrates due to an external force, the first split bus bar 571 and the second split bus bar 572 each tend to vibrate in the same phase as the case 580. Therefore, it is possible to prevent loosening of the connecting bolt 573 that mechanically and electrically connects the first split bus bar 571 and the second split bus bar 572. As a result, it is possible to prevent mechanical and electrical connection failures between the first split bus bar 571 and the second split bus bar 572.

In the second split bus bar 572, the connecting portion 574, the extending portion 575, the fixing portion 576, and the connecting portion 577 are integrally connected in this order. As a result, the second split bus bar 572 extends in the x-direction and the z-direction.

The connecting portion 574 is formed with a first bolt hole 574c into which a connecting bolt 573 for connecting to the first split bus bar 571 is inserted. The fixing portion 576 is formed with a second bolt hole 576c into which a fixing bolt 578 for fixing to the terminal block 590 is inserted. The connection portion 577 is formed with a third bolt hole 577c into which a connection bolt 579 for connecting to the metal terminal 302a of the second power line 302 is inserted.

According to the configuration shown above, the first bolt hole 574c, the second bolt hole 576c, and the third bolt hole 577c are arranged in the x direction, respectively. In the x direction, the second bolt hole 576c is located between the first bolt hole 574c and the third bolt hole 577c.

According to this, when an external force is applied to the connecting portion 577 in which the third bolt hole 577c is formed, the external force is applied to the second bolt hole 576c instead of the connecting bolt 573 inserted into the first bolt hole 574c. It becomes easy to be acted on by the fixing bolt 578 to be inserted. As a result, the action of stress on the connecting bolt 573 is suppressed. Therefore, it is possible to prevent mechanical and electrical connection failures between the first split bus bar 571 and the second split bus bar 572.

The external force applied to the connection portion 577 includes, for example, the stress when the connection bolt 579 inserted into the third bolt hole 577c is fastened to the connection nut 594d, the stress caused by the vibration of the vehicle, and the like. ..

The third bolt hole 577c opens in the x direction and extends in the x direction. The first bolt hole 574c and the second bolt hole 576c each open in the z direction and extend in the z direction. Therefore, the shaft portion of the connection bolt 579 inserted into the third bolt hole 577c extends in the x direction. The shafts of the connecting bolt 573 inserted into the first bolt hole 574c and the fixing bolt 578 inserted into the second bolt hole 576c extend in the z direction.

According to this, when the connecting bolt 579 is fastened to the connecting nut 594d via the third bolt hole 577c, a rotational moment around the x direction acts on the connecting nut 594d. In response to this, the terminal block 590 tries to rotate in the x direction. However, this rotation around the x direction is suppressed by the fixing bolt 578 that connects the terminal block 590 and the second split bus bar 572. As a result, stress is suppressed from acting on the connecting bolt 573 connecting the first split bus bar 571 and the second split bus bar 572. It is possible to prevent mechanical and electrical connection failures between the first split bus bar 571 and the second split bus bar 572.

The terminal block 590 is formed with two support bolt holes 592c for fixing the terminal block 590 to the case 580 by the support bolts 592d. The two support bolt holes 592c are located between the first bolt hole 574c and the third bolt hole 577c in the x direction.

According to this, when an external force is applied to the connection portion 577, the action of the external force on the connecting bolt 573 is suppressed not only by the fixing bolt 578 but also by the support bolt 592d inserted into the support bolt hole 592c. .. Therefore, it is more effectively suppressed that mechanical and electrical connection defects occur between the first split bus bar 571 and the second split bus bar 572.

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.

(First modification)
In this embodiment, the separation distance between the first bolt hole 574c and the second bolt hole 576c and the separation distance between the second bolt hole 576c and the third bolt hole 577c are not particularly mentioned. However, as shown in FIG. 6, for example, the distance L2 between the second bolt hole 576c and the third bolt hole 577c is shorter than the distance L1 between the first bolt hole 574c and the second bolt hole 576c. preferable.

According to this, the action of the rotational moment around the x direction generated when the connecting bolt 579 is fastened to the connecting nut 594d on the connecting bolt 573 is the fixing bolt 578 as compared with the configuration in which the separation distance L2 is longer than the separation distance L1. Is suppressed more effectively by.

It should be noted that the above-mentioned action and effect are not related to the length of the separation distances L1 and L2, but simply increase as the separation distance L2 becomes shorter. In FIG. 6, the separation distance L1 is the sum of half the length of the connecting portion 574 in the x direction, the thickness of the extending portion 575 in the x direction, and half the length of the fixed portion 576 in the x direction. The separation distance L2 is the sum of half the length of the fixed portion 576 in the x direction and half the thickness of the connecting portion 577 in the x direction.

(Second modification)
In this embodiment, an example in which the N bus bar 570 has a first split bus bar 571 connected to each of the second smoothing capacitor 540 and the switch module 530, and a second split bus bar 572 connected to the second power line 302. Indicated.

However, the N bus bar 570 may include at least one third split bus bar in addition to the first split bus bar 571 and the second split bus bar 572. In this case, the N bus bar 570 is divided into at least three split bus bars.

(Third modification example)
In this embodiment, as shown in FIG. 6, a fixing bolt hole 593c is formed in the bottom portion 593, and a fixing nut 593d is connected to the inner bottom surface 593a of the bottom portion 593. However, for example, as shown in FIG. 7, the fixing nut 593d may be opened to the outer bottom surface 593b of the bottom portion 593, and the fixing nut 593d may be integrally connected to the bottom portion 593.

(Fourth modification)
In the present embodiment, as shown in FIG. 6, an example is shown in which a connection bolt hole 594c is formed in a portion of the side portion 594 facing the connection portion 577, and a connection nut 594d is connected to the inner side surface 594a of the side portion 594. However, for example, as shown in FIG. 7, the connection nut 594d may be opened to the outer surface 594b of the side portion 594, and the connection nut 594d may be integrally connected to the side portion 594.

In the case of this modification, a part of the hollow of the connection nut 594d constitutes the connection bolt hole 594c. With the lower surface of the connecting portion 577 and the outer surface 594b of the side portion 594 facing each other in the x direction, the hollows of the third bolt hole 577c and the connecting nut 594d are communicated with each other in the x direction. One bolt hole is formed by each of the third bolt hole 577c and the connecting nut 594d.

(Fifth variant)
In the present embodiment, the high-side switch 535 and the low-side switch 536 provided by each of the A-phase legs 531 to the D-phase leg 534, and the high-side diode 535a and the low-side diode 536a are resin-sealed to form one package. Indicated. An example is shown in which two switches and two diodes provided in a one-phase leg are resin-sealed to form one package.

However, unlike this, for example, the high-side switch 535 and the high-side diode 535a may be resin-sealed to form one package. The low-side switch 536 and the low-side diode 536a may be resin-sealed to form one package. The configuration of the package is not particularly limited.

(Other variants)
In this embodiment, an example is shown in which the power conversion unit 520 includes a part of the components of the converter 500. However, it is also possible to adopt a configuration in which the power conversion unit 520 includes all the components of the converter 500. Further, it is also possible to adopt a configuration in which the power conversion unit 520 includes at least a part of the components of the inverter 600.

In this embodiment, an example is shown in which the power conversion unit 520 is included in the in-vehicle system 100 for an electric vehicle. However, the application of the power conversion unit 520 is not particularly limited to the above example. For example, a configuration in which a power conversion unit 520 is included in a hybrid system including a motor and an internal combustion engine can be adopted.

In this embodiment, the configuration in which the power conversion device 300 is connected to one motor 400 is shown. However, it is also possible to adopt a configuration in which the power conversion device 300 is connected to the two motors 400. In this case, the power conversion device 300 includes two inverters 600.

100 ... In-vehicle system, 200 ... Battery, 300 ... Power converter, 302 ... Second power line, 400 ... Motor, 500 ... Converter, 510 ... Reactor, 520 ... Power conversion unit, 530 ... Switch module, 513 ... A-phase leg 532 ... B-phase leg, 533 ... C-phase leg, 534 ... D-phase leg, 537 ... Cooler, 570 ... N bus bar, 571 ... 1st split bus bar, 572 ... 2nd split bus bar, 573 ... connecting bolt, 574c ... 1st bolt hole, 576c ... 2nd bolt hole, 757c ... 3rd bolt hole, 578 ... fixing bolt, 579 ... connection bolt, 580 ... case, 590 ... terminal block, 592c ... support bolt hole, 592d ... support bolt, 594c … Connection bolt hole, 600… Inverter

Claims (4)

A switch unit (530) including a plurality of switches (531 to 534) arranged apart from each other in the arrangement direction, and a holding unit (537) for holding the plurality of the switches.
A conductive portion (570) having a plurality of divided bus bars (571, 572) connected to each other in a manner extending in the alignment direction, and a conductive portion (570).
An insulating terminal block (590) to which the conductive portion is fixed, and
It has a switch unit and a housing (580) that supports each of the terminal blocks to which the conductive portion is fixed .
The switch is connected to the split bus bar (571) located at one of the two ends of the plurality of split bus bars connected to each other, and the other of the two ends of the plurality of split bus bars. The external connection portion (302) is connected to the split bus bar (572) located in.
A plurality of the split bus bars are connected by at least one connecting bolt (573).
The terminal block is connected to the housing,
In the split bus bar located at the other of the two ends of the plurality of split bus bars, a first bolt hole (574c) into which the connecting bolt is inserted and the conductive portion are fixed to the terminal block. The second bolt hole (576c) into which the fixing bolt (578) is inserted, and the third bolt hole (577c) into which the connection bolt (579) for connecting the conductive portion and the external connection portion is inserted. Is formed,
A connection bolt hole (594c) into which the shaft portion of the connection bolt is inserted through the third bolt hole is formed in the terminal block.
A power conversion unit in which the second bolt hole is located between the first bolt hole and the third bolt hole in the alignment direction . The power conversion unit according to claim 1 , wherein the third bolt hole extends in the alignment direction, and the first bolt hole and the second bolt hole extend in an intersecting direction intersecting the alignment direction. A support bolt hole (592c) for fixing the terminal block to the housing is formed in the terminal block by a support bolt (592d).
The power conversion unit according to claim 1 or 2 , wherein the support bolt holes are located between the first bolt holes and the third bolt holes in the alignment direction. The electric power according to any one of claims 1 to 3 , wherein the separation distance between the second bolt hole and the third bolt hole is shorter than the separation distance between the first bolt hole and the second bolt hole. Conversion unit.

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