JP5655321B2 - Power converter - Google Patents

Description

  The present invention relates to a power conversion device that is connected between a DC power source and an AC load and converts power between the two.

For example, electric vehicles and hybrid vehicles are equipped with a power converter (inverter) that is connected between a DC power source (on-vehicle battery) and an AC load (three-phase AC rotating electrical machine) and converts the power between the two. Has been.
As shown in FIG. 16, the power converter 9 includes a case 92 in which components such as a semiconductor module and a capacitor including a switching element that configures a power conversion circuit are built (see Patent Document 1). A pair of power supply terminals 93 for connection to the DC power supply and a plurality (three) of load terminals 94 for connection to the AC load are arranged.

  A connector terminal 96 electrically connected to a pair of electrodes of a DC power supply is inserted into the power supply terminal 93 from the outside of the case 92 and connected thereto. In addition, a bus bar terminal 97 of a bus bar electrically connected to the U-phase, V-phase, and W-phase electrodes in an AC load is inserted into and connected to the load terminal 94 from the outside of the case 92.

The power supply terminal 93 and the connector terminal 96, and the load terminal 94 and the bus bar terminal 97 are fastened to each other by bolts (see FIGS. 3, 10, and 11).
In order to fasten the bolt, the case 92 is formed with an opening 921 that opens toward the bolt fastening portion, that is, toward the power supply terminal 93 and the load terminal 94. That is, in the case 92, the power supply terminal 93 and the connector terminal 96, and the load terminal 94 and the bus bar terminal 97 are overlapped, and then a bolt is connected from the opening 92 to the overlapping portion of these terminals. And tighten with a fastening tool.

  A cover that covers the opening 921 is attached to the opening 921 provided in the case 92 after tightening the bolt, and a sealant is interposed between the cover and the case 92 to be waterproof (FIG. 6, (Refer to FIGS. 10-12). Therefore, the case 92 is formed with a seal surface 922 around the entire outer periphery of the opening 921, and a plurality of screw holes 923 are provided outside the case 92, and the cover is fastened with screws in the screw holes 923.

JP 2007-174759 A

However, as described above, the formation of the sealing surface 922 around the entire periphery of the opening 921 and the formation of a plurality of screw holes 923 outside the opening 921 are not limited to the space for the opening 921 in the case 92. A space for forming the seal surface 922 and the screw hole 923 around the periphery is also required. Therefore, the case 92 is increased in size, and the power conversion device 9 may be prevented from being reduced in size.
On the other hand, if the screw hole 923 is to be formed at a position close to the opening 921 in order to prevent the case 92 from becoming large, the space between the screw hole 923 and the opening 921 becomes narrow, and the seal surface 922 provided at that portion. The width of will become smaller. As a result, there arises a problem that the water tightness of the case 92 is lowered.

  The present invention has been made in view of such problems, and an object of the present invention is to provide a power conversion device that facilitates downsizing while ensuring water tightness of a case.

One aspect of the present invention is a power converter that is connected between a DC power source and an AC load and converts power between the two.
The power conversion device has a pair of power supply terminals for connecting to the DC power source and a plurality of load terminals for connecting to the AC load inside a case constituting the outer shell,
The case has a communication opening portion that opens toward the pair of power terminals and the plurality of load pin,
A sealing surface that is formed over the entire circumference of the communication opening, and in which a sealing material disposed between the cover and the cover that covers the communication opening is in close contact;
A plurality of screw holes formed on the outside of the sealing surface for screwing screws for fastening the cover to the case;
An inward portion in which a part of the outline of the communication opening projects outwardly is formed inside at least one of the plurality of screw holes,
A part of the sealing surface is formed on the inward portion,
Bolt insertion holes are respectively formed in the power supply terminal and the load terminal,
When viewed from the opening direction of the communication opening, at least one of the inward portions is between a power supply terminal group including the pair of power supply terminals and a load terminal group including the plurality of load terminals. And, a part of the outline of the communication opening is an inward group between the groups formed by projecting inward,
In the power converter, the screw hole is formed outside the inward portion between the groups (claim 1) .

  In the power conversion device, an inward portion in which a part of the outline of the communication opening protrudes inward is formed inside at least one screw hole in the case. A part of the sealing surface is formed on the inward portion. Therefore, the screw hole provided outside the inward portion can be brought close to the communication opening. That is, even if the screw hole is brought close to the communication opening, the seal surface can be formed with a sufficient width between the screw hole and the communication opening.

Therefore, it is not necessary to provide a space for forming a screw hole in a wide range on the outer periphery of the communication opening. As a result, the case can be easily downsized.
Thus, according to the present invention, it is possible to easily reduce the size of the case while enabling the formation of a sufficiently wide sealing surface over the entire circumference of the communication opening. Thereby, size reduction of a power converter device can be made easy, ensuring the watertightness of a case.

  As described above, according to the present invention, it is possible to provide a power conversion device that facilitates miniaturization while ensuring water tightness of a case.

The top view of the power converter device in Example 1. FIG. The top view of the power converter device, a connector, and bus-bar assembly in Example 1. FIG. The top view of the power converter device which connected the connector and bus-bar assembly in Example 1. FIG. The side view of the power converter device in Example 1. FIG. The perspective view of the power converter device in Example 1. FIG. The side view of the power converter device which connected the connector and bus-bar assembly in Example 1. FIG. FIG. 4 is a partial cross-sectional enlarged view corresponding to a cross section taken along line AA in FIG. 3. FIG. 4 is a partial cross-sectional enlarged view corresponding to a cross section taken along line B-B in FIG. 3. FIG. 4 is an enlarged partial cross-sectional view corresponding to a cross-section taken along line CC in FIG. 3. The partial cross-section enlarged view of the state which attached the cover equivalent to the AA arrow cross section of FIG. The partial cross-section enlarged view of the state which attached the cover equivalent to the BB arrow cross section of FIG. The partial cross-section enlarged view of the state which attached the cover equivalent to the CC arrow directional cross section of FIG. The top view of a power converter device when a group inward part is made to oppose. The top view of the power converter device in Example 2. FIG. The top view of the power converter device in Example 3. FIG. The top view of the power converter device in background art.

In one aspect of the present invention, examples of the AC load include a three-phase AC rotating electric machine.
Further, the communication opening portion opens toward the pair of power supply terminals and the plurality of load terminals, and at least one of the inward portions is viewed from an opening direction of the communication opening portion. , a power supply terminal group composed of the pair of power supply terminals, Ru intergroup inward portion der formed toward between the load terminal group composed of a plurality of load terminals.
Thereby, the said inward part (inter-group inward part) can be formed with sufficient distance from the said power supply terminal and the said load terminal. In other words, since a relatively large gap is easily formed between the power supply terminal group and the load terminal group than between the power supply terminals and between the load terminals, an inward portion is formed toward this portion. However, a sufficient distance can be maintained between the inward portion and the power supply terminal or the load terminal.

  Therefore, when fastening the power supply terminal and the load terminal with the connection terminal electrically connected to the DC power supply and the AC load, the bolt and the fastening tool are placed on the inward portion (inward portion between the groups). It becomes difficult to interfere. As a result, the inward portion can be formed effectively without hindering the fastening operation.

In addition, it is preferable that at least a pair of the inward portions between the groups is formed at positions facing each other in the communication opening (claim 2 ).
In this case, the screw hole formed outside the pair of inward portions can be formed close to the communication opening. Therefore, the case can be further reduced in size, and the power converter can be further reduced in size.

Further, at least one of the inward portions is a group inward portion formed toward the power supply terminal group or the load terminal group when viewed from the opening direction of the communication opening portion, and the inward direction of the group It is preferable that the inward portion is not formed at a position facing the portion (claim 3 ).
In this case, at the time of fastening of a fastening member such as a bolt at the power supply terminal or the load terminal, it is possible to reduce the size of the power conversion device while suppressing the fastening member or the fastening tool from interfering with the inward portion. Can be easily.

That is, by forming the group inward portion, the case can be easily reduced in size, but if a pair of group inward portions are provided at positions facing each other, the space between the two becomes too small. The opening space of the communication opening around the power supply terminal or the load terminal is reduced. As a result, the fastening member or the fastening tool tends to interfere with the inward portion, and the fastening operation may be difficult.
Therefore, by not providing the inward portion at the position facing the inward portion in the group, the opening space of the communication opening portion around the power supply terminal or the load terminal is secured and the fastening operation is facilitated. Can do.

The upper SL power converter is connected to a plurality of the AC load, the plurality of load terminals, connection destination constitutes a plurality of load terminals which differ from the AC load, the communicating opening Are open toward the plurality of load terminal groups, and at least one of the inward portions faces between two adjacent load terminal groups when viewed from the opening direction of the communication opening. group between inward portion der formed Te Ru.
Thereby, the said inward part (inter-group inward part) can be formed with sufficient distance from the said load terminal. That is, between the load terminal groups, since a relatively large interval is more easily formed than between the load terminals in the same load terminal group, even if the inward portion is formed toward this portion, A sufficient distance can be maintained between the inward portion and the load terminal.
Therefore, when fastening the load terminal and the connection terminal electrically connected to the AC load, a fastening member such as a bolt or a fastening tool is less likely to interfere with the inward portion (inward portion between groups). . As a result, the inward portion can be formed effectively without hindering the fastening operation.

Further, the group inter-inward portion is not preferable that the have at least a pair formed so as to be opposite to each other in the communicating opening.
In this case, it is possible to further facilitate miniaturization of the to case, it is possible to further miniaturization of the power converter.

Further, at least one of the inward portions is a group inward portion formed toward the load terminal group when viewed from the opening direction of the communication opening portion, and at a position facing the inward portion of the group. it is not preferable that the inward portion is not formed.
In this case, at the time of bolting of the upper Symbol power terminal or the load terminals, while preventing the bolt or fastening tool interferes with the inward portion, to facilitate the miniaturization of the power converter it can.

Example 1
A power converter according to an embodiment of the present invention will be described with reference to FIGS.
The power conversion device 1 of this example is connected between a DC power supply and an AC load, and converts power between the two.
As shown in FIG. 1, the power conversion device 1 includes a pair of power supply terminals 3 for connection to a DC power supply and a plurality of load terminals 4 for connection to an AC load in a case 2 constituting an outer shell. And have.

The case 2 has a communication opening 21 that opens toward the power supply terminal 3 and the load terminal 4. And the sealing surface 22 with which the sealing material 52 (FIG. 6) arrange | positioned between the covers 51 which cover the communication opening 21 is closely_contact | adhered is formed over the perimeter of the communication opening 21. As shown in FIG.
A plurality of screw holes 23 for screwing screws 53 for fastening the cover 51 to the case 2 are formed outside the seal surface 22.
An inward portion 24 in which a part of the outline of the communication opening 21 projects inward is formed inside at least one of the plurality of screw holes 23.
A part of the seal surface 22 is formed on the inward portion 24.

  In FIG. 1, a broken line denoted by reference numeral 221 represents a part of the outer edge of the seal surface 22, but this is a virtual line and does not appear on the outer shape. However, the sealing material 52 is not in contact with the outer side of the outer edge 221, and the outer side of the outer edge 221 is not the sealing surface 22. That is, the screw hole 23 exists outside the outer edge 221 of the seal surface 22.

In this example, three inward portions 24 are formed, and two of them are a plurality of power terminal groups 30 including a pair of power terminals 3 when viewed from the opening direction of the communication opening portion 21. The inter-group inward portion 241 is formed between the load terminal group 40 including the load terminals 4. A pair of inward groups 241 is formed at positions facing each other in the communication opening 21.
The other inward portion 24 is a group inward portion 242 formed toward the load terminal group 40 when viewed from the opening direction. The inward portion 24 is not formed at a position facing the group inward portion 242.

The two power supply terminals 3 and the three load terminals 4 are arranged in a line in a substantially straight line when viewed from the opening direction of the communication opening 21. A communication opening 21 having an approximately long hole shape as a whole is formed so as to surround all of these five terminals.
The distance between the adjacent power supply terminals 3 and the load terminals 4 is larger than both the distance between the pair of power supply terminals 3 and the distance between the adjacent load terminals 4. That is, a relatively wide gap is provided between the power supply terminal group 30 and the load terminal group 40, and a pair of inter-group inward portions 241 are formed toward the gap.
The group inward portion 242 is formed between the two adjacent load terminals 4 in the load terminal group 40.

  By forming these three inward portions 24 (two inter-group inward portions 241 and one in-group inward portion 242), the communication opening 21 has a long constriction and a large constriction constricted from both sides. It has the part 211 and the small constriction part 212 which was constricted from one side. The constricted portion 211 has such a width that the bolt 11 cannot pass therethrough.

The screw holes 23 are formed with a certain distance from the communication opening 21. One screw hole 23 is formed outside each of the three inward portions 24. In addition to these, a plurality of screw holes 23 are formed on the outer periphery of the communication opening 21.
A flat sealing surface 22 is formed between all the screw holes 23 and the communication opening 21. The seal surface 22 is formed so that the width in the direction orthogonal to the outline of the communication opening 21 is a certain value or more.

  Further, as shown in FIGS. 4 to 9, the case 2 is formed so that the entire outer periphery of the communication opening 21 is thicker than the other parts, and protrudes outward from the case 2. And the seal surface 22 and the screw hole 23 are formed in this part.

The power conversion device 1 of this example is mounted on, for example, an electric vehicle or a hybrid vehicle, and is connected between a DC power source (on-vehicle battery) and an AC load (three-phase AC rotating electric machine). Convert.
The power conversion device 1 includes components such as a semiconductor module and a capacitor that incorporate a switching element constituting a power conversion circuit inside a case 2 made of aluminum or an alloy thereof. A pair of power supply terminals 3 and three load terminals 4 are arranged in the case 2 as input / output terminals in the power conversion circuit.

As shown in FIGS. 2 and 3, a connector terminal 6 that is electrically connected to a pair of electrodes of a DC power supply is inserted and connected to the power supply terminal 3 from the outside of the case 2. The bus terminal 7 electrically connected to the U-phase, V-phase, and W-phase electrodes in the AC load is inserted into the load terminal 4 from the outside of the case 2 and connected thereto.
A pair of connector terminals 6 are held in a resin casing to constitute a connector 60. The three bus bar terminals 7 also constitute a bus bar assembly 70 integrated with resin.

  As shown in FIGS. 4 and 5, the connector terminal 6 in the connector 60 and the three bus bar terminals 7 in the bus bar assembly 70 are formed on a surface substantially orthogonal to the surface in the case 2 where the communication opening 21 is formed. The terminal insertion holes 251 and 252 are inserted into the case 2 respectively.

As shown in FIG. 3, the power supply terminal 3 and the connector terminal 6, and the load terminal 4 and the bus bar terminal 7 are fastened to each other by bolts 11.
In order to fasten the bolt 11, the communication opening 21 is formed in the case 2 so as to open toward the bolt fastening portion, that is, toward the power supply terminal 3 and the load terminal 4. That is, as shown in FIGS. 7 and 8, the power terminal 3 and the connector terminal 6, and the load terminal 4 and the bus bar terminal 7 are overlapped in the case 2, and then the bolt 11 is inserted from the communication opening 21. Insert into the overlapping part of these terminals and fasten with a fastening tool.

As shown in FIG. 7, the connector 60 includes a terminal block 61 that supports the connector terminal 6 from one surface, and a female screw portion 62 is formed on the terminal block 61. As shown in FIG. 2, bolt insertion holes 301 and 601 are formed in the power supply terminal 3 and the connector terminal 6, respectively.
When fastening the power supply terminal 3 and the connector terminal 6, as shown in FIG. 7, the power supply terminal 3 and the connector terminal 6 are overlapped, and the bolt 11 is connected to the bolt insertion hole 301 of the power supply terminal 3. It penetrates through the bolt insertion hole 601 of the connector terminal 6 and is screwed into the female screw portion 62 in the terminal block 61. Thus, the power terminal 3 and the connector terminal 6 are fastened and connected on the terminal block 61 by the bolt 11.

As shown in FIG. 8, the load terminal 4 is supported from one surface by a terminal block 41 disposed in the case 2. A female screw part 42 is also formed on the terminal block 41. As shown in FIG. 2, bolt insertion holes 401 and 701 are formed in the load terminal 4 and the bus bar terminal 7, respectively.
When the load terminal 4 and the bus bar terminal 7 are fastened, as shown in FIG. 8, the load terminal 4 and the bus bar terminal 7 are overlapped, and the bolt 11 is connected to the bolt insertion hole 701 of the bus bar terminal 7 and the load. While passing through the bolt insertion hole 401 of the terminal 4, the terminal 4 is screwed into the female screw portion 42. Thus, the load terminal 4 and the bus bar terminal 7 are fastened and connected on the terminal block 41 by the bolt 11.

As shown in FIG. 3, after a pair of power supply terminals 3 and a pair of connector terminals 6 are fastened and three load terminals 4 and three bus bar terminals 7 are fastened, respectively, FIG. As shown in FIG. 12, a cover 51 is attached to the communication opening 21 to close the communication opening 21.
A seal material 52 is attached to the cover 51 at a position facing the seal surface 22 formed on the case 2. In attaching the cover 51 to the communication opening 21, the cover 51 is fastened to the case 2 by the bolt 53 while the sealing material 52 is pressed against the sealing surface 22. At this time, the bolt 53 is screwed into the screw hole 23 provided in the case 2.

  7 and 8, when the communication opening 21 is directed upward, the bolt 11 falls below the communication opening 21 and above the power supply terminal 3 and the load terminal 4. A fall prevention wall 43 for preventing the above is provided. The fall prevention wall 43 is formed so as to surround the power supply terminal group 30 and a part of the periphery of the load terminal group 40 when viewed from the opening direction of the communication opening 21. The fall prevention wall 43 is formed integrally with the terminal block 41 of the load terminal 4.

  And the fall prevention space 12 which prevents the fall of the volt | bolt 11 is formed between the fall prevention wall 43, the terminal blocks 41 and 61, and the inner wall 213 of the communication opening part 21. As shown in FIG. That is, the bolt 11 is configured to remain in the fall prevention space 12 when the bolt 11 falls around the power supply terminal 3 and the load terminal 4 during the fastening operation of the bolt 11.

Next, the effects of the present invention will be described.
In the power conversion device 1, as shown in FIG. 1, an inward portion 24 in which a part of the outline of the communication opening 21 protrudes inward is formed inside at least one screw hole 23 in the case 2. ing. A part of the seal surface 22 is formed on the inward portion 24. Therefore, the screw hole 23 provided on the outside of the inward portion 24 can be brought close to the communication opening 21. That is, even if the screw hole 23 is brought close to the communication opening 21, the seal surface 22 can be formed with a sufficient width between the screw hole 23 and the communication opening 21.

Therefore, it is not necessary to provide a space for forming the screw hole 23 in a wide range on the outer periphery of the communication opening 21. As a result, the case 2 can be easily downsized.
As described above, according to this example, it is possible to easily reduce the size of the case 2 while enabling the formation of the sealing surface 22 having a sufficient width over the entire circumference of the communication opening 21. Thereby, size reduction of the power converter device 1 can be made easy, ensuring the watertightness of the case 2. FIG.

Further, at least one of the inward portions 24 is an inter-group inward portion 241 that is formed between the power supply terminal group 30 and the load terminal group 40 when viewed from the opening direction of the communication opening 21. . Thereby, the inward portion 24 (inter-group inward portion 241) can be formed with a sufficient distance from the power supply terminal 3 and the load terminal 4. That is, since a relatively large gap is easily formed between the power supply terminal group 30 and the load terminal group 40 than between the power supply terminals 3 and between the load terminals 4, the inwardly directed toward this portion. Even if the portion 24 is formed, a sufficient distance can be maintained between the inward portion 24 and the power supply terminal 3 or the load terminal 4.
Therefore, when the power terminal 3 and the load terminal 4 are fastened to the connector terminal 6 and the bus bar terminal 7, the bolt 11 and the fastening tool are less likely to interfere with the inward portion 24 (the inter-group inward portion 241). As a result, the inward portion 24 can be formed effectively without hindering the fastening operation.

  Further, a pair of inward groups 241 is formed at positions facing each other in the communication opening 21. Thereby, the screw hole 23 formed outside the pair of inward portions 24 can be formed close to the communication opening 21. Therefore, the case 2 can be further reduced in size, and the power conversion device 1 can be further reduced in size.

  Further, at least one of the inward portions 24 is a group inward portion 242 formed toward the load terminal group 40 when viewed from the opening direction, and the position facing the group inward portion 242 has an inward direction. The part 24 is not formed. Thereby, at the time of fastening of the bolt 11 at the power terminal 3 or the load terminal 4, it is possible to easily reduce the size of the power converter 1 while suppressing the bolt 11 and the fastening tool from interfering with the inward portion 24. Can do.

That is, by forming the group inward portion 242, the case 2 can be easily reduced in size. However, as shown in FIG. 13, if a pair of group inward portions 242 are provided at positions facing each other, as shown in FIG. 13. The space 210 between them becomes too small, and the opening space of the communication opening 21 around the load terminal 4 becomes small. As a result, the bolt 11 and the fastening tool are likely to interfere with the inward portion 24, and the fastening work may be difficult.
Therefore, as shown in FIG. 1, by not providing the inward portion 24 at a position opposite to the inward portion 242 in the group, the opening space of the communication opening portion 21 around the load terminal 4 is secured and fastened. Work can be facilitated.

  As described above, according to this example, it is possible to provide a power conversion device that facilitates downsizing while ensuring water tightness of the case.

(Example 2)
In this example, as shown in FIG. 14, in the power conversion device 1 having two load terminal groups 40, the case 2 is provided with a communication opening 21 that opens toward the two load terminal groups 40. is there.

That is, the power conversion device 1 of this example is connected to two AC loads, and the plurality of load terminals 4 constitutes two load terminal groups 40 whose connection destinations are different for each AC load. A total of six load terminals 4 constituting each of the two load terminal groups 40 are arranged in a line in a substantially straight line when viewed from the opening direction of the communication opening 21. A communication opening 21 having a generally long hole shape as a whole is formed so as to surround all of these six terminals.
As in the first embodiment, the sealing surface 22 and a plurality of screw holes 23 are formed around the communication opening 21, and an inward portion 24 is formed inside some of the screw holes 23. ing.

In this example, the inward portion 24 is an inter-group inward portion 241 formed between two adjacent load terminal groups 40 when viewed from the opening direction of the communication opening 21. A pair of inward groups 241 is formed at positions facing each other in the communication opening 21.
In this example, as in the first embodiment (FIG. 1), the group inward portion 242 facing the load terminal group 40 when viewed from the opening direction can be formed.
Others are the same as in the first embodiment.

In the case of this example, the inward portion 24 (inter-group inward portion 241) can be formed with a sufficient distance from the load terminal 4. That is, since a relatively large space is easily formed between the load terminal groups 40 than between the load terminals 4 in the same load terminal group 40, the inward portion 24 is formed toward this portion. Even so, a sufficient distance can be maintained between the inward portion 24 and the load terminal 4.
Therefore, when the load terminal 4 and the bus bar terminal 7 are fastened, the bolt 11 and the fastening tool are less likely to interfere with the inward portion 24 (intergroup inward portion 241) (see FIGS. 2 and 3). As a result, the inward portion 24 can be formed effectively without hindering the fastening operation.
In addition, the same effects as those of the first embodiment are obtained.

Example 3
In this example, as shown in FIG. 15, in the power converter 1 having two load terminal groups 40, the two load terminal groups 40 and the power supply terminal group 30 arranged adjacent to the load terminal groups 40. This is an example in which the case 2 is provided with a communication opening 21 that opens toward the top.

Similarly to the second embodiment, the power conversion device 1 of this example is connected to two AC loads, and the plurality of load terminals 4 include two load terminal groups 40 whose connection destinations are different for each AC load. It is composed. A total of six load terminals 4 constituting each of the two load terminal groups 40 and two power supply terminals 3 constituting the power supply terminal group 30 are viewed from the opening direction of the communication opening 21. When arranged in a line in a substantially straight line. A communication opening 21 having a substantially long hole shape as a whole is formed so as to surround all of these eight terminals.
As in the first embodiment, the sealing surface 22 and a plurality of screw holes 23 are formed around the communication opening 21, and an inward portion 24 is formed inside some of the screw holes 23. ing.

Also in this example, all the inward portions 24 are intergroup inward portions 241. And when viewed from the opening direction of the communication opening 21, the pair of inwardly directed portions 241 is formed between two adjacent load terminal groups 40, and the other pair is a load terminal. It is formed between the group 40 and the power supply terminal group 30.
In addition, the two pairs of inward portions 241 between the groups are formed at positions facing each other in the communication opening 21.

Also in this example, as in the first embodiment (FIG. 1), the group inward portion 242 facing the load terminal group 40 when viewed from the opening direction of the communication opening portion 21 can be formed.
Others are the same as in the first embodiment.
Also in the case of this example, the same operational effects as those of the first embodiment can be obtained.

  In the first to third embodiments, as seen from the opening direction of the communication opening 21, the power supply terminal group 30 as in the group inward portion (see reference numeral 242 in FIG. 1) facing the load terminal group 40. It is also possible to provide a group inward portion formed toward the surface. Also in this case, the inward portion 24 is not provided at a position facing the group inward portion.

DESCRIPTION OF SYMBOLS 1 Power converter 2 Case 21 Communication opening part 22 Sealing surface 23 Screw hole 24 Inward part 241 Inward part between groups 242 Group inward part 3 Power supply terminal 30 Power supply terminal group 4 Load terminal 40 Load terminal group 6 Connector terminal 7 Busbar terminal

Claims (3)

In a power conversion device that is connected between a DC power source and an AC load and converts power between the two,
The power conversion device has a pair of power supply terminals for connecting to the DC power source and a plurality of load terminals for connecting to the AC load inside a case constituting the outer shell,
The case has a communication opening portion that opens toward the pair of power terminals and the plurality of load pin,
A sealing surface that is formed over the entire circumference of the communication opening, and in which a sealing material disposed between the cover and the cover that covers the communication opening is in close contact;
A plurality of screw holes formed on the outside of the sealing surface for screwing screws for fastening the cover to the case;
An inward portion in which a part of the outline of the communication opening projects outwardly is formed inside at least one of the plurality of screw holes,
A part of the sealing surface is formed on the inward portion,
Bolt insertion holes are respectively formed in the power supply terminal and the load terminal ,
At least one of the upper Symbol inward portion, when viewed from the opening direction of the communication opening portion, and a power supply terminal group composed of the pair of power supply terminals, the load terminal group composed of a plurality of load terminals A part of the outline of the communication opening is formed inwardly extending between the groups,
The power conversion device, wherein the screw hole is formed outside the inward portion between the groups.   2. The power conversion device according to claim 1, wherein at least one pair of the inward groups is formed at positions facing each other in the communication opening. 3. The power conversion device according to claim 1, wherein at least one of the inward portions is formed toward the power supply terminal group or the load terminal group when viewed from an opening direction of the communication opening. A power conversion device, wherein the inward portion is not formed at a position that is an inward portion of the group and faces the inward portion of the group.

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