JP2015002592A - Power conversion device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power conversion device capable of suppressing occurrence of a short circuit in a power terminal of a semiconductor module even when a refrigerant leaks.SOLUTION: A power conversion device 1 comprises a semiconductor module 10 in which a plurality of power terminals 12 (12a, 12b, 12c) extend from a body part 11 with a built-in semiconductor element 11a and a cooler 20 which cools the semiconductor module 10. The plurality of power terminals 12 (12a, 12b, 12c) extend to a lower side in a gravity direction Z. The cooler 20 includes a refrigerant flow passage 25 in which a refrigerant R circulates inside, and also includes a protrusion 26 protruding along the extension direction Z of the plurality of power terminals 12 (12a, 12b, 12c).

Description

  The present invention relates to a power conversion device.

  Power conversion devices such as inverters and converters are used in electric vehicles and hybrid vehicles. Among electronic components used in such power conversion devices, there are high heat generation components such as semiconductor modules, and the power conversion device has a cooler to cool such heat generation members. It is necessary to prepare. As such a power converter, for example, Patent Document 1 includes a stacked body in which semiconductor joules and coolers are alternately stacked, and a coolant flow path through which a coolant flows is formed in the cooler. A configuration is disclosed. In this configuration, the semiconductor module is cooled by heat exchange between the refrigerant flowing through the refrigerant flow path and the semiconductor module.

JP2013-9581A

  However, in the configuration of Patent Document 1, if the refrigerant leaks little by little due to a small crack in the cooling pipe, the refrigerant travels down the surface of the cooling pipe in the direction of gravity, It gathers at the lower end and eventually drops. And when arrange | positioning a semiconductor module so that a power terminal may extend in the gravity direction lower side, the drop of the refrigerant | coolant collected at the lower end part of a cooling pipe contacts the positive electrode terminal and negative electrode terminal in the power terminal of a semiconductor module. This may cause a short circuit between the two.

  The present invention has been made in view of such a problem, and intends to provide a power conversion device that prevents occurrence of a short circuit in a power terminal of a semiconductor module even if a refrigerant leaks. Is.

One aspect of the present invention is a power conversion device including a semiconductor module in which a plurality of power terminals extend from a main body portion incorporating a semiconductor element, and a cooler that cools the semiconductor module,
The plurality of power terminals extend downward in the direction of gravity,
The cooler is provided in a power conversion device including a refrigerant flow path through which a refrigerant flows and a protruding portion protruding along an extending direction of the plurality of power terminals.

  In the power converter, a plurality of power terminals extend downward in the gravity direction from the semiconductor module. And the cooler is provided with the protrusion part which protrudes along the extension direction of the said several power terminal. As a result, even if the refrigerant leaks little by little from the refrigerant flow path provided inside the cooler due to a small crack in the cooler, the leaked refrigerant It will gather in the protrusion part which protruded to the gravity direction lower side through the lower end part. As a result, the leaked refrigerant is prevented from coming into contact with the plurality of power terminals of the semiconductor module, and a short circuit can be prevented from occurring at the power terminals of the semiconductor module.

  As described above, according to the present invention, it is possible to provide a power conversion device that prevents occurrence of a short circuit in a power terminal of a semiconductor module even if a refrigerant leaks.

The top view of the power converter device in Example 1. FIG. II-II sectional view taken on the line in FIG. FIG. 3 is a plan view of the semiconductor module in the first embodiment. FIG. 11 is a cross-sectional view corresponding to the line II-II in FIG. FIG. 5 is a cross-sectional view corresponding to line V-V in FIG. FIG. 2 is a cross-sectional view corresponding to the line II-II in FIG. FIG. 2 is a cross-sectional view corresponding to the line II-II in FIG. FIG. 2 is a cross-sectional view corresponding to the line II-II in FIG.

  The power conversion device can be used as a power conversion device mounted on an electric vehicle or a hybrid vehicle.

  In the power conversion device of the present invention, examples of the refrigerant flowing through the refrigerant flow path include natural refrigerants such as water and ammonia, water mixed with ethylene glycol-based antifreeze, methanol, alcohols such as alcohol, and ketones such as acetone. A liquid refrigerant such as a system refrigerant is used.

Example 1
A power conversion device according to an embodiment of the present example will be described with reference to FIGS.
As shown in FIG. 1, the power conversion apparatus 1 of this example includes a semiconductor module 10 in which a plurality of power terminals 12 (12 a, 12 b, 12 c) are extended from a main body 11 containing a semiconductor element, and a semiconductor module 10. And a cooler 20 for cooling.
As shown in FIG. 2, the plurality of power terminals 12 (12a, 12b, 12c) extend downward in the gravity direction Z.
The cooler 20 includes a refrigerant flow path 25 through which the refrigerant R flows, and a protrusion 26 that protrudes along the extending direction Z of the plurality of power terminals 12 (12a, 12b, 12c). ing.

Hereafter, the component of the power converter device of this example is explained in full detail.
As shown in FIG. 3, the semiconductor module 10 includes a main body 11, a plurality of power terminals 12, and a control terminal 13. The main body 11 has a rectangular plate shape in plan view and incorporates a semiconductor element 11a. In this example, the main body portion 11 includes two semiconductor elements 11a. The plurality of power terminals 12 include a positive terminal 12a, a negative terminal 12b, and an output terminal 12c. The plurality of power terminals 12 protrude parallel to the main surface of the main body 11 and below the gravity direction Z. In the plurality of power terminals 12, the positive terminal 12 a, the negative terminal 12 b, and the output terminal 12 c are arranged in this order in a direction Y that is parallel to the main surface of the main body 11 and perpendicular to the gravity direction Z. Two control terminals 13 are provided, and each of the control terminals 13 is parallel to the main surface of the main body 11 and protrudes upward in the gravity direction Z.

  As shown in FIG. 1, a plurality of semiconductor modules 10 are provided, and are stacked alternately with a plurality of cooling pipes 21 described later to form a stacked body 40. The stacked body 40 is stacked along the direction X perpendicular to the Z direction and the Y direction. The cooling pipe 21a located on one end side of the laminated body 40 is in contact with the inner wall surface of the case 2 housing the laminated body 40, and the cooling pipe 21b located on the other end side is moved to the one end side by the pressing member 31. It is pressed. Thereby, the laminated body 40 is fixed in the pressed state in the case 2.

  As shown in FIG. 1, the cooler 20 includes a plurality of cooling pipes 21 and a plurality of connecting pipes 22. As shown in FIGS. 1 and 2, the cooling pipe 21 is a flat plate member whose longitudinal direction is the Y direction, and a refrigerant flow in which a refrigerant R for cooling the semiconductor module 10 flows is inside the cooling pipe 21. A path 25 is formed. A protruding portion 26 that protrudes downward in the gravity direction Z is formed at the lower end portion 211 below the gravity direction Z of the cooling pipe 21. The protrusion 26 has a tongue-like shape with a width (length in the Y direction) that decreases toward the lower side in the Z direction. In this example, when viewed from the stacking direction X, the shape of the protruding portion 26 is a trapezoidal shape in which the Z direction is the height direction and the lower base is smaller than the upper base. The length in the height direction (Z direction) is about ½ of the length of the output terminal 12c. The shape when viewed from the Y direction (that is, the thickness direction) is a flat plate as shown in FIG. In this example, the protruding portion 26 is formed integrally with the cooling pipe 21. As will be described in detail later, the protruding portion 26 is positioned on the output terminal block 4 side for connecting to an AC load in the vehicle in the Y direction.

  As shown in FIG. 1, in the stacked body 40, both end portions in the longitudinal direction Y of the cooling pipes 21 adjacent to each other in the stacking direction (X direction) among the stacked cooling pipes 21 are connected by the connecting pipe 22. It connects so that the refrigerant | coolant R can distribute | circulate. The connecting tube 22 is configured to be able to expand and contract in the stacking direction X of the stacked body 40.

  As shown in FIG. 1, in the stacked body 40, a refrigerant introduction pipe 23 for introducing the refrigerant R into the refrigerant flow path 25 is provided in the cooling pipe 21 b located at the other end in the X direction among the plurality of cooling pipes 21; A refrigerant outlet pipe 24 for leading the refrigerant R from the refrigerant flow path 25 is attached. The refrigerant R is introduced from the refrigerant introduction pipe 23 into the cooling pipe 21b on the other end side, flows into the respective cooling pipes 21 along the stacking direction X, is distributed and circulated in the respective refrigerant flow paths 25, and then the refrigerant is discharged. Derived from the tube 24.

  As shown in FIGS. 1 and 2, the power conversion device 1 includes a capacitor 3. The capacitor 3 is disposed along the stacking direction X on one side of the direction Y orthogonal to the stacking direction X of the stacked body 40. An output terminal block 4 for connecting to an AC load by a vehicle is disposed on the opposite side of the capacitor 3 from the laminated body 40. In this example, as shown in FIG. 2, the power terminals 12 of each semiconductor module 10 are arranged in the order of the positive terminal 12a, the negative terminal 12b, and the output terminal 12c from the side close to the capacitor 3 in the Y direction. Not limited to this, the negative electrode terminal 12b, the positive electrode terminal 12a, and the output terminal 12c may be arranged in this order from the side close to the capacitor 3 in the Y direction.

  As shown in FIGS. 1 and 2, the capacitor 3 is electrically connected to each semiconductor module 10 via a bus bar 30 (a positive bus bar 31 and a negative bus bar 32). The positive electrode bus bar 31 includes a plurality of positive electrode connection terminal portions 31a extending to the positive electrode terminal 12a side of each semiconductor module 10 and connected to the positive electrode terminal 12a. Further, the negative electrode bus bar 32 includes a plurality of negative electrode connection terminal portions 32a extending to the negative electrode terminal 12b side of each semiconductor module 10 and connected to the negative electrode terminal 12b. The positive electrode connection terminal portion 31a and the negative electrode connection terminal portion 32a are welded to the positive electrode terminal 12a and the negative electrode terminal 12b of the semiconductor module 10, respectively.

As shown in FIGS. 1 and 2, the output terminal 12 c of each semiconductor module 10 in the stacked body 40 is electrically connected to an output terminal block 4 for connection to an AC load in a vehicle via an AC bus bar 33. Has been. The AC bus bar 33 includes a plurality of output connection terminal portions 33a extending to the output terminal 12c side of each semiconductor module 10 and connected to the output terminal 12c. The output connection terminal portion 33 a is welded to the output terminal 12 c of each semiconductor module 10. As shown in FIG. 2, the distal end portion 33 b of each connection portion (welded portion) has a convex shape below the gravity direction Z. The distal end portion 33b can be formed by, for example, arc welding.
In this example, the positive electrode connection terminal portion 31a and the negative electrode connection terminal portion 32a, and the tips (31b, 32b) of the connection portion between the positive electrode terminal 12a and the negative electrode terminal 12b are in a horizontal plane and are below the gravity direction Z. It is not convex on the side.

  As shown in FIG. 2, the protruding portion 26 is included in the power terminals 12 of the semiconductor module 10 when viewed from the direction in which the semiconductor module 10 and the cooler 20 (cooling pipe 21) overlap (that is, the stacking direction X). It is comprised so that it may overlap with the output terminal 12c. And as shown in FIG. 1, it is comprised so that it may be located between each output terminal 12c among the some power terminals 12 with which each adjacent semiconductor module 10 is provided.

Next, the effect in the power converter device 1 of this example is explained in full detail.
In the power conversion device 1, the plurality of power terminals 12 extend from the semiconductor module 10 to the lower side in the gravity direction Z. The cooler 20 includes a protruding portion 26 that protrudes along the extending direction Z of the plurality of power terminals 12. Thereby, even if the refrigerant R leaks little by little from the refrigerant flow path 25 provided inside the cooler 20 due to a small crack occurring in the cooler 20 (cooling pipe 21), The leaked refrigerant collects in the cooler 20 at the protrusion 26 provided on the lower side in the gravity direction Z through the lower end portion 211. As a result, the leaked refrigerant is prevented from coming into contact with the plurality of power terminals 12 of the semiconductor module 10, and a short circuit can be prevented from occurring at the power terminals 12 of the semiconductor module 10.

  Further, when the protrusion 26 is viewed from the X direction where the semiconductor module 10 and the cooler 20 overlap, at least a part of the protrusion 26 is at least one of the plurality of power terminals 12 (in this example, the output terminal 12c). ). As a result, even if the refrigerant leaks, the refrigerant collects at the lower end portion 211 of the cooling pipe 21 at a position overlapping with one power terminal 12 (in this example, the output terminal 12c) when viewed from the X direction. It will be. Therefore, the refrigerant is prevented from entering between the other power terminals 12 (in this example, for example, between the positive electrode terminal 12a and the negative electrode terminal 12b), thereby further preventing a short circuit between the other power terminals 12. can do.

  In addition, the power terminal 12 (output terminal 12 c) that overlaps the protrusion 26 in the plurality of power terminals 12 and the bus bar 30 (AC bus bar 33) that is connected to the power terminal 12 (output terminal 12 c) that overlaps the protrusion 26. The tip 33b of the connection portion with the output connection terminal portion 33a) is configured to be convex downward in the gravity direction Z. As a result, even if the refrigerant leaks, even if the refrigerant gathered at the protruding portion 26 via the lower end portion 211 of the cooling pipe 21 drops and adheres to the output terminal 12c, In addition, it flows along the lower side of the gravity direction Z and gathers at the convex tip 33b on the lower side of the gravity direction Z. Thereby, the said refrigerant | coolant is prevented from adhering to the other power terminal 12 (the positive electrode terminal 12a and the negative electrode terminal 12b), and the short circuit between the said other power terminals 12 can be prevented further.

  Moreover, in the power converter device 1 of this example, the power terminal 12 that overlaps the protruding portion 26 is the output terminal 12c. As a result, even if the refrigerant leaks, the leaked refrigerant collects in the protruding portion 26 that overlaps the output terminal 12c, so that the positive terminal 12a that is the power terminal 12 that does not overlap the protruding portion 26 and It is possible to prevent the refrigerant from coming into contact with the negative electrode terminal 12b, thereby further preventing a short circuit between the two.

  Moreover, in the power converter device 1 of this example, the semiconductor module 10 and the cooling pipes 21 in the cooler 20 are provided in plural, and are stacked alternately to constitute a stacked body 40. And the protrusion part 26 with which the cooler 20 (cooling pipe | tube 21) is equipped is comprised so that it may be located between each output terminal 12c among the several power terminals 12 with which each adjacent semiconductor module 10 is equipped. Yes. Thereby, the short circuit between the positive electrode terminal 12a and the negative electrode terminal 12b can be prevented also between the semiconductor modules 10 adjacent to the stacking direction X in the stacked body 40.

In the present example, a plurality of cooling pipes 21 in the semiconductor module 10 and the cooler 20 are provided, and the stacked body 40 is configured by alternately stacking each other. The capacitor 3 is disposed in a direction Y orthogonal to the stacking direction X of the stacked body 40. Among the plurality of power terminals 12 provided in each of the plurality of semiconductor modules 10, each output terminal 12c is disposed at a position farther from the capacitor 3 than each of the positive terminal 12a and the negative terminal 12b. The capacitor 3 and the positive terminal 12a and the negative terminal 12b are electrically connected to each other by a bus bar 30 extending from the positive terminal 12a and the negative terminal 12b toward the capacitor 3 side. And when the laminated body 40 is seen from the lamination direction X, it is comprised so that the bus bar 30 may not be located in the front end side of the protrusion direction Z of the protrusion part 26. FIG.
Thereby, in the unlikely event that the refrigerant leaks, even if the refrigerant gathered at the protruding portion 26 through the lower end portion 211 of the cooling pipe 21 drops and drops into the case 2, the tip of the protruding portion 26 in the protruding direction Z The bus bar 30 is not located on the side. Therefore, the dropped refrigerant is prevented from coming into contact with the bus bar 30, and a short circuit via the bus bar 30 can be prevented.

  In the present example, the protruding portion 26 is provided at a position overlapping the output terminal 12c when viewed from the stacking direction X. However, the present invention is not limited to this. For example, the protruding portion 26 can be positioned so as not to overlap the output terminal 12c. For example, as in the power conversion device 1 in Modification 1 shown in FIG. 4, the protrusion 26 is positioned between the output terminal 12 c and the negative electrode terminal 12 b adjacent to the output terminal 12 c when viewed from the stacking direction X. It is good to do. Even in this case, even if the refrigerant leaks, the leaked refrigerant collects in the protruding portion 26, so that a short circuit between the positive electrode terminal 12a and the negative electrode terminal 12b is prevented. Further, even if the refrigerant collected in the protrusion 26 drops and drops into the case 2, the bus bar 30 is not positioned on the front end side in the protrusion direction Z of the protrusion 26. Can be prevented, and a short circuit through the bus bar 30 can be prevented.

  In this example, the protruding portion 26 has a trapezoidal shape when viewed from the stacking direction X, but is not limited thereto. The shape of the protruding portion 26 is, for example, an inverted triangular shape having an apex on the lower side in the gravity direction Z, a semicircular or semi-elliptical surface shape protruding downward in the gravity direction Z, as viewed from the stacking direction X, gravity A fan shape having an arc protruding downward in the direction Z, a bar shape protruding downward in the gravity direction Z, and the like can be used. In any of these cases, the same effects as the present example are achieved.

  Further, in this example, the protrusion 26 has a flat plate shape when viewed from the Y direction (that is, the thickness direction), but is not limited thereto. For example, as in Modification 2 shown in FIG. 5, the shape of the end portion 26 a on the lower side in the gravity direction Z of the protruding portion 26 may be curved into a U shape. As a result, in the unlikely event that the refrigerant leaks, the refrigerant gathered at the protruding portion 26 through the lower end portion 211 of the cooling pipe 21 remains at the U-shaped end portion 26a. This prevents the leaked refrigerant from dripping and dropping from the projecting portion 26, so that a part of the refrigerant splashes and adheres to the positive electrode terminal 12a, the negative electrode terminal 12b, and the bus bar 30 and is short-circuited. Can be further prevented.

  In this example, one protrusion 26 is provided in each cooling pipe 21. However, the present invention is not limited to this, and each cooling pipe 21 may include a plurality of protrusions 26. Further, in this example, all of the plurality of cooling pipes 21 are provided with the protruding portions 26. However, the present invention is not limited to this, and the protruding portions 26 may be provided only in some of the cooling pipes 21. In addition, the shapes of the protruding portions 26 provided in the plurality of cooling pipes 21 may all be the same, or the shapes of some of the protruding portions 26 may be different from the shapes of the other protruding portions 26.

  When the protrusions 26 are provided only in some of the cooling pipes 21, it is preferable to provide the cooling pipes 21 near the center in the stacking direction X of the stacked body 40. Since the stacked body 40 is fixed by the pressing member 31 and the case 2 at one end side and the other end side in the stacking direction X, the cooling pipe 21 near the center in the stacking direction X is compared with the other cooling pipes 21. Susceptible to external forces due to vibration, etc. Therefore, the cooling pipe 21 close to the center in the stacking direction X is more likely to be damaged such as a crack than the other cooling pipes 21.

(Example 2)
The power converter of this example includes a protrusion 260 as shown in FIG. 6 instead of the protrusion 26 (FIG. 2) in the first embodiment. Further, as shown in FIG. 6, a recess 2 a is formed in the case 2. Other components are the same as those in the first embodiment, and the same reference numerals as those in the first embodiment are used in this example, and the description thereof is omitted.

  As shown in FIG. 6, the protruding portion 260 is formed in the entire area of the lower end portion 211 below the cooling pipe 21 in the gravity direction Z. When viewed from the stacking direction X, the projecting portion 260 has an inverted triangular shape with the entire region of the lower end portion 211 below the gravity direction Z of the cooling pipe 21 as the base and the vertex overlapping with the output terminal 12c. .

  Moreover, in the power converter device 1 of this example, the case 2 is provided with a recess 2a. The recess 2 a is formed at the bottom of the case 2 on the lower side in the gravity direction Z of the protrusion 260. The recess 2 a is a bottomed recess that opens to the inside of the case 2.

Next, the effect in the power converter device 1 of this example is explained in full detail.
According to the power conversion device 1 of the present example, since the protruding portion 260 is formed in the entire lower end portion 211 of the cooling pipe 21 on the lower side in the gravitational direction Z, the refrigerant leaks from the cooling pipe 21 by any chance. However, the leaked refrigerant is more reliably collected from the lower end portion 211 to the protruding portion 260. Thereby, generation | occurrence | production of the short circuit between the other power terminals 12 (positive electrode terminal 12a and negative electrode terminal 12b) can be prevented further.
Further, since the projecting portion 260 is formed in the entire region of the lower end portion 211 below the cooling pipe 21 in the direction of gravity Z, the mechanical strength of the cooling pipe 21 and thus the cooler 20 is improved as a reinforcing rib for the cooling pipe 21. can do.

Furthermore, according to the power converter 1 of this example, the recessed part 2a is provided below the protruding part 260 in the gravity direction Z. As a result, even if the refrigerant leaks, even if the droplets of the refrigerant gathered from the lower end portion 211 to the projecting portion 260 are dropped from the projecting portion 260, the dropped coolant is located in the concave portion 2a located below the gravity direction Z. And stays in the recess 2a. As a result, a part of the dropped refrigerant is splashed and is prevented from adhering to the power terminals 12 such as the positive terminal 12a and the negative terminal 12b, and the occurrence of a short circuit in the power terminal 12 is prevented.
In addition, you may further provide the discharge flow path which guide | induces the refrigerant | coolant which remains in the recessed part 2a to the outer side of the case 2. FIG. In this case, the refrigerant dripped in the case 2 is further prevented from adhering to the power terminal 12, and the occurrence of a short circuit at the power terminal 12 is further prevented.
Note that the power conversion device 1 of the present example also provides the same operational effects as those of the first embodiment.

Example 3
In this example, it replaces with each front-end | tip part 31b, 32b, 33b of the bus bar 30 in Example 1, and is provided with the front-end | tip parts 310b, 320b, 330b as shown in FIG.
In this example, the tip portions 310b and 320b of the respective connecting portions (welded portions) of the positive electrode connecting terminal portion 31a and the negative electrode connecting terminal portion 32a and the positive electrode terminal 12a and the negative electrode terminal 12b of the semiconductor module 10 are shown in FIG. As shown, each is convex downward in the direction of gravity Z. On the other hand, the tip 33b of the connection portion between the output connection terminal portion 33a and the output terminal 12c has a horizontal plane shape and is not convex downward in the gravity direction Z.
The other components are the same as those in the first embodiment, and the same reference numerals as those in the first embodiment are used in this example, and the description thereof is omitted.

  According to the power conversion device 1 of this example, in the unlikely event that the leaked refrigerant drops and drops into the case 2, a part of the refrigerant is splashed and does not overlap the protrusion 26. It can be considered that it adheres to the power terminals 12 (12a, 12b). Even in such a case, the refrigerant adhering to the power terminal 12 (12a, 12b) flows along the lower side in the gravity direction Z and collects at the tips (310b, 320b) convex in the lower side in the gravity direction Z. It will be. Thereby, since the said refrigerant | coolant is prevented from accumulating between the power terminals 12, generation | occurrence | production of the short circuit between the said power terminals 12 is prevented.

Example 4
As shown in FIG. 8, the power converter 1 of this example includes a convex portion 30a in the bus bar 30 according to the first embodiment. Other components are the same as those in the first embodiment, and the same reference numerals as those in the first embodiment are used in this example, and the description thereof is omitted.

  The convex part 30a with which the power converter device 1 of this example is equipped is formed in the bus bar 30 (positive electrode bus bar 31) connected with the power terminal (positive electrode terminal 12a) which does not overlap with the protrusion part 26, as shown in FIG. ing. And the convex part 30a is located in the gravity direction Z lower side than the power terminal (positive electrode terminal 12a) which does not overlap with the protrusion part 26. FIG.

According to the power conversion device 1 of this example, if the refrigerant leaks, the leaked refrigerant collects in the protruding portion 26 through the lower end portion 211 of the cooling pipe 21, so that the power terminal 12 ( The refrigerant is prevented from contacting the positive terminal 12a and the negative terminal 12b). Further, when the refrigerant gathered at the protruding portion 26 through the lower end portion 211 of the cooling pipe 21 drops and drops into the case 2, a part of the refrigerant becomes droplets, and the refrigerant becomes the positive terminal 12 a or the positive electrode. Even if it adheres to the bus bar 31, the refrigerant collects in the convex portion 30 a protruding downward in the gravity direction Z. As a result, the refrigerant adhering to the positive electrode terminal 12a or the positive electrode bus bar 31 is prevented from flowing to the capacitor 3 side through the positive electrode bus bar 31, and a short circuit on the capacitor 3 side is prevented.
In addition, you may form the convex part 30a in the negative electrode bus bar 32 connected with the negative electrode terminal 12b which does not overlap with the protrusion part 26. FIG.
Also with the power converter device 1 of the present example, the same operational effects as in the case of the first embodiment are obtained.

DESCRIPTION OF SYMBOLS 1 Power converter 10 Semiconductor module 12 Power terminal 2 Case 20 Cooler 21 Cooling pipe 26, 260, 261 Protruding part 3 Capacitor 30 Bus bar 30a Convex part

Claims (8)

A semiconductor module (10) having a plurality of power terminals (12) extending from a main body (11) containing a semiconductor element (11a), and a cooler (20) for cooling the semiconductor module (10). A power converter (1),
The plurality of power terminals (12) extend downward in the direction of gravity (Z),
The cooler (20) includes a refrigerant flow path (25) through which a refrigerant flows, and a protrusion (26) protruding along the extending direction (Z) of the plurality of power terminals (12). The power converter device (1) characterized by comprising.   When the protrusion (26) is viewed from the direction in which the semiconductor module (10) and the cooler (20) overlap, at least a part of the protrusion (26) is the plurality of power terminals (12). It is comprised so that it may overlap with at least one of these, The power converter device (1) of Claim 1 characterized by the above-mentioned.   A power terminal (12) overlapping with the protrusion (26) in the plurality of power terminals (12), and a bus bar (30) connected to the power terminal (12) overlapping with the protrusion (26). The power converter (1) according to claim 2, wherein the tip (33b) of the connecting portion is configured to be convex downward in the direction of gravity (Z).   A power terminal (12) that does not overlap the protrusion (26) in the plurality of power terminals (12), and a bus bar (30) connected to the power terminal (12) that does not overlap the protrusion (26). The power converter (1) according to claim 2 or 3, wherein the tip (310b, 320b) of the connecting portion is configured to be convex downward in the direction of gravity (Z).   The bus bar (30) connected to the power terminal (12) that does not overlap the protrusion (26) is lower in the direction of gravity (Z) than the power terminal (12) that does not overlap the protrusion (26). The power conversion device (1) according to claim 2 or 3, further comprising a convex portion (30a) positioned.   The power converter (1) according to any one of claims 2 to 5, wherein the power terminal (12) overlapping the protruding portion (26) is an output terminal (12c).   A plurality of the semiconductor modules (10) and the coolers (20) are provided, and are alternately stacked to constitute a stacked body (40). The protrusions (26) provided in the cooler (20) are provided. ) Is configured to be positioned between the output terminals (12c) among the plurality of power terminals (12) respectively provided in the adjacent semiconductor modules (10). Item 7. The power conversion device (1) according to any one of Items 1 to 6.   A plurality of the semiconductor modules (10) and a plurality of the coolers (20) are provided, and are alternately stacked to form a stacked body (40). The stacked body (40) has a stacking direction (X) and Capacitors (3) are arranged in the orthogonal direction (Y), and among the plurality of power terminals (12) provided in the plurality of semiconductor modules (10), each output terminal (12c) is respectively The positive electrode terminal (12a) and the negative electrode terminal (12b) are located farther from the capacitor (3), and the capacitor (3), the positive electrode terminal (12a), and the negative electrode terminal (12b) The bus bar (30) extending from the positive terminal (12a) and the negative terminal (12b) toward the capacitor (3) is electrically connected to each other. Thus, when the laminated body (40) is viewed from the laminating direction (X), the bus bar (30) is not positioned on the tip side in the projecting direction (Z) of the projecting portion (26). It is comprised, The power converter device (1) as described in any one of Claims 1-7 characterized by the above-mentioned.

Images