JP2015154516A - Power conversion device, and manufacturing method thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power conversion device capable of shortening a length of a power terminal of a semiconductor module, and a manufacturing method thereof.SOLUTION: A power conversion device 1 includes a semiconductor module 2 and a bus bar 4. The semiconductor module 2 includes: a main body part 21 in which a semiconductor device is incorporated; and a power terminal 3. The bus bar 4 becomes a current path between the semiconductor module 2 and external equipment. In the bus bar 4, a plate-like part 40 is formed that is welded to the power terminal 3. The plate-like part 40 and the power terminal 3 are welded by a laser or an electron beam in the state where a distal end portion 30 of the power terminal 3 is brought into contact with a first principal surface 41 that is a principal surface at a side where the semiconductor module 2 is disposed, between two principal surfaces 41 and 42 of the plate-like part 40.

Description

  The present invention relates to a power conversion device in which a power terminal of a semiconductor module and a bus bar are welded, and a manufacturing method thereof.

  For example, as a power conversion device that performs power conversion between DC power and AC power, a device that includes a semiconductor module incorporating a semiconductor element and a bus bar made of a metal plate is known (see Patent Document 1 below). .

  The semiconductor module includes a main body portion including the semiconductor element and a power terminal protruding from the main body portion. The power terminal is electrically connected to the semiconductor element in the main body. The tip of the power terminal is joined to the bus bar.

  In the said power converter device, the power terminal and the said bus-bar are welded, for example by performing TIG welding. For example, a part to be welded (welded part) is formed in advance on the bus bar, and the welded part and the power terminal are overlapped. And it is comprised so that these welding parts and a power terminal may be welded by performing TIG welding.

Japanese Patent No. 5272666

  However, the power conversion device has a problem that it is necessary to increase the protruding length of the power terminal. That is, TIG welding generates a large amount of heat at the time of welding, so that this heat is easily transmitted to the main body through the power terminal. For this reason, the temperature of the main body part is likely to rise, and the main body part is likely to be deformed or the characteristics of the semiconductor element are fluctuated. Therefore, in the power converter, it is necessary to form the power terminal long and to dissipate the heat generated during welding and transmitted to the main body at the power terminal.

  However, when the power terminal is lengthened, the inductance parasitic on the power terminal increases, and the surge voltage applied to the semiconductor element tends to increase. Therefore, it is necessary to reduce the switching speed of the semiconductor element. In addition, if the power terminal is long, there is also a problem that the power converter is likely to be enlarged.

  The present invention has been made in view of such a background, and an object of the present invention is to provide a power conversion device capable of shortening the protruding length of a power terminal of a semiconductor module and a manufacturing method thereof.

According to a first aspect of the present invention, there is provided a semiconductor module having a main body portion incorporating a semiconductor element, and a power terminal electrically connected to the semiconductor element and at least partially sealed in the main body portion;
A bus bar serving as a current path between the semiconductor module and an external device;
The bus bar has a plate-like portion welded to the power terminal,
The plate-like portion and the power terminal are in contact with the first principal surface, which is the principal surface on the side where the semiconductor module is disposed, of the two principal surfaces of the plate-like portion. In this state, the power converter is characterized by being laser welded or electron beam welded.

Moreover, the 2nd aspect of this invention is a method of manufacturing the said power converter device, Comprising:
A fixing step of fixing the semiconductor module in the case;
Contacting the bus bar with the semiconductor module and bringing the tip of the power terminal into contact with the first main surface;
A measuring step for measuring the position of the power terminal;
From the second main surface side, which is the main surface opposite to the first main surface, of the two main surfaces of the plate-shaped part toward the power terminal whose position is measured in the measurement step, A welding step of welding the plate-like portion and the power terminal by irradiating an electron beam;
There exists in the manufacturing method of the power converter device characterized by performing.

In the power converter, the plate-like portion is formed on the bus bar. Then, the plate-like portion and the power terminal are laser-welded or electron-beam welded in a state where the tip portion of the power terminal is in contact with the first main surface of the plate-like portion.
Therefore, the protruding length of the power terminal can be shortened. That is, laser welding and electron beam welding are methods that can concentrate energy in a narrow range and can be welded in a short time, and therefore generate less heat during welding. Therefore, the heat transmitted to the power terminal and the main body during welding can be reduced. Therefore, the protruding length of the power terminal can be shortened, and the inductance parasitic on the power terminal can be reduced. Therefore, surge applied to the semiconductor element can be reduced, and the semiconductor element can be switched at high speed.

Moreover, in the manufacturing method of the said power converter device, the said measurement process is performed. And the laser or electron beam is irradiated from the 2nd main surface side toward the power terminal which measured the position in the measurement process.
Therefore, the position of the power terminal can be accurately measured in the measurement process, and the welding process by laser welding or electron beam welding can be reliably performed.

  As mentioned above, according to this invention, the power converter device which can shorten the length of the power terminal of a semiconductor module, and its manufacturing method can be provided.

  The “main surface” means a surface having the largest area among the surfaces of the plate-like portion.

Sectional drawing of the power converter device in Example 1. FIG. II-II sectional drawing of FIG. III-III sectional drawing of FIG. IV-IV sectional drawing of FIG. It is the principal part enlarged view of FIG. 1, Comprising: The figure drawn with the laser beam. It is the principal part enlarged view of FIG. 4, Comprising: The figure drawn with the laser beam. 1 is a perspective view of a semiconductor module in Embodiment 1. FIG. Sectional drawing of the semiconductor module in Example 1. FIG. The circuit diagram of the power converter device in Example 1. FIG. The manufacturing process explanatory drawing of the power converter device in Example 1. FIG. The figure following FIG. The principal part enlarged view of the power converter device in Example 2. FIG. The principal part enlarged view of the power converter device in Example 3. FIG. The principal part enlarged view of the power converter device in Example 4. FIG. FIG. 10 is a partial perspective plan view of a semiconductor module in Example 5. FIG. The principal part expanded sectional view in Example 5. FIG. Sectional drawing of the power converter device in Example 6. FIG. XIX-XIX sectional drawing of FIG.

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

In the power conversion device, a plurality of the semiconductor modules and a plurality of coolers for cooling the semiconductor modules are stacked to form a stacked body, and the thickness direction of the plate-like portion is the stacked body. It is preferable that the length of the plate-like portion in the lamination direction is longer than the dimension of the tip portion in the lamination direction.
When the laminated body is formed, the thickness variations of the individual semiconductor modules and the coolers are accumulated, and thus the positional deviation of the power terminals in the laminating direction tends to be large. However, the power conversion device is configured to easily allow the displacement of the power terminal. That is, in the power converter, since the length of the plate-shaped portion in the stacking direction is long, even if the power terminal is largely displaced in the stacking direction, the power terminal is moved to the first main surface of the plate-shaped portion at the shifted position. Can be contacted. And a power terminal and a plate-shaped part can be easily welded by irradiating a laser beam or an electron beam to the contact position.
That is, if the length of the plate-shaped member in the stacking direction is increased, and the power terminal is brought into contact with the first main surface of the plate-shaped portion and laser welding or the like is performed, it is easy to tolerate the positional deviation of the power terminal in the stacking direction. Become. Therefore, it is particularly suitable for a power converter having a large variation in the stacking direction of power terminals, such as when a stacked body is formed.

Moreover, it is preferable that the plate | board thickness of the said plate-shaped part is thinner than the dimension of the said front-end | tip part in the said lamination direction.
If it does in this way, since the thickness of a plate-shaped part is thin enough, the heat | fever generate | occur | produced when a 2nd main surface is irradiated with a laser beam can be conducted to a 1st main surface in a short time. Therefore, the welding process can be performed in a shorter time. In addition, if the thickness of the plate-like portion is reduced as described above, the amount of the metal material constituting the bus bar can be reduced, so that the bus bar can be manufactured at low cost.
Moreover, in this example, since the dimension in the stacking direction of the tip portion is sufficiently long, the range that can be welded by laser light is wide. Therefore, it is easy to perform a welding process.

Example 1
The Example which concerns on the said power converter device and its manufacturing method is described using FIGS. As shown in FIGS. 1 and 2, the power conversion device 1 of this example includes a semiconductor module 2 and a bus bar 4. The semiconductor module 2 includes a main body portion 21 containing a semiconductor element 20 (see FIGS. 8 and 9), a power terminal 3 electrically connected to the semiconductor element 20 and partially sealed in the main body portion 21. Is provided. The bus bar 4 is a current path between the semiconductor module 2 and the external device 8 (see FIG. 9).

  As shown in FIG. 1, the bus bar 4 has a plate-like portion 40 welded to the power terminal 3. As shown in FIGS. 5 and 6, the plate-like portion 40 and the power terminal 3 are the first main surfaces which are the main surfaces on the side where the semiconductor module 2 is disposed, of the two main surfaces 41 and 42 of the plate-like portion 40. Laser welding is performed with the surface 41 in contact with the tip 30 of the power terminal 3.

  The power conversion device 1 of this example is a vehicle-mounted power conversion device to be mounted on a vehicle such as an electric vehicle or a hybrid vehicle.

  As shown in FIGS. 2 and 4, in this example, a stacked body 10 is configured by stacking a plurality of semiconductor modules 2 and a plurality of coolers 11 that cool the semiconductor modules 2. The plate-like portion 40 is arranged so that its thickness direction (Z direction) is orthogonal to the lamination direction (X direction) of the laminate 10. The length A in the X direction of the plate-like portion 40 is longer than the dimension W1 of the tip portion 30 in the X direction.

  As shown in FIG. 1, the power conversion device 1 of this example includes a plurality of bus bars 4 (4a, 4b, 4c). Each semiconductor module 2 includes a plurality of power terminals 3 (3a, 3b, 3c). The power terminal 3 includes a positive terminal 3a that is electrically connected to the positive electrode 80 of the DC power supply 8a (see FIG. 9), a negative terminal 3b that is electrically connected to the negative electrode 81 of the DC power supply 8a, and an electric power to the AC load 8b. There is an AC terminal 3c to be connected. As shown in FIG. 5, the lengths H in the Z direction of the individual power terminals 3a, 3b, 3c are equal to each other.

  As shown in FIG. 1, a positive electrode bus bar 4a is welded to the positive electrode terminal 3a, and a negative electrode bus bar 4b is welded to the negative electrode terminal 3b. An AC bus bar 4c is welded to the AC terminal 3c.

  The negative electrode bus bar 4b and the AC bus bar 4c are each formed in a flat plate shape. The positive electrode bus bar 4a is formed in a step shape. A through hole 49 is formed in the positive electrode bus bar 4a. As shown in FIG. 5, the laser beam L is irradiated through the through hole 49, and the negative electrode bus bar 4b and the negative electrode terminal 3b are welded.

  A metal plating layer such as a Ni—P plating layer, a Sn plating layer, or a Cr plating layer is formed on the surface of the power terminal 3. This facilitates soldering of the semiconductor element 20 to the power terminal 3. The bus bars 4a to 4c are formed of a metal plate mainly composed of copper. A metal plating layer is not formed on the bus bar 4.

  Further, as shown in FIG. 6, the thickness T of the plate-like portion 40 is thinner than the dimension W <b> 1 in the X direction of the tip portion 30.

  Next, the structure of the semiconductor module 2 will be described. As shown in FIG. 7, the heat radiating plate 29 is exposed from the main body 21 of the semiconductor module 2. Further, a plurality of control terminals 22 protrude from the main body 21. A control circuit board 13 (see FIG. 1) is connected to the control terminal 22. The control circuit board 13 is used to control the switching operation of the semiconductor module 2.

  A plurality of semiconductor elements 20 are built in the main body 21. The semiconductor element 20 includes an upper arm semiconductor element 20a (IGBT element: see FIG. 9) and a lower arm semiconductor element 20b. A free wheel diode 200 is connected in reverse parallel to each semiconductor element 20, and this free wheel diode 200 is also built in the main body 21. As shown in FIG. 8, each semiconductor element 20 is interposed between two heat sinks 29. The semiconductor element 20 is electrically connected to the heat sink 29.

  As shown in FIG. 8, the heat sink 29 and the power terminal 3 are integrated. That is, the heat sink 29 and the power terminal 3 are formed by bending one metal plate. The radiator plate 29 and the power terminal 3 have the same dimensions W1 and W2 in the X direction.

  Next, the structure of the laminated body 10 will be described. In this example, as shown in FIG. 2, the stacked body 10 is configured by alternately stacking the semiconductor modules 2 and the coolers 11. Inside the cooler 11, a flow path for the refrigerant 17 is formed. The cooler 11 is made of metal. An insulating plate (not shown) is interposed between the cooler 11 and the heat dissipation plate 29 (see FIGS. 7 and 8). With this insulating plate, the cooler 11 and the heat radiating plate 29 are insulated.

  Two coolers 11 adjacent in the X direction are connected by a connecting pipe 18. Among the plurality of coolers 11, the end cooler 11 a disposed at one end in the X direction includes an introduction pipe 15 for introducing the refrigerant 17, and a lead-out pipe 16 for deriving the refrigerant 17. Is connected. When the refrigerant 17 is introduced from the introduction pipe 15, the refrigerant 17 flows through all the coolers 11 through the connection pipe 18 and is led out from the outlet pipe 16. Thereby, the semiconductor module 2 is cooled.

  As shown in FIG. 2, a pressurizing member 19 (plate spring) is disposed at a position adjacent to the stacked body 10 in the X direction. Using this pressing member 19, the laminate 10 is pressed toward the wall 121 of the case 12. Thereby, the laminated body 10 is fixed in the case 12 while ensuring a contact pressure between the semiconductor module 2 and the cooler 11.

  As shown in FIGS. 1 and 2, a smoothing capacitor 14 is disposed at a position adjacent to the stacked body 10 in the Y direction (a direction orthogonal to both the X direction and the Z direction). The capacitor 14 includes a capacitor case 141, a plurality of capacitor elements 142 accommodated in the capacitor case 141, and a resin portion 143 that seals the capacitor elements 142 in the capacitor case 141. The capacitor element 142 is a film capacitor. The end surfaces 144 and 145 of the capacitor element 142 are electrode surfaces. Electrode plates 146 and 147 are connected to the end faces 144 and 145, respectively. The positive electrode bus bar 4a and the negative electrode bus bar 4b described above are connected to the electrode plates 146 and 147, respectively.

  As shown in FIG. 3, in this example, a plurality of AC bus bars 4 c are integrated using a sealing portion 49 to constitute one bus bar module 400. The AC bus bar 4c includes a plate-like portion 40 having a long X direction length A (A2, A3) and a short one. The plate-like portions 40 of all the AC bus bars 4c have the X-direction length A (A2, A3) longer than the dimension W1 in the X direction of the AC terminal 3c.

  Next, a circuit diagram of the power conversion device 1 will be described. As shown in FIG. 9, in this example, a bridge circuit is configured using a plurality of semiconductor modules 2. Each semiconductor module 2 includes a plurality of semiconductor elements 20 as described above. The power conversion device 1 of this example converts the DC power into AC power by driving the semiconductor elements 20a and 20b to drive the AC load 8b.

  Next, the manufacturing method of the power converter device 1 is demonstrated. In this example, a fixing process, a contact process, a measurement process, and a welding process described below are performed. In the fixing step, the semiconductor module 2 is fixed in the case 12 as shown in FIG. That is, a plurality of semiconductor modules 2 and a cooler 11 are stacked to form a stacked body 10, and the stacked body 10 is fixed in the case 12 using a pressure member 19 (see FIG. 2).

In the contact step, as shown in FIG. 11, the bus bar 4 (4 a, 4 b, 4 c) is brought close to the semiconductor module 2, and the tip portion 30 of the power terminal 3 is brought into contact with the first main surface 41 of the bus bar 4. In the measurement process, the position of the power terminal 3 in the X direction is measured using the measurement device 7. In the welding process, the laser beam L is irradiated from the second main surface 42 side of the plate-like portion 40 toward the power terminal 3 whose position is measured in the measurement process. Thereby, the plate-shaped part 40 and the power terminal 3 are welded.
When the stacked body 10 is formed, variations in the thickness of the semiconductor module 2 and the cooler 11 are accumulated, so that variations in the X direction of the power terminals 3 are increased. Therefore, in the measurement step, the position of the power terminal 3 is accurately measured, and the laser beam L is irradiated to the measured position.

The effect of this example will be described. As shown in FIGS. 5 and 6, in this example, a plate-like portion 40 is formed on the bus bar 4. And the plate-shaped part 40 and the power terminal 3 are laser-welded in the state which made the front-end | tip part 30 of the power terminal 3 contact the 1st main surface 41 of this plate-shaped part 40. FIG.
Therefore, the protruding length H of the power terminal 3 can be shortened. That is, laser welding is a method in which energy can be concentrated in a narrow range and welding can be performed in a short time, so that heat generated during welding is small. Therefore, the heat transmitted to the power terminal 3 and the main body 21 during welding can be reduced. Therefore, the protruding length H of the power terminal 3 can be shortened, and the inductance parasitic on the power terminal 3 can be reduced. Therefore, the surge applied to the semiconductor element 20 can be reduced, and the semiconductor element 20 can be switched at high speed.

  Further, when welding is performed using the laser beam L, the welding speed can be increased, so that the number of welding devices required for mass production of the power conversion device 1 can be reduced. Therefore, it is possible to reduce the cost required for mass production equipment.

In this example, the stacked body 10 is configured by stacking a plurality of semiconductor modules 2 and a plurality of coolers 10. And as shown in FIG. 4, the X direction length A of the plate-shaped part 40 is made longer than the dimension W1 in the X direction of the front-end | tip part 30. As shown in FIG.
When the stacked body 10 is formed, the thickness variations of the individual semiconductor modules 2 and the cooler 10 are accumulated, so that the positional deviation of the power terminal 3 in the X direction tends to increase. However, if the configuration of this example is adopted, even if the power terminal 3 is largely displaced, this can be allowed. That is, since the plate-like portion 40 of the present example has a long X-direction length A, even if the power terminal 3 is largely displaced in the X-direction, the power terminal 3 is moved to the position of the plate-like portion 40 at the displaced position. 1 main surface 41 can be brought into contact. And the power terminal 3 and the plate-shaped part 40 can be easily welded by irradiating the laser beam L to the contacted position.
That is, if the length A in the X direction of the plate-like member 40 is lengthened and the power terminal 3 is brought into contact with the first main surface 41 of the plate-like portion 40 and laser welding is performed, the positional deviation of the power terminal 3 in the X direction is shifted. It becomes easier to tolerate. Therefore, it is particularly suitable for the power conversion device 1 in which the power terminal 3 has a large variation in the X direction as in the case where the stacked body 10 is formed.

In this example, as shown in FIG. 6, the thickness T of the plate-like portion 40 is thinner than the dimension W <b> 1 in the X direction of the tip portion 30.
In this case, since the thickness T of the plate-like portion 40 is sufficiently thin, the heat generated when the second main surface 42 is irradiated with the laser light L is conducted to the first main surface 41 in a short time. Can do. Therefore, the welding process can be performed in a shorter time. Further, if the thickness T of the plate-like portion 40 is reduced as described above, the amount of the metal material constituting the bus bar 4 can be reduced, so that the bus bar 4 can be manufactured at a low cost.
In this example, since the dimension W1 of the tip portion 30 in the X direction is sufficiently long, the range that can be welded by the laser beam L is wide. Therefore, it is easy to perform a welding process.

  In this example, a metal plating layer is formed only on the power terminal 3 out of the power terminal 3 and the bus bar 4. That is, no metal plating layer is formed on the surface of the bus bar 4. Therefore, the manufacturing cost of the bus bar 4 can be further reduced.

  In this example, as shown in FIG. 5, the lengths of the three power terminals 3a, 3b, 3c in the Z direction are equal to each other. Therefore, the parasitic inductances of the individual power terminals 3a, 3b, 3c can be made equal to each other. Therefore, the circuit design of the power converter 1 can be easily performed. Moreover, since the Z direction length of the whole power converter device 1 can be shortened, the power converter device 1 can be reduced in size.

Moreover, in the manufacturing method of the power converter device 1 in this example, the said measurement process is performed (refer FIG. 10, FIG. 11). And in the welding process, the laser beam L is irradiated from the 2nd main surface 42 side toward the power terminal 3 which measured the position in the said measurement process.
Therefore, the position of the power terminal 3 can be accurately measured in the measurement process, and the welding process using the laser beam L can be reliably performed.

  As mentioned above, the power converter device which can shorten the length of the power terminal of a semiconductor module, and its manufacturing method can be provided.

  In this example, the plate-like portion 40 and the power terminal 3 are laser welded, but electron beam welding may be performed.

(Example 2)
In the following embodiments, the same reference numerals used in the drawings among the reference numerals used in the drawings represent the same components as in the first embodiment unless otherwise specified.

  In this example, the shape of the power terminal 3 is changed. As shown in FIG. 12, the power terminal 3 of this example has a terminal base portion 31 protruding in the Z direction from the main body portion 21, and the tip portion 30 protrudes in the X direction from the tip of the terminal base portion 31. . And the front-end | tip part 30 is made to contact the 1st main surface 41 of the plate-shaped part 40, the 2nd main surface 42 is irradiated with the laser beam L, and is welded.

With the above configuration, the dimension W1 of the tip portion 30 in the X direction can be increased. Therefore, the range in which the laser beam L can be irradiated can be expanded, and the welding process can be performed more easily.
In addition, the configuration and operational effects similar to those of the first embodiment are provided.

(Example 3)
In this example, the shape of the power terminal 3 is changed. As shown in FIG. 13, the power terminal 3 of this example includes a terminal base portion 31 protruding from the main body portion 21 in the Z direction, as in the second embodiment. A tip portion 30 projects from the tip of the terminal base portion 31 in the X direction. The tip portion 30 of this example protrudes from the terminal base portion 31 on both sides in the X direction.

If it does in this way, the dimension W1 in the X direction of the front-end | tip part 30 can be made longer. Therefore, the range in which the laser beam L can be irradiated can be further expanded, and the welding process can be performed more easily.
In addition, the configuration and operational effects are the same as those of the second embodiment.

Example 4
In this example, the shape of the power terminal 3 is changed. As shown in FIG. 14, the tip 30 of the power terminal 3 of this example is bent in a U shape. The side surface of the tip portion 30 is brought into contact with the first main surface 41 of the plate-like portion 40, and the second main surface 41 is irradiated with the laser beam L and welded.

Also in this example, the dimension W1 in the X direction of the tip 30 can be made longer. Therefore, the range in which the laser beam L can be irradiated can be further expanded, and the welding process can be performed more easily.
In addition, the configuration and operational effects are the same as those of the second embodiment.

(Example 5)
In this example, the shape of the semiconductor module 2 is changed. As shown in FIGS. 15 and 16, the power terminal 3 of this example does not protrude from the main body portion 21. The end surface 300 of the power terminal 3 is flush with the surface 210 of the main body 21.

  In this example, as shown in FIG. 17, the end surface 300 of the power terminal 3 is brought into contact with the first main surface 41 of the plate-like portion 40 as in the first embodiment. The power terminal 3 and the bus bar 4 are welded by irradiating the laser beam L from the second main surface 42. As described above, laser welding can concentrate energy in a narrow range and can perform welding in a short time, so that large heat is hardly generated during welding. Therefore, even if the power terminal 3 does not protrude from the main body part 21, large heat is not easily transmitted to the main body part 21.

The effect of this example will be described. In this example, since the power terminal 3 does not protrude from the main body 21, the inductance parasitic on the power terminal 3 can be minimized. Therefore, surge applied to the semiconductor element 20 can be further reduced, and the semiconductor element 20 can be switched at a higher speed.
Moreover, in this example, since the power terminal 3 does not protrude from the main body portion 21, the power conversion device 1 can be easily downsized.
In addition, the configuration and operational effects are the same as those of the first embodiment.

(Example 6)
In this example, the arrangement structure of the semiconductor module 2 and the cooler 11 is changed. As shown in FIGS. 18 and 19, in this example, the semiconductor module 2 is arranged on the surface 219 of the cooler 11. In the semiconductor module 2, six semiconductor elements 20a and 20b (see FIG. 9) are sealed. A plurality of power terminals 3 protrude from the main body 21 of the semiconductor module. The power terminal 3 includes a positive electrode terminal 3a, a negative electrode terminal 3b, and three AC terminals 3c. Each power terminal 3 is in contact with a first main surface 41 of a plate-like portion 40 formed on the bus bar 4. The plate-like portion 40 and the power terminal 3 are welded by irradiating the second main surface 42 of the plate-like portion 40 with a laser or an electron beam.
In addition, the configuration and operational effects are the same as those of the first embodiment.

DESCRIPTION OF SYMBOLS 1 Power converter 2 Semiconductor module 20 Semiconductor element 21 Main-body part 3 Power terminal 30 Front-end | tip part 4 Bus bar 40 Plate-shaped part 41 1st main surface 8 External apparatus

Claims (8)

A main body (21) containing a semiconductor element (20); and a power terminal (3) electrically connected to the semiconductor element (20) and at least partially sealed in the main body (21). A semiconductor module (2);
A bus bar (4) serving as a current path between the semiconductor module (2) and the external device (8);
The bus bar (4) has a plate-like portion (40) welded to the power terminal (3),
The plate-like portion (40) and the power terminal (3) are the main portions on the side where the semiconductor module (2) is disposed, of the two principal surfaces (41, 42) of the plate-like portion (40). The power conversion device (1), wherein the first main surface (41), which is a surface, is subjected to laser welding or electron beam welding in a state in which the tip (30) of the power terminal (3) is in contact with the first main surface (41). ).   A plurality of the semiconductor modules (2) and a plurality of coolers (11) for cooling the semiconductor modules (2) are stacked to form a stacked body (10), and the plate-like portion (40) The length direction (A) in the laminating direction of the plate-like portion (40) is arranged so that the thickness direction thereof is orthogonal to the laminating direction of the laminate (10). The power converter (1) according to claim 1 or 2, wherein the power converter (1) is longer than a dimension (W1) in the stacking direction.   The power converter (1) according to claim 2, wherein a plate thickness (T) of the plate-like part (40) is thinner than a dimension (W1) of the tip part (30) in the stacking direction. .   The power terminal (3) includes a terminal base part (31) protruding in the thickness direction from the main body part (21), and the tip part (30) extends from the tip of the terminal base part (31) to the laminated layer. The power conversion device according to claim 2, wherein the power conversion device projects in a direction.   Each of the semiconductor modules (2) includes a plurality of the power terminals (3), and the plurality of power terminals (3) are positive terminals that are electrically connected to the positive electrode (80) of the DC power supply (8a). (3a), a negative electrode terminal (3b) electrically connected to the negative electrode (81) of the DC power source (8a), and an AC terminal (3c) electrically connected to the AC load (8b), the positive electrode The protruding length from the said main-body part (21) of the terminal (3a), the said negative electrode terminal (3b), and the said alternating current terminal (3c) is mutually equal, The Claim 1 characterized by the above-mentioned. The power converter (1) according to item 1.   The end surface (300) of the power terminal (3) is flush with the surface (210) of the main body (21), according to any one of claims 1 to 3. Power converter (1).   The metal plating layer is formed only on the power terminal (3) of the power terminal (3) and the bus bar (4). The power converter (1) described. A method for manufacturing the power converter (1) according to any one of claims 1 to 7,
A fixing step of fixing the semiconductor module (2) in the case (12);
Contacting the bus bar (4) with the semiconductor module (2) and bringing the tip (30) of the power terminal (3) into contact with the first main surface (41);
A measuring step for measuring the position of the power terminal (3);
Of the two main surfaces (41, 42) of the plate-like portion (40), the side opposite to the first main surface (41) is directed toward the power terminal (3) whose position has been measured in the measurement step. A welding step of welding the plate-like portion (40) and the power terminal (3) by irradiating a laser beam or an electron beam from the second main surface (42) side which is the main surface of
The manufacturing method of the power converter device characterized by performing.

Images