JP2005033123A - Semiconductor power module - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a low-cost semiconductor power module which ensures a predetermined spatial distance when used for a case in which comparatively high voltage is required to be applied to a terminal. <P>SOLUTION: The semiconductor power module 2 comprises a power semiconductor device 6a, a plate lead frame 4 for mounting the device 6a, and a plate heat sink 10 facing the rear of the lead frame 4. The device 6a, the lead frame 4 and the heat sink 10 are sealed with a resin so that a plurality of terminals 4a of the lead frame 4 and a rear 10a of the heat sink 10 are exposed. A radiating member 14 is provided facing the rear 10a of the heat sink 10. A metal spacer 16 is provided between the heat sink 10 and the radiating member 14. The spacer 16 has a thickness for ensuring the predetermined spatial direction between the surface of the radiating member 14 and the plurality of terminals 4a of the lead frame 4. As the heat sink 10 can be made from a plate member having a sufficient thickness for enabling punching process, the costs of the semiconductor power module can be reduced. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a semiconductor power module.

  2. Description of the Related Art Conventionally, as a semiconductor power module used for, for example, an inverter device, a module including a power semiconductor element and a plate-like lead frame on which the element or the like is mounted is known (see, for example, Patent Document 1). In this semiconductor putter module, the power semiconductor element is connected to the lead frame lead via a wire. A plate-shaped heat sink having a main surface facing the main surface opposite to the surface on which the power semiconductor element is mounted with a gap is provided. The heat sink is made of a metal having good thermal conductivity. The power semiconductor element, the lead frame, the heat sink, and the like are resin-sealed so that the heat sink main surface opposite to the main surface facing the lead frame and a plurality of terminals of the lead frame are exposed. The gap between the opposing main surfaces of the lead frame and the heat sink is also filled with resin so as to electrically insulate the lead frame and the heat sink. The heat sink is in contact with the heat radiating member through the main surface which is the exposed surface.

  When a predetermined voltage is applied to a lead frame terminal to operate such a semiconductor power module and a current flows through the power semiconductor element, a large amount of heat is generated in the element, but this heat is transmitted to the heat dissipation member via the heat sink. Dissipated.

JP 9-153574 A

  In the semiconductor power module as described above, in order to ensure electrical insulation between the terminal to which the voltage is applied and the heat radiating member, “space distance” which is the shortest distance passing through the space between the terminal and the heat radiating member. It is necessary to ensure a predetermined value or more (for example, 2 mm) according to the applied voltage (for example, 600 V). However, in order to use the semiconductor power module having the above configuration for applying a relatively high voltage (for example, 1200 V), it is necessary to secure a longer distance for the “spatial distance”. The thickness must be increased (for example, thickness 10 mm). Conventionally, a heat sink has been manufactured by punching a plate material in order to process it into a specific shape corresponding to the shape of a lead frame or the like having a predetermined pattern shape facing it. However, when the thickness of the heat sink is increased, punching is difficult, and for example, it is necessary to perform machining, which causes a problem that the manufacturing cost of the heat sink and thus the module is significantly increased.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a semiconductor power module for use in applications where the applied voltage is relatively high, in which a heat sink can be easily manufactured, and thus an inexpensive module.

In order to achieve the above object, a semiconductor power module according to the present invention includes:
A power semiconductor element;
A first main surface on which the power semiconductor element is mounted, and a plate-like lead frame having a second main surface opposite to the first main surface and electrically connected to the power semiconductor element; ,
A third main surface facing the second main surface of the lead frame, and a plate-shaped heat sink having a fourth main surface on the opposite side of the third main surface,
In the semiconductor power module in which the power semiconductor element, the lead frame, and the heat sink are resin-sealed so that the plurality of terminals of the lead frame and the fourth main surface of the heat sink are exposed,
A heat dissipating member having a surface facing the fourth main surface of the heat sink and thermally connected to the heat sink;
A heat dissipating member having a fifth main surface in contact with the fourth main surface of the heat sink and a sixth main surface in contact with the surface of the heat dissipating member located on the opposite side of the fifth main surface; A plate-shaped metal spacer having a thickness such that a predetermined spatial distance is secured between the surface of the lead frame and the plurality of terminals of the lead frame;
Is further provided.

  Here, the predetermined spatial distance means that the distance is not less than a distance corresponding to the withstand voltage of the semiconductor power module.

  According to the present invention, in a semiconductor power module used for an application in which a relatively high voltage is applied to a terminal, a predetermined spatial distance can be secured even if the heat sink is thinned. As a result, the cost of the semiconductor power module can be reduced.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

Embodiment 1 FIG.
1 is an external view showing a first embodiment of a semiconductor power module according to the present invention, and FIG. 2 is a cross-sectional view taken along line II-II in FIG. The semiconductor power module 2 includes a plate-like lead frame 4 formed in a predetermined pattern shape. A plurality of semiconductor elements 6 (for example, an IGBT 6a as a power semiconductor element and an IC 6b as an element for driving the element) are bonded to the surface of the lead frame 4 with a brazing material depending on the use and purpose of the semiconductor power module 2. Has been implemented. Each electrode of the semiconductor element 6 is connected to a lead (not shown) of the lead frame 4 through a bonding wire 8. These bonding wires 8 are fine metal wires such as gold and aluminum.

  A plate-shaped heat sink 10 made of a metal having good thermal conductivity, such as aluminum, is provided facing the back surface of the lead frame 4 opposite to the surface on which the semiconductor element 6 is placed. A gap is provided between the lead frame 4 and the heat sink 10. The heat sink 10 has a relatively small thickness (for example, 2 to 3 mm), for example, a predetermined pattern corresponding to the shape of the opposing lead frame, the arrangement of the semiconductor elements 6a and 6b, etc. by punching a heat sink material having a rectangular outer shape. It is formed in a shape. In the example shown in the figure, the IGBT 6a, which is a power semiconductor element, generates more heat during operation than the IC 6b. Therefore, the heat sink 10, which is a heat path, is larger than the gap between the lead frame portion on which the IC 6b is placed. The gap with the lead frame portion on which the IGBT 6a is placed is reduced. However, the thickness may be made equal over the entire surface direction of the heat sink 8 in consideration of the ease of processing.

  Various components such as the lead frame 4, the semiconductor element 6, the bonding wire, and the heat sink 10 of the semiconductor power module 2 are flat on the opposite side of the main surface of the lead frame 4 facing the lead frame 4 and the terminals 4 a of the lead frame 4. It is sealed with an electrically insulating resin 12 so that the main surface (back surface) 10a is exposed. The gap between the lead frame 4 and the heat sink 10 is also filled with the resin 12, thereby ensuring electrical insulation between the two. The resin 12 has good thermal conductivity, and therefore the lead frame 4 and the heat sink 10 are thermally connected.

  A terminal (high voltage terminal) 4a of the lead frame 4 is for operating a semiconductor power module 2 by applying a predetermined voltage from an external power source (not shown). In the present embodiment, a relatively high voltage (for example, 1200V) is applied. The front end side of each terminal 4 a is bent in a direction away from the back surface 10 a of the heat sink 10.

  A heat dissipating fin (a heat dissipating member in a broad sense) 14 having a flat surface 14a is provided opposite to the heat sink back surface 10a (FIG. 1 shows only a part of the flat surface 14a of the heat dissipating fin 14). The heat radiating fins 14 are made of, for example, aluminum or iron. The heat radiating fins 14 are grounded. Furthermore, between the heat sink 10 and the radiation fin 14, the plate-shaped metal spacer provided with the flat main surface in surface contact with the heat sink back surface 10a and the flat main surface in surface contact with the heat dissipation fin flat surface 14a. 16 is provided. The heat sink 10 and the metal spacer 16 and the metal spacer 16 and the heat radiation fin 14 are connected to each other via fixing means such as bolts (not shown). The metal spacer 16 is made of, for example, aluminum or copper having good thermal conductivity. Therefore, the heat sink 10 and the radiation fin 14a are thermally connected. The thickness of the metal spacer 16 is set so that the spatial distance between the terminal 4a and the flat surface 14a of the radiating fin 14 is not less than a value corresponding to the withstand voltage of the module 2 (for example, 10 mm). The metal spacer 16 may be prepared, for example, in a rectangular shape according to the outer shape of the heat sink 10, and the metal spacer 16 can be easily manufactured even when the thickness is increased.

  When a predetermined voltage is applied from the external power source to the terminal 4a of the lead frame 4 during the operation of the semiconductor power module 2 configured as described above, a large amount of heat generated in the semiconductor element 6, particularly the power semiconductor element 6a, is generated. The heat is transmitted to the metal spacer 16 through the heat sink 10 and further radiated to the heat radiating fins 14.

  The heat radiation fin 14 and the metal spacer 16 may be made of the same material, but may be made of different materials. In the case of using different materials, the degree of freedom in selecting the material of the heat radiating fins 14 is increased, and an inexpensive semiconductor power module 2 can be provided by using an inexpensive material such as iron.

  Moreover, it is preferable that the surface area of the heat radiating member 14 in contact with the atmosphere is set larger than the surface area of the metal spacer 16 in contact with the atmosphere. This has the advantage that the heat radiating member 14 can be made of an inexpensive material having a lower thermal conductivity than the metal spacer 16, and as a result, the cost of the semiconductor power module can be reduced. Considering this point, a heat radiating fin is preferable as the heat radiating member 14.

  As understood by those skilled in the art, the “creeping distance” that is the shortest distance along the surface of the resin package 12 between the terminal 4a and the metal spacer 16 or the heat sink 10 is equal to or greater than the value corresponding to the withstand voltage. Must be set. In the illustrated example, the outer shape of the heat sink 10 and the outer shape of the metal spacer 16 are substantially equal so that the back surface 10a of the heat sink 10 is not exposed to the atmosphere. However, the metal spacer 16 extends beyond the periphery of the heat sink back surface 10a. May be present. In these two cases, the creepage distance is the creepage distance between the terminal 4 a and the metal spacer 16. On the other hand, the metal spacer 16 may recede to the inside of the periphery of the heat sink back surface 10a and a part of the back surface 10a of the heat sink 10 may be exposed to the atmosphere. In this case, the creepage distance is between the terminal 4a and the heat sink 10. The creepage distance.

  Further, the semiconductor power module according to the present embodiment is not limited to a structure in which a plurality of lead frame terminals 4a protrude from two opposing side walls of the resin package 12, as shown in FIG.

  According to the present embodiment, it is possible to use the heat sink 10 that can be manufactured from a plate-like material having a thickness that can be punched while ensuring the spatial distance between the terminal 4a and the flat surface 14a of the radiating fin at a predetermined value. Therefore, an inexpensive semiconductor power module can be provided.

Embodiment 2. FIG.
FIG. 3 is a cross-sectional view similar to FIG. 2 of the second embodiment of the semiconductor power module according to the present invention. Hereinafter, the same reference numerals are used for the same components as those in the first embodiment. The semiconductor power module 20 according to the present embodiment does not include a heat dissipation member, and the module 20 is installed in a box 22 that forms a part of an external device (not shown). The box 22 is manufactured by bending a metal plate such as aluminum or iron having a thickness of 1 to 2 mm, for example. The heat sink 10 of the semiconductor power module 2 is fixed on the flat bottom surface 22a of the box 22 via the metal spacer 16, so that the shortest distance in the space between the terminal 4a and the metal box 22, The spatial distance between the terminal 4a and the metal box bottom surface 22a is set to be equal to or greater than the value corresponding to the withstand voltage. Thus, in this embodiment, the external box 22 for module installation can be used as a heat radiating member by providing the metal spacer 16 between the heat sink 10 and the metal box bottom surface 22a.

  According to the present embodiment, it is possible to use the heat sink 10 that can be manufactured from a plate-like material having a thickness that can be punched while securing the spatial distance between the terminal 4a and the metal box bottom surface 22a to a predetermined value. Therefore, an inexpensive semiconductor power module can be provided.

  While specific embodiments according to the present invention have been described above, the present invention is not limited to these and can be variously modified. For example, in the above embodiment, the heat dissipation member 14 (metal box 22) has a flat surface, and the shortest distance between the flat surface and the terminal 4a of the lead frame 4 is equal for all the terminals 4a. Is applied to only a part of the terminal 4a, and a space distance between the high voltage terminal and the heat radiating member 14 (metal box 22) is secured, the heat radiating member 14 (metal box 22) The portion other than the portion in surface contact with the metal spacer 16 need not be flat.

1 is an external view showing a first embodiment of a semiconductor power module according to the present invention. Sectional drawing along the II-II line of FIG. Sectional drawing similar to FIG. 2 which shows Embodiment 2 of the semiconductor power module which concerns on this invention.

Explanation of symbols

2, 20: Semiconductor power module 4: Lead frame 4a: Lead frame terminals 6a, 6b: Semiconductor element 10: Heat sink 12: Resin package 14: Radiation fin 14a: Radiation fin flat surface 16: Metal spacer 22: External metal box 22a: Metal box bottom

Claims (5)

A power semiconductor element;
A first main surface on which the power semiconductor element is mounted, and a plate-like lead frame having a second main surface opposite to the first main surface and electrically connected to the power semiconductor element; ,
A third main surface facing the second main surface of the lead frame; and a plate-shaped heat sink having a fourth main surface on the opposite side of the third main surface;
In the semiconductor power module in which the power semiconductor element, the lead frame, and the heat sink are resin-sealed so that the plurality of terminals of the lead frame and the fourth main surface of the heat sink are exposed,
A heat dissipating member having a surface facing the fourth main surface of the heat sink and thermally connected to the heat sink;
A heat dissipation member having a fifth main surface in contact with the fourth main surface of the heat sink and a sixth main surface in contact with the surface of the heat dissipation member located on the opposite side of the fifth main surface; A plate-like metal spacer having a thickness such that a predetermined spatial distance is ensured between the surface of the lead frame and the plurality of terminals of the lead frame;
A semiconductor power module further comprising: 2. The semiconductor power module according to claim 1, wherein the heat dissipating member and the metal spacer are made of different materials. 3. The semiconductor power module according to claim 1, wherein the surface area of the heat dissipating member is set larger than the surface area of the metal spacer. The semiconductor power module according to any one of claims 1 to 3, wherein the heat sink is manufactured by punching a plate-like material. A power semiconductor element;
A first main surface on which the power semiconductor element is mounted, and a plate-like lead frame having a second main surface opposite to the first main surface and electrically connected to the power semiconductor element; ,
A third main surface facing the second main surface of the lead frame; and a plate-shaped heat sink having a fourth main surface on the opposite side of the third main surface;
In the semiconductor power module in which the power semiconductor element, the lead frame, and the heat sink are resin-sealed so that the plurality of terminals of the lead frame and the fourth main surface of the heat sink are exposed to the outside,
The semiconductor power module is thermally connected to an external metal plate having a surface facing the fourth main surface of the heat sink,
A fifth main surface that contacts the fourth main surface of the heat sink, and a sixth main surface that is located on the opposite side of the fifth main surface and contacts the surface of the metal plate; A plate-like metal spacer having a thickness such that a predetermined spatial distance is ensured between the surface of the lead frame and the plurality of terminals of the lead frame;
A semiconductor power module further comprising:

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