JP2006294971A - Substrate for power module and its production process - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a substrate for power module in which heat dissipation performance and durability are enhanced. <P>SOLUTION: The substrate 1 for power module comprises: an insulating circuit board 10; a heat sink 20; and a restriction member 30. The insulating circuit board 10 comprises: a wiring layer 11 mounting a power device 7; an insulating substrate 12 bonded to the rear surface of the wiring layer 11; and a heat dissipation layer 12 bonded to the rear surface of the insulating substrate 12. The heat sink 20 is bonded to the rear surface side of the insulating circuit board 10, and a channel 20a for conducting cooling medium 29 is formed internally so that heat of the power device 7 is dissipated. The restriction member 30 is bonded to the rear surface of the heat sink 20 and restricts warping of the heat sink 20 due to difference in linear expansion coefficient between the insulating substrate 12 and the heat sink 20. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a power module substrate.

  Patent Document 1 discloses a conventional power module substrate. The power module substrate includes an insulating circuit substrate, a heat sink bonded to the other surface of the insulating circuit substrate, and a heat sink bonded to the other surface of the heat sink.

  The insulating circuit board includes an aluminum wiring layer, an insulating ceramic insulating board bonded to the other surface of the wiring layer, and an aluminum heat dissipation layer bonded to the other surface of the insulating substrate. When the power module substrate is used, a power device such as a semiconductor chip is mounted on the wiring layer.

  The heat sink is a plate made of aluminum alloy having a thickness of about 3 to 10 mm. The insulating circuit board and the heat radiating plate are joined together by brazing the heat radiating layer of the insulating circuit board directly to the upper surface of the heat radiating plate. Moreover, the heat sink and the heat sink are joined by a plurality of fixing screws.

  A typical heat sink is made of an alloy of aluminum or copper. This heat sink is formed with a coolant channel through which a cooling medium such as water is circulated, so that the heat of the power device can be cooled. More specifically, the heat sink has a horizontally long rectangular cross section, and a coolant channel having a horizontally long rectangular cross section is formed therein. A plurality of fins extending in the vertical direction are formed in the refrigerant flow path, thereby increasing the inner area of the refrigerant flow path in contact with the cooling medium.

  A conventional power module substrate having such a structure is a power module in which a power device is mounted on one surface of a wiring layer. The power module is applied to an inverter circuit of a moving body such as a hybrid car having an electric motor as a drive source, for example, so that the power supplied to the electric motor or the like according to the operating state of the moving body To control. In this power module, high heat generated by the power device is transmitted to the heat sink via the wiring layer, the insulating substrate, the heat dissipation layer, and the heat dissipation plate, and the heat is cooled by the cooling medium flowing in the refrigerant flow path.

At this time, the heat radiating plate and the heat sink have a high temperature due to the heat generated by the power device, and thus tend to thermally expand. In particular, a heat sink or heat sink made of an aluminum alloy or the like having a relatively good thermal conductivity has a relatively large linear expansion coefficient (the linear expansion coefficient of an aluminum alloy is about 23 × 10 ⁻⁶ / ° C.). Become prominent. On the other hand, since the insulating substrate is made of ceramic, the linear expansion coefficient is smaller than that of the heat sink (the linear expansion coefficient of aluminum nitride is about 3.2 × 10 ⁻⁶ / ° C.), and the temperature rises due to the heat generated by the power device. However, there is no tendency for thermal expansion.

  For this reason, if no measures are taken, the heat sink and heat sink are pulled and warped by the heat sink due to the difference in thermal expansion between the heat sink and heat sink and the insulating substrate. Cracks occur in the surface and peeling occurs on each joint surface, resulting in a decrease in durability. In this respect, the power module substrate suppresses warpage of the heat sink and heat sink by adopting a relatively thick heat sink, thereby improving durability.

JP 2003-86744 A

  However, in the above-described conventional power module substrate, a thick heat sink must be interposed between the insulating substrate and the heat sink, which increases the heat conduction path and makes it difficult to improve the heat dissipation performance.

  However, if the heat sink is eliminated and the insulating substrate is joined to the heat sink directly or via the heat dissipation layer, the effect of suppressing the warp by the thick heat sink is lost, so the heat sink warps and the durability decreases. Problems arise.

  This invention is made | formed in view of the said conventional situation, Comprising: It is set as the problem which should be solved to provide the board | substrate for power modules which can implement | achieve the improvement of heat dissipation performance and durability.

The power module substrate of the present invention has a wiring layer on which a power device is mounted on one surface;
An insulating substrate bonded to the other surface of the wiring layer;
A heat sink that is bonded to the other surface side of the insulating substrate and forms a refrigerant flow path for circulating a cooling medium therein to cool the power device;
A restraining member that is bonded to the other surface of the heat sink and restrains the warpage of the heat sink due to a difference in linear expansion coefficient between the insulating substrate and the heat sink is provided.

  The power module substrate of the present invention having such a configuration is a power module in which a power device such as a semiconductor chip is mounted on one surface of a wiring layer. And this power module controls the electric power supplied to an electric motor etc. according to the driving | running state of a moving body by applying to mobile bodies, such as a hybrid car which uses an electric motor as a part of drive source, for example. In this power module, high heat generated by the power device is transmitted to the heat sink via at least the wiring layer and the insulating substrate, and the heat is cooled by the cooling medium flowing in the refrigerant flow path.

  At this time, since the heat sink becomes a high temperature (for example, about 150 ° C.) due to heat generated by the power device, it tends to thermally expand. In particular, when the heat sink is made of aluminum or the like having a relatively good heat conductivity, this tendency becomes remarkable because the linear expansion coefficient is relatively large. On the other hand, since the insulating substrate is made of an insulating material such as an insulating ceramic, the coefficient of linear expansion is smaller than that of the heat sink, and there is no tendency for thermal expansion even when the power device is heated due to heat generation. When the power module substrate of the present invention is used, even if the heat sink tries to extend under the restraint of the insulating substrate due to the difference in coefficient of linear expansion between the insulating substrate and the heat sink, The joined restraining member restrains the warpage of the heat sink, and as a result, the warpage of the heat sink is suppressed.

  When the power module substrate of the present invention is left in a low temperature environment for a long time, even if the heat sink tries to shrink under the constraint of the insulating substrate due to the difference in linear expansion coefficient, The warping in the reverse direction of the heat sink is restrained, and as a result, the warping of the heat sink is suppressed. For example, this power module substrate may be applied to an inverter circuit of a moving body such as a hybrid car, and the moving body may be left outdoors for a long period of time at a cryogenic temperature (eg, about −50 ° C.) below freezing. Equivalent to.

  For this reason, this power module substrate is less likely to cause problems such as cracks in the insulating substrate and peeling off at each bonding surface, and can exhibit high durability.

  In addition, unlike the conventional power module substrate, the power module substrate of the present invention does not include a thick heat sink between the insulating substrate and the heat sink, so that the heat conduction path can be shortened. High heat dissipation performance can also be demonstrated.

  Therefore, the power module substrate of the present invention can realize improvement in heat dissipation performance and durability.

  The power module substrate of the present invention includes a wiring layer, an insulating substrate, a heat sink, and a restraining member. The wiring layer and the insulating substrate may be a conventionally known insulating circuit substrate. A conventionally known insulating circuit board includes a wiring layer, an insulating substrate bonded to the other surface of the wiring layer, and a heat dissipation layer bonded to the other surface of the insulating substrate.

  In the wiring layer, a power device such as a semiconductor chip is mounted on one surface by means such as wire bonding. This wiring layer can be composed of a thin layer of aluminum, copper or the like having a thickness of about 0.4 mm.

The insulating substrate is bonded to the other surface of the wiring layer. This insulating substrate can be constituted by a plate made of an insulating ceramic such as thin aluminum nitride (AlN), alumina (Al ₂ O ₃ ), silicon nitride (Si ₃ N ₄ ) or the like having a thickness of about 1 to 3 mm. From the viewpoint of suitable thermal conductivity, it is preferably made of aluminum nitride.

  The heat sink is bonded to the other surface side of the insulating substrate, and a refrigerant flow path through which a cooling medium is circulated is formed to cool the heat of the power device. This heat sink can be made of aluminum or copper alloy, ceramic such as aluminum nitride, alumina, silicon nitride, silicon carbide (SiC), composite material of silicon carbide and aluminum metal (AlSiC: Aluminum Silicon Carbide), invar (Invar) alloys (alloys composed mainly of nickel and iron), composite materials of Invar alloys and aluminum-based metals, alloys of copper and molybdenum, composite materials of copper oxide and copper, metal-impregnated carbon composites (MICC) : Metal Impregnated Carbon Composites). It is preferably made of a material having good thermal conductivity and low expansion.

  The restraining member may be any member as long as it is bonded to the other surface of the heat sink and restrains the warpage of the heat sink caused by the difference in linear expansion coefficient between the insulating substrate and the heat sink. As a material constituting the restraining member, it is preferable that at least the linear expansion coefficient is smaller than that of the material constituting the heat sink, and it is more preferable that the material is the same as that of the insulating substrate.

  In the power module substrate of the present invention, it is preferable that a heat dissipation layer is provided between the insulating substrate and the heat sink. That is, it is preferable to employ a conventionally known insulating circuit board including a wiring layer, an insulating substrate, and a heat dissipation layer.

  In this case, the joining of the heat dissipation layer and the heat sink can be easily performed by brazing or the like. Further, if the heat dissipation layer has a higher thermal conductivity than the insulating substrate, the heat transmitted from the power device is diffused in the surface direction in the heat dissipation layer, so that the heat dissipation performance can be further improved.

  The heat dissipation layer can be composed of a thin layer of aluminum, copper or the like having a thickness of about 0.4 mm.

  As a conventionally known insulating circuit board, a DBA (Direct Brazed Aluminum (registered trademark)) substrate, a DBC (Direct Bonded Cupper (registered trademark)) substrate, or the like can be adopted.

  In the power module substrate of the present invention, it is preferable that the restraining member has a rigidity capable of restraining expansion of the heat sink.

  In this case, the restraining member can withstand more reliably the force that tries to stretch the other surface of the heat sink that acts when the heat sink tries to warp.

  In the power module substrate of the present invention, it is preferable that the restraining member is disposed symmetrically with respect to the insulating substrate with the heat sink interposed therebetween.

  In this case, when the heat sink is going to thermally expand or contract, the one surface and the other surface are almost equal by the insulating substrate bonded to one surface and the restraining member bonded to the other surface. It will be pulled or pressed by. For this reason, this power module substrate can reliably suppress warping of the heat sink.

  In the power module substrate of the present invention, the restraining member may be made of the same material as the insulating substrate.

  In this case, the restraining member is made of a material having the same linear expansion coefficient and Young's modulus as the insulating substrate. For this reason, when the heat sink tries to thermally expand or contract, the one surface and the other surface are substantially evenly divided by the insulating substrate bonded to one surface and the restraining member bonded to the other surface. It is pulled or pressed by For example, when the insulating substrate itself is employed as the restraining member, one surface and the other surface are evenly pulled or pressed. For this reason, this power module substrate can more reliably suppress the heat sink warpage.

  In the power module substrate of the present invention, the restraining member may be made of alumina, electromagnetic soft iron, or Invar alloy. Since these materials have a relatively low coefficient of linear expansion and a relatively high Young's modulus, the effects of the present invention can be remarkably exhibited when these materials are employed.

The power module substrate according to the present invention includes a first wiring layer on which a first power device is mounted on one surface, a first insulating substrate bonded to the other surface of the first wiring layer, and the first insulation. The heat sink joined to the other surface side of the substrate,
The restraining member includes a second insulating substrate joined to the other surface side of the heat sink, and a second wiring that is joined to the other surface of the second insulating substrate and the second power device is mounted on the other surface. Layer.

  In this case, the power device can be mounted on the other surface of the heat sink while achieving the effects of the present invention. For this reason, the power module can be miniaturized.

  In the power module substrate of the present invention, it is preferable that a heat dissipation layer is provided between the second insulating substrate and the heat sink. That is, on the other surface side of the heat sink, similarly to the one surface side of the heat sink, it is preferable to adopt a conventionally known insulating circuit substrate including the second wiring layer, the second insulating substrate, and the second heat dissipation layer.

The method for manufacturing a power module substrate according to the present invention includes a wiring layer on which a power device is mounted, an insulating substrate, and a heat sink that cools the power device by forming a coolant channel through which a cooling medium flows. And at least a restraining member that restrains warpage of the heat sink caused by a difference in linear expansion coefficient between the insulating substrate and the heat sink, and at least the wiring layer, the insulating substrate, the heat sink, and the restraining member A laminating step of laminating in order to form a laminate;
The laminated body is fired and includes at least a bonding step of bonding the wiring layer, the insulating substrate, the heat sink, and the restraining member.

  The manufacturing method of the board | substrate for power modules of this invention is equipped with a lamination process and a joining process.

  In the laminating step, first, at least a wiring layer, an insulating substrate, a heat sink, and a restraining member are prepared. Next, at least a wiring layer, an insulating substrate, a heat sink, and a restraining member are laminated in this order to form a laminated body. At this time, a bonding material such as a brazing material can be interposed between the above members. Moreover, it is preferable to clamp a laminated body with a jig | tool etc.

  In the joining step, the laminate is fired, and at least the wiring layer, the insulating substrate, the heat sink, and the restraining member are joined. At this time, the heating temperature is set according to the material constituting each member and the bonding material, but is about 600 ° C. in the case of brazing.

  In the power module substrate manufactured by such a procedure, when the laminate is baked in the joining process, the wiring layer, the insulating substrate, the heat sink, and the restraining member constituting the laminate tend to thermally expand each. Show. In particular, when the heat sink is made of aluminum or the like having a relatively good heat conductivity, this tendency becomes remarkable because the linear expansion coefficient is relatively large. On the other hand, since the insulating substrate is made of an insulating material such as an insulating ceramic, the coefficient of linear expansion is smaller than that of the heat sink, and it does not tend to thermally expand even when fired.

  For this reason, if no countermeasure is taken, the wiring layer, the insulating substrate, the heat sink, and the restraining member are joined while the thermal expansion difference between the heat sink and the insulating substrate is generated during firing of the laminate. And after the firing of the laminate, if the temperature of the laminate drops to room temperature, the heat sink that was thermally expanded due to the high temperature will shrink, but at this time, because one surface of the heat sink is bonded to the insulating substrate , Shrinkage is constrained and tends to warp to the other side of the heat sink. For this reason, a crack arises in an insulated substrate or peeling arises in each joining surface, and the fall of a production yield will arise.

  In this regard, the power module substrate manufacturing method of the present invention is to join a restraining member that restrains the heat sink warpage caused by the difference in linear expansion coefficient between the insulating substrate and the heat sink to the other surface of the heat sink. For this reason, when the temperature of a laminated body falls to normal temperature after completion | finish of baking of a laminated body, and a heat sink tries to warp as mentioned above, it restrains so that a restraint member may not shrink | contract on the other surface of a heat sink. For this reason, in this power module substrate, warpage of the heat sink is suppressed, and it is difficult to cause a problem that a crack occurs in the insulating substrate or peeling occurs on each bonding surface.

  Therefore, the method for manufacturing a power module substrate of the present invention can also improve the production yield.

  In the method for manufacturing a power module substrate of the present invention, it is preferable that the laminate has a heat dissipation layer between the insulating substrate and the heat sink.

  In this case, the insulating substrate and the heat sink can be easily joined by brazing or the like. Also, a conventionally known insulated circuit board composed of a wiring layer, an insulating substrate and a heat dissipation layer can be adopted.

  In the method for manufacturing a power module substrate according to the present invention, the laminate includes at least a first wiring layer, a first insulating substrate, the heat sink, a second insulating substrate, and a second wiring layer stacked in this order. possible.

  In this case, a power module substrate capable of mounting the power device on the other surface of the heat sink while producing the effects of the present invention can be manufactured. For this reason, it is possible to reduce the size of the power module while reducing the manufacturing cost.

  In the method for manufacturing a power module substrate according to the present invention, the laminate may include a heat dissipation layer between the second insulating substrate and the heat sink.

  In this case, the second insulating substrate and the heat sink can be easily joined by brazing or the like. Further, if the heat dissipation layer has a higher thermal conductivity than the second insulating substrate, the heat transmitted from the power device is diffused in the surface direction in the heat dissipation layer, so that the heat dissipation performance can be further improved. And also on the other surface side of the heat sink, similarly to the one surface side of the heat sink, a conventionally known insulating circuit substrate composed of the second wiring layer, the second insulating substrate, and the second heat radiation layer can be adopted.

  Embodiments 1 to 4 embodying the present invention will be described below with reference to the drawings. In each drawing, the upper side is the front surface and the lower side is the back surface. Moreover, a pair of arrows described on the front surface and the back surface of the heat sink 20 in each drawing conceptually show the extension of the front surface and the back surface of the heat sink 20, respectively.

Example 1
As shown in FIG. 1, the power module substrate 1 of Example 1 includes an insulating circuit board 10, a heat sink 20 bonded to the back surface of the insulating circuit board 10, and a restraining member 30 bonded to the back surface of the heat sink 20. With.

  The insulated circuit board 10 includes a wiring layer 11, an insulating substrate 12 bonded to the back surface of the wiring layer 11, and a heat dissipation layer 13 bonded to the back surface of the insulating substrate 12.

  The wiring layer 11 is composed of a thin aluminum layer having a thickness of about 0.4 mm. When the power module substrate 1 is used, a power device 7 such as a semiconductor chip is mounted on the wiring layer 11 by means such as wire bonding.

Since the insulating substrate 12 is required to have insulating properties and suitable thermal conductivity, the insulating substrate 12 is made of an insulating ceramic and is made of a thin aluminum nitride plate having a thickness of about 1 mm. Since the linear expansion coefficient of aluminum nitride is 3.2 × 10 ⁻⁶ / ° C., the insulating substrate 12 has a characteristic that it is difficult to thermally expand.

  The heat dissipation layer 13 is composed of a thin aluminum layer having a thickness of about 0.4 mm.

  In the power module substrate 1 of Example 1, a DBA substrate in which the wiring layer 11, the insulating substrate 12, and the heat dissipation layer 13 are bonded in advance is employed as the insulating circuit substrate 10 having such a configuration. The insulated circuit board 10 has a rectangular shape with a length of about 30 mm and a width of about 30 mm.

  The heat sink 20 is made of an aluminum alloy. The heat sink 20 has a horizontally long rectangular cross section having a thickness of about 10 mm, and a refrigerant flow path 20a having a horizontally long rectangular cross section is formed therein. And it is made possible to cool the heat of the power device 7 by circulating the cooling medium 29 such as water in the refrigerant flow path 20a. In addition, a plurality of fins 20b extending in the vertical direction are formed in the refrigerant flow path 20a, thereby increasing the inner area of the refrigerant flow path 20a in contact with the cooling medium 29 and improving the cooling performance.

The restraining member 30 is made of a plate material made of alumina having a thickness of about 1 mm. Since the linear expansion coefficient of alumina is about 5.2 × 10 ⁻⁶ / ° C., like the insulating substrate 12, the constraining member 30 has a characteristic that hardly causes thermal expansion.

  Further, the Young's modulus of alumina constituting the restraining member 30 is about 380 GPa, which is about the same as the Young's modulus (about 310 GPa) of aluminum nitride constituting the insulating substrate 12. Since the Young's modulus of the aluminum alloy constituting the heat sink 20 is about 70 GPa, the Young's modulus of alumina is significantly superior. In this way, the restraining member 30 has a rigidity equal to or higher than that of the insulating substrate 12.

  Further, the restraining member 30 is disposed symmetrically with respect to the insulating substrate 12 with the heat sink 20 interposed therebetween. That is, the restraining member 30 is not only thick but also has the same vertical and horizontal dimensions as the insulating substrate 12 and is disposed directly behind the insulating substrate with the heat sink 20 interposed therebetween.

  The power module substrate 1 according to the first embodiment including the insulating circuit substrate 10, the heat sink 20, and the restraining member 30 is manufactured as follows, for example.

  First, an insulating circuit board 10, which is a DBA board, a heat sink 20, and a restraining member 30 are prepared. As shown in FIG. 1, the insulating circuit board 10, the heat sink 20 and the restraining member 30 are stacked in this order. At this time, a liquid or sheet-like adhesive material (for example, an epoxy resin adhesive) that cures at a temperature from room temperature to about a few hundred degrees Celsius is interposed between the above members, and the laminated members are brought to the curing temperature. The adhesive layers 41 and 42 are formed by heating. Thereby, the board | substrate 1 for power modules to which each member was joined is obtained. At this time, if the curing temperature is not so high, the difference in thermal expansion between the insulating circuit board 10 and the restraining member 30 having a relatively small linear expansion coefficient and the heat sink 20 having a relatively large linear expansion coefficient is not a significant problem. .

  The power module substrate 1 of the first embodiment having such a configuration is a power module in which the power device 7 is mounted on the wiring layer 11. And this power module controls the electric power supplied to an electric motor etc. according to the driving | running state of a moving body by applying to mobile bodies, such as a hybrid car which uses an electric motor as a part of drive source, for example. In this power module, high heat generated by the power device 7 is transmitted to the heat sink 20 via the insulating circuit board 10, and the heat is allowed to cool by the cooling medium 29 flowing in the refrigerant flow path 20 a.

  At this time, the heat sink 20 has a high temperature (for example, about 150 ° C.) due to heat generated by the power device 7, and thus tends to thermally expand. In particular, in Example 1, since the heat sink 20 is made of an aluminum alloy having relatively good thermal conductivity, the linear expansion coefficient is relatively large, and this tendency is remarkable. On the other hand, since the insulating substrate 12 is made of aluminum nitride, the coefficient of linear expansion is smaller than that of the heat sink 20, and even if the power device 7 is heated to a high temperature, it does not tend to expand so much.

  For this reason, as shown in FIG. 2, if the restraining member 30 is not provided, the heat sink 20 extends under the restraint of the insulating substrate 12 due to the difference in the linear expansion coefficient between the insulating substrate 12 and the heat sink 20. As such, the heat sink 20 tends to warp.

  However, the power module substrate 1 according to the first embodiment includes a restraining member 30 as shown in FIG. For this reason, the power module substrate 1 can be used even when the heat sink 20 tends to expand under the restraint of the insulating substrate 12 due to the difference in linear expansion coefficient between the insulating substrate 12 and the heat sink 20 during use. The restraining member 30 joined to the back surface of the 20 restrains the warp of the heat sink 20. As a result, warpage of the heat sink 20 is suppressed.

  Further, when the power module substrate 1 of Example 1 is left in a low temperature environment for a long time, as shown in FIG. 3, if the restraint member 30 is not provided, it is caused by a difference in linear expansion coefficient. Thus, the heat sink 20 tries to shrink under the restraint of the insulating substrate 12.

  Even in this case, in the power module substrate 1 according to the first embodiment, the restraining member 30 restrains the heat sink 20 from warping in the reverse direction. As a result, warpage of the heat sink 20 is suppressed. For example, when the power module substrate 1 is applied to an inverter circuit of a moving body such as a hybrid car, and the moving body is left outdoors for a long time at a cryogenic temperature (eg, about −50 ° C.) below freezing. Corresponds.

  For this reason, this power module substrate 1 is less likely to cause a problem that a crack occurs in the insulating substrate 12 or peeling occurs on each bonding surface, and can exhibit high durability.

  In addition, unlike the conventional power module substrate, the power module substrate 1 of Example 1 does not include a thick heat sink between the insulating substrate 12 and the heat sink 20, so that the power device 7 and the refrigerant flow The distance from the road 20a can be shortened. For this reason, this power module substrate 1 can shorten the heat conduction path, and can also exhibit high heat dissipation performance.

  Therefore, the power module substrate 1 according to the first embodiment can realize improvement in heat dissipation performance and durability.

  Further, in the power module substrate 1, the heat dissipation layer 13 having higher thermal conductivity than the insulating substrate 12 is provided between the insulating substrate 12 and the heat sink 20, so that heat transmitted from the power device 7 is dissipated. In this case, the heat radiation performance can be further improved.

  Further, in the power module substrate 1, the restraining member 30 is made of alumina having a Young's modulus that is significantly superior to that of the heat sink 20, and has rigidity equal to or higher than that of the insulating substrate 12. For this reason, the restraining member 30 has a rigidity capable of restraining the expansion of the heat sink 20, and as a result, the restraining member 30 is more resistant to the force of extending the back surface of the heat sink 20 acting when the heat sink 30 warps. It can withstand reliably.

  In Example 1, alumina is used as the restraining member 30, but even when electromagnetic soft iron or Invar alloy having a relatively low linear expansion coefficient and a relatively high Young's modulus is used, the same reason is used for the reason described above. There is an effect.

(Example 2)
Further, as shown in FIG. 4, a second insulating circuit board 102 that is exactly the same as the insulating circuit board 10 can be used as the power module substrate 1 a of the second embodiment, instead of the restraining member 30.

  In the power module substrate 1a of the second embodiment, the first insulating circuit substrate 101 including the first wiring layer 111, the first insulating substrate 121, and the first heat dissipation layer 131 is bonded to the surface side of the heat sink 20. ing. On the other hand, the second insulating circuit substrate 102 including the second wiring layer 112, the second insulating substrate 122, and the second heat radiation layer 132 is bonded to the back surface side of the heat sink 20.

  In this case, the effects of the present invention can be achieved, and the power device 71 is mounted on the first wiring layer 111 of the first insulating circuit board 101 and the power is applied to the second wiring layer 112 of the second insulating circuit board 102. Since the device 72 can be mounted, the power module can be miniaturized.

(Example 3)
In the power module substrate 1 of the first embodiment, the insulating circuit substrate 10, the heat sink 20 and the restraining member 30 are bonded by an adhesive material, whereas in the power module substrate 2 of the third embodiment shown in FIG. The difference is that the insulating circuit board 10, the heat sink 20, and the restraining member 30 are joined together. Other configurations are the same as those of the power module substrate 1 of the first embodiment, and thus the description thereof is omitted.

  Since the power module substrate 2 of the third embodiment employs brazing of aluminum, the manufacturing method includes a laminating process and a joining process by brazing as follows.

  In the laminating step, first, the insulating circuit board 10, the heat sink 20, and the restraining member 30 are prepared. Next, as illustrated in FIG. 6, the insulating circuit board 10, the heat sink 20, and the restraining member 30 are stacked in this order to form a stacked body 2 a. At this time, aluminum brazing materials 51a and 52a are interposed between the respective members. Further, the laminate 2a is sandwiched by a jig or the like (not shown).

  In the joining step by brazing, the laminated body 2a is disposed in the high temperature furnace 9, and then heated to a high temperature of about 600 ° C. Thereby, the laminated body 2 a is fired, and brazing layers 51 and 52 are formed between the insulating circuit substrate 10 and the heat sink 20 and between the heat sink 20 and the restraining member 30. Thus, the power module substrate 2 in which the insulating circuit substrate 10, the heat sink 20, and the restraining member 30 are joined by brazing is completed.

  In the power module substrate 2 of Example 3 manufactured by such a procedure, when the multilayer body 2a is baked in the bonding step, the wiring layer 11, the insulating substrate 12, the heat dissipation layer 13, and the multilayer body 2a. The heat sink 20 and the restraining member 30 each show a tendency to thermally expand. In particular, in Example 3, since the heat sink 20 is made of an aluminum alloy having relatively good thermal conductivity, the linear expansion coefficient is relatively large, and this tendency becomes remarkable. On the other hand, since the insulating substrate 12 is made of aluminum nitride, the coefficient of linear expansion is smaller than that of the heat sink 20, and there is no tendency for thermal expansion when firing.

  For this reason, as shown in FIG. 7, if the restraining member 30 is not provided, the wiring layer 11, the insulating substrate, while the thermal expansion difference between the heat sink 20 and the insulating substrate 12 remains during firing of the laminate 2 a. 12, the heat radiation layer 13, the heat sink 20, and the restraining member 30 are joined. Then, if the temperature of the laminated body 2a is lowered to room temperature after the completion of the firing of the laminated body 2a, the heat sink 20 that has been thermally expanded due to the high temperature contracts as shown in FIG. Since it is bonded to the insulating substrate 12, the shrinkage is constrained and tends to warp on the back side of the heat sink 20. For this reason, a crack arises in an insulated substrate or peeling arises in each joining surface, and the fall of a production yield will arise.

  In this regard, as shown in FIG. 5, the method for manufacturing the power module substrate 2 of Example 3 is a restraining member 30 that restrains the warp of the heat sink 20 due to the difference in linear expansion coefficient between the insulating substrate 12 and the heat sink 20. Is bonded to the back surface of the heat sink 20. Therefore, as shown in FIG. 6, even when the temperature of the laminated body 2 a is lowered to the normal temperature and the heat sink 20 tends to warp as described above after the firing of the laminated body 2 a, the restraining member 30 remains on the back surface of the heat sink 20. In order not to shrink, it is restrained. As a result, in the power module substrate 2, warpage of the heat sink 20 is suppressed, and it is difficult for a problem that a crack occurs in the insulating substrate 12 or a separation occurs on each bonding surface.

  Therefore, the manufacturing method of the power module substrate 2 of Example 3 can also improve the production yield.

  In the method for manufacturing the power module substrate 2, the laminate 2 a has the heat dissipation layer 13 between the insulating substrate 12 and the heat sink, so that the insulating substrate 12 and the heat sink 20 can be easily joined by brazing. Can be implemented.

  Furthermore, the power module substrate 2 obtained in this way can also exhibit the effect as the product of the present invention described above.

Example 4
In the method for manufacturing the power module substrate 2 of Example 3, as shown in FIG. 4, in the laminate 2 a, the first insulating substrate 101, the heat sink 20, and the second insulating substrate 102 were stacked in this order. The manufacturing method may include a joining method by brazing instead of the joining step by the adhesive material.

  In this case, a power module substrate capable of mounting the power device 7 on the back surface of the heat sink 20 while producing the effects of the present invention can be manufactured. For this reason, it is possible to reduce the size of the power module while reducing the manufacturing cost.

  In the above, the present invention has been described with reference to the first to fourth embodiments. However, the present invention is not limited to the first to fourth embodiments, and can be appropriately modified and applied without departing from the spirit of the present invention. Needless to say.

  For example, in the power module substrate 1 of the first embodiment, a plurality of insulating circuit boards 10 are joined to the front surface side of the heat sink 10, and a plurality of restraining members 30 corresponding to the respective insulating circuit boards 10 are provided on the back side of the heat sink 10. It may be joined to. Moreover, the dimension in each Example is an example, You may change as needed.

  The present invention is applicable to a power module substrate.

1 is a schematic cross-sectional view of a power module substrate of Example 1. FIG. It is a schematic sectional drawing which shows the curvature of the heat sink when it concerns on the board | substrate for power modules of Example 1, and is not provided with the restraint member temporarily. It is a schematic sectional drawing which shows the curvature of the heat sink when it concerns on the board | substrate for power modules of Example 1, and is not provided with the restraint member temporarily. 6 is a schematic cross-sectional view of a power module substrate of Example 2. FIG. 6 is a schematic cross-sectional view of a power module substrate of Example 3. FIG. 6 is a schematic cross-sectional view showing a method for manufacturing a power module substrate of Example 3. FIG. It is a schematic sectional drawing which concerns on the board | substrate for power modules of Example 3, and shows the manufacturing method when not providing the restraint member temporarily. It is a schematic sectional drawing which shows the curvature of the heat sink when it concerns on the board | substrate for power modules of Example 3, and is not provided with the restraint member temporarily.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1, 1a, 2 ... Power module substrate 7, 71, 72 ... Power device 11, 111, 112 ... Wiring layer (111 ... 1st wiring layer, 112 ... 2nd wiring layer)
12, 121, 122 ... Insulating substrate (121 ... First insulating substrate, 122 ... Second insulating substrate)
13, 131, 132 ... heat dissipation layer (131 ... first heat dissipation layer, 132 ... second heat dissipation layer)
DESCRIPTION OF SYMBOLS 20 ... Heat sink 20a ... Refrigerant flow path 29 ... Cooling medium 30 ... Restraint member 41, 42 ... Adhesive layer 51, 52 ... Brazing layer

Claims (12)

A wiring layer on which power devices are mounted on one side;
An insulating substrate bonded to the other surface of the wiring layer;
A heat sink that is bonded to the other surface side of the insulating substrate and forms a refrigerant flow path for circulating a cooling medium therein to cool the power device;
A power module substrate comprising: a restraining member that is bonded to the other surface of the heat sink and restrains warpage of the heat sink caused by a difference in linear expansion coefficient between the insulating substrate and the heat sink.   The power module substrate according to claim 1, wherein a heat dissipation layer is provided between the insulating substrate and the heat sink.   The power module substrate according to claim 1, wherein the restraining member has rigidity capable of restraining expansion of the heat sink.   4. The power module substrate according to claim 1, wherein the restraining member is disposed symmetrically with respect to the insulating substrate with the heat sink interposed therebetween. 5.   The power module substrate according to claim 1, wherein the restraining member is made of the same material as the insulating substrate.   5. The power module substrate according to claim 1, wherein the restraining member is made of alumina, electromagnetic soft iron, or Invar alloy. A first wiring layer on which one of the first power devices is mounted; a first insulating substrate bonded to the other surface of the first wiring layer; and a first insulating substrate bonded to the other surface of the first insulating substrate. Said heat sink,
The restraining member includes a second insulating substrate joined to the other surface side of the heat sink, and a second wiring that is joined to the other surface of the second insulating substrate and the second power device is mounted on the other surface. The power module substrate according to claim 1, further comprising a layer.   The power module substrate according to claim 7, wherein a heat dissipation layer is provided between the second insulating substrate and the heat sink. A wiring layer on which a power device is mounted, an insulating substrate, a heat sink that forms a coolant flow path for circulating a cooling medium therein, and cools the power device, and linear expansion between the insulating substrate and the heat sink A stacking step of preparing at least a restraining member for restraining warpage of the heat sink caused by a difference in coefficient, and laminating at least the wiring layer, the insulating substrate, the heat sink and the restraining member in this order; ,
A method for manufacturing a power module substrate, comprising: firing the laminated body and joining at least the wiring layer, the insulating substrate, the heat sink, and the restraining member.   The method for manufacturing a power module substrate according to claim 9, wherein the laminate includes a heat dissipation layer between the insulating substrate and the heat sink.   11. The laminate according to claim 9, wherein at least the first wiring layer, the first insulating substrate, the heat sink, the second insulating substrate, and the second wiring layer are stacked in this order. Of manufacturing a power module substrate.   The method for manufacturing a power module substrate according to claim 11, wherein the laminate includes a heat dissipation layer between the second insulating substrate and the heat sink.

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