JP4600199B2 - Cooler and power module - Google Patents

Description

  The present invention relates to a cooler that dissipates heat generated by a heating element such as a circuit board on which an electronic component such as a semiconductor chip is mounted, and a power module including the same.

2. Description of the Related Art Conventionally, power modules having an insulating circuit substrate in which metal layers are formed by bonding on both surfaces of insulating ceramics, such as DBA (Al / AlN / Al) and DBC (Cu / AlN / Cu), are known.
This type of power module is an insulating circuit board, a heat sink with one metal layer disposed through a solder layer, and a liquid-cooled heat sink in which the heat sink is provided through a thermally conductive grease layer. The structure provided with a cooler is proposed (for example, refer patent document 1).
The cooler is provided with fins that protrude into the flow path through which the coolant flows, and the cooling area is increased by increasing the contact area with the coolant. Further, this power module is used by bonding a heating element such as a semiconductor chip on an insulating circuit substrate. In use, heat generated by the heating element is conducted to the cooler via the insulating circuit board and the heat radiating plate, and is dissipated by the coolant in the cooler.

In such a power module, in order to make the heat sink uniformly contact with the cooler, both are brought into contact with each other through a heat conductive grease layer. Since it is lower than the used insulating ceramics, metal layer, and heat sink, there is a problem that the thermal resistance from the insulating circuit board to the cooler increases. Therefore, in order not to provide the thermal conductive grease layer, a means for reducing the thermal resistance by integrally molding the heat sink and the fin of the cooler can be considered.
JP 2003-86744 A

  However, the following problems remain in the conventional cooler. That is, in the above-described conventional cooler, considering that the heat sink and the fin are integrally formed as described above, the heat sink and the fin are connected to the open end of the box-like member in which the flow path of the coolant is formed. It is conceivable to cover the box-shaped member from the upper surface side with the integrally formed lid member and fix the lid member to the box-shaped member with screws. However, when the cooling liquid is circulated in the flow path, a force that presses the lid member outward is generated by the liquid pressure. Here, since the lid member is arranged so as to cover from the upper surface side of the box-shaped member, there is a possibility that a gap sufficient for leakage of the cooling liquid is generated between the box-shaped member and the lid member due to the hydraulic pressure. Then, the insulating circuit board may come into contact with the leaked coolant, so that the insulating circuit board may be defective.

  The present invention has been made in view of the above-described problems, and has a good thermal conductivity with an insulating circuit board and a cooler in which the coolant does not easily leak to the outside due to the fluid pressure even when the coolant is circulated. And it aims at providing a power module.

The present invention employs the following configuration in order to solve the above problems. That is, the cooler of the present invention includes a box-shaped base body in which a flow path through which a coolant flows is formed, and a lid that closes the opening of the base body, and the base body is disposed around the opening. By having an edge portion that protrudes inward of the opening, the lid body has a flange portion that abuts the surface of the edge portion on the flow path side, and allows the coolant to circulate, The cooling liquid dissipates heat of the lid body and the base body, and the flange portion of the lid body presses the edge of the base body by the liquid pressure of the cooling liquid, whereby the lid body and the base body Is liquid-tight .

According to the present invention, the heating liquid disposed on the lid is cooled by circulating the cooling liquid in the flow path and dissipating the heat of the lid into the cooling liquid. At this time, the lid body is urged toward the outside of the base body by the fluid pressure of the circulating coolant. Here, an edge portion is formed in the opening of the base body, and the flange portion of the lid body is in contact with the surface of the edge portion on the flow path side, so that the flange portion of the lid body presses the edge portion of the base body. As a result, the lid and the base are liquid-tight, and the coolant is less likely to leak from between the lid and the base. When the liquid pressure of the cooling liquid increases, the flange portion of the lid body presses the edge portion of the base body with a larger force, so that the liquid becomes more liquid-tight. Therefore, for example, even if an insulating circuit board on which an electronic component or the like is mounted is disposed on the lid, the electronic component is prevented from coming into contact with the electronic component, thereby preventing the electronic component from being defective.
Further, since the lid is in contact with the flow path, even when heat is conducted from the insulated circuit board to the lid when the insulated circuit board is fixed on the lid, the heat is promptly transferred to the coolant. Dissipated. Therefore, generation of deformation stress in the lid due to thermal expansion is suppressed by the conduction of heat to the lid. And it prevents that peeling arises in the joining interface of an insulated circuit board and a cover body resulting from this deformation stress. Therefore, good heat dissipation characteristics can be maintained.

In the cooler of the present invention, the base body and the lid body are joined by electron beam bonding or laser welding , a notch is formed at the periphery of the opening of the base body, and the peripheral edge portion of the lid body It is preferable that notches are formed, and these notches have a structure filled with a part of the base body and the lid body melted by electron beam bonding or laser welding .
According to the present invention, the liquid-tight joining is performed by electron beam joining or laser welding, so that leakage of the cooling liquid from between the base body and the lid can be more reliably prevented even by the liquid pressure of the cooling liquid. Moreover, it suppresses that a load is applied to the junction part of a flange part and an edge part.

Moreover, the power module of this invention is equipped with the cooler of the said description, and the insulated circuit board fixed on the said cover body, It is characterized by the above-mentioned.
According to the present invention, since the above-described cooler is provided, it is possible to prevent the coolant from coming into contact with the insulating circuit board and causing defects. Further, it is not necessary to use thermal conductive grease by bonding an insulating circuit board on the lid, and thermal conductivity is improved by reducing the bonding interface as compared with the case of using a heat sink. Furthermore, since generation | occurrence | production of the deformation stress of a cover body is suppressed and it prevents that a peeling arises in the joining interface of a cover body and an insulated circuit board, a thermal conductivity fall can be suppressed. Further, further space saving of the power module can be achieved.

According to the cooler and the power module according to the present invention, even when the lid is subjected to the liquid pressure of the coolant, the flange portion presses the edge toward the outside of the cooler, and the lid and the base are liquid-tight. It becomes. Therefore, the leakage of the coolant is prevented, and the occurrence of a defect in the insulated circuit board due to the leaked coolant coming into contact with the insulated circuit board is suppressed.
Further, the thermal conductivity is improved by eliminating the need for thermal conductive grease and reducing the bonding interface. And even if the heat generated in the insulating circuit board is conducted to the lid, the thermal expansion and the generation of deformation stress due to this are suppressed, and peeling at the bonding interface between the insulating circuit board and the lid is prevented. . Therefore, good heat dissipation characteristics can be maintained.
In addition, space saving of the power module can be achieved.

A power module according to a first embodiment of the present invention will be described below with reference to the drawings.
As shown in FIG. 1, the power module 1 in the present embodiment includes a cooler 2 and an insulating circuit board 3 fixed on the cooler 2, and heat generated in the insulating circuit board 3 is cooled by the cooler. 2 to dissipate.

The cooler 2 is a liquid-cooled heat sink that dissipates the heat conducted by circulating the coolant in the interior of the cooler 2 and has a box-like shape in which a flow path 11 through which the coolant is circulated is formed. The base 12 and the lid 13 that closes the upper opening 12A of the base 12 are configured.
The base 12 is made of, for example, an aluminum alloy die casting (ADC12: JIS standard), which is an Al (aluminum) -Si (silicon) -Cu (copper) alloy, and includes a bottom 14 and a peripheral wall 15 that are separate members. It has. A notch 12B for joining to the lid 13 is formed on the periphery of the upper opening 12A of the base 12. For example, the notch 12B has a depth of 2 mm and a width of 1 mm. Here, you may change suitably the shape of the notch part 12B.
The bottom part 14 is fixed to the peripheral wall part 15 so as to be watertight.
The peripheral wall portion 15 has a quadrangular cylindrical shape, one end of which is in contact with the peripheral edge of the bottom portion 14, and is disposed so as to stand substantially vertically from the peripheral edge. Further, an edge 16 that protrudes toward the opening 12A is formed around the other end of the peripheral wall 15.

The lid 13 is made of an Al—Mg (magnesium) -Si alloy (6063: JIS standard) and includes a flat plate portion 17 and a plurality of protruding fins 18.
The flat plate portion 17 is in close contact with the peripheral edge of the edge portion 16 of the peripheral wall portion 15 and is in contact with the lower surface of the edge portion 16 that is the inner surface of the flow path 11. Here, the edge 16 of the base 12 and the flange 19 of the lid 13 are joined by electron beam joining. Thereby, the base 12 and the lid 13 are watertight. Here, in the electron beam bonding, electrons generated from a filament heated in a vacuum are accelerated to near the speed of light by applying a voltage to collide with a material. The material is welded by using the high heat generated at this time.
The plurality of protruding fins 18 are formed to increase the contact area between the lid 13 and the coolant in the flow path 11, and are perpendicular to the flat plate portion 17 and parallel to each other. Protrusively provided.
Note that a cutout portion 13 </ b> A for electron beam bonding with the base 12 is formed on the periphery of the lid 13. For example, the notch 13A has a depth of 2 mm and a width of 1 mm. Here, you may change suitably the shape of 13 A of notches. The notches 12B and 13A are filled with the base 12 and the lid 13 melted by electron beam bonding. Providing such notches 12B and 13A eliminates the need for extra excision during electron beam bonding, and makes it difficult for the coolant to leak. Furthermore, it becomes difficult to leak by performing a caulking process on the upper part of the weld bead.

The insulated circuit board 3 includes an insulating ceramic 21 and metal layers 22 and 23 disposed on both sides of the insulating ceramic 21, and an electronic component 24 that is a heating element is disposed on the upper surface of the metal layer 22. .
The insulating ceramic 21 is made of a plate-shaped ceramic material such as AlN (aluminum nitride).
The metal layers 22 and 23 are made of a metal having a high thermal conductivity such as Al, and are fixed to the insulating ceramic 21 by brazing. As the brazing material used here, various materials can be applied, but Al-Si, Al-Ge (germanium), Al-Mn (manganese), Al-Cu, Al-Mg, One or more selected from Al—Mg—Si, Al—Cu—Mn, and Al—Cu—Mg—Mn brazing materials are preferred.

A circuit is formed on the metal layer 22 by, for example, etching or the like as appropriate so as to divide the metal layer 22, and the electronic component 24 is fixed by the solder layer 25. Here, as the electronic component 24, for example, a semiconductor chip can be applied, and a power device such as a MOSFET (Metal Oxide Silicon Field Effect Transistor), an IGBT (Insulated Gate Bipolar Transistor), or an IPM (Intelligent Power Module) is used as the semiconductor chip. can give. As the solder, for example, 95% Pb (lead) -5% Sn (tin) or Sn-Ag (silver) -Cu based solder is applicable. A solder containing 95% Pb-5% Sn may be one containing Ag.
The lower surface of the metal layer 23 is bonded to the upper surface of the lid body 13 via the solder layer 26.

In such a power module 1, when driving the electronic component 24, first, a coolant is circulated in the flow path 11. When the electronic component 24 is driven, the heat generated in the electronic component 24 reaches the metal layer 23 via the metal layer 22 and the insulating ceramic 21. The heat reaching the metal layer 23 is conducted to the lid body 13 through the solder layer 26 and is dissipated from the plurality of protrusion fins 18 into the coolant. In this way, the electronic component 24 is cooled.
At this time, when the cooling liquid is circulated in the flow path 11, the lid body 13 is pressed from the inside of the cooler 2 to the outside, that is, upward by the liquid pressure of the cooling liquid. Here, since the upper surface of the flange portion 19 of the lid body 13 is joined to the lower surface of the edge portion 16 of the base body 12, the flange portion 19 of the lid body 13 presses the edge portion 16 of the base body 12. Therefore, the lid 13 and the base 12 are watertight.

According to the cooler 2 and the power module 1 configured as described above, the lid 13 receives the liquid pressure of the coolant in the flow path 11, so that the flange portion 19 presses the edge portion 16 upward. The lid 13 and the base 12 are watertight. Further, the lid 13 and the base 12 are joined by electron beam joining. As a result, the coolant is prevented from leaking from between the lid 13 and the base 12 due to the fluid pressure of the coolant, and the occurrence of defects in the electronic component 24 due to the contact between the leaked coolant and the electronic component 24 is suppressed. To do. Further, it is possible to suppress a load from being applied to the joint portion between the flange portion 19 and the edge portion 16.
Further, the thermal conductivity is improved by eliminating the need for thermal conductive grease and reducing the bonding interface. And even if the heat generated in the electronic component 24 is conducted to the lid body 13, it is possible to suppress the thermal expansion and deformation stress caused by the thermal expansion in the lid body 13. This prevents peeling at the bonding interface between the insulating circuit board 3 and the lid 13 due to deformation stress. That is, since the insulating circuit board 3 and the lid 13 are in good contact, good heat dissipation characteristics can be maintained.
And the size reduction of a power module can be achieved.

Next, a second embodiment will be described with reference to FIG. The embodiment described here has the same basic configuration as the first embodiment described above, and is obtained by adding another element to the first embodiment described above. Therefore, in FIG. 2, the same components as those in FIG.
In the power module 30 according to the second embodiment, the insulating ceramic 21 includes the insulating ceramic 21, the metal layer 22 formed on one surface of the insulating ceramic 21, and the electronic component 24. The insulating ceramic 21 is directly on the lid 13. It is a point that is brazed.

  The power module 30 configured in this manner also has the same functions and effects as those of the first embodiment described above. However, by not providing the metal layer 23, the bonding interface is reduced, and the heat dissipation is further improved. It becomes good.

In addition, this invention is not limited to the said embodiment, A various change can be added in the range which does not deviate from the meaning of this invention.
For example, in the above-described embodiment, the base is configured by die-casting using an Al—Si—Cu-based alloy, but an aluminum alloy using an Al—Si—Mg-based alloy (AC4C: JIS standard) is used. Thus, it may be constituted by other materials and may be formed by a molding method other than die casting.
The lid is made of an Al—Mg—Si based alloy, such as an Al—Mn based alloy (3003: JIS standard) or a high thermal conductive die cast material (for example, Ryoka Max DMS alloy). You may be comprised with the other material which is an aluminum material which has corrosion resistance with respect to a cooling fluid. Further, the bonding between the lid and the insulating circuit board is not limited to soldering, and may be performed by brazing.
In addition, the lid body includes a plurality of projecting fins arranged in parallel to each other, but may include a pin fin projecting perpendicularly to the flat plate portion, and may have other shapes depending on the design. May be.
Further, although the lid and the base are joined by electron beam joining, they may be joined by laser welding. Even if it does in this way, the effect similar to the above-mentioned can be acquired. Furthermore, the lid and the base may be bonded using a liquid gasket or an anaerobic adhesive, and the lid and the base may be watertight using an O-ring or the like. Alternatively, the lid may be liquid-tight by fixing to the base with screws. Moreover, you may combine the joining mentioned above, adhesion | attachment, O-ring, or screwing.
Moreover, although the notch part is formed in the base | substrate and the cover body, respectively, it is good also as a structure which does not form a notch part.

In addition, although two insulating circuit boards are provided on the lid body, one or three or more insulating circuit boards may be provided, and a structure in which a heating element such as an electronic component is not provided may be combined.
Moreover, although the insulating ceramic is made of AlN, any insulating material that can efficiently transfer the heat generated by the heating element to the lid, such as Al ₂ O ₃ (alumina) or Si ₃ N _{4 can be used.} Other insulating materials such as (silicon nitride) and SiC (silicon carbide) may be used.
The metal layer is made of Al, but other metal materials such as Al alloy, pure Cu, and Cu alloy may be used.

  According to the present invention, regarding the cooler and the power module, the thermal conductivity with the insulating circuit board is good, and even if the coolant is circulated, the coolant does not easily leak to the outside due to the fluid pressure. The availability of is recognized.

1 is an overall view showing a power module in a first embodiment of the present invention. It is a general view which shows the power module in the 2nd Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1, 30 Power module 2 Cooler 11 Flow path 12 Base | substrate 12A Opening 13 Cover body 16 Edge part 19 Flange part

Claims (3)

A box-shaped base body in which a flow path through which a coolant flows is formed, and a lid for closing the opening of the base body,
The base has an edge formed to protrude toward the inside of the opening around the opening, and the lid body has a flange portion that contacts the surface of the edge on the flow path side. ,
By circulating the cooling liquid, the heat of the lid and the base is dissipated in the cooling liquid, and the flange portion of the lid presses the edge of the base by the liquid pressure of the cooling liquid. Accordingly , the cooler is characterized in that the lid and the base are liquid-tight . The base and the lid are joined by electron beam joining or laser welding ,
A notch is formed in the periphery of the opening of the base, and a notch is formed in the periphery of the lid. The base and the lid melted by electron beam bonding or laser welding are formed in these notches. The cooler according to claim 1, wherein a part of the body is filled .   A power module comprising: the cooler according to claim 1; and an insulating circuit board fixed on the lid.

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