JP2008166356A - Method for manufacturing aluminum heat-sink - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for manufacturing an aluminum water-cooling heat sink for soldering a DBA substrate without nickel plating after vacuum brazing or a method for manufacturing an aluminum water-cooling heat sink provided with the DBA substrate for realizing direct soldering of an electronic component to the surface of the heat-sink. <P>SOLUTION: An aluminum clad material 4 is arranged to the external surface of the heat-sink body 1 via a brazing material 3 and an assembly thereof is integrated with the vacuum brazing process. An Fe or Ni layer is arranged on the Al layer as a clad material 4. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an electronic component to be bonded to the outer surface of an aluminum heat sink via a commercially available heat conductive insulating substrate (hereinafter referred to as a DBA substrate).

Conventionally, in order to cool an electronic component such as a power module, it has been performed in the following procedure to join it to an aluminum heat sink.
First, an aluminum water-cooled heat sink having inner fins is assembled. At this time, it is preferably brazed and fixed integrally by vacuum brazing. Next, nickel plating is applied to the surface of the heat sink. This is a surface treatment for soldering the DBA substrate to the surface of the heat sink. Next, a DBA substrate is soldered to the surface of the heat sink. Furthermore, electronic components were soldered on the DBA substrate.

  In addition, the heat sink described in the following Patent Document 3 describes that the DBA substrate is brazed directly to the surface of the heat sink in the brazing process and the nickel plating process is omitted. The DBA substrate used at this time is a special one, and is not a DBA substrate having a nickel plating applied to the surface which is widely marketed. This is because the surface nickel plating deteriorates due to vacuum brazing in a commercially available DBA substrate during brazing. This is because the electronic component cannot be soldered to the surface later.

JP-A-2005-123260 JP 2002-170915 A JP 2001-168869 A

In the first heat sink manufacturing method, the surface of the heat sink needs to be nickel-plated after brazing, and the cost of the heat sink is increased due to an increase in equipment costs and man-hours.
The manufacturing method of the second heat sink has a problem that it cannot be used a commercially available nickel plated DBA substrate, and a special DBA substrate is used, resulting in high cost.

  Therefore, the present invention provides a method of manufacturing an aluminum heat sink that can directly solder a commercially available DBA substrate without applying nickel plating after vacuum brazing, or without applying nickel plating after brazing of the heat sink. It is an object of the present invention to provide a method of manufacturing an aluminum heat sink having a DBA substrate that can directly solder components.

The present invention according to claim 1 is a method of manufacturing an aluminum heat sink in which an electronic component is bonded to the outer surface of a heat sink body (1) via a heat conductive insulating substrate (hereinafter referred to as DBA substrate (2)).
Assembling the heat sink, placing the aluminum clad material (4) on the outer surface of the heat sink body (1) via the brazing material (3),
And vacuum brazing these assemblies together,
A DBA substrate (2) is bonded to the outer surface of the clad material (4) via solder (5), and an electronic component is bonded to the DBA substrate (2) via solder (5).
The DBA substrate (2) consists of a ceramic (6) such as aluminum nitride coated with nickel plating on both sides of an aluminum material (7).
The clad material (4) is an aluminum heat sink manufacturing method characterized in that it has one of the following structures in order from the surface side of the heat sink body (1).
Al layer-Fe layer-Cu layer Al layer-Fe layer-brass layer Al layer-Fe layer-Cupro (Cu-Ni) layer Al layer-Ni layer Al layer-Ni alloy layer

According to a second aspect of the present invention, there is provided an aluminum heat sink manufacturing method in which an electronic component is bonded to the outer surface of a heat sink body (1) via a DBA substrate (2).
While assembling the heat sink, a DBA substrate (2) is placed on the outer surface of the heat sink body via a brazing material (3), and an aluminum clad material (a brazing material (3) is placed on the surface of the DBA substrate (2) ( 4) arranging,
Fixing the assemblies together by vacuum brazing,
An electronic component is configured to be bonded to the outer surface of the clad material (4) via solder (5),
The DBA substrate (2) consists of a ceramic (6) such as aluminum nitride coated with nickel plating on both sides of an aluminum material (7).
The clad material (4) is an aluminum heat sink manufacturing method characterized in that it has one of the following structures in order from the surface side of the heat sink body (1).
Al layer-Fe layer-Cu layer Al layer-Fe layer-brass layer Al layer-Fe layer-Cupro (Cu-Ni) layer Al layer-Ni layer Al layer-Ni alloy layer

The method of manufacturing a heat sink according to claim 1 is a method of disposing an aluminum clad material 4 on the outer surface of an assembled heat sink via a brazing material 3 and integrally vacuum brazing the clad material. 4, since the Fe layer or the Ni layer exists in the Al layer, the DBA substrate 2 can be bonded to the outer surface of the clad material 4 through the solder 5 as it is.
That is, the step of applying nickel plating to the surface of the heat sink as in the conventional heat sink can be omitted, and the number of manufacturing steps of the heat sink is reduced and the nickel plating facility is not required. Thereby, a heat sink can be provided at low cost.

According to the second aspect of the present invention, the DBA substrate 2 is disposed on the outer surface of the heat sink body 1 via the brazing material 3, and the clad material 4 made of aluminum is disposed on the DBA substrate 2 via the brazing material 3. Therefore, the electronic component 10 can be joined directly to the outer surface of the clad material 4 via the solder 5.
In this case, there is an effect that the electronic component 10 can be attached very easily. At the same time, the step of applying nickel plating to the surface of the heat sink body 1 can be omitted.

Next, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is an explanatory longitudinal sectional view showing a first embodiment of the present invention.
The heat sink 9 is provided with an inner fin 8 inside an aluminum heat sink body 1, and a pair of cooling water inlet / outlet pipes 11 (one is omitted) communicates with the inside of the heat sink body 1. A clad material 4 is previously fixed to the outer surface of the heat sink main body 1 via a brazing material 3. The electronic component 10 is attached by the following procedure. First, the DBA substrate 2 is bonded to the outer surface of the clad material 4 via the solder 5, and the electronic component 10 is bonded to the surface of the DBA substrate 2 via the solder 5. And, such a heat sink 9 is one in which the clad material 4, the heat sink body 1 and the inner fin 8 are assembled and brazed and fixed together by vacuum brazing.

The clad material 4 is any one of (A) to (E) in FIG. That is, they are Al layer-Fe layer-Cu layer (A), Al layer-Fe layer-brass layer (B), Al layer-Ni layer (C), Al layer-Ni alloy layer from the surface side of the heat sink 9 (D), Al layer-Fe layer-Cupro (Cu-Ni) layer (E).
Note that 24Fe-16Cr-Ni, 20Cr-Ni18, or the like can be used as the Ni alloy. Further, ferritic stainless steel may be used instead of Fe.

Each of the clad materials 4 has an Fe or Ni-based layer on the surface or in the middle. It was found that the clad material without them melted the aluminum material of the clad material 4 in the vacuum brazing process.
For example, when copper is interposed on the surface of an aluminum material as the clad material 4, the melting point of the original aluminum, 660 ° C., is lowered to 548 ° C. due to the diffusion of copper. However, vacuum brazing of the aluminum heat sink is usually performed at 600 ° C., so that the aluminum material in the clad material is melted. On the other hand, even if Fe and Ni diffuse into aluminum and copper (or vice versa), the melting point of aluminum does not decrease.

When a commercially available DBA substrate having a nickel plating on the surface is used during vacuum brazing, the nickel plating on the surface deteriorates, but the nickel clad on the clad material 4 does not deteriorate.
This is due to the following reason. The nickel plating on the surface of the DBA substrate for soldering is usually Ni-P electroless plating. This plating is poor in high-temperature oxidation and deteriorates at about 350 ° C. and cannot be soldered. The cause is presumed that the plating crystallizes by heat. However, metallic nickel or the like is not substantially changed by merely evaporating some Ni atoms from the surface in a vacuum furnace at about 600 ° C.

The heat sink structure of FIG. 1 can be illustrated as shown in FIG. That is, the clad material 4 is integrally brazed and fixed to the surface of the heat sink 9 via the brazing material 3 in advance. A commercially available DBA substrate 2 is bonded to the surface of the clad material 4 via solder 5.
As shown in FIG. 5, a commercially available DBA substrate 2 has an aluminum material 7 interposed on both sides of a ceramic 6 (aluminum nitride) via a brazing material, and nickel plating 13 is coated on the surfaces of both aluminum layers. It is a thing.

Next, FIG. 2 is a longitudinal cross-sectional explanatory view of a heat sink showing a second embodiment of the present invention.
The heat sink body 1, inner fin 8, and cooling water inlet / outlet pipe 11 are the same as those in FIG. In this heat sink, the DBA substrate 2 is placed on the surface of the heat sink body 1 via the brazing material 3, and the clad material 4 is placed on the surface of the DBA substrate 2 via the brazing material 3. These assemblies are inserted into a vacuum furnace, and each contact portion is integrally brazed and fixed.
The DBA substrate 2 is commercially available, and as described above, the nickel plating 13 is coated on both surfaces of the ceramic 6 such as aluminum nitride via the aluminum material 7.

In the heat sink thus formed, the electronic component 10 is bonded to the surface of the clad material 4 via the solder 5. Then, the cooling water flows in from one cooling water inlet / outlet pipe 11, flows through the heat sink body 1, flows out from the other cooling water inlet / outlet pipe 11, and is heat-exchanged by a cooling water cooling heat exchanger (not shown). Then, the cooling water again flows in the heat sink body 1 and absorbs the heat generated by the electronic component 10.
The structure of the heat sink of FIG. 2 is illustrated as shown in FIG. That is, the DBA substrate 2 is bonded to the surface of the heat sink 9 via the brazing material 3, and the clad material 4 is bonded to the surface of the DBA substrate 2 via the brazing material 3.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a longitudinal sectional explanatory view of a heat sink 9 showing a first embodiment of the present invention. Explanatory drawing of the longitudinal cross-section of the heat sink 9 which shows the 2nd Embodiment of this invention Explanatory drawing of the structure of the heat sink 9 in FIG. Explanatory drawing of the structure of the heat sink 9 in FIG. Explanatory drawing of the commercially available DBA board | substrate 2 used for the heat sink 9. FIG. Explanatory drawing which shows each structure of the clad material 4. FIG.

Explanation of symbols

1 Heat sink body 2 DBA substrate 3 Brazing material 4 Clad material 5 Solder 6 Ceramic

7 Aluminum material 8 Inner fin 9 Heat sink
10 Electronic components
11 Cooling water inlet / outlet pipe
12 Cooling water
13 Nickel plating

Claims (2)

In an aluminum heat sink manufacturing method in which electronic components are bonded to the outer surface of the heat sink body (1) through a heat conductive insulating substrate (hereinafter referred to as DBA substrate (2)),
Assembling the heat sink, placing the aluminum clad material (4) on the outer surface of the heat sink body (1) via the brazing material (3),
And vacuum brazing these assemblies together,
A DBA substrate (2) is bonded to the outer surface of the clad material (4) via solder (5), and an electronic component is bonded to the DBA substrate (2) via solder (5).
The DBA substrate (2) consists of a ceramic (6) such as aluminum nitride coated with nickel plating on both sides of an aluminum material (7).
The method for manufacturing an aluminum heat sink, wherein the clad material (4) has one of the following structures in order from the surface side of the heat sink body (1).
Al layer-Fe layer-Cu layer Al layer-Fe layer-brass layer Al layer-Fe layer-Cupro (Cu-Ni) layer Al layer-Ni layer Al layer-Ni alloy layer In the manufacturing method of an aluminum heat sink in which electronic parts are joined to the outer surface of the heat sink body (1) via the DBA substrate (2),
While assembling the heat sink, a DBA substrate (2) is placed on the outer surface of the heat sink body via a brazing material (3), and an aluminum clad material (a brazing material (3) is placed on the surface of the DBA substrate (2) ( 4) arranging,
Fixing the assemblies together by vacuum brazing,
An electronic component is configured to be bonded to the outer surface of the clad material (4) via solder (5),
The DBA substrate (2) consists of a ceramic (6) such as aluminum nitride coated with nickel plating on both sides of an aluminum material (7).
The method for manufacturing an aluminum heat sink, wherein the clad material (4) has one of the following structures in order from the surface side of the heat sink body (1).
Al layer-Fe layer-Cu layer Al layer-Fe layer-brass layer Al layer-Fe layer-Cupro (Cu-Ni) layer Al layer-Ni layer Al layer-Ni alloy layer

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