JP5387342B2 - heatsink - Google Patents

Description

  The present invention relates to a heat sink to which a heating element such as an LED element is attached.

  As an automobile light using an LED (light emitting diode) element, an LED element is attached to the surface on the front side of the substrate provided at the bottom of the light housing, and the heat of the LED element is dissipated on the surface on the back side of the substrate. There is a thing to which the heat sink for attaching is attached (for example, refer patent document 1).

  Such a heat sink is formed by die casting using an aluminum alloy as disclosed in Patent Document 2, for example. Specifically, a molten aluminum alloy is injected into a cavity of a die casting mold in which a fixed mold and a movable mold are combined, and the aluminum alloy is cooled and solidified in the mold. Then, after the aluminum alloy is solidified in the mold to form a heat sink, the movable mold is separated from the fixed mold and the heat sink is taken out.

  In addition, when the movable mold is separated from the fixed mold, the holding force of the heat sink with respect to the movable mold and the fixed mold is set so that the heat sink is held in the movable mold. And when taking out a heat sink from a movable mold | type, the heat sink is extruded with the extrusion pin integrated in the inside of a movable mold | type. Therefore, an extruding portion having a circular cross section that is pressed by the extruding pin is formed at the front end edge portion of the radiating fin formed on the heat sink.

JP-T 2009-517813 (paragraph 0010, FIG. 1) JP 2001-316748 A (paragraphs 0012 to 0018)

  In the above-described conventional heat sink, as shown in FIG. 7, the extruded section 140 having a circular cross section formed at the front end edge of the radiating fin 130 protrudes greatly on both sides of the radiating fin 130. , 130 has a problem that the air fluidity is lowered, and consequently the heat dissipation efficiency is lowered.

  Accordingly, an object of the present invention is to provide a heat sink that solves the above-described problems and can increase the heat dissipation efficiency while sufficiently securing the cross-sectional area of the extruded portion.

In order to solve the above-described problems, the present invention includes a main body having a base portion on which a heating element mounting portion is formed and a plurality of heat dissipating fins standing on the base portion, and is formed by die casting. An extruding portion that is pressed by an extruding pin provided on the die when the main body portion is taken out from the die casting die is formed at the tip edge portion of the at least one radiating fin. The extrusion part is formed in a rectangular cross section, protrudes on one side surface of the radiating fin, and the main body part has a first region including the extrusion part by a first mold. Formed, and a second region other than the first region is formed by a second mold, and the pushing portion is formed by a notch provided on a side surface of the first die. as a feature that you are That.

  In this structure, since the extrusion part is formed in the rectangular cross section, the cross-sectional area of an extrusion part is fully securable by expanding the cross section of an extrusion part in the width direction of an extrusion part. In other words, according to this configuration, the amount of protrusion of the extruding part from the side surface of the radiating fin can be reduced as compared with the case where the extruding part is formed in a circular cross section. The heat dissipation efficiency of the heat sink can be increased.

Moreover, by dividing | segmenting a 1st metal mold | die and a 2nd metal mold | die, since the notch part of a 1st metal mold | die can be exposed outside, the maintainability of a metal mold | die can be improved.
Moreover, since the notch part for forming an extrusion part is formed by processing the side surface of a 1st metal mold | die, the process of a metal mold | die can be simplified.
In addition, when the attachment part of the heating element is formed in the first region, when the shape of the attachment part is changed, only the first mold is prepared without newly creating the entire mold. Since it suffices to create a new one, the manufacturing cost of the mold can be reduced.

  In the heat sink described above, a plurality of the extruding portions may be formed in the first region, and each of the extruding portions may be arranged around the mounting portion.

  In this configuration, since a plurality of extruding parts are arranged around the mounting part with a complicated shape, the heat sink can be smoothly released from the first mold by pressing each extruding part with an extruding pin. Can do.

In the heat sink described above, the main body can be formed by die casting using an aluminum alloy material. Here, as described above, when the extruded portion is formed in a rectangular cross section, the amount of protrusion from the heat radiating fin is small compared to the case where the extruded portion is formed in a circular cross section as in the prior art. Fin stiffness decreases.
Therefore, the material of the aluminum alloy contains 4 to 13% of silicon, 0.22 to 2.0% of magnesium, and 0.2 to 1.0% of iron, and heat-treats the main body after forming. Thus, it is desirable to reinforce the alloy substrate without reducing the thermal conductivity.
The material of the aluminum alloy contains 0.1 to 1.0% of silicon, 0.22 to 2.0% of magnesium, 0.2 to 1.0% of iron, and 0.5 to 5.%. Contains at least one of 0% copper or 0.5-5.0% nickel, and heat-treats the body after molding, strengthening the alloy substrate without reducing thermal conductivity You may let them.

As described above, by setting the composition of the aluminum alloy material and heat-treating the main body, a heat sink having excellent injection properties and release properties, high thermal conductivity, and reinforced alloy substrate is formed. be able to.
That is, by heat-treating the main body of the heat sink, a magnesium silicide compound, or an aluminum-copper or aluminum-nickel compound can be precipitated in the aluminum alloy structure, thereby strengthening the alloy substrate. Therefore, the heat radiation fin can be thinned after the extrusion portion is formed in a rectangular cross section, and the heat radiation efficiency of the heat sink can be increased.
In addition, heat treatment can be performed by heat-treating the main body of the heat sink to precipitate a magnesium silicide compound, or an aluminum-copper or aluminum-nickel compound in the aluminum alloy structure.

  The heat treatment of the main body is preferably performed at a processing temperature of 150 to 350 ° C. and a processing time of 1 to 10 hours. In addition, when the processing temperature of the main body is lower than 150 ° C. or the processing time is less than 1 hour, precipitation of the magnesium silicide compound, or the aluminum-copper or aluminum-nickel compound becomes insufficient. The strength of the alloy substrate is low, and the thermal conductivity is also low. On the other hand, when the treatment temperature is higher than 350 ° C., the precipitated magnesium silicide compound, or the aluminum-copper or aluminum-nickel compound becomes coarse, and the strength of the alloy substrate decreases. Furthermore, even if the treatment time exceeds 10 hours, the strength of the alloy substrate is saturated and does not change, so that the time required for the production of the heat sink becomes longer and the economic efficiency is lowered.

  According to the heat sink of the present invention, it is possible to increase the heat radiation efficiency while sufficiently securing the cross-sectional area of the extruded portion.

It is the figure which showed the heat sink of this embodiment, (a) is the perspective view seen from the front side, (b) is the perspective view seen from the back side. It is the figure which showed the heat sink of this embodiment, (a) is the top view seen from the front side, (b) is the top view seen from the back side. It is sectional drawing which showed the extrusion part in the heat sink of this embodiment. It is the disassembled perspective view which looked at the metal mold | die for forming the heat sink of this embodiment from the front side. It is the disassembled perspective view which looked at the metal mold | die for forming the heat sink of this embodiment from the back side. It is the figure which showed the procedure which forms the heat sink of this embodiment, (a) is a side view of the state which combined the fixed mold | type and the movable mold | type, (b) is a side view when taking out the heat sink from a movable mold | type. It is the perspective view which showed the extrusion part of the conventional heat sink.

Next, embodiments of the present invention will be described in detail with reference to the drawings as appropriate.
In the present embodiment, a heat sink attached to an automobile light housing will be described as an example. The heat sink of the present embodiment is a component for dissipating the heat of the LED element, in which a mounting portion of an LED element (“heating element” in claims) that is a light source of light is formed.

As shown in FIGS. 1A and 1B, the heat sink 1 is erected on a base portion 11 on which an LED element mounting portion 11c is formed, and a front surface 11a and a back surface 11b of the base portion 11. The main body 10 having a plurality of heat radiation fins 12 and 13 is provided. The heat sink 1 is formed by die casting using an aluminum alloy.
In the present embodiment, the upper side of FIG. 1 is the front side of the heat sink 1, and the lower side of FIG. 1 is the back side of the heat sink 1. However, the front and back sides are set for convenience, and the configuration of the heat sink 1 is limited. is not.

  As shown in FIGS. 2A and 2B, the base portion 11 is a rectangular plate-like member in plan view, and the longitudinal direction is set in the left-right direction of FIG. This base portion 11 is fixed to the housing of the light, and its shape is set corresponding to the housing to be attached.

  As shown in FIGS. 1A and 1B, the attachment portion 11 c is a cylindrical portion erected at the center of the front surface 11 a and the back surface 11 b of the base portion 11. An opening 11d on the front side of the attachment portion 11c is a portion to which the light emitting portion of the LED element is attached, and a hole 11e for fixing the reflection plate is formed on the bottom on the back side.

As shown in FIG. 1A, a plurality of radiating fins 12 are erected on the front surface 11a of the base portion 11. As shown in FIG. Each radiating fin 12 is a thin plate-like member extending in the longitudinal direction of the base portion 11, and in the present embodiment, the radiating fins 12 are arranged in parallel at equal intervals. ing.
Moreover, as shown in FIG. 3, the side surface of the radiation fin 12 is formed in a trapezoidal shape so that the width of the tip edge portion is smaller than the width of the base end portion.

As shown in FIG. 1 (b), a plurality of radiating fins 13 ... are formed on the rear surface 11b of the base portion 11 in the same manner as the radiating fins 12 ... erected on the front surface 11a. Is erected.
The side surface of the radiation fin 13 on the back surface 11b is formed in a trapezoidal shape with an inclination angle smaller than the inclination angle of the side surface of the radiation fin 12 on the front surface 11a.
Moreover, on the back side of the base part 11, the bottom part of the attaching part 11c protrudes from the front-end | tip edge part of each radiation fin 13 ....

As shown in FIG. 2B, on the back side of the base portion 11, four extruding portions 14... Are arranged around the attachment portion 11c (left and right and up and down in FIG. 2B with respect to the attachment portion 11c). Has been. Each extrusion part 14 ... is formed in two each of the radiation fins 13 and 13 arrange | positioned in the both sides (upper and lower both sides of FIG.2 (b)) of the attachment part 11c among each radiation fin 13 .... Has been.
As shown in FIG. 6B, the extruding unit 14 is pressed by an extruding pin 40 provided on the movable die 20 when the main body 10 is removed from the movable die 20 (see FIG. 6B) described later. It is a part.

  As shown in FIG. 3, the extruding portion 14 is formed on the side surface of the radiating fin 13 on the mounting portion 11 c side, and protrudes linearly from the base end portion of the radiating fin 13 to the tip edge portion. . As shown in FIG. 2B, the axial cross section of the extruding portion 14 is formed into a rectangular cross section that is wide in the longitudinal direction of the radiating fin 13. A rectangular extruded surface 14 a is formed at the end edge portion of the radiating fin 13 by the end surface of the extruded portion 14.

Here, the main body portion 10 of the heat sink 1 shown in FIGS. 1A and 1B is formed by die casting using an aluminum alloy. And in this embodiment, it is 4-13% of silicon, 0.22-2.0% of magnesium, 0.2-1.0% of iron, and the balance of the aluminum alloy comprised with aluminum and inevitable impurities. Material, or 0.1-1.0% silicon, 0.22-2.0% magnesium, 0.2-1.0% iron, 0.5-5.0% copper and An aluminum alloy material containing at least one kind of nickel of 0.5 to 5.0% and the balance of aluminum and inevitable impurities is used. In the latter of the aluminum alloy materials described above, the aluminum alloy material contains at least one of copper and nickel, but both copper and nickel may not be contained.
Further, in the present embodiment, the molded body 10 is subjected to heat treatment at a processing temperature of 150 to 350 ° C. and a processing time of 1 to 10 hours.

In addition, when the extrusion part 14 is formed in the rectangular cross section like this embodiment, since the protrusion amount from the radiation fin 13 is small compared with the conventional structure which formed the extrusion part in the circular cross section, The rigidity of the radiating fin 13 is reduced. Therefore, it is desirable to strengthen the alloy substrate without reducing the thermal conductivity of the main body 10.
Therefore, as described above, heat treatment is performed on the main body 10 to precipitate a magnesium silicide compound, or an aluminum-copper or aluminum-nickel compound in the aluminum alloy structure, thereby strengthening the alloy substrate. . Therefore, after forming the extrusion part 14 in a rectangular cross section, the heat radiation fin 13 can be thinned, and the heat dissipation efficiency of the heat sink 1 is increased.
In addition, heat treatment is performed on the main body 10 to precipitate a magnesium silicide compound, or an aluminum-copper or aluminum-nickel compound in the aluminum alloy structure, thereby improving heat dissipation characteristics.

Next, a die casting die 2 for forming the main body 10 of the heat sink 1 will be described.
As shown in FIGS. 4 and 5, the mold 2 includes a fixed mold 30 and a movable mold 20, and a cavity 2 a formed inside the mold 2 by combining the fixed mold 30 and the movable mold 20. The molten aluminum alloy is injected into (see FIG. 6 (a)), and the main body 10 (see FIG. 1 (a)) is formed in the cavity 2a.

  The fixed mold 30 is a mold that is fixed to the die casting apparatus. On the back surface 30b of the fixed mold 30, the base section 11 of the main body section 10 (see FIG. 1A) and each of the radiation fins 12. A recess 30c is formed as a cavity for forming the.

The movable mold 20 is a mold that is movable with respect to the fixed mold 30 by being attached to the drive mechanism of the die casting apparatus, and is a first movable mold 21 (“first mold” in the claims). And a second movable mold 22 (“second mold” in the claims).
The first movable mold 21 is for forming a first area A (hatched area) including the attachment part 11c and the respective extruding parts 14 in the main body part 10 shown in FIG. 2 (b). It is a mold. The second movable mold 22 is a mold for forming the second region B other than the first region A.
In addition, the 1st area | region A is a rectangular area | region set to the center part of the surface 11b of the back side of the base part 11 centering | focusing on the attaching part 11c, and each extrusion part 14 ... is arrange | positioned at four corners. Yes.

  As shown in FIGS. 4 and 5, the second movable mold 22 has a front side surface 22a and a back side surface 22b formed on the front side surface 22a (see FIG. 1B). A recess 22c serving as a cavity for forming each of the radiation fins 13 is formed. Further, a rectangular opening 22d into which the first movable mold 21 is inserted penetrates from the front surface 22a to the back surface 22b at the center of the second movable mold 22.

  The first movable mold 21 is a rectangular cross-section mold that is inserted into the opening 22 d of the second movable mold 22. The front surface 21a of the first movable mold 21 is formed with a concave portion 21c serving as a cavity for forming a mounting portion 11c of the main body portion 10 (see FIG. 1B) and a part of the radiating fin 13. Yes.

In addition, rectangular cutout portions 21e, which serve as cavities for forming the respective extruding portions 14 (see FIG. 2B) of the main body portion 10, are provided at the four corners of the first movable mold 21. Is formed. Each notch 21e is formed linearly on the side surface of the first movable mold 21 from the front surface 21a of the first movable mold 21 to the rear surface 21b.
When the first movable mold 21 is inserted into the opening 22d of the second movable mold 22, the notches 21e... Cause the four corners of the first movable mold 21 to face the rear surface 21b from the front surface 21a. A hole penetrating through is formed. The four extruding pins 40 connected to the drive mechanism of the die casting apparatus are inserted into the four holes, respectively (see FIG. 6A).

  The push pin 40 is inserted into the cutout portion 21e from the back side of the first movable mold 21, and is slidable in the front and back directions within the cutout portion 21e. As shown in FIG. 6B, the push pin 40 is a member for extruding the main body 10 from the movable mold 20 when the main body 10 is taken out from the movable mold 20.

  As shown in FIG. 6A, when the push pin 40 is inserted into the cutout portion 21e, the bottom surface of the cutout portion 21e is formed by the tip surface 40a of the pushpin 40. That is, the front end surface 40a of the extrusion pin 40 is a molding surface for forming the front end surface of the extrusion unit 14 of the main body 10 (see FIG. 1B).

Next, a procedure for forming the heat sink 1 using the mold 2 of this embodiment will be described.
First, as shown in FIG. 6A, the fixed mold 30 and the movable mold 20 are combined by superimposing the front surface 22 a of the movable mold 20 on the back surface 30 b of the fixed mold 30. As a result, a cavity 2 a is formed inside the mold 2. Further, extrusion pins 40 are inserted into the notches 21e of the first movable mold 21, respectively.

  Subsequently, the molten aluminum alloy is injected into the cavity 2a of the mold 2, and the aluminum alloy is cooled and solidified in the cavity 2a. Then, after the aluminum alloy is solidified in the cavity 2 a to form the main body 10, the movable mold 20 is separated from the fixed mold 30 as shown in FIG.

  Here, each side surface of each radiation fin 13... Of the rear surface 11 b of the main body 10 is formed at an inclination angle smaller than the inclination angle of each side surface of each radiation fin 12. ing. Further, a mounting portion 11c (see FIG. 1B) protrudes greatly on the back side of the main body portion 10. Therefore, the contact area with the mold 2 is larger on the back side (movable mold 20 side) of the main body part 10 than on the front side (fixed mold 30 side), and the holding force of the main body part 10 on the movable mold 20 is fixed. Since the holding force of the main body 10 with respect to the mold 30 is larger, the main body 10 is held by the movable mold 20 when the movable mold 20 is separated from the fixed mold 30.

  When the main body 10 is taken out from the movable mold 20 after separating the movable mold 20 from the fixed mold 30, the push pins 40... Are slid within the notches 21e. Then, the main body 10 can be pushed out of the movable mold 20 by pressing the pushers 14 of the main body 10 with the push pins 40.

  According to the heat sink 1 of the present embodiment as described above, as shown in FIG. 2B, the extrusion portion 14 is formed in a rectangular cross section, and therefore the cross section of the extrusion portion 14 is changed in the width direction of the extrusion portion 14 ( By spreading in the longitudinal direction of the heat dissipating fins 13, the cross-sectional area of the extruded portion 14 can be sufficiently secured. That is, according to this structure, since the protrusion amount of the extrusion part 14 from the side surface of the radiation fin 13 can be made small compared with the case where an extrusion part is formed in a circular cross section (refer FIG. 7), adjacent heat dissipation. The fluidity of air in the gap between the fins 13 and 13 can be increased, and the heat dissipation efficiency of the heat sink 1 can be increased.

Further, the main body 10 of the heat sink 1 of the present embodiment is formed by die casting using an aluminum alloy material, 4 to 13% of silicon, 0.22 to 2.0% of magnesium, and 0.02 of iron. 2 to 1.0% of aluminum alloy material, or 0.1 to 1.0% of silicon, 0.22 to 2.0% of magnesium, 0.2 to 1.0% of iron, and 0 A material of aluminum alloy containing at least one of 5-5.0% copper or 0.5-5.0% nickel is used, and the molded body 10 is heat treated. . Thereby, the heat sink 1 of this embodiment is excellent in injection | emission property and mold release property, high thermal conductivity, and the alloy substrate is reinforced.
As described above, in the heat sink 1 of the present embodiment, the main body 10 is subjected to heat treatment to precipitate the magnesium silicide compound, or the aluminum-copper or aluminum-nickel compound in the aluminum alloy structure, and the alloy substrate. Therefore, the heat radiation fin 13 can be thinned and the heat radiation efficiency of the heat sink 1 can be increased.
In addition, heat treatment is performed on the main body 10 of the heat sink 1 to precipitate a magnesium silicide compound, or an aluminum-copper or aluminum-nickel compound in the aluminum alloy structure, thereby improving the heat dissipation characteristics of the heat sink 1. ing.
Therefore, in the heat sink 1 of this embodiment, heat dissipation efficiency can be improved while ensuring a sufficient cross-sectional area of the extruded portion 14.

  Moreover, in the heat sink 1 of this embodiment, since the four extrusion parts 14 ... are arrange | positioned around the attachment part 11c with a complicated shape, each extrusion part 14 ... is each extrusion pin 40 ... The main body 10 can be smoothly removed from the movable mold 20 by pressing according to (see FIG. 6B).

Further, in the die casting mold 2 for forming the main body portion 10 of the heat sink 1 of the present embodiment, as shown in FIGS. 4 and 5, the movable mold 20 is replaced with the first movable mold 21 and the second movable mold 21. By dividing | segmenting into the type | mold 22, since each notch part 21e ... of the 1st movable mold | type 21 can be exposed outside, the maintainability of the metal mold | die 2 can be improved.
Moreover, since the notch part 21e for forming the extrusion part 14 is formed by processing the side surface of the 1st movable mold 21, the process of the metal mold | die 2 can be simplified.
Further, when the shape of the mounting portion 11c is changed, it is only necessary to newly create the first movable mold 21 without newly creating the entire mold 2, thereby reducing the manufacturing cost of the mold 2. be able to.

The embodiment of the present invention has been described above, but the present invention is not limited to the above-described embodiment, and can be appropriately changed without departing from the spirit of the present invention.
For example, in this embodiment, as shown in FIG. 2 (b), the extruding portions 14 are formed on the two radiating fins 13 and 13, but the number of the extruding portions 14 and the arrangement thereof are not limited. It can be set in consideration of the releasability of the main body 10.

  Moreover, in this embodiment, although the extrusion part 14 is formed in the radiation fin 13 of the surface 11b of the back side of the main-body part 10, in the radiation fin 12 of the front-side surface 11a of the main-body part 10 shown to Fig.2 (a). The extrusion unit may be formed, and the main body unit 10 may be removed from the fixed mold 20 by pressing the main body unit 10 with an extrusion pin provided on the fixed mold 20 (see FIG. 4).

  Further, in this embodiment, the heat sink attached to the light housing of the automobile is described as an example, but the application target of the heat sink of the present invention is not limited, and is applied to a heating element such as various electric components. The size and shape are not limited.

  Next, an example of the material of the aluminum alloy forming the main body portion 10 of the heat sink 1 of the present embodiment shown in FIG. 1 will be described in more detail with reference to the following examples and comparative examples. However, the present invention is not limited to these examples.

In this example, a raw material containing aluminum and an alloy element was melted, and an aluminum alloy having chemical components shown in Table 1 was formed by die casting.
The alloy name E shown in Table 1 is an example of an aluminum alloy disclosed in Patent Document 2, and the alloy name F is shown in JIS H 5302, which has been widely used as a heat treatment type die casting alloy. The specified ADC12 alloy.
About the Example of this invention, and the alloy name F, the heat processing for which the process temperature is 200 degreeC and the process time is 4 hours is performed. And the alloy of both before and after heat processing was prepared as a test material, and the result of having measured tensile strength and thermal conductivity about these test materials is shown in Table 2.

According to Table 2, in the examples of the present invention, the thermal conductivity is 160 W / mK or more and the tensile strength is 230 MPa or more, and both high thermal conductivity and strengthened alloy substrate are compatible.
In addition, even if it is alloy name A, B, C, or D, without heat processing, thermal conductivity is less than 160 W / mK or tensile strength is less than 230 MPa.
Further, although the alloy name E, which is an example of the aluminum alloy disclosed in Patent Document 2, is not a heat treatment type alloy, it has a thermal conductivity of less than 160 W / mK and a tensile strength of less than 230 MPa, and has a high thermal conductivity. Incompatible with reinforced alloy substrate.
In addition, the ADC12 alloy that has been widely used as a heat treatment type die casting alloy has a heat conductivity of less than 160 W / mK even when heat treatment is performed without heat treatment, and high heat conductivity cannot be obtained.
From these examples and comparative examples, it was found that the aluminum alloy used in the heat sink of the present invention has high thermal conductivity and the alloy substrate is reinforced.

DESCRIPTION OF SYMBOLS 1 Heat sink 2 Mold 2a Cavity 10 Main part 11 Base part 11c Mounting part 12 Front side radiating fin 13 Back side radiating fin 14 Extrusion part 20 Movable type 21 First movable type 21e Notch part 22 Second movable type 30 Fixed Mold 40 Extrusion pin A First area B Second area

Claims (5)

A heat sink formed by die casting, comprising a body portion having a base portion on which a mounting portion of a heating element is formed, and a plurality of radiating fins erected on the base portion,
At the tip edge portion of at least one of the radiating fins, when the main body portion is taken out from a die casting die, an extrusion portion that is pressed by an extrusion pin provided on the die is formed,
The extruded portion is formed in a rectangular cross section, and is protruded from one side surface of the radiating fin ,
The main body is
A first region including the extruded portion is formed by a first mold;
The second region other than the first region is formed by the second mold,
The heat sink , wherein the extrusion part is formed by a notch part provided on a side surface of the first mold . 2. The heat sink according to claim 1 , wherein a plurality of the extruding portions are formed in the first region, and each of the extruding portions is disposed around the attachment portion. The main body is formed by die casting using an aluminum alloy material,
The material of the aluminum alloy contains 4 to 13% of silicon, 0.22 to 2.0% of magnesium, and 0.2 to 1.0% of iron, and the body portion after molding is heat-treated. The heat sink according to claim 1 or claim 2 , wherein The main body is formed by die casting using an aluminum alloy material,
The material of the aluminum alloy contains 0.1 to 1.0% of silicon, 0.22 to 2.0% of magnesium, 0.2 to 1.0% of iron, and 0.5 to 5.0%. The copper according to claim 1 or 2 , wherein at least one of copper and 0.5 to 5.0% nickel is included, and the main body after molding is subjected to heat treatment. heatsink. The heat treatment of the body portion, the process temperature is 150 to 350 ° C., a heat sink according to claim 3 or claim 4, wherein the processing time is 1 to 10 hours.

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