KR100981155B1 - Heat sink - Google Patents

Abstract

The present invention relates to a heat sink, and more particularly, to increase the heat dissipation effect by changing the structure of the heat dissipation plate to increase the heat dissipation area, to control the direction of wind communication, and to provide a support structure between the laminated heat dissipation plates. A heat sink for forming.

The heat sink according to the present invention is a heat sink formed by stacking a plurality of heat dissipation plates for discharging heat of a heat source into the air, the first heat dissipation plate and a heat dissipation part for absorbing heat and a heat dissipation part for dissipating heat; 2 including a heat dissipation plate, wherein a plurality of trenches are formed in the heat dissipation portion of the first heat dissipation plate in a direction through which the wind passes, and the heat dissipation portion of the second heat dissipation plate is symmetrical with the trench of the first heat dissipation plate. A plurality of trenches are bent to form a plurality of trenches, and the first and second heat dissipation plates are cross-laminated so that the outer surfaces of the trenches are interconnected to each other to form a plurality of wind tunnels for ventilation and support structure.

Heat sink, heat radiating plate, heat absorbing part, heat generating part, heat pipe

Description

Heatsink {HEAT SINK}

The present invention relates to a heat sink, and more particularly, to increase the heat dissipation effect by changing the structure of the heat dissipation plate to increase the heat dissipation area, to control the direction of wind communication, and to provide a support structure between the laminated heat dissipation plates. A heat sink for forming.

The heat sink refers to a device that absorbs heat from an electronic component or a thermoelectric element and cools the electronic component through heat exchange between a heat radiating plate and air.

In the case of various heat generating semiconductor components, malfunctions may occur or components may be damaged at temperatures above an appropriate temperature. Therefore, in the case of a system in which a CPU, a graphics card, and various heating semiconductor parts are built, such as a computer, installation of a heat sink for cooling the parts is essential.

Generally, the heat dissipation plate of the thin film plate is laminated horizontally or vertically at regular intervals, and the heat dissipation function is performed through mutual heat exchange by passing wind, which is a refrigerant, between the heat dissipation plates containing heat using a cooling fan. The type of heat sink determines the heat dissipation effect by the area where the heat sink is in contact with the wind and how much heat the wind passing through the heat sink exits. That is, the heat dissipation effect of the heat dissipation plate having a large heat dissipation area, the higher the heat exchange between the heat dissipation plate and the wind.

However, if the heat dissipation plate is designed to be infinitely wide considering only the heat dissipation effect, it may cause a lot of problems in terms of space efficiency, and in the case of a heat sink laminated with a conventional flat heat dissipation plate, a part that plays a role of guiding wind between the heat dissipation plates. There was no problem that the wind escapes everywhere without sufficient heat exchange to reduce the heat dissipation efficiency.

In addition, in the case of the conventional heat sink, there is a problem that hot air flows irregularly by other heat sinks or fans installed inside the system, causing interference between refrigerants, and the thin plate heat radiation plate has a weak plate support structure. It is easily crushed by the impact, causing a problem of significantly reducing the heat dissipation effect.

In order to solve the above problems, the heat sink according to the present invention aims to provide a high heat dissipation effect and a strong support structure between the heat dissipation plates by improving the structure of the heat dissipation plate.

The heat sink according to the present invention is a heat sink formed by stacking a plurality of heat dissipation plates for discharging heat of a heat source into the air, the first heat dissipation plate and a heat dissipation part for absorbing heat and a heat dissipation part for dissipating heat; 2 including a heat dissipation plate, wherein a plurality of trenches are formed in the heat dissipation portion of the first heat dissipation plate in a direction through which the wind passes, and the heat dissipation portion of the second heat dissipation plate is symmetrical with the trench of the first heat dissipation plate. A plurality of trenches are bent to form a plurality of trenches, and the first and second heat dissipation plates are cross-laminated so that the outer surfaces of the trenches are interconnected to each other to form a plurality of wind tunnels for ventilation and support structure.

" 형태를 형성하는 것을 특징으로 한다.In addition, the wind tunnel has a unit cross section having a cross section of the first heat radiation plate and the second heat radiation plate by "

"To form a feature.

" 형태를 형성하는 것을 특징으로 하는 히트싱크.In addition, the wind tunnel has a unit cross section having a cross section of the first heat radiation plate and the second heat radiation plate by "

Heat sink, characterized in that forming a shape.

" 형태를 형성하는 것을 특징으로 한다.In addition, the wind tunnel has a unit cross section having a cross section of the first heat radiation plate and the second heat radiation plate by "

"To form a feature.

" 형태를 형성하는 것을 특징으로 한다.In addition, the wind tunnel has a unit cross section having a cross section of the first heat radiation plate and the second heat radiation plate by "

"To form a feature.

In addition, the wind tunnel is characterized in that it is formed to change the wind direction of the fan.

In addition, the heat absorbing portion is characterized in that it is formed in a circular hole inside the heat dissipation plate to be connected to a plurality of heat pipes passing through the heat sink and transferring the heat of the heat source.

In addition, the endothermic portion is characterized in that the circumferential portion of the hole is bent and protruded in order to maintain a distance from the adjacent heat radiating plate and secure the contact surface with the heat pipe to increase the efficiency of heat transfer.

In addition, the heat absorbing portion is characterized in that the heat radiation plate side is extended to form a plate.

In addition, the heat absorbing portion is characterized in that the coupling between the grooves formed in the heat transfer block.

In addition, the heat absorbing portion is formed with a through groove for fixing, a plurality of support pieces formed with a through groove for fixing is inserted between the heat absorbing portion in which the heat radiating plate is stacked is characterized in that the fixing means integrally by the fixing means.

In addition, the endothermic portion is characterized in that the end is bent in a "┛" shape in order to be fixed to the heat transfer block surface by soldering.

As described above, the heat sink according to the present invention has a bent trench formed on the first heat dissipation plate and the second heat dissipation plate, thereby securing a wider heat dissipation area than the heat sink formed by stacking the flat heat dissipation plates. Since the guided wind guides the heat exchange by sufficient contact between the heat radiating plate and the wind, the heat from the heat sink can be released with a lot of heat. The heat dissipation efficiency is remarkably higher than that of the heat sink composed of the conventional flat heat radiating plate. It can be seen as high.

In addition, the wind tunnel can guide the direction of the wind can direct the hot wind emitted from the heat sink in the desired direction inside the system and can exclude the interference of the hot wind emitted from other heat sinks or fans.

In addition, since the heat sink according to the present invention has a supporting structure formed by the junction of the trench outer surface of the first heat dissipation plate and the second heat dissipation plate, it is very effective in maintaining the heat dissipation plate shape from external impact.

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

Heat sink 1 according to the present invention is formed as a plurality of heat dissipation plate 100 for discharging the heat of the heat source into the air, as shown in Figure 1, like most conventional heat sinks, stacked heat dissipation plate ( A fan (not shown) or the like is mounted on the side surface of the heat sink 1 formed by 100 to allow air to flow through the gap between the stacked heat dissipation plates 100.

The heat sink 1 according to the present invention is characterized in that the heat dissipation part 110 for absorbing heat and the heat dissipation part 120 for dissipating heat are formed as shown in FIGS. 1 to 3. 100a) and a second heat dissipation plate 100b, wherein a plurality of trenches 121a are formed in the heat dissipation portion of the first heat dissipation plate in a direction through which the wind passes by bending, and the second heat dissipation plate is formed. A plurality of trenches 121b are formed in the heat dissipation portion of the first heat dissipation plate symmetrically with the trench 121a of the first heat dissipation plate, and the first heat dissipation plate 100a and the second heat dissipation plate 100b are formed. ), The outer surfaces of the trenches 121a and 121b are interconnected to form a plurality of wind tunnels 10 for ventilation and support structure.

The trenches 121a and 121b have a wider heat dissipation area than the area occupied by the heat dissipation plate, thereby expanding the contact area with air, and not only guide the air to be vented but also protrude by bending. By acting as such to have a more robust support structure of the heat dissipation plate of the plate. The trenches 121a and 121b are formed in the trench 121a and the second heat dissipation plate 100b formed in the first heat dissipation plate 100a because the trenches 121a and 121b are for forming a wind tunnel by mutual connection when the heat dissipation plates are stacked. The trench 121b should be bent to be symmetrical with each other.

In the case of a heat sink formed of a heat sink plate of the conventional flat plate, since there is no part for guiding the air to be vented, the air can escape in all directions as it passes between the heat sink plates, and thus a high density of air pressure cannot be formed between the heat sink plates. As a result, sufficient heat exchange between the heat dissipation plate and the air flowing out was difficult. However, in the case of the heat sink according to the present invention, the wind tunnel 10 guides the wind in a predetermined direction and allows the wind passing through the wind tunnel to form a high air pressure. Make contact and let out a lot of heat as the wind blows out. In addition, since the outer wall of the wind tunnel serves to prevent the wind from entering the side of the heat sink, the interference caused by the wind from other heat sinks inside the system can be excluded.

In addition to the heat dissipation effect as described above, since the wind tunnel 10 is formed by the interconnection of the trenches, the wind tunnel 10 may help to form a strong support structure of the heat dissipation plate and prevent the heat dissipation plate from being easily bent from external impact. .

In order to form the wind tunnel 10, since the first heat dissipation plate 100a and the second heat dissipation plate 100b are laminated to each other, the outer surfaces of the trenches 121a and 121b are formed to be in contact with each other. The second heat dissipation plate (100a) (100b) must be a pair to be stacked.

The wind tunnel 10 may be formed in various forms, and may be configured in various shapes in consideration of the contact area of the wind passing through, the support structure, and the simplification in the manufacturing process, as shown in FIGS. 4 to 7. have.

" 형태의 벌집구조(10a)는 통과되는 바람의 접촉면적을 고려하여 설계될 수 있을 것이고, 단위 횡단면이 "

" 형태의 사각구조(10b)는 지지구조의 강화를 좀더 고려하여 설계될 수 있을 것이며, 단위 횡단면이 "

" 형태의 원구조(10c)는 제조공정상의 간편화를 고려하여 설계될 수 있을 것이고, 단위 횡단면이 "

" 형태의 다이아몬드구조(10d)는 보다 강화된 지지구조를 위하여 설계될 수 있을 것이다.For example, the unit cross section is "

"The honeycomb structure 10a of the type may be designed in consideration of the contact area of the wind passing through, the unit cross section"

"The rectangular structure 10b of the type may be designed in consideration of the strengthening of the support structure, the unit cross section is"

"The circular structure 10c of the form may be designed in consideration of the manufacturing process simplicity, the unit cross section"

The diamond shape 10d may be designed for a more strengthened support structure.

8 is another embodiment of the wind tunnel 10e, the wind tunnel can be changed by forming the wind tunnel in a direction not diagonal to the side of the heat sink to be attached to the fan (fan) by changing the wind direction of the fan (fan) It is shown. This may be useful when heat-sensitive parts or components are placed in the direction that the wind escapes from the heat sink in a situation where the heat sink cannot be changed due to the internal structure of the system. Although shown is a straight wind tunnel (10e) formed in the diagonal direction may be configured to guide the direction by configuring the wind tunnel in a variety of forms, such as curves depending on the environment of the system.

In the heat absorbing part 110 of the heat sink 1 according to the present invention, as shown in FIGS. 9 to 10, a plurality of heat pipes 2 receiving heat from the heat transfer block 3 pass through the heat sink. And it can be formed in the shape of a circular hole in the heat dissipation plate plate to be connected. In addition, the circular heat absorbing portion 110a may be formed by protruding the circumferential portion of the hole as shown in FIGS. 2 to 3, which ensures a sufficient contact surface with the heat pipe and the heat pipe and the heat dissipation plate. In order to improve the efficiency of heat transfer between the liver and to maintain a constant distance between adjacent heat dissipation plates to help form a support structure.

The heat absorbing portion of the heat sink 1 according to the present invention may be formed in a plate shape by extending the side of the heat dissipation plate in addition to the circular hole shape as shown in Figure 11 to 14, which is a heat transfer block, etc. without the help of the heat pipe It can be used mainly if you want to connect directly.

As shown in FIG. 11, the heat absorbing unit 110b may be fitted into a groove between the grooves formed in the heat transfer block 4, and fixing means may penetrate the heat absorbing unit 110c as illustrated in FIG. 12. A plurality of support pieces 5 having a through groove for fixing are formed between the heat absorbing portions in which the through grooves are formed and the heat dissipation plates are stacked, and can be fixed integrally by fixing means such as screws or bolts. As shown in FIG. 14, the end portion 111d of the heat absorbing part 110d may be bent in a “┛” shape to be coupled to the heat transfer block 6 by soldering.

Although the above contents are expressed as preferred embodiments for the purpose of specific implementation of the invention, the contents of the present invention may be variously modified and implemented within the technical spirit and equivalent range, so the scope of the present invention is limited by the above contents. It should not be interpreted.

1 is a perspective view showing a heat dissipation plate of a heat sink according to the present invention;

Figure 2 is a front view showing a heat dissipation plate of the heat sink according to the present invention.

3 is a perspective view of a heat sink according to the present invention;

4 is a front view of a heat sink according to the present invention;

5 is a front view showing another embodiment of the heat sink according to the present invention.

6 is a front view showing another embodiment of the heat sink according to the present invention.

7 is a front view showing another embodiment of the heat sink according to the present invention.

8 is a perspective view showing another embodiment of a heat sink according to the present invention;

9 is a perspective view showing another embodiment of a heat sink according to the present invention;

10 is a perspective view showing another embodiment of a heat sink according to the present invention.

11 is a perspective view showing another embodiment of a heat sink according to the present invention.

12 is a perspective view showing another embodiment of the heat sink according to the present invention;

<Explanation of symbols for the main parts of the drawings>

1: heat sink 10: wind tunnel

100a: first heat dissipation plate 100b: second heat dissipation plate

110: heat absorbing portion 120: heat radiating portion

121: trench 2: heat pipe

3, 4, 6: heat transfer block 5: support piece

Claims (12)

In the heat sink formed by stacking a plurality of heat radiation plates for discharging heat of the heat source into the air, And a first heat dissipation plate and a second heat dissipation plate having a heat absorbing portion for absorbing heat and a heat dissipating portion for dissipating heat, wherein the heat dissipating portion of the first heat dissipation plate includes a plurality of trenches in a direction through which wind passes by bending. Is formed, and a plurality of trenches are formed in the heat dissipation portion of the second heat dissipation plate symmetrically with the trenches of the first heat dissipation plate, and the first heat dissipation plate and the second heat dissipation plate are cross-laminated to form an outer side of the trenches. Heat sink, characterized in that the surface is interconnected to each other formed a plurality of wind tunnel for ventilation and support structure. The unit of claim 1, wherein the wind tunnel has a unit cross section by stacking the first heat dissipation plate and the second heat dissipation plate.

Heat sink, characterized in that forming a shape. The unit of claim 1, wherein the wind tunnel has a unit cross section by stacking the first heat dissipation plate and the second heat dissipation plate.

Heat sink, characterized in that forming a shape. The unit of claim 1, wherein the wind tunnel has a unit cross section by stacking the first heat dissipation plate and the second heat dissipation plate.

Heat sink, characterized in that forming a shape. The unit of claim 1, wherein the wind tunnel has a unit cross section by stacking the first heat dissipation plate and the second heat dissipation plate.

Heat sink, characterized in that forming a shape. delete The heat sink of claim 1, wherein the heat absorbing portion is formed by a circular hole in the heat dissipation plate so as to be connected to a plurality of heat pipes passing through the heat sink and transferring heat of the heat source. 8. The heat sink of claim 7, wherein the heat absorbing portion is bent to protrude from the circumferential portion of the hole in order to maintain a distance from an adjacent heat radiating plate and to secure a contact surface with the heat pipe to increase heat transfer efficiency. The heat sink according to claim 1, wherein the heat absorbing portion is formed in a plate shape with a side surface of the heat radiating plate extending. 5. The heat sink of claim 4, wherein the heat absorbing portion is fitted into a groove between grooves formed in the heat transfer block. The method according to claim 4, wherein the heat absorbing portion is formed with a through groove for fixing, and a plurality of support pieces having a through groove for fixing are inserted between the heat absorbing portions, the heat dissipation plate is laminated, characterized in that fixed by the fixing means integrally. Heatsink. The heat sink as set forth in claim 4, wherein the heat absorbing portion is formed by bending an end portion of the heat absorbing portion in a “┛” shape in order to fix the heat absorbing portion to the surface of the heat transfer block by soldering.

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