KR20100092688A - Heat sink and manufacturing method of it - Google Patents

Abstract

PURPOSE: A heatsink having no folding portion and a manufacturing method thereof are provided to supply a radial fin by using the elasticity of a pin without using a folding fin. CONSTITUTION: AN air flow path(11) is formed by bending a plurality of flat plates(1) and enables the inflow of air into the inside thereof, and a plurality of fins(10) comprise a fixing unit(13) for forming a fixing hole(12) at end unit of the plate. A fixing block is fixed by laminating and pressurizing the fixing unit. When fixing the fin, the air flow path is secured by elastic force of the fin and the fin is arranged in radial shape of the half circle form.

Description

Heat Sink and Manufacturing Method of it

The present invention relates to a heat sink and a method for manufacturing the same, and more particularly, to a heat sink and a method for manufacturing the same so that the spacing between the fins is radially disposed by a predetermined interval by the elastic force of the metal fin.

As the performance of electronic products increases rapidly, the problem of heat dissipation of components disposed inside the products is gradually increasing. In particular, as computers become faster and larger in size, more heat is generated from the CPU, graphics card chipset, power transistor, etc., and malfunctions occur when the temperature of the parts exceeds an appropriate level due to heat dissipation. In some cases, the parts themselves may be damaged.

In order to solve the heat dissipation problem of the electronic component, a heat sink in which a heat dissipation fin is integrally attached to the surface of a heat generating component is conventionally attached or a cooling fan is attached to the heat sink in a more aggressive manner. A method of cooling the part was used.

Referring to the prior art taking the cooler (cooler) assembly shown in Figure 1 as an example. Conventional cooler assembly is configured by coupling the cooling fan 130 on the top of the heat sink 101 of the rectangular parallelepiped or cylindrical type attached to a heating element (not shown) mounted on the substrate 140. The heat sink 101 may also include a circular fan insertion groove 120 for installation efficiency. The air flow induced by the electrically driven cooling fan 130 dissipates heat transferred from the heating element to the heat sink 101 by convective heat transfer.

At this time, the fins attached to the heat sink 101 are manufactured radially.

An example of a heat sink in which fins are radially manufactured has been disclosed in Korean Patent Registration No. 10-0389257 (name of the invention: heat sink), which is shown in FIG. 2.

The heat sink is a heat dissipation unit which receives heat directly from a heat source in contact with a heat source, a connection unit formed integrally with the heat absorption unit, and extends integrally with the connection unit to radiate heat conducted through the connection unit from the heat absorption unit into the air. In the heat sink configured by stacking a plurality of heat dissipation plates 210 having a portion, the heat absorbing portions 211 of each of the heat dissipating plates are tightened and in close contact with the heat absorbing portions 211 of the heat radiating plates adjacent thereto, and the heat absorbing portions ( 211) When the heat dissipation unit 212 is tightened close to each other characterized in that the folded portion 213 is provided between each heat dissipation plate to be spaced radially apart.

By providing the folded portion 213 as described above, when the heat absorbing portions 211 of each of the heat dissipation plates 210 are tightened to be in close contact with each other, they are radiated radially.

Since the heat dissipation plate 210 should be provided with a folded portion 213, a punching process for forming the space portion 214 is required to form the folded portion 213, and a cutting and bending process of the folded portion 213 is performed. Since there is a need for the manufacturing process is a complex problem. In addition, when the height of the heat dissipation plate 210 is large, the number of folding portions 213 must be provided, so that the number of labors increases and manufacturing cost increases.

Another example of a heat sink in which the fin is radially disclosed has been disclosed Korean Patent Registration No. 10-0650122 (name of the invention: heat sink), which is illustrated in FIG. 3.

The heat sink has a heat absorbing portion 311 at the lower end thereof in contact with the heat source so as to receive heat from the heat source, and a heat dissipating portion 312 extending from the side of the heat absorbing portion and receiving heat from the heat absorbing portion and dissipating to the outside. Comprising a plurality of heat dissipation plate 310 of the form, wherein the heat absorbing portion is in close contact with the pressure applied from the outside to form a central portion 313, the heat dissipating portion is taken radially centered around the center portion. In the heat sink, a portion of the heat dissipating portion 312 is cut and folded at the upper and lower portions of the portion adjacent to the heat absorbing portion 311 to form a pair of folding portions 314, or a folding portion at the end of the heat dissipation plate 310. When formed by the pressing block 320 when the fixed portion 314 takes the form of radially spread around the central portion of the heat radiating plate.

The heat sink manufactured in the same manner is Korean Patent Registration No. 10-0464914 (name of the invention: heat sink).

Since the heat sink must be provided with a folded portion 314 in the heat dissipation plate 310 in the same manner as the heat sink described above, a cutting and bending process or a bending process is required to form the folded portion 314. There is a problem. In addition, when a portion of the heat dissipating portion 312 is cut and folded to form a pair of folds at the upper and lower portions of the portion adjacent to the heat absorbing portion 311, when the height of the heat dissipation plate is increased, a plurality of folds 314 are provided. Therefore, there is a problem that the man-hours increase and the manufacturing cost increases.

The present invention is to solve the above problems, to provide a heat sink for producing a fin radially by using the elastic force of the pin without having a folding portion and a manufacturing method thereof.

In order to achieve the above object, the heat sink of the present invention is formed by bending a plurality of flat plate 1 in half and an air flow passage 11 through which air flows, and both end portions of the plate 1. A plurality of pins 10 having a fixing part 13 having a fixing tool 12 formed therein; A fixing block 20 for pressing and fixing the fixing part 13 by stacking the fixing parts 13 of the pins 10 adjacent to each other; When the pin 10 is fixed by the fixing block 20, the air flow passage 11 is secured by the elastic force of the pin 10 itself, and thus the overall shape of the pin 10 is increased. It is characterized in that the radial arrangement of the semi-circular form.

In addition, when the pin 10 is fixed by the fixing block 20, the pin 10 is in contact with the pin 10 positioned outside the pin 10 stacked so that the fixing part 13 is adjacent to the pin 10. It is characterized in that it is fixed by the pin pressing block 30 is provided with a receiving portion 31 of a semi-circular fan-shaped shape to be kept radial in form.

In addition, the pin 10 is stacked so that each fixing part 13 of the pin 10 is adjacent to the left and right, respectively, and presses the fixing part 13 by one fixing block 20 to fix the pin 10. It is characterized in that to be arranged in a radial form of a circular shape.

In addition, the upper inside of the fin 10 is characterized in that the insertion groove 14 is further provided with a discharge fan 40 is inserted to forcibly discharge the air from the air flow passage (11).

Method for producing a heat sink of the present invention comprises the steps of: a) forming a fixture 12 at both ends of the plate (1); b) Bending a plurality of flat plate 1 in half so as to form an air flow passage 11 through which air flows, and pins 10 are formed at both ends of the bent plate 1. Molding; c) stacking the fixing parts 13 of each of the pins 10 to be adjacent to press the fixing parts 13 to the fixing blocks 20 to fix the pins 10; When the pin 10 is fixed by the fixing block 20, the air flow passage 11 is secured by the elastic force of the pin 10 itself, and thus the overall shape of the pin 10 is increased. It is characterized in that the radial arrangement of the semi-circular form.

In addition, in step b), the pin pressurizing pin 10 is provided with a receiving portion 31 in contact with the pin 10 positioned in the outer portion of the pin 10 stacked so that the fixing portion 13 is adjacent to each other and having a semi-circular fan shape. Maintaining the pin (10) in a semicircular radial fashion by the block (30); And further comprising:

In addition, in the step b), the pin 10 is stacked so that each fixing part 13 of the pin 10 is adjacent to the left and the right, respectively, and the fixing part 13 is formed by one fixing block 20. Press to be fixed to be characterized in that the radially arranged in a circular shape.

In addition, in step a), an insertion groove 14 into which a discharge fan 40 for forcibly discharging air from the air flow passage 11 is inserted into the upper portion of the fin 10 disposed radially is formed. Forming an insertion groove forming recess 15; And further comprising:

According to the present invention, unlike the conventional method of arranging the pins radially by providing the folded portions, the flat plate is formed by bending without the folded portions, thereby simplifying the manufacturing process and reducing the manufacturing cost and manufacturing cost. And, there is an advantage to improve the productivity.

Hereinafter, with reference to the accompanying drawings will be described in detail the heat sink of the present invention and its manufacturing method.

Figure 4 is a view showing the forming process of the fin for manufacturing the heat sink according to the present invention, Figure 5 is an exploded perspective view showing a heat sink according to the present invention, Figure 6 is a heat sink of another form according to the present invention 7 is an exploded perspective view showing another form of heat sink according to the present invention, FIG. 8 is a perspective view showing another form of heat sink according to the present invention, and FIG. 9 is still another view according to the present invention. It is a top view which shows the heat sink of the form.

Heat sink 100 of the present invention comprises a plurality of fins (10) formed by bending a flat plate (1) and a fixed block (20) for fixing the fins (10); It is made, including.

The fin 10 is formed by bending a plurality of flat plate 1 (FIG. 4 (a)) in half (FIG. 4 (b)), and an air flow passage 11 through which air flows. (C) of FIG. 4 and the fixing part 13 in which the fastener 12 (refer FIG. 5) was formed in the both ends of the said plate 1 ((c) of FIG. 4), and it becomes many The fixing parts 13 are stacked (Fig. 4 (d)) to be fixed.

At this time, the material of the plate 1 is excellent in thermal conductivity, such as aluminum, copper or aluminum alloy, and uses a metal material having its own elastic force.

The fixing block 20 serves to press and fix the fixing part 13 by stacking the fixing parts 13 of the pins 10 to be adjacent to each other. The fixing block 20 is fixed by fastening means such as bolts in contact with the left and right sides of the fixing part 13 located outside the stacked pins 10.

When the pin 10 is fixed by the fixing block 20, the pin 10 is secured to the air flow passage 11 by the elastic force of the pin 10 itself, and thus the overall shape of the pin 10. The semi-circular radial arrangement.

In this case, when the pin 10 is not easy to be disposed radially because the elastic force of the pin 10 is large, the fixing part 13 is adjacent when the pin 10 is fixed by the fixing block 20. A pin press provided with a semicircular fan-shaped accommodating portion 31 in contact with the pin 10 positioned at an outer side of the pin 10 stacked so as to keep the pin 10 radially in a semicircular shape. Secured by block 30.

When the fin 10 is radially maintained by the fin pressing block 30 to be fixed by the fixing block 20, the fin pressing block 30 is separated from the heat sink 100 to heat the sink 100. ) Production is completed.

5 shows that the pin 10 is arranged in a radial shape of a semicircle, but as shown in FIG. 6, the pin 10 may be arranged in a radial shape of a circular shape.

In this case, the fixing parts 13 of the pins 10 are stacked on the left side and the right side of the pins 10, respectively, and the pins are fixed by pressing the fixing parts 13 by one fixing block 20. 10) to be arranged radially in a circular shape.

This form is to install a discharge fan in a circular shape to facilitate the cooling by discharging the air through the air flow passage (11).

7 to 9 are easy to install the discharge fan 40, in order to reduce the installation space of the discharge fan 40, in the heat sink shown in Figure 6 in the upper inside of the fin 10 It is further shown that the insertion groove 14 is inserted into the discharge fan 40 for forcibly discharging the air from the air flow passage (11).

At this time, in order to form the insertion groove 14 in the pin 10 is formed by cutting the insertion groove forming recess 15 in the plate 1 before bending the plate (1).

The heat sink of the present invention having the above configuration is manufactured by the following method.

First, to form a fastener 12 to be coupled to the fastening means for fixing the pin 10 by the fixing block 20 to both end portions of the plate (1).

After the fastener 12 is formed, a plurality of flat plates 1 are bent in half so that air flow passages 11 through which air flows are formed, and fixing parts are formed at both ends of the bent plate 1. The pin 10 is molded as much as possible.

After the pin 10 is formed, the fixing parts 13 of each of the pins 10 are stacked to be adjacent to each other to press the fixing parts 13 with the fixing block 20 to fix the pins 10.

When the pin 10 is fixed by the fixing block 20 as described above, the pin 10 having the air flow passage 11 convexly widened from side to side as shown in (c) of FIG. 4 is the pin 10. The overall shape of the fin 10 of the fin 10 is arranged radially in a semi-circular shape while securing the slim air flow passage 11 by its elastic force (FIG. 4 (d)). ).

At this time, when the pin 10 is not easy to be disposed radially because the elastic force of the pin 10 is large, the fixing part 13 is fixed when the pin 10 is fixed by the fixing block 20. The pin 10 is semicircle by a pin pressing block 30 which is in contact with the pin 10 positioned on the outer side of the pin 10 stacked adjacent to each other and is provided with a receiving portion 31 of a semi-circular fan shape. To remain radial in shape.

In order to manufacture the heat sink shown in FIG. 6, the fixing parts 13 of the fins 10 are stacked adjacent to the left and the right sides, respectively, and the fixing parts 13 are connected by one fixing block 20. It is fixed by pressing so that the pin 10 is arranged in a radial shape in a circular shape.

In addition, in order to manufacture the heat sink illustrated in FIGS. 7 to 9, that is, the heat sink in which the insertion groove 14 is formed in the fin 10, an insertion groove forming recess in the plate 1 is formed before bending the plate 1. 15 is formed by cutting in advance.

1 is a perspective view of a cooler assembly;

2 and 3 show a conventional heat sink.

4 is a view showing a process of forming a fin for manufacturing a heat sink according to the present invention.

5 is an exploded perspective view showing a heat sink according to the present invention.

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

Figure 7 is an exploded perspective view showing a heat sink of another form according to the present invention.

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

9 is a plan view showing a heat sink of another embodiment according to the present invention.

DESCRIPTION OF REFERENCE NUMERALS

1: plate 10: pin

11: air flow path 12: fixture

13: Fixing part 14: Insertion groove

15: recessed groove forming portion 20: fixed block

30: pin press block 31: receiving portion

40: exhaust fan

Claims (8)

It is formed by bending a plurality of flat plate (1) each half and an air flow passage (11) through which air flows, and a fixing portion (13) having fasteners (12) formed at both ends of the plate (1) A plurality of pins 10 provided; A fixing block 20 for pressing and fixing the fixing part 13 by stacking the fixing parts 13 of the pins 10 adjacent to each other; It is made, including When the pin 10 is fixed by the fixing block 20, the overall shape of the pin 10 is arranged in a semi-circular radial shape while the air flow passage 11 is secured by the elastic force of the pin 10 itself. Heat sink, characterized in that. The method of claim 1, When the pin 10 is fixed by the fixing block 20, the fixing part 13 is in contact with the pin 10 located at the outside of the pin 10 stacked so that the pin 10 is adjacent, and the pin 10 has a semicircular shape. Heat sink characterized in that it is fixed by the pin pressing block 30 is provided with a receiving portion 31 of a semi-circular fan-shaped shape to be kept radially. The method according to claim 1 or 2, The pins 10 are stacked so that each fixing part 13 of the pin 10 is adjacent to each other on the left and right sides so as to press and fix the fixing part 13 by one fixing block 20. Heat sink characterized in that to be arranged in a radial shape of the circular. The method of claim 3, wherein Heat sink, characterized in that the upper inside of the fin 10 is further provided with an insertion groove 14 is inserted into the discharge fan 40 for forcibly discharging air from the air flow passage (11). a) forming fasteners 12 at both ends of the plate 1; b) Bending a plurality of flat plate 1 in half so as to form an air flow passage 11 through which air flows, and pins 10 are formed at both ends of the bent plate 1. Molding; c) stacking the fixing parts 13 of each of the pins 10 to be adjacent to press the fixing parts 13 to the fixing blocks 20 to fix the pins 10; And, When the pin 10 is fixed by the fixing block 20, the overall shape of the pin 10 is arranged in a semi-circular radial shape while the air flow passage 11 is secured by the elastic force of the pin 10 itself. Heat sink manufacturing method characterized in that. The method of claim 1, In the step b), the pin pressing block is provided with a receiving portion 31 in the shape of a semi-circular fan shape in contact with the pin 10 located on the outer side of the pin 10 stacked so that the fixing portion 13 is adjacent to each other ( 30) allowing the pin (10) to be held radially in a semicircular shape; Heat sink manufacturing method characterized in that it further comprises. The method according to claim 5 or 6, In step b), the pins 10 are stacked on the left and right sides of the pins 10 so that the fixing parts 13 are adjacent to each other, and the fixing parts 13 are connected by one fixing block 20. Heat sink manufacturing method characterized in that to be fixed by pressing to be arranged in a radial form of a circular shape. The method of claim 7, wherein In the step a), an insertion groove in which an insertion groove 14 into which a discharge fan 40 for forcibly discharging air from the air flow passage 11 is inserted into the upper portion of the fin 10 disposed radially is formed. Forming forming recesses 15; Heat sink manufacturing method characterized in that it further comprises.

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