DE202013103297U1 - Fluted cooling rib and heat sink with self - Google Patents

Abstract

A corrugated fin (1) comprising a corrugated fin body (12) having a corrugated sheet shape and a plug portion (11) disposed on an underside of the corrugated fin body for mounting the same, the corrugated fin body defining a corrugated pattern formed distributed in a direction perpendicular to the male portion.

Description

FIELD OF THE INVENTION

The present invention relates to the technology of cooling fins, and more particularly relates to a corrugated fin for heatsinks having a corrugated fin body with a high surface area providing a larger surface area for heat dissipation to improve the efficiency of heat dissipation. The invention also relates to a heat sink employing this design of corrugated fins.

BACKGROUND OF THE INVENTION

Conventional heatsinks generally include a heatsink block and a plurality of cooling fins. Some heat sinks have one or more heatpipes or heat pipes attached to the heat sink block. Conventional cooling fins for heat sinks are usually formed in the form of a flat sheet for dissipating heat, which is relayed from the heat sink block through heat pipes. The support and overall area of the cooling fins has a direct influence on the overall efficiency of heat dissipation of the heat sink. The larger the number of cooling fins, the higher the heat dissipation efficiency of the heat sink.

U.S. Patent No. 5,014,776 entitled "Radiator or Radiator Heat Exhaust Unit" discloses a heat sink design. U.S. Patent No. 6,758,262 entitled "Heatsink, Method of Making Same and Pressing Template" discloses another heat sink design. According to these known designs, fins (cooling fins) are inserted in channels of a heat sink block and pressed in place by deformation of intermediate fins. However, since these fins (cooling fins) are formed as flat sheet metal elements, their surface content for heat dissipation is subject to restrictions.

SUMMARY OF THE INVENTION

It is an object of the present invention to provide an improved cooling fin for heat sinks for further improving the overall efficiency of heat dissipation of the fin and a heat sink using the same. It is a further object of the present invention to provide a corresponding heat sink.

The above objects are achieved by a corrugated fin according to claim 1 and by a heat sink according to any one of claims 5 to 7. Further advantageous embodiments are the subject of the dependent claims.

According to the present invention, there is provided a corrugated fin for a heat sink, which has a corrugated fin body having a large surface area providing an enlarged surface for heat dissipation, and a plug portion provided at the bottom of the corrugated fin body for mounting.

By using the corrugated fin body having a large surface area, the total surface area for heat dissipation is increased and the overall efficiency of heat dissipation of the fin is improved.

According to another embodiment, the corrugated fin body of the corrugated fin defines a corrugated pattern formed distributed in a direction perpendicular to the plug portion.

According to another embodiment, each corrugated fin has a portion that is configured to provide a partially deformed transition region between the corrugated fin body and the plug portion.

According to a further embodiment, the plug-in portion of each corrugated fin is configured to have at least one heat pipe groove at the center for receiving at least one heat pipe, two lower mounting edges on two opposite sides relative to the at least one heat pipe. Groove for attachment to two rod-shaped heat sink blocks and two angled flanges provide, which are each arranged between the at least one heatpipe groove and the lower mounting edges and are flush with the inserted at least one heat pipe or heat pipe and the rod-shaped heat sink blocks.

An embodiment of the heat sink of the present invention includes an integrally formed heat sink block defining a plurality of mounting grooves on one side thereof, and a plurality of corrugated fins each attached to the mounting grooves of the integrally formed heat sink block. Each corrugated fin has a corrugated fin body having a large surface area providing an enlarged surface for heat dissipation, and a mating portion located at the bottom of the corrugated fin body with a press fit in a mounting groove of the integrally formed heatsink block is.

Another embodiment of the heat sink according to the present invention comprises two rod-shaped heat sink blocks each defining a plurality of mounting grooves on one side thereof and a plurality of corrugated cooling fins respectively attached to the mounting grooves of the rod-shaped heat sink blocks. Each corrugated fin has a corrugated fin body having a large surface area providing an enlarged surface for heat dissipation, and a mating portion located at the bottom of the corrugated fin body having been press-fitted into a mounting groove of each of the two rod heatsink blocks ,

Another embodiment of the heat sink according to the present invention comprises an integrally formed heat sink block or two rod-shaped heat sink blocks, a plurality of corrugated fins, which are respectively provided on the integrally formed heat sink block or the two rod-shaped heat sink blocks, and a plurality of heat pipes or heatpipes are attached to the ribbed cooling fins. Each corrugated fin has a corrugated fin body having a large surface area providing an enlarged surface for heat dissipation and a mating portion located at the bottom of the corrugated fin body with a press-fit into a respective mounting groove of the integrally formed heatsink block or each rod-shaped heat sink block is inserted or pressed, and a plurality of through holes, which are formed through the corrugated fin body with a high surface area.

FIGURE OVERVIEW

1 is a side view of a corrugated fin according to the present invention.

2 is a top view of the in 1 shown corrugated fin.

3 FIG. 10 is an exploded view of a heat sink according to a first embodiment of the present invention. FIG.

4 is a schematic view in the assembled state of the heat sink according to the first embodiment of the present invention.

5 illustrates through-holes formed in the corrugated fin according to the present invention.

6 FIG. 15 is a top perspective view of a heat sink according to a second embodiment of the present invention. FIG.

7 is a plan view of the heat sink after 6 ,

8th shows an alternative form of the corrugated fin according to the present invention.

9 FIG. 15 is a top perspective view of a heat sink according to a third embodiment of the present invention. FIG.

10 is a plan view of the heat sink after 9 ,

11 is an exploded view of a heat sink according to a fourth embodiment of the present invention.

12 FIG. 14 is a top perspective view of the heat sink according to the fourth embodiment of the present invention. FIG.

DETAILED DESCRIPTION

The ribbed cooling fin 1 according to the present invention for use in a heat sink is in the 1 and 2 shown. The ribbed cooling fin 1 is a corrugated sheet metal element that has a corrugated fin body 12 having a large surface, the, z. B. by punching, is formed, and a plug-in section 11 Standing on the bottom of the ribbed fin 12 is located, for pressing into an integrally formed heat sink block 2 (please refer 3 ) or in two rod-shaped heat sink blocks 2 ' (please refer 11 ). Because the corrugated fin body 12 has a large surface area, the entire radiation or heat dissipation surface is larger and the overall heat dissipation capability of the cooling fin or the heat sink using the cooling fin is improved.

The corrugated pattern of the corrugated fin body 12 is in a direction perpendicular to the male portion 11 distributed trained. That is, the beads and grooves (or grooves) of the corrugated fin body 12 extend transversely to the plug portion 11 , Further, the corrugated fin body is 1 partially deformed by punching, around a partially deformed transition surface 13 between the plug section 11 and the corrugated fin body 12 provide. Because the ribbed pattern of the corrugated fin body 12 in a direction perpendicular to the male portion 11 is distributed, is the mechanical strength of the corrugated fin body 12 improved.

Furthermore, the aforementioned plug-in section 11 for pressing into corresponding mounting grooves 21 be designed differently. In the embodiment, in the 1 is shown is the bottom edge of the cooling fin folded back and upright formed to the plug portion portion 11 train. Alternatively, the distal end of the male portion may be reworked or otherwise formed to provide an overall L-shaped configuration.

With reference to the 3 and 4 a heat sink according to a first embodiment of the present invention is shown. As shown, the heat sink has a plurality of corrugated fins 1 and an integrally formed heat sink block 2 on. The integrally formed heat sink block 2 has a plurality of mounting grooves 21 on, which are arranged in parallel on the upper side. Each ribbed cooling fin 1 has a plug-in section 11 on its underside, a corrugated fin body 12 on its top and a transitional area 13 between the plug section 11 and the corrugated fin body 12 on. The plug sections 11 the ribbed cooling fins 1 are each in the mounting grooves 21 the integrally formed heat sink block 2 pressed. Furthermore, these ribbed cooling fins 1 the same size. The corrugated or corrugated design of the ribbed cooling fins 1 allows a larger surface for heat dissipation to improve the overall efficiency of heat dissipation of the heat sink.

With reference to the 5 to 7 a heat sink according to a second embodiment of the present invention is shown. As shown, the heat sink has a plurality of corrugated fins 1a , an integrally formed heat sink block 2a and a plurality of heat pipes (heat pipes) 3 on. Each ribbed cooling fin 1a has a plug-in section 11a , which is arranged on its underside, a corrugated fin body 12a Located on its top, a transitional area 13a between the plug section 11a and the corrugated fin body 12a and a plurality of through holes 121 on, at selected points through the corrugated fin body 12a are formed through. The integrally formed heat sink block 2a has a plurality of mounting grooves 21a which are arranged in parallel on its top, and a plurality of heat pipe grooves 22a on, which are arranged on its underside. The plug section parts 11a the ribbed cooling fins 1a are each in the mounting grooves 21a the integrally formed heat sink block 2a pressed. The heatpipes or heat pipes 3 are bent tubes, one end of each in a corresponding mounting groove 21a the integrally formed heat sink block 2a is mounted, and the other end in each case closely fitting in a corresponding through hole 121 each ribbed cooling fin 1a is mounted.

The aforementioned first and second embodiments are convenient for use in a computer for cooling the CPU. The latter is with the additional heatpipes or heat pipes 3 Mistake.

With reference to the 8th to 10 For example, a heat sink according to a third embodiment for use in a computer for cooling the graphics card is shown. This third embodiment is substantially similar to the above-mentioned second embodiment except for the structure of the corrugated fins. As shown, the corrugated fins are 1b wide and flat, each of which has a plug-in section 11b , which is arranged on the underside, a corrugated fin body 12b disposed on the top thereof, a transitional area 13b between the plug section 11b and the corrugated fin body 12b and a plurality of through holes 121b through the corrugated fin body 12b are formed through at selected locations. The integrally formed heat sink block 2 B has a plurality of mounting grooves 21b which are arranged in parallel on its top, and a plurality of heat pipe grooves 22b on, which are arranged on its underside. The plug sections 11b the ribbed cooling fins 1b are each in the mounting grooves 21b the integrally formed heat sink block 2 B pressed. The heatpipes or heat pipes 3 are curved tubes, one end of each in a corresponding mounting groove 21b the integrally formed heat sink block 2 B is inserted, and the other end of each closely fitting in a respective through hole 121b each ribbed cooling fin 1b is used.

With reference to the 11 and 12 a heat sink according to a fourth embodiment of the present invention is shown. As shown, the heat sink has a plurality of corrugated fins 1c , two rod-shaped heat sink blocks 2 ' and a plurality of heat pipes or heat pipes 3 on. Each ribbed cooling fin 1c has a plug-in section 11c on one side of it, a corrugated fin body 12c Located on the other side of it, a transition area 13c between the plug section 11c and the corrugated fin body 12c and a plurality of through holes 121c on through the ribbed body of the cooling rib 12c through at selected locations are formed. Furthermore, the one side of the plug-in section 11c with the transition area 12c and the other side thereof is formed to have a plurality of heat pipe grooves 111c placed in the middle to accommodate the heatpipes 3 are arranged, two lower mounting edges 112c on two opposite sides of the heatpipe grooves 11c disposed are and each in a corresponding mounting groove 21 ' a respective rod-shaped heat sink block 2 ' are pressed in, and two angled flanges 113c to provide spaced between the heat pipe grooves 111c and the lower mounting grooves 112c are arranged and flush with the heatpipes used 3 and the rod-shaped heat sink block 2 ' are arranged or complete (see 12 ). After mounting the heatpipes 3 in the through holes 121c and the heatpipe grooves 111c the ribbed cooling fins 1c are the rod-shaped heat sink blocks 2 ' flush with the angled flanges 113c the ribbed cooling fins 1c and the heatpipes 3 to allow direct contact with the surface of an external heat exchanger surface. Furthermore, the heat sink without the heat pipes 3 be designed.

Furthermore, the heat pipe grooves 111c each ribbed cooling fin 1c be arranged together throughout. Alternatively, the heat pipe grooves 111c each ribbed cooling fin 1c spaced apart from each other at a predetermined distance. In the example that is in the 4 shown are two heatpipe grooves 111c arranged together throughout. Thus, after installation of the two matching heat pipes 3 the two heatpipes 3 directly to each other, and without a gap in between (see 12 ). If the two heatpipe grooves 111c spaced apart from each other, is a plane between the two heat pipes or heat pipes 3 educated.

After assembly of the heat sink, the two rod-shaped heat sink blocks 2 ' , the heatpipes 3 and angled flanges 113c the ribbed cooling fins 1c kept flush, creating a common plane is spanned.

While specific embodiments of the invention have been described in detail for purposes of illustration, numerous modifications and enhancements may be made without departing from the general spirit and scope of the invention. Accordingly, the invention is not limited except for those of the accompanying claims.

In summary, the present invention discloses a heat sink having a heat sink block or two heat sink blocks and corrugated fins attached to the heat sink block or heatsink blocks. Each corrugated fin has a corrugated fin body having a large surface area to provide better heat dissipation, and a plug portion disposed on the underside of the corrugated fin body with a large surface and press-fitted into a corresponding mounting groove of the heat sink block or heatsink blocks is.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 5014776 [0003]
• US Pat. No. 6,758,262 [0003]

Claims (11)

Ribbed cooling fin ( 1 ) comprising a corrugated fin body ( 12 ) with the form of a corrugated sheet and a plug-in portion ( 11 ) disposed on an underside of the corrugated fin body for mounting the same, the corrugated fin body defining a corrugated pattern formed distributed in a direction perpendicular to the plug portion. A corrugated fin according to claim 1, further comprising a transition region ( 13 ) between the corrugated fin body ( 12 ) and the plug-in section ( 11 ). Fluted fin according to claim 1 or 2, wherein the plug portion has a lower edge which is folded back and folded up or upright to the plug portion ( 11 ) train. Corrugated fin according to one of the preceding claims, wherein the plug-in portion ( 11 ) is formed to at least one heat pipe groove or heat pipe groove ( 22a . 111c ) for receiving at least one heat pipe or heat pipe, two lower mounting edges ( 112c ) provided on two opposite sides relative to the at least one heat pipe groove or heat pipe groove, and an angled flange (FIG. 113c ) provided between the at least one heat pipe groove and each lower attachment edge. A heat sink comprising: a one-piece heat sink block ( 2 ; 2 ' ) with a plurality of mounting grooves ( 21 ) arranged on one side thereof; and a plurality of ribbed cooling fins ( 1 ), which are respectively fastened to the mounting grooves of the integrally formed heat sink block, each corrugated cooling fin having a corrugated fin body ( 12 ) with a shape of a corrugated or corrugated sheet and a plug portion ( 11 ) which is provided on an underside of the corrugated fin body and is press-fitted into one of the mounting grooves of the integrally formed heat sink block, wherein the corrugated fin body ( 12 ) defines a corrugated pattern which is distributed in a direction perpendicular to the male portion. A heat sink comprising: a one-piece heat sink block ( 2 ; 2 ' ) with a plurality of mounting grooves ( 21 ) disposed on one side thereof and a plurality of heat pipe grooves (heat pipe grooves). 22a ) arranged on the other side thereof; a plurality of ribbed cooling fins ( 1 ), which are respectively secured to the mounting grooves of the integrally formed heat sink block, wherein each corrugated fin a corrugated fin body ( 12 ) with a shape of a corrugated or corrugated sheet, a plug-in portion ( 11 ) located on a lower side of the corrugated fin body ( 12 ) is arranged and with a press fit in one of the mounting grooves of the corrugated fin body ( 12b ) of the integrally formed heat sink block is inserted or pressed into this, and a plurality of through holes ( 121b ) formed through the corrugated fin body, the corrugated fin body defining a corrugated pattern extending in a direction perpendicular to the plug portion (FIG. 11b ) is formed distributed; and a plurality of heat pipes or heatpipes ( 3 ), wherein one end of the heat pipe or the heat pipe is inserted into a respective one of the heat pipe grooves of the integrally formed heat sink block and another end is tightly fitted in a respective through hole of the corrugated fin. A heat sink comprising: two rod-shaped heat sink blocks ( 2 ; 2 ' ), wherein each rod-shaped heat sink block has a plurality of mounting grooves ( 21 ) disposed on one side thereof; a plurality of ribbed cooling fins ( 1 ), which are respectively secured to the mounting grooves of the rod-shaped heat sink blocks, wherein each corrugated fin a corrugated fin body ( 12 ) having the form of a corrugated sheet, a plug portion ( 11 ) provided on the underside of the corrugated fin body and fixed in one of the mounting grooves of the rod-shaped heat sink blocks, and a plurality of through-holes (FIGS. 121 ) through the corrugated fin body ( 12 are formed, wherein the corrugated fin body determines a corrugated pattern, which in a direction perpendicular to the plug portion ( 11 ), wherein the plug portion defines a plurality of heat pipe grooves in a middle portion thereof and two lower mounting edges disposed on two opposite sides relative to the heat pipe grooves ( 22b ) are arranged and in each case in a corresponding mounting groove ( 21b ) are inserted or pressed into the rod-shaped heat sink blocks with a press fit; and several heat pipes or heatpipes ( 3 ), which are each mounted in the heat pipe grooves of the corrugated fins and flush with the rod-shaped heat sink blocks. A heat sink according to any one of claims 5 to 7, wherein each of the corrugated fins ( 12a ) a plurality of through holes ( 121 ) formed through the fin body; one end of each heat pipe or each heat pipe ( 3 ) into a respective heat pipe groove ( 22a ) of the corrugated fin is mounted and / or inserted and the other end is firmly or tightly mounted or mounted in a respective through hole of the corrugated fin. A heat sink according to claim 7 or 8, wherein each corrugated fin further comprises two angled flanges ( 113c ) each extending from the male portion between the heat pipe grooves ( 111c ) and the lower mounting edges ( 112c ) and flush with the heat pipes and the rod-shaped heat sink blocks. Heat sink according to one of claims 7 to 9, wherein the heat pipe grooves of each corrugated fin directly abut each other. A heat sink according to any one of claims 7 to 10, wherein the heat pipe grooves of each corrugated fin are spaced apart from each other by a predetermined distance.

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