DE102004023819A1 - Heat sinks and passages thereof with multiple directions - Google Patents

Abstract

A heat sink. Multiple heat dissipating units each provide a base and a plurality of parallel ribs disposed thereon. The ribs of each two adjacent heat-dissipating units extend in different directions.

Description

background the invention

Territory of invention

The The present invention relates to a heat sink, and more particularly to a heat sink Heatsink, the passages with providing multiple directions.

description of the prior art

Heat dissipating Devices or systems are widely used in electronic Products such as personal and notebook computers to dissipate heat, generated by components or microprocessors, such as one integrated circuit disposed therein. Due to the progressive Reducing the size of integrated circuits and an advanced pack, however, it decreases per unit area thereof generated heat accordingly. Therefore, heat dissipative devices or heat sink with high power for the described products are indispensable.

1A shows a conventional heat dissipating device 10 comprising an axial fan 20 and a rib structure 30 , The axial fan 20 includes a frame 22 , a hub 24 and a fan 26 that is located at it. The rib structure 30 has a base 32 and several ribs 34 based on that 32 are arranged. The fan wheel 26 has several leaves, and the ribs 34 the rib structure 30 extend in a Y direction of a rectangular XY coordinate system.

After the axial fan 20 on the ribbed structure 30 has been attached, the bottom surface of the rib structure 30 the heat dissipating device 10 centered on a component such as a CPU (not shown). The hub 24 of the axial fan 20 is on the middle of the rib structure 30 arranged, and the blades of the fan 26 are along the circumferential edge of the rib structure 30 located.

During operation, heat generated by the CPU will go over the base 32 on the ribs 34 transfer, and heat in the ribs 34 is derived by an air flow or air flow coming from the fan 20 is produced. The temperature in the middle of the base 32 the rib structure 30 is highest, and gradually decreases in the direction of the circumference thereof.

It is noticed that the middle of the rib structure 30 below the hub 24 of the fan 20 is located, and that the performance of heat dissipation in the middle of the rib structure 30 much less than the circumference thereof, ie the heat dissipation of the middle of the rib structure 30 is through the hub 24 of the fan.

Furthermore, an airflow flows from the fan 20 is driven, due to the longitudinal direction of the ribs 34 the rib structure 30 extending in a Y direction, partially along the passages between the ribs 34 are formed and hits the ribs 34 partially in the X direction (the direction perpendicular to the Y direction). Parts of the air flow collide with each other, causing the smoothness thereof and the cooling rate of the heat dissipating device 10 reduced. The effect of heat dissipation in the middle of the rib structure 30 is also reduced.

1B shows another conventional heat dissipating device 50 that has a ribbed structure 70 and the above-mentioned axial fan 20 includes. The rib structure 70 is different from the rib structure 30 from 1A in that several spaced slots 740 in the X direction on the ribs 74 are formed, ie the slots 740 function as air flow passages in the X direction of the rib structure 70 , Therefore, a larger stream of air can flow evenly through the passages in the X and Y direction of the ribbed structure 70 are formed in the middle of the rib structure 70 enter.

In comparison with the rib structure 30 from 1A is an effective discharge area of the rib structure 70 about 30% smaller than the rib structure 30 , due to the slots 740 on the ribs 74 are formed. Although the formation of the slots 740 allow an air flow, in the X and Y direction in the middle of the rib structure 70 to enter, reduces the loss of dissipative area on the rib structure 70 the convection of the heat dissipating device 50 , Furthermore, the air flow collides in the passages in the X and Y directions, which increases the resistance of the airflow as well as the flow rate and the volume of airflow output from the fins 74 reduced.

Summary the invention

Accordingly It is an object of the invention to provide a heat sink to solve the problems overcome the above-described rib structure.

The invention comprises a plurality of heat-dissipating units, each of which has a base and having a plurality of parallel ribs disposed on the base. The ribs of each two adjacent heat-dissipating units extend in different directions to form passages having multiple directions therebetween. Therefore, a collision of the air flow does not occur in the passages of each heat-dissipating unit.

each Heat dissipating Unit of the heat sink includes furthermore a welding area, which is situated at the circumference of the base of it, with a other heat connecting unit. The base and the fins of the heat dissipating Units are integrally formed and made of copper, a copper alloy, Made of aluminum or an aluminum alloy. The base and the ribs of heat dissipative unit are also connected by welding with each other.

The Heat dissipating Unit further includes several slots in an upper surface of the base of which are formed. The ribs are exactly fitting in the slots arranged to the passages to form between.

The Base of heat dissipative unit comprises a polygonal rod with at least three surfaces, as triangular, sectoral (sectorial), pentagonal and hexagonal. Each two adjacent heat-dissipating units are by welding connected with each other. The bases of all heat dissipating units are through a conductive Adhesive or a conductive Adhesive with low thermal resistance connected. The base and fins of the heat dissipating units are off a conductive Material produced.

A Detailed description will be given in the following embodiments given with reference to the accompanying drawings.

Short description the drawing

The The present invention will be better understood by reading the following detailed Description and examples are fully understood, wherein Reference is made to the accompanying drawing, in which:

1A Fig. 12 is a perspective view of a conventional heat dissipating device;

1B Fig. 12 is a perspective view of another conventional heat dissipating device;

2A Fig. 12 is a perspective view of a heat dissipation device according to a first embodiment of the present invention;

2 B a perspective view of the heat-dissipating device of 2A is;

2C Fig. 12 is a perspective view of a heat dissipation device according to a second embodiment of the present invention;

3A Fig. 12 is a perspective view of a heat dissipating device according to a third embodiment of the present invention;

3B a perspective view of the heat-dissipating device of 3A is;

3C Fig. 12 is a perspective view of a heat dissipating device according to a fourth embodiment of the present invention;

4 Fig. 15 is a perspective view of a heat dissipating device according to a fifth embodiment of the present invention;

5 Fig. 12 is a perspective view of a heat dissipation device according to a sixth embodiment of the present invention; and

6 Fig. 15 is a perspective view of a heat dissipating device according to a seventh embodiment of the present invention.

detailed Description of the invention

In the preferred embodiment of the present invention can with an electric fan (not shown in the figures) heat sink of components or components derive from it.

Referring to 2A and 2 B includes a heat sink 100 in a first embodiment of the invention, four heat-dissipating units 102 . 104 . 106 and 108 , Each heat dissipating unit 102 . 104 . 106 and 108 each includes a base 112 . 114 . 116 and 118 , and a group of parallel ribs 122 . 124 . 126 and 128 is on the bases 112 . 114 . 116 and 118 arranged. Ribs 122 . 124 . 126 and 128 extend individually in different directions with respect to the XY rectangular coordinate system.

The heat-dissipating units 102 . 108 are two opposite and symmetrical polygonal structures, shaped essentially triangular. In 2 B is every basis 112 . 118 the heat dissipating units 102 . 108 essentially triangular, ie every base 112 . 118 makes three surfaces be riding.

The heat-dissipating units 104 . 106 are two opposite and symmetrical polygonal structures, near the heat-dissipating units 102 . 108 and are essentially pentagonal. In 2 B is every basis 114 . 116 the heat dissipating units 104 . 106 formed essentially in a pentagonal column, ie, each base 114 . 116 provides 5 surfaces. Two surfaces each 112 . 114 . 116 and 118 the heat dissipating units 102 . 104 . 106 and 108 are connected along two surfaces, ie the welding areas 115 , That means the heat dissipating units 104 . 106 are both with the heat dissipating unit 102 as well as 108 connected to the edge thereof by welding. In other words, the longitudinal directions of the ribs 122 / 124 . 122 / 126 . 128 / 124 and 128 / 126 the adjacent heat dissipating units 102 / 104 . 102 / 106 . 108 / 104 and 108 / 106 are vertically connected to form multiple passages therebetween.

Further, each heat dissipating unit 104 . 106 two extended sections 130 . 130 that are different from the bases 114 . 116 extend from it and all a hook 132 have it. By connecting the hooks 132 each extended section 130 the heat dissipating units 104 . 106 with the electric fan, the electric fan on the heat-dissipating units 102 . 104 . 106 and 108 attached and is in the middle of the heat sink 100 located.

In this embodiment, for example, the bases 112 and the ribs 122 the heat dissipating unit 102 formed integrally, thereby forming passages with multiple directions. The base and fins of each heat dissipating unit are preferably made of conductive materials such as copper, a copper alloy, aluminum or an aluminum alloy. In other embodiments, the ribs may be welded to the base to form the multi-directional passages thereon, ie, one passage is formed by two adjacent ribs.

In 2A The passages of each heat dissipating unit extend 102 . 104 . 106 and 108 each in different directions with respect to the XY rectangular coordinate system. That means the heat sink 100 provides multi-directional passes in the XY plane of the XY rectangular coordinate system. A positive X direction defines the longitudinal direction of the ribs 122 the heat dissipating unit 102 , and a negative X direction defines the longitudinal direction of the ribs 128 the heat dissipating unit 108 , A positive Y direction defines the longitudinal direction of the ribs 126 the heat dissipating unit 106 , and a negative Y-direction defines the longitudinal direction of the ribs 124 the heat dissipating unit 104 ,

Therefore, the longitudinal direction of the ribs 122 the heat dissipating unit 102 perpendicular to both the ribs 124 the heat dissipating unit 104 as well as the ribs 126 the heat dissipating units 106 , and the longitudinal direction of the ribs 128 the heat dissipating unit 108 is also perpendicular to both the ribs 124 the heat dissipating unit 104 and the ribs 126 the heat dissipating unit 106 , In other words, the connected ribs 122 / 124 the heat dissipating units 102 / 104 , the connected ribs 122 / 126 the heat dissipating units 102 / 106 , the connected ribs 128 / 126 the heat dissipating units 108 / 106 and the connected ribs 128 / 124 the heat dissipating units 108 / 104 are all L-shaped.

During operation, the electric fan drives airflow into all passages of the heat dissipating units 102 . 104 . 106 and 108 to enter, to dissipate heat from it. The air flow then flows out of the heat sink 100 along the passages from the center to the edge thereof, uniformly and radially. Heat, which is in the middle of the heat sink 100 is effectively discharged and carried by the air flow in different directions.

With the ribs 122 . 124 . 126 and 128 the area for discharging increases, and an airflow from the electric fan becomes uniform from each heat dissipating unit 102 . 104 . 106 and 108 conducted, allowing heat from the heat sink 100 , especially from the middle is derived quickly. Furthermore, a collision, turbulence or influence is prevented, whereby the effectiveness of the heat dissipation of the heat sink 100 is increased.

Referring to 2C differs, in a second embodiment, a heat sink 150 from the heat sink 100 the first embodiment in that four bars 140 ' each extending from the bottom thereof, and a conductive plate 140 passing through the bars 140 ' is limited, further provided to connect to the bottom thereof, that is, the conductive plate 140 is directly on the outer surface of the bases 112 . 114 . 116 and 118 appropriate. In this embodiment, the conductive plate 140 preferably made of copper or a copper alloy.

If the conductive plate 140 is disposed on a component such as a CPU (not shown) is the heat sink 150 it is mounted directly and centered on the top surface of the CPU, and therefore heat is transferred from the CPU via the conductive plat th 140 directly on each heat dissipating unit 102 . 104 . 106 and 108 transfer.

Furthermore, a conductive adhesive or a conductive adhesive 145 with low thermal resistance as well as solder paste between the conductive plate 140 and any heat dissipating unit 102 . 104 . 106 and 108 arranged, ie the heat dissipating units 102 . 104 . 106 and 108 are also via the conductive adhesive or the conductive adhesive 145 connected. Therefore, using the conductive adhesive or adhesive 145 that is between the conductive plate 140 and the heat dissipating units 102 . 104 . 106 and 108 is arranged, the heat resistance reduces therebetween, and therefore, the heat flow from the CPU to the heat sink 150 elevated.

Referring to 3A and 3B differs, in a third embodiment, a heat sink 200 from the heat sink 100 the first embodiment in that the number of heat-dissipating units is three, denoted by reference numerals 202 . 204 and 208 where the heat dissipating unit 202 a single structure is essentially through the heat-dissipating units 104 and 106 integrated the first embodiment.

Each heat dissipating unit 202 . 204 and 208 includes a base 212 . 214 and 218 and three groups of parallel ribs 222 . 224 and 228 , each on the bases 212 . 214 and 218 are arranged. The base 212 the heat dissipating unit 202 is formed in an hourglass-spaced column, and the ribs 222 it extends in the Y-axis on the XY plane. The heat-dissipating unit 202 includes for advanced sections 230 that are different from the bases 212 extend from it and all a hook 232 having the same function as the extended portions and the hooks mentioned above.

Ribs 222 the heat dissipating unit 202 are each perpendicular to both the ribs 224 as well as 228 the heat dissipating units 204 respectively. 208 connected.

Two bases each 212 . 214 and 218 the heat dissipating units 202 . 204 and 208 are along welding areas 215 connected.

In this embodiment For example, the base and fins of the heat-dissipating unit are integral formed, and preferably of conductive materials such as copper, a copper alloy, aluminum or an aluminum alloy. In other embodiments can The ribs should be welded to the base to pass through the multiple To form directions on it, i. One passage is through two adjacent ones Formed ribs.

Referring to 3C differs, in a fourth embodiment, a heat sink 250 from the heat sink 200 of the third embodiment in that four bars 240 ' each extending from the bottom thereof, and a conductive plate 240 passing through the bars 240 ' is limited, further provided to be attached to the bottom thereof, ie the conductive plate 240 is directly on the outer surface of the bases 212 . 214 and 218 appropriate.

In this embodiment, the conductive plate 240 preferably made of copper or a copper alloy. A conductive adhesive or a conductive adhesive 245 with low thermal resistance is between the conductive plate 240 and any heat dissipating unit 202 . 204 and 208 arranged, ie the heat dissipating units 202 . 204 and 208 are also via the conductive adhesive or the conductive adhesive 245 connected.

Referring to 4 comprises, in a fifth embodiment of the invention, a heat sink 300 four heat-dissipating units 302 . 304 . 306 and 308 essentially having a rectangular column or shape. Each heat dissipating unit 302 . 304 . 306 and 308 has the same rectangular structure.

For example, each heat dissipating unit 302 . 304 , and 306 a base 312 . 314 and 316 and a group of parallel ribs 322 . 324 and 326 , Ribs 322 . 324 and 326 are each vertical on the bases 312 . 304 and 316 arranged. The bases 312 . 314 and 318 the heat dissipating units 302 . 304 and 308 are formed essentially rectangular, ie each base 312 . 314 . 316 provides four surfaces. When the heat dissipating units 302 . 304 and 306 are connected by welding, is the heat dissipating unit 302 both with the heat dissipating unit 304 as well as 306 connected, each along two surfaces.

By welding the heat dissipating units 302 . 304 . 306 and 308 to the heatsink 300 Ribs extend to form 322 . 324 . 326 and 328 individually in different directions with respect to the rectangular XY coordinate system. In other words, the passages of each heat dissipating unit 302 . 304 . 306 and 308 each extend in different directions with respect to the rectangular XY coordinate system. A positive X direction defines the longitudinal direction of the ribs 326 the heat dissipating unit 306 , and a negative X direction defines the longitudinal Direction of the ribs 324 the heat dissipating unit 304 , A positive Y direction defines the longitudinal direction of the ribs 328 the heat dissipating unit 308 , and a negative Y-direction defines the longitudinal direction of the ribs 322 the heat dissipating unit 302 ,

Therefore, the longitudinal direction of the ribs 322 the heat dissipating unit 302 perpendicular to both the ribs 324 the heat dissipating unit 304 as well as the ribs 326 the heat dissipating unit 306 , and the longitudinal direction of the ribs 328 the heat dissipating unit 308 is also perpendicular to both the ribs 324 the heat dissipating unit 304 as well as the ribs 326 the heat dissipating unit 306 ,

In this embodiment For example, the base and fins of the heat-dissipating unit are integral formed, and preferably of conductive materials such as copper, a copper alloy, aluminum or an aluminum alloy. In other embodiments can The ribs should be welded to the base to pass through the multiple To form directions on it, i. a passage is through two formed adjacent ribs.

A conductive plate, preferably made of copper or a copper alloy, is further provided to attach to the underside of the heat sink 300 be attached in the same way as those in the description of the heat sink 100 . 200 has been described, and a conductive adhesive or a conductive adhesive with low thermal resistance is disposed therebetween.

Referring to 5 comprises, in a sixth embodiment of the invention, a heat sink 400 six heat-dissipating units 402 . 404 . 406 . 408 . 410 and 412 essentially forming a hexagonal column or shape. Each heat dissipating unit 402 . 404 . 406 . 408 . 410 and 412 has the same triangular structure.

For example, each heat dissipating unit 402 . 404 and 412 One Base 422 . 424 . 432 and a group of parallel ribs 442 . 444 and 442 , Ribs 442 . 444 and 442 are each vertical on the bases 422 . 424 . 432 arranged. The bases 422 . 424 and 432 the heat dissipating units 402 . 404 and 412 are essentially triangular, ie each base 422 . 424 and 432 provides three surfaces.

When the heat dissipating units 402 . 404 and 412 are connected to each other by welding, two surfaces of the heat dissipating unit 402 with both heat dissipating units 404 respectively. 412 connected. Ribs 442 are in addition to the middle each with each rib 442 . 452 the heat dissipating units 404 and 412 connected to form a plurality of V-shaped passages therebetween. That is, the ribs 442 . 444 and 446 . 448 . 450 and 452 extend in different directions on the XY plane, and a 60 degree angle is between each two longitudinal directions of the ribs 442 . 444 and 446 . 448 . 450 and 452 the heat dissipating units 402 . 404 . 406 . 408 . 410 and 412 available.

A conductive plate, preferably made of copper or a copper alloy, is further provided to attach to the underside of the heat sink 400 be attached in the same way as those in the description of the heat sink 100 . 200 and 300 has been described, and a conductive adhesive or a conductive adhesive with low thermal resistance is disposed therebetween.

Referring to 6 comprises, in a seventh embodiment of the invention, a heat sink 500 three heat-dissipating units 502 . 504 and 506 essentially forming a rectangular pillar or mold. Each heat dissipating unit 502 . 504 and 506 has a rectangular structure, and the heat-dissipating units 502 are between the heat dissipating units 504 and 506 arranged.

Each heat dissipating unit 502 . 504 and 506 includes a base 512 . 514 . 516 and a group of parallel ribs 522 . 524 and 526 , Ribs 522 . 524 and 526 are each vertical on the bases 512 . 514 . 516 arranged. The bases 512 . 514 . 516 the heat dissipating units 502 . 504 and 506 are essentially rectangular, ie each base 512 . 514 . 516 provides four surfaces. In the preferred embodiment, the base is 512 the heat dissipating unit 502 square, and the longitudinal direction of the ribs 522 is perpendicular to both the ribs 524 the heat dissipating unit 504 as well as the ribs 526 the heat dissipating unit 506 ,

By welding the heat dissipating units 502 . 504 and 506 to the heatsink 500 to form, the ribs extend 522 and 524 or the ribs 522 or 526 individually in different directions with respect to the rectangular XY coordinate system. The passages of each heat dissipating unit 502 . 504 and 506 each extend in different directions with respect to the rectangular XY coordinate system. A positive and negative X direction define the longitudinal direction of the ribs 522 the heat dissipating unit 502 , A positive Y direction defines the longitudinal direction of the ribs 526 the heat dissipating unit 506 , and a negative Y-direction defines the longitudinal direction of the ribs 524 the heat dissipating unit 504 ,

In other words, the longitudinal directions of the ribs 522 / 524 and 522 / 526 the adjacent heat dissipating units 502 / 504 and 502 / 506 are vertically connected to form multiple passages therebetween.

In this embodiment For example, the base and fins of the heat-dissipating unit are integral formed, and preferably of conductive materials such as copper, a copper alloy, aluminum or an aluminum alloy. In other embodiments can The ribs should be welded to the base to pass through the multiple To form directions on it, i. a passage is through two adjacent ribs formed; several spaced slots (not shown in the figures) as well on the upper surface the bases are formed. The ribs are inserted into the slots, in each case the passages to form between.

A conductive plate, preferably made of copper or a copper alloy, is further provided to attach to the underside of the heat sink 500 be attached in the same way as those in the description of the heat sink 100 . 200 . 300 and 400 has been described, and a conductive adhesive or a conductive adhesive with low thermal resistance is disposed therebetween.

Farther can, in the other embodiments, the bases of heat be divergent units polygonal structures, such as sector-shaped, isosceles triangular or other structures to form the heat sink, so that heat, the generated in the middle of the heat sink is quickly dissipated and carried by airflow that along different passages flows, i.e. the temperature of the center and the edge of the base of the heat sink are close side by side. No airflow collisions occur in the passages of the Heat dissipating Units up.

Even though the invention has been described in connection therewith, which is currently is considered to be the most practical and most preferred embodiment, It should be understood that the invention is not to be disclosed Embodiments is limited but on the contrary it is intended that manifold modifications and equivalent arrangements included within the spirit and scope of the appended claims are.

Claims (11)

Heat sink, comprising: several Heat dissipating Units, each of which has a base and several parallel ribs which are arranged on the base, wherein the ribs of two adjacent heat dissipative units extend individually in different directions. Heat sink after Claim 1, wherein each heat dissipating unit further comprises a welding area attached to the Edge of the base thereof is arranged to provide it with another heat-dissipating unit connect to. Heat sink after Claim 1, wherein the base and the fins of the heat dissipating unit integrally formed are. Heat sink after Claim 3, wherein the base and the fins of the heat dissipating unit of copper, a copper alloy, aluminum or an aluminum alloy are. Heat sink after Claim 1, wherein the base and the fins of the heat dissipating unit connected by welding are. Heat sink after Claim 5, wherein the base and the fins of the heat dissipating unit of copper, a copper alloy, aluminum or an aluminum alloy are. Heat sink after Claim 1, wherein the heat dissipating unit further comprises a plurality of slots on one upper surface the basis of which are formed; and wherein the ribs respectively in the Slits are arranged. Heat sink after Claim 1, wherein the base of the heat dissipating unit a polygonal column with at least three surfaces includes. Heat sink after Claim 1, wherein the base of the heat dissipating unit a sectored pillar includes. Heat sink after Claim 1, wherein each two adjacent heat-dissipating units connected by welding are. Heat sink after Claim 1, wherein the bases of all heat-dissipating units means a conductive Adhesive or adhesive with low thermal resistance are connected.