CN218735697U

CN218735697U - Heat radiation module

Info

Publication number: CN218735697U
Application number: CN202222463995.8U
Authority: CN
Inventors: 林胜煌
Original assignee: Asia Vital Components Co Ltd
Current assignee: Asia Vital Components Co Ltd
Priority date: 2022-09-16
Filing date: 2022-09-16
Publication date: 2023-03-24
Anticipated expiration: 2032-09-16

Abstract

The utility model provides a heat radiation module, including a heat radiation fin unit and plural heat pipe group, this heat radiation fin unit contains a plurality of fin group intervals and piles up the setting and form, its two ends of plural heat pipe group respectively have a heat absorption portion and a radiating part, and each heat absorption portion of this heat pipe group contacts different sources that generate heat respectively, and each radiating part of this heat pipe group is then clamped respectively between each fin group of above-mentioned, its characterized in that: each heat dissipation part of each heat pipe set extends horizontally from one short side of the fin set to the other short side along the long side direction, so that the heat dissipation parts can be completely distributed on the contact surface of the fin set, the maximum heat dissipation contact area is obtained, and the structural strength of the heat dissipation fin unit can be increased by means of the heat dissipation parts.

Description

Heat radiation module

Technical Field

The utility model relates to a heat dissipation field especially relates to a heat dissipation module.

Background

Referring to fig. 1A and 1B, which are perspective views of a conventional heat sink and with reference to taiwan certificate No. I649530, the conventional heat sink includes a first heat pipe group 91, a second heat pipe group 92, and a heat dissipation portion 93. The heat dissipation member 93 includes a first fin group 931, a second fin group 932 and a third fin group 933, which are stacked, the first fin group 931 is located above the 2 nd and 3

rd fin groups

932 and 933, and the first fin group 931 includes a first support 9311 and a plurality of first fins 9312 attached to the first support 9311.

The second fin group 932 includes a plurality of second supports 9321 and a plurality of second fins 9322 attached to the second supports 9321, and the top and bottom surfaces of the plurality of second fins 9322 are connected to the upper and lower second supports 9321, respectively.

The third fin group 933 includes a third support 9331 and a plurality of third fins 9332 attached to the third support 9331 so as to be in contact with each other, and the plurality of third fins 9332 are located below the plurality of second fins 9322 with the third support 9331 interposed therebetween.

The first fin group 931 and the third fin group 933 have an upper cutout 9314 corresponding to the first heat pipe group 91 and a lower cutout 9334 corresponding to the second heat pipe group 92, respectively, at the center of the long sides of the fins.

The first heat pipe group 91 and the second heat pipe group 92 have 4

first heat pipes

911 and 921, respectively, one end portions (i.e., evaporation portions 9111, 9211) of the first heat pipes 911 and the second heat pipes 921 are connected to water-cooled

heads

94A, 94B contacting heating elements, respectively, the other end portions (i.e., condensation portions 9112, 9212) of the first heat pipes 11 and the second heat pipes 921 are inserted into corresponding upper cutout portions 9314 and lower cutout portions 9334, respectively, and the left and right 2 first heat pipes 911 of the first heat pipes 911 are connected to the first support 9311 and are bent and extended in the left and right directions, respectively, and the left and right 2 second heat pipes 921 similarly located below the second heat pipes 921 are connected to the second support 9331 and are bent and extended in the left and right directions, respectively, so that the heat generation amounts of the heat radiators can be equalized by the design. However, referring to fig. 1B, the bent portions 9113 of the left 2 first heat pipes 911 and the bent portions 9113 of the right 2 first heat pipes 11 of the conventional heat sink located in the upper cutout portion 9314 have a certain bending ratio, so that the bent portions 9113 of the plurality of first heat pipes 911 are horizontally arranged at intervals, and thus cannot be densely and horizontally arranged, then a large gap 913 exists between the bent portions 9113 of the plurality of first heat pipes 911, and a gap 914 also exists between the bent portions 9113 of the 2 first heat pipes 11 in the same direction, and the gaps 913 and the gap 914 are a waste region that is not used at all (e.g., a gray region in fig. 1B (i.e., the contact surface area of the heat dissipation fin group is not used), that is, the plurality of first heat dissipation fins 9312 and the first support 9311 do not completely contact the condensation portions 9112 of the plurality of first heat pipes 911, resulting in reducing the contact area between the plurality of first heat dissipation fins 9312 and the condensation portions 9112 of the plurality of first heat pipes 911. The bent portions of the left and right 2 second heat pipes 921 in the lower cut part 9334 also have a certain bending ratio, which results in the problems that they cannot be closely arranged horizontally and the voids 913 and gaps 914 are wasted areas that are not used, which causes the plurality of third heat sinks 9332 and the third support 9331 not to contact the condensation portions 9212 of the plurality of second heat pipes 921, which results in the contact area between the plurality of third heat sinks 9332 and the plurality of second heat pipes 921 being reduced, which results in the heat sinks having many unused heat conduction areas, thereby reducing the overall heat conduction efficiency.

In addition, the bending portions of the plurality of heat pipes (i.e., the first heat pipe 911 and the second heat pipe 921) have no heat transfer effect because the regions where the heat insulating portions are located inside the upper and lower cut-out

portions

9314 and 9334 are formed as the ineffective heat transfer region X (the dotted-line box region in fig. 1B), so that only the

condensing portions

9112 and 9212 of the first heat pipe 911 and the second heat pipe 921 located at both sides of the ineffective heat transfer region X can actually transfer heat to the first fin group 931 and the third fin group 933 for heat dissipation, but the lengths of the

condensing portions

9112 and 9212 of the first heat pipe 911 and the second heat pipe 921 only cover the positions located at about one third of the lengths of the fin groups, which results in short heat transfer distance and insufficient contact heat transfer area, and thus poor heat dissipation effect.

Further, the opening sizes of the upper and lower cut-

outs

9314, 9334 of the first and second

heat pipe groups

931, 933 of the conventional heat sink are increased as the number of heat pipes (i.e., the first and second heat pipes 911, 921) to be mounted (e.g., 6 or more heat pipes) is increased, so that the area where the bent portions of more heat pipes are located in the upper and lower cut-

outs

9314, 9334 is increased, which results in an increase in the ineffective heat transfer area, and also causes a problem of reducing the contact area between the

condensation portions

9112, 9212 of the plurality of first heat pipes 911 and second heat pipes 921 and the heat sink group. In addition, since the upper and

lower cut portions

9314, 9334 of the plurality of 1 st and 3

rd fin groups

931 and 933 are provided, the structural strength is not good, so that the first, second and

third fin groups

931, 932 and 933 must be used as structural support members through the first, second and

third supports

9311, 9321 and 9331, respectively, which not only increases the cost and the overall weight, but also increases the thermal efficiency due to the heat of each heat pipe group being indirectly transferred to each fin group for heat dissipation, which increases the thermal resistance transferred between the two heat pipe groups, thereby reducing the heat dissipation efficiency.

In addition, in order to insert the other end portions of the first and second

heat pipe groups

91 and 92 into the central positions of the first fin group 931 and the third fin group 933, the upper and

lower cutout portions

9314 and 9334 must be dug out at the expense of the heat radiation area at the central positions, which not only increases the manufacturing process of digging out the upper and

lower cutout portions

9314 and 9334, but also reduces the overall heat radiation area. In addition, the upper and lower cut-out

portions

9314, 9334 are formed in the central positions of the first and third heat

dissipation plate groups

931 and 933, so that the first and second heat

dissipation plate groups

91, 92 are aligned vertically, and the

water cooling heads

94A and 94B connected to the

evaporation portions

9111, 9211 of the first and second heat

dissipation plate groups

91, 92 are aligned vertically, which leads to the problem that the heat sink is easily assembled in the inner space of an electronic product (such as a computer or a server) due to the obstruction of electronic components and thus cannot be assembled.

Therefore, how to solve the problems and disadvantages of the heat sink with more supporting bodies, such as increased cost, reduced heat dissipation area, increased overall weight, and limited space, is a direction in which designers and related manufacturers engaged in the industry need to research and improve.

SUMMERY OF THE UTILITY MODEL

The main objective of the present invention is to provide a heat dissipation module that can be used as a support to increase structural strength, wherein the heat dissipation portion of each heat pipe set extends comprehensively to be laid on the fin set integral contact surface for effective heat exchange.

Another object of the present invention is to provide a heat dissipation module without extra supporting members, so as to effectively reduce the cost and the overall weight.

To achieve the above object, the present invention provides a heat dissipation module, which includes:

a heat radiation fin unit, which comprises a plurality of fin groups stacked, each fin group is formed by mutually horizontally fastening a plurality of fins and is provided with at least one contact surface;

plural heat pipe group, its two ends have a heat absorption portion and a radiating part respectively, this heat absorption portion of this plural heat pipe group contacts different sources of generating heat respectively, and the radiating part of this plural heat pipe group is clamped respectively between per two fin groups, its characterized in that: each heat dissipation part of each heat pipe set horizontally extends to the other short side of the fin set from the outer side of the fin set through one short side along the long side direction, so that the heat dissipation parts are completely distributed on the contact surface of the fin set.

The heat dissipation module, wherein: the heat pipe sets are provided with heat transfer bending parts, the heat transfer bending parts of the heat pipe sets are respectively positioned between the heat absorbing part and the heat radiating part and are connected with each other, and the heat pipe sets correspond to the short sides of the same side or different sides of the plurality of fin sets.

The heat dissipation module, wherein: a heat dissipation flow channel is arranged between every two adjacent fins of each fin group, and the heat dissipation flow channel of each fin group is perpendicular to each heat pipe group.

The heat dissipation module, wherein: each fin of each fin group is provided with an upper folded edge and a lower folded edge, and the upper folded edge and the lower folded edge of the plurality of fins of each fin group are horizontally buckled with each other to form a top contact surface and a bottom contact surface respectively.

The heat dissipation module, wherein: a base is arranged between the heat absorption part and the heating source of each heat pipe set, the base is provided with a plurality of combination parts, the combination parts are connected with the heat absorption parts of the corresponding heat pipe sets, and the heat absorption parts of the heat pipe sets are directly or indirectly contacted with different heating sources.

The utility model discloses a each heat pipe group's each radiating part is extended to another minor face department of this fin group along long limit direction level by a minor face of this fin group to use each radiating part to have laid the contact surface of this fin group completely, outside in order to obtain the biggest area of contact, and can borrow again the radiating part increases radiating fin unit structural strength. And because the utility model discloses save the metal (like iron) support piece that the fin group of every layer had now must install additional, so the utility model discloses compare in prior art and can effectively reach saving cost and weight reduction.

Drawings

Fig. 1A is a perspective view of a conventional heat sink;

FIG. 1B is a schematic top view of a conventional heat sink with some heat dissipating fins omitted;

fig. 2A is an exploded view of the heat dissipation module of the present invention;

fig. 2B is a schematic perspective view of the heat dissipation module of the present invention.

Description of reference numerals: a heat radiation fin unit 1; a bottom fin group 11a; the middle layer fin group 11b; a top fin group 11c; the front long side 12a; the rear long side 12b; left short side 13a; right short side 13b; a fin 12; a top contact surface 121; a bottom contact surface 122; a heat dissipation flow channel 123; an upper hem 124; a lower hem 125; a snap-fit portion 126; a lower heat pipe set 2; a heat pipe 21; a heat absorbing portion 211; a heat dissipation portion 212; a heat transfer bend 213; an upper heat pipe group 3; a heat pipe 31; a heat absorbing portion 311; a heat dissipating portion 312; a heat transfer bend 313; a base 4; a bonding portion 41; a first heat pipe group 91; a first heat pipe 911; an evaporation portion 9111; a condensing portion 9112; a curved portion 9113; a void 913; the gap 914; a second heat pipe group 92; the second heat pipe 921; an evaporation portion 9211; a condensing portion 9212; a heat dissipating portion 93; the first fin group 931; a first support 9311; a first heat sink 9312; upper cutout portion 9314; a second fin group 932; a second support 9321; the second fins 9322; a third fin group 933; a third support 9331; a third heat sink 9332; a lower cutout part 9334;

water cooling heads

94A, 94B; the ineffective heat transfer area X.

Detailed Description

The above objects, together with the structural and functional features thereof, will be best understood from the following description of the preferred embodiment when read in connection with the accompanying drawings.

Referring to fig. 2A and 2B, the heat dissipating module of the present invention includes a heat dissipating fin unit 1 and a plurality of heat pipe sets, which will be described in detail below.

The heat sink unit 1 includes a plurality of fin groups stacked at intervals, and in this embodiment, the plurality of fin groups are explained by using three fin groups, and as described below, for convenience of description, the fin groups are divided into a bottom fin group 11a, an intermediate fin group 11b, and a top fin group 11c, which are respectively explained by stacking the heat pipes at intervals.

Each fin set (i.e. the bottom, middle and

top fin sets

11a, 11b and 11 c) is formed by fastening a plurality of fins 12, and a heat dissipation channel 123 is formed between two adjacent fins 12 of each fin set. In the figure, each fin 12 of the bottom, middle and

top fin groups

11a, 11b and 11c has an upper flap 124 and a lower flap 125 protruding to align with the upper flap 124 and the lower flap 125 of the other adjacent fin, and the upper flap 124 and the lower flap 125 of each fin 12 of each fin group are respectively provided with a fastening portion 126, and the fastening portion 126 is shown in the figure as a concave-convex matching structure, but is not limited thereto, and includes any combination of technical means.

Each fin 12 of each fin set is horizontally buckled (buckled or overlapped) with the buckling part 126 of the adjacent fin by the respective buckling part 126 to form a buckled fin (fin) set. Thus, the upper flanges 124 of each fin group together form a top contact surface 121 of a heat transfer (contact) area of each fin group, and the lower flanges 125 of each fin group together form a bottom contact surface 122 of a heat transfer (contact) area of each fin group. And two opposite long sides (i.e., the front long side 12a and the rear long side 12 b) and two opposite short sides (i.e., the left short side 13a and the right short side 13 b) connecting the two long sides are connected between the top contact surface 121 and the bottom contact surface 122 of each fin group.

Referring to fig. 2A again, the plural heat pipe sets in this embodiment represent two heat pipe sets, and the following description will be divided into a lower heat pipe set 2 and an upper heat pipe set 3 for convenience of description, but the heat pipe sets in practical implementation of the present invention are not limited to the above number.

The lower heat pipe set 2 and the upper heat pipe set 3 each have a plurality of

heat pipes

21, 31 arranged in parallel, each layer of

heat pipe

21, 31 has a

heat absorbing part

211, 311, a

heat dissipating part

212, 312 and a heat

transfer bending part

213, 313, the

heat absorbing part

211, 311 of each layer of heat pipe (i.e. the upper heat pipe 21 and the lower heat pipe 31) respectively contacts with different heat sources (not shown) indirectly or directly, the heat

transfer bending part

213, 313 of each layer of

heat pipe

21, 31 is respectively located between the

heat absorbing part

211, 311 and the

heat dissipating part

212, 312 of the

heat pipe

21, 31 and connected with each other. The heat

transfer bending portions

213 and 313 of the

heat pipes

21 and 31 on the lower and upper layers are located at the short sides corresponding to the same side or different sides of the plurality of fin groups, that is, the heat transfer bending portions 213 of the heat pipes 21 on the lower and upper layers can be selected to be located at the same side direction or different sides corresponding to the left short side 13a of the bottom fin group 11a and the right short side 13b of the top fin group 11 c.

Referring to fig. 2A and 2B, the

heat dissipation portions

212 and 312 of the plurality of

heat pipes

21 and 31 are respectively sandwiched between every two fin sets, the heat dissipation portion 212 of the plurality of heat pipes 21 of the lower layer is sandwiched between the bottom fin set 11a and the middle fin set 11B, and the heat dissipation portion 312 of the plurality of heat pipes 31 of the upper layer is sandwiched between the top fin set 11c and the middle fin set 11B. In detail, the heat dissipation portions 212 of the plurality of heat pipes 21 on the lower layer are horizontally extended from the outer side of the bottom fin group 11a to the right short side 13b of the bottom fin group 11a through the left short side 13a along the long side direction, the heat dissipation portions 312 of the plurality of heat pipes 31 on the upper layer are extended from the outer side of the middle fin group 11b to the left short side 13a of the middle fin group 11b through the right short side 13b along the long side horizontal direction, and the heat dissipation portions 212 of the plurality of heat pipes 21 on the lower layer in parallel are respectively vertically arranged with the heat dissipation flow channels 123 of each fin group. With such an arrangement, the

heat dissipation portions

212 and 312 of the plurality of

heat pipes

21 and 31 of the lower layer and the upper layer are closely attached to each other, juxtaposed, and fully (completely) laid on the top contact surface 121 and/or the bottom contact surface 122 of the fin group contacting the entire corresponding layer, so as to obtain a complete contact area, and the structural strength of the plurality of fin groups (i.e., the bottom layer, the middle layer, and the top

layer fin groups

11a, 11b, and 11 c) is increased by the heat pipe groups.

Referring to fig. 2B again, the

heat absorbing portions

211, 311 of the

heat pipe sets

2, 3 of the lower and upper layers of the present invention are in contact with two corresponding heat sources, i.e. a base 4 is disposed between the

heat absorbing portions

211, 311 of the plurality of

heat pipes

21, 31 of the lower and upper layers and the corresponding different heat sources.

The base 4 has an upper side, a lower side and a plurality of combining portions 41 disposed on the upper side or the lower side of the base or between the upper side and the lower side, in this embodiment, the plurality of combining portions are recessed grooves on the lower side of the base 4 and respectively connected to the corresponding

heat absorbing portions

211, 311, so that the

heat absorbing portions

211, 311 of the plurality of

heat pipes

21, 31 on the upper layer and the lower layer are respectively in direct contact with two different heat sources.

The

heat pipes

21, 31 of the lower and upper layers have the heat-transferring

bent portions

213, 313 located on the short sides (i.e., the left and right

short sides

13a, 13 b) corresponding to different sides of the bottom and top fin groups 11a, 11c, respectively, but are not limited thereto. In other embodiments, the

heat pipes

21, 31 of the lower and upper layers have their heat transfer bends 213, 313 located on the same side corresponding to the short sides (e.g., the right short side 13b or the left short side 13 a) of the bottom and top fin groups 11a, 11c, respectively.

Borrow by the utility model discloses this plural

heat dissipation part

212, 312 of each heat pipe group (be lower floor and upper

heat pipe group

2, 3 promptly) and the bottom contact surface 122 and/or the top contact surface 121 that correspond each fin group (be bottom, intermediate level and top

layer fin group

11a, 11b, 11 c) are complete comprehensive complete contact, let the heat can be complete carry out heat-conduction, this plural

heat dissipation part

212, 312 that see through each heat pipe group simultaneously hug closely each other and constitute the bearing structure who corresponds the fin group as the contact side by side, with the efficiency of the structural strength who effectively increases this heat radiation fin unit. Furthermore, the utility model discloses each fin group has saved the metal (like iron) support piece of traditional (current) fixed fin for can effectively reach reduce cost and alleviate the efficiency of whole weight, and can solve the problem that produces the thermal resistance increase again between current each heat pipe crowd and the fin crowd.

The foregoing description is intended to be illustrative, rather than limiting, and it will be appreciated by those skilled in the art that many modifications, variations, or equivalents may be made without departing from the spirit and scope of the invention as defined in the appended claims.

Claims

1. A heat dissipation module, comprising:

a heat dissipation fin unit, which comprises a plurality of fin groups stacked, each fin group is formed by mutually horizontally buckling a plurality of fins and is provided with at least one contact surface;

plural heat pipe group, its two ends have a heat absorption portion and a radiating part respectively, this heat absorption portion of this plural heat pipe group contacts different sources that generate heat respectively, and the radiating part of this plural heat pipe group is pressed from both sides respectively and is established between per two fin group, its characterized in that: each heat dissipation part of each heat pipe set horizontally extends to the other short side of the fin set from the outer side of the fin set through one short side along the long side direction, so that the heat dissipation parts are completely distributed on the contact surface of the fin set.

2. The heat dissipation module of claim 1, wherein: the heat pipe sets are provided with heat transfer bending parts, the heat transfer bending parts of the heat pipe sets are respectively positioned between the heat absorbing part and the heat radiating part and are connected with each other, and the heat pipe sets correspond to the short sides of the same side or different sides of the plurality of fin sets.

3. The heat dissipation module of claim 1, wherein: a heat dissipation flow channel is arranged between every two adjacent fins of each fin group, and the heat dissipation flow channel of each fin group is perpendicular to each heat pipe group.

4. The heat dissipation module of claim 1, wherein: each fin of each fin group is provided with an upper folded edge and a lower folded edge, and the upper folded edge and the lower folded edge of the plurality of fins of each fin group are horizontally buckled with each other to form a top contact surface and a bottom contact surface respectively.

5. The heat dissipation module of claim 1, wherein: a base is arranged between the heat absorbing part and the heating source of each heat pipe set, the base is provided with a plurality of combining parts, the plurality of combining parts are connected with the heat absorbing parts of the corresponding heat pipe sets, and the heat absorbing parts of the plurality of heat pipe sets are directly or indirectly contacted with different heating sources.