HEAT DISSIPATING MODULE

Abstract

The present invention relates to a heat dissipating module which comprises a first flat shell body and a plurality of second flat shell bodies. The first flat shell body has a first chamber and a first wick structure formed on an inner wall of the first chamber. Each of the second flat shell bodies defines a second chamber which is provided with a working fluid and a second wick structure therein. Each of the second flat shell bodies has a heat pipe plugged and connected to the first flat shell body. Therefore, the working fluid in each of the second chambers flows into the first chamber through the corresponding heat pipes to perform heat dissipation by liquid-vapor circulation.

Claims

1. A heat dissipating module, comprising: a first flat shell body defining a first chamber and having a plurality of first holes communicating with the first chamber, wherein the first chamber has a first wick structure disposed therein and a top side spaced with the first holes correspondingly; and a plurality of second flat shell bodies each defining a second chamber and having at least one second hole communicating with the second chamber, wherein the second chamber is provided with a working fluid and a second wick structure therein, wherein the second chamber has a bottom side spaced with the second hole correspondingly, wherein each of the second flat shell bodies is connected to the first flat shell body through a heat pipe having a heat pipe channel and a heat pipe wick structure, wherein the heat pipe channel is connected to the second chamber and the first chamber, wherein the heat pipe wick structure is disposed in the heat pipe channel and connected to the first wick structure and the second wick structure by a capillary connection.

2. The heat dissipating module according to claim 1, wherein the first flat shell body has a first outer top surface defining a heat dissipating area, wherein the each of the second flat shell bodies has a second outer bottom surface defining a heat absorbing area, wherein the heat dissipating area of the first flat shell body is larger than the heat absorbing area of the each of the second flat shell bodies.

3. The heat dissipating module according to claim 1, wherein the first flat shell body has a first outer top surface defining a heat dissipating area, wherein the each of the second flat shell bodies has a second outer bottom surface defining a heat absorbing area, wherein the heat dissipating area of the first flat shell body is larger than the sum of the absorbing areas of the second flat shell bodies.

4. The heat dissipating module according to claim 1, wherein the first flat shell body is disposed above the second flat shell bodies.

5. The heat dissipating module according to claim 4, wherein the second flat shell bodies are disposed to a left-and-right arrangement below the first flat shell body.

6. The heat dissipating module according to claim 1, wherein the heat pipe has a pipe wall, a first extension portion, and a second extension portion opposite to the first extension portion, wherein the first extension portion forms a first open end and the second extension portion forms a second open end, wherein the heat pipe channel and the heat pipe wick structure are both disposed in the pipe wall and between the first open end and the second open end.

7. The heat dissipating module according to claim 6, wherein the first extension portion extends from the first open end into the first chamber such that the first open end is pressed against the first wick structure on the top side in the first chamber, wherein the second extension portion extends from the second open end into the second chamber such that the second open end is pressed against the second wick structure on the bottom side in the second chamber.

8. The heat dissipating module according to claim 7, wherein the heat pipe wick structure is connected to the first wick structure and the second wick structure through the first open end and the second open end by the capillary connection.

9. The heat dissipating module according to claim 8, wherein the first extension portion and the second extension portion are provided with a first throughhole and a second throughhole, respectively, both penetrating through the pipe wall, wherein the heat pipe channel communicates with the first chamber and the second chamber through the first throughhole and the second throughhole, respectively.

10. The heat dissipating module according to claim 9, wherein the pipe wall has an inner surface facing the heat pipe channel and the inner surface is provided with a plurality of ribs disposed spacedly, wherein a groove is disposed between each two adjacent ribs, wherein the grooves and the ribs are interlaced with one another and extend along a longitudinal direction of the heat pipe.

11. The heat dissipating module according to claim 1, wherein a supporting cylinder is disposed in the heat pipe channel and extends along a longitudinal direction of the heat pipe, wherein two opposite ends of the supporting cylinder are individually pressed against the first wick structure on the top side in the first chamber and the second wick structure on the bottom side in the second chamber.

12. The heat dissipating module according to claim 11, wherein the supporting cylinder is made of metal and is provided with a cylindrical wick structure on an outer surface thereof.

13. The heat dissipating module according to claim 11, wherein the supporting cylinder is made of metal sintered powder.

14. The heat dissipating module according to claim 1, wherein the first flat shell body and the second flat shell bodies are vapor chambers or planar uniform-temperature heat pipes.

Description

BRIEF DESCRIPTION OF DRAWING

[0028] The purpose of the following drawings is to make the present invention understood easily. The descriptions of the drawings will be detailed in the specification and incorporated to be part of the embodiments. Through the embodiments in the specification and reference to the corresponding figures, the embodiments of the present invention will be explained in detail and the operating theory will be described.

[0029] FIG. 1A is a perspective exploded view of the present invention;

[0030] FIG. 1B is a perspective exploded view of the present invention from another view;

[0031] FIG. 2 is a perspective assembled view of the present invention;

[0032] FIG. 3A is a partial top view of the present invention;

[0033] FIG. 3B is a partial cross-sectional view of the present invention;

[0034] FIG. 4A is a partial top view of the heat pipe according to an alternative embodiment of the heat pipe of the present invention;

[0035] FIG. 4B is a partial cross-sectional view of the heat pipe according to an alternative embodiment of the heat pipe of the present invention;

[0036] FIG. 5A is a partial top view of the heat pipe according to another alternative embodiment of the heat pipe of the present invention;

[0037] FIG. 5B is a partial cross-sectional view of the heat pipe according to another alternative embodiment of the heat pipe of the present invention;

[0038] FIG. 6A is a cross-sectional view of the heat dissipating module according to the first embodiment of the present invention; and

[0039] FIG. 6B is a cross-sectional view of the heat dissipating module according to another condition of the first embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

[0040] The above objectives, structural and functional characteristics of the present invention will be described according to the preferred embodiments in the accompanying drawings.

[0041] The present invention provides a heat dissipating module which comprises a first flat shell body and a plurality of second flat shell bodies. The first flat shell body has first chamber having a first wick structure formed on an inner wall of the first chamber. Each of the second flat shell bodies defines a second chamber. The second chamber has a working fluid and a second wick structure therein. Each of the second flat shell bodies is connected to and below the first flat shell body through a heat pipe. Each second chamber communicates with the first chamber through the corresponding heat pipe. The working fluid in each of the second chambers flows into the first chamber through the corresponding heat pipe to dissipate heat and then flows back to the second chamber through the corresponding heat pipe.

[0042] The embodiments of the present invention will be detailed below in reference to the accompanying drawings, the reference signs, and the explanation thereof.

[0043] FIG. 1A is a perspective exploded view of the present invention.

[0044] FIG. 1B is a perspective exploded view of the present invention from another view. FIG. 2 is a perspective assembled view of the present invention. FIG. 3A is a partial top view of the present invention. FIG. 3B is a partial cross-sectional view of the present invention. As shown in the above figures, a heat dissipating module comprises a first flat shell body 11 and a plurality of second flat shell bodies 12. The first flat shell body 11 is disposed above the second flat shell bodies 12. In the current embodiment, there are two second flat shell bodies 12 disposed to a left-and-right arrangement below the first flat shell body 11. The first flat shell body 11 and the second flat shell bodies 12 are preferably made of metal with high heat conductivity such as gold, silver, copper, or the alloy thereof. The first flat shell body 11 and the second flat shell bodies 12 are physically embodied as vapor chambers or planar uniform-temperature heat pipes.

[0045] The interior of the first flat shell body 11 defines a first chamber 111. The first flat shell body 11 has a first outer bottom surface 112, a first outer top surface 113, and a plurality of first holes 114 penetrating through the bottom surface 112 and communicating with the first chamber 111. A first wick structure 115 is disposed on an inner wall of the first chamber 111. The first chamber 111 has a top side 1111 spaced with the first holes 114 correspondingly. The first outer top surface 113 is used for heat dissipation and defines a heat dissipating area. The heat dissipating area is the surface area of the first outer top surface 113. For example, the first outer top surface 113 shown in FIG. 1A is a rectangle and its surface area equals the product of the length and the width of the first outer top surface 113. In another embodiment, if the first outer top surface 113 is a circle, its surface area equals the product of 3.14 and the radius squared.

[0046] The interior of each of the second flat shell bodies 12 defines a second chamber 121. The second flat shell body 12 has a second outer bottom surface 122 facing the first outer bottom surface 112 of the first flat shell body 11 and a second outer top surface 123 provided with at least one second hole 124 communicating with the second chamber 121. The second chamber 121 is provided with a working fluid 125 and a second wick structure 126 therein. The second wick structure 126 is disposed on the inner wall of the second chamber 121. The second chamber 121 has a bottom side 1211 spaced with the second hole 124 correspondingly. Each of the second flat shell bodies 12 is connected to the first flat shell body 11 through a heat pipe 13 such that the second chambers 121 individually communicate with the first chamber 111 of the first flat shell body 11 through the corresponding heat pipes 13. The second outer bottom surface 122 in FIGS. 1A and 1B is a surface protruding downward and used for heat absorption and defines a heat absorbing area. The heat absorbing area is the surface area of the second outer bottom surface 122. For example, the second outer bottom surface 122 shown in FIG. 1B is a rectangle and its surface area equals the product of the length and the width of the second outer bottom surface 122. In another embodiment, if the shape of the second outer bottom surface 122 is a circle, then its surface area equals the product of 3.14 and the radius squared.

[0047] In a preferred embodiment, the heat dissipating area of the first flat shell body 11 is larger than the heat absorbing area of each of the second flat shell bodies 12. In another preferred embodiment, the heat dissipating area of the first flat shell body 11 is larger than the sum of the absorbing areas of the second flat shell bodies 12.

[0048] The heat pipe 13 has a pipe wall 131, a first extension portion 132, and a second extension portion 133 opposite to the first extension portion 132. The first extension portion 132 forms a first open end 1321 and the second extension portion 133 forms a second open end 1331. The heat pipe channel 134 and the heat pipe wick structure 135 are both disposed in the pipe wall 131 and between the first open end 1321 and the second open end 1331. The first extension portion 132 of the heat pipe 13 extends from the first open end 114 into the first chamber 111 such that the first open end 1321 is pressed against the first wick structure 115 on the top side 1111 in the first chamber 111. Further, the heat pipe wick structure 135 at the first open end 1321 is connected to the first wick structure 115 on the top side 1111 by a capillary connection. Also, the first open end 1321 is closed by the top side 1111 in the first chamber 111.

[0049] Besides, the second extension portion 132 of the heat pipe 13 extends from the second open end 124 into the second chamber 121 such that the second open end 1331 is pressed against the second wick structure 126 on the bottom side 1211 in the second chamber 121. Further, the heat pipe wick structure 135 at the second open end 1331 is connected to the second wick structure 126 on the bottom side 1211 in a capillary connection. Also, the second open end 1331 is closed by the bottom side 1211 in the second chamber 121.

[0050] The first extension portion 132 and the second extension portion 133 of the heat pipe 13 are provided with a first throughhole 1322 and a second throughhole 1332, respectively, both penetrating through the pipe wall 131. The heat pipe channel 134 communicates with the first chamber 111 and the second chamber 121 through the first throughhole 1322 and the second throughhole 1332, respectively.

[0051] In one embodiment, as shown in FIGS. 3A and 3B, the pipe wall 131 of the heat pipe 13 has an inner surface 136 facing the heat pipe channel 134. The inner surface 136 is an internal smooth and circular surface. The heat pipe wick structure 135 is disposed on the inner surface 136. However, in an alternative embodiment as shown in FIGS. 4A and 4B, the inner surface 136 is provided with a plurality of ribs 137 disposed spacedly and a groove 138 is disposed between each two adjacent ribs 137. The ribs 137 and the grooves 138 are interlaced with one another and extend along a longitudinal direction of the heat pipe 13. The heat pipe wick structure 135 is formed on the ribs 137 and the grooves 138. Thus, the area of the heat pipe wick structure 135 increases.

[0052] The first and second wick structures 115, 126 and the heat pipe wick structure 135 are made of a porous structure such as the metal sintered powder, woven mesh, groove, or fiber bundle, which can provide capillary force to drive the working fluid 125 to flow.

[0053] The term of “capillary connection” in the specification means that the first and second wick structures 115, 126 are physically touched by, pressed against, or connected to the heat pipe wick structure 135 such that the pores of the first and second wick structures 115, 126 communicate with those of the heat pipe wick structure 135. In this way, the capillary force can pass or deliver from the heat pipe wick structure 135 to the first and second wick structures 115, 126; the cooled working fluid 125 can flow back from the first chamber 111 to the second chamber 121 by the capillary force.

[0054] In operation, the second outer bottom surface 122 of each of the second flat shell bodies 12 touches a heat source such as a CPU, a MPU, a GPU, or other electronic components. The heat generated by each heat source is transferred to the corresponding second chamber 121 through the second outer bottom surface 122. The working fluid 125 in the second chamber 121 is heated and vaporized to transform into a vapor state and then flows through the second throughhole 1332 into the heat pipe channel 134 and then through the first throughhole 1322 into the first chamber 111. Then, the working fluid 125 dissipates the heat by means of the first outer top surface 113. After the working fluid 125 dissipates the heat, it transforms into a liquid state. Then, the working fluid 125 splits and flows to each heat pipe channel 134 by means of the capillary connection between the first wick structure 115 in the first chamber 111 and the heat pipe wick structure 135 at the first open end 1321 of the heat pipe 13. After that, the working fluid 125 flows back to the second open end 1331 of the heat pipe 13 by gravity and the capillary force of the heat pipe wick structure 135 and then flows back to the second chambers 121 by means of the capillary connection between the heat pipe wick structure 135 and the second wick structure 126. That is, the working fluid 125 in the plural second flat shell bodies 12 flows through the heat pipes 13 into the first flat shell body 11 to merge and dissipate the heat. After dissipating the heat, the working fluid 125 splits and flows back to the second flat shell bodies 12 from the first flat shell body 11 through the corresponding heat pipes 13.

[0055] In addition, FIGS. 5A and 5B show another alternative embodiment of the present invention. As shown in FIGS. 5A and 5B, a supporting cylinder 14 is disposed in the heat pipe channel 134 of the above-mentioned heat pipe 13 and extends along a longitudinal direction of the heat pipe 13. Two opposite ends of the supporting cylinder 14 are individually pressed against the top side 1111 in the first chamber 111 and the bottom side 1211 in the second chamber 121. The outer surface of the supporting cylinder 14 is provided with a cylindrical wick structure 141 made of metal sintered powder and/or grooves. The cylindrical wick structure 141 following the two opposite ends of the supporting cylinder 14 are individually pressed against the first wick structure 115 on the top side 1111 in the first chamber 111 and the second wick structure 126 on the bottom side 1211 in the second chamber 121. By means of such an arrangement, the heat pipes 13 and the supporting cylinders 14 are located between and support the first flat shell body 11 and the second flat shell bodies 12. Also, the cooled working fluid 125 in the first chamber 111 flows back to the respective second chambers 121 through the heat pipe wick structure 135 and the cylindrical wick structure 141.

[0056] The supporting cylinders 14 and the cylindrical wick structure 141 have preferably circular cross sections which are the same as that of the heat pipe 13 and the circular cross sections are concentric circles. The cross sectional diameter of the supporting cylinders 14 is preferably smaller than that of the heat pipe 13 and there is thus a channel space existing between the inner surface 136 of the pipe wall of the heat pipe 13 and the outer surface of the supporting cylinder 14 and the cylindrical wick structure 141 to allow the working fluid 125 to flow in the heat pipe channel 134. The above-mentioned supporting cylinder 14 is made of metal such as copper. However, in another alternative embodiment, the supporting cylinder 14 is made of metal sintered powder which itself is a wick structure and thus the above-mentioned cylindrical wick structure 141 can be omitted.

[0057] Please continue to refer to FIGS. 6A and 6B. The first outer top surface 113 of the first flat shell body 11 is selectively provided with a heat sink unit like a cooler or a fan; a heat sink 21 is disposed as shown in FIG. 6A in a preferred embodiment. However, in another embodiment, two heat sinks 21a, 21b are disposed on the first outer top surface 113 of the first flat shell body 11. These two heat sinks 21a, 21b are spaced to each other and individually correspond to two second flat shell bodies 12. Because each of the heat sinks 21, 21a, and 21b has plural fins to increase the contact area with air, the heat on the first outer top surface 113 can be dissipated quickly through the heat sinks 21, 21a, and 21b.

[0058] By means of the above arrangement, the working fluid 125 in each of the second flat shell bodies 12 flows into the first flat shell body 11 through the corresponding heat pipes 13 and dissipates the heat through the first outer top surface 113 of the first flat shell body 11 and then flows back to the second flat shell bodies 12 from the first flat shell body 11 through the heat pipes 13 by gravity and capillary force. Due to the dual effect of the gravity and capillary force, the reflow speed of the working fluid 125 increases. As a result, the liquid-vapor circulation is enhanced and the efficiency of the heat dissipation is thus enhanced. On the other hand, because the heat dissipating area of the first outer top surface 113 of the first flat shell body 11 is larger than the heat absorbing area of the second outer bottom surface 122 of each of the second flat shell bodies 12 or larger than the sum of the absorbing areas of the second flat shell bodies 12, after the working fluid 125 in the second flat shell bodies 12 merges and flows into the first flat shell body 11, the efficiency of the heat dissipation is further increased by means of the large heat dissipating area of the first shell body 11.

[0059] The above-mentioned embodiments are only the preferred ones of the present invention. All variations regarding the above method, shape, structure, and device according to the claimed scope of the present invention should be embraced by the scope of the appended claims of the present invention.