CN211234063U

CN211234063U - Temperature equalizing plate

Info

Publication number: CN211234063U
Application number: CN201921926908.XU
Authority: CN
Inventors: 洪银树; 尹佐国; 李明聪
Original assignee: Sunonwealth Electric Machine Industry Co Ltd
Current assignee: Sunonwealth Electric Machine Industry Co Ltd
Priority date: 2019-10-31
Filing date: 2019-11-08
Publication date: 2020-08-11
Anticipated expiration: 2029-11-08
Also published as: CN112747619B; TWI701992B; CN112747619A; CN115143827A; TW202119897A; CN115143828A

Abstract

The utility model provides a temperature-uniforming plate for solve the problem of the slim processing difficulty of current temperature-uniforming plate. This temperature-uniforming plate includes: a heat-releasing sheet; at least one of the heat-releasing sheet and the heat-absorbing sheet is provided with a groove, the groove is formed by etching process, the heat-releasing sheet and the heat-absorbing sheet are mutually involutory to form a cavity by the groove; a capillary structure located in the chamber; and a working fluid filled in the chamber.

Description

Temperature equalizing plate

Technical Field

The utility model relates to a heat abstractor, especially, a carry out radiating samming board to electronic component.

Background

In an electronic product, an existing temperature equalization plate is generally combined on the surface of a heat source, a working fluid is filled in the existing temperature equalization plate, the heat source can heat the working fluid and vaporize the working fluid, the gaseous working fluid is evaporated to one side far away from the heat source to release heat and then is condensed, and therefore the heat away from the heat source can be carried away to achieve the purpose of heat dissipation. The existing temperature equalizing plate is provided with an upper plate body and a lower plate body, the peripheries of the upper plate body and the lower plate body are bent through stamping or die casting so that the upper plate body and the lower plate body respectively form a groove, therefore, the upper plate body and the lower plate body can be butted to form a space which can be used for filling the working fluid, and the space can be internally provided with a capillary structure to help the working fluid to carry out evaporation and condensation circulation.

However, when the conventional temperature equalization plate is used for a tiny electronic component to be thinned, it is difficult to bend the peripheries of the upper plate body and the lower plate body, which increases the difficulty in production, and the thickness of the bent peripheries of the upper plate body and the lower plate body is also limited to adapt to the thinning, so that the grooves formed by the upper plate body and the lower plate body are too shallow, which causes the insufficient space of the conventional temperature equalization plate and affects the heat dissipation efficiency.

In view of the above, there is still a need for improvement of the conventional vapor chamber.

SUMMERY OF THE UTILITY MODEL

In order to solve the problems, the utility model aims to provide a temperature-uniforming plate which is easy to process and can improve the production efficiency.

The utility model discloses a next purpose provides a temperature-uniforming plate, can promote the radiating efficiency.

In the present invention, the directions or the similar terms thereof, such as "front", "back", "left", "right", "top", "bottom", "inner", "outer", "side", etc., refer to the directions of the drawings, and the directions or the similar terms thereof are only used to assist the explanation and understanding of the embodiments of the present invention, but not to limit the present invention.

The elements and components described throughout the present invention are referred to by the term "a" or "an" merely for convenience and to provide a general meaning of the scope of the invention; in the present invention, it is to be understood that one or at least one is included, and a single concept also includes a plurality unless it is obvious that other meanings are included.

The utility model discloses a temperature-uniforming plate, include: a heat-releasing sheet; one or both of the heat-releasing sheet and the heat-absorbing sheet are provided with a groove, the groove is formed by etching process, the heat-releasing sheet and the heat-absorbing sheet are mutually matched to form a cavity by the groove; a capillary structure located in the chamber; and a working fluid filled in the chamber.

Therefore, the utility model discloses a vapor chamber forms the groove of this heat release sheet and the groove of this heat absorbing sheet through the etching, and need not buckle to the periphery of this heat release sheet and this heat absorbing sheet, can process the vapor chamber of slimming simply to through the etching, can be less than mm with the degree of depth and form this groove as the unit, with the production demand that accords with the slimming vapor chamber, can reach the efficiency that promotes production efficiency. Meanwhile, the groove is formed by etching, so that the thickness of the heat release sheet and the heat absorption sheet can be reduced to improve the capacity of the cavity of the shell, the amount of the working fluid is increased on the premise of not increasing the thickness of the temperature equalization plate, or enough evaporation space of the working fluid is provided, and the effect of providing good heat dissipation efficiency is achieved.

Wherein, the heat-releasing sheet and the heat-absorbing sheet are respectively provided with the groove. Therefore, the effect of further providing good heat dissipation efficiency can be achieved.

The heat releasing sheet or the heat absorbing sheet is provided with at least one supporting column, and the supporting column is positioned between the heat releasing sheet and the heat absorbing sheet. Therefore, the strength of the shell can be improved, and the shell has the effect of being not easy to bend.

The heat-releasing sheet or the heat-absorbing sheet is provided with at least one positioning column, and the positioning column is oppositely positioned on the supporting column. Therefore, when the heat release sheet is in butt joint with the heat absorption sheet, the positioning column can be positioned with the supporting column, and the heat release sheet and the heat absorption sheet can be stably positioned.

The heat-releasing sheet is provided with a groove surface, the groove surface is arranged on the groove of the heat-absorbing sheet, the periphery of the groove surface forms an annular edge, the annular edge surrounds the groove surface, and the annular edge of the heat-releasing sheet or the annular edge of the heat-absorbing sheet is abutted against the groove surface of the heat-absorbing sheet or the groove surface of the heat-releasing sheet. Therefore, the overall thickness of the shell can be reduced, and the shell has the effect of meeting the requirement of thinning.

Wherein, the annular edge of the heat-releasing sheet is adjacent to the annular edge of the heat-absorbing sheet. Therefore, the volume of a cavity formed by the groove of the heat releasing sheet and the groove of the heat absorbing sheet in an involution mode can be increased, and the heat radiating device has the effect of providing good heat radiating efficiency.

The thickness of the annular edge of the heat-releasing sheet or the annular edge of the heat-absorbing sheet is greater than the depth of the groove of the heat-absorbing sheet or the groove of the heat-releasing sheet, and the annular edge of the heat-releasing sheet or the annular edge of the heat-absorbing sheet is abutted against the groove surface of the heat-absorbing sheet or the groove surface of the heat-releasing sheet to form a step difference. Therefore, laser welding can be conveniently carried out at an included angle of 30-75 degrees, and the heat-radiating plate and the heat-absorbing plate can be really welded and combined without generating gaps.

The heat-releasing sheet or the heat-absorbing sheet forms a ring shoulder part on the ring edge by an etching process, and the depth of the ring shoulder part formed relative to the ring edge is equal to the thickness of the ring edge of the heat-releasing sheet or the ring edge of the heat-absorbing sheet. Therefore, the heat-releasing sheet does not protrude out of the heat-absorbing sheet, and the overall thickness of the shell is further reduced.

Wherein, the ring edge of the heat-releasing sheet is butted with the ring edge of the heat-absorbing sheet. Therefore, a larger cavity is formed, and the heat dissipation efficiency is improved.

Wherein, the juncture of the heat releasing sheet and the heat absorbing sheet after being closed has no opening. Therefore, the temperature-equalizing plate can be more easily applied to a thinned temperature-equalizing plate in a small electronic product, and has the effect of improving the production convenience.

Wherein, weld the juncture of this heat release piece and this heat absorption piece through radium-shine, this radium-shine welded angle is 30~75 degrees. Therefore, the heat-radiating sheet and the heat-absorbing sheet can be firmly welded and combined without generating gaps.

Wherein, the thickness of the capillary structure is 0.05-0.5 mm. Thus, the thickness of the capillary structure can be reduced.

Wherein, the thickness of the capillary structure is 0.2-0.4 mm. Thus, the thickness of the capillary structure can be reduced.

Wherein, the capillary structure is provided with at least one perforation which is aligned with the supporting column. Therefore, the capillary structure can be accurately aligned, and the production convenience is improved.

The capillary structure is located between the supporting column and the corresponding heat releasing sheet or the corresponding heat absorbing sheet, and the supporting column abuts against the capillary structure. Therefore, the capillary structure can be adjacent to the heat release sheet or the heat absorption sheet so as to ensure that the working fluid can be gathered on the groove surface of the heat release sheet or the groove surface of the heat absorption sheet to fully absorb the heat of a heating source, and the heat dissipation efficiency is improved.

Wherein, the capillary structure is a thin slice sintered by powder. Therefore, the capillary structure can be placed in the groove, difficult operations such as sintering and the like on the heat release sheet or the heat absorption sheet can be avoided, and the capillary structure has the effect of being more easily applied to a thinned temperature equalization plate in a small electronic product so as to improve the production convenience.

The supporting columns are arranged in the grooves of the heat releasing sheet and the grooves of the heat absorbing sheet in a staggered mode, and the supporting columns are abutted to the capillary structure respectively. Therefore, the capillary structure forming the sheet can be in a wavy structure, and a plurality of gaps are formed among the capillary structure, the heat release sheet and the heat absorption sheet, so that the evaporation efficiency of the working fluid is improved, and the effect of further improving the overall heat dissipation efficiency of the temperature equalization plate is achieved.

The heat-releasing sheet or the heat-absorbing sheet is not provided with the groove and is provided with at least one combination hole, and the opposite heat-absorbing sheet or the heat-releasing sheet is provided with an abutting column which is aligned with the combination hole. Thus, the method has the effect of simplifying processing steps.

Wherein, the heat-releasing sheet or the heat-absorbing sheet is punched to form the combining hole. Thus, the method has the effect of simplifying processing steps.

Drawings

FIG. 1: the utility model is an exploded perspective view of a preferred embodiment of the vapor chamber;

FIG. 2: the utility model is a combined front view of a preferred embodiment of the temperature-uniforming plate;

FIG. 3: a cross-sectional view taken along line A-A of FIG. 2;

FIG. 4: the cross section of the heat release sheet and the heat absorption sheet of the temperature equalization plate of the utility model is in butt joint;

FIG. 5: the cross section of the other butt joint form of the heat release sheet and the heat absorption sheet of the temperature equalizing plate of the utility model;

FIG. 6: the utility model discloses a sectional view of a second embodiment of the vapor chamber;

FIG. 7: the utility model discloses a sectional view of a third embodiment of the vapor chamber;

FIG. 8: the cross-sectional view of the fourth embodiment of the vapor chamber of the present invention;

FIG. 9: an exploded perspective view of a fifth embodiment of the vapor chamber of the present invention;

FIG. 10: a sectional view of a fifth embodiment of the vapor chamber of the present invention;

FIG. 11 a: a top view of the heat absorbing sheet of the temperature equalizing plate of the utility model is formed by a base plate;

FIG. 11 b: the top view of the heat releasing sheet of the temperature equalizing plate of the present invention is formed by a substrate.

Description of the reference numerals

1 Heat-releasing sheet

11 groove

12 groove surface

13 ring edge

14 support column

15 combination hole

2 Heat absorbing sheet

21 groove

22 groove surface

23 ring edge

231 ring shoulder

24 positioning column

241 counter bore

25 abutting column

251 abutting against the shoulder

3 capillary structure

31 perforation

S chamber

P substrate

P1 penetration part

P2 cut-off part

Thickness D1

Depth of D2

D3 step difference

Depth of D4

The angle theta.

Detailed Description

In order to make the aforementioned and other objects, features and advantages of the invention more comprehensible, preferred embodiments accompanied with figures are described in detail as follows:

referring to fig. 1 and 2, a first embodiment of a temperature equalizing plate structure of the present invention includes a heat releasing sheet 1 and a heat absorbing sheet 2, wherein the heat releasing sheet 1 and the heat absorbing sheet 2 are connected to each other.

The temperature equalizing plate structure can be made of high thermal conductivity materials such as copper or aluminum, and can be directly or indirectly connected with a heating source to dissipate heat of the heating source, and the heating source can be a central processing unit of a mobile phone, a computer or other electrical products, or an electronic element such as a chip generating heat due to work on a circuit board. The temperature equalization plate structure can be filled with a working fluid, the working fluid can be water, alcohol or other liquid with low boiling point, preferably the working fluid can be non-conductive liquid, so that the working fluid can absorb heat from liquid state and evaporate into gaseous state, the temperature equalization plate structure can be in a vacuum closed state, the working fluid is prevented from losing after being in gaseous state, the interior of the temperature equalization plate structure is prevented from being occupied by air, the working fluid is compressed to the space after being in gaseous state, and the heat dissipation efficiency is further influenced.

As shown in fig. 1, the heat-dissipating fin 1 may have at least one groove 11, and the groove 11 may be used to accommodate the working fluid, so that the heat carried by the working fluid can be transferred out from the heat-dissipating fin 1, for example, to the outside for dissipation, or the heat-dissipating fin 1 may be connected to a fin, a metal tube, a fan, or other components with heat-conducting effect, so as to carry the heat away from the heat-dissipating fin 1 for heat dissipation.

It should be noted that the groove 11 is formed by etching process, for example, by dry etching, wet etching or plasma etching, the present invention is not limited thereto, so that the groove 11 can be simply formed on the heat sink 1, and the depth of the groove 11 can be precisely controlled by using less than mm as a unit through the etching process, for example, in a small electronic product, the thickness of the thinned isothermal plate is less than or equal to 1mm, the groove 11 can be formed in the thinned isothermal plate through etching process, which has the effect of reducing the processing difficulty.

Referring to fig. 1, the groove 11 is etched to form a groove surface 12, and a circumferential edge 13 is formed around the groove surface 12, the circumferential edge 13 surrounding the groove surface 12. In this embodiment, the groove surface 12 may have at least one supporting pillar 14, the supporting pillar 14 may abut between the heat-releasing sheet 1 and the heat-absorbing sheet 2, and the supporting pillar 14 may be assembled with the heat-releasing sheet 1 after being manufactured respectively, for example, may be welded to the groove surface 12, or the supporting pillar 14 may be integrally formed on the groove surface 12, for example, the supporting pillar 14 may be formed in the groove 11 by etching.

The heat absorbing sheet 2 can be mutually butted with the heat releasing sheet 1, so that the heat absorbing sheet 2 and the heat releasing sheet 1 can jointly form a cavity S, the cavity S can be used for containing the working fluid to achieve the purpose of heat dissipation through the evaporation and condensation circulation of the working fluid, and the heat absorbing sheet 2 can be used for being connected with the heat generating source to absorb the heat generated by the heat generating source. In this embodiment, the heat absorbing sheet 2 may also have at least one groove 21, and the groove 21 is also formed by an etching process, such as dry etching, wet etching or plasma etching, for example, the present invention is not limited thereto, so that the groove 21 can be formed in the thinned isothermal plate by etching, which has the effect of reducing the processing difficulty. The groove 21 is etched to form a groove surface 22, and the periphery of the groove surface 22 forms an annular edge 23, the annular edge 23 surrounds the groove surface 22, the groove 21 of the heat absorbing plate 2 can be aligned with the groove 11 of the heat releasing plate 1, so that the groove 21 of the heat absorbing plate 2 and the groove 11 of the heat releasing plate 1 can form the chamber S together. Preferably, a plurality of

grooves

11, 21 having the

rims

13, 23 can be formed on a substrate (panel) P by an etching process, and a plurality of penetrating portions P1 can be formed around the

rims

13, 23, a cut-off portion P2 is formed between the penetrating portions P1, and the penetrating portions P1 can be stamp-holes or slot holes (as shown in fig. 11a, 11 b), so that a plurality of heat-releasing sheets 1 or a plurality of heat-absorbing sheets 2 having the

grooves

11, 21 can be obtained by cutting off the cut-off portion P2, which can be mass-produced and has the effect of improving the production convenience.

The groove surface 22 of the heat absorbing plate 2 may further have at least one positioning post 24, the positioning post 24 is opposite to the supporting post 14 of the heat releasing plate 1, and preferably, the supporting post 14 can be welded and combined with the positioning post 24 by spot welding, in this embodiment, the positioning post 24 may have a counter bore 241, the counter bore 241 may be opposite to the pillar body of the supporting post 14, thereby, when the heat releasing plate 1 is opposite to the heat absorbing plate 2, the supporting post 14 and the positioning post 24 can be positioned mutually, and have an effect of stably positioning the heat releasing plate 1 and the heat absorbing plate 2, in addition, the positioning post 24 may also not have the counter bore 241, so that the end surface of the positioning post 24 abuts against the end surface of the supporting post 14. The positioning post 24 can be assembled or welded to the groove surface 22 after being manufactured separately from the heat absorbing sheet 2, which is not limited by the present invention. It should be noted that the supporting pillars 14 may be located on the heat releasing sheet 1 or the heat absorbing sheet 2, and the supporting pillars 14 may be multiple and may be located on the heat releasing sheet 1 and the heat absorbing sheet 2 in a staggered manner, so that the end surfaces of the supporting pillars 14 can directly abut against the opposite heat releasing sheet 1 or the heat absorbing sheet 2 from the heat releasing sheet 1 or the heat absorbing sheet 2 (as shown in fig. 8), and the supporting pillars 14 can be welded and combined with the heat releasing sheet 1 or the heat absorbing sheet 2 by spot welding, and similarly, the heat absorbing sheet 2 and the heat releasing sheet 1 may also have positioning pillars 24 located on the supporting pillars 14, which is known by those skilled in the art and will not be described herein.

Referring to fig. 3, the annular edge 13 of the heat-releasing plate 1 may abut against the groove surface 22 of the heat-absorbing plate 2, or the annular edge 23 of the heat-absorbing plate 2 may abut against the groove surface 12 of the heat-releasing plate 1, but the present invention is not limited thereto, and in this embodiment, the annular edge 13 of the heat-releasing plate 1 abuts against the groove surface 22 of the heat-absorbing plate 2 as an example, so that the overall thickness of the uniform temperature plate structure (i.e., the thickness between the heat-releasing plate 1 and the heat-absorbing plate 2) can be reduced to meet the requirement of thinning. At this time, the junction of the heat releasing sheet 1 and the heat absorbing sheet 2 can be welded by laser, preferably, the angle θ (included angle with the horizontal plane) of laser welding is preferably 30 to 75 degrees, so that the heat releasing sheet 1 and the heat absorbing sheet 2 can be welded and combined without generating a gap.

With reference to fig. 3 to 5, preferably, the annular edge 13 of the heat releasing plate 1 is adjacent to the annular edge 23 of the heat absorbing plate 2, so as to increase the volume of the chamber S formed by the joining of the grooves 11 of the heat releasing plate 1 and the grooves 21 of the heat absorbing plate 2, wherein the thickness D1 of the annular edge 13 of the heat releasing plate 1 may be greater than the depth D2 of the grooves 21 of the heat absorbing plate 2, so that when the annular edge 13 of the heat releasing plate 1 abuts against the groove surface 22 of the heat absorbing plate 2, a step D3 may be formed to facilitate laser welding at an angle θ of 30 to 75, or the heat absorbing plate 2 may be etched to form an annular shoulder 231 on the annular edge 23, and the depth D4 of the annular shoulder 231 relative to the annular edge 23 of the heat absorbing plate 2 may be equal to the thickness D1 of the annular edge 13 of the heat releasing plate 1 (as shown in fig. 4), so that the heat releasing plate 1 does not protrude from the heat absorbing plate 2, the temperature equalizing plate structure has the function of further reducing the overall thickness of the temperature equalizing plate structure. Alternatively, the annular edge 13 of the heat-releasing fin 1 and the annular edge 23 of the heat-absorbing fin 2 may be abutted (as shown in fig. 5), so as to form a larger chamber S, which has the effect of enhancing the heat-dissipating efficiency.

Please continue to refer to fig. 1 and 3, the temperature equalization plate structure of the present invention may further include a capillary structure 3, the capillary structure 3 is located in the chamber S, so as to help the condensed working fluid to be recollected for backflow, so as to absorb heat of the heat source again, the capillary structure 3 may be a porous mesh structure, a micro groove or a sintered powder, etc., so as to increase the flow of the working fluid due to the capillary phenomenon, the capillary structure 3 may be made by a powder sintering (power sintering process), the powder may be copper powder or other suitable powder, which is not limited by the present invention. In detail, the thickness of the capillary structure 3 may be 0.05 to 0.5 mm, preferably 0.2 to 0.4 mm, and the capillary structure 3 may be directly sintered on the groove surface 12 of the heat-releasing sheet 1 or the groove surface 22 of the heat-absorbing sheet 2, so that the capillary structure 3 may be located in the chamber S after the heat-releasing sheet 1 and the heat-absorbing sheet 2 are combined. In this embodiment, a thin sheet may be sintered from powder in advance to serve as the capillary structure 3, and then the capillary structure 3 forming the thin sheet is placed on the groove surface 12 of the heat releasing sheet 1 or the groove surface 22 of the heat absorbing sheet 2, preferably, powder metallurgy sintering may be performed first, and the sintered powder may also be processed to form the required thickness or size by pressurizing and leveling, and the thin sheet-like capillary structure 3 with a proper shape may be formed, at this time, a groove may be formed on the capillary structure 3 at the same time to enhance the flow conductivity of the capillary structure 3, thereby, the capillary structure 3 forming the thin sheet may be placed in the chamber S in a vacuum environment, and the working fluid may be injected into the chamber S, and then the heat releasing sheet 1 and the heat absorbing sheet 2 are welded together to form the temperature equalizing plate structure, thereby, difficult operations such as sintering on the heat releasing sheet 1 or the heat absorbing sheet 2 may be avoided, an opening for injecting the working fluid and vacuumizing the cavity S is not required to be reserved, and the device can be more easily applied to a thinned temperature-uniforming plate in a small electronic product to improve the production convenience. The capillary structure 3 may have at least one through hole 31, and the positions and the number of the through holes 31 may correspond to the supporting columns 14 and the positioning pillars 24, so that the supporting columns 14 and the positioning pillars 24 can penetrate through.

Referring to fig. 6 and 7, the capillary structure 3 may be located between the supporting pillar 14 and the opposite heat-releasing sheet 1 or the heat-absorbing sheet 2, preferably, the supporting pillar 14 may abut against the capillary structure 3, for example, the supporting pillar 14 of the heat-releasing sheet 1 may abut against the capillary structure 3 (as shown in fig. 6), and the supporting pillar 14 may be welded to the capillary structure 3 by spot welding, so that the capillary structure 3 may be abutted against the heat-absorbing sheet 2 to ensure that the working fluid may be collected on the groove surface 22 of the heat-absorbing sheet 2 to fully absorb heat of the heat-generating source, thereby improving heat dissipation efficiency. Alternatively, the plurality of supporting pillars 14 alternately located on the heat releasing sheet 1 and the heat absorbing sheet 2 may respectively abut against the capillary structure 3 forming the sheet, so that the capillary structure 3 forming the sheet is in a wavy structure (as shown in fig. 7), thereby forming a plurality of gaps between the capillary structure 3 and the heat releasing sheet 1 and the heat absorbing sheet 2, so as to improve the evaporation efficiency of the working fluid, and further improve the overall heat dissipation efficiency of the temperature equalization plate.

Referring to fig. 9 and 10, the heat-dissipating sheet 1 may not have the groove 11, and the heat-dissipating sheet 1 may abut against the annular shoulder 231 of the heat-absorbing sheet 2, so that only the heat-absorbing sheet 2 may be etched, thereby simplifying the processing steps. In detail, the heat-releasing plate 1 may have at least one combining hole 15, the combining hole 15 may be formed as an elongated hole by, for example, stamping, which has the effect of simplifying the process, the heat-absorbing plate 2 may be formed with at least one abutting pillar 25 by etching process, the abutting pillar 25 is aligned with the combining hole 15, preferably, the abutting pillar 25 may have an abutting shoulder 251, so that when the combining hole 15 is combined with the abutting pillar 25, the combining periphery may abut against the abutting shoulder 251, thereby, the heat-releasing plate 1 may be supported by the annular shoulder 231 and the abutting shoulder 251 of the heat-absorbing plate 2 together. The boundary between the heat-releasing sheet 1 and the heat-absorbing sheet 2 and the boundary between the connecting hole 15 and the abutting column 25 can be welded by laser, so that the heat-releasing sheet 1 and the heat-absorbing sheet 2 form a seal. The capillary structure 3 may also be disposed between the heat-releasing sheet 1 and the heat-absorbing sheet 2, and the through hole 31 of the capillary structure 3 may be aligned with the abutting column 25, so that the abutting column 25 can pass through the through hole. Additionally, the present invention is not limited to the position of the connection hole 15 and the abutting column 25, that is, the abutting column 25 may be formed on the heat dissipating sheet 1 by etching process, and the heat absorbing sheet 2 does not have the groove 21 and the connection hole 15 is disposed to abut against the abutting column 25 on the heat dissipating sheet 1.

To sum up, the utility model discloses a samming plate structure forms the groove of this heat release piece and the groove of this heat absorbing sheet through the etching, and need not buckle to the periphery of this heat release piece and this heat absorbing sheet, can process the samming board of slimming simply to through the etching, can be less than mm with the degree of depth and form this groove as the unit, in order to accord with the production demand of slim samming board, can reach the efficiency that promotes production efficiency. Meanwhile, the groove is formed by etching, so that the thickness of the heat release sheet and the heat absorption sheet can be reduced to improve the capacity of the cavity of the shell, the amount of the working fluid is increased on the premise of not increasing the thickness of the temperature equalization plate, or enough evaporation space of the working fluid is provided, and the effect of providing good heat dissipation efficiency can be achieved.

Although the present invention has been described with reference to the above preferred embodiments, it is not intended to limit the present invention, and various changes and modifications can be made by those skilled in the art without departing from the spirit and scope of the present invention.

Claims

1. A vapor chamber, comprising:

a heat-releasing sheet;

at least one of the heat-releasing sheet and the heat-absorbing sheet is provided with a groove formed by an etching process, the heat-releasing sheet and the heat-absorbing sheet are mutually matched, and a cavity is formed by the groove;

a capillary structure located in the chamber; and

a working fluid filled in the chamber.

2. The vapor chamber of claim 1, wherein: the heat-releasing sheet and the heat-absorbing sheet are respectively provided with the groove.

3. The vapor chamber of claim 2, wherein: the heat releasing sheet or the heat absorbing sheet is provided with at least one supporting column, and the supporting column is positioned between the heat releasing sheet and the heat absorbing sheet.

4. The vapor chamber of claim 3, wherein the heat sink or the heat spreader has at least one positioning post, the positioning post being aligned with the support post.

5. The temperature equalizing plate of claim 2, wherein the grooves of the heat dissipating fins and the grooves of the heat absorbing fins each have a groove surface, the groove surface has a circumferential edge, the circumferential edge surrounds the groove surface, and the circumferential edge of the heat dissipating fins abuts against the groove surface of the heat absorbing fin or the circumferential edge of the heat absorbing fin abuts against the groove surface of the heat absorbing fin.

6. The vapor panel of claim 5, wherein the perimeter of the heat sink sheet abuts the perimeter of the heat sink sheet.

7. The vapor chamber of claim 6, wherein the thickness of the rim of the heat-releasing sheet or the rim of the heat-absorbing sheet is greater than the depth of the groove of the heat-absorbing sheet or the groove of the heat-releasing sheet, and the rim of the heat-releasing sheet or the rim of the heat-absorbing sheet abuts against the groove surface of the heat-absorbing sheet or the groove surface of the heat-releasing sheet to form a step difference.

8. The vapor chamber of claim 5, wherein the heat spreader plate or the heat sink plate is etched to form a collar shoulder at the rim, the collar shoulder being formed at a depth relative to the rim equal to the thickness of the opposing rim of the heat sink plate or the heat spreader plate.

9. The vapor panel of claim 5, wherein the perimeter of the heat sink is abutted with the perimeter of the heat spreader.

10. The vapor chamber of claim 2, wherein the interface between the heat releasing sheet and the heat absorbing sheet has no opening.

11. The temperature-uniforming plate of claim 2, wherein the juncture of the heat-releasing sheet and the heat-absorbing sheet is connected by laser welding, and the angle of the laser welding is 30-75 °.

12. The vapor-deposition plate of claim 2, wherein the thickness of the capillary structure is 0.05-0.5 mm.

13. The vapor-deposition plate of claim 12, wherein the thickness of the capillary structure is 0.2-0.4 mm.

14. The vapor-deposition plate of claim 3, wherein the capillary structure has at least one perforation.

15. The vapor chamber of claim 3, wherein the capillary structure is located between the supporting pillar and the opposite heat-releasing sheet or the opposite heat-absorbing sheet, and the supporting pillar abuts against the capillary structure.

16. A temperature-uniforming plate according to claim 3, wherein the capillary structure is a sheet sintered from powder.

17. The vapor chamber of claim 16, wherein the supporting pillars are disposed in a plurality, and the supporting pillars are alternately disposed in the grooves of the heat releasing sheet and the grooves of the heat absorbing sheet, and the supporting pillars abut against the capillary structure.

18. The vapor panel of claim 1, wherein the heat-releasing sheet or the heat-absorbing sheet does not have the groove and has at least one coupling hole, and the opposite heat-absorbing sheet or the heat-releasing sheet has an abutment post aligned with the coupling hole.

19. The vapor panel of claim 18, wherein the heat-releasing sheet or the heat-absorbing sheet is punched to form the bonding holes.