GB2445575A

GB2445575A - Radiating structure

Info

Publication number: GB2445575A
Application number: GB0700598A
Authority: GB
Inventors: Kuan-Yin Chou
Original assignee: Individual
Current assignee: Individual
Priority date: 2007-01-12
Filing date: 2007-01-12
Publication date: 2008-07-16
Also published as: GB0700598D0

Abstract

A radiating structure comprises a plurality of pipes 30, a plurality of fins 40 each having a plurality of slots 41 in one side so that each fin 40 can be slid over the pipes 30, a guiding edge 42 comprising a raised skirt perpendicular to each fin 40 that extends around the periphery of each slot 41 and abuts each pipe 30, and at least one hollow positioning assembly 50 functioning as a manifold fixed and in fluid communication to the pipes 30. One end 43 of the guiding edge 42 may be arc (fig 5) or cone (fig 6) shaped. The positioning assembly 50 may comprise of end pieces 51 with a series of holes for the pipes 30 and fixed at each end of the pipes 30, and hollow posts 52 mounted on the end pieces 51. Hollow posts 52 may have a positioning piece 53 for fixing the posts 52 to a housing 60. When the radiating structure employs a cooling fan to dissipate heat, the fins 40 can use the guiding edge 42 to guide air flow and carry away dust, thus ensuring that the air passage of the fins 40 and the pipes 30 is not blocked.

Description

RADIATING STRUCTURE

BACKGROUND OF THE INVENTION

Field of the Invention

The present invention relates to a radiating structure, and more particularly to an improved radiating structure.

Description of the Prior Art

Fig. I is an exploded view of a conventional radiating structure, the radiating structure 10 comprises at least two thermal pipes 11, at least one radiating fin 12 and two positioning elements 13. The thermal pipes 11 and the radiating fin 12 are arranged orderly, and the radiating fin 12 is wave-shaped. Both ends of the thermal pipe 11 and the radiating fin 12 are fixed on the positioning elements 13 respectively, and the thermal pipe 11 is in communication with the positioning elements 13, so that water flows therein for carrying out heat exchange. However, the conventional radiating structure has the following disadvantages: The radiating fin 12 is wave-shaped, so the time of manufacturing such a radiating fin 12 is increased. When the radiating structure 10 employs a cooling fan (not shown) to improve the heat dissipation, the dust is likely to accumulate in the wind-receiving surface of the radiating fin 12, such that the heat exchange between the thermal pipe 11 and the radiating fin 12 will be hindered, thus reducing the radiating efficiency of the radiating structure 10.

Fig. 2 is another exploded view of a conventional radiating structure, the radiating structure 20 comprises a plurality of thermal pipes 21, a plurality of radiating fins 22 and two positioning elements 23. One end of each thermal pipe 21 is fixed on one of the positioning elements 23, each radiating fin 22 is defined with a plurality of through holes 221 for insertion of the thermal pipes 21, and the quantity of the through holes 221 of the radiating fin 22 is the same as that of the thermal pipes 21. And the other end of the thermal pipe 21 and the radiating fin 22 are fixed on the other positioning element 23 respectively in such a manner that the thermal pipe 21 is in communication with the positioning elements 23, so that water flows therein for carrying out heat exchange. However, the conventional radiating structure still has the following disadvantages: The quantity of the through holes 221 of the radiating fin 22 must be the same as that of the thermal pipes 21, so the manufacturing time is prolonged. And the radiating fins 22 are assembled on the thermal pipes 21 one by one via the through holes 221, and are hard to assemble. Further, when the radiating structure 20 employs a cooling fan (not shown) to improve the heat dissipation, the dust is likely to accumulate in the wind-receiving surface of the radiating fin 22 to block the air passage, thus hindering the heat exchange between the thermal pipe 21 and the radiating fin 22 and reducing the radiating efficiency of the radiating structure 20.

The present invention has arisen to mitigate and/or obviate the afore-described disadvantages.

SUMMARY OF THE INVENTION

The primary objective of the present invention is to provide a radiating structure, wherein a radiating fin is inserted into a thermal pipe via plural inserting holes, and the radiating fin can use a guiding edge to guide the wind and carry away the dust, such that the heat exchange between the thermal pipe and the radiating fin will not be hindered.

The radiating structure of the present invention comprises a plurality of thermal pipes, a plurality of radiating fins and two positioning assemblies. A plurality of inserting holes is equidistantly formed in one side of the radiating fin, such that the radiating fin can be inserted into the thermal pipe quickly via the inserting holes, so the present invention is easy to assemble. One side of each inserting hole is formed with a guiding edge, the guiding edge is formed with a wind conduction section and two abutting sections, and the wind conduction section of the guiding edge cooperates with the abutting sections to guide the wind and carry away the dust, so as to improve the heat exchange between the radiating fin and the thermal pipe.

The present invention will become more obvious from the following description when taken in connection with the accompanying drawings, which show, for purpose of illustrations only, the preferred embodiments in accordance with the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 is an exploded view of a conventional radiating structure; Fig. 2 is another exploded view of the conventional radiating structure; Fig. 3 is a perspective view of a radiating structure in accordance with the present invention; Fig. 4 is an exploded view of the radiating structure in accordance with the present invention; Fig. 5 is a cross sectional view of a thermal pipe and a radiating fin in accordance with the radiating structure of the present invention; and Fig. 6 is another cross sectional view of the thermal pipe and the radiating fin in accordance with the radiating structure of the present invention.

DETAJLED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Fig. 3 is a perspective view of a radiating structure in accordance with a first embodiment of the present invention (further referring to Figs. 4 and 5), the radiating structure comprises a plurality of thermal pipes 30, a plurality of radiating fins 40, at least one positioning assembly 50 and a housing 60.

The respective thermal pipes 30 are sheet-shaped and have two planes 31 at both sides thereof, one ends of the planes 31 are connected by an arc-shaped surface 32, and the thermal pipes 30 are equidistantly arranged.

The respective radiating fins 40 are formed with plural inserting holes 41 and guiding edges 42. The inserting holes 41 are equidistantly formed in one side of the radiating fin 40, and the shape of each inserting hole 41 is the same as that of the cross section of the thermal pipe 30. The guiding edges 42 are vertically formed on the radiating fin 40 and located around the peripheries of the inserting holes 41, one end of the guiding edge 42 is formed with an arc-shaped wind conduction section 43, and the other end of the guiding edge 42 is formed with two abutting sections 44 extending from the wind conduction section 43. The quantity of the inserting holes 41 of the radiating fin 40 is the same as that of the thermal pipes 30.

The positioning assembly 50 has two hollow pieces 51 and two hollow posts 52. The pieces 51 of the positioning assembly 50 are fixed on both ends of the thermal pipe 30 respectively, the posts 52 are mounted on the outer sides of the pieces 51 respectively, and one side of each post 52 is formed with two positioning pieces 53.

The guiding pipe 30 is in communication with the pieces 51 and the posts 52 of the positioning assembly 50, so that water flows therein for carrying out heat exchange.

The housing 60 is fixed on the positioning pieces 53 of the posts 52.

Fig. 6 is a cross sectional view of the radiating structure in accordance with a second embodiment of the present invention, the wind conduction section 43 of each guiding edge 42 of the radiating fin 40 can be cone-shaped, so that the radiating fin 40 cooperates with the abutting sections 44 to guide the wind.

For a better understanding of the present invention, its operations and functions, references should be further made to Figs. 4 and 5: Both ends of the thermal pipe 30 are fixed on one side of the pieces 51, and the other side of each piece 51 is mounted on one side of each post 52 respectively. The radiating fin 40 is inserted into the arc- shaped surface 32 of the thermal pipe 30 via the wind conduction section 43 of the inserting hole 41, such that the abutting sections 44 of the radiating fin 40 are abutted against the planes 31 of the thermal pipe 30, thereby, the radiating fin 40 can be assembled and disassembled quickly. The abutting sections 44 enable to the radiating fin 40 to be abutted against the thermal pipe 30 firmly, and the contact area of the radiating fin 40 and the thermal pipe 30 is increased, so as to improve the efficiency of heat exchange. When the radiating structure employs a cooling fan to dissipate heat, the arc-shaped surface of the wind conduction section 43 of the guiding edge 42 cooperates with the abutting sections 44 to guide the wind and carry away the dust, thus ensuring that the air passage of the radiating fin 40 and the thermal pipe 30 is unblocked. As can be clearly seen from the above-mentioned structure, the radiating fin 40 can be assembled and disassembled quickly by the inserting hole 41, and the radiating fin 40 can use the guiding edge 42 of the inserting hole 4lto guide the wind, thus ensuring that the air passage of the radiating fin 40 and the thermal pipe 30 is unblocked.

To summarize, the radiating structure of the present invention mainly comprises a plurality of thermal pipes, a plurality of radiating fins and at least one positioning assembly. The radiating fin has an inserting hole and a guiding edge, and the radiating fin can be assembled and disassembled quickly by the inserting holes. In addition, when the radiating structure employs a cooling fan to dissipate heat, and the radiating fin can use the guiding edge to guide the wind and cany away the dust, thus ensuring that the air passage of the radiating fin and the thermal pipe is unblocked While we have shown and described various embodiments in accordance with the present invention, it should be clear to those skilled in the art that further embodiments may be made without departing from the scope of the present invention.

Claims

WHAT IS CLAIMED IS: I. A radiating structure, comprising: a plurality

of thermal pipes; a plurality of radiating fins, each radiating fin formed with plural inserting holes and guiding edges; the inserting holes being equidistantly formed in one side of the radiating fin, a guiding edge being formed on the radiating fin and located around a periphery of the inserting hole and being abutted against the thermal pipe; and at least one hollow positioning assembly for fixing the thermal pipes respectively, and the thermal pipes being in communication with the positioning assembly.
2. The radiating structure as claimed in claim 1, wherein a quantity of the inserting holes of the radiating fin is the same as that of the thermal pipes.
3. The radiating structure as claimed in claim 1, wherein a shape of each inserting hole is the same as that of a cross section of the thermal pipe.
4. The radiating structure as claimed in claim I, wherein the respective thermal pipes are sheet-shaped and have two planes at both sides thereof, one ends of the planes are connected by an arc-shaped surface, and the thermal pipes are equidistantly arranged.
5. The radiating structure as claimed in claim 4, wherein one end of the guiding edge is formed with a wind conduction section located correspondingly to the arc-shaped surface of the thermal pipe, and the other end of the guiding edge is extendedly formed with two abutting sections located correspondingly to the planes of the thermal pipe.
6. The radiating structure as claimed in claim 5, wherein the wind conduction section of the guiding edge is arc-shaped.
7. The radiating structure as claimed in claim 5, wherein the wind conduction section of the guiding edge is cone-shaped.
8. The radiating structure as claimed in claim 1, wherein the positioning assembly has two hollow pieces and two hollow posts; the pieces of the positioning assembly are fixed on both ends of the thermal pipe respectively; the posts are mounted on outer sides of the pieces respectively, the other side of each post is formed with one positioning piece, and the guiding pipe is in communication with the pieces and the posts of the positioning assembly.
9. The radiating structure as claimed in claim 8, wherein the other side of each post is formed with one positioning piece for fixing a housing.
10. A radiating structure substantially as hereinbefore described with reference to and as shown in Figures 3 to 6 of the accompanying drawings.