KR20130005980U - A tubular radiating seat integrally formed by one working procedure - Google Patents

Abstract

The present invention is directed to a tubular heat dissipation sheet formed integrally by one working process comprising a hollow heat dissipation sheet structured by punching or extruding a certain aluminum solid disk (hydraulic). The front portion or the middle portion of the tubular heat dissipation sheet has an integrated closed end. Several slots are integrally formed in the outer wall of the tubular heat dissipation sheet to engage the corresponding fin set. The closed end formed in the front portion of the tubular heat dissipation sheet has an integrally structured projecting periphery. Furthermore, the recessed portion is integrally structured in the protruding periphery. Furthermore, the recessed portion is integrally structured in the protruding peripheral portion, and grooves are formed in the inner wall of the recessed portion by the turning process. Attaching the closed end, the protruding periphery or the recessed portion to the heat generating unit contributes to a rapid heat absorption effect and an advantageous heat dissipation effect. The design of the groove is preferably consistent with the light cover.

Description

Tubular heat dissipation sheet integrally formed by one work process {A TUBULAR RADIATING SEAT INTEGRALLY FORMED BY ONE WORKING PROCEDURE}

The present invention punches or extrudes a fixed amount of aluminum solid disk (hydraulically) to structure the hollow heat dissipation sheet so that not only the closed end but also several slots in the wall can be integrally and simultaneously configured on the tubular heat dissipation sheet. It relates to the design of the tubular heat dissipation sheet formed integrally by the working process of.

Conventional radiators surrounded by several heat dissipation fins mainly comprise a plurality of heat dissipation fins and a tubular heat dissipation sheet. The manufacturing cost of this radiator is substantially expensive because the fins must be integrally arranged on the outer wall of the tubular heat dissipation sheet. Furthermore, such radiators are also bulky and heavy; To make matters worse, the amount of fins is limited. As a result, the heat dissipation effect of the radiator is unsatisfactory.

The conventional tubular heat dissipation sheet of the radiator attaches the closed end to a heat generating unit, such as a CPU or LED unit, to dissipate heat. Alternatively, a heat generating tube that collects heat can be freely employed to improve the heat dissipation effect. The formation of the tubular heat dissipation sheet may be circular, square or polygonal or the like.

There is another type of conventional tubular heat dissipation sheet that uses a heat dissipation tray with a central hole to engage the hollow tubular sheet. Here, the heat dissipation tray and the hollow tubular sheet are two separate parts. Therefore, the capillary phenomenon easily appears when two parts are combined, resulting in thermal resistance. Here, unsatisfactory absorption of exothermic temperatures and substandard heat transfers result in poor heat dissipation effects. Furthermore, the cost of molding the heat dissipation tray and the hollow tubular sheet respectively is high, and the two parts have to be further assembled by an extra work process. Thus, this labor and time consuming means of producing expensive radiators is not economical.

Therefore, an object of the present invention is to provide a tubular heat dissipation sheet formed integrally by one working process. The present invention includes a hollow heat dissipation sheet structured by punching or extrusion (a hydraulically) a predetermined amount of an aluminum solid disk. The front portion or the middle portion of the tubular heat dissipation sheet has an integrated closed end, and a plurality of slots are integrally formed on the outer wall of the tubular heat dissipation sheet to engage with a corresponding set of fins. Thus, the tubular heat dissipation sheet is compact and integrally formed to simplify the manufacturing process and reduce the manufacturing cost. Less problems are caused at the joints and the capillary phenomenon is no longer a problem. The heat dissipation effect is greatly improved by preventing thermal resistance and absorbing the exothermic temperature well.

Another object of the present invention is to provide a tubular heat dissipation sheet which is formed integrally by one working process of structuring a closed end in the front part of the protruding periphery and the tubular heat dissipation sheet which is formed integrally. Preferably, the recessed portion is integrally structured at the protruding periphery. Preferably, grooves are formed on the inner wall of the recessed portion by the turning process. A slot can cooperate with the light cover to attach the closed end, the protruding periphery or the recessed portion to the heat generating unit.

1 is an assembled perspective view showing a first preferred embodiment of the present invention.
2 is an exploded view of FIG. 1;
3 is an end view of FIG.
4 is a cross-sectional view of the section AA of FIG. 3.
5 is an exploded view showing protruding light composed of a light cover and an electrical connector;
6 is an assembled perspective view of FIG. 5.
7 is an assembled perspective view of a second preferred embodiment of the present invention.
8 is an exploded view of FIG. 7;
9 is a plan view of Fig.
10 is a cross-sectional view of section AA of FIG. 9.
11 is an assembled perspective view of a third preferred embodiment of the present invention.
12 is a plan view of FIG.
13 is a cross-sectional view of the section AA of FIG. 11.

1 to 4, a first preferred embodiment of the present invention is shown. The tubular heat dissipation sheet formed integrally by one working process includes a hollow heat dissipation sheet 1 structured by punching or extruding a predetermined amount of aluminum solid disk (hydraulically). The front part or the middle part of the tubular heat dissipation sheet 1 has an integrated closed end 11 (shown in FIGS. 3 and 4). The plurality of slots 12 are integrally formed on the outer wall of the tubular heat dissipation sheet to engage the corresponding fin set 2. Next, the fin set 2 is compactly coupled and inserted into the outer wall of the tubular heat dissipation sheet 1 such that the tubular heat dissipation sheet 1 provides the fin set 2.

The appearance of the tubular heat dissipating sheet 1 that has just been punched or extruded hydraulically can be rough. The rough appearance here can be easily smoothed by the processing device. Clearly, the production of the tubular heat dissipation sheet is trouble free and the subsequent processing is also not complicated. Therefore, the tubular heat dissipation sheet 1 can be advantageous in cost reduction of the product, which is also competitive and practical in the market.

As mentioned in the above embodiment, the closed end formed in the front portion 11 of the tubular heat dissipation sheet 1 has an integrally structured projecting periphery 111. Alternatively, the recessed portion 112 may be integrally structured with the protruding portion 111. Therefore, attaching the closed end 11, the protruding periphery 111 or the recessed portion 112 to a heat generating unit, such as a CPU or LED unit, preferably improves the effect of absorbing and dissipating heat.

Subsequently, a groove 113 may alternatively be formed in the inner wall of the recessed portion 112 by a turning procedure to engage with the light cover 3 (shown in FIG. 5). When the electrical connector 4 is further cooperated, a protruding light (shown in FIG. 6) is provided. Here, at least one set of LED units can be inserted into the closed end 11, the protruding peripheral part 111 or the recessed part 112 of the tubular heat dissipation sheet 1 previously.

7 to 10, a second preferred embodiment of the present invention is shown. In this embodiment, the protruding peripheral portion 111a is integrally formed around the closed end 11a at the front portion of the tubular heat dissipation sheet 11a. Furthermore, a plurality of slots 12a are integrally formed in the outer wall of the tubular heat dissipation sheet 1 so that the tubular heat dissipation sheet can be coupled to the fin set 2a around the periphery. That is, the recessed portion 112 that existed in the first preferred embodiment can be omitted here. Furthermore, one end of the pin set 2a may be designed according to the formation of the periphery 111a that protrudes in order to uniquely lead to the recess 21a. Accordingly, the pin set 2a may surround the protruding peripheral portion 111a.

11 to 13 show a third preferred embodiment of the present invention. Here, the closed end 11b (shown in FIG. 13) is integrally structured in the middle portion of the tubular heat dissipation sheet 1b. The plurality of slots 12b are integrally formed in the outer wall of the tubular heat dissipation sheet 1b in order to cooperate with the annular fin set 2b. Thereby, the fin set 2b can be compactly and completely coupled to the outer wall of the tubular heat dissipation sheet 1b, thereby implementing the tubular heat dissipation sheet 1b having the fin set 2b.

In summary, the present invention particularly employs a tubular heat dissipating sheet 1 / 1b formed integrally by one working process for attaching the solid closed end 11 / 11a / 11b to the heat generating unit. Furthermore, slots 12 / 12a / 12b are also provided for compactly cooperating with the pin sets 2 / 2a / 2b. Obviously, the joint is not a problem in the tubular heat dissipation sheet 1, and the possibility of capillary action is also reduced. Furthermore, extra thermal resistance is prevented to promote the heat absorbing effect and improve the heat dissipation effect. As a result, the manufacturing of the present invention is simplified and the associated costs are preferably reduced.

Claims (6)

A tubular heat dissipation sheet formed integrally by one work process,
A hollow heat dissipating sheet structured by punching or extruding a predetermined amount of aluminum solid disk (hydraulic);
A front portion or a middle portion of the tubular heat dissipation sheet having an integrated closed end;
A plurality of slots integrally formed in the outer wall of the tubular heat dissipation sheet for mating with a corresponding set of fins
Tubular heat dissipation sheet comprising a. The tubular heat dissipation sheet according to claim 1, wherein the fin set is compactly coupled and inserted into the outer wall of the tubular heat dissipation sheet. The tubular heat dissipation sheet according to claim 1, wherein an appearance of the tubular heat dissipation sheet is neatly trimmed. The tubular heat dissipation sheet according to claim 1, wherein said closed end formed in said front portion of said tubular heat dissipation sheet has an integrally structured projecting periphery. The tubular heat dissipation sheet according to claim 4, wherein a recessed portion is integrally structured in the protruding peripheral portion. 6. The tubular heat dissipation sheet according to claim 5, wherein a groove is formed in the inner wall of the recessed portion by a turning procedure.

Images