DE20201961U1 - Heat sink for computers - Google Patents

Description

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PATENT ATTORNEYS · EUROPEAN PATENT AND TRÄOEMARK ATTORNEYS

PO BOX 26 02 51 TELEPHONE: +49-89-22 18 06 HERRNSTRASSE

D-80059 MUNICH FAX: +49-69-22 26 27 D-80539 MUNICH

EMAIL: masterpat@t-online.de

CHEN, Yang Shiau

4Fl., No. 39, Fu-Kang St.,

Taipei, Taiwan

R.O.C.

and Glacialtech, Inc.

9Fl., No. 352, lake. 2, Jungshan Rd.

Junghe City, Taipei

Taiwan

R.O.C.

·

Cooling plate for computer

The present invention relates to a heat sink, in particular to a heat sink with good thermal conductivity suitable for heat dissipation of high temperatures generated during operation of a computer from a built-in so-called chip set or microprocessor (e.g. chip set for VGA card or CPU device).

It is known that a chip set or a microprocessor of a computer generates a high temperature during operation, and the faster the operating speed, the higher the power consumption. If the operating temperature of a chip set or a microprocessor is too high, its function will be affected and there is a risk of the computer breaking down. If the heat dissipation problem cannot be solved, the operating speed of a computer will be greatly limited. Therefore, a chip set or a microprocessor for computers with an even faster operating speed cannot be developed.

As can be seen from Fig. 7, a conventional cooling plate consists essentially of an aluminum base (1), a plurality of guide fins (2) and an electrical fan (3), wherein the aluminum base (1) has a chip set or a microprocessor on it, the guide fins (2) are formed to extend upwards on the circumference of this aluminum base (1), and the electrical fan (3) is equipped in the middle of the aluminum base (1). When the aluminum base (1) absorbs the heat generated by the chip set or microprocessor, it immediately transfers this heat to the guide fins (2). The cooling air generated by the electrical fan (3) will flow through the gaps between the guide fins (2) in order to be able to lower the temperature of a chip set or a microprocessor. The conventional aluminum base (1) and the guide fins (2) are first injection molded from aluminum into a certain shape (A) and then further processed as required (B). Therefore, the manufacturing process is both complicated and wasteful of materials.

In addition, the number of guide fins (2) is limited due to an aluminum injection molding process and therefore their available heat dissipation surfaces are also limited.

Fig. 8 shows a second embodiment of a conventional cooling plate for computers, which is also first injection-molded from aluminum into a specific shape (A) and then further processed as required. It differs from that of Fig. 7 in the different designs of curved guide ribs (2) in order to enable improved ventilation between the gaps of the respective guide ribs (2). The disadvantages of this known construction are, however, that it is complicated to manufacture and wastes material, and the number of guide ribs is limited during manufacture.

Fig. 9 shows a third embodiment of a conventional computer cooling fin, which is first stamped from an aluminum sheet (C) into a configuration of a base (1) and a plurality of fins (2), the fins (2) later being conveniently bent upright on the base (1). Although such a known construction can avoid wastage of material, such fins (2) create perpendicular obstructions to ventilation along their inner sides and can consequently result in poor heat dissipation efficiency since rapid air movement through the gaps of the fins (2) is not possible.

Fig. 10 shows a fourth embodiment of a conventional cooling plate for computers, which is a construction similar to that of Fig. 9, but differs in that the gaps between the guide fins (2) are not formed by respective cutouts of certain portions of the guide fins (2), but by the distance difference between the two adjacent guide fins (2) in the direction toward the center of the base (1). In comparison with the construction of the above-mentioned third conventional embodiment, from that of Fig. 9, although it is possible to increase the number of the guide fins (2) considerably, there is a disadvantage that the air cannot pass quickly through the gaps of the guide fins (2).

Taking into account the above mentioned disadvantages, the inventor has tried to develop a cooling plate for

To provide a computer which essentially consists of a base, a plurality of guide fins extended upwards on this base and along its circumference, and an electrical fan, with a receiving space in the middle of this base for the arrangement of an electrical fan. As the cooling air generated by the electrical fan continuously flows through the gaps between the guide fins, heat exchange can occur between the guide fins and the air flow to enable heat dissipation. A preferred construction of the invention is that there is a distance difference between the two adjacent guide fins towards the center of the base to increase the gaps therebetween; that there is an angle of inclination on the tangential line between the respective top of the guide fins and the center line of the base to enable the cooling air to be accelerated by guiding this angle of inclination through the gaps of the guide fins to increase the thermal conductivity of the cooling plates.

The invention is therefore based on the important task of designing a cooling plate for computers in the manner described above in such a way that there is a distance difference between the two adjacent guide ribs in the direction of the center of the base in order to increase the gaps between them; that there is an angle of inclination on the tangential line between the respective upper part of the guide ribs and the center line of the base in order to enable the cooling air to be accelerated by guiding this angle of inclination through the gaps of the guide ribs in order to increase the thermal conductivity of the cooling plates.

The invention is based on a further object of creating a cooling plate for computers, the base and guide ribs of which are injection-molded and machined from an aluminum sheet, the guide ribs being designed in a star-like, slanted manner and finally the guide ribs being able to be bent upwards by pressing. The advantages of this design are the simple manufacturing process and the reduced manufacturing costs.

Another object of the invention is to provide a cooling plate for computers that

the above-mentioned angle of inclination can be achieved by deforming a majority of guide ribs so that an angle difference can be formed between the upper part and the lower part of the guide ribs.

Finally, an object of the invention is to provide a cooling plate for computers in which the flank sides of the guide fins are each punched outwardly in stepped reduced thicknesses in order to increase the heat dissipation surfaces of the guide fins and to accelerate good ventilation.

The stated objects were achieved according to the invention by a cooling plate according to claim 1. Further developments of the invention are specified in the dependent claims.

Further features and advantages of the invention will become clear from reading the following description of preferred embodiments, which refers to the drawings, in which:

Fig. 1 is a perspective view of the invention in exploded
Arrangement;

Fig. 2 is a schematic representation of the invention showing the arrangement of guide ribs
and base;

Fig. 3 is a schematic representation of the invention to show how the components
to be edited;

Fig. 4 is a schematic representation of the invention to show how the guide ribs
be bent;

Fig. 5 is a perspective view of the invention to show how a guide rib
is deformed;

Fig. 6 is a schematic representation of the invention to show how a flank side

a guide rib is formed into a guide surface;

Fig. 7 shows a first perspective embodiment of a conventional cooling plate,
to show how it is made;

Fig. 8 shows a second perspective embodiment of a conventional cooling plate,
to show how it is made;

Fig. 9 shows a third perspective embodiment of a conventional cooling plate,
to show how it is made; and

Fig. 10 shows a fourth perspective embodiment of a conventional cooling plate,
to show how it is made.

As can be seen in Fig. 1 and 2, a cooling plate according to the invention consists essentially of a base (10), a plurality of guide fins (20, 20') extended upwards on this base (10) and on its circumference and an electrical fan (30), with a receiving space (11) in the middle of this base (10) for the arrangement of an electrical fan (30). As the cooling air generated by the electrical fan (30) continuously flows through the gaps between the guide fins (20, 20'), a heat exchange can take place between the guide fins and the air flow in order to enable heat dissipation. A preferred construction of the invention is that there is a distance difference (H) between the two adjacent guide fins (20, 20') in the direction of the middle of the base (10) in order to increase the gaps therebetween; that has an angle of inclination (Θ) on the tangential line (Y) between the respective upper part of the guide ribs (20, 20') and the center line (X) of the base (10) in order to enable the cooling air to be accelerated by guiding this angle of inclination through the gaps of the guide ribs (20, 20') in order to increase the thermal conductivity of the cooling plates.

As can be seen in Fig. 3, the base (10) and the guide ribs

(20,20') of a cooling plate according to the invention is first injection-molded from an aluminum sheet (A) and then punched and cut into a plurality of guide ribs (20 ₅ 20') on its circumference. Finally, the guide ribs (20, 20') can be formed at an angle in a star shape and further bent upwards by a pressing process so that an angle of inclination (Θ) can be achieved by deforming a plurality of guide ribs (20, 20') and a base (10) can be formed in the middle of this aluminum sheet (A). In addition, the guide ribs (20, 20') are wrapped around the circumference of this base (10) in order to be able to form a receiving space (11) in the middle of the base (10). Furthermore, the adjacent guide ribs (20, 20') can be bent upwards alternately by a clamping device in order to allow an angle difference (H) to be formed between the upper part of the guide ribs (20, 20') and the center line of the base (10). Except for the above-mentioned processing method, the

The cooling plate according to the invention can also be manufactured in one piece with other tools by means of a uniform casting process.

The design of the base (10) for the cooling plate according to the invention is not limited to a circular shape. The aluminum sheet (A) shown in Fig. 3 is circular, so the designed base (10) will be circular. If the aluminum sheet (A) is square, the designed base (10) will then be square.

As can be seen in particular from Fig. 4, the two adjacent guide ribs (20 ₅ 20') can be bent upwards alternately by a clamping device in order to enable an angle difference (H) to be formed between the upper part of the guide ribs (20, 20') and the center line of the base (10). For example, in a bending process, the first guide rib (20) can be bent upwards by a right angle (90°) and the adjacent guide rib (20') by a 60° angle, so that a distance difference (H) in the direction of the center of the base (10) can be formed by the stop angles formed by the two guide ribs (20, 20').

As can be seen in Fig. 3, the above-mentioned inclination angle (Θ) can be achieved by forming an inscribed angle (Θ) between the intersection line of the two

adjacent guide ribs (20, 20') and the center line (X) of the base (10) during manufacture of the guide ribs (20, 20') by means of the punching process. After the guide ribs (20, 20') are bent upwards, an inclination angle (Θ) can be formed on the vertical tangential line (Y) between the respective upper part of the guide ribs (20, 20') and the center line (X) of the base (10).

As can be seen in Fig. 5, the above-mentioned inclination angle (θ) can also be formed by deforming a plurality of guide ribs (20, 20'). For example, the bottom (21) of a guide rib (20) can be made parallel to the tangential line (Y) of the center line (X) of the base (10). After deforming the top (22) of the guide rib (20), an angle difference can be formed between the bottom (21) of the guide rib (20) and the top (22) of the guide rib (20). This angle difference can be referred to as the above-mentioned inclination angle (θ).

An advantage of the above preferred construction is that the cooling air of an electrical fan can be accelerated by guiding such angles of inclination (θ) through the gaps of the adjacent guide ribs (see Fig. 2) in order to increase the thermal conductivity of the cooling plates. It is also possible to arrange such guide ribs (20, 20') in stepped reduced thicknesses for better effect in the manufacturing process. For example, as can best be seen from the illustration in Fig. 6, the flank side of one of these guide ribs (20) can be punched outwards in stepped reduced thicknesses in order to form an inclined guide surface (23) on the flank side of the guide rib (20). In addition, the flank sides of the aforementioned guide ribs (20) can each be punched outward in gradually reduced thicknesses using a press-forming machine, so that the heat dissipation surfaces of the guide ribs can be increased and good ventilation can be accelerated.

As can be seen in Fig. 2, a holding hole (12) can be arranged on each of the two sides of the base (10) so that the base (10) can be screwed to an object to be dissipated heat (e.g. a chip set or a microprocessor) through these holding holes (12).

The designations of the parts of the embodiment of the present invention and the drawings are for illustrative purposes only and are not intended to limit the scope of the present invention. It is to be understood that the embodiment described above may be embodied in various ways without departing from the spirit and scope of the present invention. Accordingly, the following claims, which form a part of this invention, also apply to any modifications of the embodiment.

A cooling plate for computers is described, which essentially consists of a base, a plurality of guide fins extended upwards on this base and along its circumference, and an electrical fan, with a receiving space in the middle of this base for the arrangement of an electrical fan and while the cooling air generated by the electrical fan flows continuously through the gaps between the guide fins, can cause a heat exchange between the guide fins and the air flow to enable heat dissipation, characterized in that there is a distance difference between the two adjacent guide fins in the direction of the middle of the base in order to increase the gaps therebetween; that there is an angle of inclination on the tangential line between the respective upper part of the guide fins and the center line of the base in order to enable the cooling air to be accelerated by guiding this angle of inclination through the gaps of the guide fins in order to increase the thermal conductivity of the cooling plates.

Claims (6)

1. Cooling plate for computers consisting of a base, a plurality of guide fins extended upwards on this base and along its circumference, and an electrical fan, with a receiving space in the middle of this base for the arrangement of an electrical fan and during the cooling air generated by the electrical fan constantly flows through the gaps between the guide fins, can cause a heat exchange between the guide fins and the air flow in order to enable heat dissipation, characterized in that there is a distance difference between the two adjacent guide fins in the direction of the middle of the base in order to increase the gaps therebetween; that there is an angle of inclination on the tangential line between the respective upper part of the guide fins and the center line of the base in order to enable the cooling air to be accelerated by guiding this angle of inclination through the gaps of the guide fins in order to increase the thermal conductivity of the cooling plates. 2. Cooling plate for computers according to claim 1, characterized in that a majority of guide fins and the base are made in one piece from an aluminum sheet by a uniform injection molding process. 3. Cooling plate for computers according to claim 1, characterized in that the above-mentioned difference in distance is formed by the different stop angles bent upwards by the two guide ribs from the base. 4. Cooling plate for computers according to claim 1, characterized in that the guide ribs are deformed and an angle difference is formed between the upper part and lower part of the guide ribs in order to be able to form the above-mentioned angle of inclination. 5. Cooling plate for computers according to claim 1, characterized in that the flank sides of the guide ribs are each punched outwardly in stepped reduced thicknesses in order to enable an inclined guide surface to be formed on the flank sides of the guide ribs. 6. Cooling plate for computers according to claim 1, characterized in that a holding hole can be arranged on each of the two sides of the base.