DE20109355U1 - Improved spotlight for central microprocessors - Google Patents

Description

P13138 RW/hei/fle

Title: Improved radiator for central microprocessors

S Description

This invention relates to an improved radiator for central microprocessors, and more particularly to a radiator structure having a large radiating surface and an improved heat conduction effect for improving heat dissipation.

In recent years, the continuous progress and development of technology has brought about very rapid innovations in personal computer-related equipment and elements. For example, hard disk drives, interface cards, central processing units, and the like can process a larger amount of data at a faster processing speed. Along with the faster processing speed, the operating temperature of the computer's internal devices and integrated circuit elements is increasing. Even the IC (integrated circuit) chips of interface cards will generate a high temperature during operation. If the heat is not properly dissipated, normal operation will be affected and may result in performance degradation or even affect device durability. Therefore, setting up a radiator or heat dissipation device at the heat generation source (i.e., the chips) is a common solution to address this problem.

Conventional radiators generally consist of a fan and cooling fins. Heat is distributed by a fan above the cooling fins through air convection and radiation. The

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Heat dissipation is proportional to the size of the radiating surface.

'Conventional cooling fins made of extruded aluminum or die-casting usually do not have adequate radiating area. Due to manufacturing limitations, the extruded aluminum cooling fins usually have a relatively large thickness and a large fin interval and thus a smaller radiating area. They also have a larger air flow resistance and a lower air flow velocity and thus cannot effectively increase heat dissipation or achieve the desired heat dissipation effect. Similarly, although the injection molded fins have a smaller air flow resistance, they still do not have adequate radiating area and cannot achieve the desired cooling effect. Manufacturing by die-casting also involves higher costs and is not economically justified.

Fig. 1 shows a conventional radiator A having a contact base Al with a plurality of sets of sheet-like fins A2 mounted thereon. There is a large convection well A3 formed between two sets of fins A2.

Actual application experiments show that the previous design and structure does not have the desired cooling effect. The problem is caused by insufficient radiation area. Simply counting on a number of cooling fins A2 cannot provide sufficient heat dissipation area. Even adding a cooling fan set still does not produce a satisfactory result.

The object of the present invention is to provide a radiator which eliminates the preceding disadvantages.

This object is achieved by a radiator according to claim 1.

The invention provides an improved radiator that uses a soldering process to cause the cooling fins to closely contact a thermally conductive base so that the cooling fins have a surface-to-surface contact with the conductive base to achieve a better heat conduction effect.

In the present invention, the cooling fins are vertically soldered to the conductive base and form a height difference between the top of the cooling fins and the top edge of the two side walls of the conductive base. The height difference forms a fan chamber. The two side walls each have engaging slots for mounting the fan.

Preferred embodiments of the present invention are explained in more detail below with reference to the accompanying drawings.

Fig. 1 is a perspective view of conventional cooling fins;

Fig. 2 is a perspective view of the cooling fins of this invention; and

Fig. 3 is a schematic view of the invention in its

Application.
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Referring to Figure 2, the radiator 1 according to this invention consists of a plurality of cooling fins 12 welded to a thermally conductive base 11. The conductive base

■11 has two side walls 14 each having a selected number of engaging slots 141. The side walls 14 are slightly higher than the cooling fins 12 to form a fan chamber 15 above the cooling fins 12. There is a convection well 13 formed between the cooling fins 12.

The cooling fins 12 are formed by a thin metal sheet and are bent by machining to form a U-shape.

The conductive base 11 is made of a material with good thermal conductivity.

The cooling fins 12 are attached to the conductive base 11 by a special soldering method, which may be, but is not limited to, conventional TIG (tungsten inert gas) or WIG soldering or high-precision laser soldering, which has lower deformation and lower effort, such that the cooling fins 12 completely contact the conductive base 11 to achieve an optimal heat conduction effect.

Referring to Fig. 3, in the use of this invention, the radiator 1 is mounted on a central microprocessor 2. A fan 3 is disposed in the fan chamber 15 and secured by the engaging slots 141.

The radiator constructed in this way will greatly shrink the thickness of the cooling fins, reduce the interval between the fins and narrow the width of the convection trough. Therefore, the number of cooling fins can be greatly

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can be increased, and consequently the heat dissipation area can be increased and the heat dissipation effect can be improved. In addition, the fan can quickly drive out the high temperature generated by the central microprocessor.

By means of the structure set forth above, the cooling fins are formed by a thin metal sheet in a corrugated manner to be a plurality of fins that contact each other adjacently. The upper ends of the fins and the upper end of the side walls of the conductive base have a height difference to form a fan chamber. The side walls have a plurality of engaging slots for mounting the fan. The cooling fins are connected to the conductive base in surface-to-surface contact by soldering. Therefore, heat can be evenly distributed. The invention therefore solves the disadvantages of conventional radiators and becomes a highly efficient radiator.

Claims (3)

1. A radiator for central microprocessors comprising at least one thermally conductive base ( 11 ) having two opposite side walls ( 14 ) and a plurality of cooling fins ( 12 ) soldered to the conductive base ( 11 ) between the side walls ( 14 ), the cooling fins ( 12 ) being made of a thin metal sheet and formed into a U-shape; wherein a selected soldering method is used to solder the cooling fins ( 12 ) to the conductive base ( 11 ) to form a closed and close contact so that the heat absorbed by the conductive base ( 11 ) is effectively transferred to the cooling fins ( 12 ) for complete dissipation. 2. A radiator according to claim 1, wherein the cooling fins ( 12 ) and the conductive base ( 11 ) are made of a material with a high thermal conductivity selected from a group consisting of copper and aluminum. 3. A radiator according to claim 1 or 2, wherein the conductive base ( 11 ) and the cooling fins ( 12 ) have different heights to form a fan chamber ( 15 ) in the height difference at the upper ends thereof, the side walls ( 14 ) having a selected number of engaging slots ( 141 ) for attaching a fan ( 3 ).