DE29819315U1 - Device for fastening cooling elements - Google Patents

Description

STRASSP &-HOFSTE7TER

Patent attorneys

European Patent Attorneys °

European trademark attorneys

Dipl.-lng. JOACHIM STRASSE "♦ Dr.rer.nat. ALFONS J. HOFSTETTER °*

Dr.-ing. Eduard F. Schurack °* Of Counsel

Dr. jur. PETER C. BlTTNER Authorized representative at

" European Patent Office
* European Office for Harmonization in the Internal Market (Trade Marks and Designs)

In cooperation with

LENZINC GERBER
Patent Attorneys · Düsseldorf

Attorney file: 24918

ECL
Electronic Cooling Systems Leutkirch GmbH

Nadlerstr. 10
88299 Leutkirch

GERMAN UTILITY MODEL RE-REGISTRATION

Device for fastening cooling elements

BALANSTRASSE 57 · D-81541 MUNICH

Telephone +49/(0)89 - 45 09 18 &ogr; · Fax +49/(0)89 - 45 09 18 12 · Voice +49/(0)89 - 45 09 18 20

EMAIL Strasse-Hofstetter@T-Online.de

EKL Attorney File: 24918

Electronic Cooling Systems Leutkirch GmbH,

88299 Leutkirch

German utility model application

Device for fastening cooling elements

The present invention relates to a device for fastening cooling elements, in particular for fastening active and passive cooling elements to processors.

Known fastening devices are, for example, frame-like snap devices that enclose a cooling element that rests on a processor on the one hand and, on the other hand, enclose the edge of the processor and snap into place behind it. So-called metal clips are also known that are placed over or in the cooling element and also snap into place on the edges of the processor. For this purpose, grooves or lugs are formed on the edges of the processor.

It is also known that processors are inserted into corresponding grooves of a plastic adapter, whereby the plastic adapter carries the cooling element.

The disadvantage of the known fastening devices for cooling elements on processors is that they are very difficult to install and often require the use of aids such as special tools. In particular, retrofitting to other, more powerful cooling elements is often not possible or very difficult. The known fastening devices are of limited use, particularly for processors that have a processor cover.

It is therefore an object of the present invention to provide a device for fastening cooling elements, in particular for fastening

To provide a solution for mounting active or passive cooling elements on processors, which ensures simple and secure attachment of the cooling elements to the processors without the need for complex mounting devices.

To solve this problem, a generic device according to the features of claim 1 serves.

Advantageous embodiments are described in the subclaims.

A device according to the invention for fastening cooling elements has at least one web, with at least two guide locking pins arranged on the web and perpendicular to it. The guide locking pins each have locking elements at their ends which are designed to be inserted into corresponding openings in a processor cover of the processor and lock into place therein. The design according to the invention ensures simple assembly of a cooling element on a processor with a processor cover. The web, which is arranged on or in the active or passive cooling element and is axially movable therein, engages with its guide locking pins in the corresponding openings in the processor cover and locks into place therein. The processor lies between the processor cover and the cooling element in such a way that the cooling element comes into contact with the processor. The guide locking pins of the web protrude through corresponding cooling element openings in the cooling element.

In an advantageous embodiment of the invention, the guide locking pins also protrude through corresponding processor openings in the processor and can be locked into the openings in the processor cover located behind the processor openings. The design of the processor with processor openings ensures that the fastening device or cooling element can be positioned precisely on the processor. The diameter of the respective guide locking pin

zens adapts to the respective diameter of the corresponding opening, whereby the diameter in the area of the cooling element opening is larger than in the area of the processor opening and the opening in the area of the processor cover.

In a further advantageous embodiment of the invention, the diameter of the guide locking pin is smaller than the diameter of the cooling element opening or the processor opening. This ensures that the web with the guide locking pin remains axially movable within the cooling element, so that the fastening device can be used for processors of different sizes or thicknesses.

In a further advantageous embodiment of the invention, a bead is formed between the larger diameter of the guide locking pin and the smaller diameter of the guide locking pin. The formation of this bead ensures that the fastening device with the cooling element can only be inserted up to a predetermined stop on the processor surface or in the processor. Damage caused by excessive pressure during assembly is therefore excluded.

In a further advantageous embodiment of the device according to the invention for fastening cooling elements to processors, a spring element is arranged centrally between the guide locking bolts on the surface of the web facing the processor. By arranging a spring element in this way, a path-dependent contact pressure of the cooling element on the processor surface is achieved. This ensures that the cooling element is always in close contact with the processor surface without the cooling element exerting too great a pressure load on the processor. In a particularly advantageous embodiment of the invention, the spring element has an elliptical shape. By designing the spring element in this way, a particularly uniform contact pressure of the cooling body on the processor surface is generated.

The present invention further comprises a processor with a processor cover and an active or passive cooling element arranged on the processor, wherein the cooling element is arranged on the processor by means of a device for fastening the cooling element and the device has at least one web, wherein at least two guide locking pins are arranged on the web and perpendicular thereto and the guide locking pins each have locking elements at their ends which are designed to be inserted into corresponding openings in the processor cover and engage therein. The web is arranged on or in the active or passive cooling element and the guide locking pins protrude through corresponding cooling element openings and processor openings in the processor, wherein the guide locking pins can then be engaged in the openings in the processor cover located behind the processor openings.

Further details, features and advantages of the invention emerge from an embodiment shown in the following drawings. They show:

Figure 1 is a schematic sectional drawing of a device according to the invention for fastening cooling elements, mounted on a processor;

Figure 2 is a schematic sectional drawing of the device according to the invention for fastening cooling elements; and

Figure 3 is a schematic plan view of the device according to the invention for fastening cooling elements.

Figure 1 shows a device 10 for fastening a cooling element 36. The device 10 comprises a web 12, with two guide locking pins 16, 18 arranged on the web 12 and perpendicular thereto. The guide locking pins 16, 18 each have locking elements 24, 26 at their ends opposite the web 12.

The locking elements 24, 26 are designed such that they can be inserted into corresponding openings 46, 48 of a processor cover 34 of a processor 32 and lock into place therein.

It can also be seen that the web 12 is arranged in the passive cooling element 36 and is axially movable. The guide locking pins 16, 18 protrude through corresponding cooling element openings 38, 40. Passive cooling elements 36 of the type shown usually have longitudinal and transverse grooves into which the device 10 can be introduced. In contrast to the known cooling elements, the cooling element 36 used here also has the cooling element openings 38, 40 for receiving and passing through the guide locking pins 16, 18.

It can also be seen that the guide locking pins 16, 18 also protrude through corresponding processor openings 42, 44 of the processor 32 and engage in openings 46, 48 of the processor cover 34 located behind the processor openings 42, 44. The diameter of the guide locking pin 16, 18 is larger in the area of the cooling element opening 38, 40 than its diameter in the area of the processor opening 42, 44 and the opening 46, 48 in the area of the processor cover 34. The diameter of the guide locking pin 16, 18 in the area of the cooling element 36 is always smaller than the diameter of the cooling element opening 38, 40. This ensures axial mobility of the device 10 within the cooling element 36. However, so that the device 10 cannot fall out of the cooling body 36, a bead 20, 22 is formed between the larger diameter of the guide locking pin 16, 18 and the smaller diameter of the guide locking pin 16, 18. The diameter of this bead 20, 22 is slightly larger than the diameter of the cooling element opening 38, 40. The guide locking pins 16, 18 can thus be pushed through the cooling element openings 38, 40, but falling out of the cooling element 36 is prevented by the larger bead diameter. Furthermore, the bead 20, 22 serves as a defined spacer or as a support between the processor surface and the cooling element. This

prevents the device 10 with the cooling element 36 from being pressed too firmly onto the processor 32, which could potentially damage the latter. Usually - this cannot be seen in Figure 1 - the distance between the bead 20, 22 and the processor 32 is 0.6 - 0.8 mm in depth and is therefore freely movable.

The distance and diameter of the guide locking pins 16, 18 can be adapted to the type of heat sink and the processor or processor cover, depending on the requirements.

Figure 1 also shows that a spring element 14 is arranged centrally between the guide locking bolts 16, 18 on the surface of the web 12 facing the processor 32. The spring element 14 has an elliptical shape. The spring element 14 serves to achieve a path-dependent, defined contact pressure of the heat sink element 36 on the surface of the processor 32.

The device 10 and the spring element 14 can be made of metal, a metal alloy and/or plastic. It has proven advantageous for the device 10 and/or the spring element 14 to be made of polycarbonate or glass fiber reinforced polycarbonate. The device 10 and the spring element 14 can be manufactured using a plastic injection molding process.

Figure 2 shows the device 10 for fastening a cooling element to a processor in a schematic representation. It can be seen that the spring element 14 is arranged centrally on the side of the web 12 facing a processor 32. A corresponding recess 50 is provided in the web 12 for receiving the spring element 14. Furthermore, the design of the guide locking bolts 16, 18, which protrude vertically from the web 12, can be seen. In the area of the locking elements 24, 26, they each have a guide strip 28, 30. The guide strips 28, 30 serve for the exact positioning of the web 12 or

- 7 wise
of the cooling element 36 on the processor 32.

Figure 3 shows a top view of the web 12 in the direction of the bulge 50. The arrangement of the guide strips 28, 30 on the guide locking pins 16, 18 can be seen.

The device 10 for attaching cooling elements 36 to processors 32 is assembled without the need for complex assembly tools. The processor 32 is placed on the processor cover 34. The cooling element 36 with the pre-assembled web 12 is then placed on so that the guide locking pins 16, 18 are guided through the processor 32. The web 12 is pressed in as far as it will go, i.e. until the bead 20, 22 rests on the processor surface, using a screwdriver or similar auxiliary tool. At the same time, the locking elements 24, 26 of the guide locking pins 16, 18 engage in the corresponding openings 46, 48 of the processor cover 34. After assembly, a defined cooling element/processor contact pressure is established due to the axial mobility of the web 12 or the cooling element 36, which is supported by the spring element 14.

Claims (11)

1. Device for fastening cooling elements, in particular for fastening active or passive cooling elements to processors, characterized in that the device ( 10 ) has at least one web ( 12 ) and at least two guide locking pins ( 16 , 18 ) are arranged on the web ( 12 ) and perpendicular thereto, the guide locking pins ( 16 , 18 ) each having locking elements ( 24 , 26 ) at their ends which are designed to be inserted into corresponding openings ( 46 , 48 ) of a processor cover ( 34 ) of the processor ( 32 ) and to lock into place therein. 2. Device according to claim 1, characterized in that the web ( 12 ) is arranged on or in the active or passive cooling element ( 36 ) and is axially movable, wherein the guide locking bolts ( 16 , 18 ) protrude through corresponding cooling element openings ( 38 , 40 ). 3. Device according to claim 1 or 2, characterized in that the guide locking bolts ( 16 , 18 ) protrude through corresponding processor openings ( 42 , 44 ) of the processor ( 32 ) and can be locked into openings ( 46 , 48 ) of the processor cover ( 34 ) located behind the processor openings ( 42 , 44 ). 4. Device according to one of the preceding claims, characterized in that the diameter of the guide locking bolt ( 16 , 18 ) in the region of the cooling element opening ( 38 , 40 ) is larger than its diameter in the region of the processor opening ( 42 , 44 ) and the opening ( 46 , 48 ) in the region of the processor cover ( 34 ). 5. Device according to claim 4, characterized in that the diameter of the guide locking bolt ( 16 , 18 ) in the region of the cooling element ( 36 ) is smaller than the diameter of the cooling element opening ( 38 , 40 ). 6. Device according to claim 4 or 5, characterized in that a bead ( 20 , 22 ) is formed between the larger diameter of the guide locking bolt ( 16 , 18 ) and the smaller diameter of the guide locking bolt ( 16 , 18 ). 7. Device according to one of the preceding claims, characterized in that a spring element ( 14 ) is arranged centrally between the guide locking bolts ( 16 , 18 ) on the surface of the web ( 12 ) facing the processor ( 32 ). 8. Device according to claim 7, characterized in that the spring element ( 14 ) has an elliptical shape. 9. Device according to one of the preceding claims, characterized in that the device ( 10 ) and the spring element ( 14 ) consist of metal, a metal alloy and/or plastic. 10. Device according to claim 9, characterized in that the device ( 10 ) and/or the spring element ( 14 ) consists of polycarbonate or glass fiber reinforced polycarbonate. 11. Processor with a processor cover and an active or passive cooling element arranged on the processor, characterized in that the cooling element ( 36 ) is arranged on the processor ( 32 ) by means of a device ( 10 ) for fastening the cooling element ( 36 ), wherein the device ( 10 ) has at least one web ( 12 ) and at least two guide locking bolts ( 16 , 18 ) are arranged on the web ( 12 ) and perpendicularly thereto, wherein the guide locking bolts ( 16 , 18 ) each have locking elements ( 24 , 26 ) at their ends, which are designed to be inserted into corresponding openings ( 46 , 48 ) of the processor cover ( 34 ) and lock into place therein, and the web ( 12 ) is arranged on or in the active or passive cooling element ( 36 ) and the guide locking bolts ( 16 , 18 ) are secured by corresponding Cooling element openings ( 38 , 40 ) and processor openings ( 42 , 44 ) of the processor ( 32 ) protrude and can then be snapped into the openings ( 46 , 48 ) of the processor cover ( 34 ) located behind the processor openings ( 42 , 44 ).