SU978399A1 - Device for cooling radio apparatus components - Google Patents

Description

This invention relates to a device; You need cooling of electronic equipment and it is designed to provide the necessary heat transfer modes of high-integration radio elements, for example large integrated circuits, which dissipate considerable thermal powers.

 A device for cooling radioelements is known, which contains channels for circulating coolant and heat sinks, with which heat is removed from C1 radioelements.

The known device is characterized by TqH by insufficient efficiency of heat removal from radio elements with a high level of released heat power.

The closest technical solution to the proposed is. a device for cooling radio equipment components containing a refrigerant filled pipeline with openings in its walls. and heat sinks tightly connected to the pipeline through its openings at their ends with the possibility of their other ends contacting with the surface of the cooled elements 2.

The disadvantages of the known device are the large dimensions and insufficient cooling efficiency of the high-integral elements are determined by the presence in the device of intermediate radiators and bellows, which increase the dimensions of the device and the thermal resistance of the coolant-radioelement junction.

The purpose of the invention is to increase cooling efficiency and reduce overall dimensions. 15

The goal is achieved due to the fact that in the device for cooling the radio equipment components, which contains a refrigerant filled pipe with openings in its

20 walls and heat pipes, hermetically connected to the pipe through its holes with one of its ends with the possibility of its other ends contacting with the surface

25 cooled elements, each heat sink is made in the form of a movable metal membrane with a flat base fixed along the contour of the corresponding opening of the pipeline,

Claims (2)

30a, throttling protrusions of a triangular shape are made on the inner surface of the pipeline walls opposite the openings, each of which is not less than half the height of the pipeline, and its width is equal to the maximum size of the flat base of the movable metal membrane, and its apex is relative to the geometric center of the corresponding movable metal membrane Storbnu opposite to the direction of flow of the refrigerant. FIG. 1 shows a device for cooling radio components, a section; in fig. 2 shows section A-A in FIG. 1. The device for cooling the elements comprises a pipe 1 with circulating refrigerant 2 for heat removal and heat sinks 3, made in the form of movable metal / Iembranes, designed to cool the elements 4 placed on the printed circuit board 5. The heat sink 3 is located in the corresponding hole L of pipeline 1 and tightly fixed along the contour of this hole b, for example, by welding. The pitch of the holes 6 on the walls 7 of the pipeline 1 corresponds to the pitch of installation 4 on the printed circuit board 5. The heat sinks 3, with their flat bases 8, directly contact the corresponding heat sink surfaces B of the cooled elements 4, which are fastened on the rigid heat conducting frame 9 with the help of screws 10. On the inner surface of the wall 7 of the pipeline 1 above each of the holes in the center of the installation of the heat sinks 3, throttling protrusions 11 are made, having a triangular view in axial section. The presence of such throttling protrusions 11 improves the circulation conditions of refrigerant 2 Near the surface into the heat sinks 3. Thanks to them, the pressure of the refrigerant 2 on the surface 8 of the movable metal membranes of the heat sink 3 is redistributed in accordance with their elastic characteristics, which leads to a uniform pressure on the entire surface of the flat base 8 heat sinks 3 to the heat-removing surface B of the cooled elements 4. The mutual arrangement of the printed plate 5 with the heat-conducting frame 9 -i pipeline 1 is provided with frame 12, fastened to which is carried out with screws 13. The height li of each throttling protrusion 11 is not less than half the height I of pipeline 1, its base width is equal to the maximum size of the movable metal membrane of the corresponding heat sink 3, and its height C is offset from the geometric center of the movable metal diaphragm in the direction opposite to the direction D of the refrigerant flow 2. The device is connected to the refrigerant main with the absorption of the inlet 14 and the outlet 15 nozzles. To regulate and control the flow and pressure of the refrigerant, the valve 16 and the pressure gauge 17 are used. The execution of the heat sinks 3 in the form of movable metal membranes allows the self-alignment of the contact surface of the flat base 8 of each heat sink 3 relative to the heat sink surface B of the respective cooled element 4. Due to this, the overall dimensions of the device and the thermal resistance of the transition of the coolant element is reduced, which makes it possible to increase the cooling efficiency. The use of movable metal membranes also makes it possible to create significant contact pressures, which improves the cooling of radio components. Apparatus of the invention for cooling radio equipment components, comprising a refrigerant filled pipeline with openings in its walls and heat lines, tightly connected to the pipeline through its openings with their ends, with the possibility of other ends contacting with the surface of cooled elements, characterized in that cooling efficiency and decreasing overall dimensions; each heat sink is designed as a corresponding hole fixed along the contour A movable metal membrane gadfly with a flat base and triangular shaped protrusions are made on the inner surface of the pipeline walls opposite the holes, each of which is not less than half the height of the pipeline, and its base width is equal to the maximum size of the flat base of the movable membrane, and its top is offset from the geometric center of the corresponding movable metal membrane in the direction opposite to the direction of flow of the refrigerant. Sources of information taken into account in the examination 1. US patent number 4072188, 16580, 1979. 2. USSR author's certificate number 572951, cl. H 05 K 7/20, 10/24/74 (prototype). “Rig. f