RU2554113C2 - Electronic unit - Google Patents

Abstract

FIELD: physics, computer engineering.

SUBSTANCE: invention relates to computer engineering and can be used in radio-electronic equipment blocks in which plug-in electronic modules are installed and which operate in conditions of high heat release by radio-electronic equipment components, significant mechanical loads, as well as aggressive weather conditions during field use. An electronic unit includes channels which form a coolant stream. Through said channels, which are located in the walls of the unit, the coolant stream can reach electronic modules and can also reach the inside of said modules through an opening in the housing. Other openings in the housing of the unit link said channels with the outer space. Any of the openings can be made while ensuring air-tightness.

EFFECT: providing an electronic unit with a new functional capability of cooling electronic modules by directing a coolant stream into said modules when installed in the unit, as well as improving efficiency of removing heat released by radio-electronic equipment components while saving the coolant.

3 cl, 9 dwg

Description

The invention relates to electronic computer technology and can be used in the construction of electronic equipment blocks (REA), in which replaceable electronic modules can be installed, and operating in conditions of increased heat release by REA elements, significant mechanical loads, as well as aggressive weather and climate factors during military operation.

Known radio-electronic unit (RF patent No. 2231236), in which the printed circuit boards are mounted on heat sink plates and frames connected in a package. Thus, the case of this unit is formed from the frames of the Г- and / or T-shaped profile, along the perimeter of which there are grooves and protrusions that provide a labyrinth connection. The disadvantage of this device is the lack of functionality to direct the flow of coolant inside the electronic modules installed in it, with the aim of cooling them. It does not provide heat dissipation efficiency sufficient for the operation of electro-radio elements with a high level of dissipated power. This is due to the fact that the heat-conducting plates and frames on which the printed circuit boards are fixed, by virtue of their shape, introduce a sufficiently large thermal resistance along the path of heat propagation from the heat-generating elements to the outer surface of the block. In addition, the described unit has a large number of connections on the outer surface of the housing requiring sealing.

The closest in technical essence and the achieved effect to the proposed invention is the invention according to the patent of the Russian Federation No. 2323712. The basis of the design of this device is a sealed enclosure containing a cooling system. This system is formed by the inner and outer walls of the casing, in the space between which there is a flow of air pumped under pressure through openings in the rear wall of the casing and out through the openings of the side walls. As in the case of the prototype, the disadvantage of this design is the lack of functionality for cooling electronic modules by directing the flow of coolant inside these modules, if installed in the unit. With this solution, when the coolant flow is in contact only with the peripheral parts of the design of the electronic device, it is impossible to efficiently remove heat from the heat-loaded elements due to the presence of high thermal resistance in the area between the heat source and the cooling coolant.

The technical result of the present invention is to provide the electronic unit with a new functionality for cooling electronic modules having a structure suitable for such a cooling method by directing the flow of coolant inside these modules if installed in the unit. Another technical result is to increase the efficiency of heat removal from the above electronic modules due to the fact that the present invention allows the supply of heat carrier flux directly to heat sources. This solution allows you to: minimize or completely eliminate the ingress of coolant into the space between the electronic modules, which ensures savings of coolant, as well as a high level of dust protection of the device; exclude the presence of holes that violate the tightness of the electronic unit, which makes it possible to fulfill the most stringent requirements for electromagnetic compatibility; to exclude direct contact of the heat carrier, as well as the substances and particles contained in it, with the surfaces of printed circuit boards and electro-radio elements inside the electronic unit, which leads to increased reliability of the device and the expansion of its scope.

This technical result is achieved by the fact that in the electronic unit, consisting of a housing having openings for supplying / discharging the heat carrier, at least one channel passing through at least one wall, the bottom or the cover of the electronic unit, is additionally included for the formation of a coolant flow directed into the electronic modules having a design suitable for such a cooling method, if installed in this unit. The holes of the electronic unit can be made to ensure tightness. In the case of incomplete filling of this unit with modules, unused openings on the unit walls can be closed using sealed plugs or other means.

The following abbreviations are adopted in the text:

- channel designed to form a coolant flow - channel;

- a channel designed to form a coolant flow inside an electronic module - a channel of an electronic module;

- space external to the electronic unit - external space.

The invention is illustrated by drawings, given as an example and not bearing any restrictive nature.

Figures 1 and 2 show an electronic unit without a cover together with electronic modules installed in it;

figure 3 and 4 - the electronic unit without a cover together with the holes on its walls and corresponding holes of the electronic module, used to combine the channel of the electronic module with external space or with a channel included in the outer wall of the electronic block;

figure 5 - the electronic unit and its outer wall without an outer partition, and also shows the hole connecting the outer space with the channel included in this wall;

Fig.6 is a schematic illustration of an electronic unit in a plan view together with electronic modules installed in it (shown by large shading), having one external wall with a channel included in it. The movement of the coolant flow is indicated by arrows;

7 is a schematic image of an electronic unit in a plan view together with electronic modules installed in it (shown by large shading), having more than one external wall with channels included in them. The movement of the coolant flow is indicated by arrows;

on Fig and 9 is a schematic image of an electronic unit in a plan view together with electronic modules installed in it (shown in large shading), which, in addition to the external walls, also has an internal wall with a channel included in it. The movement of the coolant flow is indicated by arrows;

where 1 and 10 are holes located on the outer walls 3 and 5 of the electronic unit, combining the channels 14 and 15 with the rest of the internal space of the electronic unit. These holes serve to connect the channels 14 and 15 to the channel of the electronic module by combining and docking these holes with the corresponding holes 2 and 9 located on the electronic module, 2 and 9 - holes located on the electronic module and used to connect the channels 14, 15 and 16 with the channel of this module, 3 and 5 are the external walls of the electronic unit with the channels 14 and 15 included in them, 4 and 6 are the walls of the electronic unit that do not have channels included in them, 7 and 11 are the protrusions in the areas of holes 1 and 10 on the walls of the electronic unit, designed to ensure the coupling of these holes with the corresponding holes 2 and 9 located on the electronic modules, 8 - electronic modules having channels designed to form a coolant flow inside these modules, 12, 13 and 20 - holes on the walls of the electronic unit, used to the flow of coolant from the external space inside the unit or to remove the flow of coolant from the electronic unit to the outside, 14 and 15 are the channels included in the outer walls 3 and 5 of the electronic unit, intended started to form the coolant flow, 16 — channel included in the inner wall 17 of the electronic block, 17 — inner wall of the electronic block, 18 and 19 — openings located on the inner wall 17 of the electronic block, combining channel 16 with the rest of the internal space of the electronic block. These holes serve to connect the above channel 16 with the channel of the electronic module by combining and docking these holes with their corresponding holes 2 and 9 located on the electronic module.

The design of the electronic unit is as follows. The wall 3 of this unit, to which, if installed in the unit, adjoins one or more electronic modules 8, is made with the channel 14 included in it, as well as with holes 10 and 13. The wall 3 is mounted in the electronic unit so that when installing and fixing the electronic modules 8 inside this unit, the above-mentioned channel 14 was connected to the channels of the modules 8. This connection is achieved by joining the holes 10 located on the wall 3 of the electronic unit with the holes 2 located on the module 8 x e.

Since with the above installation of electronic modules 8 they are adjacent to at least one more wall 5 of the electronic unit, the second of the walls can also be made with a channel 15 included in it, as in FIG. 7. In this case, wall 5 is made with holes 1 and 12, made according to the same principle as in wall 3. Like wall 3, wall 5 is mounted in the electronic unit so that when installing and fixing electronic modules 8 inside this unit, the connection the aforementioned channel 15 with channels of the modules 8. This connection is achieved by docking the holes 1 located on the wall 5 of the electronic unit with the holes 9 located on the electronic modules 8.

A variant of the design of the electronic unit is possible, when one of its walls, to which the electronic modules 8 adjoin when installed in the electronic unit, for example, wall 5, does not have a channel included in it, for example, as shown in Fig.6. In this case, this wall will have holes 1. At the same time, wall 5 is mounted in the electronic unit so that when installing and fixing electronic modules 8 inside this unit, the channels of the modules are connected to the external space. This connection is achieved by docking holes 1 located on the wall 5 of the electronic unit with holes 9 located on the electronic modules 8. Otherwise, this embodiment of the electronic unit is similar to the above option.

A variant of the design of the electronic unit is possible, in addition to the above-described walls 3 and 5, there is an inner wall 17, which, like the wall 3, is made with the channel 16 included in it, as well as with the holes 18 and 19. At the same time, the holes connecting the channel 16 with external space, wall 17 does not have, as shown in FIG. Such a wall is mounted in the electronic unit so that when installing and fixing the electronic modules 8 inside this unit, the aforementioned channel 16 is connected to the channels of the modules 8. This connection is achieved by joining the holes 18 and 19 located on the wall 17 of the electronic unit with holes 2 and 9 located on the electronic modules 8. Otherwise, such an embodiment of the electronic unit is similar to the above-described embodiment.

A variant of the construction of the electronic unit is possible, similar to the one just described and characterized in that the wall 17 of the electronic unit, in addition to the holes 18 and 19, has an opening 20 connecting the channel 16 with the external space, as shown in Fig. 9.

Any of the aforementioned openings can be made to ensure tightness. This means that for sealing compounds with electronic modules 8 on the surfaces of the walls 5, 3 and 17 at the locations of the holes 1, 10, 18 and 19, various structural elements can be made, as well as various parts, devices and means (for example: pipe , rubber gasket, sealant, etc.). Holes 12, 13 and 20 are designed to connect the above-mentioned channels with the external space, therefore, similar sealing methods can be used at the locations of such holes on the surface of the walls of the electronic unit.

Depending on the design, the electronic unit may contain any number of the above walls. The number of channels described above, as well as the number of holes described above in each of the walls of the electronic unit, can be any. The bottom and / or cover of the electronic unit may have any of the structural and other properties that describe the walls of this unit and are given above.

The principle of operation of the device will consider the example of Fig.7. The coolant flow under pressure enters from the external source into the electronic unit, namely, into the channel 14 through the opening 13. Then, passing through this channel, the coolant flow reaches the openings 10, overcoming which, it enters the electronic modules 8. Passing through the channels of the electronic modules 8, this flow reaches the holes 1. Overcoming the holes 1, the coolant flow enters the channel 15, passing through which, leaves the electronic unit through the hole 12.

In the case when all the seats intended for installation of the electronic modules 8 are used in the electronic unit, special plugs and / or other means can be used to seal the coolant through these holes into the tightly closed unused openings 1, 10, 18 or 19 the space between the modules.

The electronic unit in comparison with the prototype allows you to:

- cool electronic modules having a structure suitable for such a cooling method by directing the flow of coolant inside these modules if they are installed in the unit;

- to carry out the removal of the coolant flow from electronic modules containing channels designed to form this flow, if these modules are installed in the unit;

- to exclude hit of the heat carrier flow into the space between the modules inside the electronic unit during operation of the cooling system;

- reduce the flow of coolant used to cool the electronic unit, due to the target direction of its flow only to certain places in the structure;

- to increase the resistance of the device to external weather and climate factors due to the fact that the walls of the channels designed to form the flow of the heat carrier exclude direct contact of the radio elements, the printed circuit board and other structural elements with the heat carrier and the particles and substances contained therein;

- to increase the electromagnetic compatibility of the device with other products due to the lack of need for holes that violate the integrity and shielding properties of the electronic housing.

Claims (3)

1. The electronic unit, consisting of a housing having holes for supplying / discharging coolant, characterized in that its design further includes at least one channel passing through at least one wall, bottom or cover of the electronic unit, designed to form a coolant flow directed into the electronic modules, if installed in this unit. 2. The electronic unit according to claim 1, characterized in that the holes connecting the channels to both the external and internal space of the unit are made to ensure tightness. 3. The electronic unit according to claim 1 or 2, characterized in that in case of incomplete filling of the given unit with electronic modules, unused openings of the unit are closed using sealed plugs and / or other means.

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