RU2491662C1 - Air-cooled device housing - Google Patents

Abstract

FIELD: radio engineering, communication.SUBSTANCE: air-cooled device housing has a cooling system formed by an inlet opening and outlet openings, a bottom cover, inner and outer left-side, right-side and rear walls, as well as a double top cover, forming closed inner and outer loops and adapted to allow passage of a cold air stream between the inner and outer walls, wherein lateral inner walls are in form of heat sinks. The outlet openings are made on the front panel and the inner top cover is in form of a heat sink. Double partition walls are mounted inside the housing such that a cooling air stream can pass between them and the partition walls are mounted so as to form at least two main compartments and one additional compartment. Inside each main compartment there is at least one functionally assembled heat-removing element which is made in form of an radioelectronic module with heat removal, mounted by heat removal contact surfaces on the inner lateral wall of the housing or partition wall and mounted tightly to inner surfaces thereof, and by the front contact surface to the surface of the inner top cover of the housing. At least one radioelectronic module is mounted in the additional compartment.EFFECT: high efficiency of cooling the housing and radioelectronic equipment modules.7 cl, 5 dwg

Description

The invention relates to the field of radio equipment and can be used in the design of electronic equipment cases.

The housing of the radio-electronic unit is known from the prior art (copyright certificate No. 1725414, IPC: H05K 5/00, 04/07/1992). The housing of the electronic unit is made in the form of upper and lower sections of a box-shaped, interconnected along a diagonal plane. The bases of the sections and panels are equipped with shelves placed at an angle to them. The shelves are located one above the other and are detachably connected. The mating side walls are equipped with curly flanges of a U-shape. To remove heat in the side walls of the upper section, blinds are made.

The disadvantage of this device is the insufficiently effective heat removal from the radioelements and the device body.

A known cooling system of the housing (application No. 2001113266, published 2003.06.10, IPC: H05K 7/20). The cooling system of the housing, in which the heat-generating element is located, has an inlet through which air enters from the outside, an outlet through which air flows out of the housing, a radiator with a heat-dissipating fin, which is partially or wholly located inside the housing near the inlet hole, and a device for transferring heat, which is released by a working heat-generating element, into a radiator with a heat-dissipating fin. In this case, the heat that is emitted by the working heat-generating element is transferred to the radiator with a heat-dissipating fin device for heat transfer, and the air that enters the casing through the inlet first passes through the heat-dissipating fin of the radiator, taking heat from it that is released by the working a heat-generating element, and then after heating in the radiator it is released through the outlet from the housing to the outside, while cooling the housing itself.

The disadvantages of this device include the insufficiently efficient heat removal from the radioelements and the device body.

The closest in technical essence and the achieved results to the proposed technical solution is the cooling system of the case (Patent No. 2233712, published June 20, 2008, IPC: H05K 7/20). The cooling system of the housing of the device with the heat-generating element enclosed in it comprises a cooling system of the housing with an inlet and outlet openings. The body cooling system is formed by the inner and outer left side, right side, front and rear walls, forming a closed loop and configured to pass between the inner and outer walls of the cooling air flow, as well as a double top cover. Moreover, the inner side walls are made in the form of radiators. The inlet is located on the rear wall, and the outlet is located on the outer side walls and the top cover on the side of the front wall of the housing.

Since there are fuel elements inside the case, during the operation of the device the internal walls of the case are heated. Heat removal in the housing of the device is as follows. Through the inlet in the rear wall of the housing and the cooling system of the housing, cooling the internal rear wall, the air is distributed into three flows and enters the space formed by the inner and outer upper covers, as well as the space formed by the inner and outer left and right side and front walls.

The disadvantages of this solution include insufficiently effective heat removal from the inner front wall, since it is located in the center of the housing and it is cooled through the side walls, which have outlet openings, which significantly reduces the amount of air passing through the front wall.

The technical result, which is achieved by the claimed technical solution, is to increase the cooling efficiency of the housing and modules of electronic equipment by increasing the cooling area and reducing the distance from radio and radio products (ERE) to the cooling surfaces.

The technical result is achieved in that the air-cooled device case contains a body cooling system formed by an inlet, outlet openings, a lower cover, internal and external left side, right side, rear walls, and also a double upper cover, forming closed internal and external circuits and made with the possibility of passage between the inner and outer walls of the cooling air stream, and the side inner walls are made in the form of radiators. In this case, the outlet openings are made on the front panel, the inner top cover is made in the form of a radiator. Moreover, double partitions are installed inside the case with the possibility of passing between them a cooling air flow, installed with the possibility of forming at least two main and one additional compartments. Moreover, at least one functionally arranged fuel element is arranged inside each main compartment, made in the form of a radio-electronic module with a heat sink, mounted by the contact surfaces of the heat sink on the inner side wall of the housing or partition, and fixed with the possibility of tight fit to their internal surfaces, and the end contact surface - to the surface of the inner upper housing cover.

In the case of an air-cooled device, the inlet can be made on the back wall or on the bottom cover.

At least one radio-electronic module can be installed in the air-cooled device case in an additional compartment.

At least one radio-electronic module with a heat sink, installed by the contact surfaces of the heat sink on the inner side wall of the housing or the partition and fixed with the possibility of its snug fit to their internal surfaces, and the end contact surface, can be placed in the air-cooled device case in the additional compartment - to the surface of the inner upper housing cover.

In the case of the device with air cooling, one of the walls of the double partition can be made in the form of a radiator.

In the case of the device with air cooling, both walls of the double partition can be made in the form of radiators.

In the case of the device with air cooling, the inner back wall can be made in the form of a radiator.

The invention is illustrated by drawings, where:

Figure 1 is a front view of the housing of the device with air cooling;

Figure 2 is a rear view of the housing of the device with air cooling;

Figure 3 is a top view of the cooling channels;

Figure 4 is a side view of the cooling channels;

5 is a radio-electronic module (printed circuit board with ERI installed on it).

An example of using an air-cooled instrument case can be a case for an on-board computer complex (BVK) with three main and one additional compartments, on the front panel of which connectors are installed. In the main compartments, digital heat-loaded electronic modules with heat sinks are installed, and in the additional compartment, for example, switching power supplies made in the form of electronic modules are installed. Communication between digital electronic modules and switching power supplies is via a multilayer patch backplane installed on the bottom cover side.

The housing of the device with air cooling 1 (Figure 1-Figure 4) contains heat-generating elements 2. The heat-generating element may be, for example, a radio-electronic module (Figure 5), made in the form of a printed circuit board with installed on it radio and heat sink.

The housing of the device 1 contains a cooling system 3, including an inlet 4, an air distribution system 5, a right side cooling channel 6, a left side cooling channel 7, an inner right cooling channel 8, an inner left cooling channel 9, a front right cooling channel 10, a front left cooling channel 11, upper cooling channel 12 and outlet openings 13, right main compartment 14, left main compartment 15, central main compartment 16, additional compartment 17. The inlet 4 is located, for example, on the outer rear wall 18 The air distribution system 5 is formed by a cavity bounded by an inner rear wall 19 and an outer rear wall 18, an inner upper cover 20, an outer upper cover 21, a lower cover 22. The left side cooling channel 7 is formed by a left inner side wall 23, a left outer side wall 24 and the left row of outlet openings 13. The right side cooling channel 6 is formed by the right inner side wall 25, the right outer side wall 26 by the right row of outlet openings 13. The inner right cooling channel 8 is formed by the right oh internal partition 27, left inner partition 28. The inner left cooling channel 9 is formed by the right inner partition 29, the left inner partition 30. The front right cooling channel 10 is formed by the front right inner partition 31, the front right outer partition 32. The front left cooling channel 11 is formed the front left inner partition 33, the front left outer partition 34. The upper cooling channel 12 is formed by the inner upper cover 20, the outer upper cover 21, the upper row you one holes 13. Moreover, the inner top cover 20, the left inner side wall 23, the inner right side wall 25, the right inner partition 27, the left inner partition 28, the right inner partition 29, the left inner partition 30, the front left inner partition 33, the front right the inner partition 31 is made in the form of radiators.

Inside the body of the air-cooled device 1, the main right compartment 14, the main left compartment 15, the main central compartment 16, and the additional compartment 17 are located. Moreover, the main left compartment 15 is separated from the main central compartment 16 by the internal left cooling channel 9, and the main right compartment 14 is separated from the main central compartment 16 by the internal right cooling channel 8. The additional compartment 17 is separated from the main left compartment 15 by the internal left cooling channel 9 and the front left cooling channel 11, and from the main Vågå compartment 14 - internal cooling channel 8, the right front and right cooling channel 10, and the main central compartment - middle partition 36.

The main left compartment 15 is formed between the left inner side wall 23, the left inner partition 30, the front left inner partition 33, the inner back wall 19, the inner top cover 20 and the multilayer patch backplane printed circuit board 37 located in the lower part of the housing parallel to the surface of the lower cover 22 The main right compartment 14 is formed between the right inner side wall 25, the right inner partition 27, the front right inner partition 31, the inner back wall 19, the inner its upper cover 20 and a multilayer patch backplane 37. The main central compartment 16 is formed between the right inner partition 29, the left inner partition 28, the inner back wall 19, the inner top cover 20, the middle partition 36 and the multilayer patch backplane 37. Additional the compartment 17 is formed between the right inner partition 29, the left inner partition 28, the front panel 35, the front right outer partition 32, the front left outer partition a small pipe 34, an inner top cover 20, a middle partition 36 and a multilayer patch backplane 37.

Radio-electronic modules (Figure 5) for a given case of an air-cooled device 1, mounted and fixed inside its main compartments, are configured to conduct heat removal from heat-loaded ERI to the case walls. The radio-electronic module consists of a printed circuit board 38 with installed ERI, a heat sink 39, a wedge mechanism 40, and extractor handles 41. A heat sink 39 is used to remove heat from the ERI to the walls of the casing and the partition wall, extractor handles 41 are used to remove the module from the device casing 1, and the wedge mechanism 40 - for fixing the electronic module in the housing of the device 1 with the possibility of a snug fit of the heat sink 39 to the walls and partitions of the housing 1. The most heat-loaded ERI are placed on the printed circuit board 38 from the side of the heat sink 39, directly contacting with its surfaces. To reduce thermal resistance, contacting is carried out through materials of the thermal interface (for example, paste KPT-8 or others). To transfer heat to the housing of the device 1 on the heat sink 39, contact surfaces 42, 43, 44, 45 are provided.

In order to increase the cooling area, increase the area of heat transfer from the electronic module to the inner walls 19, 23, 25 and the partitions 27, 28, 29, 30, 33 of the inner upper cover 20 of the housing and reduce heat flux on the heat sink 39 of the electronic module, contact surfaces 41 are provided , 42, 43, 44, which leads to a decrease in the temperature gradient from the heat-loaded ERI to the inner walls 19, 23, 25, partitions 27, 28, 29, 30, 33 and the inner top cover 20. To effectively use the contact surface 44 of the heat sink 39 from the device 1 it is divided into four compartments 14, 15, 16, 17, and cooling channels 8, 9, 10, 11 are organized between the compartments. Functionally arranged heat-generating elements in the form of radio-electronic modules with heat sinks 39 inside each main compartment are installed and fixed with the possibility of tight the contact surfaces 42, 43, 44 of the heat sinks 39 to the inner walls of the housing 19, 23, 25 and the partitions 27, 28, 29, 30, 33.

For effective use of the end contact surface 45, it is pressed against the surface of the inner top cover 20. All this allows us to ensure the thermal regime of the EIS installed on the electronic modules, since the housing of the device 1 contains a cooling system 3, and the cooling system is organized as a blowing of the outer walls of the housing 1 (right side cooling channel 6, left side cooling channel 7, upper cooling channel 12) and between compartments (internal right cooling channel 8, internal left cooling channel Nia 9, front right cooling channel 10, front left cooling channel 11).

Radio-electronic modules 2 are installed in the housing of the device 1 from the side of the inner upper cover 20 and secured by tightening the screws of the wedge mechanism 40, which ensures tight contact of the contact surfaces 42, 43, 44 of the heat sink 39 to the inner walls of the housing 19, 23, 25 and partitions 27, 28, 29, 30, 33, and after installing the inner top cover 20, a tight fit of the contact surfaces 45 of the electronic modules to this cover is ensured.

During operation of the BWC, the ERI is heated, the heat from which is supplied to the heat sink 39, and since the heat sink 39 has contact surfaces 42, 43, 44, 45 that fit snugly against the inner walls 19, 23, 25, partitions 27, 28, 29, 30, 33 and the inner top cover 20, then heat is transferred through it to the inner walls 19, 23, 25, the partitions 27, 28, 29, 30, 33 and the inner top cover 20 and they are heated. Heat removal from the heated walls 19, 23, 25, partitions 27, 28, 29, 30, 33 and the inner top cover 20 (Figs. 3, 4) is as follows. Through the inlet 4 on the outer rear wall 18 of the device body 1, cold air under pressure enters the air distribution system 5, where, cooling the inner rear wall 19, the air is distributed into five streams. Then it enters the right side cooling channel 6, the left side cooling channel 7, the inner right cooling channel 8, the inner left cooling channel 9 and the upper cooling channel 12. In the left side cooling channel 7, the air stream cools the left inner side wall 23, in the right side cooling channel 6, the air stream cools the right inner side wall 25, in the inner right cooling channel 8, the air stream cools the right inner partition 27 and the left inner partition 28 and then goes to the front equal channel 10, where it cools the front right inner partition 31 and the front right outer partition 32 and then enters the right side cooling channel 6. In the inner left cooling channel 9, the air stream cools the right inner partition 29, the left inner partition 30 and then goes to the front the right channel 11, where it cools the front right inner partition 33 and the front right outer partition 34 and then enters the left side cooling channel 7. In the upper cooling channel 12, the air cools inside the upper upper cover 20. Heated air from the left side cooling channel 7, from the right side cooling channel 6 and from the upper cooling channel 12 through the outlet openings 13 located on the front panel 35, enters the external environment.

The proposed design of the device’s case allows to increase the cooling efficiency of radio-electronic modules due to the formation of branched cooling channels inside the case (between compartments), by increasing the number of heat transfer surfaces from radio-electronic modules with heat sinks to the inner walls, partitions, top cover and their effective use (electronic modules in each compartment deployed in opposite directions), which leads to the effective use of cooled surfaces and to zheniyu temperature gradient from ERI to the inner walls of the housing to increase the heat transfer coefficient due to the different channels aligned hydraulic resistance (length of the air channel are equal) and organizing them in the air stream, thus cooling the air stream misses inside compartments.

Claims (7)

1. The housing of the device is air-cooled, comprising a cooling system of the housing formed by the inlet, outlet, bottom cover, inner and outer left side, right side, rear walls, as well as a double upper cover, forming closed internal and external circuits and made with the possibility of passage between the inner and outer walls of the cooling air stream, and the side inner walls are made in the form of radiators, characterized in that the outlet openings are made on faces th panel, the inner top cover is made in the form of a radiator, while inside the body are placed with the possibility of passing between them a cooling air flow double partitions installed with the possibility of formation of at least two main and one additional compartments, and inside each main compartment is placed, at least one functionally arranged fuel element, made in the form of a radio-electronic module with a heat sink, mounted by the contact surfaces of the heat sink on the inside the front side wall of the housing or the partition and fixed with the possibility of tight fit to their inner surfaces, and the end contact surface to the surface of the inner upper cover of the housing. 2. The case of the device with air cooling according to claim 1, characterized in that the inlet is made on the rear wall or on the bottom cover. 3. The case of the device with air cooling according to claim 1, characterized in that at least one electronic module is installed in the additional compartment. 4. The case of the device with air cooling according to claim 1, characterized in that at least one radio-electronic module with a heat sink is installed in the additional compartment, installed by the contact surfaces of the heat sink on the inner side wall of the housing or the partition and fixed with the possibility of tight fit their inner surfaces, and the end contact surface to the surface of the inner upper housing cover. 5. The housing of the device with air cooling according to claim 1, characterized in that one of the walls of the double partition is made in the form of a radiator. 6. The housing of the device with air cooling according to claim 1, characterized in that both walls of the double partition are made in the form of radiators. 7. The housing of the device with air cooling according to claim 1, characterized in that the inner rear wall is made in the form of a radiator.

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