RU90643U1 - RADIO ELECTRONIC UNIT - Google Patents

Abstract

A radio electronic unit containing a housing, the inner cavity of which is divided by a partition into two compartments, in the first of which are the control units of the device, and in the second are two heat exchangers installed along its opposite sides, each of the heat exchangers consisting of three identical radiators with fins forming internal longitudinal channels intended for circulation of the refrigerant pumped by the fans, the fans being built into the openings of the casing combined with the heat exchanger inlets kov, on the outer surfaces of which are placed electronic elements of the device that require the most intensive cooling.

Description

The utility model relates to electrical engineering and can be used in the design of secondary power supplies for a wide range of purposes, for example, voltage converters designed for aircraft.

Known electronic unit containing a housing with a mounting plate inside it, a partition dividing the housing into two compartments, a heat exchanger and two fans (1). One of the fans organizes the circulation of air inside the case through the slots between the mounting plate and the surface of the case, and a heat exchanger cooled by the air drawn in from the outside helps to reduce the temperature of the circulating air. The known device is characterized by low cooling efficiency.

The device closest to the utility model is a radio-electronic unit containing a housing, the internal cavity of which is divided by a partition into two compartments, in the first of which are the control units of the device, in the second - two heat exchangers. Each of the heat exchangers consists of three radiators installed along its opposite sides. Each of the radiators is made in the form of a monolithic unit, in the upper outer surface of which are drilled recesses designed to accommodate electronic elements that require intensive cooling (2).

A disadvantage of the known device is the poor mass and dimensions, low reliability and low working life (due to the insufficient cooling efficiency of electronic elements and the massiveness of the heat exchangers).

The technical result that can be achieved using the utility model is to improve the overall dimensions, increase the reliability and increase the working life by increasing the efficiency of cooling electronic components and reducing the mass of heat exchangers.

The technical result is achieved in that in a radio-electronic unit containing a housing, the internal cavity of which is divided by a partition into two compartments, in the first of which are the control units of the device, and in the second - two heat exchangers installed along its opposite sides (2), each of heat exchangers consists of three identical radiators with fins forming internal longitudinal channels intended for circulation of the refrigerant pumped by the fans, the fans being built into the openings of the housing whiskers, combined with the inlets of heat exchangers, on the outer surfaces of which electronic components of the device are located, requiring the most intensive cooling.

The drawing shows the design of the device (top view of the cavity of the housing).

The electronic unit contains a housing 1, the internal cavity of which is divided by a partition into two compartments. In the first of the compartments, the control units of the device are located, and in the second there are two heat exchangers 2 installed along its opposite sides. Each of the heat exchangers 2 consists of three identical flat radiators 3 with fins forming internal longitudinal channels designed to pass the refrigerant pumped by the fans 4. Fans 4 are built into the openings of the casing, combined with the inlets of the heat exchangers. On the outer surfaces of the heat exchangers 2 there are electronic elements of the device that require the most intensive cooling.

The device operates as follows.

When the unit is turned on, two fans 4 start working, which inject refrigerant (air) into the cavities of the internal channels of the radiators 3, causing intense heat transfer from the electronic components attached to their outer surface. The temperature of the outer surface of the radiators 3 is lower than the temperature in the compartments, therefore, when air circulates in the cavity of the housing 1, it cools.

The implementation of heat exchangers of three flat radiators 3 with internal channels intended for circulation of refrigerant (rather than monolithic bulky blocks), allowed to increase the cooling efficiency of electronic elements of the device, improve mass and dimensions and increase the operating life of the device. The placement of radiators inside the enclosure isolated from the external environment made it possible to increase the effective surface participating in the heat exchange between the refrigerant and the cooled radioelements, and thereby reduce the temperature of the refrigerant circulating in the enclosure, while reducing the dimensions of the enclosure.

Tests of prototypes showed that the most optimal for effective cooling is the implementation of heat exchangers of three radiators with fins.

Adequate working life and high reliability, provided by high cooling efficiency of radioelements of elements (with optimal mass and dimensions), make it possible to attribute the utility model to the most promising one when developing power supply designs used, for example, in aircraft.

Sources of information taken into account when compiling the description:

SU 1691986 A1, H05K 7/20, 1989

Power supply device BVRK-9 MT, 8E3.222.023. TU, 2006

Claims (1)

A radio electronic unit containing a housing, the inner cavity of which is divided by a partition into two compartments, in the first of which are the control units of the device, and in the second are two heat exchangers installed along its opposite sides, each of the heat exchangers consisting of three identical radiators with fins forming internal longitudinal channels intended for circulation of the refrigerant pumped by the fans, the fans being built into the openings of the casing combined with the heat exchanger inlets kov, on the outer surfaces of which are placed electronic elements of the device that require the most intensive cooling.