RU2805978C1 - Thermoelectric device for heat removal from rea elements - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: thermoelectric device for removing heat from elements of radio electronic apparatus (REA), used to provide the required temperature conditions of REA. In the main heat exchanger, which is designed as an evaporative heat removal, non-through cylindrical holes are made in the vertical direction in-line, having a depth equal to 3/4 of the height of the main heat exchanger in its center, while on the lower surface, using fasteners, a fan unit is installed, powered from a source of electrical energy, operating to blow air into cylindrical holes. The thermoelectric device also contains an additional heat exchanger, made in the form of a hollow all-metal container filled with a melting working substance with high heat capacity, and also a temperature sensor is installed in contact with the REA, the output of which is electrically connected to the input of the temperature controller, the output of the latter is electrically connected to the main and additional sections of TEB.

EFFECT: increasing the efficiency of heat removal from the REA element by increasing the intensity of heat removal from the heat-generating junctions of the thermoelectric battery (TEB) sections through the main heat exchanger by organizing forced air heat removal from it.

1 cl, 1 dwg

Description

The invention relates to electronics and can be used to ensure the required temperature conditions of electronic equipment (REA) elements.

The prototype of the proposed device is the device described in [1]. The device contains a thermoelectric battery (TEB), electrically connected to the output of the temperature controller, the input of which is connected to a temperature sensor in contact with the fuel element of the REA, located in the recess formed by the design of the TEB, the main heat exchanger, which is in thermal contact with the fuel junctions of the TEB and additional heat exchanger. The fuel cell is divided into a main section and two additional sections, electrically connected in series and made from thermoelements identical in their geometric, electrical and thermophysical characteristics. The main TEB section is located in the center of the main heat exchanger, and additional TEB sections are located at the edges on the protrusions of the main heat exchanger, the area of which corresponds to the area of the additional TEB sections. The fuel element of the REA is placed in the resulting recess, ensuring thermal contact with the heat-absorbing junctions of the main section of the thermopile, an additional heat exchanger made in the form of a hollow all-metal container filled with a consumable working substance with a high heat of fusion and melting temperature is in contact with the heat-absorbing junctions of additional sections of the TEB and the fuel element of the REA. , lying in the range of 35-55°C. The main heat exchanger is designed as an evaporative heat sink.

The disadvantage of the device is the low intensity of heat removal from the fuel junctions of the TEB sections through the main heat exchanger, which implements natural air heat removal, characterized by a low heat transfer coefficient, which reduces the efficiency of heat removal from the RE element.

The purpose of the invention is to increase the efficiency of heat removal from the electronic element by increasing the intensity of heat removal from the fuel junctions of the fuel cell sections through the main heat exchanger by organizing forced air heat removal from it.

The goal is achieved by the fact that in the main heat exchanger, non-through cylindrical holes are made in the vertical direction in a corridor order, having a depth equal to 3/4 of the height of the main heat exchanger in its center. A fan unit is installed on the lower surface using fasteners, powered by an electrical energy source, and working to blow air into the cylindrical holes.

The design of the device is shown in Fig. 1. The device contains a main section of fuel cell 1 located in the center and two additional sections of fuel cell 2 located at the edges. The main 1 and additional 2 sections of the fuel cell, electrically connected in series, consist of thermoelements identical in their geometric, electrical and thermophysical characteristics. The main 1 and additional 2 sections of the fuel cell with their heat-releasing junctions are in thermal contact with the main heat exchanger 3, made in the form of an evaporative heat sink, with protrusions along the edges, the area of which corresponds to the area of the additional sections of the fuel cell 2. Main 1, additional 2 sections of the fuel cell and the main heat exchanger 3 form a structure that has a recess in its central part, into which the heat-generating element REA 4 is installed to ensure thermal contact with the heat-absorbing junctions of the main section of TEB 1. An additional heat exchanger 5, made in the form of a hollow an all-metal container filled with a melting working substance with a high heat of fusion and a melting point in the range of 35-55°C. A temperature sensor 6 is brought into direct contact with the fuel element REA 4, the output of which is electrically connected to the input of the temperature controller 7, the output of the latter is electrically connected to the main 1 and additional 2 sections of the fuel cell.

In the main heat exchanger 3, non-through cylindrical holes 8 are made in the vertical direction in a corridor order, having a depth equal to 3/4 of the height of the main heat exchanger in its center. On the lower surface, using fasteners 9, a fan unit 10 is installed, powered by an electrical energy source 11, which blows air into the cylindrical holes.

The device works as follows.

Since the temperature regime for effective operation of the fuel element REA 4 is higher than the ambient temperature, during such operation the heat flow is always directed from the fuel element REA 4 through heat exchangers 3 and 5 into the environment. The main 1 and additional 2 sections of the fuel cell, being included in this process, intensify heat transfer. Part of the heat from the fuel element REA 4 is transferred to the heat-absorbing junctions of the main section of the TEB 1 and through the fuel junctions to the main heat exchanger 3, which dissipates it into the environment. The other part is transferred to an additional heat exchanger 5, the heat from which is dissipated both directly into the environment and through the heat-absorbing and heat-releasing junctions of additional sections of the fuel cell 2, as well as the main heat exchanger 3.

Since there is no need to cool the fuel element REA 4 below the ambient temperature, the temperature controller 7, in accordance with the readings of the sensor 6 and the operating temperature value set on the scale of the temperature controller 7, turns on and off, if necessary, the main 1 and additional 2 sections of the fuel cell, automatically maintaining the temperature fuel element REA 4 in a given range.

The fan unit 10, fixed with the help of fasteners 9, powered by an electrical energy source 11, operating to blow air into the cylindrical holes 8, implements forced heat removal from the main heat exchanger 3, in which the heat transfer coefficient is significantly higher than in the case of natural air heat exchange. Due to the higher intensity of heat removal from the main heat exchanger 3, the intensity of heat removal from the fuel junctions of TEB sections 1 and 2 also increases, which in turn increases the efficiency of heat removal from the REA element 4.

Literature

1. RF Patent No. 2790357, Thermoelectric device for heat removal from RE elements / Ismailov T.A., Evdulov O.V., Gabitov I.A., Ibragimova A.M. // BI No. 5, 2023.

Claims (1)

A thermoelectric device for removing heat from elements of a REA, containing a thermoelectric battery (TEB), electrically connected to the output of a temperature controller, the input of which is connected to a temperature sensor in contact with the fuel element of the REA, located in a recess formed by the design of the TEB, a main heat exchanger located in thermal contact with the heat-releasing junctions of the thermopile, and an additional heat exchanger, wherein the thermopile is divided into the main and two additional sections, connected electrically in series and made of thermoelements identical in their geometric, electrical and thermophysical characteristics, and the main section of the fuel thermopile is located in the center of the main heat exchanger, and additional fuel cell sections are located at the edges on the protrusions of the main heat exchanger, the area of which corresponds to the area of the additional fuel cell sections, while the REA fuel element is placed in the resulting recess to ensure thermal contact with the heat-absorbing junctions of the main section of the fuel cell, with the heat-absorbing junctions of additional fuel cell sections and the REA fuel element contacts an additional heat exchanger, made in the form of a hollow all-metal container filled with a melting working substance with a high heat of fusion and a melting point lying in the range of 35-55 ° C, while the main heat exchanger is made in the form of an evaporative heat sink, characterized in that in the main heat exchanger in in the vertical direction, non-through cylindrical holes are made in a corridor order, having a depth equal to 3/4 of the height of the main heat exchanger in its center, and on the lower surface, using fasteners, a fan unit is installed, powered from a source of electrical energy, working to blow air into the cylindrical holes.