RU2796627C1 - Thermoelectric device for heat removal from electronic equipment elements - Google Patents

Abstract

FIELD: electronics.

SUBSTANCE: invention can be used to provide the required temperature conditions for elements of electronic equipment (EE). The main and additional sections of the TEB, electrically connected in series are in thermal contact with the main heat exchanger by with their heat-generating junctions, which is a hollow all-metal container filled with a melting substance with a high melting heat and a melting temperature in the range of 35-55°C, with protrusions along the edges, the area of which corresponds to the area of additional sections of the TEB, while in the main heat exchanger in the horizontal direction there are through cylindrical air ducts located in the hall order, which are tubes made of highly thermally conductive material, the upper of which are in height below the level of the surface of the recess , in which the EE element is located, at a distance of 2 mm from it. A temperature sensor is installed in direct contact with the EE, connected to the main and additional sections of the TEB, two fan units are installed on the sides of the main heat exchanger, powered by an electric power source, which blow air through cylindrical air ducts.

EFFECT: increasing the efficiency of heat removal from the EE element by increasing the intensity of heat removal from the heat-generating junctions of the thermoelectric battery (TEB) sections through the main heat exchanger due forced air heat removal from it, whereas the device comprises the main section of the TEB located in the centre, and two additional sections of the TEB located at the edges.

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Description

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

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 that is 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 thermopile is divided into the main and two additional sections connected electrically in series and made of thermoelements identical in their geometric, electrical and thermal characteristics. The main section of the thermopile is located in the center of the main heat exchanger, and additional sections of the thermopile are located at the edges on the protrusions of the main heat exchanger, the area of \u200b\u200bwhich corresponds to the area of the additional sections of the thermopile. The REE fuel element is placed in the formed recess to provide thermal contact with the heat-absorbing junctions of the main section of the thermopile, with the heat-absorbing junctions of the additional sections of the thermopile and the REE fuel element, an additional heat exchanger made in the form of an evaporative heat sink contacts the heat-absorbing junctions. The main heat exchanger is made in the form of a hollow all-metal container filled with a melting working substance with a high melting heat and a melting temperature in the range of 35-55 °C.

The disadvantage of the device is the low intensity of heat removal from the heat-generating junctions of the thermopile 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 electronic equipment element.

The aim of the invention is to increase the efficiency of heat removal from the electronic equipment element by increasing the intensity of heat removal from the heat-generating junctions of the thermopile sections through the main heat exchanger by organizing forced air heat removal from it.

The goal is achieved by the fact that through cylindrical air ducts are made in the horizontal direction in the main heat exchanger in the corridor order, which are tubes made of highly thermally conductive material, the upper of which are located in height below the level of the surface of the recess in which the electronic equipment element is located, at a distance of 2 mm from it. On the sides of the main heat exchanger opposite each other, with the help of fasteners, two fan units are installed, powered from a source of electrical energy, so that they blow air through through cylindrical air ducts.

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

In the main heat exchanger 3 in the horizontal direction, through cylindrical air ducts 8 are made in the in-line order, which are tubes made of a highly thermally conductive material, the upper of which are located in height below the level of the surface of the recess in which the electronic equipment element is located, at a distance of 2 mm from it. On the sides of the main heat exchanger 3, opposite each other, with the help of fasteners 9, two fan units 10 are installed, powered from an electric power source 11, so that they blow air through through cylindrical air ducts 8.

The device works as follows.

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

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

The fan units 10, fixed by fasteners 9 on the sides of the main heat exchanger 3, fed by the electric power source 11, blow air through the through cylindrical air ducts 8, thereby realizing the forced removal of heat 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 heat-generating junctions of the thermopile sections also increases, which in turn increases the efficiency of heat removal from the REA element.

Literature

1. RF patent 2788036 Thermoelectric device for heat removal from REA elements / Ismailov T.A., Evdulov O.V., Gabitov I.A., Ibragimova A.M. // BI No. 2, 2023.

Claims (1)

A thermoelectric device for removing heat from REA elements, containing a thermoelectric battery (TEB) electrically connected to the output of the temperature controller, the input of which is connected to a temperature sensor that is in contact with the REA fuel element located in the recess formed by the design of the TEB, the main heat exchanger located in thermal contact with the fuel junctions of the thermopile, and an additional heat exchanger, and 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 thermal characteristics, and the main section of the thermopile is located in the center of the main heat exchanger, and additional sections of the thermopile are located at the edges on the protrusions of the main heat exchanger, the area of \u200b\u200bwhich corresponds to the area of \u200b\u200bthe additional sections of the thermopile, while the fuel element of the REE is placed in the formed recess to provide thermal contact with the heat-absorbing junctions of the main section of the thermopile, with the heat-absorbing junctions of the additional sections of the thermopile and the fuel element of the REE contacts an additional heat exchanger made in the form of an evaporative heat sink, while the main heat exchanger is made in the form of a hollow all-metal container filled with a melting working substance with a high melting heat and a melting temperature in the range of 35-55 ° C, characterized in that in the main heat exchanger in in the horizontal direction, through cylindrical air ducts are made in the corridor order, which are tubes made of highly thermally conductive material, the upper of which are located in height below the level of the surface of the recess in which the electronic equipment element is located, at a distance of 2 mm from it, while on the sides of the main heat exchanger opposite each other with the help of fasteners, two fan units are installed, powered from a source of electrical energy, so that they blow air through through cylindrical air ducts.

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