RU2161385C1 - Gear for thermal stabilization of high-power radio electronic elements - Google Patents

Abstract

FIELD: provision for required thermal modes for elements of radio electronic equipment. SUBSTANCE: gear includes heat damper made of high heat-conductive material in the form of truncated pyramid whose small base has recess. Enclosure with thermostating substance whose point of phase transition coincides with thermostating temperature of cooled object is put into recess. Cooled object is placed into chamber which is heat insulated from environment and is in direct heat contact with enclosure. Battery of thermal electric modules is placed with its heat-absorbing junctions on bigger base of truncated pyramid. Control unit tests resistance of heat-stabilizing substance, supplies power to battery of thermal electric modules or disconnects it. EFFECT: enhanced accuracy of thermal stabilization of high-power radio electronic elements. 1 dwg

Description

 The invention relates to electronics and can be used to provide the required thermal regimes of elements of electronic equipment (REA), which dissipate significant power during their operation.

 The operation of most modern REA devices and devices substantially depends on systems for ensuring the required temperature conditions for their operation, which, as a rule, is associated with the need to remove significant heat from fuel elements. At the same time, there is a whole class of electronic components in which the optimal operating mode is achieved at temperatures exceeding the ambient temperature by several tens of degrees. In order to increase the efficiency of their work, it is important to thermally stabilize such elements at the optimum operating temperature.

 Known devices with a developed heat exchange surface that remove heat from the REA fuel elements under the influence of a natural temperature difference. Various types of radiators are widely used as them [1, 2, 3]. To intensify the heat transfer, the radiators are provided with additional corrugated inserts, the radiator fins are streamlined, with through holes [4], etc. All these design features are used to create turbulence in the air flow around the radiator fins to increase the heat transfer rate. However, such devices are not very effective when the temperature of the effective operation of the CEA element exceeds the ambient temperature, but the element itself warms up significantly higher during operation. In addition, radiators in these cases have significant dimensions, which makes the device cumbersome.

 Often, solutions are practiced according to which a thermoelectric battery (TEB) is directly connected to the cooled CEA element with providing thermal contact. The disadvantage of such methods of heat removal is low efficiency, because the area of the base of the cooled CEA element is small and this does not allow to attach a significant amount of thermoelectric elements to it.

 In [5], a thermoelectric heat transfer intensifier was described, in which a battery of thermoelectric modules (TEM) is installed between the heat exchanger and the fuel element. In this device, the heat transfer is intensified by the use of thermoelectric elements, heat-absorbing junctions of which cool the heat-generating element, and the heat exchanger removes heat from the heat-generating junctions. The disadvantage of this device is cumbersome, because Large heat exchanger required.

 A device is known [6], containing fuel-cell assembly with a heat exchanger on fuel junctions. The thermopile is composed of low and high semiconductor branches, the low are located in the middle and the high are around them with the formation of a recess in which in cooling contact with the heat-absorbing junctions of the low branches are a cooled element and a temperature sensor connected to the thermopile operation control unit. The device is equipped with an additional heat exchanger in thermal contact with the heat-absorbing junctions of the high branches of the thermopile and a cooled element.

 The specified design solution allows to reduce the dimensions of the device, as well as increase its effectiveness. The disadvantage of this device is the low accuracy of thermal stabilization of CEA elements.

 The aim of the invention is to eliminate the above disadvantages.

 For this, a device is proposed, the design of which is shown in the drawing.

 The device contains a thermal damper in the form of a truncated quadrangular pyramid 1, on a small base 2 of which there is a recess with a casing 3 placed in it, filled with a heat-stabilizing substance 4, the phase transition point of which coincides with the temperature of thermal stabilization of the radio-electronic element 5. The radio-electronic element 5 is placed in the chamber 6, which is in thermal contact with the casing 3 and insulated from the environment. On a large base 7 of damper 1, a TEM 8 battery is installed in heat contact with it with its heat-absorbing junctions, to the heat-generating junctions of which heat exchanger 9 is connected to provide heat contact. The control unit 10 monitors the resistance of the substance filling the casing 3, and feeds the TEM 8 battery with electrical energy Damper 1, casing 3 and heat exchanger 9 are made of highly conductive material.

 The essence of the device is as follows.

It is known that the phase transition of crystalline substances occurs at a strictly defined temperature value. This value for some crystalline materials is in the range of 30-50 ^o C (for example, gallium ≈30). If we put in a direct thermal contact with such a material in a phase transition state a REA fuel element, then it can be thermally stabilized with very high accuracy. In this case, the problem arises of the removal of heat generated by the CEA element from the thermostabilizing substance in the state of phase transition. In the proposed solution, such removal of excess heat is carried out by means of a thermopile battery. Monitoring the state of thermostabilizing substance is carried out by measuring its resistance.

 The device operates as follows.

 If the resistance of the heat-stabilizing substance 4 differs from the permissible value, the control unit 10 supplies the necessary supply current to the TEM 8 battery. As a result, the TEM 8 battery removes excess heat from the heat-stabilizing substance 4, while maintaining the necessary temperature of the CEA 5. The excess heat from the heat-soldering junctions the batteries of the TEM 8 are discharged by the heat exchanger 9. When the resistance of the thermostabilizing substance 4 is set to the required level, the control unit 10 turns off the battery of the TEM 8.

Literature
1. Dulnev G. I. Heat and mass transfer in electronic equipment. M .: Higher school, 1984.

 2. Auto 752836 (USSR) Radiator. / Fedotov A.I., Reife E.D., Denisenkov A.I. et al. / B.I. 1980.

 3. Auth. St. 801331 (USSR) A device for cooling semiconductor devices./ Blagodatny V.M., Kostyuk V.A., Remkha Yu.S. / B.I. N 4, 1981.

 4. Auto 721870 (USSR) Radiator. / Seferovsky V.N. / B.I. N 10, 1980.

 5. Lukishker E.M., Weiner A.L. Efficiency of thermoelectric heat transfer intensifiers. Questions of radio electronics, ser. TRTO, 1978, N 1, p. 86-90.

 6. Auto 1824681 (USSR) Thermoelectric heat transfer intensifier primarily for heat removal from high-power electronics elements / T. Ismailov / B.I. N 24, 1993.

Claims (1)

 A device for thermal stabilization of high-power electronics elements containing a battery of thermoelectric modules, to the heat-generating junctions of which a heat exchanger is connected to ensure thermal contact, a control unit, characterized in that it contains a heat damper in the form of a truncated pyramid, in the small base of which there is a recess in which a casing with a thermostabilizing substance, the phase transition point of which coincides with the temperature of thermal stabilization of the cooled element, placed in A thermoelectric module battery installed in direct thermal contact with the casing and thermally insulated from the environment, and on the large base of the truncated pyramid of the thermal damper, a thermoelectric module battery is installed with its heat-absorbing junctions, and the control unit monitors the resistance of the heat-stabilizing substance and supplies power to the thermoelectric module battery or turns it off.