SU620787A2 - Heat-conducting device - Google Patents

Description

The proposed device operates as follows. The heat flux supplied from the source to the evaporation zone 2 evaporates the liquid phase of the heat carrier in the internal cavity of the heat pipe 1. The resulting steam enters the cross section of the pipe 1 through the transport zone 3 to the condensation zone 4, where it condenses and transfers heat to the environment. The condensed coolant is returned back to the evaporation zone with the help of wetting forces. The inert gas occupying the tank 5 and a certain part of the zone 4 of condensation has a relatively sharp boundary with the working coolant vapor. Regulation is carried out by moving the interface and, accordingly, by changing the heat transfer surface. The inert gas is heated with the help of an additional heat pipe 6. The working coolant vapor heats the evaporation section 7 of the additional heat pipe 6 and evaporates the heat carrier of this pipe. The steam condenses in the condensation section 8, giving away the heat of condensation to the inert gas located in the condensation zone 4 and the tank 5. To increase the heat transfer intensity, the condensation section 8 is equipped with fins 10. With good thermal insulation 1I, the gas temperature in the tank 5 will be close to the saturation temperature a pair of additional heat pipe 6. When hydrogen is released in the heat pipe 1, it is added to the inert gas, and the working pressure in the pipe gradually rises. The corrosion process and the release of hydrogen also occur in the additional heat pipe 6. The hydrogen released is pushed aside by the flow of the coolant vapor to the end of the volume of the condensation section 8, turning off

.

Claims (1)

/ while a certain part of the heat exchange surface of the condensation section 8. At the same time, the process of diffusion of accumulated hydrogen into the coolant vapor in the opposite direction. Diffusion of non-condensing hydrogen. To steam causes a decrease in the partial pressure of the latter, respectively, the saturation temperature of the water vapor of the additional heat pipe decreases. Simultaneously, the mechanism of the complete displacement of water vapor from the volume of the condensation section by hydrogen (like a gas-controlled pipe) also functions. Reducing the temperature difference of the coolant in the volume of section 8 and the inert gas in the tank 5 reduces the heat flow transmitted through the fins 10, and the temperature of the inert gas (respectively, pressure) drops. Thus, the pressure increase by the evolution of hydrogen in a gas-controlled heat pipe is compensated for by lowering it when cooling inert gas by gradually lowering the temperature of the heating surface of the condensation section 8. The geometry of the conical volume 9 can be chosen so that both factors affect the change in the working pressure in pipe 1 mutual compensating. The invention of the heat transfer device auth. St. N ° 547631, characterized in that, in order to increase operational reliability, the internal cavity of the condensation section of the additional heat pipe is made conical in shape with an extension towards the end of this section.