A solution of inverse heat conduction problem for investigating short liner heat pipes

DOI: DOI: 10.17586/1606-4313-2022-21-1-83-97
UDC 681.3:536.24.08

A solution of inverse heat conduction problem for investigating short liner heat pipes

Seryakov A. V., Alekseev Andrey P.

For citation: Seryakov A.V., Alekseev A.P. A solution of inverse heat conduction problem for investigating short liner heat pipes. Journal of International Academy of Refrigeration. 2022. No 1. p.83-97. DOI: 10.17586/1606-4313-2022-21-1-83-97

Abstract
The article presents the results of the researching thermophysical characteristics (heat-absorbing capacity) for an evaporator Cev of short liner heat pipes (HPs) with vapor channel (in the form of the de Laval nozzle) by a solution of inverse heat conduction problem. The pipes in question are intended for cooling spacecrafts and satellites with strict takeoff mass regulation. Mathematical statement of the coefficient inverse heat conduction problem in one-dimensional coordinate system is supplemented by the results of temperature measurementsfor the surface of the HPs under adiabatic conditions along generator line across the entire rangeof the temperature loads, as well as the measurements of thermal resistance RTT, heat capacity of the evaporator Qev, and condensation heat capacity Qcond transferred to vortex continuous-flow calorimeter at monotonous and nearly liner in time heating of the evaporator. At great temperature drop and the beginning of working fluid boiling, the measured temperature of the external surface of the capillary porous evaporator is close to constant. Therefore, solving the coefficient inverse heat conduction problem with experimental values of the evaporator temperature we are able to obtain both an estimation for extreme heat-absorbing capacity of the HPs’evaporator under operation and the values for specific evaporation heat of the boiling working fluid and compare them with the tabulated values.

Keywords: short linear heat pipes, inverse heat conduction problem, monotonous heating method, thermal resistance, heat-absorbing capacity.


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