Development and Study of a Loop Heat Pipe with Several Heat Sources of Different Power

The results of the development and experimental studies of a loop heat pipe designed for the simultaneous cooling of several heat sources that dissipate different power amounts is presented. The pipe has a cylindrical evaporator and a serpentine-shaped condenser that is connected via the vapor and l...

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Bibliographic Details
Published in:High temperature 2019-09, Vol.57 (5), p.700-706
Main Authors: Pastukhov, V. G., Maydanik, Yu. F.
Format: Article
Language:English
Subjects:
Ammonia
Atoms and Molecules in Strong Fields
Classical and Continuum Physics
Economic impact
Evaporators
Freons
Heat
Heat and Mass Transfer and Physical Gasdynamics
Heat exchangers
Heat pipes
Heat sources
Industrial Chemistry/Chemical Engineering
Laser Matter Interaction
Loop heat pipes
Materials Science
Maximum power
Physical Chemistry
Physics
Physics and Astronomy
Power
Vapors
Working fluids
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Summary:The results of the development and experimental studies of a loop heat pipe designed for the simultaneous cooling of several heat sources that dissipate different power amounts is presented. The pipe has a cylindrical evaporator and a serpentine-shaped condenser that is connected via the vapor and liquid lines. The evaporator was in thermal contact with the main heat source. Two additional, less powerful heat sources were in contact with the heat exchangers located on the vapor line and liquid lines. Freon-152a and ammonia were used as the working fluids. The efficiency of the loop heat pipe is estimated according to the ratio of the maximum heat load on the additional sources to the heat load of the main source. A temperature of 90°C was the limiting condition for each source. The tests were performed at a condenser coolant temperature of 20°C. The maximum power of the pipe with ammonia, without additional heat sources, was equal to 350 W, and that with freon-152a was130 W. We show that the maximum load on the additional source located on the liquid line was 34 W (57%) for a freon pipe under a nominal heat load on the main source of 60 W and 10 W (16%) on the source located on the vapor line. For an ammonia loop heat pipe under a nominal load on the main source of 220 W, the respective values for the additional sources were 60 W (27%) and 13 W (6%).
ISSN:0018-151X
1608-3156
DOI:10.1134/S0018151X19050122