The role of heat flux in the nonsteady thermal problem of molybdenum sphere cooling in an electrostatic levitation experiment

—The method for determining time dependences of the entropy-production density, force, and heat flux are presented. This method is based on processing the experimental thermogram at electrostatic levitation during spontaneous cooling of a solid molybdenum sphere. The results of numerical simulation...

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Bibliographic Details
Published in:High temperature 2017-11, Vol.55 (6), p.866-869
Main Authors: Kostanovskiy, A. V., Kostanovskaya, M. E.
Format: Article
Language:English
Subjects:
Ambient temperature
Atoms and Molecules in Strong Fields
Classical and Continuum Physics
Computer simulation
Cooling
Density
Entropy
Heat
Heat flux
Heat transfer
Industrial Chemistry/Chemical Engineering
Laser Matter Interaction
Levitation
Materials Science
Molybdenum
Physical Chemistry
Physics
Physics and Astronomy
Temperature distribution
Thermophysical Properties of Materials
Time dependence
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Summary:—The method for determining time dependences of the entropy-production density, force, and heat flux are presented. This method is based on processing the experimental thermogram at electrostatic levitation during spontaneous cooling of a solid molybdenum sphere. The results of numerical simulation of cooling a spherical sample from melting temperature T m ≈ 2880 K showed that the isothermal approximation for the temperature field in the sphere is valid, which made it possible to pass to the entropy density and calculate its production density. It is shown that heat flux in the time-dependent thermal problem under consideration determines the time dependence of the entropy production (it tends to the minimum zero value while approaching ambient temperature) and, therefore, is responsible for the validity of the extremum principle.
ISSN:0018-151X
1608-3156
DOI:10.1134/S0018151X17060104