A THROUGH METHOD FOR SOLVING PROBLEMS OF HEAT AND MASS TRANSFER IN VAPOR–LIQUID SYSTEMS THAT TAKES ACCOUNT OF MANY-PARTICLE INTERACTIONS

The paper demonstrates a further development of the approach, which makes it possible to take into account manyparticle interactions inside of the condensed phase. This method is applied to the study of the problem of heat conduction for argon and xenon. The values of thermal conductivity coeffi cient for diff erent numbers of interacting particles are obtained. Next, using the proposed approach, a one-dimensional problem of evaporation–condensation of argon between two layers of liquid is solved. Distributions of macroparameters along the coordinate and their evolution in time are presented
The paper demonstrates a further development of the approach, which makes it possible to take into account manyparticle interactions inside of the condensed phase. This method is applied to the study of the problem of heat conduction for argon and xenon. The values of thermal conductivity coeffi cient for diff erent numbers of interacting particles are obtained. Next, using the proposed approach, a one-dimensional problem of evaporation–condensation of argon between two layers of liquid is solved. Distributions of macroparameters along the coordinate and their evolution in time are presented
Author:  I. N. Shishkova, A. P. Kryukov
Keywords:  heat and mass transfer through the interphase surface, function of velocity distribution of molecules, Boltzmann kinetic equation, potential of intermolecular interaction, through solution for the liquid–vapor system
Page:  1891