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Influence of the Homochronism Number of the Liquid in a Spherical Layer on the Heat Exchange in it and its Magnetic HydrodynamicsJournal of Engineering Physics and Thermophysics, 93
Results of a numerical simulation of the nonstationary heat transfer in the layer of an electrically conducting liquid between two concentric spheres are presented, the influence of the internal heat sources in this layer on the structure of the liquid flow, the temperature and magnetic induction fields, and the distribution of Nusselt numbers in it was investigated.
Journal of Engineering Physics and Thermophysics – Springer Journals
Published: Mar 1, 2022
Keywords: mathematical simulation; nonstationary heat transfer; magnetic hydrodynamics; spherical liquid layer; internal heat sources
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