Thermal convection in Al2O3-water nanoliquid rotating chamber with a local isothermal heater S. A. Mikhailenko, M. A. Sheremet, H. F. Oztop, N. Abu-Hamdeh
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ArticleSubject(s): наножидкости | конвекционный теплообмен | численное моделированиеGenre/Form: статьи в журналах Online resources: Click here to access online
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International journal of mechanical sciences Vol. 156. P. 137-145Abstract: Convective energy transport within rotating cavities is a very important topic taking into account different rotating systems in electronics, chemical industry and thermal engineering. This study is consecrated to computational modelling of convective thermal transport and liquid circulation within a rotating enclosure loaded with water-based nanoliquid. Mathematical model formulated using the dimensionless non-primitive parameters has been worked out by the finite difference technique. The developed computational code has been verified using experimental and theoretical data of other researchers. Investigation has been performed in a broad range of the Rayleigh number, Taylor number and nanoparticles volume fraction. Calculated data have indicated the energy transport enhancement with nanoparticles concentration for high Taylor numbers.
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Convective energy transport within rotating cavities is a very important topic taking into account different rotating systems in electronics, chemical industry and thermal engineering. This study is consecrated to computational modelling of convective thermal transport and liquid circulation within a rotating enclosure loaded with water-based nanoliquid. Mathematical model formulated using the dimensionless non-primitive parameters has been worked out by the finite difference technique. The developed computational code has been verified using experimental and theoretical data of other researchers. Investigation has been performed in a broad range of the Rayleigh number, Taylor number and nanoparticles volume fraction. Calculated data have indicated the energy transport enhancement with nanoparticles concentration for high Taylor numbers.
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