Wind Reversal in Bubbly Natural Convection
The multi-phase Rayleigh–Bènard convection has been weakly investigated, even though it plays a leading role in the theoretical and applied physics of the heat transfer enhancement. For the case of moderate turbulent convection, a rather unexpected result is an unusual kind of wind reversal, in the...
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MDPI AG
2020-11-01
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Series: | Applied Sciences |
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Online Access: | https://www.mdpi.com/2076-3417/10/22/8242 |
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author | Paolo Oresta Laura Fabbiano Gaetano Vacca |
author_facet | Paolo Oresta Laura Fabbiano Gaetano Vacca |
author_sort | Paolo Oresta |
collection | DOAJ |
description | The multi-phase Rayleigh–Bènard convection has been weakly investigated, even though it plays a leading role in the theoretical and applied physics of the heat transfer enhancement. For the case of moderate turbulent convection, a rather unexpected result is an unusual kind of wind reversal, in the sense that the fluid is found to be strongly influenced by the bubbles, whereas the bubbles themselves appear to be little affected by the fluid, despite the relative smallness of the Stokes numbers. The wind reversal induced by the bubbles dispersed in the fluid is a new and remarkable phenomenon in multi-phase flows that provides further perspectives in understanding the complex physics leading the enhancement of thermal convection. For this reason, the fundamental research proposed in this paper aimed to identify a space of control parameters and the physical mechanisms responsible for the wind reversal induced by dispersed bubbles in a confined convective flow. The strength of the following description lies in an innovative numerical approach, based on the multi-scale physics induced by the coupling of the local thermal and mechanical mechanisms arising between each bubble and the surrounding fluid. The continuous phase has been solved numerically using the direct numerical simulation (DNS) technique and each bubble has been tracked by means of a particle Lagrangian model. |
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format | Article |
id | doaj.art-e68a9ae2660f42d38460968d97d1116e |
institution | Directory Open Access Journal |
issn | 2076-3417 |
language | English |
last_indexed | 2024-03-10T14:42:27Z |
publishDate | 2020-11-01 |
publisher | MDPI AG |
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series | Applied Sciences |
spelling | doaj.art-e68a9ae2660f42d38460968d97d1116e2023-11-20T21:45:01ZengMDPI AGApplied Sciences2076-34172020-11-011022824210.3390/app10228242Wind Reversal in Bubbly Natural ConvectionPaolo Oresta0Laura Fabbiano1Gaetano Vacca2Department of Mechanics, Mathematics and Management, Polytechnic University of Bari, 70125 Bari, ItalyDepartment of Mechanics, Mathematics and Management, Polytechnic University of Bari, 70125 Bari, ItalyDepartment of Mechanics, Mathematics and Management, Polytechnic University of Bari, 70125 Bari, ItalyThe multi-phase Rayleigh–Bènard convection has been weakly investigated, even though it plays a leading role in the theoretical and applied physics of the heat transfer enhancement. For the case of moderate turbulent convection, a rather unexpected result is an unusual kind of wind reversal, in the sense that the fluid is found to be strongly influenced by the bubbles, whereas the bubbles themselves appear to be little affected by the fluid, despite the relative smallness of the Stokes numbers. The wind reversal induced by the bubbles dispersed in the fluid is a new and remarkable phenomenon in multi-phase flows that provides further perspectives in understanding the complex physics leading the enhancement of thermal convection. For this reason, the fundamental research proposed in this paper aimed to identify a space of control parameters and the physical mechanisms responsible for the wind reversal induced by dispersed bubbles in a confined convective flow. The strength of the following description lies in an innovative numerical approach, based on the multi-scale physics induced by the coupling of the local thermal and mechanical mechanisms arising between each bubble and the surrounding fluid. The continuous phase has been solved numerically using the direct numerical simulation (DNS) technique and each bubble has been tracked by means of a particle Lagrangian model.https://www.mdpi.com/2076-3417/10/22/8242multi-phase flowRayleigh-Bénard convectionLagrangian particle trackingdirect numerical simulation |
spellingShingle | Paolo Oresta Laura Fabbiano Gaetano Vacca Wind Reversal in Bubbly Natural Convection Applied Sciences multi-phase flow Rayleigh-Bénard convection Lagrangian particle tracking direct numerical simulation |
title | Wind Reversal in Bubbly Natural Convection |
title_full | Wind Reversal in Bubbly Natural Convection |
title_fullStr | Wind Reversal in Bubbly Natural Convection |
title_full_unstemmed | Wind Reversal in Bubbly Natural Convection |
title_short | Wind Reversal in Bubbly Natural Convection |
title_sort | wind reversal in bubbly natural convection |
topic | multi-phase flow Rayleigh-Bénard convection Lagrangian particle tracking direct numerical simulation |
url | https://www.mdpi.com/2076-3417/10/22/8242 |
work_keys_str_mv | AT paolooresta windreversalinbubblynaturalconvection AT laurafabbiano windreversalinbubblynaturalconvection AT gaetanovacca windreversalinbubblynaturalconvection |