On the vortical characteristics and cold-to-hot transfer of rarefied flow in a lid-driven isosceles orthogonal triangular cavity with isothermal walls
Year
: 2018
Abstract: Rarefied gas flows in nano-scale isosceles triangular cavities with a motion away from the square corner are considered over a wide range of flow rarefactions regimes, i.e., 0.01≤Kn≤10, using the direct simulation Monte Carlo (DSMC) method. We put emphasis to the rarefaction effects on the vortical behaviors and heat transfer patterns of rarefied monatomic and diatomic gases. We show that the primary vortices appearing in the triangular cavity are Moffat-type vortices, which disappear as velocity slip increases over the walls. However, an additional vortex is observed at Kn>1 on the inclined wall attributable to the balance of the thermally driven flows from the cold to the hot region and flow induced by the primary vortex. We also report variations in the effective length scale of the fluid circulation with the Knudsen number. Our investigations specify that the competition between the Fourier term and shear stress gradient component of the heat flux constitutive relation results in the cold-to-hot transfer in triangular cavities. Also, heat flux patterns predicted by the asymptotic theory of the Boltzmann equation for the weakly non-linear flow and by the linearized form of the Regularized 13 moments (R13) equations are compared with the DSMC solution suitably at low Knudsen number regimes.
Keyword(s): Triangular Nano-Cavity,Anti-Fourier Heat Transfer,Shear Stress Gradient,Vortical Behavior,Rarefied Gas Flow,DSMC
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On the vortical characteristics and cold-to-hot transfer of rarefied flow in a lid-driven isosceles orthogonal triangular cavity with isothermal walls
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contributor author | احسان روحی گل خطمی | en |
contributor author | وحید شهابی | en |
contributor author | Amir Bagherzadeh | en |
contributor author | Ehsan Roohi | fa |
contributor author | Vahid Shahabi | fa |
date accessioned | 2020-06-06T13:37:42Z | |
date available | 2020-06-06T13:37:42Z | |
date issued | 2018 | |
identifier uri | http://libsearch.um.ac.ir:80/fum/handle/fum/3362592?locale-attribute=en | |
description abstract | Rarefied gas flows in nano-scale isosceles triangular cavities with a motion away from the square corner are considered over a wide range of flow rarefactions regimes, i.e., 0.01≤Kn≤10, using the direct simulation Monte Carlo (DSMC) method. We put emphasis to the rarefaction effects on the vortical behaviors and heat transfer patterns of rarefied monatomic and diatomic gases. We show that the primary vortices appearing in the triangular cavity are Moffat-type vortices, which disappear as velocity slip increases over the walls. However, an additional vortex is observed at Kn>1 on the inclined wall attributable to the balance of the thermally driven flows from the cold to the hot region and flow induced by the primary vortex. We also report variations in the effective length scale of the fluid circulation with the Knudsen number. Our investigations specify that the competition between the Fourier term and shear stress gradient component of the heat flux constitutive relation results in the cold-to-hot transfer in triangular cavities. Also, heat flux patterns predicted by the asymptotic theory of the Boltzmann equation for the weakly non-linear flow and by the linearized form of the Regularized 13 moments (R13) equations are compared with the DSMC solution suitably at low Knudsen number regimes. | en |
language | English | |
title | On the vortical characteristics and cold-to-hot transfer of rarefied flow in a lid-driven isosceles orthogonal triangular cavity with isothermal walls | en |
type | Journal Paper | |
contenttype | External Fulltext | |
subject keywords | Triangular Nano-Cavity | en |
subject keywords | Anti-Fourier Heat Transfer | en |
subject keywords | Shear Stress Gradient | en |
subject keywords | Vortical Behavior | en |
subject keywords | Rarefied Gas Flow | en |
subject keywords | DSMC | en |
journal title | International Journal of Thermal Sciences | en |
journal title | International Journal of Thermal Sciences | fa |
pages | 381-394 | |
journal volume | 125 | |
journal issue | 3 | |
identifier link | https://profdoc.um.ac.ir/paper-abstract-1065719.html | |
identifier articleid | 1065719 |