Comparative numerical study of single and two-phase models of nanofluid liquid film evaporation in a vertical channel

Comparative numerical study of single and two-phase models of nanofluid liquid film evaporation in a vertical channel

The main purpose of this study is to survey numerically comparison of two-phase and single-phase models of heat and mass transfer of Al2O3-water nanofluid liquid film flowing downward a vertical channel. A finite difference method is developed to produce the computational predictions for heat and ma...

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Main Authors: Najim Monssif, Feddaoui M’barek, Nait Alla Abderrahman, Charef Adil
Format: Article
Language:English
Published: EDP Sciences 2020-01-01
Series:MATEC Web of Conferences
Online Access:https://www.matec-conferences.org/articles/matecconf/pdf/2020/03/matecconf_icome2017-2018_01034.pdf
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spelling doaj-3b2eb9ba43d447e1af5883b7b80082e82021-08-05T13:49:16ZengEDP SciencesMATEC Web of Conferences2261-236X2020-01-013070103410.1051/matecconf/202030701034matecconf_icome2017-2018_01034Comparative numerical study of single and two-phase models of nanofluid liquid film evaporation in a vertical channelNajim MonssifFeddaoui M’barekNait Alla AbderrahmanCharef AdilThe main purpose of this study is to survey numerically comparison of two-phase and single-phase models of heat and mass transfer of Al2O3-water nanofluid liquid film flowing downward a vertical channel. A finite difference method is developed to produce the computational predictions for heat and mass transfer during the evaporation of the liquid film approached by the single-phase and two-phase models. The model solves the coupled governing equations in both nanofluid and gas phases together with the boundary and interfacial conditions. The systems of equations obtained by using an implicit finite difference method are solved by Tridiagonal Matrix Algorithm. The results show that the two-phase model is more realistic since it takes into account the thermophoresis and Brownian effects.https://www.matec-conferences.org/articles/matecconf/pdf/2020/03/matecconf_icome2017-2018_01034.pdf
collection DOAJ
language English
format Article
sources DOAJ
author Najim Monssif
Feddaoui M’barek
Nait Alla Abderrahman
Charef Adil
spellingShingle Najim Monssif
Feddaoui M’barek
Nait Alla Abderrahman
Charef Adil
Comparative numerical study of single and two-phase models of nanofluid liquid film evaporation in a vertical channel
MATEC Web of Conferences
author_facet Najim Monssif
Feddaoui M’barek
Nait Alla Abderrahman
Charef Adil
author_sort Najim Monssif
title Comparative numerical study of single and two-phase models of nanofluid liquid film evaporation in a vertical channel
title_short Comparative numerical study of single and two-phase models of nanofluid liquid film evaporation in a vertical channel
title_full Comparative numerical study of single and two-phase models of nanofluid liquid film evaporation in a vertical channel
title_fullStr Comparative numerical study of single and two-phase models of nanofluid liquid film evaporation in a vertical channel
title_full_unstemmed Comparative numerical study of single and two-phase models of nanofluid liquid film evaporation in a vertical channel
title_sort comparative numerical study of single and two-phase models of nanofluid liquid film evaporation in a vertical channel
publisher EDP Sciences
series MATEC Web of Conferences
issn 2261-236X
publishDate 2020-01-01
description The main purpose of this study is to survey numerically comparison of two-phase and single-phase models of heat and mass transfer of Al2O3-water nanofluid liquid film flowing downward a vertical channel. A finite difference method is developed to produce the computational predictions for heat and mass transfer during the evaporation of the liquid film approached by the single-phase and two-phase models. The model solves the coupled governing equations in both nanofluid and gas phases together with the boundary and interfacial conditions. The systems of equations obtained by using an implicit finite difference method are solved by Tridiagonal Matrix Algorithm. The results show that the two-phase model is more realistic since it takes into account the thermophoresis and Brownian effects.
url https://www.matec-conferences.org/articles/matecconf/pdf/2020/03/matecconf_icome2017-2018_01034.pdf
work_keys_str_mv AT najimmonssif comparativenumericalstudyofsingleandtwophasemodelsofnanofluidliquidfilmevaporationinaverticalchannel
AT feddaouimbarek comparativenumericalstudyofsingleandtwophasemodelsofnanofluidliquidfilmevaporationinaverticalchannel
AT naitallaabderrahman comparativenumericalstudyofsingleandtwophasemodelsofnanofluidliquidfilmevaporationinaverticalchannel
AT charefadil comparativenumericalstudyofsingleandtwophasemodelsofnanofluidliquidfilmevaporationinaverticalchannel
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