Numerical modelling and experimental study of heat and moisture properties of a wall based on date palm fibers concrete

Numerical modelling and experimental study of heat and moisture properties of a wall based on date palm fibers concrete

In the present paper, we study with both experimental and numerical aspect the heat and moisture transfer properties of a wall based on concrete filled with the natural fibers. The wall was placed in climatic chamber and temperature and relative humidity were monitored at different depths. A develop...

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Main Authors: Alioua Tarek, Agoudjil Boudjemaa, Boudenne Abderrahim
Format: Article
Language:English
Published: EDP Sciences 2019-01-01
Series:E3S Web of Conferences
Online Access:https://www.e3s-conferences.org/articles/e3sconf/pdf/2019/11/e3sconf_enviro2018_02009.pdf
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spelling doaj-680348dfa2ae441c9f0a579f504b01562021-02-02T03:33:50ZengEDP SciencesE3S Web of Conferences2267-12422019-01-01850200910.1051/e3sconf/20198502009e3sconf_enviro2018_02009Numerical modelling and experimental study of heat and moisture properties of a wall based on date palm fibers concreteAlioua TarekAgoudjil BoudjemaaBoudenne AbderrahimIn the present paper, we study with both experimental and numerical aspect the heat and moisture transfer properties of a wall based on concrete filled with the natural fibers. The wall was placed in climatic chamber and temperature and relative humidity were monitored at different depths. A developed model describing heat and moisture transfers in porous building materials was implemented in COMSOL Multiphysics and solved with the finite element method. The obtained results are compared with experimental data. A relatively good agreement was obtained for both temperature and relative humidity variation at different depths. Finally, the developed model gives almost a good prediction despite the classical difficulties encountered at the experiment, which is very promising for the prediction of the hygrothermal behavior of bio-based building materials at different conditions.https://www.e3s-conferences.org/articles/e3sconf/pdf/2019/11/e3sconf_enviro2018_02009.pdf
collection DOAJ
language English
format Article
sources DOAJ
author Alioua Tarek
Agoudjil Boudjemaa
Boudenne Abderrahim
spellingShingle Alioua Tarek
Agoudjil Boudjemaa
Boudenne Abderrahim
Numerical modelling and experimental study of heat and moisture properties of a wall based on date palm fibers concrete
E3S Web of Conferences
author_facet Alioua Tarek
Agoudjil Boudjemaa
Boudenne Abderrahim
author_sort Alioua Tarek
title Numerical modelling and experimental study of heat and moisture properties of a wall based on date palm fibers concrete
title_short Numerical modelling and experimental study of heat and moisture properties of a wall based on date palm fibers concrete
title_full Numerical modelling and experimental study of heat and moisture properties of a wall based on date palm fibers concrete
title_fullStr Numerical modelling and experimental study of heat and moisture properties of a wall based on date palm fibers concrete
title_full_unstemmed Numerical modelling and experimental study of heat and moisture properties of a wall based on date palm fibers concrete
title_sort numerical modelling and experimental study of heat and moisture properties of a wall based on date palm fibers concrete
publisher EDP Sciences
series E3S Web of Conferences
issn 2267-1242
publishDate 2019-01-01
description In the present paper, we study with both experimental and numerical aspect the heat and moisture transfer properties of a wall based on concrete filled with the natural fibers. The wall was placed in climatic chamber and temperature and relative humidity were monitored at different depths. A developed model describing heat and moisture transfers in porous building materials was implemented in COMSOL Multiphysics and solved with the finite element method. The obtained results are compared with experimental data. A relatively good agreement was obtained for both temperature and relative humidity variation at different depths. Finally, the developed model gives almost a good prediction despite the classical difficulties encountered at the experiment, which is very promising for the prediction of the hygrothermal behavior of bio-based building materials at different conditions.
url https://www.e3s-conferences.org/articles/e3sconf/pdf/2019/11/e3sconf_enviro2018_02009.pdf
work_keys_str_mv AT aliouatarek numericalmodellingandexperimentalstudyofheatandmoisturepropertiesofawallbasedondatepalmfibersconcrete
AT agoudjilboudjemaa numericalmodellingandexperimentalstudyofheatandmoisturepropertiesofawallbasedondatepalmfibersconcrete
AT boudenneabderrahim numericalmodellingandexperimentalstudyofheatandmoisturepropertiesofawallbasedondatepalmfibersconcrete
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