Study on Characteristics of Heat Transfer and Flow Resistance in Random Porous Foam Metal

Porous foam metal has great application prospects in the field of compact heat exchangers. The characteristics of heat transfer and resistance for foam metal with random structure and different porosities (30%, 50%, 70% and 90%) were studied by finite element method in this study. The generated foam...

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Main Authors: Chen Aiqiang, Gu Sizhong, Georges El Achkar, Bennacer Rachid, Liu Bin
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/2019/54/e3sconf_icchmt2019_04010.pdf
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spelling doaj-6c0c0e37c5a7486497b1853b756906442021-03-02T10:25:48ZengEDP SciencesE3S Web of Conferences2267-12422019-01-011280401010.1051/e3sconf/201912804010e3sconf_icchmt2019_04010Study on Characteristics of Heat Transfer and Flow Resistance in Random Porous Foam MetalChen AiqiangGu SizhongGeorges El AchkarBennacer RachidLiu BinPorous foam metal has great application prospects in the field of compact heat exchangers. The characteristics of heat transfer and resistance for foam metal with random structure and different porosities (30%, 50%, 70% and 90%) were studied by finite element method in this study. The generated foam structures can be considered as homogeneous model and has better heat exchange capacity at higher inlet flow rate, and the boundary layer can develop well along the flow direction. The open–cell foammetal structure has a uniform heat transfer perpendicular to the flow direction. The bottom plate temperature of the low–porosity structure is more uniform at low flow rates. The intermediate porosities (50% and 70%) at high flow rates has a higher uniformity. As the porosity decreases, the internal pressure increases significantly and the pressure loss also becomes significantly larger. The corresponding optimal porosity is 57%, 66% and 76% at inlet flow rates of 0.001 m/s, 0.01 m/s and 0.1 m/s, respectively.https://www.e3s-conferences.org/articles/e3sconf/pdf/2019/54/e3sconf_icchmt2019_04010.pdf
collection DOAJ
language English
format Article
sources DOAJ
author Chen Aiqiang
Gu Sizhong
Georges El Achkar
Bennacer Rachid
Liu Bin
spellingShingle Chen Aiqiang
Gu Sizhong
Georges El Achkar
Bennacer Rachid
Liu Bin
Study on Characteristics of Heat Transfer and Flow Resistance in Random Porous Foam Metal
E3S Web of Conferences
author_facet Chen Aiqiang
Gu Sizhong
Georges El Achkar
Bennacer Rachid
Liu Bin
author_sort Chen Aiqiang
title Study on Characteristics of Heat Transfer and Flow Resistance in Random Porous Foam Metal
title_short Study on Characteristics of Heat Transfer and Flow Resistance in Random Porous Foam Metal
title_full Study on Characteristics of Heat Transfer and Flow Resistance in Random Porous Foam Metal
title_fullStr Study on Characteristics of Heat Transfer and Flow Resistance in Random Porous Foam Metal
title_full_unstemmed Study on Characteristics of Heat Transfer and Flow Resistance in Random Porous Foam Metal
title_sort study on characteristics of heat transfer and flow resistance in random porous foam metal
publisher EDP Sciences
series E3S Web of Conferences
issn 2267-1242
publishDate 2019-01-01
description Porous foam metal has great application prospects in the field of compact heat exchangers. The characteristics of heat transfer and resistance for foam metal with random structure and different porosities (30%, 50%, 70% and 90%) were studied by finite element method in this study. The generated foam structures can be considered as homogeneous model and has better heat exchange capacity at higher inlet flow rate, and the boundary layer can develop well along the flow direction. The open–cell foammetal structure has a uniform heat transfer perpendicular to the flow direction. The bottom plate temperature of the low–porosity structure is more uniform at low flow rates. The intermediate porosities (50% and 70%) at high flow rates has a higher uniformity. As the porosity decreases, the internal pressure increases significantly and the pressure loss also becomes significantly larger. The corresponding optimal porosity is 57%, 66% and 76% at inlet flow rates of 0.001 m/s, 0.01 m/s and 0.1 m/s, respectively.
url https://www.e3s-conferences.org/articles/e3sconf/pdf/2019/54/e3sconf_icchmt2019_04010.pdf
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AT georgeselachkar studyoncharacteristicsofheattransferandflowresistanceinrandomporousfoammetal
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