Employing numerical method for evaluating the heat transfer rate of a hot tube by nanofluid natural convection

One of the major issues in industry is cooling of pipes when using forced convection mechanism is not able to cool pipes, but free convection mechanism can be a suitable method. In this regard, a half-pipe was installed in the center of a half-elliptical enclosure in which the gap of between them wa...

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Main Authors: Wu, Yujia, Mansir, Ibrahim B., Althobaiti, Ali, Cao, Yan, Dahari, Mahidzal, Nguyen, Dinh Tuyen, Mohamed, Abdullah, Huynh, Phat Huy, Wae-hayee, Makatar
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Published: Elsevier 2022
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Online Access:http://eprints.um.edu.my/42195/
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spelling my.um.eprints.421952023-10-16T02:48:57Z http://eprints.um.edu.my/42195/ Employing numerical method for evaluating the heat transfer rate of a hot tube by nanofluid natural convection Wu, Yujia Mansir, Ibrahim B. Althobaiti, Ali Cao, Yan Dahari, Mahidzal Nguyen, Dinh Tuyen Mohamed, Abdullah Huynh, Phat Huy Wae-hayee, Makatar TA Engineering (General). Civil engineering (General) One of the major issues in industry is cooling of pipes when using forced convection mechanism is not able to cool pipes, but free convection mechanism can be a suitable method. In this regard, a half-pipe was installed in the center of a half-elliptical enclosure in which the gap of between them was saturated with nanofluid of water and alumina (aluminum oxide) nanoparticle depending on temperature and nanoparticle diameter. Several samples were simulated by means of CFD and FVM to understand the impacts of Rayleigh number, inclined angle, and volume fraction of nanoparticles on the heat flux of hot pipe. In addition, the dynamic viscosity and thermal conductivity coefficient of nanofluid depended on temperature, nanoparticle diameter, and volume fraction, which were used for precising simulation to physical results. The obtained results showed that adding 3% volume fraction of alumina could increase the average heat flux of hot half-pipe by 8.7%. Moreover, at high Rayleigh numbers, volume fraction of 1% was optimum amount for volume fraction. In addition, inclined angle had considerable influence on average heat flux, specifically, in high Rayleigh numbers. Elsevier 2022-07 Article PeerReviewed Wu, Yujia and Mansir, Ibrahim B. and Althobaiti, Ali and Cao, Yan and Dahari, Mahidzal and Nguyen, Dinh Tuyen and Mohamed, Abdullah and Huynh, Phat Huy and Wae-hayee, Makatar (2022) Employing numerical method for evaluating the heat transfer rate of a hot tube by nanofluid natural convection. Case Studies in Thermal Engineering, 35. ISSN 2214-157X, DOI https://doi.org/10.1016/j.csite.2022.102006 <https://doi.org/10.1016/j.csite.2022.102006>. 10.1016/j.csite.2022.102006
institution Universiti Malaya
building UM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Malaya
content_source UM Research Repository
url_provider http://eprints.um.edu.my/
topic TA Engineering (General). Civil engineering (General)
spellingShingle TA Engineering (General). Civil engineering (General)
Wu, Yujia
Mansir, Ibrahim B.
Althobaiti, Ali
Cao, Yan
Dahari, Mahidzal
Nguyen, Dinh Tuyen
Mohamed, Abdullah
Huynh, Phat Huy
Wae-hayee, Makatar
Employing numerical method for evaluating the heat transfer rate of a hot tube by nanofluid natural convection
description One of the major issues in industry is cooling of pipes when using forced convection mechanism is not able to cool pipes, but free convection mechanism can be a suitable method. In this regard, a half-pipe was installed in the center of a half-elliptical enclosure in which the gap of between them was saturated with nanofluid of water and alumina (aluminum oxide) nanoparticle depending on temperature and nanoparticle diameter. Several samples were simulated by means of CFD and FVM to understand the impacts of Rayleigh number, inclined angle, and volume fraction of nanoparticles on the heat flux of hot pipe. In addition, the dynamic viscosity and thermal conductivity coefficient of nanofluid depended on temperature, nanoparticle diameter, and volume fraction, which were used for precising simulation to physical results. The obtained results showed that adding 3% volume fraction of alumina could increase the average heat flux of hot half-pipe by 8.7%. Moreover, at high Rayleigh numbers, volume fraction of 1% was optimum amount for volume fraction. In addition, inclined angle had considerable influence on average heat flux, specifically, in high Rayleigh numbers.
format Article
author Wu, Yujia
Mansir, Ibrahim B.
Althobaiti, Ali
Cao, Yan
Dahari, Mahidzal
Nguyen, Dinh Tuyen
Mohamed, Abdullah
Huynh, Phat Huy
Wae-hayee, Makatar
author_facet Wu, Yujia
Mansir, Ibrahim B.
Althobaiti, Ali
Cao, Yan
Dahari, Mahidzal
Nguyen, Dinh Tuyen
Mohamed, Abdullah
Huynh, Phat Huy
Wae-hayee, Makatar
author_sort Wu, Yujia
title Employing numerical method for evaluating the heat transfer rate of a hot tube by nanofluid natural convection
title_short Employing numerical method for evaluating the heat transfer rate of a hot tube by nanofluid natural convection
title_full Employing numerical method for evaluating the heat transfer rate of a hot tube by nanofluid natural convection
title_fullStr Employing numerical method for evaluating the heat transfer rate of a hot tube by nanofluid natural convection
title_full_unstemmed Employing numerical method for evaluating the heat transfer rate of a hot tube by nanofluid natural convection
title_sort employing numerical method for evaluating the heat transfer rate of a hot tube by nanofluid natural convection
publisher Elsevier
publishDate 2022
url http://eprints.um.edu.my/42195/
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