A critical assessment on evaporative cooling performance of micro finned micro gap for high heat flux applications
Micro gap heat sinks reduce flow boiling instabilities and generate more uniform surface temperature than typical microchannels. Heat transfer rate in micro gaps can be increased by providing micro fins. Micro fins increase surface area as well as generate turbulence, which disturbs the laminar sub...
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Asian Research Publishing Network (ARPN)
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iium-492922017-03-28T07:27:11Z http://irep.iium.edu.my/49292/ A critical assessment on evaporative cooling performance of micro finned micro gap for high heat flux applications Ahmed, Shugata Ismail, Ahmad Faris Sulaeman, Erwin Muhammad, Hasibul Hasan TJ Mechanical engineering and machinery Micro gap heat sinks reduce flow boiling instabilities and generate more uniform surface temperature than typical microchannels. Heat transfer rate in micro gaps can be increased by providing micro fins. Micro fins increase surface area as well as generate turbulence, which disturbs the laminar sub-layer. Hence, heat transfer rate enhances due to rapid fluid mixing. In this paper, effectiveness of flow boiling in a micro finned micro gap for cooling purpose has been investigated numerically. Flow boiling of pure water in the heat sink has been simulated using FLUENT 14.5 release. From results, it has been observed that upper and lower solid-fluid interfaces show different thermal behaviors with heat flux increment.Area-weighted average heat transfer coefficient of upper surface increases with increasing heat flux, while decreases for lower surface. In a net effect, thermal resistance of the heat sink increases with heat flux increment after onset of boiling for low Reynolds number. However, for high Reynolds number, thermal resistance changes slowly with heat flux variation. Pressure drop penalty has been found high for high heat fluxes during boiling. Interestingly, increment of pumping power is not always cost effective as thermal resistance does not decrease sharply all over the range. Hence, it is suggested that optimized pumping power should be used for highest efficiency. Asian Research Publishing Network (ARPN) 2016-01-10 Article PeerReviewed application/pdf en http://irep.iium.edu.my/49292/1/jeas_0116_3341.pdf application/pdf en http://irep.iium.edu.my/49292/4/49292_A%20critical%20assessment_SCOPUS.pdf Ahmed, Shugata and Ismail, Ahmad Faris and Sulaeman, Erwin and Muhammad, Hasibul Hasan (2016) A critical assessment on evaporative cooling performance of micro finned micro gap for high heat flux applications. ARPN Journal of Engineering and Applied Sciences, 11 (1). pp. 331-336. ISSN 1819-6608 http://www.arpnjournals.org/jeas/research_papers/rp_2016/jeas_0116_3341.pdf |
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TJ Mechanical engineering and machinery Ahmed, Shugata Ismail, Ahmad Faris Sulaeman, Erwin Muhammad, Hasibul Hasan A critical assessment on evaporative cooling performance of micro finned micro gap for high heat flux applications |
description |
Micro gap heat sinks reduce flow boiling instabilities and generate more uniform surface temperature than typical
microchannels. Heat transfer rate in micro gaps can be increased by providing micro fins. Micro fins increase surface area as well as generate turbulence, which disturbs the laminar sub-layer. Hence, heat transfer rate enhances due to rapid fluid mixing. In this paper, effectiveness of flow boiling in a micro finned micro gap for cooling purpose has been investigated numerically. Flow boiling of pure water in the heat sink has been simulated using FLUENT 14.5 release. From results, it has been observed that upper and lower solid-fluid interfaces show different thermal behaviors with heat flux increment.Area-weighted average heat transfer coefficient of upper surface increases with increasing heat flux, while decreases for lower surface. In a net effect, thermal resistance of the heat sink increases with heat flux increment after onset of boiling for low Reynolds number. However, for high Reynolds number, thermal resistance changes slowly with heat flux variation.
Pressure drop penalty has been found high for high heat fluxes during boiling. Interestingly, increment of pumping power is not always cost effective as thermal resistance does not decrease sharply all over the range. Hence, it is suggested that optimized pumping power should be used for highest efficiency. |
format |
Article |
author |
Ahmed, Shugata Ismail, Ahmad Faris Sulaeman, Erwin Muhammad, Hasibul Hasan |
author_facet |
Ahmed, Shugata Ismail, Ahmad Faris Sulaeman, Erwin Muhammad, Hasibul Hasan |
author_sort |
Ahmed, Shugata |
title |
A critical assessment on evaporative cooling performance of micro finned micro gap for high heat flux applications |
title_short |
A critical assessment on evaporative cooling performance of micro finned micro gap for high heat flux applications |
title_full |
A critical assessment on evaporative cooling performance of micro finned micro gap for high heat flux applications |
title_fullStr |
A critical assessment on evaporative cooling performance of micro finned micro gap for high heat flux applications |
title_full_unstemmed |
A critical assessment on evaporative cooling performance of micro finned micro gap for high heat flux applications |
title_sort |
critical assessment on evaporative cooling performance of micro finned micro gap for high heat flux applications |
publisher |
Asian Research Publishing Network (ARPN) |
publishDate |
2016 |
url |
http://irep.iium.edu.my/49292/ http://irep.iium.edu.my/49292/ http://irep.iium.edu.my/49292/1/jeas_0116_3341.pdf http://irep.iium.edu.my/49292/4/49292_A%20critical%20assessment_SCOPUS.pdf |
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2023-09-18T21:09:43Z |
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2023-09-18T21:09:43Z |
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