Thermal Performance Optimization of Perforated Fins for Flat Plate Heat Sinks Using CFD Approach

A comprehensive multi-dimensional computational fluid dynamics (CFD) analysis was conducted on a flat plate heat sink, equipped with four perforated fins. This study aimed to optimize the thermal performance by exploring the effects of the geometry and placement of the perforations within the fins....

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Main Authors: Al-Muhsen N.F.O., Al-Khafaji O.R.S., Ismail F.B.
Other Authors: 57197748656
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Published: International Information and Engineering Technology Association 2024
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spelling my.uniten.dspace-340672024-10-14T11:17:50Z Thermal Performance Optimization of Perforated Fins for Flat Plate Heat Sinks Using CFD Approach Al-Muhsen N.F.O. Al-Khafaji O.R.S. Ismail F.B. 57197748656 57216252729 58027086700 computational fluid dynamics (CFD) heat transfer coefficient natural convection heat transfer perforated fins perforation position perforation shape temperature difference Buoyancy Computational fluid dynamics Enclosures Fins (heat exchange) Natural convection Computational fluid dynamic Flat plate Heat transfer co-efficients matrix Natural convection heat transfer Perforated fin Perforation position Perforation shape Temperature differences Thermal Performance Heat transfer coefficients A comprehensive multi-dimensional computational fluid dynamics (CFD) analysis was conducted on a flat plate heat sink, equipped with four perforated fins. This study aimed to optimize the thermal performance by exploring the effects of the geometry and placement of the perforations within the fins. The heat transfer was modelled under conduction for the heat sink body, and natural convection for the enclosure. The investigation focused on the combined influence of the shape of the fin perforations (circular, square, triangular) and their spatial positioning (bottom, middle, top) on the overall thermal performance. It was observed that the temperature gradients (?T) from the bottom to the top of the fins were significantly enhanced with the introduction of perforations. Notably, the smallest ?T of 2.64C� was recorded with circular perforations, independent of their placement within the fin matrix. Conversely, the highest ?T of 12.58C� was observed when the perforations were triangular in shape. Furthermore, an increase in ?T was noted when all perforation matrices were relocated from the top to the bottom of the fins. Interestingly, the heat transfer coefficient was found to be higher when the heat sink made use of perforated fins. However, the effect of the perforations' shape and placement on this coefficient was found to be less significant. In conclusion, optimal thermal performance was achieved with circularly perforated fins. The buoyancy effect within the enclosure and in the vicinity of the fins was amplified when the heat sink's fins were top-positioned and circularly perforated. This resulted in a 15.6% increase in ?T, but also a 29.6% increase in the heat transfer coefficient, indicating an overall enhancement in thermal performance under most tested conditions. � 2023 International Information and Engineering Technology Association. All rights reserved. Final 2024-10-14T03:17:50Z 2024-10-14T03:17:50Z 2023 Article 10.18280/ijht.410426 2-s2.0-85173886800 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85173886800&doi=10.18280%2fijht.410426&partnerID=40&md5=affe9de7a57ac2c1a6fe5c69306c2fae https://irepository.uniten.edu.my/handle/123456789/34067 41 4 1052 1062 All Open Access Hybrid Gold Open Access International Information and Engineering Technology Association Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic computational fluid dynamics (CFD)
heat transfer coefficient
natural convection heat transfer
perforated fins
perforation position
perforation shape
temperature difference
Buoyancy
Computational fluid dynamics
Enclosures
Fins (heat exchange)
Natural convection
Computational fluid dynamic
Flat plate
Heat transfer co-efficients
matrix
Natural convection heat transfer
Perforated fin
Perforation position
Perforation shape
Temperature differences
Thermal Performance
Heat transfer coefficients
spellingShingle computational fluid dynamics (CFD)
heat transfer coefficient
natural convection heat transfer
perforated fins
perforation position
perforation shape
temperature difference
Buoyancy
Computational fluid dynamics
Enclosures
Fins (heat exchange)
Natural convection
Computational fluid dynamic
Flat plate
Heat transfer co-efficients
matrix
Natural convection heat transfer
Perforated fin
Perforation position
Perforation shape
Temperature differences
Thermal Performance
Heat transfer coefficients
Al-Muhsen N.F.O.
Al-Khafaji O.R.S.
Ismail F.B.
Thermal Performance Optimization of Perforated Fins for Flat Plate Heat Sinks Using CFD Approach
description A comprehensive multi-dimensional computational fluid dynamics (CFD) analysis was conducted on a flat plate heat sink, equipped with four perforated fins. This study aimed to optimize the thermal performance by exploring the effects of the geometry and placement of the perforations within the fins. The heat transfer was modelled under conduction for the heat sink body, and natural convection for the enclosure. The investigation focused on the combined influence of the shape of the fin perforations (circular, square, triangular) and their spatial positioning (bottom, middle, top) on the overall thermal performance. It was observed that the temperature gradients (?T) from the bottom to the top of the fins were significantly enhanced with the introduction of perforations. Notably, the smallest ?T of 2.64C� was recorded with circular perforations, independent of their placement within the fin matrix. Conversely, the highest ?T of 12.58C� was observed when the perforations were triangular in shape. Furthermore, an increase in ?T was noted when all perforation matrices were relocated from the top to the bottom of the fins. Interestingly, the heat transfer coefficient was found to be higher when the heat sink made use of perforated fins. However, the effect of the perforations' shape and placement on this coefficient was found to be less significant. In conclusion, optimal thermal performance was achieved with circularly perforated fins. The buoyancy effect within the enclosure and in the vicinity of the fins was amplified when the heat sink's fins were top-positioned and circularly perforated. This resulted in a 15.6% increase in ?T, but also a 29.6% increase in the heat transfer coefficient, indicating an overall enhancement in thermal performance under most tested conditions. � 2023 International Information and Engineering Technology Association. All rights reserved.
author2 57197748656
author_facet 57197748656
Al-Muhsen N.F.O.
Al-Khafaji O.R.S.
Ismail F.B.
format Article
author Al-Muhsen N.F.O.
Al-Khafaji O.R.S.
Ismail F.B.
author_sort Al-Muhsen N.F.O.
title Thermal Performance Optimization of Perforated Fins for Flat Plate Heat Sinks Using CFD Approach
title_short Thermal Performance Optimization of Perforated Fins for Flat Plate Heat Sinks Using CFD Approach
title_full Thermal Performance Optimization of Perforated Fins for Flat Plate Heat Sinks Using CFD Approach
title_fullStr Thermal Performance Optimization of Perforated Fins for Flat Plate Heat Sinks Using CFD Approach
title_full_unstemmed Thermal Performance Optimization of Perforated Fins for Flat Plate Heat Sinks Using CFD Approach
title_sort thermal performance optimization of perforated fins for flat plate heat sinks using cfd approach
publisher International Information and Engineering Technology Association
publishDate 2024
_version_ 1814061039704080384
score 13.214268