Experimental passive electronics cooling: Parametric investigation of pin-fin geometries and efficient phase change materials

•The performance of circular and square TCE with staggered and inline arrays is monitored.•Six PCMs in pin fin heat sinks are investigated for electronic cooling.•Passive cooling for heat flux of range from 4 to 8W is investigated.•Most suitable PCM based heat sink for a certain power level is sugge...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2017-12, Vol.115, p.251-263
Main Authors: Ashraf, Muhammad Junaid, Ali, Hafiz Muhammad, Usman, Hazrat, Arshad, Adeel
Format: Article
Language:English
Subjects:
Circular and square cross-sectional pin–fin heat sinks
Enhancement ratios
Enhancement time
Phase change materials
Staggered and inline arrays
Thermal conductivity enhancers
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Summary:•The performance of circular and square TCE with staggered and inline arrays is monitored.•Six PCMs in pin fin heat sinks are investigated for electronic cooling.•Passive cooling for heat flux of range from 4 to 8W is investigated.•Most suitable PCM based heat sink for a certain power level is suggested. This experimental investigation focuses on the optimization of passive cooling system using extruded finned surfaces with phase change materials (PCMs) as the thermal conductivity enhancers (TCEs). The study develops comparison between fins of circular and square cross-sectional area, made of aluminium. Further classification is done in configuration in terms of staggered and inline arrays. The volume fraction of fins is kept constant at 9% of total volume of heat sink. The purpose is to single out the better arrangement with and without PCM. Six PCMs of varying phase change temperature and heat capacities, namely Paraffin wax, RT-54, RT-44, RT-35HC, SP-31 and n-eicosane are selected for thermal conductivity enhancement. The volume fraction of PCM is also constant at 90% of the heat sink volume, giving a 10% volume for expansion after melting. Moreover, power levels are used in a range of 4–8W with an increment of 1W. The analysis was carried out on graphical trends produced and explanations were given accordingly. The most effective PCMs were also discussed considering their enhancement time, enhancement ratios and other material properties. Finally, the results were justified by the scientific knowledge and found in compliance with the work of famous researchers as well.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2017.07.114