Enhancement of Confined Air Jet Impingement Heat Transfer Using Perforated Pin-Fin Heat Sinks

The development of semiconductor fabrication process and electronic packaging technology causes the size and weight of electronic components to decrease consistently. Along with the increasing operating power, the heat generation rate of the electronic pr

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Abstract The development of semiconductor fabrication process and electronic packaging technology causes the size and weight of electronic components to decrease consistently. Along with the increasing operating power, the heat generation rate of the electronic products apparently gets higher. For the sustainable future, we must limit using natural resources and also reduce the greenhouse gas emission. Efﬁcient removal of heat from the electronic products in a limited space becomes a major task in electronics cooling. Air impingement cooling with a heat sink is an attractive option for electronic cooling, because it is inexpensive, robust, and localized. Rapid heat transfer from heated surfaces and reducing material weight is also becoming a major task for the design of heat exchanger equipment for electronic cooling. Rectangular plate ﬁns as extended surfaces are good heat transfer equipment which are widely used for various industrial applications. Heat transfer rate can be improved by introducing perforations, porosity, or slots. Moreover, due to restrictions in setup space and economic reasons, heat transfer equipment has been required to be much more compact in size and lighter in weight. Studies on three-dimensional plate and pin-ﬁn heat sinks are extensive. But no focus has been yet given on air jet impingement heat transfer with perforated pin-ﬁn heat sink. Thermal-fluid characteristics of solid and perforated pin-ﬁn heat sinks cooled by conﬁned air jet impingement are investigated numerically in this study. The SST k-x turbulence model is used to predict the turbulence flow parameters. The numerical model is veriﬁed with previously published experimental data. Flow and heat transfer characteristics are presented for the impinging Reynolds number, Re = 5000−25000 having constant impingement distance (Y/D = 8), ﬁn width (W/L = 0.1), and height (H/L = 0.5). The main objective of this study is to examine the effects of ﬁn perforations on the thermal performance of Md. Farhad Ismail School of Mechatronic Systems Engineering, Simon Fraser University, Burnaby, BC V5A1S6, Canada S.C. Saha (&) School of Chemistry, Physics & Mechanical Engineering, Queensland University of Technology, Brisbane, QLD 4001, Australia e-mail: [email protected]; [email protected] © Springer Nature Singapore Pte Ltd. 2018 M.M.K. Khan et al. (eds.), Application of Thermo-ﬂuid Processes in Energy Systems, Green Energy and Technology, https://doi.org/10.1007/978-981-10-0697-5_10

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Md. Farhad Ismail and S.C. Saha

pin-ﬁn heat sinks. Results show that thermal resistance decreases and ﬁn efﬁciency increases with the increase of Reynolds number due to perforation. Thus, this kind of heat sink equipment would reduce the cooling power consumption rate. Keywords Thermal-fluid characteristics Conﬁned jet impingement

Thermal resistance Perforated ﬁns

1 Introduction Heat sinks are utilized to dissipate thermal energy generated by electronic components to maintain a safe temperature. Browne et al. [1] investigated the performance

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Enhancement of Confined Air Jet Impingement Heat Transfer Using Perforated Pin-Fin Heat Sinks

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