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Overall efficiency increment in a pin-fin microchannel heat sink using response surface methodology and Pareto optimization

Fadi AlthoeyDepartment of Civil Engineering, College of Engineering, Najran University, Najran, Saudi ArabiaSinan Q. SalihPradeep Kumar SinghDepartment of Mechanical Engineering, Institute of Engineering & Technology, GLA University, Mathura, U.P., 281406, IndiaAli ShawabkehCollege of Engineering and Technology, American University of the Middle East, KuwaitSalem AlkhalafDepartment of Computer, College of Science and Arts in Ar Rass, Qassim University, Ar Rass, Qassim, Saudi ArabiaFawaz S. AlharbiDepartment of Mechanical Engineering, College of Engineering, University of Hafr Al Batin, P.O. Box 1803, Hafr Al Batin 39524, Saudi ArabiaSherzod AbdullaevEngineering School, Central Asian University, Tashkent, UzbekistanYasser ElmasryDepartment of Mathematics - Faculty of Science - King Khalid University, P.O. Box 9004, Abha 61466, Saudi ArabiaAhmed Farouk DeifallaDepartment of Structural Engineering and Construction Management, Future University in Egypt, New Cairo City 11835, Egypt
ABI

Аннотация

In modern technology, anticipating the optimal thermal performance in microchannel heat sinks (MCHSs) is a vital response to overheating challenges in high-performance electronic devices. The Response Surface Methodology (RSM) application presents an innovative way of modeling such equipment's behavior. In the current study, an MCHS with pin fins was chosen to examine the Nusselt number (Nu) and pressure drop (ΔP). Using two RSM models and multi-objective optimization, the study tried to discern the optimal values of the responses in the MCHS. The RSM models examined three key parameters: length, installation angle, and the spacing between pin fins. The interactive impacts of independent parameters and their consequent effect on the responses were also explored. The RSM models attained exceptional predictive accuracy, with the determination coefficient values of 0.9946 and 0.9986 for Nu and ΔP, respectively. The working fluid applied in the present work was water with an inlet temperature of 288 K and a Reynolds number of 300. Besides, the constant heat flux of 100 W/cm2 was exposed to the bottom wall of the MCHS. In pursuit of an optimal MCHS design that maximizes Nu while minimizing ΔP, the study employed the relative efficiency index (η) parameter. Considering heat transfer and ΔP in the pin-fin MCHS, the optimal design showed an impressive improvement of about 64.5 % compared to the fin-free heat sink. Moreover, the study provided Pareto optimal points for Nu, ΔP, and η, adding depth to understanding the complex trade-offs within the investigated MCHS.

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