Performance Analysis of Central Processing Unit Heat Sinks Fitted With Perforation Technique and Splitter Inserts-Reference-Cited by-同舟云学术

Performance Analysis of Central Processing Unit Heat Sinks Fitted With Perforation Technique and Splitter Inserts

Published:2022-11-17 Issue:1 Volume:145 Page:
ISSN:2832-8450
Container-title:ASME Journal of Heat and Mass Transfer
language:en
Short-container-title:

Author:

Bencherif Brahim¹,Sahel Djamel²,Benzeguir Redouane¹,Ameur Houari³

Affiliation:

1. Laboratoire des Carburants Gazeux et Environnement (LCGE), Faculté de Génie Mécanique, Université des Sciences et de Technologie d'Oran, USTO-MB , Oran 31000, Algeria

2. Département des Sciences Techniques, Université Amar Telidji-Laghouat , Laghouat 03000, Alegria

3. Département de Technologie, Centre Universitaire de Naama Salhi Ahmed , BP 66, Naama 45000, Algeria

Abstract

Abstract The increase in the heat dissipation rate in heat sinks (HSs), the reduction of the occupied volume and mass, and the elimination of the lower heat transfer areas (LHTAs) behind the pins are the main parameters to be controlled in HSs design. For this purpose, this study is devoted to numerically investigating the effect of the combination between perforation technique and splitters inserts on the heat dissipation and turbulent fluid flow characteristics of pin fins heat sinks (PFHSs). The splitter is located in the back of the pin, and the cylindrical pin fins heat sinks (CPFHSs) are perforated with different pairs of hole numbers. These configurations are named PFHS-0 (without perforation) to PFHS-5. The results obtained for the PFHS-5 show an increase in Nusselt number by 34.91% and a reduction in the thermal resistance by 24.22%, compared with CPFHSs. For the same conditions, the occupied volume and mass of this case are also reduced by 70% and 47.5%, respectively. In addition, the PFHS-5 case ensures the highest hydrothermal performance factor (HTPF) of 1.42 at Re = 8,740.

Publisher

ASME International

Link

https://asmedigitalcollection.asme.org/heattransfer/article-pdf/145/1/014501/6951972/ht_145_01_014501.pdf

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