Experimental and numerical investigation of circular minichannel heat sinks with various hydraulic diameter for electronic cooling application

Abstract

This article presents the experimental thermal and hydraulic performances of heat sinks with various channel diameter for cooling electronic components. A heat sink with the length and width of 60mm and total height of 16mm fabricated from aluminum material. The heat sink is designed with four circular minichannels and three different values of hydraulic diameter of channel (D=4mm, D=6mm and D=8mm). The minichannel heat sink is heated with a uniform base heat flux. Also, numerical simulation of the problem is performed using Finite Volume Method (FVM). Comparing the experimental and numerical results show that numerical results are in a good agreement with experimental data. The variation of channel diameter affects the heat transfer and pressure drop characteristics of the circular shaped minichannel heat sink. The experimental results show that the increase of channel diameter reduces the pressure drop in the heat sink. Also, the minichannel heat sink with a hydraulic diameter of 4mm has a much lower thermal resistance than the minichannel heat sinks with a hydraulic diameter of 6mm and 8mm. Furthermore, the optimization is done to have the maximum heat transfer coefficient and minimum of pressure drop along the heat sink.