Optimizing Thermal Performance of Mini Heat Exchangers: An Experimental Analysis Using a Full Factorial Design

Optimizing Thermal Performance of Mini Heat Exchangers: An Experimental Analysis Using a Full Factorial Design

This study seeks to investigate the heat dissipation process in a minichannel heat exchanger, commonly employed for cooling electronic components. The analysis centers on two key factors: global thermal resistance (<i>G<sub>TR</sub></i>) and the heat transfer coefficient. The...

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Main Authors: Sergio da Silva Franco, Álvaro Augusto Soares Lima, Alvaro Antonio Villa Ochoa, José Ângelo Peixoto da Costa, Gustavo de Novaes Pires Leite, Márcio Vilar, Kilvio Alessandro Ferraz, Paula Suemy Arruda Michima
Format: Article
Language:English
Published: MDPI AG 2025-04-01
Series:Applied Sciences
Subjects:
heat dissipation
chemometric
mini heat exchanger
global thermal resistance
electronic processor cooling systems
Online Access:https://www.mdpi.com/2076-3417/15/7/4052
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Summary:This study seeks to investigate the heat dissipation process in a minichannel heat exchanger, commonly employed for cooling electronic components. The analysis centers on two key factors: global thermal resistance (<i>G<sub>TR</sub></i>) and the heat transfer coefficient. The innovation of this study resides in the development and analysis of a mini heat exchanger optimized using chemometric methods to achieve efficient thermal dissipation. Various conditions, including the power source, volumetric flow rate, and ambient temperature, were varied at both low and high levels to assess their impact on these variables and establish the optimal conditions for heat dissipation. The cooling of electronic components, such as processors, remains a topic of ongoing research, as the miniaturization of components through nanotechnology requires enhanced heat dissipation within increasingly smaller spaces. This experimental study identifies the optimal conditions for both <i>G<sub>TR</sub></i> and the heat transfer coefficient within the examined parameters. <i>G<sub>TR</sub></i> is minimized with a power of 30 W, an ambient temperature of 29 °C, and a flow rate of 2.50 L·min<sup>−1</sup>. The results indicate that electrical power was the most significant variable affecting <i>G<sub>TR</sub></i>, while ambient temperature also played a determining role in the heat transfer coefficient.
ISSN:2076-3417

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