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This work is licensed under a Creative Commons Attribution 4.0 International License (CC BY 4.0).
© 2025 The Authors. Published by Tech Science Press.Impinging jet arrays are extensively used in numerous industrial operations, including the cooling of electronics, turbine blades, and other high-heat flux systems because of their superior heat transfer capabilities. Optimizing the design and operating parameters of such systems is essential to enhance cooling efficiency and achieve uniform pressure distribution, which can lead to improved system performance and energy savings. This paper presents two multi-objective optimization methodologies for a turbulent air jet impingement cooling system. The governing equations are resolved employing the commercial computational fluid dynamics (CFD) software ANSYS Fluent v17. The study focuses on four controlling parameters: Reynolds number (Re), swirl number (S), jet-to-jet separation distance (Z/D), and impingement height (H/D). The effects of these parameters on heat transfer and impingement pressure distribution are investigated. Non-dominated Sorting Genetic Algorithm (NSGA-II) and Weighted Sum Method (WSM) are employed to optimize the controlling parameters for maximum cooling performance. The aim is to identify optimal design parameters and system configurations that enhance heat transfer efficiency while achieving a uniform impingement pressure distribution. These findings have practical implications for applications requiring efficient cooling. The optimized design achieved a 12.28% increase in convective heat transfer efficiency with a local Nusselt number of 113.05 compared to 100.69 in the reference design. Enhanced convective cooling and heat flux were observed in the optimized configuration, particularly in areas of direct jet impingement. Additionally, the optimized design maintained lower wall temperatures, demonstrating more effective thermal dissipation.
Author(s): Debnath S, Ahmed ZU, Ikhlaq M, Khan MT, Kaur A, Grewal KS
Publication type: Article
Publication status: Published
Journal: Frontiers in Heat and Mass Transfer
Year: 2025
Volume: 23
Issue: 1
Pages: 71-94
Online publication date: 26/02/2025
Acceptance date: 09/12/2024
Date deposited: 24/03/2025
ISSN (electronic): 2151-8629
Publisher: Tech Science Press
URL: https://doi.org/10.32604/fhmt.2024.059734
DOI: 10.32604/fhmt.2024.059734
Data Access Statement: Availability of Data and Materials: Data available on a request from corresponding author.
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