Radiative cooling: Experimental and numerical analysis for enhanced thermal management strategies in engineering systems

IF 2.8 Q2 THERMODYNAMICS
Heat Transfer Pub Date : 2024-04-23 DOI:10.1002/htj.23058
Birkut Güler
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Abstract

This study aims to fully evaluate the radiation effect in existing cooling systems. The research, a combination of experimental analysis and numerical simulations using ANSYS Fluent, examines the complexity of radiative cooling processes and their impact on thermal management in various engineering applications. The experiments began by carefully placing a 112.5 W heater into the thermal channel. Next, temperature measurements were made under various conditions. In particular, the use of black cotton fabric as the inner duct lining applied in the thermal channel stands out as an innovation that aims to optimize heat absorption by increasing radiative properties. The findings highlight the significant impact of radiation on cooling performance. A temperature drop of 2–3°C was observed in cooling under the effect of radiation. Additionally, numerical simulations reveal the feasibility of radiative cooling systems by providing valuable information about the flow dynamics and heat transfer mechanisms within the channel. The novelty of this work is its detailed examination of radiative cooling effects and its focus on its potential to optimize thermal management strategies in various engineering applications. Explaining the role of radiation in heat transfer and providing practical information to improve cooling efficiency demonstrates that this research brings important insight and lays the foundation for future advances in the field. Considering the urgent need for energy-efficient cooling solutions and the increasing demand for sustainable engineering practices, the findings of this study will provide important insights for researchers and practitioners. This study provides innovative perspectives and solutions to address the increasing challenges of heat transfer and energy conservation in engineering systems. It makes a significant contribution to the field of thermal management by offering methodologies.

Abstract Image

辐射冷却:加强工程系统热管理策略的实验和数值分析
本研究旨在全面评估现有冷却系统中的辐射效应。研究结合了实验分析和使用 ANSYS Fluent 进行的数值模拟,考察了辐射冷却过程的复杂性及其对各种工程应用中热管理的影响。实验首先将一个 112.5 W 的加热器小心地放入热通道中。接着,在各种条件下进行温度测量。其中,使用黑色棉织物作为热通道的内管衬里是一项创新,其目的是通过增加辐射特性来优化热量吸收。研究结果凸显了辐射对冷却性能的重要影响。在辐射作用下,冷却温度下降了 2-3°C 。此外,数值模拟揭示了辐射冷却系统的可行性,提供了有关通道内流动动力学和传热机制的宝贵信息。这项工作的新颖之处在于详细研究了辐射冷却效应,并重点关注其在各种工程应用中优化热管理策略的潜力。该研究解释了辐射在热传递中的作用,并提供了提高冷却效率的实用信息,这表明该研究具有重要的洞察力,并为该领域未来的发展奠定了基础。考虑到对高能效冷却解决方案的迫切需求以及对可持续工程实践的日益增长的需求,本研究的结果将为研究人员和从业人员提供重要启示。本研究提供了创新的视角和解决方案,以应对工程系统中日益严峻的传热和节能挑战。它通过提供方法,为热管理领域做出了重要贡献。
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来源期刊
Heat Transfer
Heat Transfer THERMODYNAMICS-
CiteScore
6.30
自引率
19.40%
发文量
342
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