Optimization of Thermal Conductivity and Latent Heat Capacity Using Fractional Factorial Approach for the Synthesis of Nano-Enhanced High-Performance Phase-Change Material

IF 4.3 3区 工程技术 Q2 ENERGY & FUELS
Man Mohan, Sheetal Kumar Dewangan, Kwan Lee, Byungmin Ahn
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Abstract

This study systematically optimizes the synthesis parameters for nano-enhanced phase-change materials (NEPCMs) based on paraffin wax and copper oxide. The objective is to collectively improve both thermal conductivity and latent heat capacity. Unlike the previous research, the present approach considers all significant synthesis parameters simultaneously, employing a fractional factorial approach for efficient experimentation. By varying CuO nanoparticle sizes, paraffin wax melting temperatures, and mass fractions of CuO and surfactant in pure paraffin wax, the comprehensive thermal analysis reveals a maximum enhancement of 51.2% thermal conductivity compared to pure paraffin wax. In addition to thermal conductivity improvement, the applied optimization strategy identifies six NEPCM combinations, collectively enhancing thermal conductivity, latent heat of melting, and solidification. Among these, one NEPCM exhibits notable improvements of 13.39%, 6.9%, and 4.5% in thermal conductivity, latent heat of melting, and solidification, respectively, making it suitable for thermal energy storage systems due to combined enhanced thermal properties. Additionally, the ANOVA approach indicates the melting temperature of pure PCM as the most significant factor for thermal conductivity enhancement, with a contribution of 55.45%. The present study has a direct impact on improving thermal properties, specifically in thermal energy storage technology, making it relevant to the thermal management research community.

Abstract Image

利用分数因子法优化热导率和潜热容量以合成纳米增强型高性能相变材料
本研究系统优化了基于石蜡和氧化铜的纳米增强相变材料 (NEPCM) 的合成参数。目的是共同提高热导率和潜热容量。与以往的研究不同,本方法同时考虑了所有重要的合成参数,采用分数因子法进行高效实验。通过改变 CuO 纳米粒子的尺寸、石蜡熔化温度以及纯石蜡中 CuO 和表面活性剂的质量分数,综合热分析表明,与纯石蜡相比,热导率最大提高了 51.2%。除了热导率的提高,应用优化策略还确定了六种 NEPCM 组合,它们共同提高了热导率、熔化潜热和凝固性。其中,一种 NEPCM 的热导率、熔化潜热和凝固性分别显著提高了 13.39%、6.9% 和 4.5%,由于其热学特性得到了综合增强,因此适合用于热能储存系统。此外,方差分析方法表明,纯 PCM 的熔化温度是热导率增强的最重要因素,贡献率为 55.45%。本研究对改善热性能,特别是热能储存技术有直接影响,因此与热管理研究领域息息相关。
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来源期刊
International Journal of Energy Research
International Journal of Energy Research 工程技术-核科学技术
CiteScore
9.80
自引率
8.70%
发文量
1170
审稿时长
3.1 months
期刊介绍: The International Journal of Energy Research (IJER) is dedicated to providing a multidisciplinary, unique platform for researchers, scientists, engineers, technology developers, planners, and policy makers to present their research results and findings in a compelling manner on novel energy systems and applications. IJER covers the entire spectrum of energy from production to conversion, conservation, management, systems, technologies, etc. We encourage papers submissions aiming at better efficiency, cost improvements, more effective resource use, improved design and analysis, reduced environmental impact, and hence leading to better sustainability. IJER is concerned with the development and exploitation of both advanced traditional and new energy sources, systems, technologies and applications. Interdisciplinary subjects in the area of novel energy systems and applications are also encouraged. High-quality research papers are solicited in, but are not limited to, the following areas with innovative and novel contents: -Biofuels and alternatives -Carbon capturing and storage technologies -Clean coal technologies -Energy conversion, conservation and management -Energy storage -Energy systems -Hybrid/combined/integrated energy systems for multi-generation -Hydrogen energy and fuel cells -Hydrogen production technologies -Micro- and nano-energy systems and technologies -Nuclear energy -Renewable energies (e.g. geothermal, solar, wind, hydro, tidal, wave, biomass) -Smart energy system
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