Eco-friendly approach to thermal energy storage: Assessing the thermal and chemical properties of coconut biochar-enhanced phase change material

Energy Storage Pub Date : 2024-07-07 DOI:10.1002/est2.679
Reji K. Rajamony, Johnny K. S. Paw, Adarsh K. Pandey, Abd G. N. Sofiah, Aman Yadav, Yaw C. Tak, Tiong S. Kiong, Asit Mohanty, Manzoore E. M. Soudagar, Yasser Fouad
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Abstract

Phase change materials (PCMs) can absorb, store, and release substantial latent heat within a specific temperature range during phase transition and have gained huge attention due to environmental concerns and energy crises. However, PCMs have a significant downside in energy storage due to their relatively lower thermal conductivity, leading to inadequate heat transfer (HT) performance. The foremost aim of the research is to synthesize an eco-friendly coconut shell biochar (CSB) dispersed with organic A46 PCM in the temperature range of 44°C to 46°C to form a green nanocomposite. A two-step approach is adopted to formulate the nanocomposites with different weight concentrations (0.2% and 0.8%) of green CSB particles. The developed nanocomposite's thermal conductivity and chemical stability were examined using a thermal properties analyzer and a Fourier transforms infrared spectrometer. The developed biochar composites have excellent thermal conductivity (0.39 W/m K) compared with base PCM (0.22 W/m K). Also, the developed nanocomposites were physically mixed together; there were no additional functional groups formed compared to pristine PCM, and the prepared materials were composite. Furthermore, a numerical analysis was performed using two-dimensional energy modeling software to ascertain the HT rate of A46 composites. These thermally energized green nanocomposites show great promise for thermal energy storage and thermal management applications like battery thermal management, photovoltaic thermal systems, desalination systems, electronic cooling, building applications, and textiles.

热能储存的生态友好型方法:评估椰子生物炭强化相变材料的热和化学特性
相变材料(PCMs)在相变过程中可在特定温度范围内吸收、储存和释放大量潜热,因环境问题和能源危机而备受关注。然而,由于 PCM 的热传导率相对较低,导致其热传导(HT)性能不足,因此在储能方面存在很大弊端。本研究的首要目标是在 44°C 至 46°C 温度范围内合成一种生态友好型椰壳生物炭(CSB),并将其分散到有机 A46 PCM 中,形成一种绿色纳米复合材料。采用两步法配制出不同重量浓度(0.2% 和 0.8%)的绿色 CSB 颗粒纳米复合材料。使用热性能分析仪和傅立叶变换红外光谱仪检测了所开发的纳米复合材料的导热性和化学稳定性。与基础 PCM(0.22 W/m K)相比,所开发的生物炭复合材料具有出色的导热性(0.39 W/m K)。此外,所开发的纳米复合材料是物理混合在一起的;与原始 PCM 相比,没有形成额外的官能团,而且所制备的材料是复合材料。此外,还使用二维能量建模软件进行了数值分析,以确定 A46 复合材料的热效率。这些热能绿色纳米复合材料在电池热管理、光伏热系统、海水淡化系统、电子制冷、建筑应用和纺织品等热能储存和热管理应用领域大有可为。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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