聚合物支撑型形状稳定相变材料在热能储存应用中的重要评述

Energy Storage Pub Date : 2024-05-21 DOI:10.1002/est2.639
Rahul Bidiyasar, Rohitash Kumar, Narendra Jakhar
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引用次数: 0

摘要

近年来,相变材料(PCM)因其在相变过程中存储和释放热能的能力而备受关注。然而,传统的 PCMs 面临着热传导率有限、从固态到液态相变过程中的泄漏、热降解和耐久性等挑战。为了克服这些困难,研究人员集中精力创造以聚合物为支撑基质的形状稳定 PCM(SSPCM),并加入高导热添加剂以提高导热性。与传统的 PCM 相比,基于聚合物的 SSPCM 通常更灵活、更轻便、更耐用,而且很容易根据具体应用进行定制。在构建聚合物基 SSPCM 时,必须考虑 PCM 负载、热循环性、成本效益和环境问题等各种因素。本综述论文全面探讨了各种聚合物,包括聚氨酯、聚丙烯酸酯、聚烯烃等,由于它们具有相对较高的机械强度、与 PCM 的兼容性、出色的热稳定性和耐化学性,可作为 SSPCMs 的理想支撑材料。壳聚糖、纤维素和淀粉等天然聚合物也被认为是环保解决方案。我们还讨论了每种聚合物的具体特性、成本效益以及开发此类 SSPCM 时对环境的影响,以指导研究人员选择材料。我们还简要讨论了聚合物基 SSPCM 在太阳能储存、医疗设备、建筑材料、电子产品、运输业和废热回收中的应用。最后,还讨论了一些未来发展领域,以吸引该领域新研究人员的关注。本综述所提供的信息将有助于读者了解聚合物基 SSPCM,并根据不同的应用方法选择所需的聚合物作为支撑材料。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A critical review of polymer support-based shape-stabilized phase change materials for thermal energy storage applications

Phase change materials (PCMs) have drawn considerable attention in recent years due to their capability of storing and releasing thermal energy during phase transformation. However, traditional PCMs face challenges like limited thermal conductivity, leakage while phase transformation from solid to liquid, thermal degradation, and durability. Researchers have concentrated on creating shape-stabilized PCMs (SSPCMs) employing polymers as the supporting matrix to overcome these difficulties and incorporating highly thermally conductive additives to improve thermal conductivity. Compared to conventional PCMs, polymer-based SSPCMs are often more flexible, lightweight, and durable and may be easily customized according to specific applications. Various factors like PCM loading, thermal cyclability, cost-effectiveness and environmental concerns must be considered while constructing polymer-based SSPCMs. This review paper comprehensively explored various polymers, including polyurethane, polyacrylates, polyolefin, and so on, as promising supporting materials for SSPCMs due to their relatively high mechanical strength, compatibility with PCM, excellent thermal stability, and chemical resistance. Natural polymers like chitosan, cellulose, and starch are also considered for eco-friendly solutions. We have also discussed about specific properties of each polymer, their cost-effectiveness, and the environmental impact while developing such SSPCMs to guide researchers in material selection. Applications of polymer-based SSPCMs in solar energy storage, medical devices, building materials, electronics, transportation industry, and waste heat recovery are briefly discussed. Finally, some future development areas have been discussed to attract the attention of new researchers in this field. The information provided in this review will assist readers in understanding polymer-based SSPCM and selecting their desired polymer for support material with diverse application methods.

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