增强蓄热能力:PCM 系统的纳米粒子和形状优化

Energy Storage Pub Date : 2024-10-25 DOI:10.1002/est2.70078
Hayder I. Mohammed
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引用次数: 0

摘要

基于相变材料(PCM)的蓄热系统利用蓄热材料在相变过程中吸收或释放潜热来储存热能。然而,这些系统的有效性受限于其封闭的形状和结构,以及存储材料的导热性。这项工作研究了一种新方法,通过同时使用两种技术来提高 PCM 系统的有效性:加入纳米颗粒和改变系统的几何形状。在改变形状的同时,引入纳米颗粒可增强存储介质的热导率,从而通过调整热交换的表面积提高传热效率。经测试,RT-35 可用于空间加热和冷却的潜热热能储存系统。RT-35 的熔点为 35°C,可通过储存和释放热能来调节建筑物的温度,用于空间供暖和制冷。结果表明,使用纳米颗粒和调整形状可以大大提高 PCM 系统的效果。通过加入 Al2O3 纳米粒子,PCM 的熔化时间比纯 PCM 缩短了 20%,而且比形状改性的最佳情况更有效。这些研究结果表明,加入纳米颗粒和改变形状是提高蓄热设备性能的有效方法。这项技术的潜力超越了本研究的限制,可用于太阳能热能储存、区域供热和制冷以及工业加工热等多种应用领域。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Enhancing Heat Storage Capacity: Nanoparticle and Shape Optimization for PCM Systems

Phase change material (PCM)-based heat storage systems utilize the absorption or release of latent heat during a phase change of the storage material to store thermal energy. Nevertheless, the effectiveness of these systems is restricted by the shape and structure of their confinement, as well as the heat conductivity of the storage material. This work investigates a novel method to enhance the effectiveness of PCM systems by concurrently utilizing two techniques: the inclusion of nanoparticles and the alteration of the system's geometry. Introducing nanoparticles enhances the thermal conductivity of the storage medium while altering the shape, which improves heat transfer efficiency by adjusting the surface area available for heat exchange. RT-35 was tested for use in latent heat thermal energy storage systems for space heating and cooling. With a melting point of 35°C, RT-35 was chosen to moderate building temperatures by storing and releasing thermal energy for space heating and cooling. The results indicate that using nanoparticles and adjusting shape can greatly enhance the effectiveness of PCM systems. By incorporating Al2O3 nanoparticles, the melting time of the PCM was reduced by 20% compared to the pure PCM, and it is more efficient than the best case of shape modification. These findings indicate that including nanoparticles and modifying the shape are effective methods to improve the performance of heat storage devices. This technology's potential surpasses this study's limits and can be utilized in diverse applications, including solar thermal energy storage, district heating and cooling, and industrial process heat.

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