Asymmetrical melting and solidification processes of phase change material and the challenges for thermal energy storage systems

Pub Date : 2024-07-12 DOI:10.24425/ather.2024.151224
I. Sutjahja, A. Yusuf, Y. Anggraini, S. Ulhaq, D. Kurnia, S. Wonorahardjo
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Abstract

The melting and solidification processes of the organic phase change material – lauric acid exposed to air were experi-mentally studied to investigate the heat exchange and its effect on the heat transfer behaviour inside a shell as well as its phase-change characteristics. Lauric acid was placed in spherical shells made of polyvinyl chloride with diameters of 44, 63, and 74 mm. This study was based on analyses of the surface temperature and vertical temperature distribution data inside the shells. We found that the phase change characteristics were strongly related to the dominant heat transfer mech-anism. In this case, melting was dominated by convection, whereas solidification was dominated by conduction. The convection intensity increased as the shell diameter increased. Further analysis revealed the melting and solidification periods. In contrast to latent heat release accompanying solidification, latent heat absorption accompanied by melting does not occur at a constant temperature, although it has a smaller temperature gradient than does sensible heat absorption. Based on the asymmetry between the melting and solidification processes, we discuss various possible strategies by which to control the charging and discharging of the phase change material by restraining the heat transfer rate to optimise its performance as a latent thermal energy storage material.
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相变材料的非对称熔化和凝固过程以及热能储存系统面临的挑战
对暴露在空气中的有机相变材料--月桂酸的熔化和凝固过程进行了实验研究,以探究热交换及其对外壳内部传热行为的影响以及月桂酸的相变特性。月桂酸被置于直径分别为 44、63 和 74 毫米的聚氯乙烯球形外壳中。这项研究基于对外壳内表面温度和垂直温度分布数据的分析。我们发现,相变特征与主要的传热机制密切相关。在这种情况下,对流主导熔化,而传导主导凝固。对流强度随着壳体直径的增加而增加。进一步分析显示了熔化和凝固期。与伴随凝固的潜热释放不同,伴随熔化的潜热吸收并非在恒定温度下发生,尽管其温度梯度小于显热吸收。基于熔化和凝固过程的不对称性,我们讨论了各种可能的策略,通过限制热传导率来控制相变材料的充放电,从而优化其作为潜热储能材料的性能。
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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