Convective Melting Modeling Approach for Phase Change Materials with Variable Boundary Heating

Proceedings of The 59th Conference on imulation and Modelling (SIMS 59), 26-28 September 2018, Oslo Metropolitan University, Norway Pub Date : 2018-11-19 DOI:10.3384/ECP18153103

D. Rubinetti, D. Weiss, A. Chaudhuri, D. Kraniotis

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引用次数: 2

Abstract

The present study conceives a numerical model for phase change materials following the apparent heat capacity method where the phase change occurs within a chosen temperature interval. A multiphysical modeling approach to satisfy the coupled momentum, energy and continuity conservation equations whilst avoiding numerical singularities is applied. By means of a 2D test-case geometry with variable boundary heating the influence of natural convection within the melted liquid zone is visualized. Corresponding non-dimensional governing equations are analysed to quantify the dominant contributing terms. It turns out that for sufficiently small Grashof number, or consequently small Rayleigh numbers the influence of natural convection can be neglected, thus simplyfing the problem substantially. The modeling approach has been adapted to a 2D-axisymmetric geometry within the scope of experimental validation. The simulation results and experimental data show reasonably good agreement. The model is numerically stable and suitable to facilitate design of latent heat storage systems.

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变边界加热相变材料的对流熔化建模方法

本研究设想相变材料的数值模型遵循表观热容法，其中相变发生在一个选定的温度区间内。采用了一种多物理场建模方法来满足耦合动量、能量和连续性守恒方程，同时避免了数值奇异性。通过具有可变边界加热的二维测试用例几何图形，可视化了熔化液体区域内自然对流的影响。分析了相应的无量纲控制方程，量化了主导贡献项。结果表明，对于足够小的格拉什夫数，或因此较小的瑞利数，可以忽略自然对流的影响，从而大大简化了问题。在实验验证的范围内，建模方法已适应于二维轴对称几何。仿真结果与实验数据吻合较好。该模型数值稳定，适用于潜热蓄热系统的设计。

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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Proceedings of The 59th Conference on imulation and Modelling (SIMS 59), 26-28 September 2018, Oslo Metropolitan University, Norway

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