Effect of Thermal Expansion Coefficient, Viscosity and Melting Range in Simulation of PCM Embedded Heat Exchangers With and Without Fins

Volume 8B: Energy Pub Date : 2021-11-01 DOI:10.1115/imece2021-70401

T. Alam, D. Bacellar, Jiazhen Ling, V. Aute

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Abstract

Phase change material heat exchangers (PCMHX) have animportant role in integrating renewable energy systems. PCMHX can offer high storage density at various temperatures of interest and can be used for grid load shifting purposes. Numerical models enable engineers to estimate PCMHX performance for different design parameters and operating conditions. Modeling phase change phenomena is challenging due to the complex time-dependent nature of the process. The accuracy of models is highly sensitive to PCM thermo-physical properties. Thermal expansion coefficient (β), viscosity (μ) and melting temperature range (MR) of a PCM are important properties, especially when natural convection is not negligible. In PCMHX modeling, using less than accurate values for these properties can have significant impact on the simulation outcomes. These propertiesand discussions thereof are not readily available in the literature. This paper presents a brief review of the literature and a numerical study investigating the model sensitivity to the above-mentioned properties for PCMHX with and without fins. CFD is used to evaluate the charging (melting) phenomena. The study quantifies the impact of uncertainty in these properties on the melting rate and temperature profile. Constant wall temperature was consideredas heat source with no heat loss to ambient. The results show that β and μ has significant effect on the melting rate andevolution of the melting front. For a non-finned domain when comparing results for different published values of β and μ, the deviation in melting time can be up to 12.9% and 57.6% respectively. For high wall temperatures, change in melting range did not impact melting time. But when the wall temperature is reduced, up to 9.8% deviation in melting time is observed.

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热膨胀系数、粘度和熔化范围对有翅片和无翅片PCM嵌入式换热器模拟的影响

相变材料换热器(PCMHX)在集成可再生能源系统中具有重要作用。PCMHX可以在各种温度下提供高存储密度，并可用于电网负荷转移目的。数值模型使工程师能够估计PCMHX在不同设计参数和操作条件下的性能。由于相变过程具有复杂的时间依赖性，因此对相变现象进行建模具有挑战性。模型的精度对PCM热物性非常敏感。热膨胀系数(β)、粘度(μ)和熔化温度范围(MR)是PCM的重要性能，特别是在自然对流不可忽略的情况下。在PCMHX建模中，使用不准确的这些属性值可能会对模拟结果产生重大影响。这些特性及其讨论在文献中并不容易获得。本文简要回顾了文献和数值研究，探讨了带翅和不带翅的PCMHX模型对上述性质的敏感性。利用CFD对充装(熔化)现象进行了数值模拟。该研究量化了这些性质的不确定性对熔化速度和温度分布的影响。恒定的壁温被认为是热源，没有热量损失给环境。结果表明，β和μ对熔点的熔化速度和熔融锋的演化有显著影响。对于非翅片区域，对不同公布的β和μ值的结果进行比较，熔化时间的偏差分别可达12.9%和57.6%。对于高壁温，熔化范围的变化不影响熔化时间。但当壁温降低时，熔化时间偏差达9.8%。

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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Volume 8B: Energy

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