Performance of a Simplified Computational Fluid Dynamics Model for a Phase Change Material–Water Finned Heat Exchanger Under Different Orientations

Energy Storage Pub Date : 2024-08-28 DOI:10.1002/est2.70021
Francisco Javier González Gallero, Gabriel González Siles, Ismael Rodríguez Maestre, Juan Luis Foncubierta Blázquez, Luis Pérez-Lombard
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Abstract

The prevalent numerical models for simulating axially finned heat exchangers with phase change materials (PCMs) and water as the heat transfer fluid rely on computational fluid dynamics (CFD) techniques, with a primary focus on phase change modeling. However, the computational demands of these models, incorporating phase change effects and resolving PCM movement in the liquid state, are substantial. From experiments suggesting that conduction in the solidified PCM around the finned tube dominates heat transfer during the heat discharge process, this article introduces a simplified CFD-based model in which convective flow of the PCM is neglected. The model is experimentally validated using a 1-m-long axially finned heat exchanger prototype with four fins, recording temperatures under different water flow rates and orientations (horizontal and vertical). Results show that the proposed model predicts outlet water temperature satisfactorily, with absolute errors below 1.0°C and 2.2°C for the horizontal and vertical orientations, respectively. Additionally, the model can capture the temperature trend inside the PCM for the horizontal orientation.

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相变材料-水翅片热交换器的简化计算流体动力学模型在不同方向上的性能
模拟使用相变材料 (PCM) 和水作为传热流体的轴向翅片式热交换器的主流数值模型依赖于计算流体动力学 (CFD) 技术,主要侧重于相变建模。然而,这些模型的计算要求很高,既要考虑相变效应,又要解决 PCM 在液态下的运动问题。实验表明,在热量排放过程中,翅片管周围凝固 PCM 的传导主导了热量传递,因此本文介绍了一种基于 CFD 的简化模型,其中忽略了 PCM 的对流。该模型使用一个 1 米长、带四个翅片的轴向翅片换热器原型进行了实验验证,记录了不同水流速和方向(水平和垂直)下的温度。结果表明,所提出的模型对出口水温的预测令人满意,水平和垂直方向的绝对误差分别低于 1.0°C 和 2.2°C。此外,在水平方向上,该模型还能捕捉到 PCM 内部的温度变化趋势。
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