Improvement of Latent Heat Thermal Energy Storage Rate for Domestic Solar Water Heater Systems Using Anisotropic Layers of Metal Foam

IF 3.1 3区工程技术 Q2 CONSTRUCTION & BUILDING TECHNOLOGY

Buildings Pub Date : 2024-07-26 DOI:10.3390/buildings14082322

Obai Younis, M. Mozaffari, Awadallah Ahmed, M. Ghalambaz

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引用次数: 0

Abstract

Latent Heat Transfer Thermal Energy Storage (LHTES) units are crucial in managing the variability of solar energy in solar thermal storage systems. This study explores the effectiveness of strategically placing layers of anisotropic and uniform metal foam (MF) within an LHTES to optimize the melting times of phase-change materials (PCMs) in three different setups. Using the enthalpy–porosity approach and finite element method simulations for fluid dynamics in MF, this research evaluates the impact of the metal foam’s anisotropy parameter (Kn) and orientation angle (ω) on thermal performance. The results indicate that the configuration placing the anisotropic MF layer to channel heat towards the lower right corner shortens the phase transition time by 2.72% compared to other setups. Conversely, the middle setup experiences extended melting periods, particularly when ω is at 90°—an increase in Kn from 0.1 to 0.2 cuts the melting time by 4.14%, although it remains the least efficient option. The findings highlight the critical influence of MF anisotropy and the pivotal role of ω = 45°. Angles greater than this significantly increase the liquefaction time, especially at higher Kn values, due to altered thermal conductivity directions. Furthermore, the tactical placement of the anisotropic MF layer significantly boosts thermal efficiency, as evidenced by a 13.12% reduction in the PCM liquefaction time, most notably in configurations with a lower angle orientation.

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利用各向异性金属泡沫层提高家用太阳能热水器系统的潜热蓄热率

潜热传导式热能储存（LHTES）装置对于管理太阳能热储存系统中的太阳能变化至关重要。本研究探讨了在 LHTES 中战略性地放置各向异性的均匀金属泡沫 (MF) 层的有效性，以优化三种不同设置中相变材料 (PCM) 的熔化时间。这项研究利用焓-孔隙度方法和有限元法模拟 MF 中的流体动力学，评估了金属泡沫的各向异性参数（Kn）和取向角（ω）对热性能的影响。结果表明，与其他设置相比，将各向异性金属泡沫层向右下角导热的配置可将相变时间缩短 2.72%。相反，中间的设置会延长熔化时间，尤其是当ω为 90°时--Kn 从 0.1 增加到 0.2 可将熔化时间缩短 4.14%，尽管它仍然是效率最低的选择。研究结果凸显了中频各向异性的关键影响以及 ω = 45° 的关键作用。由于热传导方向的改变，角度大于 45°会显著增加液化时间，特别是在 Kn 值较高的情况下。此外，各向异性 MF 层的战术性放置大大提高了热效率，PCM 液化时间缩短了 13.12%，这在角度方向较小的配置中最为明显。

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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来源期刊

Buildings Multiple-

CiteScore

3.40

自引率

26.30%

发文量

1883

审稿时长

11 weeks

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