Experimental and numerical investigation on thermal performance enhancement of phase change material embedding porous metal structure with cubic cell

•The porous metal structure fabricated by additive manufacturing is embedded in PCM as heat transfer enhancer.•Role of PMS in enhancing heat transfer of PCM is experimentally and numerically investigated.•Pore-scale numerical method is developed and compares well with the experiment.•Materials of po...

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Bibliographic Details
Published in:Applied thermal engineering 2020-07, Vol.175, p.115337, Article 115337
Main Authors: Hu, Xusheng, Gong, Xiaolu
Format: Article
Language:English
Subjects:
Additive manufacturing
Advanced manufacturing technologies
Computer simulation
Controllability
Embedding
Energy storage
Experiments
Heat transfer
Liquid-solid interfaces
Mathematical models
Melting
Numerical analysis
Numerical models
Performance enhancement
Phase change material
Phase change materials
Physics
Pore-scale numerical simulation
Porous materials
Porous metal structure
Stability
Temperature distribution
Thermal conductivity
Thermal energy
Thermal performance
Three dimensional models
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Summary:•The porous metal structure fabricated by additive manufacturing is embedded in PCM as heat transfer enhancer.•Role of PMS in enhancing heat transfer of PCM is experimentally and numerically investigated.•Pore-scale numerical method is developed and compares well with the experiment.•Materials of porous metal structure have an effect on the thermal performance enhancement of PCM. Phase change material (PCM) is a promising candidate for application to thermal energy storage. However, low thermal conductivity hinders its wide application. In this paper, a porous metal structure (PMS) with cubic cell is used to enhance the thermal performance of PCM, in which additive manufacturing (AM) as advanced manufacturing technology enables the fast and precise fabrication of PMS with a controlled structure and material. A visualized experiment setup is built to investigate the thermal performance of PCM with and without PMS, including solid-liquid interface, temperature variation, and total melting time. To examine the heat transfer characteristics and clarify the role of PMS in the melting process, a three-dimensional numerical model is developed based on the pore-scale numerical simulation method. The experimental results illustrate that embedding PMS can significantly improve the thermal performance of PCM, e.g., the total melting time can be shortened by 38% compared with that for PCM without PMS. The numerical results are in good agreement with experimental results, which indicates that heat transfer characteristics can be predicted using pore-scale numerical simulation. The numerical results show that the temperature field of PCM with PMS is more uniform and heat transfer mechanics is different for PCM with and without PMS. In addition, PMS made of highly thermally conductive materials significantly enhances the thermal performance of PCM. Due to structure and material controllability of porous material fabricated by AM, this study highlights the capacity and potential of PMS as a heat transfer enhancer.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2020.115337