Integration of phase change materials in improving the performance of heating, cooling, and clean energy storage systems: An overview

S.F. Ahmed; N. Rafa; T. Mehnaz; B. Ahmed; N. Islam; M. Mofijur; A.T. Hoang; GM. Shafiullah

doi:10.1016/j.jclepro.2022.132639

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Integration of phase change materials in improving the performance of heating, cooling, and clean energy storage systems: An overview

Journal article

Peer reviewed

Integration of phase change materials in improving the performance of heating, cooling, and clean energy storage systems: An overview

S.F. Ahmed, N. Rafa, T. Mehnaz, B. Ahmed, N. Islam, M. Mofijur, A.T. Hoang and GM. Shafiullah

Journal of Cleaner Production, Vol.364, Art. 132639

2022

DOI: https://doi.org/10.1016/j.jclepro.2022.132639

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Abstract

Phase change materials (PCMs) have garnered significant attention as low-cost thermal energy storage systems that efficiently capture and store solar energy. Recent review works have largely focused only on thermal conductivity enhancement techniques, and/or applications of PCMs, while others have mainly discussed the performance enhancement of either heating, cooling, or clean energy storage systems integrating with PCMs. However, not enough studies recently reviewed all of these techniques/systems comprehensively to provide insights into them. This paper thus comprehensively reviews the integration of PCMs as an enhancement to most types of heating, cooling, and clean energy storage system performance, and the techniques to enhance thermal conductivity. The integration of PCMs with these systems has shown promising performance. For instance, an improvement of 13.5% is found in the efficiency of photovoltaic (PV) system when it is integrated with PCM/Al2O3 nanoparticles. In addition, the solar air heater's daily energy efficiency reaches 17% on its own, but when combined with PCM, it reaches 33%. However, the major drawback of using PCM–TES (thermal energy storage) for cooling is that PCM does not entirely solidify at night. The literature also shows that the issues related to PCMs' low thermal conductivity, phase separation, and subcooling/supercooling, their poor compatibility with other materials, and the environmental hazards they pose hinder their application on a large scale. It is necessary to implement international standards for assessing the thermophysical properties of PCMs and compile data to better facilitate the utilization of PCMs by end-users.

Details

Title: Integration of phase change materials in improving the performance of heating, cooling, and clean energy storage systems: An overview
Authors/Creators: S.F. Ahmed (Author/Creator)
N. Rafa (Author/Creator)
T. Mehnaz (Author/Creator)
B. Ahmed (Author/Creator)
N. Islam (Author/Creator)
M. Mofijur (Author/Creator)
A.T. Hoang (Author/Creator)
GM. Shafiullah (Author/Creator)
Publication Details: Journal of Cleaner Production, Vol.364, Art. 132639
Publisher: Elsevier Limited
Identifiers: 991005544781807891
Copyright: © 2022 Elsevier Ltd.
Murdoch Affiliation: School of Engineering and Energy
Language: English
Resource Type: Journal article

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Collaboration types: Domestic collaboration; International collaboration
Citation topics: 7 Engineering & Materials Science; 7.70 Thermodynamics; 7.70.1214 Phase Change Material
Web Of Science research areas: Engineering, Environmental; Environmental Sciences; Green & Sustainable Science & Technology
ESI research areas: Engineering