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Development of non-deform micro-encapsulated phase change energy storage tablets

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  • Darkwa, J.
  • Su, O.
  • Zhou, T.

Abstract

This study evaluates the concept of developing a non-deform phase change energy storage material possessing higher thermal conductivity and energy storage density through pressure compaction process. The theoretical and experimental investigations have shown that the technique is able to reduce porosity and increase conductivity and energy storage density of a composite material. Even though there was some measure of plastoelasticity due to decompression, the average porosity was reduced from 62% to 23.8% at a relatively low compaction pressure of 2.8MPa without any structural damage to the tested sample. The mean energy storage density increased by 97% and the effective thermal conductivity also increased by twenty five times despite 10% reduction in its latent heat capacity. There is however the need for further development towards minimising the effect of decompression and achieving stronger energy storage tablets at relatively low compaction force.

Suggested Citation

  • Darkwa, J. & Su, O. & Zhou, T., 2012. "Development of non-deform micro-encapsulated phase change energy storage tablets," Applied Energy, Elsevier, vol. 98(C), pages 441-447.
  • Handle: RePEc:eee:appene:v:98:y:2012:i:c:p:441-447
    DOI: 10.1016/j.apenergy.2012.04.006
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    References listed on IDEAS

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    1. Borreguero, Ana M. & Luz Sánchez, M. & Valverde, José Luis & Carmona, Manuel & Rodríguez, Juan F., 2011. "Thermal testing and numerical simulation of gypsum wallboards incorporated with different PCMs content," Applied Energy, Elsevier, vol. 88(3), pages 930-937, March.
    2. Darkwa, Jo, 2009. "Mathematical evaluation of a buried phase change concrete cooling system for buildings," Applied Energy, Elsevier, vol. 86(5), pages 706-711, May.
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    Cited by:

    1. Lazaro, Ana & Peñalosa, Conchita & Solé, Aran & Diarce, Gonzalo & Haussmann, Thomas & Fois, Magali & Zalba, Belén & Gshwander, Stefan & Cabeza, Luisa F., 2013. "Intercomparative tests on phase change materials characterisation with differential scanning calorimeter," Applied Energy, Elsevier, vol. 109(C), pages 415-420.
    2. Su, Weiguang & Darkwa, Jo & Kokogiannakis, Georgios, 2015. "Review of solid–liquid phase change materials and their encapsulation technologies," Renewable and Sustainable Energy Reviews, Elsevier, vol. 48(C), pages 373-391.
    3. Lv, Song & Yang, Jiahao & Ren, Juwen & Zhang, Bolong & Lai, Yin & Chang, Zhihao, 2023. "Research and numerical analysis on performance optimization of photovoltaic-thermoelectric system incorporated with phase change materials," Energy, Elsevier, vol. 263(PC).
    4. Zhou, Tongyu & Darkwa, Jo & Kokogiannakis, Georgios, 2015. "Thermal evaluation of laminated composite phase change material gypsum board under dynamic conditions," Renewable Energy, Elsevier, vol. 78(C), pages 448-456.
    5. Yu, Qinghua & Jiang, Zhu & Cong, Lin & Lu, Tiejun & Suleiman, Bilyaminu & Leng, Guanghui & Wu, Zhentao & Ding, Yulong & Li, Yongliang, 2019. "A novel low-temperature fabrication approach of composite phase change materials for high temperature thermal energy storage," Applied Energy, Elsevier, vol. 237(C), pages 367-377.
    6. Su, Weiguang & Hu, Meiyong & Wang, Li & Kokogiannakis, Georgios & Chen, Jun & Gao, Liying & Li, Anqing & Xu, Chonghai, 2022. "Microencapsulated phase change materials with graphene-based materials: Fabrication, characterisation and prospects," Renewable and Sustainable Energy Reviews, Elsevier, vol. 168(C).
    7. Darkwa, J. & Calautit, J. & Du, D. & Kokogianakis, G., 2019. "A numerical and experimental analysis of an integrated TEG-PCM power enhancement system for photovoltaic cells," Applied Energy, Elsevier, vol. 248(C), pages 688-701.

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