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Assessing the Dynamic Performance of Thermochemical Storage Materials

Author

Listed:
  • Sara Walsh

    (Specific IKC, Baglan Bay Innovation Centre, Swansea University, Central Avenue, Port Talbot SA12 7AX, UK)

  • Jack Reynolds

    (Specific IKC, Baglan Bay Innovation Centre, Swansea University, Central Avenue, Port Talbot SA12 7AX, UK)

  • Bahaa Abbas

    (Specific IKC, Baglan Bay Innovation Centre, Swansea University, Central Avenue, Port Talbot SA12 7AX, UK)

  • Rachel Woods

    (Specific IKC, Baglan Bay Innovation Centre, Swansea University, Central Avenue, Port Talbot SA12 7AX, UK)

  • Justin Searle

    (Specific IKC, Baglan Bay Innovation Centre, Swansea University, Central Avenue, Port Talbot SA12 7AX, UK)

  • Eifion Jewell

    (Specific IKC, Baglan Bay Innovation Centre, Swansea University, Central Avenue, Port Talbot SA12 7AX, UK)

  • Jonathon Elvins

    (Specific IKC, Baglan Bay Innovation Centre, Swansea University, Central Avenue, Port Talbot SA12 7AX, UK)

Abstract

Thermochemical storage provides a volumetric and cost-efficient means of collecting energy from solar/waste heat in order to utilize it for space heating in another location. Equally important to the storage density, the dynamic thermal response dictates the power available which is critical to meet the varied demands of a practical space heating application. Using a laboratory scale reactor (127 cm 3 ), an experimental study with salt in matrix (SIM) materials found that the reactor power response is primarily governed by the flow rate of moist air through the reactor and that creating salt with a higher salt fraction had minimal impact on the thermal response. The flowrate dictates the power profile of the reactor with an optimum value which balances moisture reactant delivery and reaction rate on the SIM. A mixed particle size produced the highest power (22 W) and peak thermal uplift (32 °C). A narrow particle range reduced the peak power and peak temperature as a result of lower packing densities of the SIM in the reactor. The scaled maximum power density which could be achieved is >150 kW/m 3 , but achieving this would require optimization of the solid–moist air interactions.

Suggested Citation

  • Sara Walsh & Jack Reynolds & Bahaa Abbas & Rachel Woods & Justin Searle & Eifion Jewell & Jonathon Elvins, 2020. "Assessing the Dynamic Performance of Thermochemical Storage Materials," Energies, MDPI, vol. 13(9), pages 1-12, May.
  • Handle: RePEc:gam:jeners:v:13:y:2020:i:9:p:2202-:d:353301
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    References listed on IDEAS

    as
    1. Solé, Aran & Martorell, Ingrid & Cabeza, Luisa F., 2015. "State of the art on gas–solid thermochemical energy storage systems and reactors for building applications," Renewable and Sustainable Energy Reviews, Elsevier, vol. 47(C), pages 386-398.
    2. Pinel, Patrice & Cruickshank, Cynthia A. & Beausoleil-Morrison, Ian & Wills, Adam, 2011. "A review of available methods for seasonal storage of solar thermal energy in residential applications," Renewable and Sustainable Energy Reviews, Elsevier, vol. 15(7), pages 3341-3359, September.
    3. Mehrabadi, Abbas & Farid, Mohammed, 2018. "New salt hydrate composite for low-grade thermal energy storage," Energy, Elsevier, vol. 164(C), pages 194-203.
    4. Navarro, Lidia & de Gracia, Alvaro & Colclough, Shane & Browne, Maria & McCormack, Sarah J. & Griffiths, Philip & Cabeza, Luisa F., 2016. "Thermal energy storage in building integrated thermal systems: A review. Part 1. active storage systems," Renewable Energy, Elsevier, vol. 88(C), pages 526-547.
    5. Michel, Benoit & Mazet, Nathalie & Neveu, Pierre, 2014. "Experimental investigation of an innovative thermochemical process operating with a hydrate salt and moist air for thermal storage of solar energy: Global performance," Applied Energy, Elsevier, vol. 129(C), pages 177-186.
    6. Navarro, Lidia & de Gracia, Alvaro & Niall, Dervilla & Castell, Albert & Browne, Maria & McCormack, Sarah J. & Griffiths, Philip & Cabeza, Luisa F., 2016. "Thermal energy storage in building integrated thermal systems: A review. Part 2. Integration as passive system," Renewable Energy, Elsevier, vol. 85(C), pages 1334-1356.
    7. Alva, Guruprasad & Lin, Yaxue & Fang, Guiyin, 2018. "An overview of thermal energy storage systems," Energy, Elsevier, vol. 144(C), pages 341-378.
    8. Xu, J.X. & Li, T.X. & Chao, J.W. & Yan, T.S. & Wang, R.Z., 2019. "High energy-density multi-form thermochemical energy storage based on multi-step sorption processes," Energy, Elsevier, vol. 185(C), pages 1131-1142.
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