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Seasonal thermochemical energy storage: Comparison of the experimental results with the modelling of the falling film tube bundle heat and mass exchanger unit

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  • Daguenet-Frick, Xavier
  • Gantenbein, Paul
  • Müller, Jonas
  • Fumey, Benjamin
  • Weber, Robert

Abstract

This paper focuses on the assessment of a heat and mass exchanger dedicated to an absorption/desorption seasonal thermal energy storage system. The closed sorption heat storage based on water vapour absorption in aqueous sodium hydroxide (NaOH-H2O) solution theoretically achieves a significantly higher volumetric energy density compared to conventional hot water storage systems. To this purpose, a prototype designed for a power output of 10 kW was built and operated in both absorption and desorption mode under steady state boundary conditions. In this work, the influence of two main parameters on the exchanged power is evidenced. Furthermore, a comparison with the results of the initial numerical model used to design the heat and mass exchanger is carried out. On one hand it is found that, for the absorption process, the measured exchanged power is much lower than the numerically predicted value. On the other hand, for the desorption process the numerical and experimental results have the same order of magnitude. Physical explications of the strongly diverging results encountered during the absorption process as well as an improved heat transfer coefficient model for the desorption process are proposed.

Suggested Citation

  • Daguenet-Frick, Xavier & Gantenbein, Paul & Müller, Jonas & Fumey, Benjamin & Weber, Robert, 2017. "Seasonal thermochemical energy storage: Comparison of the experimental results with the modelling of the falling film tube bundle heat and mass exchanger unit," Renewable Energy, Elsevier, vol. 110(C), pages 162-173.
    • Handle: RePEc:eee:renene:v:110:y:2017:i:c:p:162-173
    DOI: 10.1016/j.renene.2016.10.005
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    References listed on IDEAS

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    1. Tatsidjodoung, Parfait & Le Pierrès, Nolwenn & Luo, Lingai, 2013. "A review of potential materials for thermal energy storage in building applications," Renewable and Sustainable Energy Reviews, Elsevier, vol. 18(C), pages 327-349.
    2. Yate Ding & S.B. Riffat, 2012. "Thermochemical energy storage technologies for building applications: a state-of-the-art review," International Journal of Low-Carbon Technologies, Oxford University Press, vol. 8(2), pages 106-116, January.
    3. Heier, Johan & Bales, Chris & Martin, Viktoria, 2015. "Combining thermal energy storage with buildings – a review," Renewable and Sustainable Energy Reviews, Elsevier, vol. 42(C), pages 1305-1325.
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    Cited by:

    1. Frazzica, A. & Brancato, V. & Caprì, A. & Cannilla, C. & Gordeeva, L.G. & Aristov, Y.I., 2020. "Development of “salt in porous matrix” composites based on LiCl for sorption thermal energy storage," Energy, Elsevier, vol. 208(C).
    2. Fumey, B. & Weber, R. & Baldini, L., 2019. "Sorption based long-term thermal energy storage – Process classification and analysis of performance limitations: A review," Renewable and Sustainable Energy Reviews, Elsevier, vol. 111(C), pages 57-74.
    3. Böhm, Hans & Lindorfer, Johannes, 2019. "Techno-economic assessment of seasonal heat storage in district heating with thermochemical materials," Energy, Elsevier, vol. 179(C), pages 1246-1264.
    4. Sun, Chongzheng & Liu, Yuxiang & Yang, Xin & Li, Yuxing & Geng, Xiaoyi & Han, Hui & Lu, Xiao, 2024. "Experimental and numerical study on the offshore adaptability of new FLH2 floating hydrogen liquefaction production storage and offloading unit," Renewable Energy, Elsevier, vol. 224(C).
    5. Palomba, Valeria & Sapienza, Alessio & Aristov, Yuri, 2019. "Dynamics and useful heat of the discharge stage of adsorptive cycles for long term thermal storage," Applied Energy, Elsevier, vol. 248(C), pages 299-309.

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