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Experimental study on operating features of heat and mass recovery processes in adsorption refrigeration

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  • Pan, Q.W.
  • Wang, R.Z.

Abstract

Combined use of heat and mass recovery processes in adsorption refrigeration is an efficient way to improve the system performance. Several kinds of heat and mass recovery processes have been proposed. In this study, a serial heat recovery process between two adsorbers and a mass recovery-like process between two evaporators is selected. Their operating features in a practical silica gel-water adsorption refrigeration system are experimentally studied. Operating features and performances of heat and mass recovery process can be presented in terms of inlet and outlet temperatures and transferred heat of two adsorbers and two evaporators. The results show that residual heat transfer fluid in the adsorbers and evaporators significantly influences the heat and mass recovery processes, respectively. In the case of this study, optimal ranges of heat and mass recovery time is 25–45 s and 5–50 s, respectively. Heat recovery process can produce negative effect when heat recovery time is beyond 45 s and it is inefficient when heat recovery time is below 25 s. Cooling effect is remarkably yielded when mass recovery time is within the range of 5–50 s.

Suggested Citation

  • Pan, Q.W. & Wang, R.Z., 2017. "Experimental study on operating features of heat and mass recovery processes in adsorption refrigeration," Energy, Elsevier, vol. 135(C), pages 361-369.
  • Handle: RePEc:eee:energy:v:135:y:2017:i:c:p:361-369
    DOI: 10.1016/j.energy.2017.06.131
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    References listed on IDEAS

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    1. Alam, K.C.A. & Akahira, A. & Hamamoto, Y. & Akisawa, A. & Kashiwagi, T., 2004. "A four-bed mass recovery adsorption refrigeration cycle driven by low temperature waste/renewable heat source," Renewable Energy, Elsevier, vol. 29(9), pages 1461-1475.
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    Cited by:

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    2. Maciej Chorowski & Piotr Pyrka & Zbigniew Rogala & Piotr Czupryński, 2019. "Experimental Study of Performance Improvement of 3-Bed and 2-Evaporator Adsorption Chiller by Control Optimization," Energies, MDPI, vol. 12(20), pages 1-17, October.
    3. Xu, Jing & Pan, Qaunwen & Zhang, Wei & Liu, Zhiliang & Wang, Ruzhu & Ge, Tianshu, 2022. "Design and experimental study on a hybrid adsorption refrigeration system using desiccant coated heat exchangers for efficient energy utilization," Renewable and Sustainable Energy Reviews, Elsevier, vol. 169(C).
    4. Tokarev, M.M. & Zlobin, A.A. & Aristov, Yu.I., 2019. "A new version of the large pressure jump (T-LPJ) method for dynamic study of pressure-initiated adsorptive cycles for heat storage and transformation," Energy, Elsevier, vol. 179(C), pages 542-548.
    5. He, Fang & Nagano, Katsunori & Togawa, Junya, 2023. "Performance prediction of an adsorption chiller combined with heat recovery and mass recovery by a three-dimensional model," Energy, Elsevier, vol. 277(C).
    6. He, Fang & Nagano, Katsunori & Seol, Sung-Hoon & Togawa, Junya, 2022. "Thermal performance improvement of AHP using corrugated heat exchanger by dip-coating method with mass recovery," Energy, Elsevier, vol. 239(PE).
    7. Sapienza, Alessio & Palomba, Valeria & Gullì, Giuseppe & Frazzica, Andrea & Vasta, Salvatore, 2017. "A new management strategy based on the reallocation of ads-/desorption times: Experimental operation of a full-scale 3 beds adsorption chiller," Applied Energy, Elsevier, vol. 205(C), pages 1081-1090.
    8. Chauhan, P.R. & Kaushik, S.C. & Tyagi, S.K., 2022. "Current status and technological advancements in adsorption refrigeration systems: A review," Renewable and Sustainable Energy Reviews, Elsevier, vol. 154(C).

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