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An absorption–compression refrigeration system driven by a mid-temperature heat source for low-temperature applications

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  • Chen, Yi
  • Han, Wei
  • Jin, Hongguang

Abstract

An ammonia–water absorption refrigeration system is a promising way to make use of waste heat to generate cooling energy for freezing applications. When the refrigeration temperature is below −30 °C, the conventional absorption system cannot be adopted because its performance decreases dramatically. In this work, a totally heat-driven absorption–compression refrigeration system is proposed to produce cooling energy at temperatures of −40 °C to −55 °C. The proposed system comprises a heat-driven power generation subsystem using an ammonia–water mixture as the working fluid and an absorption–compression refrigeration subsystem. Simulation results showed that the coefficient of performance and the cooling capacity per unit mass of flue gas reach 0.357 and 84.18 kJ kg−1, respectively. The results of a process energy analysis showed that the cycle coupling configuration of the proposed system enhances its energy cascade utilization. Furthermore, the energy saving mechanism of the proposed system was elucidated by means of an exergy analysis and a pinch point analysis. Finally, a more comprehensive comparison with a heat-driven double-stage compression refrigeration system was conducted to show the advantage of the proposed system. This work may provide a new way to produce low-temperature cooling energy by using a mid-temperature heat source.

Suggested Citation

  • Chen, Yi & Han, Wei & Jin, Hongguang, 2015. "An absorption–compression refrigeration system driven by a mid-temperature heat source for low-temperature applications," Energy, Elsevier, vol. 91(C), pages 215-225.
  • Handle: RePEc:eee:energy:v:91:y:2015:i:c:p:215-225
    DOI: 10.1016/j.energy.2015.08.046
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    2. Wu, Wei & Ran, Siyuan & Shi, Wenxing & Wang, Baolong & Li, Xianting, 2016. "NH3-H2O water source absorption heat pump (WSAHP) for low temperature heating: Experimental investigation on the off-design performance," Energy, Elsevier, vol. 115(P1), pages 697-710.
    3. Mingzhang Pan & Huan Zhao & Dongwu Liang & Yan Zhu & Youcai Liang & Guangrui Bao, 2020. "A Review of the Cascade Refrigeration System," Energies, MDPI, vol. 13(9), pages 1-26, May.
    4. Akbari Kordlar, M. & Mahmoudi, S.M.S. & Talati, F. & Yari, M. & Mosaffa, A.H., 2019. "A new flexible geothermal based cogeneration system producing power and refrigeration, part two: The influence of ambient temperature," Renewable Energy, Elsevier, vol. 134(C), pages 875-887.
    5. Li, Yinlong & Liu, Guoqiang & Chen, Qi & Yan, Gang, 2023. "Progress of auto-cascade refrigeration systems performance improvement: Composition separation, shift and regulation," Renewable and Sustainable Energy Reviews, Elsevier, vol. 187(C).
    6. Gado, Mohamed G. & Ookawara, Shinichi & Nada, Sameh & El-Sharkawy, Ibrahim I., 2021. "Hybrid sorption-vapor compression cooling systems: A comprehensive overview," Renewable and Sustainable Energy Reviews, Elsevier, vol. 143(C).

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