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Thermodynamic study on the effect of cold and heat recovery on performance of liquid air energy storage

Author

Listed:
  • Peng, Xiaodong
  • She, Xiaohui
  • Cong, Lin
  • Zhang, Tongtong
  • Li, Chuan
  • Li, Yongliang
  • Wang, Li
  • Tong, Lige
  • Ding, Yulong

Abstract

Liquid Air Energy Storage (LAES) is one of the most promising large-scale energy storage technologies for intermittent renewable energy. The LAES includes an air liquefaction (charging) process and a power recovery (discharging) process. In the charging process, off-peak electricity is stored in the form of liquid air; meantime, a large amount of compression heat is recovered and stored at over 200 °C for later use in the discharging process to enhance the output power of air turbines. During peak times, liquid air is pumped and heated, and then expands to generate electricity in the discharging process, with cold energy of the liquid air recovered and stored to help liquefying the air in the charging process. It is well known that the recovery and utilization of both the cold and heat energy are crucial to the LAES. However, little attention is paid on the quantity and quality of the cold and heat energy. This paper carries out thermodynamic analyses on the recovered cold and heat energy based on steady-state modelling. It is found that the cold energy has a much more effect on the LAES than the heat energy; the cold energy loss leads to a decrease rate of the round trip efficiency, which is ∼7 times of that caused by the heat energy loss. In addition, the recovered cold energy from the liquid air is insufficient to cool the compressed air to the lowest temperature with the shortage of ∼18% and liquid air yield does not achieve the maximum in the charging process; external free cold sources would be needed to further increase the liquid air yield, and the round trip efficiency could easily break through 60%. Unlike the cold energy, 20–45% of the stored heat energy is in excess and cannot be efficiently used in the discharging process; we propose to use the excess heat to drive an Organic Rankine Cycle (ORC) for power generation. The ORC is considered to work at two different cold sources: the ambient and the sub-ambient. The sub-ambient cold source is generated through an Absorption Refrigeration Cycle (ARC) by consuming part of the excess heat. The combinations of the LAES and ORC with ambient and sub-ambient cold sources are denoted as LAES-ORC and LAES-ORC-ARC, respectively. Comparisons are made among the LAES, LAES-ORC and the LAES-ORC-ARC. The results show that both the LAES-ORC and LAES-ORC-ARC could achieve a much higher round trip efficiency than the LAES, with the maximum improvement of 17.6% and 13.1% under the studied conditions, respectively. It is concluded that the LAES-ORC has a simpler configuration with a better performance than the LAES-ORC-ARC configuration.

Suggested Citation

  • Peng, Xiaodong & She, Xiaohui & Cong, Lin & Zhang, Tongtong & Li, Chuan & Li, Yongliang & Wang, Li & Tong, Lige & Ding, Yulong, 2018. "Thermodynamic study on the effect of cold and heat recovery on performance of liquid air energy storage," Applied Energy, Elsevier, vol. 221(C), pages 86-99.
    • Handle: RePEc:eee:appene:v:221:y:2018:i:c:p:86-99
    DOI: 10.1016/j.apenergy.2018.03.151
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    References listed on IDEAS

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    1. Peng, Hao & Yang, Yu & Li, Rui & Ling, Xiang, 2016. "Thermodynamic analysis of an improved adiabatic compressed air energy storage system," Applied Energy, Elsevier, vol. 183(C), pages 1361-1373.
    2. Rodrigues, E.M.G. & Godina, R. & Santos, S.F. & Bizuayehu, A.W. & Contreras, J. & Catalão, J.P.S., 2014. "Energy storage systems supporting increased penetration of renewables in islanded systems," Energy, Elsevier, vol. 75(C), pages 265-280.
    3. Morgan, Robert & Nelmes, Stuart & Gibson, Emma & Brett, Gareth, 2015. "Liquid air energy storage – Analysis and first results from a pilot scale demonstration plant," Applied Energy, Elsevier, vol. 137(C), pages 845-853.
    4. Hamdy, Sarah & Morosuk, Tatiana & Tsatsaronis, George, 2017. "Cryogenics-based energy storage: Evaluation of cold exergy recovery cycles," Energy, Elsevier, vol. 138(C), pages 1069-1080.
    5. Krawczyk, Piotr & Szabłowski, Łukasz & Karellas, Sotirios & Kakaras, Emmanuel & Badyda, Krzysztof, 2018. "Comparative thermodynamic analysis of compressed air and liquid air energy storage systems," Energy, Elsevier, vol. 142(C), pages 46-54.
    6. Sciacovelli, A. & Vecchi, A. & Ding, Y., 2017. "Liquid air energy storage (LAES) with packed bed cold thermal storage – From component to system level performance through dynamic modelling," Applied Energy, Elsevier, vol. 190(C), pages 84-98.
    7. Peng, Hao & Shan, Xuekun & Yang, Yu & Ling, Xiang, 2018. "A study on performance of a liquid air energy storage system with packed bed units," Applied Energy, Elsevier, vol. 211(C), pages 126-135.
    8. Lee, Inkyu & Park, Jinwoo & Moon, Il, 2017. "Conceptual design and exergy analysis of combined cryogenic energy storage and LNG regasification processes: Cold and power integration," Energy, Elsevier, vol. 140(P1), pages 106-115.
    9. Kantharaj, Bharath & Garvey, Seamus & Pimm, Andrew, 2015. "Compressed air energy storage with liquid air capacity extension," Applied Energy, Elsevier, vol. 157(C), pages 152-164.
    10. Su, Wen & Zhao, Li & Deng, Shuai & Xu, Weicong & Yu, Zhixin, 2018. "A limiting efficiency of subcritical Organic Rankine cycle under the constraint of working fluids," Energy, Elsevier, vol. 143(C), pages 458-466.
    11. Du, S. & Wang, R.Z. & Xia, Z.Z., 2014. "Optimal ammonia water absorption refrigeration cycle with maximum internal heat recovery derived from pinch technology," Energy, Elsevier, vol. 68(C), pages 862-869.
    12. Guizzi, Giuseppe Leo & Manno, Michele & Tolomei, Ludovica Maria & Vitali, Ruggero Maria, 2015. "Thermodynamic analysis of a liquid air energy storage system," Energy, Elsevier, vol. 93(P2), pages 1639-1647.
    13. She, Xiaohui & Peng, Xiaodong & Nie, Binjian & Leng, Guanghui & Zhang, Xiaosong & Weng, Likui & Tong, Lige & Zheng, Lifang & Wang, Li & Ding, Yulong, 2017. "Enhancement of round trip efficiency of liquid air energy storage through effective utilization of heat of compression," Applied Energy, Elsevier, vol. 206(C), pages 1632-1642.
    14. Li, Yongliang & Cao, Hui & Wang, Shuhao & Jin, Yi & Li, Dacheng & Wang, Xiang & Ding, Yulong, 2014. "Load shifting of nuclear power plants using cryogenic energy storage technology," Applied Energy, Elsevier, vol. 113(C), pages 1710-1716.
    15. Abdo, Rodrigo F. & Pedro, Hugo T.C. & Koury, Ricardo N.N. & Machado, Luiz & Coimbra, Carlos F.M. & Porto, Matheus P., 2015. "Performance evaluation of various cryogenic energy storage systems," Energy, Elsevier, vol. 90(P1), pages 1024-1032.
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