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A concept for storing utility-scale electrical energy in the form of latent heat

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  • Peterson, Richard B.

Abstract

A concept is introduced here for storing utility-scale electrical energy in the form of latent heat. The storage process utilizes a boiling refrigerant at sub-ambient temperatures to freeze a latent heat storage material using electrically driven compressors. Recovery of the latent heat for electrical generation then uses vapor expansion and condensation which essentially reverses the storage process. Sensible heat storage is incorporated into the cycle to efficiently implement the concept. Both energy storage and generation are carried out under steady flow closed-loop conditions where the T-s diagram is similar to a Rankine cycle. From a thermodynamic perspective, work is supplied to the system while heat is transferred to the surroundings from the latent heat store. The reverse process generates work while using heat supplied by the surroundings. An analysis with expander/compressor isentropic efficiencies and small temperature differentials for the heat transfer processes can give projected round trip efficiencies in the 50–60% range using a common refrigerant. One of the attractive features of this approach is the ability to use different ambient temperatures for storage and generation. Exploiting diurnal temperature differences or sources of low grade heat (50–90 °C) significantly increases the apparent round trip storage efficiency.

Suggested Citation

  • Peterson, Richard B., 2011. "A concept for storing utility-scale electrical energy in the form of latent heat," Energy, Elsevier, vol. 36(10), pages 6098-6109.
  • Handle: RePEc:eee:energy:v:36:y:2011:i:10:p:6098-6109
    DOI: 10.1016/j.energy.2011.08.003
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    Cited by:

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    3. Peng Hu & Gao-Wei Zhang & Long-Xiang Chen & Ming-Hou Liu, 2017. "Theoretical Analysis for Heat Transfer Optimization in Subcritical Electrothermal Energy Storage Systems," Energies, MDPI, vol. 10(2), pages 1-15, February.
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    6. Baik, Young-Jin & Heo, Jaehyeok & Koo, Junemo & Kim, Minsung, 2014. "The effect of storage temperature on the performance of a thermo-electric energy storage using a transcritical CO2 cycle," Energy, Elsevier, vol. 75(C), pages 204-215.
    7. Yang, Zhao & Wu, Xi, 2013. "Retrofits and options for the alternatives to HCFC-22," Energy, Elsevier, vol. 59(C), pages 1-21.
    8. Zhang, Yanchao & Xie, Zhenzhen, 2022. "Thermodynamic efficiency and bounds of pumped thermal electricity storage under whole process ecological optimization," Renewable Energy, Elsevier, vol. 188(C), pages 711-720.
    9. Xiao, X. & Zhang, P., 2015. "Numerical and experimental study of heat transfer characteristics of a shell-tube latent heat storage system: Part II – Discharging process," Energy, Elsevier, vol. 80(C), pages 177-189.
    10. Morandin, Matteo & Maréchal, François & Mercangöz, Mehmet & Buchter, Florian, 2012. "Conceptual design of a thermo-electrical energy storage system based on heat integration of thermodynamic cycles – Part A: Methodology and base case," Energy, Elsevier, vol. 45(1), pages 375-385.
    11. Datas, Alejandro & Ramos, Alba & Martí, Antonio & del Cañizo, Carlos & Luque, Antonio, 2016. "Ultra high temperature latent heat energy storage and thermophotovoltaic energy conversion," Energy, Elsevier, vol. 107(C), pages 542-549.
    12. Guido Francesco Frate & Lorenzo Ferrari & Umberto Desideri, 2020. "Rankine Carnot Batteries with the Integration of Thermal Energy Sources: A Review," Energies, MDPI, vol. 13(18), pages 1-28, September.

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