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Numerical study on the hydrodynamic and thermodynamic properties of compressed carbon dioxide energy storage in aquifers

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  • Li, Yi
  • Yu, Hao
  • Li, Yi
  • Liu, Yaning
  • Zhang, Guijin
  • Tang, Dong
  • Jiang, Zhongming

Abstract

Solving the undesirable intermittence and fluctuation problems of renewable energy production needs complementary energy storage on a large scale. Compressed air energy storage in caverns (CAES-C) has been verified as an effective technique. To further improve the energy storage efficiency and save costs, compressed air energy storage in aquifers (CAES-A) and compressed carbon dioxide energy storage in aquifers (CCES-A) were proposed successively. However, the operation performances of CCES-A, especially the hydrodynamic and thermodynamic properties of its underground components (the wellbore-reservoir system), are not clear. Here we introduce a coupled wellbore and reservoir model, T2WELL-ECO2N, initially used for geologic carbon sequestration simulation, for simulating the dynamics of CO2 injection and production through wellbore in both the construction and operation stages of CCES-A. The temperature, pressure, CO2 saturation and transfer, energy efficiency, maximum system cycle times, total stress change induced by CO2 injection in aquifer, and sensitivity analysis of permeability in the wellbore-reservoir system of the designed CCES-A are comprehensively studied. The simulation results show that during the operation stage the CO2 is supercritical and fluctuates in both wellbore and aquifer where the CO2 saturation decreases and CO2 bubble generally moves to the central and lower parts of the target aquifer rather than the outside direction. The system itself effectively alleviates the loss of CO2 mass from the side walls of the aquifer. The fact that the cold CO2 zone in the aquifer can continuously receive energy by heat transfer from the surroundings helps the energy efficiency of the CCES-A system gradually increase, and even reach 1.1. The system cycle times exceed 1000 days when the aquifer permeability is larger than 5.0 × 10−13 m2, indicating that CCES-A needs less time to reconstruct the cushion gas compared with CAES-A and can lower the operating cost accordingly.

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  • Li, Yi & Yu, Hao & Li, Yi & Liu, Yaning & Zhang, Guijin & Tang, Dong & Jiang, Zhongming, 2020. "Numerical study on the hydrodynamic and thermodynamic properties of compressed carbon dioxide energy storage in aquifers," Renewable Energy, Elsevier, vol. 151(C), pages 1318-1338.
    • Handle: RePEc:eee:renene:v:151:y:2020:i:c:p:1318-1338
    DOI: 10.1016/j.renene.2019.11.135
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    References listed on IDEAS

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    1. Wang, Zhiwen & Xiong, Wei & Ting, David S.-K. & Carriveau, Rupp & Wang, Zuwen, 2016. "Conventional and advanced exergy analyses of an underwater compressed air energy storage system," Applied Energy, Elsevier, vol. 180(C), pages 810-822.
    2. Jian Xie & Keni Zhang & Litang Hu & Yongsheng Wang & Maoshan Chen, 2015. "Understanding the carbon dioxide sequestration in low‐permeability saline aquifers in the Ordos Basin with numerical simulations," Greenhouse Gases: Science and Technology, Blackwell Publishing, vol. 5(5), pages 558-576, October.
    3. Zakeri, Behnam & Syri, Sanna, 2015. "Electrical energy storage systems: A comparative life cycle cost analysis," Renewable and Sustainable Energy Reviews, Elsevier, vol. 42(C), pages 569-596.
    4. Zhibing Yang & Auli Niemi & Liang Tian & Saba Joodaki & Mikael Erlström, 2015. "Modeling of pressure build‐up and estimation of maximum injection rate for geological CO2 storage at the South Scania site, Sweden," Greenhouse Gases: Science and Technology, Blackwell Publishing, vol. 5(3), pages 277-290, June.
    5. Haisheng Chen & Xinjing Zhang & Jinchao Liu & Chunqing Tan, 2013. "Compressed Air Energy Storage," Chapters, in: Ahmed F. Zobaa (ed.), Energy Storage - Technologies and Applications, IntechOpen.
    6. Li, Qi & Wei, Ya-Ni & Liu, Guizhen & Lin, Qing, 2014. "Combination of CO2 geological storage with deep saline water recovery in western China: Insights from numerical analyses," Applied Energy, Elsevier, vol. 116(C), pages 101-110.
    7. Zhang, Yuan & Yang, Ke & Hong, Hui & Zhong, Xiaohui & Xu, Jianzhong, 2016. "Thermodynamic analysis of a novel energy storage system with carbon dioxide as working fluid," Renewable Energy, Elsevier, vol. 99(C), pages 682-697.
    8. David Elliott, 2016. "A balancing act for renewables," Nature Energy, Nature, vol. 1(1), pages 1-3, January.
    9. Guo, Chaobin & Pan, Lehua & Zhang, Keni & Oldenburg, Curtis M. & Li, Cai & Li, Yi, 2016. "Comparison of compressed air energy storage process in aquifers and caverns based on the Huntorf CAES plant," Applied Energy, Elsevier, vol. 181(C), pages 342-356.
    10. Budt, Marcus & Wolf, Daniel & Span, Roland & Yan, Jinyue, 2016. "A review on compressed air energy storage: Basic principles, past milestones and recent developments," Applied Energy, Elsevier, vol. 170(C), pages 250-268.
    11. Julien Mouli-Castillo & Mark Wilkinson & Dimitri Mignard & Christopher McDermott & R. Stuart Haszeldine & Zoe K. Shipton, 2019. "Inter-seasonal compressed-air energy storage using saline aquifers," Nature Energy, Nature, vol. 4(2), pages 131-139, February.
    12. Guo, Chaobin & Zhang, Keni & Li, Cai & Wang, Xiaoyu, 2016. "Modelling studies for influence factors of gas bubble in compressed air energy storage in aquifers," Energy, Elsevier, vol. 107(C), pages 48-59.
    13. Szablowski, Lukasz & Krawczyk, Piotr & Badyda, Krzysztof & Karellas, Sotirios & Kakaras, Emmanuel & Bujalski, Wojciech, 2017. "Energy and exergy analysis of adiabatic compressed air energy storage system," Energy, Elsevier, vol. 138(C), pages 12-18.
    14. Curtis M. Oldenburg & Lehua Pan, 2013. "Utilization of CO 2 as cushion gas for porous media compressed air energy storage," Greenhouse Gases: Science and Technology, Blackwell Publishing, vol. 3(2), pages 124-135, April.
    15. Safaei, Hossein & Keith, David, 2014. "Compressed air energy storage with waste heat export: An Alberta case study," Scholarly Articles 13489207, Harvard Kennedy School of Government.
    16. Wang, Mingkun & Zhao, Pan & Yang, Yi & Dai, Yiping, 2015. "Performance analysis of energy storage system based on liquid carbon dioxide with different configurations," Energy, Elsevier, vol. 93(P2), pages 1931-1942.
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    Cited by:

    1. Carro, A. & Chacartegui, R. & Ortiz, C. & Carneiro, J. & Becerra, J.A., 2022. "Integration of energy storage systems based on transcritical CO2: Concept of CO2 based electrothermal energy and geological storage," Energy, Elsevier, vol. 238(PA).
    2. Li, Yi & Yu, Hao & Tang, Dong & Li, Yi & Zhang, Guijin & Liu, Yaning, 2022. "A comparison of compressed carbon dioxide energy storage and compressed air energy storage in aquifers using numerical methods," Renewable Energy, Elsevier, vol. 187(C), pages 1130-1153.
    3. Huang, Rui & Zhou, Kang & Liu, Zhan, 2022. "Reduction on the inefficiency of heat recovery storage in a compressed carbon dioxide energy storage system," Energy, Elsevier, vol. 244(PB).
    4. Zhang, Yuan & Liang, Tianyang & Yang, Ke, 2022. "An integrated energy storage system consisting of Compressed Carbon dioxide energy storage and Organic Rankine Cycle: Exergoeconomic evaluation and multi-objective optimization," Energy, Elsevier, vol. 247(C).
    5. Yi Zhang & Wenjing Li & Guodong Chen, 2022. "A Thermodynamic Model for Carbon Dioxide Storage in Underground Salt Caverns," Energies, MDPI, vol. 15(12), pages 1-20, June.
    6. Li, Yi & Yu, Hao & Xiao, Yanling & Li, Yi & Liu, Yinjiang & Luo, Xian & Tang, Dong & Zhang, Guijin & Liu, Yaning, 2023. "Numerical verification on the feasibility of compressed carbon dioxide energy storage in two aquifers," Renewable Energy, Elsevier, vol. 207(C), pages 743-764.
    7. Li, Yi & Liu, Yaning & Hu, Bin & Li, Yi & Dong, Jiawei, 2020. "Numerical investigation of a novel approach to coupling compressed air energy storage in aquifers with geothermal energy," Applied Energy, Elsevier, vol. 279(C).

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