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Modelling studies for influence factors of gas bubble in compressed air energy storage in aquifers

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  • Guo, Chaobin
  • Zhang, Keni
  • Li, Cai
  • Wang, Xiaoyu

Abstract

CAES (Compressed air energy storage) is credited with its potential ability for large-scale energy storage. Generally, it is more convenient using deep aquifers than employing underground caverns for energy storage, because of extensive presence of aquifers. During the first stage in a typical process of CAESA (compressed air energy storage in aquifers), a large amount of compressed air is injected into the target aquifer to develop an initial space (a gas bubble) for energy storage. In this study, numerical simulations were conducted to investigate the influence of aquifer's permeability, geological structure and operation parameters on the formation of gas bubble and the sustainability for the later cycling operation. The SCT (system cycle times) was designed as a parameter to evaluate the reservoir performance and the effect of operation parameters. Simulation results for pressure and gas saturation results of basic model confirm the feasibility of compressed air energy storage in aquifers. The results of different permeability cases show that, for a certain scale of CAESA system, there is an optimum permeability range for a candidate aquifer. An aquifer within this permeability range will not only satisfy the injectivity requirement but also have the best energy efficiency. Structural impact analysis indicates that the anticline structure has the best performance to hold the bubble under the same daily cycling schedule with the same initial injected air mass. In addition, our results indicate that the SCT shows a logarithmic growth as the injected air mass increase. During the formation of gas bubble, compressed air should be injected into aquifers with moderate rate and the injection can be done in several stages with different injection rate to avoid onset pressure.

Suggested Citation

  • 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.
    • Handle: RePEc:eee:energy:v:107:y:2016:i:c:p:48-59
    DOI: 10.1016/j.energy.2016.04.003
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    1. Li, Yi & Liu, Yaning & Li, Yi & Hu, Bin & Gai, Peng, 2023. "Potential influences of leakage through a high permeability path on shallow aquifers in compressed air energy storage in aquifers," Renewable Energy, Elsevier, vol. 209(C), pages 661-676.
    2. Yang, Lichao & Cai, Zuansi & Li, Cai & He, Qingcheng & Ma, Yan & Guo, Chaobin, 2020. "Numerical investigation of cycle performance in compressed air energy storage in aquifers," Applied Energy, Elsevier, vol. 269(C).
    3. Li, Yi & Pan, Lehua & Zhang, Keni & Hu, Litang & Wang, Jinsheng & Guo, Chaobin, 2017. "Numerical modeling study of a man-made low-permeability barrier for the compressed air energy storage in high-permeability aquifers," Applied Energy, Elsevier, vol. 208(C), pages 820-833.
    4. Sun, Dongmei & Chu, Zhubin & Chen, Wenyuan & Feng, Ping & Zhang, Jiaxin, 2023. "Comparison of the characteristics of compressed air energy storage in dome-shaped and horizontal aquifers based on the Pittsfield aquifer field test," Applied Energy, Elsevier, vol. 348(C).
    5. 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.
    6. 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.
    7. 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.
    8. 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).
    9. Chen, Shang & Arabkoohsar, Ahmad & Zhu, Tong & Nielsen, Mads Pagh, 2020. "Development of a micro-compressed air energy storage system model based on experiments," Energy, Elsevier, vol. 197(C).
    10. Li, Yi & Wang, Hao & Wang, Jinsheng & Hu, Litang & Wu, Xiaohua & Yang, Yabin & Gai, Peng & Liu, Yaning & Li, Yi, 2024. "The underground performance analysis of compressed air energy storage in aquifers through field testing," Applied Energy, Elsevier, vol. 366(C).
    11. Li, Yi & Yu, Hao & Li, Yi & Luo, Xian & Liu, Yinjiang & Zhang, Guijin & Tang, Dong & Liu, Yaning, 2023. "Full cycle modeling of inter-seasonal compressed air energy storage in aquifers," Energy, Elsevier, vol. 263(PD).
    12. Guo, Chaobin & Zhang, Keni & Pan, Lehua & Cai, Zuansi & Li, Cai & Li, Yi, 2017. "Numerical investigation of a joint approach to thermal energy storage and compressed air energy storage in aquifers," Applied Energy, Elsevier, vol. 203(C), pages 948-958.
    13. Bennett, Jeffrey A. & Simpson, Juliet G. & Qin, Chao & Fittro, Roger & Koenig, Gary M. & Clarens, Andres F. & Loth, Eric, 2021. "Techno-economic analysis of offshore isothermal compressed air energy storage in saline aquifers co-located with wind power," Applied Energy, Elsevier, vol. 303(C).

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