References
- Allen, R., Doherty, T., & Fossum, A. F. (1982). Geotechnical issues and guidelines for storage of compressed air in excavated hard rock caverns. Technical report, Pacific Northwest Lab., Richland, WA.
- Amani, J., Oterkus, E., Areias, P., Zi, G., Nguyen-Thoi, T., & Rabczuk, T. (2016). A non-ordinary state-based peridynamics formulation for thermoplastic fracture. International Journal of Impact Engineering, 87, 83–94.
- Badnava, H., Msekh, M. A., Etemadi, E., & Rabczuk, T. (2018). An h-adaptive thermo-mechanical phase field model for fracture. Finite Elements in Analysis and Design, 138, 31–47.
- Chen, J., Jiang, W., Yang, C., Yin, X., Fu, S., & Yu, K. (2007). Study on engineering thermal analysis of gas storage in salt formation during gas injection and production. Chinese Journal of Rock Mechanics and Engineering, 26(Supp 1), 2887–2894.
- Connolly, D., Lund, H., Finn, P., Mathiesen, B. V., & Leahy, M. (2011). Practical operation strategies for pumped hydroelectric energy storage (PHES) utilising electricity price arbitrage. Energy Policy, 39(7), 4189–4196.
- Crotogino, F., Mohmeyer, K., & Scharf, R. (2001). Huntroft CAES: more than 20 years of successful operation. In Solution Mining Research Institute (SMRI) Spring 2001 Meeting, pp 15–18, Orlando, FL.
- Ishihata, T. (1997). Underground compressed air storage facility for CAES-G/T power plant utilizing an airtight lining. International Society for Rock Mechanics, 5(1), 17–21.
- Kim, H.-M., Rutqvist, J., & Choi, B.-H. (2012). Feasibility analysis of underground compressed air energy storage in lined rock caverns using the tough-flac simulator. In TOUGH Symposium, pp. 17–19, Berkeley, California: Lawrence Berkeley National Laboratory.
- Kim, H.-M., Rutqvist, J., Jeong, J.-H., Choi, B.-H., Ryu, D.-W., & Song, W.-K. (2013). Characterizing excavation damaged zone and stability of pressurized lined rock caverns for underground compressed air energy storage. Rock Mechanics and Rock Engineering, 46(5), 1113–1124.
- Kim, H.-M., Rutqvist, J., Ryu, D.-W., Choi, B.-H., Sunwoo, C., & Song, W.-K. (2012). Exploring the concept of compressed air energy storage (CAES) in lined rock caverns at shallow depth: A modeling study of air tightness and energy balance. Applied Energy, 92, 653–667.
- Kovári, K. (1993). Basic consideration on storage of compressed natural gas in rock chambers. Rock Mechanics and Rock Engineering, 26(1), 1–27.
- Kushnir, R., Dayan, A., & Ullmann, A. (2012). Temperature and pressure variations within compressed air energy storage caverns. International Journal of Heat and Mass Transfer, 55(21), 5616–5630.
- Kushnir, R., Ullmann, A., & Dayan, A. (2012). Thermodynamic and hydrodynamic response of compressed air energy storage reservoirs: A review. Reviews in Chemical Engineering, 28, 123–148.
- Lindblom, U. (1997). Design criteria for the Brooklyn union gas storage caverns at JFK airport, new york. International Journal of Rock Mechanics and Mining Sciences, 34(3–4), 179.e1.
- Perazzelli, P. & Anagnostou, G. (2016). Design issues for compressed air energy storage in sealed underground cavities. Journal of Rock Mechanics and Geotechnical Engineering, 8(3), 314–328.
- Rabizadeh, E., Bagherzadeh, A. S., & Rabczuk, T. (2016). Goal-oriented error estimation and adaptive mesh refinement in dynamic coupled thermoelasticity. Computers & Structures, 173, 187–211.
- Raju, M. & Khaitan, S. K. (2012). Modeling and simulation of compressed air storage in caverns: A case study of the huntorf plant. Applied Energy, 89(1), 474–481.
- Rutqvist, J., Kim, H.-M., Ryu, D.-W., Synn, J.-H., & Song, W.-K. (2012). Modeling of coupled thermodynamic and geomechanical performance of underground compressed air energy storage in lined rock caverns. International Journal of Rock Mechanics and Mining Sciences, 52, 71–81.
- Song, W., Ryu, D., & Lee, Y. (2011). Stability analysis of concrete plugs in a pilot cavern for compressed air energy storage. In 12th ISRM Congress. International Society for Rock Mechanics. London: CRC Press.
- Stille, H., Johansson, J., & Sturk, R. (1994). High pressure storage of gas in lined shallow rock caverns e results from field tests. In A. Balkema (Ed.), Proceedings of the SPE/ISRM Conference (pp. 689–696). Rotterdam: Society of Petroleum Engineers.
- Wang, Z. (2005). Principles of chemical engineering. Beijing, China: Chemical Industry Press.
- Xia, C.-C., Zhou, S.-W., Zhang, P.-Y., Hu, Y.-S., & Zhou, Y. (2015). Strength criterion for rocks subjected to cyclic stress and temperature variations. Journal of Geophysics and Engineering, 12(5), 753.
- Xia, C., Zhou, Y., Zhou, S., Zhang, P., & Wang, F. (2015). A simplified and unified analytical solution for temperature and pressure variations in compressed air energy storage caverns. Renewable Energy, 74, 718–726.
- Zhang, J. & Zhao, T. (1987). A handbook for the thermo-physical properties of engineering materials. Beijing, China: New Era Press.
- Zheng, Y., Zhu, H., Fang, Z., & Liu, H. (2013). The stability analysis and design theory of surrounding rock of underground engineering. Beijing, China: China Communications Press.
- Zhou, S.-W., Xia, C.-C., Du, S.-G., Zhang, P.-Y., & Zhou, Y. (2015). An analytical solution for mechanical responses induced by temperature and air pressure in a lined rock cavern for underground compressed air energy storage. Rock Mechanics and Rock Engineering, 48(2), 749–770.
- Zhou, S.-W., Xia, C., Hu, Y., Zhou, Y., & Zhang, P. (2015). Damage modeling of basaltic rock subjected to cyclic temperature and uniaxial stress. International Journal of Rock Mechanics and Mining Sciences, 77, 163–173.
- Zhou, S.-W., Xia, C.-C., Zhao, H.-B., Mei, S.-H., & Zhou, Y. (2017b). Numerical simulation for the coupled thermo-mechanical performance of a lined rock cavern for underground compressed air energy storage. Journal of Geophysics and Engineering, 14(6), 1382.
- Zhou, S.-W., Xia, C.-C., Zhao, H.-B., Mei, S.-H., & Zhou, Y. (2017c). Statistical damage constitutive model for rocks subjected to cyclic stress and cyclic temperature. Acta Geophysica, 65(5), 893–906.
- Zhou, S.-W., Xia, C., & Zhou, Y. (2017a). A theoretical approach to quantify the effect of random cracks on rock deformation in uniaxial compression. Journal of Geophysics and Engineering 15, 627–637.
- Zhu, H., Wang, Q., & Zhuang, X. (2016). A nonlinear semi-concurrent multiscale method for fractures. International Journal of Impact Engineering, 87, 65–82.
- Zhuang, X., Huang, R., Liang, C., & Rabczuk, T. (2014). A coupled thermo-hydro-mechanical model of jointed hard rock for compressed air energy storage. Mathematical Problems in Engineering, 2014, 1–10.
- Zhuang, X., Wang, Q., & Zhu, H. (2017). Multiscale modelling of hydro-mechanical couplings in quasi-brittle materials. International Journal of Fracture, 204(1), 1–27.