Impact of fracture networks on the structural deformation of lined rock caverns under high internal gas pressure

Chenxi Zhao; Qinghua Lei; Zixin Zhang

doi:10.1016/j.undsp.2024.03.009

Underground Space ›› 2025, Vol. 21 ›› Issue (2) :252 -269. DOI: 10.1016/j.undsp.2024.03.009

Research article

research-article

Impact of fracture networks on the structural deformation of lined rock caverns under high internal gas pressure

Chenxi Zhao ^a^,^b
, Qinghua Lei ^c^,^*
, Zixin Zhang ^a^,^b

Author information +

History +

PDF (6066KB)

Abstract

In this paper, we develop a two-dimensional (2D) numerical model based on the finite element method to analyse the impact of fracture networks on the behaviour of pressurised lined rock caverns (LRCs). We use the discrete fracture network approach to represent the fracture system in rock obeying a power law length distribution. The LRC consisting of an inner steel lining and an outer reinforced concrete is situated within the rock mass characterised by spatially distributed and intersected fractures. An elasto-brittle constitutive relationship is adopted to characterise the deformation/failure of intact rocks, while the classical Mazars damage model is used to simulate the cracking of concrete linings. For pre-existing fractures in rock, a non-linear stress-displacement formulation is implemented to capture their normal and shear deformations. The 2D model, representing the horizontal cross-section of an LRC with its surrounding rock mass, is subject to a prescribed in situ stress condition. We explore various fracture network scenarios associated with different values of power law length exponent and fracture intensity. We analyse the damage evolution in rock/concrete and tangential strain in the concrete/steel linings. It is found that the damage within the rock mass mainly evolves in the form of wing cracks that emanate from the tips of pre-existing fractures. For damage development in the concrete lining, it is primarily induced by tensile cracking under cavern pressurisation. The damage emerges in the lining sections where pre-existing fractures are located in the tensile region around the cavern and either intersect with the cavern wall or could reach the cavern wall by promoting wing crack propagation. The results and insights obtained from our study have significant implications for the design optimisation and performance assessment of LRCs for sustainable hydrogen storage.

Keywords

Lined rock cavern / Discrete fracture network / Finite element method / Damage mechanics / Cavern-fracture interaction

Cite this article

Download citation ▾

Chenxi Zhao, Qinghua Lei, Zixin Zhang. Impact of fracture networks on the structural deformation of lined rock caverns under high internal gas pressure. Underground Space, 2025, 21(2): 252-269 DOI:10.1016/j.undsp.2024.03.009

登录浏览全文

4963

注册一个新账户忘记密码

Data availability

The data that support the findings of this study are available from the corresponding author upon reasonable request.

Declaration of competing interest

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

Acknowledgement

Qinghua Lei is grateful for the support from the Nordic Energy Research (Grant No. 187658). Zixin Zhang thanks for the support from the National Natural Science Foundation of China (Grant No. 42377146).

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Barton, N., & Quadros, E. (2015). Anisotropy is everywhere, to see, to measure, and to model. Rock Mechanics and Rock Engineering, 48, 1323-1339.

[2]	Bonnet, E., Bour, O., Odling, N. E., Davy, P., Main, I., Cowie, P., & Berkowitz, B. (2001). Scaling of fracture systems in geological media. Reviews of Geophysics, 39, 347-383.

[3]	Bäcklin, Å. (2022). Fossil-free steel - a joint opportunity!. HYBRIT: Fossil-free steel.

[4]	Damasceno, D. R., Spross, J., & Johansson, F. (2023a). Effect of rock joints on lined rock caverns subjected to high internal gas pressure. Journal of Rock Mechanics and Geotechnical Engineering, 15, 1625-1635.

[5]	COMSOL. (2018). COMSOL. Multiphysics ^®, 5 (5), p. 1742.

[6]	Damasceno, D.R., Spross, J., & Johansson, F. (2023b). Reliability-based design tool for gas storage in lined rock caverns. Georisk: Assessment and Management of Risk for Engineered Systems and Geohazards, (pp.1-13).

[7]	Damasceno, D. R., Spross, J., & Johansson, F. (2023c). Rock mass response for lined rock caverns subjected to high internal gas pressure. Journal of Rock Mechanics and Geotechnical Engineering, 15, 119-129.

[8]	Darcel, C., Bour, O., Davy, P., & De Dreuzy, J. R. (2003). Connectivity properties of two-dimensional fracture networks with stochastic fractal correlation. Water Resources Research, 39, 1-13.

[9]	De Dreuzy, J. R., Darcel, C., Davy, P., & Bour, O. (2004). Influence of spatial correlation of fracture centers on the permeability of twodimensional fracture networks following a power law length distribution. Water Resources Research, 40, 1-11.

[10]	Glamheden, R., & Curtis, P. (2006). Excavation of a cavern for highpressure storage of natural gas. Tunnelling and Underground Space Technology, 21, 56-67.

[11]

Heinemann, N., Alcalde, J., Miocic, J. M., Hangx, S. J. T., Kallmeyer, J., Ostertag-Henning, C., Hassanpouryouzband, A., Thaysen, E. M., Strobel, G. J., Schmidt-Hattenberger, C., Edlmann, K., Wilkinson, M., Bentham, M., Stuart Haszeldine, R., Carbonell, R., & Rudloff, A. (2021). Enabling large-scale hydrogen storage in porous media - the scientific challenges. Energy Environmental Science, 14, 853-864.

[12]	Jaeger, J., Cook, N., & Zimmerman, R. (2007). Fundamentals of rock mechanics. Oxford: Blackwell Publishing.

[13]	Jirásek, M., & Bauer, M. (2012). Numerical aspects of the crack band approach. Computers and Structures, 110-111, 60-78.

[14]	Johanasson, J. (2003). High pressure storage of gas in lined rock cavernscavern wall design principles. [Ph.D. thesis, Royal Institute of Technology].

[15]	Johansson, F., Spross, J., Damasceno, D.R., Johansson, J., & Stille, H. (2018). Investigation of research needs regarding the storage of hydrogen gas in lined rock caverns: Prestudy for work package 2.3 in HYBRIT research program 1, URL: https://api.semanticscholar.org/CorpusID:49309570.

[16]	Jongpradist, P., Tunsakul, J., Kongkitkul, W., Fadsiri, N., Arangelovski, G., & Youwai, S. (2015). High internal pressure induced fracture patterns in rock masses surrounding caverns: Experimental study using physical model tests. Engineering Geology, 197, 158-171.

[17]	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, 1113-1124.

[18]	Kim, H. M., Rutqvist, J., Kim, H., Park, D., Ryu, D. W., & Park, E. S. (2016). Failure monitoring and leakage detection for underground storage of compressed air energy in lined rock caverns. Rock Mechanics and Rock Engineering, 49, 573-584.

[19]	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.

[20]	Krevor, S., de Coninck, H., Gasda, S. E., Ghaleigh, N. S., de Gooyert, V., Hajibeygi, H., Juanes, R., Neufeld, J., Roberts, J. J., & Swennenhuis, F. (2023). Subsurface carbon dioxide and hydrogen storage for a sustainable energy future. Nature Reviews Earth and Environment, 4, 102-118.

[21]	Lei, Q., & Barton, N. (2022). On the selection of joint constitutive models for geomechanics simulation of fractured rocks. Computers and Geotechnics, 145, 104707.

[22]	Lei, Q., & Gao, K. (2018). Correlation between fracture network properties and stress variability in geological media. Geophysical Research Letters, 45, 39944006.

[23]	Lei, Q., Gholizadeh Doonechaly, N., & Tsang, C. F. (2021). Modelling fluid injection-induced fracture activation, damage growth, seismicity occurrence and connectivity change in naturally fractured rocks. International Journal of Rock Mechanics and Mining Sciences, 138, 104598.

[24]	Lei, Q., Latham, J.-P., & Tsang, C.-F. (2017a). The use of discrete fracture networks for modelling coupled geomechanical and hydrological behaviour of fractured rocks. Computers and Geotechnics, 85, 151-176.

[25]	Lei, Q., Latham, J.-P., & Xiang, J. (2016). Implementation of an empirical joint constitutive model into finite-discrete element analysis of the geomechanical behaviour of fractured rocks. Rock Mechanics and Rock Engineering, 49, 4799-4816.

[26]	Lei, Q., Latham, J. P., Xiang, J., & Tsang, C. F. (2017b). Role of natural fractures in damage evolution around tunnel excavation in fractured rocks. Engineering Geology, 231, 100-113.

[27]	Lei, Q., Latham, J.-P., Xiang, J., Tsang, C.-F., Lang, P., & Guo, L. (2014). Effects of geomechanical changes on the validity of a discrete fracture network representation of a realistic two-dimensional fractured rock. International Journal of Rock Mechanics and Mining Sciences, 70, 507-523.

[28]	Lei, Q., & Tsang, C.-F. (2021). Numerical study of fluid injection-induced deformation and seismicity in a mature fault zone with a lowpermeability fault core bounded by a densely fractured damage zone. Geomechanics for Energy and the Environment, 31, 100277.

[29]	Lei, Q., & Wang, X. (2016). Tectonic interpretation of the connectivity of a multiscale fracture system in limestone. Geophysical Research Letters, 43, 1551-1558.

[30]	Lindblom, U. (1985). A conceptual design for compressed hydrogen storage in mined caverns. International Journal of Hydrogen Energy, 10, 667-675.

[31]	Lu, M. (1998). Finite element analysis of a pilot gas storage in rock cavern under high pressure. Engineering Geology, 49, 353-361.

[32]	Lynch, S. (2012). Hydrogen embrittlement phenomena and mechanisms. Corrosion Reviews, 30, 105-123.

[33]	Mazars, J., & Grange, S. (2022). Damage modeling. In Damage and Cracking of Concrete Structures (pp.45-69). Bognor Regis: John Wiley & Sons Ltd.

[34]	Park, D., Kim, H.-M., Ryu, D.-W., Choi, B.-H., & Han, K.-C. (2013). Probability-based structural design of lined rock caverns to resist high internal gas pressure. Engineering Geology, 153, 144-151.

[35]	Perazzelli, P., & Anagnostou, G. (2016). Design issues for compressed air energy storage in sealed underground cavities. Journal of Rock Mechanics and Geotechnical Engineering, 8, 314-328.

[36]	Potyondy, D., & Cundall, P. (2004). A bonded-particle model for rock. International Journal of Rock Mechanics and Mining Sciences, 41, 1329-1364.

[37]	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.

[38]	Rutqvist, J., Wu, Y.-S., Tsang, C.-F., & Bodvarsson, G. (2002). A modeling approach for analysis of coupled multiphase fluid flow, heat transfer, and deformation in fractured porous rock. International Journal of Rock Mechanics and Mining Sciences, 39, 429-442.

[39]

Schultz, R. A., Heinemann, N., Horváth, B., Wickens, J., Miocic, J. M., Babarinde, O. O., Cao, W., Capuano, P., Dewers, T. A., Dusseault, M., Edlmann, K., Goswick, R. A., Hassanpouryouzband, A., Husain, T., Jin, W., Meng, J., Kim, S., Molaei, F., Odunlami, T., Prasad, U., Lei, Q., Schwartz, B. A., Segura, J. M., Soroush, H., Voegeli, S., Williams-Stroud, S., Yu, H., & Zhao, Q. (2023a). An overview of underground energy-related product storage and sequestration. Geological Society, London, Special Publications, 528, 15-35.

[40]

Schultz, R. A., Williams-Stroud, S., Horváth, B., Wickens, J., Bernhardt, H., Cao, W., Capuano, P., Dewers, T. A., Goswick, R. A., Lei, Q., McClure, M., Prasad, U., Schwartz, B. A., Yu, H., Voegeli, S., & Zhao, Q. (2023b). Underground energy-related product storage and sequestration: site characterization, risk analysis and monitoring. Geological Society, London, Special Publications, 528, 37-59.

[41]	Tarkowski, R. (2019). Underground hydrogen storage: Characteristics and prospects. Renewable and Sustainable Energy Reviews, 105, 86-94.

[42]	Tunsakul, J., Jongpradist, P., Kim, H. M., & Nanakorn, P. (2018). Evaluation of rock fracture patterns based on the element-free Galerkin method for stability assessment of a highly pressurized gas storage cavern. Acta Geotechnica, 13, 817-832.

[43]	Tunsakul, J., Jongpradist, P., Kongkitkul, W., Wonglert, A., & Youwai, S. (2013). Investigation of failure behavior of continuous rock mass around cavern under high internal pressure. Tunnelling and Underground Space Technology, 34, 110-123.

[44]	Tunsakul, J., Jongpradist, P., Soparat, P., Kongkitkul, W., & Nanakorn, P. (2014). Analysis of fracture propagation in a rock mass surrounding a tunnel under high internal pressure by the element-free Galerkin method. Computers and Geotechnics, 55, 78-90.

[45]	Vattenfall (2022). HYBRIT: Milestone Reached - Pilot Facility for Hydrogen Storage Up and Running. Vattenfall. https://group.vatten-fall.com/press-and-media/newsroom/2022/hybrit-milestone-reached-pilot-facility-for-hydrogen-storage-up-and-running.

[46]	Wang, L., & Lei, Q. (2023). Modelling the pre- and post-failure behaviour of faulted rock slopes based on the particle finite element method with a damage mechanics model. Computers and Geotechnics, 153, 105057.

[47]	Zhang, Y., Huang, J., Yuan, Y., & Mang, H. A. (2021). Cracking elements method with a dissipation-based arc-length approach. Finite Elements in Analysis and Design, 195, 103573.

[48]	Zhang, Y., Lackner, R., Zeiml, M., & Mang, H. A. (2015). Strong discontinuity embedded approach with standard SOS formulation: Element formulation, energy-based crack-tracking strategy, and validations. Computer Methods in Applied Mechanics and Engineering, 287, 335-366.

[49]	Zhao, C., Zhang, Z., & Lei, Q. (2021). Role of hydro-mechanical coupling in excavation-induced damage propagation, fracture deformation and microseismicity evolution in naturally fractured rocks. Engineering Geology, 289, 106169.

[50]	Zhao, C., Zhang, Z., Wang, S., & Lei, Q. (2022). Effects of fracture network distribution on excavation-induced coupled responses of pore pressure perturbation and rock mass deformation. Computers and Geotechnics, 145, 104670.

[51]	Johansson, J., Stille, H., & Sturk, R. (1995). Pilot plant for lined underground gas storage facility at graengesberg. Deeper analysis of test results ( pilotanlaeggning foer inklaedda gaslager i graengesberg. Foerdjupad analys av foersoeksresultaten) (in swedish).