Poroelastic model in a vertically sealed gas storage: a case study from cyclic injection/production in a carbonate aquifer

Silverii, Francesca; Maccaferri, Francesco; Richter, Gregor; Cansado, Borja Gonzalez; R, Wang; Hainzl, Sebastian; Dahm, Torsten

doi:10.1093/gji/ggab268

Cited by 6 publications

(2 citation statements)

References 47 publications

(55 reference statements)

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“…The injection and production of energy-rich green fluids into underground reservoirs are influenced by the cyclical nature of demand and supply of renewable energy [55,56]. Consequently, the reservoir's pore pressure and temperature will cyclically vary, leading to potential hazards during and after operations, such as reduced strength, subsidence, or uplift [57], compromised well integrity [48], chronic H 2 leakage, reduced caprock sealing capability, and induced seismicity from fault reactivation [58,59]. The use of salt caverns for storage may also result in unintended consequences, including excessive cavern convergence (loss of storage volume) [60], roof collapse [61], fluid leakage [62], and other events [63].…”

Section: Introductionmentioning

confidence: 99%

Comprehensive review of geomechanics of underground hydrogen storage in depleted reservoirs and salt caverns

Ramesh Kumar,

Honorio,

Chandra

et al. 2023

Preprint

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Hydrogen is a promising energy carrier for a low-carbon future energy system, as it can be stored on a megaton scale (equivalent to TWh of energy) in subsurface reservoirs. However, safe and eﬀicient underground hydrogen storage requires a thorough understanding of the geomechanics of the host rock under fluid pressure fluctuations. In this context, we summarize the current state of knowledge regarding geomechanics relevant to carbon dioxide and natural gas storage in salt caverns and depleted reservoirs. We further elaborate on how this knowledge can be applied to underground hydrogen storage. The primary focus lies on the mechanical response of rocks under cyclic hydrogen injection and production, fault reactivation, the impact of hydrogen on rock properties, and other associated risks and challenges. In addition, we discuss wellbore integrity from the perspective of underground hydrogen storage. The paper provides insights into the history of energy storage, laboratory scale experiments, and analytical and simulation studies at the field scale. We also emphasize the current knowledge gaps and the necessity to enhance our understanding of the geomechanical aspects of hydrogen storage. This involves developing predictive models coupled with laboratory scale and field-scale testing, along with benchmarking methodologies.

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Section: Introductionmentioning

confidence: 99%

Comprehensive review of geomechanics of underground hydrogen storage in depleted reservoirs and salt caverns

Ramesh Kumar,

Honorio,

Chandra

et al. 2023

Preprint

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“…Additionally, the impact of inelastic deformation in a field-scale relevant test case is studied. It is worth mentioning that an important consequence of altering the subsurface stress is the subsidence/uplift; specially if the site is close to populated urban areas 74 – 76 . In this study, as a relevant test case, the Dutch Bergermeer gas field is also investigated in detail to quantify the associated uplift over a few years of cyclic loading.…”

Section: Introductionmentioning

confidence: 99%

Simulation of the inelastic deformation of porous reservoirs under cyclic loading relevant for underground hydrogen storage

Kumar

Honório

Hajibeygi

2022

Sci Rep

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Subsurface geological formations can be utilized to safely store large-scale (TWh) renewable energy in the form of green gases such as hydrogen. Successful implementation of this technology involves estimating feasible storage sites, including rigorous mechanical safety analyses. Geological formations are often highly heterogeneous and entail complex nonlinear inelastic rock deformation physics when utilized for cyclic energy storage. In this work, we present a novel scalable computational framework to analyse the impact of nonlinear deformation of porous reservoirs under cyclic loading. The proposed methodology includes three different time-dependent nonlinear constitutive models to appropriately describe the behavior of sandstone, shale rock and salt rock. These constitutive models are studied and benchmarked against both numerical and experimental results in the literature. An implicit time-integration scheme is developed to preserve the stability of the simulation. In order to ensure its scalability, the numerical strategy adopts a multiscale finite element formulation, in which coarse scale systems with locally-computed basis functions are constructed and solved. Further, the effect of heterogeneity on the results and estimation of deformation is analyzed. Lastly, the Bergermeer test case—an active Dutch natural gas storage field—is studied to investigate the influence of inelastic deformation on the uplift caused by cyclic injection and production of gas. The present study shows acceptable subsidence predictions in this field-scale test, once the properties of the finite element representative elementary volumes are tuned with the experimental data.

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Study on the long-term airtightness of salt cavern gas storage considering the permeability variation of surrounding rock

Wang,

Zhao

et al. 2024

Computers and Geotechnics

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Poroelastic model in a vertically sealed gas storage: a case study from cyclic injection/production in a carbonate aquifer

Cited by 6 publications

References 47 publications

Comprehensive review of geomechanics of underground hydrogen storage in depleted reservoirs and salt caverns

Comprehensive review of geomechanics of underground hydrogen storage in depleted reservoirs and salt caverns

Simulation of the inelastic deformation of porous reservoirs under cyclic loading relevant for underground hydrogen storage

Study on the long-term airtightness of salt cavern gas storage considering the permeability variation of surrounding rock

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