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Main Authors: Manoorkar, Sojwal, Kalyoncu, Gülce, Omar, Hamdi, Barbaix, Soetkin, Ceursters, Dominique, Latinis, Maxime, Van Offenwert, Stefanie, Bultreys, Tom
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2411.14122
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author Manoorkar, Sojwal
Kalyoncu, Gülce
Omar, Hamdi
Barbaix, Soetkin
Ceursters, Dominique
Latinis, Maxime
Van Offenwert, Stefanie
Bultreys, Tom
author_facet Manoorkar, Sojwal
Kalyoncu, Gülce
Omar, Hamdi
Barbaix, Soetkin
Ceursters, Dominique
Latinis, Maxime
Van Offenwert, Stefanie
Bultreys, Tom
contents Underground hydrogen storage in saline aquifers is a potential solution for seasonal renewable energy storage. Among potential storage sites, facilities used for underground natural gas storage have advantages, including well-characterized cyclical injection-withdrawal behavior and partially reusable infrastructure. However, the differences between hydrogen-brine and natural gas-brine flow, particularly through fractures in the reservoir and the sealing caprock, remain unclear due to the complexity of two-phase flow. Therefore, we investigate fracture relative permeability for hydrogen versus methane (natural gas) and nitrogen (commonly used in laboratories). Steady-state relative permeability experiments were conducted at 10 MPa on fractured carbonate rock from the Loenhout natural gas storage in Belgium, where gas flows through {\textmu}m-to-mm scale fractures. Our results reveal that the hydrogen exhibits similar relative permeability curves to methane, but both are significantly lower than those measured for nitrogen. This implies that nitrogen cannot reliably serve as a proxy for hydrogen at typical reservoir pressures. The low relative permeabilities for hydrogen and methane indicate strong fluid phase interference, which traditional relative permeability models fail to capture. This is supported by our observation of periodic pressure fluctuations associated with intermittent fluid connectivity for hydrogen and methane. In conclusion, our findings suggest that the fundamental flow properties of fractured rocks are complex but relatively similar for hydrogen and natural gas. This is an important insight for predictive modeling of the conversion of Loenhout and similar natural gas storage facilities, which is crucial to evaluate their hydrogen storage efficiency and integrity.
format Preprint
id arxiv_https___arxiv_org_abs_2411_14122
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Pore-scale imaging of hydrogen and methane storage in fractured aquifer rock: The impact of gas type on relative permeability
Manoorkar, Sojwal
Kalyoncu, Gülce
Omar, Hamdi
Barbaix, Soetkin
Ceursters, Dominique
Latinis, Maxime
Van Offenwert, Stefanie
Bultreys, Tom
Fluid Dynamics
Underground hydrogen storage in saline aquifers is a potential solution for seasonal renewable energy storage. Among potential storage sites, facilities used for underground natural gas storage have advantages, including well-characterized cyclical injection-withdrawal behavior and partially reusable infrastructure. However, the differences between hydrogen-brine and natural gas-brine flow, particularly through fractures in the reservoir and the sealing caprock, remain unclear due to the complexity of two-phase flow. Therefore, we investigate fracture relative permeability for hydrogen versus methane (natural gas) and nitrogen (commonly used in laboratories). Steady-state relative permeability experiments were conducted at 10 MPa on fractured carbonate rock from the Loenhout natural gas storage in Belgium, where gas flows through {\textmu}m-to-mm scale fractures. Our results reveal that the hydrogen exhibits similar relative permeability curves to methane, but both are significantly lower than those measured for nitrogen. This implies that nitrogen cannot reliably serve as a proxy for hydrogen at typical reservoir pressures. The low relative permeabilities for hydrogen and methane indicate strong fluid phase interference, which traditional relative permeability models fail to capture. This is supported by our observation of periodic pressure fluctuations associated with intermittent fluid connectivity for hydrogen and methane. In conclusion, our findings suggest that the fundamental flow properties of fractured rocks are complex but relatively similar for hydrogen and natural gas. This is an important insight for predictive modeling of the conversion of Loenhout and similar natural gas storage facilities, which is crucial to evaluate their hydrogen storage efficiency and integrity.
title Pore-scale imaging of hydrogen and methane storage in fractured aquifer rock: The impact of gas type on relative permeability
topic Fluid Dynamics
url https://arxiv.org/abs/2411.14122