Optimizing the Operational Efficiency of the Underground Hydrogen Storage Scheme in a Deep North Sea Aquifer Through Compositional Simulations.

Prashant Jadhawar; Motaz Saeed

doi:10.1016/j.est.2023.108832

Optimizing the Operational Efficiency of the Underground Hydrogen Storage Scheme in a Deep North Sea Aquifer Through Compositional Simulations.

Prashant Jadhawar^*, Motaz Saeed

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

6 Citations (Scopus)

Abstract

In this study, we evaluate the technical viability of storing hydrogen in a deep UKCS aquifer formation through a series of numerical simulations utilising the compositional simulator CMG8 GEM. Effects of various operational parameters such as injection and production rates, number and length of storage cycles, and shut-in periods on the performance of the underground hydrogen storage (UHS) process are investigated in this study. Results indicate that higher H2 operational rates degrade both the aquifer’s working capacity and H2 recovery during the withdrawal phase. This can be attributed to the dominant viscous forces at higher rates which lead to H2 viscous fingering and gas gravity override of the native aquifer water resulting in an unstable displacement of water by the H2 gas. Furthermore, analysis of simulation results shows that longer and less frequent storage cycles lead to higher storage capacity and decreased H2 retrieval. We conclude that UHS in the studied aquifer is technically feasible, however, a thorough evaluation of the operational parameters is necessary to optimise both storage capacity and H2 recovery efficiency.

Original language	English
Article number	108832
Number of pages	16
Journal	Journal of Energy Storage
Volume	73
Issue number	Part A
Early online date	31 Aug 2023
DOIs	https://doi.org/10.1016/j.est.2023.108832
Publication status	Published - 1 Dec 2023

Bibliographical note

Acknowledgement
The authors gratefully acknowledge the funding support by the Net Zero Technology Centre, UK to accomplish this work under the Hydrogen Innovation technology development Grant scheme. We also thank valuable support from a UKCS Northern North Sea operator, BatiGea Ltd., UK and the Computer Modelling Group (CMG) Ltd, Canada in this study.

Data Availability Statement

The authors do not have permission to share data.

Keywords

Energy Storage
Hydrogen Storage Project
North Sea Aquifer
Operaional Efficiency
Energy transition
Renewable energy
Underground hydrogen storage,

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1016/j.est.2023.108832Licence: CC BY

Jadhawar_etal_JES_Optimizing_The_Operational_VOR
© 2023 The Author(s). Published by Elsevier Ltd. This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/).
Final published version, 4.54 MBLicence: CC BY

3 Invited talk
1 Member of peer review panel or committee
1 Conference
1 Presentation

Geological Storage of Hydrogen and CO2 Sequestration
Prashant Jadhawar (Keynote speaker)
5 Oct 2023 → 6 Oct 2023
Activity: Disseminating Research › Invited talk
Energy Transition - The Underground Storage of Hydrogen (Key Note Speaker)
Prashant Jadhawar (Keynote speaker)
8 Feb 2023
Activity: Disseminating Research › Invited talk

File
Hydrogen Pipeline Transport to Subsurface Storage in Depleted Oil and Gas Reservoirs and Aquifers
Prashant Jadhawar (Speaker)
7 Sept 2023
Activity: Disseminating Research › Conference

Cite this

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title = "Optimizing the Operational Efficiency of the Underground Hydrogen Storage Scheme in a Deep North Sea Aquifer Through Compositional Simulations.",

abstract = "In this study, we evaluate the technical viability of storing hydrogen in a deep UKCS aquifer formation through a series of numerical simulations utilising the compositional simulator CMG8 GEM. Effects of various operational parameters such as injection and production rates, number and length of storage cycles, and shut-in periods on the performance of the underground hydrogen storage (UHS) process are investigated in this study. Results indicate that higher H2 operational rates degrade both the aquifer{\textquoteright}s working capacity and H2 recovery during the withdrawal phase. This can be attributed to the dominant viscous forces at higher rates which lead to H2 viscous fingering and gas gravity override of the native aquifer water resulting in an unstable displacement of water by the H2 gas. Furthermore, analysis of simulation results shows that longer and less frequent storage cycles lead to higher storage capacity and decreased H2 retrieval. We conclude that UHS in the studied aquifer is technically feasible, however, a thorough evaluation of the operational parameters is necessary to optimise both storage capacity and H2 recovery efficiency. ",

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author = "Prashant Jadhawar and Motaz Saeed",

note = "Acknowledgement The authors gratefully acknowledge the funding support by the Net Zero Technology Centre, UK to accomplish this work under the Hydrogen Innovation technology development Grant scheme. We also thank valuable support from a UKCS Northern North Sea operator, BatiGea Ltd., UK and the Computer Modelling Group (CMG) Ltd, Canada in this study. ",

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AU - Saeed, Motaz

N1 - Acknowledgement The authors gratefully acknowledge the funding support by the Net Zero Technology Centre, UK to accomplish this work under the Hydrogen Innovation technology development Grant scheme. We also thank valuable support from a UKCS Northern North Sea operator, BatiGea Ltd., UK and the Computer Modelling Group (CMG) Ltd, Canada in this study.

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N2 - In this study, we evaluate the technical viability of storing hydrogen in a deep UKCS aquifer formation through a series of numerical simulations utilising the compositional simulator CMG8 GEM. Effects of various operational parameters such as injection and production rates, number and length of storage cycles, and shut-in periods on the performance of the underground hydrogen storage (UHS) process are investigated in this study. Results indicate that higher H2 operational rates degrade both the aquifer’s working capacity and H2 recovery during the withdrawal phase. This can be attributed to the dominant viscous forces at higher rates which lead to H2 viscous fingering and gas gravity override of the native aquifer water resulting in an unstable displacement of water by the H2 gas. Furthermore, analysis of simulation results shows that longer and less frequent storage cycles lead to higher storage capacity and decreased H2 retrieval. We conclude that UHS in the studied aquifer is technically feasible, however, a thorough evaluation of the operational parameters is necessary to optimise both storage capacity and H2 recovery efficiency.

AB - In this study, we evaluate the technical viability of storing hydrogen in a deep UKCS aquifer formation through a series of numerical simulations utilising the compositional simulator CMG8 GEM. Effects of various operational parameters such as injection and production rates, number and length of storage cycles, and shut-in periods on the performance of the underground hydrogen storage (UHS) process are investigated in this study. Results indicate that higher H2 operational rates degrade both the aquifer’s working capacity and H2 recovery during the withdrawal phase. This can be attributed to the dominant viscous forces at higher rates which lead to H2 viscous fingering and gas gravity override of the native aquifer water resulting in an unstable displacement of water by the H2 gas. Furthermore, analysis of simulation results shows that longer and less frequent storage cycles lead to higher storage capacity and decreased H2 retrieval. We conclude that UHS in the studied aquifer is technically feasible, however, a thorough evaluation of the operational parameters is necessary to optimise both storage capacity and H2 recovery efficiency.

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KW - Hydrogen Storage Project

KW - North Sea Aquifer

KW - Operaional Efficiency

KW - Energy transition

KW - Renewable energy

KW - Underground hydrogen storage,

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JO - Journal of Energy Storage

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M1 - 108832

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Optimizing the Operational Efficiency of the Underground Hydrogen Storage Scheme in a Deep North Sea Aquifer Through Compositional Simulations.

Abstract

Bibliographical note

Data Availability Statement

Keywords

UN SDGs

Access to Document

Fingerprint

Activities

Geological Storage of Hydrogen and CO2 Sequestration

Energy Transition - The Underground Storage of Hydrogen (Key Note Speaker)

Hydrogen Pipeline Transport to Subsurface Storage in Depleted Oil and Gas Reservoirs and Aquifers

Cite this