Print Email Facebook Twitter Impact of experimentally measured relative permeability hysteresis on reservoir-scale performance of underground hydrogen storage (UHS) Title Impact of experimentally measured relative permeability hysteresis on reservoir-scale performance of underground hydrogen storage (UHS) Author Bo, Z. (TU Delft Reservoir Engineering; University of Queensland) Boon, M.M. (TU Delft Reservoir Engineering) Hajibeygi, H. (TU Delft Reservoir Engineering) Hurter, Suzanne (University of Queensland; TNO) Date 2023 Abstract Underground Hydrogen Storage (UHS) is an emerging large-scale energy storage technology. Researchers are investigating its feasibility and performance, including its injectivity, productivity, and storage capacity through numerical simulations. However, several ad-hoc relative permeability and capillary pressure functions have been used in the literature, with no direct link to the underlying physics of the hydrogen storage and production process. Recent relative permeability measurements for the hydrogen-brine system show very low hydrogen relative permeability and strong liquid phase hysteresis, very different to what has been observed for other fluid systems for the same rock type. This raises the concern as to what extend the existing studies in the literature are able to reliably quantify the feasibility of the potential storage projects. In this study, we investigate how experimentally measured hydrogen-brine relative permeability hysteresis affects the performance of UHS projects through numerical reservoir simulations. Relative permeability data measured during a hydrogen-water core-flooding experiment within ADMIRE project is used to design a relative permeability hysteresis model. Next, numerical simulation for a UHS project in a generic braided-fluvial water-gas reservoir is performed using this hysteresis model. A performance assessment is carried out for several UHS scenarios with different drainage relative permeability curves, hysteresis model coefficients, and injection/production rates. Our results show that both gas and liquid relative permeability hysteresis play an important role in UHS irrespective of injection/production rate. Ignoring gas hysteresis may cause up to 338% of uncertainty on cumulative hydrogen production, as it has negative effects on injectivity and productivity due to the resulting limited variation range of gas saturation and pressure during cyclic operations. In contrast, hysteresis in the liquid phase relative permeability resolves this issue to some extent by improving the displacement of the liquid phase. Finally, implementing relative permeability curves from other fluid systems during UHS performance assessment will cause uncertainty in terms of gas saturation and up to 141% underestimation on cumulative hydrogen production. These observations illustrate the importance of using relative permeability curves characteristic of hydrogen-brine system for assessing the UHS performances. Subject Relative permeability hysteresisReservoir simulationUnderground hydrogen storage To reference this document use: http://resolver.tudelft.nl/uuid:41b31770-b8a4-4f0a-a7cb-5571aad5df96 DOI https://doi.org/10.1016/j.ijhydene.2022.12.270 ISSN 0360-3199 Source International Journal of Hydrogen Energy, 48 (36), 13527-13542 Part of collection Institutional Repository Document type journal article Rights © 2023 Z. Bo, M.M. Boon, H. Hajibeygi, Suzanne Hurter Files PDF 1_s2.0_S0360319922061316_main.pdf 3.38 MB Close viewer /islandora/object/uuid:41b31770-b8a4-4f0a-a7cb-5571aad5df96/datastream/OBJ/view