摘要This paper discusses UHS characteristics, introduces the geological structures and industrial practices of UHS, and reviews UHS research current situation and main scientific problems. The main advantages of underground hydrogen storage are:1) large-scale storage, 2) long-term storage, 3) low-cost storage, and 4) higher safety. Salt caverns, depleted gas reservoirs and aquifers are three main types of geological structures suitable for UHS. There have been some operation cases of pure hydrogen storage in salt caverns, and only a few of mixed hydrogen storage has been stored in depleted gas reservoirs and aquifers. Underground hydrogen storage will be technically and economically feasible. Industrial-scale application of underground hydrogen storage technology involves geological, technical, economic, legal and social factors. The cost reduction of hydrogen production by electrolysis will be a decisive factor for implementation of the underground hydrogen storage on an industrial scale. Underground hydrogen storage began in the 1970s, but only in the 2010s did the EU and the US take it seriously, and many research and demonstration projects have been launched. In general, UHS technology is still in its infancy and not yet mature.
Abstract:This paper discusses UHS characteristics, introduces the geological structures and industrial practices of UHS, and reviews UHS research current situation and main scientific problems. The main advantages of underground hydrogen storage are:1) large-scale storage, 2) long-term storage, 3) low-cost storage, and 4) higher safety. Salt caverns, depleted gas reservoirs and aquifers are three main types of geological structures suitable for UHS. There have been some operation cases of pure hydrogen storage in salt caverns, and only a few of mixed hydrogen storage has been stored in depleted gas reservoirs and aquifers. Underground hydrogen storage will be technically and economically feasible. Industrial-scale application of underground hydrogen storage technology involves geological, technical, economic, legal and social factors. The cost reduction of hydrogen production by electrolysis will be a decisive factor for implementation of the underground hydrogen storage on an industrial scale. Underground hydrogen storage began in the 1970s, but only in the 2010s did the EU and the US take it seriously, and many research and demonstration projects have been launched. In general, UHS technology is still in its infancy and not yet mature.
出版日期: 2023-03-30
引用本文:
Zhou Qingfan. Underground Hydrogen Storage Technology: a Method for Large-scale Hydrogen Storage[J]. 中国油气, 2022, 29(6): 13-20.
Zhou Qingfan. Underground Hydrogen Storage Technology: a Method for Large-scale Hydrogen Storage. China Oil & Gas, 2022, 29(6): 13-20.
Davood Zivar, Sunil Kumar, Jalal Foroozesh. Underground hydrogen storage:A comprehensive review, International journal of hydrogen energy, 46(2021),2343-2362.
[2]
Radoslaw Tarkowski. Underground hydrogen storage:Characteristics and prospects. Renewable and Sustainable Energy Reviews,105(2019), 86-94
[3]
Jan Cihlar, David Mavins, Kees van der Leun, Picturing the value of underground gas storage to the European hydrogen system, June, 2021.
[4]
Niklas Heinemann, Juan Alcalde, b Johannes M. Miocic et al. Enabling large-scale hydrogen storage in porous media-the scientific challenges, Energy & Environmental Science, 14(2021), 853-864.
[5]
Olaf Kruck Fritz Crotogino, Ruth Prelicz, Tobias Rudolph. Overview on all Known Underground Storage Technologies for Hydrogen, Grant agreement no.:303417, Deliverable No. 3.1, 14.08.2013.
[6]
Nasiru Salahu Muhammed, Bashirul Haq, Dhafer Al Shehri et al. A review on underground hydrogen storage:Insight into geological sites, influencing factors and future outlook, Energy Reports, 8(2022), 461-499
[7]
M. Panfilov. Underground and pipeline hydrogen storage, Compendium of Hydrogen Energy Vol.2, 87-111, 2016, Elsevier Ltd.
[8]
Mark W. Shuster, Shuvajit Bhattacharya, Ian J. Duncan, et al. Hydrogen infrastructure expansion requires realistic framework, Oil & Gas Journal, May, 3rd, 2021.
[9]
Anna S. Lord, Peter H. Kobos, David J. Borns. Geologic storage of hydrogen:Scaling up to meet city transportation demands, International journal of hydrogen energy, 39 (20 14), 15570-15582.
[10]
J.B. Taylor, J.E A. Alderson, K.M. Kalyan am, et al. Technical and economic assessment of methods for the storage of large quantities of hydrogen, International Association for Hydrogen Energy, Vol.2, No. 1, pp. 5-22, 1986.
2022, Vol. 29 
