A technical review on underground hydrogen storage potential in porous media: A dynamic reservoir simulation approach
多孔質媒体における地下水素貯蔵の可能性に関する技術的レビュー:動的リザーバシミュレーションアプローチ (AI 翻訳)
Opara. Stanley Uchenna, Okere. Chinedu J
🤖 gxceed AI 要約
日本語
本論文は、水素をクリーンエネルギー源として大規模貯蔵するための地下貯留層(枯渇油ガス層など)の可能性を、動的リザーバシミュレーションを用いて技術的にレビューしている。ワーキングガスとクッションガスの区別、水素漏洩防止、地質・工学的選定基準を議論し、CMGソフトウェアによる感受性分析で注入圧力や浸透率などの影響を評価した。
English
This paper reviews underground hydrogen storage potential in porous media using dynamic reservoir simulation. It distinguishes working gas and cushion gas, discusses leakage prevention, and geological/engineering selection criteria. Sensitivity analysis with CMG software evaluates injection pressure, permeability, etc.
Unofficial AI-generated summary based on the public title and abstract. Not an official translation.
📝 gxceed 編集解説 — Why this matters
日本のGX文脈において
日本は水素社会実現に向け大規模貯蔵技術が不可欠であり、本レビューは枯渇ガス田等を活用した地下貯蔵の実装に技術的示唆を与える。特に、SSBJやGX基本方針での水素活用促進と連動し、安全性・経済性評価に寄与する。
In the global GX context
Underground hydrogen storage is critical for global hydrogen economy scalability. This paper provides a systematic simulation methodology applicable to depleted reservoirs worldwide, informing ISSB/TCFD-aligned transition planning for energy storage infrastructure.
👥 読者別の含意
🔬研究者:Provides a simulation framework and sensitivity analysis approach for hydrogen storage in porous media.
🏢実務担当者:Offers criteria for site selection and operational parameters for underground hydrogen storage projects.
🏛政策担当者:Highlights technical considerations for regulatory frameworks on hydrogen storage safety and efficiency.
📄 Abstract(原文)
As the global demand for energy continues to climb and the urgency for carbon-neutral alternatives grows, hydrogen becomes increasingly prominent as a clean energy source [1], [2]. The research reviewed underground hydrogen storage potentials, discussing the distinction between the working gas and cushion gas that are critical in maintaining pressure and optimal injection conditions. Emphasis on the similarities between underground hydrogen storage and underground gas storage was made. Various underground hydrogen storage facilities were outlined, necessitating specific criteria for adaptability. Depleted hydrocarbon deposits emerge as prevalent storage systems for hydrogen due to their existing infrastructure for gas injection and retrieval, presenting a cost-efficient conversion for underground gas storage while other geological storage options include salt domes and aquifers [3], [4]. Selection criteria for sites or structures for underground hydrogen storage demand a thorough geological and engineering analyses, considering factors such as reservoir pressure, depth, permeability, and structural integrity and adaptability. Furthermore, the need to prevent hydrogen leakage and adhere to technical, economic, and safety considerations was underscored, particularly in managing fracture pressures within the reservoir during gas injection or withdrawal. The research methodology involved developing a hypothetical reservoir model to evaluate the factors and parameters facilitating efficient hydrogen injection and withdrawal for large-scale storage. The Computer Modelling Group (CMG) reservoir simulation software was used in the research to simulate hydrogen storage and transport in porous media. Some of the model's input variables included parameters such as reservoir porosity, permeability, temperature, compressibility, and bottomhole pressure. Sensitivity runs were done on injection pressure, bottomhole pressure, permeability, and porosity to establish the significant properties that impacted hydrogen storage and the extent of their impact.
🔗 Provenance — このレコードを発見したソース
- EarthArXiv https://eartharxiv.org/repository/object/14000/download/24546/first seen 2026-07-18 04:15:16
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