Enhanced clathrate hydrate formation at ambient temperatures (287.2 K) and near atmospheric pressure (0.1 MPa): Application to solidified natural gas technology

• Published in: Chemical engineering journal (Lausanne, Switzerland : 1996) Vol. 454; p. 140325
• Main Authors: Sun, Lingjie, Sun, Huilian, Yuan, Chengyang, Zhang, Lunxiang, Yang, Lei, Ling, Zheng, Zhao, Jiafei, Song, Yongchen
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 15.02.2023
• Subjects: Gas storage; Kinetic properties; Natural gas hydrate; Net-zero emissions; Thermodynamic analysis; Gas storage; Kinetic properties; Thermodynamic analysis; Natural gas hydrate; Net-zero emissions
• ISSN: 1385-8947; 1873-3212
• DOI: 10.1016/j.cej.2022.140325

•A new hydrate formation promoter was selected for methane storage.•The R141b was confirmed to improve the equilibrium condition of methane hydrate.•Thermodynamic characteristics of mixture hydrate was analysed.•Mechanism of mixture hydrate nucleation was proposed.•Gas storage procedure was optimized. Solidified natural gas is a promising alternative for improving natural gas storage owing to its safe and environmentally friendly properties. However, harsh conditions limit its application. In this study, the R141b was used as a thermodynamic promoter to enhance methane hydrate formation under mild conditions. Addition of R141b to the water system significantly shifted the phase equilibrium boundary to lower pressures and higher temperatures, in which the R141b-CH4 hydrate can be formed at 0.1 MPa and 287.2 K. Notably, the final pressure of the cell after hydrate formation was near the atmospheric pressure even at an initial pressure of 5.384 MPa, suggesting that the R141b-CH4 mixed hydrate had milder storage conditions and lower costs than liquefied natural gas (approximately 110 K). The higher initial pressure significantly reduces the induction time and increases gas storage. The mechanism of unusual kinetic characteristics of the R141b-CH4 hydrates that were observed can be attributed to the different nucleation behaviour of CH4, R141b, and R141b-CH4 hydrates. This study provides evidence of a new promoter using the solid hydrate method under mild conditions that can be alternatively used for the storage and transport of natural gas, thereby increasing the supply of clean energy without the high economic costs and safety issues.