AUTHOR=Ding Ya-Long , Wang Hua-Qin , Lv Tao TITLE=Effect of Gas Exchange Interval on CH4 Recovery Efficiency and Study of Mechanism of CH4 Hydrate Replacement by CO2 Mixture JOURNAL=Frontiers in Energy Research VOLUME=9 YEAR=2021 URL=https://www.frontiersin.org/journals/energy-research/articles/10.3389/fenrg.2021.760235 DOI=10.3389/fenrg.2021.760235 ISSN=2296-598X ABSTRACT=

As an environment-friendly natural gas hydrate exploitation method, CO₂ replacement method can not only achieve the purpose of mining natural gas hydrate, but also store the current greenhouse gas CO₂ in the form of hydrate on the seabed, and maintain the stratum stability of hydrate deposit area. In order to improve the rate and efficiency of CH₄-CO₂ replacement reaction, researchers proposed to use CO₂ contained gas mixture instead of pure CO₂ to replace CH₄ in natural gas hydrate. Based our previous work about CH₄ hydrate recovery with 40% CO₂ + 60% H₂, in this study, the effect of gas concentration in gas phase on final CH₄ recovery are investigated by implying different time interval of gas exchange operation. Experimental results show that The CH₄ recovery efficiency is 10.41 when the gas exchange is continues through the whole replacement process, and CH₄ recovery efficiency changes to 12.25, 32.24 and 28.86 when gas exchange operation is carried out every 12, 24, 36 h. Indicating that replaced CH₄ needs to be discharged in time to avoid CH₄ molecules being replaced to form hydrates again, and it is necessary to accurately control the time interval of gas exchange operation to avoid insufficient contact time between CO₂ and H₂ molecules and CH₄ hydrate, which affects the final replacement efficiency. In addition, the mechanism of CO₂ gas mixture containing small gas molecule such as H₂, N₂ are studied. The results indicate that when CO₂ containing small molecules such as H₂ and N₂ displace CH₄ hydrate, the existence of small molecules (H₂, N₂) can give rise to decompose the hydrate lattice and release CH₄ gas. If the gas molecules (CO₂, N₂, H₂, CH₄) in the gas phase have enough driving force to enter the hydrate lattice and remain stability, CH₄ hydrate will not decompose completely; If not, CH₄ hydrate will be completely decomposed.