Investigation of the formation characteristics of methane hydrate in frozen porous media

The replacement technique of CO2-CH4 hydrate in naturally occurring gas hydrates is a promising method for achieving CO2 storage and CH4 recovery in permafrost regions. Revealing the formation characteristics of CH4 hydrate becomes an urgent need in porous medium below the freezing point. For this p...

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Bibliographic Details
Published in:Petroleum Science and Technology
Main Authors: Zhang, Xuemin, Zhang, Shanling, Li, Yinhui, Li, Jinping, Wang, Yingmei, Yang, Li
Format: Report
Language:English
Published: TAYLOR & FRANCIS INC 2022
Subjects:
CH4 hydrate
conversion rate
formation rate
freezing point
porous media
GAS HYDRATE
WATER
DISSOCIATION
STORAGE
SEDIMENTS
EQUILIBRIUM
PRESSURE
HUFF
ICE
Energy & Fuels
Engineering
Chemical
Petroleum
Ice
Methane hydrate
permafrost
Online Access:http://ir.giec.ac.cn/handle/344007/35872
http://ir.giec.ac.cn/handle/344007/35873
https://doi.org/10.1080/10916466.2022.2036191
Description
Summary:The replacement technique of CO2-CH4 hydrate in naturally occurring gas hydrates is a promising method for achieving CO2 storage and CH4 recovery in permafrost regions. Revealing the formation characteristics of CH4 hydrate becomes an urgent need in porous medium below the freezing point. For this purpose, the formation experiment was carried out under different conditions and the formation characteristics were systematically investigated. The result indicated that the initial pressure was the key factor affecting the formation process of CH4 hydrate. And the final pressure drop was greater at higher initial pressure conditions. The final pressure drop reached to 0.92 MPa when the initial pressure was 9 MPa under the same temperature conditions. The results also illustrated that, the formation rate of hydrate was the fastest when the temperatures were closely to the freezing point. The average formation rate of CH4 hydrate reached to 0.646 mmol/h when the temperature was 273.15 K. Moreover, the smaller the particle size was, the higher the final conversion rate of ice. The final conversion rate reached to 56.5% when the initial pressure was 9 MPa. The results are of significance for exploiting natural gas hydrate in the permafrost regions.

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