CO2, N2, and CO2/N2 mixed gas injection for enhanced shale gas recovery and CO2 geological storage

IF 3.1 4区 工程技术 Q3 ENERGY & FUELS Frontiers in Energy Pub Date : 2023-02-28 DOI:10.1007/s11708-023-0865-9
Jianfa Wu, Haoran Hu, Cheng Chang, Deliang Zhang, Jian Zhang, Shengxian Zhao, Bo Wang, Qiushi Zhang, Yiming Chen, Fanhua Zeng
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Abstract

In this work, using fractured shale cores, isothermal adsorption experiments and core flooding tests were conducted to investigate the performance of injecting different gases to enhance shale gas recovery and CO2 geological storage efficiency under real reservoir conditions. The adsorption process of shale to different gases was in agreement with the extended-Langmuir model, and the adsorption capacity of CO2 was the largest, followed by CH4, and that of N2 was the smallest of the three pure gases. In addition, when the CO2 concentration in the mixed gas exceeded 50%, the adsorption capacity of the mixed gas was greater than that of CH4, and had a strong competitive adsorption effect. For the core flooding tests, pure gas injection showed that the breakthrough time of CO2 was longer than that of N2, and the CH4 recovery factor at the breakthrough time \(\left({{R_{{\rm{C}}{{\rm{H}}_4}}}} \right)\) was also higher than that of N2. The \({R_{{\rm{C}}{{\rm{H}}_4}}}\) of CO2 gas injection was approximately 44.09%, while the \({R_{{\rm{C}}{{\rm{H}}_4}}}\) of N2 was only 31.63%. For CO2/N2 mixed gas injection, with the increase of CO2 concentration, the \({R_{{\rm{C}}{{\rm{H}}_4}}}\) increased, and the \({R_{{\rm{C}}{{\rm{H}}_4}}}\) for mixed gas CO2/N2 = 8:2 was close to that of pure CO2, about 40.24%. Moreover, the breakthrough time of N2 in mixed gas was not much different from that when pure N2 was injected, while the breakthrough time of CO2 was prolonged, which indicated that with the increase of N2 concentration in the mixed gas, the breakthrough time of CO2 could be extended. Furthermore, an abnormal surge of N2 concentration in the produced gas was observed after N2 breakthrough. In regards to CO2 storage efficiency \(\left({{S_{{\rm{storage - C}}{{\rm{O}}_2}}}} \right)\), as the CO2 concentration increased, \({S_{{\rm{storage - C}}{{\rm{O}}_2}}}\) also increased. The \({S_{{\rm{storage - C}}{{\rm{O}}_2}}}\) of the pure CO2 gas injection was about 35.96%, while for mixed gas CO2/N2 = 8:2, \({S_{{\rm{storage - C}}{{\rm{O}}_2}}}\) was about 32.28%.

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注CO2、N2和CO2/N2混合气,提高页岩气采收率和二氧化碳地质封存
本文采用裂缝型页岩岩心,通过等温吸附实验和岩心驱油试验,研究了在真实储层条件下注入不同气体提高页岩气采收率和CO2地质储气效率的效果。页岩对不同气体的吸附过程符合扩展langmuir模型,3种纯气体中CO2吸附量最大,CH4次之,N2吸附量最小。此外,当混合气体中的CO2浓度超过50%, the adsorption capacity of the mixed gas was greater than that of CH4, and had a strong competitive adsorption effect. For the core flooding tests, pure gas injection showed that the breakthrough time of CO2 was longer than that of N2, and the CH4 recovery factor at the breakthrough time \(\left({{R_{{\rm{C}}{{\rm{H}}_4}}}} \right)\) was also higher than that of N2. The \({R_{{\rm{C}}{{\rm{H}}_4}}}\) of CO2 gas injection was approximately 44.09%, while the \({R_{{\rm{C}}{{\rm{H}}_4}}}\) of N2 was only 31.63%. For CO2/N2 mixed gas injection, with the increase of CO2 concentration, the \({R_{{\rm{C}}{{\rm{H}}_4}}}\) increased, and the \({R_{{\rm{C}}{{\rm{H}}_4}}}\) for mixed gas CO2/N2 = 8:2 was close to that of pure CO2, about 40.24%. Moreover, the breakthrough time of N2 in mixed gas was not much different from that when pure N2 was injected, while the breakthrough time of CO2 was prolonged, which indicated that with the increase of N2 concentration in the mixed gas, the breakthrough time of CO2 could be extended. Furthermore, an abnormal surge of N2 concentration in the produced gas was observed after N2 breakthrough. In regards to CO2 storage efficiency \(\left({{S_{{\rm{storage - C}}{{\rm{O}}_2}}}} \right)\), as the CO2 concentration increased, \({S_{{\rm{storage - C}}{{\rm{O}}_2}}}\) also increased. The \({S_{{\rm{storage - C}}{{\rm{O}}_2}}}\) of the pure CO2 gas injection was about 35.96%, while for mixed gas CO2/N2 = 8:2, \({S_{{\rm{storage - C}}{{\rm{O}}_2}}}\) was about 32.28%.
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来源期刊
Frontiers in Energy
Frontiers in Energy Energy-Energy Engineering and Power Technology
CiteScore
5.90
自引率
6.90%
发文量
708
期刊介绍: Frontiers in Energy, an interdisciplinary and peer-reviewed international journal launched in January 2007, seeks to provide a rapid and unique platform for reporting the most advanced research on energy technology and strategic thinking in order to promote timely communication between researchers, scientists, engineers, and policy makers in the field of energy. Frontiers in Energy aims to be a leading peer-reviewed platform and an authoritative source of information for analyses, reviews and evaluations in energy engineering and research, with a strong focus on energy analysis, energy modelling and prediction, integrated energy systems, energy conversion and conservation, energy planning and energy on economic and policy issues. Frontiers in Energy publishes state-of-the-art review articles, original research papers and short communications by individual researchers or research groups. It is strictly peer-reviewed and accepts only original submissions in English. The scope of the journal is broad and covers all latest focus in current energy research. High-quality papers are solicited in, but are not limited to the following areas: -Fundamental energy science -Energy technology, including energy generation, conversion, storage, renewables, transport, urban design and building efficiency -Energy and the environment, including pollution control, energy efficiency and climate change -Energy economics, strategy and policy -Emerging energy issue
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