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CO₂提高天然气采收率的重力效应与气藏压力影响模拟
刘树阳^1,2,孙宝江^1,2,宋永臣³,张毅³
(1.非常规油气开发教育部重点实验室(中国石油大学(华东)),山东青岛 266580;2.中国石油大学(华东)石油工程学院, 山东青岛 266580;3.大连理工大学能源与动力学院,辽宁大连 116024)

摘要:

利用TOGUH2开展均质天然气藏模型中实施CO₂提高天然气采收率的模拟研究,分析重力效应作用机制和气藏压力对CO₂运移和CH₄采收率变化规律的影响,为CO₂提高天然气采收率的工程应用提供指导。模拟结果表明:重力效应抑制CO₂向上运移,减缓了CO₂与天然气纵向方向的混相,间接促进水平方向运移,导致气藏内CO₂水平运移速率显著大于纵向运移速率,但是CH₄采收率曲线不仅受重力效应影响,也受CO₂注入流速和气藏压力的综合影响;气藏内的CH₄生产时间及最终采收率随气藏压力降低而增加,在枯竭状态的低气藏压力条件下实施CO₂提高天然气采收率能够获得更好的CH₄采收率,但生产时间相对较长;较高气藏压力条件下,CO₂为超临界状态,重力效应作用明显,CO₂快速沉降并优先驱替气藏底层CH₄,但是容易从生产井底部自下而上突破至生产井,提高天然气采收率效果不佳。

关键词: CO₂提高天然气采收率重力效应 CO₂运移气藏压力影响

DOI：10.3969/j.issn.1673-5005.2020.03.009

分类号::TQ 28

文献标识码:A

基金项目:国家自然科学基金项目(U1762216);教育部“长江学者”创新团队项目(IRT_14R58)

Simulation on gravity effect and reservoir pressure influence analysis in CO₂ enhanced gas recovery

LIU Shuyang^1,2, SUN Baojiang^1,2, SONG Yongchen³, ZHANG Yi³

(1.Key Laboratory of Unconventional Oil ＆ Gas Development (China University of Petroleum (East China)), Ministry of Education, Qingdao 266580, China;2.School of Petroleum Engineering in China University of Petroleum(East China), Qingdao 266580, China;3.School of Energy and Power Engineering in Dalian University of Technology, Dalian 116024, China)

Abstract:

In this study, TOGUH2 simulator was applied to simulate CO₂ enhanced natural gas recovery (CO₂-EGR) with a homogeneous natural gas reservoir model, in which the gravity effect and influence of reservoir pressure on CO₂ migration and CH₄ recovery were studied in order to provide theoretical support for the application of the CO₂-EGR technique. The simulation results show that the gravity effect can inhibit upward migration of CO₂ and slow down the vertical mixing of CO₂ and CH₄, which can indirectly promote the horizontal migration and make the horizontal displacing rate significantly greater than the vertical one. However, the produced curve of CH₄ is not only determined by gravity effect, but also affected by CO₂ injection rate and reservoir pressure. The CH₄ production time and final recovery efficiency increase with the decrease of reservoir pressure, and better CH₄ recovery efficiency can be achieved at the depleted reservoir pressure than other operation conditions, while the production duration can be relatively longer. When CO₂ is in a supercritical state at relatively high reservoir pressure, the gravity effect can have relatively significant effect on the displacement process. CO₂ can rapidly sink and preferentially displace CH₄ in the bottom layer of the gas reservoir, but it can break through vertically from the bottom of the production well, resulting in a poor natural gas recovery.

Key words: CO₂ enhanced gas recovery gravity effect CO₂ migration pressure effect of gas reservoir