石油学报 ›› 2026, Vol. 47 ›› Issue (6): 1217-1233.DOI: 10.7623/syxb202606007

• 油田开发 • 上一篇    

考虑孔-渗演化机制的储气库注CO2过程多场耦合机理

郭肖1,2, 王作豪1,2, 王鹏鲲3, 陈祖伟1,2, 王皓东1,2   

  1. 1. 西南石油大学 四川成都 610500;
    2. 油气藏地质及开发工程全国重点实验室 四川成都 610500;
    3. 昆仑数智科技有限责任公司 四川成都 610000
  • 收稿日期:2025-08-25 修回日期:2026-04-24 发布日期:2026-07-02
  • 通讯作者: 王作豪,男,1997年9月生,2023年获重庆科技大学石油与天然气工程专业硕士学位,现为西南石油大学博士研究生,主要从事非常规渗流理论与储气库建设方面的研究。Email:202311000060@stu.swpu.edu.cn
  • 作者简介:郭肖,男,1972年5月生,1999年获西南石油学院油气田开发工程专业博士学位,现为西南石油大学二级教授、博士生导师、国家有突出贡献中青年专家、享受国务院政府特殊津贴专家、“百千万人才工程”国家级人选、教育部新世纪优秀人才、四川省学术和技术带头人,主要从事复杂油气藏渗流物理实验与基础理论研究工作。Email:guoxiao72@163.com
  • 基金资助:
    国家自然科学基金面上项目(No.52474046)、新型油气勘探开发国家科技重大专项(2025ZD1404103)和油气藏地质及开发工程全国重点实验室开放基金(PLN202412,PLN202414)资助。

Multi-field coupling mechanism of CO2 injection in underground gas storage under porosity-permeability evolution

Guo Xiao1,2, Wang Zuohao1,2, Wang Pengkun3, Chen Zuwei1,2, Wang Haodong1,2   

  1. 1. Southwest Petroleum University, Sichuan Chengdu 610500, China;
    2. State Key Laboratory of Oil and Gas Reservoir Geology and Exploitation, Sichuan Chengdu 610500, China;
    3. Kunlun Digital Technology Co., Ltd., Sichuan Chengdu 610000, China
  • Received:2025-08-25 Revised:2026-04-24 Published:2026-07-02

摘要: 储气库工程作为中国能源调控与资源战略布局的重要组成部分,若能以CO2作为垫底气,则可兼顾经济效益,助力实现双碳目标,具有广阔的应用前景。然而,在CO2注入过程中伴随着渗流、传热与岩石骨架应变等多重效应,其机理复杂。目前,国内外多数研究偏重于渗流场分析,较少考虑分子扩散、热传导和骨架形变对储层孔-渗结构和流体流动行为的综合影响。为深入揭示渗流场、热力学场与应力场的耦合机理及孔-渗演化特征,结合分子模拟结果,建立了考虑扩散的热-流-固耦合数学模型,开展了有限元数值模拟。研究结果表明:①在超临界CO2注入过程中,对流、重力分异与分子扩散协同控制着CO2的整体驱替。宏观运移由压力梯度驱动的对流主导,分子扩散显著拓宽了驱替前缘并形成有限混溶过渡带,重力分异则使得CO2优先沿储层底部运移;②当低温CO2注入后,CO2通过热传导和对流换热机制与孔隙内的天然气及围岩发生热交换,致使井周温降最大可达9 K,提高注入温度可优化储层的温度分布;③孔隙压力与热应力协同作用导致岩石的有效应力降低,孔隙度和渗透率的最大增幅分别为1.6 % 、4.8 %; 4储层的初始孔隙度对其孔-渗演化的影响最显著,渗透率次之,注入温度影响最小;⑤合理的注采配置有助于CO2注入并优化储气库的垫气效率,当采用注气量为40×104m3/d、产气量为17.7×104m3/d的多轮次周期注采策略时,储层中CO2的垫气效率可达55.48 % 。研究成果为储气库的合理建设与安全高效运行提供了理论支持与技术参考。

关键词: 储气库, 多物理场耦合, CO2注入过程, 垫底气, 孔-渗演化机制

Abstract: As an integral component of China’s energy regulation and strategic resource allocation, underground gas storage (UGS) engineering offers significant potential for application. Utilizing CO2 as a cushion gas can simultaneously enhance economic viability and contribute to the realization of "dual carbon" goals. However, the CO2 injection process involves intricate mechanisms characterized by the synergistic effects of seepage, heat transfer, and rock matrix strain. Currently, the majority of domestic and international research prioritizes seepage field analysis, with insufficient attention paid to the coupled impacts of molecular diffusion, thermal conduction, and matrix deformation on reservoir porosity-permeability structures and fluid flow behavior. To further elucidate the coupling mechanisms between the seepage, thermodynamic, and stress fields, as well as the porosity-permeability evolution characteristics, this study establishes a diffusion-inclusive thermo-hydro-mechanical (THM) coupled mathematical model integrated with molecular simulation results and performs finite element numerical simulations. The research results indicate as follows. (1) During the injection of supercritical CO2, the overall displacement process is synergistically governed by convection, gravitational segregation, and molecular diffusion. Macroscopic transport is dominated by pressure gradient-driven convection, whereas molecular diffusion significantly broadens the displacement front and facilitates the formation of a finite miscible transition zone; concurrently, gravitational segregation causes CO2 to migrate preferentially along the bottom of reservoir. (2) Upon the injection of low-temperature CO2, heat exchange occurs with the interstitial natural gas and the surrounding host rock via thermal conduction and convective heat transfer mechanisms, resulting in a maximum temperature decrease of 9 K in the near-wellbore region. Increasing the injection temperature can effectively optimize the thermal distribution in reservoirs. (3) The synergistic effects of pore pressure and thermal stress lead to a reduction in the effective stress of the rock, resulting in maximum increments of 1.6 % and 4.8 % in porosity and permeability, respectively. (4) The initial reservoir porosity exerts the most significant influence on porosity-permeability evolution, followed by initial permeability, while injection temperature has the least impact. (5) Rational injection-production configurations facilitate CO2 sequestration and optimize the cushion gas efficiency of the storage facility; specifically, under a multi-cycle periodic strategy with an injection rate of 40×104m3/d and a production rate of 17.7×104m3/d, the CO2 cushion gas efficiency reaches 55.48 % . These findings provide theoretical support and technical references for the rational construction and safe, efficient operation of un derground gas storage facilities.

Key words: underground gas storage, multiphysics coupling, CO2 injection process, cushion gas, porosity-permeability evolution mechanism

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