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    刘瑜

    • 教授     博士生导师   硕士生导师
    • 性别:男
    • 毕业院校:大连理工大学
    • 学位:博士
    • 所在单位:能源与动力学院
    • 学科:能源与环境工程. 动力机械及工程
    • 办公地点:能动大楼912
    • 联系方式:0411-84708015
    • 电子邮箱:liuyu@dlut.edu.cn

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    Dynamic stability characteristics of fluid flow in CO2 miscible displacements in porous media

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    论文类型:期刊论文

    发表时间:2015-01-01

    发表刊物:RSC ADVANCES

    收录刊物:SCIE、EI、Scopus

    卷号:5

    期号:44

    页面范围:34839-34853

    ISSN号:2046-2069

    摘要:The dynamic characteristics of fluid flow are important in miscible displacement processes in carbon dioxide enhanced oil recovery (CO2-EOR) projects. And the stability of the in situ mixing zone greatly influences the oil recovery factor, which deserves further research. We investigated CO2 miscible displacement processes using magnetic resonance imaging (MRI) apparatus. The CO2 miscible displacement flows were performed at a low injection rate of 0.1 ml min(-1) with reservoir conditions of 8.5 to 9.5 MPa and 37.8 degrees C. The oil saturation evolution, the length of the in situ mixing zone, and the mixing-frontal velocity and CO2-frontal velocity were quantified. The experimental results showed that the residual oil saturation decreased with pressure and the mixing zone length was independent of pressure. The mixing-frontal velocity and the CO2-frontal velocity were nearly the same and increased with pressure. The critical velocity of the CO2/n-decane (CO2/nC(10)) system was 1.105 x 10(-5) m s(-1). Although the whole mixing zone length had no obvious change with pressure, a higher pressure compressed the mixing zone and led to an unstable mixing front above the critical velocity. The longitudinal dispersion coefficient was calculated by fitting the experimental data with an error function, which had no obvious change with pressure. Additionally, a three-dimensional lattice-Boltzmann method (LBM) was used to simulate pore-scale miscible fluid flows in upward vertical displacements. A front fingering occurred at a low kinematic viscosity ratio (nu(Co2) : nu(o) = 1 : 1). At a large kinematic viscosity ratio (nu(Co2) : nu(o) = 1 : 15), the high kinematic viscous oil restrained the buoyancy of supercritical CO2, but also impeded the displacement with a pore-scale backflow which might lead to a low oil recovery factor.