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压汞法与数字图像分析技术在致密砂岩储层微观孔隙定量分析中的应用——以鄂尔多斯盆地吴起油田X区块为例

孙雅雄 张坦 丁文龙 姚威 张驰

孙雅雄, 张坦, 丁文龙, 姚威, 张驰. 压汞法与数字图像分析技术在致密砂岩储层微观孔隙定量分析中的应用——以鄂尔多斯盆地吴起油田X区块为例[J]. 石油实验地质, 2022, 44(6): 1105-1115. doi: 10.11781/sysydz2022061105
引用本文: 孙雅雄, 张坦, 丁文龙, 姚威, 张驰. 压汞法与数字图像分析技术在致密砂岩储层微观孔隙定量分析中的应用——以鄂尔多斯盆地吴起油田X区块为例[J]. 石油实验地质, 2022, 44(6): 1105-1115. doi: 10.11781/sysydz2022061105
SUN Yaxiong, ZHANG Tan, DING Wenlong, YAO Wei, ZHANG Chi. Application of mercury intrusion method and digital image analysis in quantitative analysis of micro-scale pores in tight sandstone reservoirs: a case study of X block in Wuqi Oil Field, Ordos Basin[J]. PETROLEUM GEOLOGY & EXPERIMENT, 2022, 44(6): 1105-1115. doi: 10.11781/sysydz2022061105
Citation: SUN Yaxiong, ZHANG Tan, DING Wenlong, YAO Wei, ZHANG Chi. Application of mercury intrusion method and digital image analysis in quantitative analysis of micro-scale pores in tight sandstone reservoirs: a case study of X block in Wuqi Oil Field, Ordos Basin[J]. PETROLEUM GEOLOGY & EXPERIMENT, 2022, 44(6): 1105-1115. doi: 10.11781/sysydz2022061105

压汞法与数字图像分析技术在致密砂岩储层微观孔隙定量分析中的应用——以鄂尔多斯盆地吴起油田X区块为例

doi: 10.11781/sysydz2022061105
基金项目: 

国家科技重大专项 2016ZX05046-003-001

详细信息
    作者简介:

    孙雅雄(1993—),男,博士,从事非常规油气地质理论与评价研究。E-mail: sunyaxiong2015@163.com

  • 中图分类号: TE122.2

Application of mercury intrusion method and digital image analysis in quantitative analysis of micro-scale pores in tight sandstone reservoirs: a case study of X block in Wuqi Oil Field, Ordos Basin

  • 摘要: 为了探究鄂尔多斯盆地吴起油田X区块三叠系延长组长4+5、长6和侏罗系延安组延9、延10等4个亚段致密砂岩储层的孔隙结构,对该区12块样品进行了储层物性分析、扫描电镜观察、全岩X衍射实验及高压压汞实验,并利用图像分析技术和分形几何学定量地表征了致密砂岩的孔隙参数与分形维数。此外,讨论了分形维数与样品物性(孔隙度、渗透率)、孔隙结构参数(平均孔喉半径、分选系数)、孔隙几何参数(主要孔径、周长面积比、孔体比)之间的关系,还量化分析了沉积相及成岩环境对孔隙结构的影响。分析结果表明,孔隙结构分形维数范围为2.164~2.895(平均2.395)。分形维数与渗透率、孔隙度、平均孔喉半径呈负相关关系,与分选系数呈强正相关关系。研究区致密砂岩主要孔径较小、周长面积比大、孔体比较小、分形维数高,且分形维数随着孔体比和周长面积比的增大而增大,随主要孔径的增大而减小。可见样品孔隙结构相对复杂、各向异性较强且沉积环境会影响储层岩石的成分成熟度和结构成熟度,压实、胶结、淋滤等成岩作用会对储层进行改造,二者对致密砂岩储层的孔隙结构有着至关重要的影响。

     

  • 图  1  鄂尔多斯盆地吴起油田X区位置(a)及岩性柱状图(b)

    Figure  1.  Location (a) and stratigraphic column (b) of X block in Wuqi Oil Field, Ordos Basin

    图  2  鄂尔多斯盆地吴起油田X区样品岩心及薄片

    Figure  2.  Core and slice images of samples in X block, Wuqi Oil Field, Ordos Basin

    图  3  鄂尔多斯盆地吴起油田X区样品扫描电镜特征

    Figure  3.  FE-SEM images of samples in X block, Wuqi Oil Field, Ordos Basin

    图  4  鄂尔多斯盆地吴起油田X区样品孔隙度(φ)与渗透率(K)关系

    Figure  4.  Relationships between porosity and permeability of samples in X block, Wuqi Oil Field, Ordos Basin

    图  5  压汞法得出的样品分形维数计算结果与LnS/LnJ之间的关系

    Figure  5.  Relationship between LnS/LnJ and fractal dimension calculation results of samples from mercury intrusion method

    图  6  样品分形维数与孔隙度(a)、渗透率(b)、平均孔喉半径(c)、分选系数(d)以及退汞效率(e)的关系

    Figure  6.  Relationship between fractal dimension and porosity (a), permeability (b), average pore-throat radius (c), sorting coefficient (d) and mercury removal efficiency (e) of samples

    图  7  样品分形维数与周长面积比(a)、主要孔径(b)以及孔体比(c)的关系

    Figure  7.  Relationship between fractal dimension and perimeter over area (a), dominant pore size (b) and body-to-throat ratio (c) of samples

    图  8  样品颗粒圆度与分形维数(a)和主要孔径的关系(b)

    Figure  8.  Relationship between particle roundness and fractal dimension (a) and dominant pore size (b) of samples

    表  1  鄂尔多斯盆地吴起油田X区样品压汞数据

    Table  1.   Mercury intrusion data of samples in X block, Wuqi Oil Field, Ordos Basin

    样品 孔隙度/% 渗透率/(10-3μm2) 分形维数 相关系数(r2) 最大孔喉半径/μm 平均孔喉半径/μm 分选系数 平均孔喉比 歪度 退汞效率/% 阈压(Pt)/MPa 中值压力/MPa
    T-1 11.7 0.670 2.173 0.973 1.803 0.236 0.212 3.347 1.477 22.536 0.408 2.458
    T-3 7.2 0.011 2.570 0.969 0.090 0.019 1.089 3.132 1.464 24.200 8.160 39.613
    T-5 18.2 6.151 2.298 0.975 3.605 0.096 0.168 1.885 1.033 34.666 0.204 1.552
    T-6 11.9 0.035 2.321 0.980 0.270 0.066 0.530 2.755 1.914 26.632 2.720 18.531
    T-7 6.2 0.067 2.478 0.990 0.043 0.016 1.001 3.039 1.270 24.762 17.000 84.468
    T-9 12.4 0.179 2.164 0.963 0.309 0.071 0.447 2.771 2.280 23.771 2.380 70.348
    T-11 6.9 0.008 2.895 0.976 0.043 0.011 1.919 3.207 1.514 16.517 17.000 66.075
    T-12 2.208 0.969 5.407 0.148 0.242 2.022 1.141 33.095 0.136 4.992
    T-13 18.3 0.252 2.271 0.975 0.541 0.096 0.416 1.907 1.479 34.397 1.360 24.466
    T-14 9.6 0.012 2.415 0.956 12.571 0.022 0.950 4.215 1.622 19.175 0.059 34.088
    T-15 3.6 0.003 2.688 0.979 0.027 0.012 1.804 11.670 3.491 7.895 27.200
    T-16 14.9 0.577 2.256 0.960 1.352 0.096 0.382 2.196 1.356 31.290 0.544 7.657
    下载: 导出CSV

    表  2  鄂尔多斯盆地吴起油田X区样品薄片观察及全岩衍射数据

    Table  2.   X-ray diffraction and thin-section observation data of samples in X block, Wuqi Oil Field, Ordos Basin %

    样品 薄片 全岩衍射
    石英碎屑 长石碎屑 火成岩碎屑 变质岩屑 其他
    (云母等)
    石英 钾长石 斜长石 方解石 白云石 菱铁矿 黏土矿物
    T-1 33 34 10 11 12 28.1 18 16.9 4.8 32.2
    T-3 31 39 8 14 67.6 7.4 17.9
    T-5 30 25 15 30 32.0 13.1 3.7 7.3 43.9
    T-6 36 35 9 8 12 48.2 33.8 5.5 12.5
    T-7 38 38 12 8 4 34.0 18.4 6.0 8.6 33.0
    T-9 46 18 9 27 80.1 5.4 11.3 3.2
    T-11 33 32 12 22 1 45.6 23.1 11.2 20.1
    T-12 32 26 16 24 2 81.2 7.4 11.4
    T-13 34 35 14 10 7 36.4 6.9 27.7 3.3 7.1 18.6
    T-14 43 30 6 8 13 35.0 8.0 11.2 45.8
    T-15 35 25 10 15 15 30.5 20.9 12.5 36.1
    T-16 30 34 16 18 2 38.8 2.5 10.0 9.6 5.5 33.6
    下载: 导出CSV

    表  3  样品分形维数计算结果

    Table  3.   Results of fractal dimension of samples

    样品 拟合方程 R2 分形维数(D1) 拟合方程 R2 分形维数(D2)
    T-1 y=3.532 4x+13.179 0.972 3 5.532 4 y=0.172 6x+4.131 6 0.972 6 2.172 6
    T-3 y=1.863 8x+5.328 3 0.995 7 3.863 8 y=0.569 8x+4.119 4 0.968 6 2.569 8
    T-5 y=5.509 5x+18.187 0 0.956 3 7.509 5 y=0.298 1x+4.168 3 0.975 0 2.298 1
    T-6 y=2.973 4x+9.660 2 0.995 2 4.973 4 y=0.321 4x+4.163 1 0.979 8 2.321 4
    T-7 y=1.327 7x+2.314 5 0.995 8 3.327 7 y=0.477 7x+3.307 7 0.990 1 2.477 7
    T-9 y=2.085 1x+5.851 2 0.992 9 4.085 1 y=0.163 9x+3.714 7 0.962 5 2.163 9
    T-11 y=2.072 3x+5.032 9 0.996 8 4.072 3 y=0.895 3x+3.936 6 0.975 6 2.895 3
    T-12 y=0.977 5x+3.729 3 0.967 4 2.977 5 y=0.207 5x+3.575 7 0.969 1 2.207 5
    T-13 y=2.316 3x+8.499 1 0.979 9 4.346 3 y=0.271 0x+3.946 4 0.974 9 2.271 0
    T-14 y=2.330 7x+6.441 9 0.994 7 4.330 7 y=0.415 3x+4.163 9 0.956 2 2.415 3
    T-15 y=0.687 8x+1.379 0 0.994 8 2.687 8 y=1.404 4x+1.425 7 0.978 8 3.404 4
    T-16 y=3.509 9x+11.724 0 0.995 0 5.509 9 y=0.255 7x+4.004 0 0.960 4 2.255 7
    下载: 导出CSV

    表  4  样品数字图像分析结果

    Table  4.   Results of digital image analysis of samples

    样品 面积周长比/mm-1 主要孔径大小/μm 孔体比 颗粒圆度
    T-1 536.580 6.302 1.748 2.282
    T-3 892.860 2.764 15.339 3.300
    T-5 565.560 4.699 0.652 2.644
    T-6 855.810 3.561 6.585 2.688
    T-7 1 242.710 2.707 31.259 3.243
    T-9 577.138 6.149 9.950 2.560
    T-11 1 854.432 2.460 28.406 3.766
    T-12 720.921 4.963 0.459 2.534
    T-13 722.861 4.533 4.192 2.918
    T-14 1 176.639 2.712 0.108 2.668
    T-15 1 323.333 2.017 37.352 3.226
    T-16 665.289 5.272 1.950 2.248
    下载: 导出CSV
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  • 收稿日期:  2021-11-28
  • 修回日期:  2022-09-21
  • 刊出日期:  2022-11-28

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