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多薄层致密砂岩储层大型水力压裂三维物理模拟实验

房茂军 杜旭林 白玉湖 李昊 张浩 朱海燕

房茂军, 杜旭林, 白玉湖, 李昊, 张浩, 朱海燕. 多薄层致密砂岩储层大型水力压裂三维物理模拟实验[J]. 石油实验地质, 2024, 46(4): 786-798. doi: 10.11781/sysydz202404786
引用本文: 房茂军, 杜旭林, 白玉湖, 李昊, 张浩, 朱海燕. 多薄层致密砂岩储层大型水力压裂三维物理模拟实验[J]. 石油实验地质, 2024, 46(4): 786-798. doi: 10.11781/sysydz202404786
FANG Maojun, DU Xulin, BAI Yuhu, LI Hao, ZHANG Hao, ZHU Haiyan. Three-dimensional physical simulation experiments on large-scale hydraulic fracturing in multi-thin interbedded tight sandstone reservoirs[J]. PETROLEUM GEOLOGY & EXPERIMENT, 2024, 46(4): 786-798. doi: 10.11781/sysydz202404786
Citation: FANG Maojun, DU Xulin, BAI Yuhu, LI Hao, ZHANG Hao, ZHU Haiyan. Three-dimensional physical simulation experiments on large-scale hydraulic fracturing in multi-thin interbedded tight sandstone reservoirs[J]. PETROLEUM GEOLOGY & EXPERIMENT, 2024, 46(4): 786-798. doi: 10.11781/sysydz202404786

多薄层致密砂岩储层大型水力压裂三维物理模拟实验

doi: 10.11781/sysydz202404786
基金项目: 

中海油(有限)科技项目十四五重点攻关课题“多薄层致密气藏开发关键技术” KJGG2022-1004

详细信息
    作者简介:

    房茂军(1980—), 男, 硕士, 高级工程师, 从事非常规油气田开发综合研究。E-mail: fangmj@cnooc.com.cn

    通讯作者:

    杜旭林(1992—), 男, 博士, 从事非常规油气渗流、计算岩石力学研究。E-mail: duxl11@cnooc.com.cn

  • 中图分类号: TE135

Three-dimensional physical simulation experiments on large-scale hydraulic fracturing in multi-thin interbedded tight sandstone reservoirs

  • 摘要: 鄂尔多斯盆地东北缘临兴气田以多薄互层型致密砂岩储层为主,储层岩性复杂、渗透率低,受多种因素影响且作用机理不明确,导致压裂施工难度大、效果差异大。为此,针对临兴气田致密砂岩储层不同岩石组分、黏土含量、粒径、沉积旋回、平面及纵向非均质性等特性,设计并开展了不同地质条件下的水力压裂室内大型三维物理模拟实验。根据相似准则,参照二叠系石盒子组三向地应力、岩石强度、井身结构参数、现场压裂施工参数,确定了实验基本参数。根据临兴气田典型井主力储层特征,制作了考虑不同岩石组分、黏土含量、粒径、沉积旋回组合、平面非均质性组合、纵向非均质性组合的15块立方体岩心,开展了15组压裂模拟实验,并从分析注入压力曲线和观察岩样破裂面两个方面总结了影响水力压裂缝扩展规律的储层主控因素。研究表明,岩石矿物和粒径、沉积旋回、平面及纵向非均质性对致密储层裂缝扩展形态有显著影响。砂岩粒度较大、胶结较弱、黏土含量较高、平面非均质性较强,使得裂缝面更易于屈曲,扩展压力增大,导致加砂困难;沉积旋回会使得水力压裂缝易于沿旋回层面扩展,从而形成水平缝,其中反旋回界面突破难度比正旋回大;由于砂—泥层间界面、砂—煤层间界面、天然砂岩弱面易被激活,从而产生“工”或“T”字形裂缝,对于砂泥多薄互层还会产生“工”+“T”+“十”字形的组合裂缝。实验研究揭示了不同地质条件下的水力压裂缝扩展形态,也为类似区块的研究提供了借鉴。

     

  • 图  1  水力压裂三维物理模拟实验系统示意图

    Figure  1.  Diagram of three-dimensional physical simulation system for hydraulic fracturing

    图  2  水力压裂三维物理模拟实验系统主要设备实物照片

    Figure  2.  Photos of main equipments for three-dimensional physical simulation experiments on hydraulic fracturing

    图  3  水力压裂三维物理模拟实验系统中两种井筒实物图

    Figure  3.  Photos of two types of wellbores in three-dimensional physical simulation experiments for hydraulic fracturing

    图  4  天然岩样采集和加工流程示意图

    Figure  4.  Workflow of natural rock sample collection and processing

    图  5  人工模拟岩心制作流程示意图

    Figure  5.  Diagram of production process of artificial simulated rock cores

    图  6  不同岩石组分、黏土含量、粒径、沉积旋回组合制样方案示意图

    Figure  6.  Diagram of sample preparation plans for different rock components, clay contents, particle sizes, and sedimentary cycle combinations

    图  7  不同平面非均质性组合制样方案示意图

    Figure  7.  Diagram of sample preparation plans for different planar heterogeneity combinations

    图  8  不同纵向非均质性组合制样方案示意图

    Figure  8.  Diagram of sample preparation plans for different longitudinal heterogeneity combinations

    图  9  不同纵向非均质性组合制样实物图

    Figure  9.  Photos of sample preparation for different longitudinal heterogeneity combinations

    图  10  不同岩石组分、黏土含量、粒径、沉积旋回组合实验注入压力曲线

    Figure  10.  Injection pressure curves for experiments with different rock components, clay contents, particle sizes, and sedimentary cycle combinations

    图  11  不同岩石组分、黏土含量、粒径、沉积旋回组合实验岩样压裂结果

    Figure  11.  Fracturing results of rock samples after experiments with different rock components, clay contents, particle sizes, and sedimentary cycle combinations

    图  12  不同平面非均质性组合实验注入压力曲线

    Figure  12.  Injection pressure curves for experiments with different planar heterogeneity combinations

    图  13  不同平面非均质性组合实验岩样压裂结果

    Figure  13.  Fracturing results of rock samples after experiments with different planar heterogeneity combinations

    图  14  不同纵向非均质性组合实验注入压力曲线

    Figure  14.  Injection pressure curves for experiments with different longitudinal heterogeneity combinations

    图  15  不同纵向非均质性组合实验岩样压裂结果

    Figure  15.  Fracturing results of rock samples after experiments with different longitudinal heterogeneity combinations

    表  1  水力压裂三维物理模拟实验参数与现场参数对比

    Table  1.   Comparison between parameters in three-dimensional physical simulation experiments for hydraulic fracturing and on-site parameters

    几何参数 现场实验参数范围 现场实验参考值 室内实验参数
    井筒直径/mm 215.9 215.9 18
    射孔直径/mm 20~30 20 2
    X方向地应力/MPa 25~36 28 14
    Y方向地应力/MPa 35~39 36 18
    Z方向地应力/MPa 40~44 42 21
    破裂压力/MPa 30~34 31 30
    压裂排量/(m3/min) 3~5 3 1×10-5
    下载: 导出CSV

    表  2  考虑不同岩石组分和沉积旋回实验分组

    Table  2.   Experimental grouping considering different rock components and sedimentary cycles

    组号 岩石组分 主要粒度设置 备注
    1-1 中砂60%、细粉砂10%、水泥30% 恒定中值粒度为375 μm 中砂标准组
    1-2 粗砂60%、细粉砂10%、水泥30% 恒定中值粒度为710 μm 粗砂标准组
    1-3 细砂30%、细粉砂10%、水泥30%、黏土30% 恒定中值粒度为160 μm 泥岩组
    1-4 中砂60%、细粉砂10%、水泥20%、黏土10% 恒定中值粒度为375 μm 中砂加黏土组
    1-5 底层:粗砂60%、黏土0%,从下到上渐变至细砂30%,黏土30%(每层均含细粉砂10%、水泥30%) 从下到上由710 μm渐变至160 μm 正旋回组
    1-6 底层:细砂30%,黏土30%,从下到上渐变至粗砂60%、黏土0%(每层均含细粉砂10%、水泥30%) 从下到上由160 μm渐变至710 μm 反旋回组
    下载: 导出CSV

    表  3  考虑不同非均质性平面组合实验分组

    Table  3.   Experimental grouping considering different planar heterogeneous combinations

    组号 岩性变化 渗透性变化 备注
    2-1 泥—砂—泥 低—高—低 盒2段某水平井
    2-2 砂—泥—砂 高—低—高 盒4段某水平井
    2-3 标准组 标准组 均质对照
    下载: 导出CSV

    表  4  考虑不同纵向非均质性组合实验分组

    Table  4.   Experimental grouping considering different longitudinal heterogeneity combinations

    组号 从上到下地层岩性 各层厚比例设置 备注
    3-1 泥—砂—泥 单砂体 下石盒子组盒6段
    3-2 泥—砂—泥 单砂体 上石盒子组盒4段
    3-3 煤—砂—煤 单砂体上下含煤板 太原组太2段
    3-4 砂—泥—砂—泥—砂 砂泥交互多层 太原组太1段
    3-5 砂—砂—砂 弱胶结面 均质对照
    3-6 天然露头砂岩 含薄弱面、粒间弱胶结 均质对照
    下载: 导出CSV
  • [1] 米立军, 朱光辉. 鄂尔多斯盆地东北缘临兴—神府致密气田成藏地质特征及勘探突破[J]. 中国石油勘探, 2021, 26(3): 53-67. https://www.cnki.com.cn/Article/CJFDTOTAL-KTSY202103005.htm

    MI Lijun, ZHU Guanghui. Geological characteristics and exploration breakthrough in Linxing-Shenfu tight gas field, northeastern Ordos Basin[J]. China Petroleum Exploration, 2021, 26(3): 53-67. https://www.cnki.com.cn/Article/CJFDTOTAL-KTSY202103005.htm
    [2] 吴克强, 赵志刚, 祝彦贺, 等. 鄂尔多斯盆地东北缘"双低"致密气藏差异成藏规律及勘探开发关键技术[J]. 中国海上油气, 2022, 34(4): 43-54. https://www.cnki.com.cn/Article/CJFDTOTAL-ZHSD202204004.htm

    WU Keqiang, ZHAO Zhigang, ZHU Yanhe, et al. Differential accumulation laws and key exploration and development technologies of "double-low" tight gas reservoirs in the northeastern margin of the Ordos Basin[J]. China Offshore Oil and Gas, 2022, 34(4): 43-54. https://www.cnki.com.cn/Article/CJFDTOTAL-ZHSD202204004.htm
    [3] 王波, 齐宇, 杜凯, 等. 基于GR测井信息的层序细分及砂体预测技术: 以鄂尔多斯盆地临兴A地区上石盒子组盒四段为例[J]. 中国海上油气, 2022, 34(4): 164-174. https://www.cnki.com.cn/Article/CJFDTOTAL-ZHSD202204015.htm

    WANG Bo, QI Yu, DU Kai, et al. Sequence subdivision and sand bodies prediction technology based on GR logging information: taking H4 member of Upper Shihezi Formation in Linxing A area of Ordos Basin as an example[J]. China Offshore Oil and Gas, 2022, 34(4): 164-174. https://www.cnki.com.cn/Article/CJFDTOTAL-ZHSD202204015.htm
    [4] 杨帆, 梅文博, 李亮, 等. 薄互层致密砂岩水力压裂裂缝扩展特征研究[J]. 煤田地质与勘探, 2023, 51(7): 61-71. https://www.cnki.com.cn/Article/CJFDTOTAL-MDKT202307007.htm

    YANG Fan, MEI Wenbo, LI Liang, et al. Propagation of hydraulic fractures in thin interbedded tight sandstones[J]. Coal Geology & Exploration, 2023, 51(7): 61-71. https://www.cnki.com.cn/Article/CJFDTOTAL-MDKT202307007.htm
    [5] LI Sanbai, FIROOZABADI A, ZHANG Dongxiao. Hydromechanical modeling of nonplanar three-dimensional fracture propagation using an iteratively coupled approach[J]. Journal of Geophysical Research: Solid Earth, 2020, 125(8): e2020JB020115. doi: 10.1029/2020JB020115
    [6] 唐慧莹, 张东旭, 刘环竭, 等. 页岩气藏水平井分段压裂缝间应力干扰全三维模拟[J]. 西安石油大学学报(自然科学版), 2019, 34(5): 37-44. https://www.cnki.com.cn/Article/CJFDTOTAL-XASY201905005.htm

    TANG Huiying, ZHANG Dongxu, LIU Huanjie, et al. Three-dimensional simulation of stress interference between fractures in segmented fracturing process of horizontal wells in shale gas reservoirs[J]. Journal of Xi'an Shiyou University (Natural Science Edition), 2019, 34(5): 37-44. https://www.cnki.com.cn/Article/CJFDTOTAL-XASY201905005.htm
    [7] 唐煊赫, 朱海燕, 李奎东. 基于FEM-DFN的页岩气储层水力压裂复杂裂缝交错扩展模型[J]. 天然气工业, 2023, 43(1): 162-176. https://www.cnki.com.cn/Article/CJFDTOTAL-TRQG202301014.htm

    TANG Xuanhe, ZHU Haiyan, LI Kuidong. A FEM-DFN-based complex fracture staggered propagation model for hydraulic fracturing of shale gas reservoirs[J]. Natural Gas Industry, 2023, 43(1): 162-176. https://www.cnki.com.cn/Article/CJFDTOTAL-TRQG202301014.htm
    [8] PALUSZNY A, THOMAS R N, SACEANU M C, et al. Hydro-mechanical interaction effects and channeling in three-dimensional fracture networks undergoing growth and nucleation[J]. Journal of Rock Mechanics and Geotechnical Engineering, 2020, 12(4): 707-719.
    [9] 师访. 岩石破裂过程的扩展有限元法研究[D]. 徐州: 中国矿业大学, 2015.

    SHI Fang. Study on the cracking process of rock using the extended finite element method[D]. Xuzhou: China University of Mining and Technology, 2015.
    [10] 杜旭林, 程林松, 牛烺昱, 等. 基于XFEM-MBEM的嵌入式离散裂缝模型流固耦合数值模拟方法[J]. 力学学报, 2021, 53(12): 3413-3424. https://www.cnki.com.cn/Article/CJFDTOTAL-LXXB202112023.htm

    DU Xulin, CHENG Linsong, NIU Langyu, et al. Numerical simulation for coupling flow and geomechanics in embedded discrete fracture model based on XFEM-MBEM[J]. Chinese Journal of Theoretical and Applied Mechanics, 2021, 53(12): 3413-3424. https://www.cnki.com.cn/Article/CJFDTOTAL-LXXB202112023.htm
    [11] YAN Chengzeng, GAO Yakun, GUO Hui. A FDEM based 3D discrete mixed seepage model for simulating fluid driven fracturing[J]. Engineering Analysis with Boundary Elements, 2022, 140: 447-463.
    [12] YAN Chengzeng, ZHENG Yuchen, WANG Gang. A 2D adaptive finite-discrete element method for simulating fracture and fragmentation in geomaterials[J]. International Journal of Rock Mechanics and Mining Sciences, 2023, 169: 105439.
    [13] 侯冰, 张其星, 陈勉. 页岩储层压裂物理模拟技术进展及发展趋势[J]. 石油钻探技术, 2023, 51(5): 66-77. https://www.cnki.com.cn/Article/CJFDTOTAL-SYZT202305008.htm

    HOU Bing, ZHANG Qixing, CHEN Mian. Status and tendency of physical simulation technology for hydraulic fracturing of shale reservoirs [J]. Petroleum Drilling Techniques, 2023, 51(5): 66-77. https://www.cnki.com.cn/Article/CJFDTOTAL-SYZT202305008.htm
    [14] 侯冰, 崔壮, 曾悦. 深层致密储层大斜度井压裂裂缝扩展机制研究[J]. 岩石力学与工程学报, 2023, 42(S2): 4054-4063. https://www.cnki.com.cn/Article/CJFDTOTAL-YSLX2023S2016.htm

    HOU Bin, CUI Zhuang, ZENG Yue. Experimental study on fracture propagation morphology of deviated well in tight reservoir[J]. Chinese Journal of Rock Mechanics and Engineering, 2023, 42(S2): 4054-4063. https://www.cnki.com.cn/Article/CJFDTOTAL-YSLX2023S2016.htm
    [15] 邹雨时, 石善志, 张士诚, 等. 薄互层型页岩油储集层水力裂缝形态与支撑剂分布特征[J]. 石油勘探与开发, 2022, 49(5): 1025-1032. https://www.cnki.com.cn/Article/CJFDTOTAL-SKYK202205018.htm

    ZOU Yushi, SHI Shanzhi, ZHANG Shicheng, et al. Hydraulic fracture geometry and proppant distribution in thin interbedded shale oil reservoirs[J]. Petroleum Exploration and Development, 2022, 49(5): 1025-1032. https://www.cnki.com.cn/Article/CJFDTOTAL-SKYK202205018.htm
    [16] 陈峥嵘, 齐宇, 韩磊, 等. 非均质致密储层水平井分段压裂裂缝扩展模拟[J]. 大庆石油地质与开发, 2024, 43(2): 53-60. https://www.cnki.com.cn/Article/CJFDTOTAL-DQSK202402007.htm

    CHEN Zhengrong, QI Yu, HAN Lei, et al. Fracture propagation simulation of horizontal well staged fracturing in heterogeneous tight reservoirs[J]. Petroleum Geology & Oilfield Development in Daqing, 2024, 43(2): 53-60. https://www.cnki.com.cn/Article/CJFDTOTAL-DQSK202402007.htm
    [17] 冯彦军. 基于真三轴物理模拟实验的水力裂缝扩展规律研究[J]. 中国矿业, 2022, 31(10): 126-132. https://www.cnki.com.cn/Article/CJFDTOTAL-ZGKA202210018.htm

    FENG Yanjun. Study on propagation of hydraulic fracture based on true triaxial physical simulation experiment[J]. China Mining Magazine, 2022, 31(10): 126-132. https://www.cnki.com.cn/Article/CJFDTOTAL-ZGKA202210018.htm
    [18] 郭培峰, 周文, 邓虎成, 等. 致密储层压裂真三轴物理模拟实验及裂缝延伸规律[J]. 成都理工大学学报(自然科学版), 2020, 47(1): 65-74. https://www.cnki.com.cn/Article/CJFDTOTAL-CDLG202001006.htm

    GUO Peifeng, ZHOU Wen, DENG Hucheng, et al. Real triaxial physical simulation experiment of fracturing and the law of fracture extension in tight reservoir[J]. Journal of Chengdu University of Technology (Science & Technology Edition), 2020, 47(1): 65-74. https://www.cnki.com.cn/Article/CJFDTOTAL-CDLG202001006.htm
    [19] 柳贡慧, 庞飞, 陈治喜. 水力压裂模拟实验中的相似准则[J]. 石油大学学报(自然科学版), 2000, 24(5): 45-48. https://www.cnki.com.cn/Article/CJFDTOTAL-SYDX200005013.htm

    LIU Gonghui, PANG Fei, CHEN Zhixi. Development of scaling laws for hydraulic fracture simulation tests[J]. Journal of the University of Petroleum, China, 2000, 24(5): 45-48. https://www.cnki.com.cn/Article/CJFDTOTAL-SYDX200005013.htm
    [20] 郭天魁, 刘晓强, 顾启林. 射孔井水力压裂模拟实验相似准则推导[J]. 中国海上油气, 2015, 27(3): 108-112. https://www.cnki.com.cn/Article/CJFDTOTAL-ZHSD201503018.htm

    GUO Tiankui, LIU Xiaoqiang, GU Qilin. Deduction of similarity laws of hydraulic fracturing simulation experiments for perforated wells[J]. China Offshore Oil and Gas, 2015, 27(3): 108-112. https://www.cnki.com.cn/Article/CJFDTOTAL-ZHSD201503018.htm
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  • 收稿日期:  2024-02-29
  • 修回日期:  2024-06-26
  • 刊出日期:  2024-07-28

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