组构对片麻岩断裂韧度及裂缝扩展规律的影响

陈立超; 张超鹏; 闫睿昶; 吕帅锋; 肖宇航

doi:10.20174/j.JUSE.2025.04.14

地下空间与工程学报 >

2025 , Vol. 21 >Issue 4: 1228 - 1235

DOI: https://doi.org/10.20174/j.JUSE.2025.04.14

理论与试验研究

组构对片麻岩断裂韧度及裂缝扩展规律的影响

陈立超 ,
张超鹏 ,
闫睿昶 ,
吕帅锋 ,
肖宇航

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1.内蒙古工业大学资源与环境工程学院,呼和浩特 010051;
2.中国石油华北油田巴彦勘探开发分公司, 内蒙古巴彦淖尔 015000;
3.中国地质大学(武汉) 资源学院,武汉 430074;
4.中国石油勘探开发研究院,北京 110083

陈立超(1985—),男,内蒙古赤峰人,博士,副教授,主要从事岩石水力压裂理论与技术方面的教学研究。E-mail:chenlichaogas@163.com

收稿日期: 2024-12-21

网络出版日期: 2025-09-03

基金资助

内蒙古科技计划项目(2023YFSH0005,2023MS05018);中央引导地方科技发展资金项目(2024ZY0008);内蒙古直属高校基本科研业务费项目(JY20220251);锡林郭勒盟科技计划项目(202402)

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Effect of Fabric on Fracture Toughness and Crack Propagation Behavior of Gneiss

Chen Lichao ,
Zhang Chaopeng ,
Yan Ruichang ,
Lü Shuaifeng ,
Xiao Yuhang

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1. School of Resources and Environmental Engineering, Inner Mongolia University of Technology, Hohhot 010051, P.R. China;
2. Bayan Exploration and Development Company, Huabei Oilfield, CNPC, Bayannaoer, Inner Mongolia 015000, P.R. China;
3. School of Earth Resources, China University of Geosciences (Wuhan), Wuhan 430074, P.R. China;
4. Research Institute of Petroleum Exploration and Development, Beijing 110083, P.R. China

Received date: 2024-12-21

Online published: 2025-09-03

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摘要

片麻岩断裂力学性质各向异性对储层缝网压裂改造具有关键制约,针对内蒙古大青山地区太古界片麻岩研究了片麻岩断裂韧度、断裂能及断口形貌等在不同方向上的差异。结果表明:三点弯加载下片麻岩断裂过程包括孔隙压缩、弹性变形、断裂、卸载4个阶段,片麻岩脆性显著,对体积压裂改造有利;片麻岩断裂韧度在0.93~1.28 MPa·m^0.5,片麻岩在不同组构方向断裂性能差异大,表现为垂直片理/垂直线理＞平行片理/垂直线理＞垂直片理/平行线理＞平行片理/平行线理,影响压裂裂缝扩展方向;在垂直片理方向,片麻岩裂缝扩展受弱面影响形成顺层裂缝,裂缝面粗糙度和裂缝曲折度较高,易形成缝网;平行片理面方向,片麻岩裂缝平行主压应力方位扩展。裂缝面平坦,裂缝曲折度较小,不利于成网;垂直片理/垂直线理、垂直片理/平行线理、平行片理/垂直线理、平行片理/平行线理方向上片麻岩试样断裂能为0.47、0.43、0.37、0.25 J,片麻岩油气储层在不同组构方向上压裂改造能耗存在较大差异,基于扩大储层体积压裂波及体积考虑,建议水平井平行片麻岩线理走向钻进。

关键词： 片麻岩; 断裂行为; 各向异性; 三点弯实验; 裂缝扩展; 体积压裂

本文引用格式

陈立超 , 张超鹏 , 闫睿昶 , 吕帅锋 , 肖宇航 . 组构对片麻岩断裂韧度及裂缝扩展规律的影响[J]. 地下空间与工程学报, 2025 , 21(4) : 1228 -1235 . DOI: 10.20174/j.JUSE.2025.04.14

Abstract

The anisotropy of fracture behavior of gneiss is a key constraint to the fracturing of reservoir fracture network. The differences of fracture toughness, fracture energy and fracture morphology of gneiss in different directions are studied by selecting gneiss in Daqingshan of Inner Mongolia. The results show that: The fracture process of gneiss specimens under three-points bending loading includes four stages: pore compression, elastic compression deformation, fracture and rapid unloading. The brittleness of gneiss is significant, which is beneficial for volumetric fracturing. The fracture toughness of gneiss ranges from 0.93 to 1.28 MPa·m^0.5, and the fracture performance of gneiss varies greatly in different orientations. The vertical bedding/vertical lineation > parallel bedding /vertical lineation > vertical bedding /parallel lineation > parallel bedding/parallel lineation has certain mechanical constraints on the selection of fracture propagation direction. In the vertical schistosity direction, the fracture propagation of gneiss is seriously affected by the weak plane. The shear and displacement of cracks occur at the schistosity face and form bedding-parallel fractures. In the later stage, the fractures turn to extend along the loading direction. In the parallel schistosity direction, the fractures of gneiss extend parallel to the maximum principal stress orientation. The fracture surface is flat, and the fracture tortuosity is small, which is not conducive to fracture network formation. The breaking energy consumption of samples in vertical bedding/vertical lineation, parallel bedding /vertical lineation, vertical bedding /parallel lineation, parallel bedding/parallel lineation direction is 0.47, 0.43, 0.37 and 0.25 J, respectively, and the energy consumption of fracture in each direction of gneiss varies greatly. In order to expand the reservoir volume fracturing coverage, it is recommended to drill horizontal wells parallel to gneiss lineation.

Key words： gneiss; fracture behavior; anisotropy; three-points bending test; fracture propagation; volumetric fracturing

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