高水压下岩体裂纹扩展的渗流-断裂耦合机制与数值实现

›› 2014, Vol. 299 ›› Issue (2): 556-564.

高水压下岩体裂纹扩展的渗流-断裂耦合机制与数值实现

赵延林^{1, 2, 3}，彭青阳^{1, 3}，万文^{1, 3}，王卫军^{1, 3}，张盛国^{1, 3}

1.湖南科技大学能源与安全工程学院，湖南湘潭 411201；2. 中国矿业大学煤炭资源与安全开采国家重点实验室，江苏徐州 221008； 3.湖南科技大学煤矿安全开采技术湖南省重点实验室，湖南湘潭 411201

收稿日期:2012-12-04 出版日期:2014-02-11 发布日期:2014-02-18
作者简介:赵延林，男，1973年生，博士，副教授，主要从事岩体渗流力学方面的研究工作
基金资助:
国家自然科学基金资助项目（No. 51274097）；湖南省教育厅资助科研项目（No. 13A020）；中国矿业大学煤炭资源与安全开采国家重点实验室开放研究基金资助项目（No. 13KF03）。

Seepage-fracture coupling mechanism of rock masses cracking propagation under high hydraulic pressure and numerical verification

ZHAO Yan-lin^{1, 2, 3}, PENG Qing-yang¹, ³, WAN Wen^{1, 3}, WANG Wei-jun^{1, 3}, ZHANG Sheng-guo^{1, 3}

1. School of Energy and Safty Engineering, Hunan University of Science and Technology, Xiangtan, Hunan 411201, China; 2. State Key Laboratory of Coal Resources and Safety Mining, China University of Mining and Technology, Xuzhou, Jiangsu, 221008, China; 3. Hunan Provincial Key Laboratory of Safe Mining Techniques of Coal Mines, Hunan University of Science and Technology, Xiangtan, Hunan 411201, China

Received:2012-12-04 Online:2014-02-11 Published:2014-02-18

摘要/Abstract

摘要： 采用渗流力学、断裂力学理论结合Monte Carlo方法描述岩体裂纹的随机分布，研究高水压作用下岩体原生裂纹的变形和翼形裂纹的萌生、扩展、贯通的渗流-断裂耦合作用机制，建立高水压作用下岩体裂纹的渗流-断裂耦合数学模型，给出该数学模型的求解策略与方法，在Fortran95平台下开发高水压下岩体裂纹扩展的渗流-断裂耦合分析程序 HWFSC.for。高水压下岩体裂纹扩展的渗流-断裂耦合体现在岩体裂纹网络和渗流初始条件都随渗流时步变化。对高压注水岩体裂纹扩展过程进行渗流-断裂耦合分析。结果表明，高压注水条件下，岩体裂纹扩展存在起动水压力，当水压力大于起动水压力时，裂纹尖端开始萌生翼形裂纹，随着裂纹水压力的增加，翼形裂纹扩展，进而与其他裂纹搭接贯通，停止扩展。渗流-断裂耦合分析考虑了裂纹动、静水压力对裂纹产生的法向扩张效应及翼形裂纹的扩展而形成新的渗流通道两方面的影响，连通裂纹数随渗流的发展而增加。岩体裂纹的渗流-断裂耦合分析，能较真实地再现岩体裂纹的水力劈裂现象，描述岩体裂纹的扩展、贯通过程及与之相耦合的渗流响应。

关键词: 岩石力学, 高水压, 渗流-断裂耦合, 数值实现, 水力劈裂

Abstract: With the theory of fluid mechanics and fracturing mechanics combined with Monte Carlo method to describe random distribution of rock cracks, seepage-fracture coupling mechanism involving deformation of primary crack, initiation, propagation and coalescence of wing cracks under high hydraulic pressure was studied. The mathematical model of seepage-fracture coupling of rock masses cracks propagation was established. The solving strategies and methods were proposed, as well as developing the analysis program HWFSC.for for seepage-fracture coupling of cracks propagation under high hydraulic pressure on the Fortran95 platform. The fact that crack networks and seepage initial condition vary with seepage conditions embodies in seepage-fracture coupling of cracking propagation under high hydraulic pressure. Coupling analysis of the process of rock cracking propagation during high pressure water injection process comes to the conclusion: starting water pressure has been shown to reside in rock cracking propagation under high hydraulic pressure, when the water pressure is more than the starting water pressure, the wing crack is born on the crack tips, as water pressure on the crack tips increases, the wing cracks propagate, and then coalesce with other cracks, finally stop propagating . The analysis of seepage-fracture coupling considers the influence of the dynamic and static water pressure of the cracks on the cracks normal expansionary and the wing cracks propagation, and the number of connected cracks increases as the seepage develops. Analysis of seepage-fracture coupling analysis of rock cracks can re-create the phenomenon of hydraulic fracturing, describe the process of rock cracks propagation, the rock bridge coalescence and inter-coupling response of seepage in fractured rock masses.

Key words: rock mechanics, high hydraulic pressure, seepage-fracture coupling, numerical verification, hydraulic fracturing

中图分类号:

TU 452

赵延林，彭青阳，万文，王卫军，张盛国 , . 高水压下岩体裂纹扩展的渗流-断裂耦合机制与数值实现[J]. , 2014, 299(2): 556-564.

ZHAO Yan-lin, PENG Qing-yang, WAN Wen, WANG Wei-jun, ZHANG Sheng-guo, . Seepage-fracture coupling mechanism of rock masses cracking propagation under high hydraulic pressure and numerical verification[J]. , 2014, 299(2): 556-564.

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