水力劈裂裂隙扩展与软弱面作用机理离散元研究

doi:10.12068/j.issn.1005-3026.2021.03.021

东北大学学报（自然科学版） ›› 2021, Vol. 42 ›› Issue (3): 444-456.DOI: 10.12068/j.issn.1005-3026.2021.03.021

• 资源与土木工程 • 上一篇

水力劈裂裂隙扩展与软弱面作用机理离散元研究

刘帅奇^1,2,3，马凤山^1,2，郭捷^1,2，孙琪皓^1,2,3

(1. 中国科学院地质与地球物理研究所页岩气与地质工程重点实验室，北京100029; 2. 中国科学院地球科学研究院，北京100029; 3. 中国科学院大学地球与行星科学学院，北京100049)

收稿日期:2020-07-02 修回日期:2020-07-02 接受日期:2020-07-02 发布日期:2021-03-12
通讯作者: 刘帅奇
作者简介:刘帅奇(1993-)，男，河北保定人，中国科学院地质与地球物理研究所博士研究生；马凤山(1964-)，男，河北沧州人，中国科学院地质与地球物理研究所研究员，博士生导师.
基金资助:
国家自然科学基金资助项目(41831293， 41877274， 41772341).

Discrete Element Investigation on the Interaction of Hydraulic Fracturing and Weak Plane in Deep Tunnels

LIU Shuai-qi^1,2,3， MA Feng-shan^1,2， GUO Jie^1,2， SUN Qi-hao^1,2,3

1. Key Laboratory of Shale Gas and Geoengineering， Institute of Geology and Geophysics， Chinese Academy of Sciences， Beijing 100029， China; 2. Innovation Academy for Earth Science， Chinese Academy of Sciences，Beijing 100029， China; 3. College of Earth and Planetary Sciences， University of Chinese Academy of Sciences， Beijing 100049， China.

Received:2020-07-02 Revised:2020-07-02 Accepted:2020-07-02 Published:2021-03-12
Contact: MA Feng-shan
About author:-
Supported by:
-

摘要/Abstract

摘要： 针对高承压水引发水力劈裂导致巷道的突水渗水问题，对离散元流固耦合算法进行改进，更新了流体通道长度和水压力对颗粒的作用模式.进行水力劈裂裂隙(HFs)与天然软弱面(WPs)相互作用的数值模拟，得到5种作用模式，并获取不同模式之间的临界水压力值，进一步分析了试件的位移、接触力以及特征点的应力变化.结果表明:1) 定压力注水试验，流体压力值在初始注水处最大，沿裂隙扩展方向逐渐减小;2) 不同模式下试样位移响应具有差异性，法向接触力接触方向存在明显竖直优势面，切向接触力则产生4个垂直的优势方向;3) 测量圆1处应力在起裂阶段变化剧烈，最大主应力始终为压应力，测量圆2处应力响应相对滞后，主应力曲线的特征是由劈裂裂隙和软弱面之间的作用模式决定.

关键词: 颗粒离散元;流固耦合;水力劈裂;位移响应;最大主应力

Abstract: Hydraulic fracturing caused by high confined water is the root cause of water inrush in roadway. The discrete element fluid-solid coupling algorithm was improved， and the action mode of fluid channel length and water pressure on particles was updated. The interaction between the hydro-splitting fractures (HFs) and the weak planes (WPs) was simulated. Five different modes were obtained and the critical pressure values were calculated. The displacement， contact force of the specimen and the various of the stress at a specific point were analyzed. The research shows that: 1) with a constant injection pressure， the pressure value is the largest at the initial crack， then gradually decreases along the crack. 2) the displacement response are different under five interaction modes. The normal contact force has obvious vertical dominant surface in its contact direction， and the shear contact force generates four vertical dominant distribution directions. 3) the stress at Mc1 changes dramatically during the initiation stage， and the maxmium principal is always compressive. Stress response in Mc2 is relatively hysteretic. The diversity of principal stress is fundamentally determined by the interaction mode between HFs and WPs.

Key words: particle flow code(PFC); fluid-solid coupling; hydraulic fracturing; displacement response; maximum principal stress

中图分类号:

TU45

刘帅奇，马凤山，郭捷，孙琪皓. 水力劈裂裂隙扩展与软弱面作用机理离散元研究[J]. 东北大学学报（自然科学版）, 2021, 42(3): 444-456.

LIU Shuai-qi， MA Feng-shan， GUO Jie， SUN Qi-hao. Discrete Element Investigation on the Interaction of Hydraulic Fracturing and Weak Plane in Deep Tunnels[J]. Journal of Northeastern University(Natural Science), 2021, 42(3): 444-456.

参考文献

[1]谢和平.“深部岩体力学与开采理论”研究构想与预期成果展望［J］.工程科学与技术，2017，49 (2): 1-16.(Xie He-ping. Research framework and anticipated results of deep rock mechanics and mining theory［J］. Advanced Engineering Sciences，2017，49(2):1-16.)
[2]Andreev G E. Brittle failure of rock materials:test results and constitutive models［M］. Rotterdam:A A Balkema，1995.
[3]仵彦卿.岩体水力学基础(七):岩体水力学参数的确定方法［J］. 水文地质工程地质，1998(2):42-48.(Xu Yan-qing. Rock mass hydraulics foundation (7): determination method of rock mass hydraulic parameters ［J］. Hydrogeological Engineering Geology，1998(2):42-48.)
[4]施龙青，韩进. 底板突水机制及预测预报［M］.北京:中国矿业大学出版社，2004.(Shi Long-qing，Han Jin. Floor water inrush mechanism and prediction［M］. Beijing:China University of Mining and Technology Press，2004.)
[5]许学汉.煤矿突水预报研究［M］. 北京:地质出版社，1991.(Xu Xue-han.Research on coal mine water inrush prediction［M］. Beijing:Geological Publishing House，1991.)
[6]Fucik E M.The Teton Dam failure—a discussion［J］. Engineering Geology，1987，24(1/2/3/4):207-215.
[7]黄润秋，王贤能，陈龙生. 深埋隧道涌水过程的水力劈裂作用分析［J］. 岩石力学与工程学报， 2000， 19(5):573-576.(Huang Run-qiu，Wang Xian-neng，Chen Long-sheng. Hydro-splitting off analysis on underground water in deep-lying tunnels and its effect on water gushing out［J］. Chinese Journal of Rock Mechanics and Engineering，2000，19(5):573-576.)
[8]李宗利，张宏朝，任青文. 岩石裂纹水力劈裂分析与临界水压计算［J］. 岩土力学， 2005，26(8):1216-1220.(Li Zong-li，Zhang Hong-chao，Ren Qing-wen. Analysis of hydraulic fracturing and calculation of critical internal water pressure of rock fracture［J］. Rock and Soil Mechanics，2005，26(8):1216-1220.)
[9]王成，邓安福. 岩体节理内压致裂解析研究［J］. 岩石力学与工程学报，2002，21(5):640-643.(Wang Cheng，Deng An-fu. Analytical study on fracture of jointed rock mass under internal pressure［J］. Chinese Journal of Rock Mechanics and Engineering，2002，21(5):640-643.)
[10]朱珍德，胡定. 裂隙水压力对岩体强度的影响［J］. 岩土力学，2000，21(1):64-67.(Zhu Zhen-de，Hu Ding. The effect of intestitial water pressure on rock mass strength［J］. Rock and Soil Mechanics，2000，21(1):64-67.)
[11]Renshaw C，Pollard D. An experimentally verified criterion for propagation across unbounded frictional interfaces in brittle，linear elastic materials［J］. International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts，1995，32(3):237-249.
[12]Blair S C，Thorpe R K ，Heuze F. Propagation of fluid-driven fractures in jointed rock. Part 2—physical tests on blocks with an interface or lens［J］. International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts，1990，27(4):255-268.
[13]李全明，张丙印，于玉贞，等. 土石坝水力劈裂发生过程的有限元数值模拟［J］. 岩土工程学报，2007，29 (2):212-217.(Li Quan-ming，Zhang Bing-yin，Yu Yu-zhen，et al. Numerical simulation of the process of hydraulic fracturing in earth and rockfill dams［J］. Chinese Journal of Geotechnical Engineering，2007，29(2):212-217.)
[14]郑安兴，罗先启，陈振华. 基于扩展有限元法的岩体水力劈裂耦合模型［J］. 岩土力学，2019，40 (2):385-394. (Zheng An-xing，Luo Xian-qi，Chen Zhen-hua. Hydraulic fracturing coupling model of rock mass based on extended finite element method［J］. Rock and Soil Mechanics，2019，40(2):385-394.)
[15]Taron J，Elsworth D. Thermal-hydrologic-mechanical-chemical processes in the evolution of engineered geothermal reservoirs［J］. International Journal of Rock Mechanics ＆ Mining Sciences，2009，46(5):855-864.
[16]Papanastasiou P C.A coupled elastoplastic hydraulic fracturing model［J］. International Journal of Rock Mechanics ＆ Mining Sciences，1997，34(3/4):240.e1-240.e15.
[17]Du C Z，Mao X B，Bu W K. Analysis of fracture propagation in coal seams during hydraulic fracturing［J］. Journal of Mining and Safety Engineering，2008，25(2):231-234.
[18]Sesetty V，Ghassemi A. Simulation of hydraulic fractures and their interactions with natural fractures［C］// Proceedings of the 46^th US Rock Mechanics/Geomechanics Symposium. Chicago，2012:24-27.
[19]Zeng Q，Yao J. Numerical simulation of fracture network generation in naturally fractured reservoirs［J］. Journal of Natural Gas Science and Engineering，2016，30:430-443.
[20]Dehghan A N，Goshtasbi K， Ahangari K，et al. 3D numerical modeling of the propagation of hydraulic fracture at its intersection with natural (pre-existing) fracture［J］. Rock Mechanics and Rock Engineering，2017，50(2):367-386.
[21]Cundall P A，Strack O D L. Discussion:a discrete numerical model for granular assemblies［J］. Geotechnique，1980，30(3):331-336.
[22]Hazzard J F，Young R P，Oates S J. Numerical modeling of seismicity induced by fluid injection in a fractured reservoir:mining and tunnel innovation and opportunity［C］//Proceedings of the 5th North American Rock Mechanics Symposium.Toronto， 2002:1023-1030.
[23]周健，张刚，孔戈. 渗流的颗粒流细观模拟［J］. 水利学报，2006，37(1):28-32.(Zhou Jian，Zhang Gang，Kong Ge. Meso-mechanics simulation of seepage with particle flow code［J］. Journal Hydraulic Engineering，2006，37(1):28-32.)
[24]Zhang Q，Zhang X P， Ji P Q. Numerical study of interaction between a hydraulic fracture and a weak plane using the bonded-particle model based on moment tensors［J］. Computer Geotechnique，2019，105:79-93.
[25]Potyondy D O，Cundall P A. A bonded-particle model for rock［J］. International Journal of Rock Mechanics ＆ Mining Sciences，2004，41(8):1329-1364.
[26]Cho N，Martin C D，Sego D C. A clumped particle model for rock［J］. International Journal of Rock Mechanics ＆ Mining Sciences，2007，44(7):997-1010.
[27]Cundall P A，Strack O D L. Discussion:a discrete numerical model for granular assemblies［J］. Geotechnique，1980，30(3):331-336.
[28]Cundall P.Fluid formulation for PFC2D［M］.Minneapolis，MN:Itasca Consulting Group，2000.
[29]Zhou J，Zhang L Q. Numerical modeling and investigation of fluid-driven fracture propagation in reservoirs based on a modified fluid-mechanically coupled model in two-dimensional particle flow code［J］. Energies，2016，9(9):699.
[30]Tan P，Jing Y，Xiong Z Y，et al. Effect of interface property on hydraulic fracture vertical propagation behavior in layered formation based on discrete element modeling［J］. Journal of Geophysics and Engineering，2018，15(4):1542-1550.［31］Han Z H，Zhou J，Zhang L Q. Influence of grain size heterogeneity and in situ stress on the hydraulic fracturing process by PFC2D modeling［J］. Energies，2018，11(6):1413. ［32］郭捷，马凤山，赵海军. 三山岛海底金矿突涌水优势渗流通道与来源研究［J］. 工程地质学报，2015， 23: 784-789.(Guo Jie，Ma Feng-shan，Zhao Hai-jun . Preferred seepage channels and source of water inrush in seabed gold mine at Sanshandao［J］. Journal of Engineering Geology，2015，23:784-789.)［33］Gao S，Zhang J J， Sun S S，et al. Hydrogeological characteristics of gold deposit in North Sea Area of Sanshandao［J］. Gold Science Technology，2016，24:11-16.［34］Liu S，Ma F，Zhao H，et al. Numerical investigation of a hydrosplitting fracture and weak plane interaction using discrete element modeling［J］. Water，2020，12(2):535.［35］Hubbert M K，Willis D G. Mechanics of hydraulic fracturing［J］. Petroleum Transactions AIME，1972，18(1):369-390.［36］Zoback M D，Rummel F，Jungi R，et al. Laboratory hydraulic fracturing experiments in intact and pre-fractured rock［J］. International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts，1977，14(2):49-58.［37］Zhou J，Zhang L，Pan Z. Numerical studies of interactions between hydraulic and natural fractures by smooth joint model［J］. Journal of Natural Gas Science and Engineering，2017，46:592-602.［38］Emilien A，Farhang R. Stress-strain behavior and geometrical properties of packings of elongated particles［J］. Physical Review E，2010，81:703-708.

水力劈裂裂隙扩展与软弱面作用机理离散元研究

Discrete Element Investigation on the Interaction of Hydraulic Fracturing and Weak Plane in Deep Tunnels

RichHTML

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	贾蓬，李博，祝鹏程，王琦伟. 单轴受压高温损伤砂岩的电学响应特征[J]. 东北大学学报（自然科学版）, 2023, 44(4): 558-564.
[2]	康玉梅，谷今，魏梦琦. 不同加载速率下软硬互层类岩石力学及声发射特性[J]. 东北大学学报（自然科学版）, 2023, 44(3): 399-407.
[3]	纪洪广，陈东升，苏晓波，权道路. 基于三轴加卸载试验的花岗岩弹性模量变异与能量演化分析[J]. 东北大学学报（自然科学版）, 2023, 44(3): 415-423.
[4]	王述红，朱宝强，张泽. 基于改进理想点模型的岩体结构面分级方法[J]. 东北大学学报（自然科学版）, 2021, 42(1): 117-123.
[5]	韩滔，金长宇，鲁宇，刘冬. 岩体裂隙区全长黏结锚杆应变测试方法[J]. 东北大学学报（自然科学版）, 2021, 42(1): 131-138.
[6]	李光，马凤山，郭捷，赵海军. 大尺寸工程模型试验中的相似材料配比试验研究[J]. 东北大学学报:自然科学版, 2020, 41(11): 1653-1660.
[7]	王述红，朱宝强，王鹏宇. 模拟退火聚类算法在结构面产状分组中的应用[J]. 东北大学学报:自然科学版, 2020, 41(9): 1328-1333.
[8]	付腾飞，徐涛，朱万成，王兴伟. 基于多晶离散元法的砂岩三轴压缩损伤特性[J]. 东北大学学报:自然科学版, 2020, 41(7): 968-974.
[9]	王鹏宇，朱承金，王述红，姚骞. 预制管廊横向接头抗弯力学模型及取值方法[J]. 东北大学学报:自然科学版, 2020, 41(5): 629-634.
[10]	张泽，王述红，杨天娇，张雨浓. 寒区隧道围岩水热耦合数值分析[J]. 东北大学学报:自然科学版, 2020, 41(5): 635-641.
[11]	朱承金，王述红，任艺鹏，孙子涵. 无人机摄影测量边坡结构面及块体稳定分析[J]. 东北大学学报:自然科学版, 2019, 40(11): 1636-1641.
[12]	贾蓬，张瑶，刘冬桥，张亚兵. 真三轴条件下单裂隙砂岩破坏过程的颗粒流模拟[J]. 东北大学学报:自然科学版, 2019, 40(11): 1654-1659.
[13]	杨天娇，王述红，张泽，高钰. 寒区隧道围岩水热力耦合数值分析[J]. 东北大学学报:自然科学版, 2019, 40(8): 1178-1184.
[14]	王鹏宇，王述红，朱承金. 城市地下管廊结构地震动力响应分析[J]. 东北大学学报:自然科学版, 2019, 40(7): 1020-1027.
[15]	王述红，邱伟，高红岩，张紫杉. 数值流形位移法在岩体裂缝扩展中的应用[J]. 东北大学学报:自然科学版, 2019, 40(4): 552-556.