跨断层隧道施工应力路径识别与扰动分析∗

乔亚飞

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跨断层隧道施工应力路径识别与扰动分析∗

“西部艰险山区重大基础设施防灾减灾关键理论与技术”专题其他论文综述 | 更新时间：2026-01-04

- 跨断层隧道施工应力路径识别与扰动分析∗
- Identification of Stress Path and Analysis of Disturbance Induced by Construction of Tunnel across Fault
- 防灾减灾工程学报 2023年43卷第1期页码：50-59
- 作者机构：
  
  同济大学土木工程学院地下建筑与工程系,上海,200092
- 作者简介：
- 基金信息：
  
  国家自然科学基金(42007255,52090083)、滇中引水工程关键技术研究(2020)资助
- DOI：
  中图分类号：
- 纸质出版：2023
- 稿件说明：
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乔亚飞. 跨断层隧道施工应力路径识别与扰动分析∗[J]. 防灾减灾工程学报, 2023,43(1):50-59.

乔亚飞,肖颖鸣,丁文其,何满潮,樊勇.跨断层隧道施工应力路径识别与扰动分析∗[J].防灾减灾工程学报,2023,43(1):50-59
乔亚飞. 跨断层隧道施工应力路径识别与扰动分析∗[J]. 防灾减灾工程学报, 2023,43(1):50-59. DOI：

乔亚飞,肖颖鸣,丁文其,何满潮,樊勇.跨断层隧道施工应力路径识别与扰动分析∗[J].防灾减灾工程学报,2023,43(1):50-59 DOI：

摘要

跨断层隧道围岩性质会发生突变，给隧道施工扰动分析和安全预测带来了挑战。准确识别跨断层隧道在不同围岩条件下施工诱发的应力路径并开展基于应力路径的扰动分析，具有重要的科学价值和工程实践意义。因此，构建了基于围岩应力路径的隧道开挖扰动分析方法，通过三维数值分析识别了跨断层隧道施工诱发的典型应力路径并进行了扰动分析，总结了跨断层隧道施工扰动时空规律。结合围岩的强度准则和应力路径，用扰动系数描述扰动后围岩应力状态接近破坏的程度。随着扰动系数的增大，围岩应力状态逐渐接近破坏准则，当扰动系数等于 1 时，围岩发生破坏。跨断层隧道在上下盘围岩区的扰动系数始终小于 1，处于弹性状态；而断层破碎区因围岩性质差，其开挖扰动系数达到 1，进入塑性和破坏状态。离洞壁越远，施工扰动越小，扰动系数亦越小。支护后，断层破碎区和上下盘硬岩区的扰动系数均出现减小趋势，围岩趋于稳定，表明了支护的有效性。

Abstract

The mechanical properties of rock changes abruptly at the fault， which poses challenges for the analysis of construction disturbance and safety prediction of tunnels across faults. It is of great sci- entific value and practical engineering significance to accurately identify the stress path induced by the construction of a tunnel across faults under different surrounding rock conditions and performing distur- bance analysis based on the stress path. Therefore， this paper proposes a new analysis method of dis- turbance induced by the tunnel construction based on the stress path and identifies the typical stress path induced by the construction of a tunnel across a fault through three-dimensional numerical analy- sis. The disturbance analysis is finally performed and the results are summarized in terms of the time-space law of construction disturbance. By combining the strength criterion and stress path， the distur- bance coefficient (DC) is defined to describe the relative distance between the stress state and the strength line. As DC increases， the stress state approaches the strength line. When DC=1， the rock reaches the failure state. For tunnels across faults， DC in the footwall or hanging wall is always less than 1， indicating its elastic state， while DC in the fault equals 1 after excavation due to its poor me- chanical properties. DC deceases with the increase of distance to the cave. After the construction of lin- ing， DC in both fault zone and footwall/hanging wall zone decrease， and the surrounding rock become more stable， demonstrating the effectiveness of the lining.

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references

陶志刚,罗森林,李梦楠,等.层状板岩隧道大变形控制参数优化数值模拟分析及现场试验[J].岩石力学与工程学报,2020,39(3):491-506.Tao Z G,Luo S L,Li M N,et al.Optimization of largedeformation control parameters of layered slate tunnelsbased on numerical simulation and field test[J].ChineseJournal of Rock Mechanics and Engineering,2020,39(3):491-506.(in Chinese)

肖春晓,唐倩,徐军,等.开挖扰动及降雨入渗影响的地表沉降特征研究[J].中国安全科学学报,2020,30(2):133-139.Xiao C X,Tang Q,Xu J,et al.Characteristics of surfacesettlement induced by excavation disturbance and rain?fall infiltration[J].China Safety Science Journal,2020,30(2):133-139.(in Chinese)

邢芳.大断面巷道煤柱帮在开挖扰动下的应力场[J].煤炭技术,2019,38(4):53-56.Xing F.Stress field of coal pillar in large section road?way under excavation disturbance[J].Coal Technolo?gy,2019,38(4):53-56.(in Chinese)

徐文彬,宋卫东,杜建华,等.金属矿山底部结构巷道群开挖扰动稳定性分析[J].地下空间与工程学报,2014,10(3):689-696.Xu W B,Song W D,Du J H,et al.Influence on the sta?bility of bottom structure openings by excavation in met?al mines[J].Chinese Journal of Underground Space andEngineering,2014,10(3):689-696.(in Chinese)

Cantieni L,Anagnostou G.The effect of the stress pathon squeezing behavior in tunneling[J].Rock Mechanicsand Rock Engineering,2009,42(2):289-318.

Cai H,Lu A,Ma Y.An analytical solution for shallowburied tunnel reinforced by point anchored rockbolts[J].Tunnelling and Underground Space Technology,2020,100:103402.

Huang F,Zhu H,Xu Q,et al.The effect of weak inter?layer on the failure pattern of rock mass around tunnelScaled model tests and numerical analysis[J].Tunnel?ling and Underground Space Technology,2013,35(APR):207-218.

周建,胡坚,王浩,等.深埋隧洞分步支护合理支护时机的力学研究[J].工程力学,2019,36(12):145-152.Zhou J,Hu J,Wang H,et al.Mechanical study on stepby-timely supporting for deep-buried tunnels[J].Engi?neering Mechanics,2019,36(12):145-152.(in Chi?nese)

任明洋,张强勇,陈尚远,等.复杂地质条件下大埋深隧洞衬砌与围岩协同作用物理模型试验研究[J].土木工程学报,2019,52(8):98-109.Ren M Y,Zhang Q Y,Chen S Y,et al.Physical modeltest study on synergistic action of lining-rock for deeptunnel under complex geological conditions[J].ChinaCivil Engineering Journal,2019,52(8):98-109.(in Chi?nese)

Mousivand M,Malek M,Nekooei M,et al.Applicationof convergence-confinement method in analysis of shal?low non-circular tunnels[J].Geotechnical and Geologi?cal Engineering,2017,35(3):1185-1198.

Wu X,Jiang Y,Guan Z,et al.Influence of confiningpressure-dependent young's modulus on the conver?gence of underground excavation[J].Tunnelling andUnderground Space Technology,2019,83(JAN):135-144.

Bai Q,Tibbo M,Nasseri M H B,et al.True triaxial ex?perimental investigation of rock response around themine-by tunnel under an in situ 3D stress path[J].RockMechanics and Rock Engineering,2019,52(10):3971-3986.

吴梦军,曹兴松,方林.陡倾岩层隧道开挖力学特性研究[J].地下空间与工程学报,2014,10(4):823-828.Wu M J,Cao X S,Fang L.Research on mechanical be?havior for tunnel excavation in steeply inclined strata[J].Chinese Journal of Underground Space and Engi?neering,2014,10(4):823-828.(in Chinese)

刘聪,李术才,周宗青,等.复杂地层超大断面隧道施工围岩力学特征模型试验[J].岩土力学,2018,39(9):3495-3504.Liu C,Li S C,Zhou Z Q,et al.Model test on mechnicalcharacteristics of surrounding rock during contructionprocess of super-large section tunnel in complex strata[J].Rock and Soil Mechanics,2018,39(9):3495-3504.(in Chinese)

文海家,胡晶,谢朋,等.含2条软弱夹层的隧道围岩开挖过程破坏模式研究[J].中国公路学报,2018,31(10):220-229.Weng H J,Hu J,Xie P,et al.Failure modes of rockssurrounding tunnel with two weak interlayers during ex?cavation[J].China Journal Highway Transportation,2018,31(10):220-229.(in Chinese)

庞义辉,王国法,李冰冰.深部采场覆岩应力路径效应与失稳过程分析[J].岩石力学与工程学报,2020,39(4):682-694.Pang Y H,Wang G F,Li B B.Stress path effect and in?stability process analysis of overlying strata in deepstopes[J].Chinese Journal of Rock Mechanics and En?gineering,2020,39(4):682-694.(in Chinese)

孙振宇,张顶立,房倩,等.浅埋小净距公路隧道围岩压力分布规律[J].中国公路学报,2018,31(9):84-94.Sun Z Y,Zhang D L,Fang Q,et al.Distribution of sur?rounding rock pressure of shallow highway tunnels withsmall spacing[J].China Journal Highway Transporta?tion,2018,31(9):84-94.(in Chinese)

谢和平,高峰,鞠杨.深部岩体力学研究与探索[J].岩石力学与工程学报,2015,34(11):2161-2178.Xie H P,Gao F,Ju Y.Research and development ofrock mechanics in deep ground enginering[J].ChineseJournal of Rock Mechanics and Engineering,2015,34(11):2161-2178.(in Chinese)

Von K.Festigkeitsversuche unter allseitigem[J].Z.Ver?eins Deutscher Ingenieure,1911,55:1749-1757.

Boker R.Die mechanik der bleibenden formanderung inkristallinisch aufgebauten korpern[J].Forschungsarbe?iten,1915,175:1-51.

王忠凯,徐光黎.基于三轴试验和联合强度理论预测盾构施工引起的地表变形[J].岩石力学与工程学报,2019,38(9):1928-1936.Wang Z K,Xu G L.Prediction of ground deformationcaused by shield tunneling based on triaixial test andjoint strength theory[J].Chinese Journal of Rock Me?chanics and Engineering,2019,38(9):1928-1936.(inChinese)

李建贺,盛谦,朱泽奇,等.Mine-by 试验洞开挖过程中围岩应力路径与破坏模式分析[J].岩石力学与工程学报,2017,36(4):821-830.Li J H,Shen Q,Zhu Z Q,et al.Analysis of stress pathand failure mode of surrounding rock during Mine-bytest tunnel excavation[J].Chinese Journal of Rock Me?chanics and Engineering,2017,36(4):821-830.(in Chi?nese)

郑颖人,沈珠江,龚晓南.岩土塑性力学原理[M].北京:中国建筑出版社,2002:52-56.Zheng Y R,Sheng Z J,Gong X N.Principle of geotech?nical plastic mechanics[M].Beijing:China ArchitecturePress,2002:52-56.(in Chinese)

Hoek E,Brown E T.Empirical strength criterion for rock masses[J].Journal of the Geotechnical Engineer?ing Division-ASCE,1980,106(9):1013-1035.

Zhang L,Zhu H.Three-dimensional Hoek-Brownstrength criterion for rocks[J].Journal of Geotechnicaland Geoenvironmental Engineering,2007,133(9):1128-1135.

Simon N,Roslee R,Rafek A G,et al.Rock mass assess?ment using geological strength index(GSI)along theRanau-Tambunan Road,Sabah,Malaysia[J].ResearchJournal of Applied Sciences,Engineering and Technolo?gy,2016,12(1):108-115.

何满潮,景海河,孙晓明.软岩工程地质力学研究进展[J].工程地质学报,2000,8(1):46-62.He M C,Jing H H,Sun X M.Research progress of softrock engineering geomechanics in china coal mine[J].Journal of Engineering Geology,2000,8(1):46-62.(inChinese)

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