Compensation excavation method control for large deformation disaster of mountain soft rock tunnel

In recent years,the mine tunneling method and the new Austrian tunneling method have been considered the main theories of tunneling approaches in China.It is difficult for the traditional technique to overcome the large deformation problems imposed by complex geological conditions of mountain soft rock tunneling.Hence,the compensation excavation method has been proposed to solve this issue under the consideration that all damage in tunneling originates from the excavation.It uses supportive strategies to counteract the excavation effects successfully.This paper provides an overview of the fundamental ideas of the compensation excavation method,methodologies,and field applications.The scientific validity and feasibility of the compensation excavation method were investigated through the practical engineering study of the Muzhailing and Changning tunnels.

Numerical modeling of large deformation and nonlinear frictional contact of excavation boundary of deep soft rock tunnel

Roadways excavated in soft rocks at great depth are difficult to be maintained due to large deformation of surrounding rocks, which greatly influences the safety and efficiency of deep resources exploitation. During the excavation process of a deep soft rock tunnel, the rock wall may be compacted due to large deformation. In this paper, the technique to address this problem by a two-dimensional (2D) finite element software, large deformation engineering analyses software (LDEAS 1.0), is provided. By using the Lagrange multiplier method, the kinematic constraint of non-penetrating condition and static constraint of Coulomb friction are introduced to the governing equations in the form of incremental displacement. The numerical example demonstrates the efficiency of this technology. Deformations of a transportation tunnel in inclined soft rock strata at the depth of 1 000 m in Qishan coal mine and a tunnel excavated to three different depths are analyzed by two models, i.e. the additive decomposition model and polar decomposition model. It can be found that the deformation of the transportation tunnel is asymmetrical due to the inclination of rock strata. For extremely soft rock, large deformation can converge only for the additive decomposition model. The deformation of surrounding rocks increases with the increase in the tunnel depth for both models. At the same depth, the deformation calculated by the additive decomposition model is smaller than that by the polar decomposition model.

Time-dependent squeezing deformation mechanism of tunnels in layered soft-rock stratum under high geo-stress

Large squeezing deformation of layered soft rock tunnel under high geo-stress has a significant time-dependent deformation behavior.In this paper,we studied the deformation mechanism during the construction period of deep-buried softrock tunnel by means of a combination of field observations and a numerical method.First,a new classification criterion for large deformations based on the power exponent variation law between the deformation and the strength-stress ratio is proposed.Then,the initial damage tensor reflecting the bedding plane(joint)distribution and an equivalent damage evolution equation derived from the viscoplastic strain are introduced based on the geometric research method,i.e.,a new rheological damage model(RDL model)of layered soft rock is established consisting of elastic,viscous,viscoelastic,viscoplastic and plastic elements.A field test was conducted on the Maoxian tunnel in Sichuan province,southwestern China,which is in broken phyllite(layered soft rock)under high geo-stress.The tunnel has experienced large deformation due to serious squeezing pressure,thus we adopted double primary support method to overcome the supporting structure failure problems.The rheological parameters of phyllite in the Maoxian tunnel were recognized by using SA-PSO optimization,and the RDL model does a good job in describing the time-dependent deformation behavior of a layered soft-rock tunnel under high geo-stress.Thus,the RDL model was used to investigate the supporting effect and bearing mechanism of the double primary support method.Compared with the single primary support method,the surrounding rock pressure,secondary lining force,surrounding rock deformation,and the depth of the damage to the rock mass was reduced by 40%-60%after the double primary support method was used.

Analysis of mechanical behavior of soft rocks and stability control in deep tunnels

Due to the weakness in mechanical properties of chlorite schist and the high in situ stress in Jinping II hydropower station, the rock mass surrounding the diversion tunnels located in chlorite schist was observed with extremely large deformations. This may significantly increase the risk of tunnel instability during excavation. In order to assess the stability of the diversion tunnels laboratory tests were carried out in association with the petrophysical properties, mechanical behaviors and waterlweakening properties of chlorite schist. The continuous deformation of surrounding rock mass, the destruction of the support structure and a large-scale collapse induced by the weak chlorite schist and high in situ stress were analyzed. The distributions of compressive deformation in the excavation zone with large deformations were also studied. In this regard, two reinforcement schemes for the excavation of diversion tunnel bottom section were proposed accordingly. This study could offer theoretical basis for deed tunnel construction in similar geological condition~

极高地应力软岩隧道非对称变形机理及支护优化研究

针对极大断面公路隧道施工中出现的非对称大变形问题,考虑高地应力第一主应力与隧道轴线关系、层状软岩夹层与互层状态、掌子面软岩空间不对称、地下水等因素,基于对工程地质条件、围岩与支护结构失效及破坏特征的分析,结合岩样物理力学特性室内试验研究及地应力实测情况,探究了非对称大变形形成机理并提出针对性的支护结果优化方案。结果表明:高地应力层状软岩隧道围岩不对称变形是在岩层倾角α、最大水平主应力与隧道轴线夹角β和岩层夹角γ、围岩岩性和地下水综合作用下的大变形,围岩不对称部位由以上几种因素共同决定;当主应力σ1与隧道轴线既不垂直也不平行时,会产生挤压性偏压构造水平地应力,使隧道横断面侧向受力不对称,发生偏压性非对称大变形;通过改变锚杆的布设方式、提高超前注浆小导管的长度和刚度、喷射临时封闭、在防水板与喷射砼间增加高密度橡塑海绵板缓冲层等措施,可以有效的减少变形量,防止围岩因开挖扰动而松动和坍塌。

施工期铁路隧道软岩大变形快速分级方法研究

研究目的:西南复杂艰险山区等典型构造活跃区的构造地质环境复杂,断裂、褶皱发育,构造应力显著,铁路隧道围岩大变形问题突出,随着构造活跃区铁路隧道工程日益增加,将面临更严峻的大变形问题。在隧道施工开挖过程中,快速判别可能发生的大变形等级,有利于施工工法的调整和支护措施的制定。研究结论:(1)深入分析构造软岩大变形工程案例,以施工期掌子面开挖揭示围岩分级数据为基准,结合区域地应力、岩层厚度、岩性等大变形关键控制因素,快速判定大变形等级,提出了施工期铁路隧道围岩大变形快速分级方法,并结合典型工程案例对分级方法的有效性和准确性进行了验证;(2)本研究成果可应用于施工期间铁路隧道开挖围岩大变形的快速分级,适用于工程地质勘察领域。

考虑湿度应力的深部软岩隧道大变形控制研究

为探明深部高地应力软岩隧道大变形产生机理,制定适应大变形控制措施,以月直山隧道为工程依托,首先明确求解围岩形变压力与松动压力的Kastner与Caquot公式,基于岩体弹塑性力学与连续介质理论建立围岩湿度应力解析解,采用收敛-约束法绘制出3种围岩应力作用下围岩与初期支护特征曲线,分析断面变形过程中围岩与支护结构相互作用规律及3种应力占比演化规律。分别以混凝土与型钢钢架作为二衬支护结构对月直山隧道围岩稳定性进行计算分析,明确考虑湿度应力与松动压力条件下隧道二衬最优支护时机与支护参数,以支护结构安全系数FS评判出最优支护方案并对隧道软岩大变形进行治理。结果表明:当围岩径向位移达到550 mm时,仅考虑形变压力Pi时围岩对支护结构的压力P仅为0.813 MPa,考虑湿度应力Pw与松动压力Pa时P增大为1.372 MPa,湿度应力与松动应力总占比达40.7%,仅考虑形变压力而设计的支护结构不满足围岩稳定性要求;根据“卸压支护”理念,确定以“位移释放峰值upeak=0.325 m”与“间距d=0.7 m”作为增设第二层钢架的最佳支护时机与支护参数,现场二次钢架设置24天后使围岩变形收敛于50.8 mm,围岩大变形得到控制,研究成果可为今后相关隧道工程设计与施工提供参考。

西(宁)成(都)铁路高地应力节理发育软岩地层隧道支护体系研究

为保证西成铁路高地应力节理发育软岩大变形隧道安全修建,采用现场勘察、室内试验、地应力测试、工程类比、数值模拟等方法展开研究,结果表明,西成铁路与毗邻兰渝线地质条件类似,均以二叠系、三叠系板岩与砂岩为主,层理清晰、节理裂隙发育,地应力以水平主应力为主导,水平主应力在10~30 MPa之间,竖直主应力在4~13 MPa之间,有较强水平构造应力作用,兰渝线控制围岩变形主要采用增加预留变形量、自进式长锚杆、钢花管加固、增加初支及衬砌刚度、钢纤维喷射混凝土等技术措施。在此基础上针对西成铁路节理发育软岩大变形主要发生在垂直节理倾角方向上的特点,提出首先增大矢跨比,然后增大钢拱架刚度,对于Ⅲ级大变形在垂直节理方向设置预应力锚索的非对称大变形隧道支护体系,该支护体系相比传统支护体系能够减小13.8%~21.2%软岩变形,对于控制节理发育软岩变形效果良好。

基于变形控制的某深埋软岩水工隧洞初期支护参数的选择与验证

大变形下围岩的稳定控制一直是水利水电、公路、铁路等行业的传统难题,尚未形成一套验证软岩大变形等级下初期支护型式及参数选取的经验方法。依据某深埋水工隧洞工程地质情况,选择典型洞段预测挤压变形风险,利用控制变形估算所需支护力,依据规范和相关工程经验确定支护类型与参数的同时,考虑实际开挖过程利用数值仿真分析验算支护的合理性。结果表明,该隧洞具有极大的大变形风险,采用支护力的方法所确定的支护类型和参数基本合理,可将围岩变形有效控制在规范要求的1.0%~3.0%范围,且锚杆长度及支护应力等均未超过极限强度。

高地应力软岩地层敞开式TBM法隧洞围岩变形控制技术——以香炉山隧洞为例

为解决敞开式TBM在滇西地区高地应力软岩地层施工中遭遇围岩大变形而导致的支护破坏、设备频繁被卡、隧洞侵限等工程难题,通过分析围岩允许变形量与变形规律,提出围岩控制时空原则:有效初期支护施作时间为开挖后15 d内、空间位置为距掌子面30 m范围内,TBM掘进日进尺不低于2 m/d。通过不同类型的支护结构现场试验,得出控制围岩变形的有效措施为预应力长锚索主动控制变形、灌混凝土箱体H型钢拱架被动强支撑。另通过滇中引水香炉山隧洞敞开式TBM施工实践,开发出“掌子面位置刀盘扩挖预留允许变形量、围岩出护盾灌混凝土箱体拱架被动强支撑、隧洞上半圆前置式自动化喷混凝土早封闭、预应力长锚索主动控制深层围岩变形、隧洞底部自进式锚杆后补强”等围岩变形有效控制技术。

深埋软岩隧道衬砌开裂原因分析及整治技术研究

针对深埋高地应力软岩大变形隧道支护开裂问题,以某铁路A工程为依托,分析了衬砌开裂的原因,结合现场实际条件提出相应的整治技术。研究表明,复杂地质构造及高地应力岩体流变等因素引发围岩挤压甚至松动变形是衬砌开裂的主要原因,采用围岩加固+拆换衬砌整治技术有效控制大变形及二次开裂问题,可保障隧道后期运营安全,为类似工程提供参考。

大埋深引水隧洞穿越断裂带围岩变形规律研究

断裂带是深埋隧洞开挖过程中常见的不良地质现象。以滇中引水工程香炉山隧洞为工程背景,通过建立隧洞穿越断裂带的开挖数值模型,研究了隧洞拱顶、拱底、拱腰两侧的围岩变形规律,进一步分析了隧洞在穿越不同断裂带宽度、倾角、走向以及不同隧洞埋深工况下对围岩变形的影响。研究表明,由于断裂带区域的存在,围岩的垂直位移和水平位移发生了明显的改变,越靠近断裂带核心区域,隧洞拱顶、拱底和拱腰两侧围岩的变形越大,在断裂带中心区域附近围岩的变形达到最大值;围岩的垂直位移和水平位移随着断裂带宽度和隧洞埋深的增大而增大,随着断裂带倾角的增大而减小;断裂带走向的变化对围岩的垂直位移和水平位移影响较小。对于拱顶沉降,其综合因素影响程度从小到大依次为断裂带走向、断裂带倾角、断裂带宽度、隧洞埋深。

软岩小净距大变形隧道施工控制措施的优化

成兰铁路杨家坪隧道处于龙门山主中央断裂带与龙门山后山断裂带之间,区内发育有与隧道基本平行的断层、背斜及向斜,构造条件复杂;围岩陡倾直立,岩质软弱,呈片状结构。隧道间最小净岩柱为1.66m,施工难度极大、安全风险高。文章结合现场测试数据分析了杨家坪隧道小净距段变形机理,总结了围岩加固及置换、优化支护结构形式、工序错位距离、非爆破开挖方式等应对小净距大变形隧道的优化措施,有效强化了软岩小净距大变形隧道的变形控制能力。

软岩大变形铁路隧道控变技术措施

结合具体工程实例,介绍了高地应力作用下的软岩隧道挤压变形概念,通过对隧道高地应力软岩大变形情况的研究,提出了隧道工程变形控制技术措施。经过实践得出结论,论文提出的技术措施可以控制铁路隧道高地应力软岩大变形问题,确保隧道工程施工质量,为工程顺利进行提供了保障。

软岩大变形隧道施工技术研究

为了提升隧道工程施工水平,总结了软岩隧道的变形机制和分类,分析了CRD法、双侧壁法、留核心土开挖法等在软岩隧道施工中的应用特点。随后,依托扎务隧道,利用MIDAS/GTS软件建立计算模型,计算了不同开挖方法对软岩隧道变形的影响。同时,从技术方案、监控量测和施工管理3方面提出了软岩大变形隧道的施工质量控制措施。

套孔应力解除法在老营盘隧道洞身段的应用

依托老营盘隧道工程,本文采用应力解除法对隧道洞身段Z1K17+880处进行现场地应力测试。由测孔内的原岩应变,利用岩石的本构关系来间接计算原岩应力,同时将取出的岩芯制成标准试件,进行室内试验以获取原岩的力学参数。计算结果表明,最大主应力大小为27.44MPa,倾角-16.56°,方位角192.60°,测点岩石抗压强度与隧道洞身最大主应力之比为0.24。测试结果表明隧道测点处属于极高地应力状态,隧道在施工过程中可能会出现软岩大变形。

炭质板岩软弱围岩隧道挤压变形规律及处理措施分析

炭质板岩软弱围岩隧道施工中存在严重的挤压变形风险,最大位移达62.5cm,呈现潜在坍塌威胁。最大变形速率为34.18mm/d,需80-130d完成90%的变形。以地质调查,室内试验和现场监测为依据,在正确认识隧道变形原因的基础上,提出了变形段加固方案,具体包括:拱腰至拱脚进行超前注浆导管预加固+药卷锚杆和锁脚注浆导管加固。对隧道治理方案进行综合评估,方案取得了较好的治理效果,为类似隧道提供工程指导和借鉴。

软岩大变形隧道不同支护模式的合理性探讨——以木寨岭公路隧道为例

高地应力隧道修建过程中软弱围岩大变形灾害问题极为突出,虽经支护能得到一定程度的治理与改善,但实际工程中支护模式的选择仍是一个难题。首先,总结当前软岩大变形隧道中常用的支护模式,即强力支护、预应力支护和让压支护,并根据支护体系承载特性的不同,将上述3种支护模式划分为主动型支护和被动型支护2类。然后,基于不同支护强度下隧道开挖后围岩变形规律,探究被动支护模式的适用性,提出以挤压因子Nc为控制指标的被动与主动支护模式选用依据,即当挤压因子Nc≥0.2时,现行的强力支护模式能够对围岩进行有效支护,而Nc<0.2时,可根据现场围岩变形情况考虑采用主动支护模式;同时,基于锚固体系材料特性进一步分析主动支护适用性范围可知,当施加预应力不超过200kN时可采用预应力锚杆系统,超过200kN时则建议采用预应力锚索系统。接着,基于预应力锚索系统提出以索体延伸率εa为控制指标的主动与主动-让压支护模式选用依据,即索体工作状态延伸率εa不超过2.3%时可采用主动支护,超过2.3%时则建议采用具有更大变形能力的主动-让压支护模式。最后,依托木寨岭公路隧道典型大变形区段,基于上述支护模式的选用依据选取适宜的支护模式,并开展相应支护模式下的现场试验,试验结果一定程度上验证了选用依据的可行性。

宁缠隧道高地应力软岩大变形控制措施研究

为解决高地应力软岩隧道在建设过程中支护及围岩不稳定、变形时间长、经常性设计变更的难题,通过分析国内外高地应力软岩隧道大变形控制措施成功案例,对隧道所处地应力和地质环境及其对应的工法与支护形式进行分类总结归纳,提出高地应力软岩隧道安全且经济有效的控制措施,并结合实际工程对研究成果进行分析验证。结果表明:1)宁缠隧道岩体极破碎,岩石强度低,围岩产生大变形的主要原因有极高地应力、地层岩性、节理及软化夹层、岩层产状及倾角以及人为因素的影响;2)考虑强度应力比和相对变形并结合地质构造情况对高地应力软岩隧道进行大变形分级,得出5级制分级更合理、精准;3)采取“抗让结合、柔度适度、共同承载”的变形控制理念,并通过预支护、支护、预留变形量、施工工法等措施相结合,可以有效地控制隧道大变形。

基于主动支护的木寨岭隧道高地应力软岩大变形预应力锚索支护设计实践

为解决在建木寨岭特长公路隧道薄层极软岩在高地应力下发生的挤压性大变形问题,结合现场展开的工程地质分析、设计变更、监控量测工作,提出一种预应力长短锚索+W型钢带+柔性纤维网组合的基于主动支护的设计方案。该方案采用“先锚后支”的施工工艺,采用数值分析和试验段施工对设计方案进行验证。结果表明,预应力长短锚索组合的主动支护能够充分发挥锚索的锚固和悬吊作用加固围岩,提高围岩的抗剪能力,控制围岩形变能的释放态势,有效控制围岩变形,将初期支护变形控制在20 cm以内,减小约50%。在实际施工过程中对锚索防腐、锚索支护参数及锚索施工设备选型等进行优化调整,确保了隧道施工的顺利进行。