Numerical analysis and field monitoring tests on shallow tunnels under weak surrounding rock

The Jianpudong No. 4 tunnel is a shallow tunnel, which belongs to Shaoshan County scenic highway in Hunan province, China and whose surrounding rock is weak. According to its characteristics, the field monitoring tests and numerical analysis were done. The mechanical characteristics of shallow tunnels under weak surrounding rock and the stress-strain rule of surrounding rock and support were analyzed. The numerical analysis results show that the settlement caused by upper bench excavating accounts for 44% of the total settlement, and the settlement caused by tunnel upper bench supporting accounts for 56% of the total settlement. The maximum axial force of shotcrete lining is 177.2 k N, which locates in hance under the secondary lining. The maximum moment of shotcrete lining is 5.08 k N·m, which locates in the arch foot. The stress curve of steel arch has three obvious stages during the tunnel construction. The maximum axial force of steel arch is 297.4 k N, which locates in tunnel vault. The axial forces of steel arch are respectively 23.5 k N and-21.8 k N, which is influenced by eccentric compression of shallow tunnel and locates in hance. The results show that there is larger earth pressure in tunnel vault which is most unfavorable position of steel arch. Therefore, the advance support should be strengthened in tunnel vault during construction process.

Deformation mechanism and collapse treatment of the rock surrounding a shallow tunnel based on on-site monitoring

When tunnels are constructed at shallow depths in areas with poor geological conditions,such as portal sections,valleys and hillsides in regions with granitic bedrock,considerable excavation-induced deformation of the surrounding rock may occur,potentially resulting in tunnel collapses.The main reason for these problems is the lack of understanding of the deformation mechanism and evolution of the soft granitic rock surrounding the tunnel and the adoption of inappropriate construction technology and methods.This article analyzes the deformation mechanism of the rock surrounding a shallow tunnel based on in situ monitoring data as a case study and suggests that certain measures should be taken to effectively control the deformation of the surrounding rock and to minimize the potential for tunnel collapse.The results show that the deformation of the granitic soil surrounding the tunnel can be divided into three stages:the rapid deformation stage,the slow deformation stage and the stabilization stage.Appropriate construction methods should be carefully selected to ensure safety during tunnel excavation in the first stage.To avoid secondary disasters caused by tunnel collapses,three treatment measures may be implemented as part of safety management:enhancing the monitoring of the surrounding rock deformation,adjusting the construction methods and optimizing the support systems.In particular,accurate monitoring data and timely information feedback play a vital role in tunnel construction.Therefore,engineers with considerable engineering experience and professional knowledge are needed to analyze the monitoring data and make accurate predictions of tunnel deformation to ensure that reasonable measures are taken in the process of shallow tunnel excavation.

Experimental study on performance of spring damping support structure system for large deformation tunnel in soft rock

According to the convergence confinement theory,it is an effective measure to control the large deformation of high ground stress in fractured soft rock tunnels by using yielding support.The yielding support can be classified as either radial or circumferential yielding support.Circumferential yielding support is achieved by transforming radial displacement into circumferential tangential closure without compromising the support capacity of the primary lining support structure.Based on this,and inspired by the design principle of dampers,a yielding support structure system with spring damping elements as its core was developed,based on the connection characteristics of steel arches in highway tunnel,which can provide increasing support resistance in the yielding deformation section.Then the mechanical properties of spring damping elements were obtained through indoor axial pressure and flexural tests.In addition,according to these results with numerical calculations,the yielding support structure system with embedded spring damping elements can reduce the internal force of the support structure by approximately 10%and increase the area of the plastic zone of the surrounding rock by 11.23%,which can fully utilize the self-bearing capacity of surrounding rock and verify the effectiveness of circumferential yielding support.Finally,the spring damping support structure system was designed with reference to the construction process of the tunnel excavated by drilling and blasting method,and the transformation of the spring damping element to spring damping support structure was achieved.Based on field test results,surrounding ground pressure for the yielding support optimization scheme was reduced by 40%and more evenly distributed,resulting in the successful application and a reduction in the construction cost of large deformation tunnels in soft rock.

高地应力软岩隧道仰拱结构受力特性与参数优化

为探索高地应力软岩隧道施工期间仰拱结构受力特性与合理支护参数,以陕西省宝汉高速公路连城山隧道工程为依托,针对仰拱施工病害及其主要影响因子,采用现场试验与数值模拟相结合的方法,探讨了不同影响因素下的仰拱结构变形与力学响应,分析了仰拱结构变形与受力对不同影响因素的敏感性,基于仰拱结构病害特征及数值模拟结果,对仰拱半径(深度)、仰拱厚度等支护参数进行了优化,并进行了工程验证。结果表明:连城山隧道施工期间仰拱二次衬砌最大接触压力达1.034 MPa,混凝土最大应力超过其抗压强度(30 MPa),出现了仰拱回填隆起、开裂等病害,仰拱设计支护参数难以保障结构稳定;地应力水平和基底围岩劣化对仰拱结构变形与受力状态均有显著影响,其中基底软化深度的影响最为突出,地应力水平次之;减小仰拱半径、增大仰拱厚度、增大仰拱钢筋直径、减小仰拱钢筋间距均能显著抑制仰拱变形,而提高混凝土强度等级对控制仰拱变形效果不明显,且经济性较差;优化后的仰拱受力得以明显改善,有效控制了仰拱结构病害,避免了频繁拆换仰拱,保障了隧道结构安全稳定。研究成果可为类似软岩隧道仰拱变形控制及病害防治提供重要借鉴。

隧道穿越岩堆体围岩剪切特性及分级

为解决隧道穿越岩堆体围岩分级不准确的问题,通过相似材料直剪试验分析岩堆体的直剪特性,将含水率和填充土含量两个因素带入熵权可拓物元法,并结合地质指标进行分级研究。结果表明岩堆体的抗剪强度随着含水率、填充土含量的增大,先增大后减小,最终趋于平稳,过高或过低的含水率和填充土都会“弱化”岩堆体的抗剪强度。根据岩堆体的特点,选取岩石单轴饱和抗压强度、节理裂隙密度、岩体完整性系数、含水率和填充土含量作为分级指标,结合熵权可拓物元法,将所选指标和熵权可拓物元法结合并在工程实例进行验证,分级结果比原方法准确性更好,证明研究提出的围岩分级方法是合理可行的。研究结果能够为岩堆体隧道的围岩分级提供指导,为施工设计和支护方式提供依据。

黄土盾构隧道围岩强度指标结构性参数表征与荷载计算

为了考虑黄土地层特征,获取合理的围岩压力以指导黄土盾构隧道结构设计,通过对比盾构隧道与新奥法隧道围岩压力现场测试数据,结合黄土盾构施工实践,验证形变围岩压力计算黄土盾构隧道围岩荷载的合理性;考虑黄土地层的强度参数,通过芬纳公式构建黄土盾构隧道形变围岩压力的计算方法;采用三轴剪切实验,探究原状黄土的应力应变关系以及应力结构性参数的变化规律,构建应力结构性参数下黄土强度指标的计算方法;结合盾构隧道开挖支护下围岩的应力应变变化规律,建立深埋黄土盾构隧道围岩结构性参数场的计算框架,结合结构性参数修正的黄土强度准则,给出深埋黄土盾构隧道围岩压力的计算方法。研究发现,使用形变压力理论计算黄土盾构隧道围岩荷载具有合理性;原状黄土相比重塑黄土有明显的应力峰值及应变软化现象;黄土应力结构性参数与粘聚力存在较好的拟合关系,与内摩擦角相关性低;当仅考虑地层浸水造成黄土结构性演变引起的围岩压力变化时,当含水率由1%增加到25%,塑性圈半径由4.6 m增加为5 m,围岩压力由587 kPa增加到622 kPa。

黄土盾构隧道开挖围岩扰动特性模型试验研究

为了探究不同含水率和埋深等工况下的黄土盾构隧道开挖对围岩的扰动作用特征,采用相似模型试验,首先通过三轴试验测定了不同含水率下原状黄土物理参数及强度指标,通过大量试配得到了不同含水率下与原状黄土强度指标参数相似的试验用土。其后,考虑盾构隧道盾尾间隙特征,开展不同含水率及埋深等组合工况下盾构开挖模拟试验,通过微型土压力传感器、百分表等监测元件以及数字图像技术等手段,分析了不同工况下地层变形、地表沉降和围岩应力的变化规律。研究发现:含水率较低时,围岩的自稳能力强;含水率越高,埋深越大,开挖对地层的扰动作用也越大;地表最大沉降值与含水率呈正相关,与埋深呈负相关;围岩剩余应力随含水率和埋深的增大而增大,但当含水率增大至一定值(26.6%)时,围岩剩余应力骤减;基于不同含水率下的围岩应力及变形发展规律,可将黄土含水率分为自稳、形变以及松动含水率,基于含水率和埋深引起的围岩松动情况,可将不同工况下的黄土盾构隧道围岩压力作用模式按照形变压力和松动压力计算,以更加适应黄土地层的特性。

穿越活动断裂带深埋隧道围岩地震响应分析

西南艰险山区道路和铁路隧道工程占比大,存在着埋深大、地质条件复杂、地震活动频发的特点,还存在隧道工程与活动断裂小角度穿越的工程问题,且近场地震对不同埋深的围岩影响不同,因而活动断裂近场地震对隧道工程顺利施工和安全运营存在显著不利影响。基于此,本文首先基于国内外发生的多次灾难性地震对隧道工程的影响,分析归纳了历史地震震级对穿越发震断裂隧道围岩(围岩埋深、岩性和级别)破坏的影响规律。其次,结合活动断层等特性,获取了能够反映区域断层特征和脉冲特性的地震动记录。最后,采用有限差分软件FLAC3D研究了活动断裂近场地震对深埋隧道工程围岩的影响规律。研究结果表明:隧道埋深的增加使得隧道围岩更加稳定,对于隧道围岩的塑性变形有抑制作用。不同地震动作用下的最大剪应力和最大主应力走势基本相同,断层段隧道围岩应力均大于普通围岩段。IV级及以下围岩在200 m埋深、PGA在0.3g以上时发生了较大的位移和应力响应。响应水平随着PGA的增大而增加,PGA从0.2g到0.39g的过程中有一个较大的增加,增幅接近50%,此过程是隧道产生塑性变形的主要过程,塑性区面积也随着PGA的增大而逐渐增大,因而在穿越活动断裂深埋隧道需认真考虑其近场地震的影响。研究成果可为隧道抗震优化设计提供技术支撑。

水平层状碳质页岩地层高速铁路大断面隧道基底变形机理研究

我国西部、西南部地区在建及建成的高速铁路隧道常发生仰拱隆起病害,严重威胁着隧道施工进度及运营安全。依托兴山东隧道典型的水平层状碳质页岩地层,开展仰拱基底隆起机理研究,对仰拱基底以下的围岩进行模型简化,应用构件试验定性分析、数值模拟定量计算的方法,揭示了不同层厚、层间黏聚力以及材料强度对层状岩体破坏模式的影响,分析导致水平层状围岩隧道底鼓的原因,并提出相应的底鼓控制处置技术。研究结果表明:(1)层厚的减小降低了层状复合岩体抵抗变形和破坏的能力,主要表现为弹性阶段的缩短和变形速率的加快;层间黏结强度的降低破坏了层状复合岩体的整体性,导致层状岩体加速进入单一岩层受力阶段,但对极限承载力劣化效应不明显;(2)岩体本身材料强度降低极大地降低了层状复合岩层的承载能力,使得破坏过程显著加快,影响程度和范围进一步加深,结合数值模拟结果进一步证明了岩体本身强度在层状岩体的变形和破坏当中占据主导位置;(3)列车振动的疲劳损伤、地下水聚集的弱化作用以及围岩的长期力学性能均将影响隧道仰拱的稳定性,变形控制效果排序为:加深仰拱>基底注浆>仰拱锚杆。

岩体变形及二次应力下矿体开采效应研究

为了解围岩在变形及二次应力下矿体开采效应的影响,本文选取-410 m中段采用现场试验与数值模拟相结合的方法对崩落法采矿进行矿体效应研究。结果表明:围岩应力发生震荡变化,在矿体上下盘围岩附近存在应力明显降低区域,下盘大于上盘,顶板最大主应力达0.44 MPa,局部呈现应力集中,且应力集中部位呈现类似水平零散分布的现象。同时开采边界呈现裂隙发育的状态。水平矿体有轻微下沉趋势,且在该中段的水平巷道边界和顶板裂隙附近易出现断层破碎带。竖直方向变形明显,且倾斜部位呈椭圆分布,最大下沉位移值达8.00 mm,最大上升方向变形值为3.03 mm,交界线附近易受到应力挤压现象。该研究对及时准确地掌握岩体变形规律和矿山安全信息使矿山安全有效合理地进行开采具有一定的指导意义。

土石交界地层隧道双侧壁导坑法施工围岩压力与变形研究

为探究土石交界地层双侧壁导坑法施工围岩变形与压力分布规律,通过现场监测对白塔山隧道围岩压力与收敛沉降变形进行研究分析。结果表明:下台阶施工易导致拱腰和拱脚围岩压力产生突变,最大增量可达70%,而对拱肩影响较小;相较于岩石地层,黄土层稳定性差,更易受隧道施工扰动影响导致围岩变形大、稳定距离长,黄土层稳定距离比岩石层长4~9 m;土石交界地层围岩压力呈现快速增加→缓慢增加→逐渐稳定的变化趋势,在快速增长阶段岩石层荷载释放率高达80%,大于黄土层荷载释放率;断面围压分布呈现出明显的不对称性,表现为“黄土侧大,岩石侧小”的分布规律。因此,双侧壁导坑法下穿土石交界地层时,建议在下台阶工序交替时保留部分土体进行反压控制,并提高下台阶锚杆布设密度,黄土层应做好超前支护预加固,并提高初期支护强度。

基于图像分析的TBM掘进参数与岩碴特征关系研究

岩碴图像分析是隧道掘进机(tunnelboringmechine,TBM)智能掘进中实时破岩效率评价和掘进参数优化的重要手段。为了研究掘进参数与岩碴图像特征的关系,依托青岛地铁6号线创石区间TBM施工段,在一段较完整花岗岩地层中开展了分步推力掘进试验,并通过搭载的岩碴图像分析系统对岩碴图像进行采集和分析。结果表明,岩碴图像的中位粒径d50、最大粒径dmax和粗糙度指数CI与推力、扭矩和贯入度之间均表现出正相关,与现场贯入指数FPI和工程比能SE之间均呈现出良好的负相关。当推力超过破岩临界值后,推力的提升将显著提高岩碴的d50和CI,而只有当推力进一步增大到一定水平后dmax才显著增大。此外,随着推力的提升,大岩片的二维形状逐渐呈现出长条形,其平均长短轴比也将增加,但是推力超过一定水平后,大岩片长短轴将保持不变。上述研究结果表明,岩碴粒径和形状参数均反映出破岩效率,可作为实时TBM掘进参数优化的评价指标。

深部巷道围岩分区破裂带理论及试验对比研究

深部岩体巷道围岩分区破裂化现象形成机制一直存在较大争议。本文从应力波传播的角度对此问题进行了理论探索。以半圆型巷道围岩为对象,建立了巷道围岩应力波传播物理模型。对围岩区域波动方程进行了求解,得到巷道围岩区域应力波幅值分布呈波动衰减变化特征,创新性地提出了巷道围岩分区破裂带宽度及理论深度。以丁集矿井为对象,对其围岩分区中心半径进行理论计算并与实测结果进行对比研究,大部分分区半径吻合度较好。本文的研究成果对巷道围岩分区破裂化理论有一定的推进作用。

基于损伤理论的深井巷道围岩松动圈计算方法

在岩体开挖过程中,岩体内部的许多微小裂隙会发生扩张或者闭合等变化,因此在计算巷道围岩应力场时,有必要考虑岩石材料的损伤特性。损伤理论考虑了岩石材料峰值后的软化特性,结合实际深井工程,验证了在深部巷道围岩松动圈计算中应用损伤理论的可行性和准确性。在围岩弹塑性理论基础上,着重推导了基于Sidoroff损伤模型的围岩应力状态的损伤理论解析解。利用基于Mohr-Coulomb准则的塑性理论以及分别基于Sidoroff损伤模型和双直线损伤模型的损伤理论,对巷道围岩松动圈厚度进行了计算。对比理论计算结果与现场测试数据,发现基于Mohr-Coulomb塑性理论的计算值误差约为19.77%,利用损伤理论得出的松动圈厚度误差仅为6.43%。验证了利用损伤理论对深部巷道软化岩石围岩松动圈厚度进行预测的可行性,且得到的松动圈厚度更接近现场实测值,具有重要的推广意义。

基于总安全系数法的宜兴高速铁路隧道支护参数优化与试验

隧道支护结构设计总安全系数法的应用,可实现隧道支护结构设计由类比设计向量化设计转变。依托宜兴高速铁路(宜昌—兴山)优化试验段,基于总安全系数法对隧道支护参数进行优化,结合现场测试将优化后支护参数的设计值和实测值进行对比。结果表明:与原设计方案相比,Ⅲ、Ⅳ、Ⅴ级围岩条件下,优化后支护参数的经济性指标最多可降低5.24%、23.85%、22.61%;Ⅲ、Ⅳ级围岩条件下,隧道施工进度指标最多可提高29.6%、40.0%。通过现场测试,围岩压力设计值均大于实测值,喷射混凝土层安全系数设计值均小于实测值。优化后支护参数均满足安全要求,总安全系数法可靠。

洛川隧道围岩变形规律模型试验研究

以洛川隧道DK194+835为研究断面,开展不同埋深下隧道模型试验研究。通过各种试验确定原型、相似材料土和衬砌的参数,利用3D打印技术研制出一套新型衬砌材料及连接方式较好的模拟了实际工程中喷射混凝土、钢架、超前小导管。利用自制多点位移计等各种监测原件采集开挖过程中围岩内部变形及地表沉降数据。试验表明:可通过拼装的方式在模型试验中模拟隧道的分布支护,可使用滑动式连接件链接相邻位置的石膏块;不同测点竖向位移均经历缓慢增长(开挖面远离监测断面)、迅速增长(开挖面接近监测断面)、逐步稳定(开挖面经过监测断面)3个阶段。随埋深增加,监测断面前期变形(开挖面远离、接近监测断面)占比减小;地表沉降经历缓慢增长、迅速增长、逐步稳定3个阶段。随埋深增加,监测断面前期地表沉降占比减小。

寒区隧道衬砌渗水挂冰试验研究

为揭示寒区隧道衬砌渗水挂冰发育规律,研制出一套模拟地表水补给条件下寒区隧道衬砌渗水挂冰发育的模型试验装置,实时监测渗水断面围岩温度和挂冰发育过程;采用Image-J软件测量挂冰图像截面积和线性回归分析方法分析挂冰发育过程,研究不同风速和围岩初始温度条件下渗水点围岩温度和挂冰堵塞率演变规律。结果表明:1)挂冰开始发育时刻,随着风速的增大和围岩初始温度的升高,渗水点围岩临界温度逐渐升高;渗水点围岩温度随冷却时间逐渐降低,近似呈对数函数关系;风速越小、围岩初始温度越高,平均降温速率越慢,挂冰发育持续时间越长;当风速分别为0.6 m/s和1.2 m/s时,由于渗水断面围岩冻结圈的形成和衬砌内壁冰体封堵渗水点导致衬砌挂冰停止发育。2)挂冰堵塞率与时间近似呈线性关系,风速越小、围岩初始温度越高,挂冰开始发育的时间越晚,冻害严重程度越高,而紧急程度越低。

双洞八车道特大跨度隧道Ⅴ级石质围岩开挖工法

为减小双洞八车道特大跨度隧道洞口Ⅴ级石质围岩后行导坑爆破对已完成支护结构的不利影响,该文以平潭牛寨山隧道工程为例,针对原设计双侧壁导坑法在后行的临近导坑爆破时,易将原先已施工完成的临时钢支撑震塌,提出取消临时横向支撑的变更方案1,以及带竖向支撑的上下台阶法(变更方案2),再利用有限元法计算,模拟3种不同开挖工法对隧道变形及受力的影响。计算结果表明:3种方案引起的拱顶沉降相差较小,最大相差约11.8%;变更方案2引起的围岩应力最大,但变更方案2同时取消了左右侧壁导坑的横向支撑以及左右侧壁导坑下台阶的竖向支撑,大大简化了施工工序。最后,结合监测数据进行分析,隧道结构安全稳定,变更方案2不仅合理可靠,而且加快了施工进度,节约了造价。

Impact and explosion resistance of NPR anchor cable:Field test and numerical simulation

With the reduction of shallow resources,the degree of damage and the frequency of dynamic hazards,such as deep rock bursts and impact ground pressure,are increasing dramatically.However,the existing support materials are incapable of meeting the safety require-ments of the refuges and roadways under a strong impact force.To effectively solve these problems,a novel negative Poisson’s ratio(NPR)anchor cable with excellent properties,such as impact resistance and the ability to withstand large deformation,is proposed.In the present study,a series of field tests and numerical simulations are conducted to investigate the mechanical and support charac-teristics of NPR anchor cables under blast impact.Laboratory mechanical tests show that NPR anchor cables can maintain constant resistance and produce large deformation under the action of multiple drop hammer impacts.According to the results of field tests,the roadway supported by conventional anchor cables was unable to endure the blast impact,while the roadway supported by NPR anchor cables was able to withstand the severe impact equivalent to a Class 3 mine earthquake.The dynamic response of the NPR anchor cable that supports the roadway under explosion is investigated using the innovative coupled modeling approach that combines the finite element method and the discrete element method,and the support effect of the NPR anchor cable is verified.The study shows that the NPR anchor cable has a superior impact and blast resistance performance,and a broad application prospect in the support of chambers and roadways that are at high risk of rock bursts and impact ground pressure.

鑫顺煤业迎采强扰动巷道围岩稳定性控制研究

为解决迎采对掘沿空掘巷过程中巷道围岩变形严重、支护困难等问题,以山西煤炭进出口集团左权鑫顺煤业某一轨道顺槽为研究对象,采用钻孔窥视和数值模拟等方法,研究了迎采对掘迎采强扰动巷道围岩稳定性控制的问题,确定巷道的支护方案为锚杆+锚索+锚网以及W型钢带等相互配合的联合支护方法。现场应用后对围岩变形进行监测,结果表明该支护措施有效抑制了围岩变形,达到了很好的支护效果。