砂卵石地层土压盾构掘进掌子面稳定性室内试验与三维离散元仿真研究

采用Φ800 mm模型土压盾构开展室内掘进试验,以探究砂卵石中土压盾构隧道掌子面失稳诱发地层变形特征。同时,补充开展三维离散元仿真以挖掘室内试验难以获取的掌子面失稳信息,并研究隧道埋深对掌子面稳定性的影响规律。研究结果表明:砂卵石地层中盾构隧道掌子面失稳发展到地表后,沉降曲面呈上大下小逐步收缩的沙漏状,影响范围小于砂土地层。考虑盾构动态掘进过程后,卵石颗粒接触关系变化十分剧烈,掌子面稳定性被削弱,极限支护压力随之增大。掌子面极限支护压力随隧道埋深基本呈线性增加,极限支护压力与初始支护压力之比则随埋深增大而减小。掌子面失稳机制可根据隧道埋深划分为3种模式。与既有研究相比,考虑了盾构动态掘进过程与实际工程更加接近,可为确保砂卵石地层土压盾构隧道施工掌子面稳定提供参考。

层状围岩管片衬砌配合陶粒与锚杆的联合支护技术研究

深部层状围岩中修建盾构隧道,管片衬砌易受偏压作用,对结构安全构成挑战。提出一种管片衬砌配合陶粒可压缩层与锚杆的联合支护技术,采用大比例尺相似模型试验针对联合支护技术的支护效果进行研究,进行了可压缩层配合不同长度和间距的锚杆支护效果对比研究,从管片衬砌内力、变形角度分析了联合支护效果,从可压缩层的压缩变形路径和移动特征角度分析了联合支护机理。研究结构表明：联合支护技术一定程度上改变了管片的内力分布形式,降低了围岩偏压作用,削减管片衬砌内力和形变量;锚杆的施作可以有效减小层状围岩变形,陶粒压缩层可以有效吸收围岩变形;联合支护中锚杆的长度和间距存在一个最优值,超过该最优值,锚杆的加固效果不再明显增加;联合支护的作用机理由两部分构成：陶粒压缩层的让压作用与锚杆加固作用。研究结果对层状围岩中修建盾构隧道的支护结构型式设计具有一定参考价值。

层状围岩中管片衬砌受力特征的模型试验研究

深部层状围岩结构强度具有各向异性特点,此类地层中修建盾构隧道,管片衬砌易受偏压作用,对结构安全构成挑战。开展层状围岩与盾构管片衬砌相互作用关系的相似模型试验研究,研究不同层理倾角下管片衬砌壁后围岩压力、管片衬砌内力和变形分布规律。研究结构表明：管片衬砌受力和变形特征受层理面控制明显,管片衬砌受力极不均匀,弯矩、轴力和变形呈现非对称分布;管片衬砌壁后围岩压力最大值集中在强度最弱的层理面法线方向,该方向上管片衬砌的弯矩最大,轴力最小,变形最大;层理倾角对管片衬砌的受力和变形影响显著,层理倾角不仅影响管片衬砌壁后围岩压力分布形状还影响其量值大小;均质地层中,管片衬砌裂缝主要出在封顶块接头处和其他环向接头处,层状地层中管片衬砌裂缝出现位置受接头位置影响减弱,而受层理倾角影响明显,管片衬砌裂缝出现位置主要集中在层理面法向。研究结果对层状围岩中修建盾构隧道的支护结构型式设计具有一定参考价值。

考虑围岩蠕变特性的TBM隧道管片衬砌受力特性研究

为研究深部高地应力岩层中修建TBM隧道时管片衬砌结构的力学行为,以某深埋TBM工法隧道为研究对象,建立基于围岩蠕变和管片分块效应的衬砌-围岩复合模型,研究考虑时间效应下管片衬砌的受力特性。结果表明:考虑围岩蠕变效应下管片衬砌受力表现出明显的时间效应。随着围岩蠕变时间的延长,管片衬砌的形变、内力和接缝张开量均呈现两阶段增长,具体表现为前期呈线性增长,后期增加趋缓。洞周围岩应力经历三阶段变化,即先减小后增大直至稳定。围岩蠕变时间为100年时,管片衬砌的内力和形变量均接近极限值。研究结果可为深部高地应力且考虑围岩蠕变效应下的TBM隧道衬砌结构设计提供参考。

Effect of stress paths on failure mechanism and progressive damage of hard-brittle rock

During deep buried hard-brittle rock tunnel excavation,the surrounding rock experiences a complicated stress path and stress adjustment process.Once the adjusted stress exceeds the ultimate bearing capacity of rockmass,a rock failure mode defined as stress-cracking type will occur.In order to investigate the effect of stress paths on failure mechanism and progressive damage of deep-buried rockmass,the cyclic loading-unloading,loading-unloading,uniaxial,conventional and unloading triaxial compression tests on samples of hard-brittle sandstone were conducted.According to the experimental results,increase in the confining pressure was beneficial to improve the mechanical parameters of rock,but it will reduce the brittle failure features.Compared with conventional triaxial compression,the sandstone under unloading state had more remarkable stress drop and unstable failure characteristics.Meanwhile,it was found that the energy dissipation and energy release in the whole process of rock deformation were the internal power of driven rock progressive damage.With the increase of confining pressure,the energy hardening and energy accumulation features of rock were weakened,while the progressive damage evolution characteristics could be enhanced.In unloading state,more energy could be converted into elastic energy in the energy softening phase(σeb-σP),so that the prepeak damage rate of rock was lower than that of conventional triaxial compression state.Thus,the energy dissipation rate of rock after peak strength decreased linearly with the increase of confining pressure under conventional triaxial compression state,while in unloading state it showed the opposite law.