深部节理岩体塑性损伤耦合微面模型

采用微面模型理论和损伤力学方法,建立了节理岩体的弹塑性损伤耦合微面模型. 在节理岩体的微面上,将岩体视为由节理面与岩石组成的二元介质,以节理连通率作为岩体沿该方向的面积损伤变量,考虑微面法向拉应力和压应力下的不同塑性变形和损伤耦合作用机制,基于塑性理论建立了节理岩体的微面塑性损伤增量本构关系. 采用微面物理量与宏观物理量的几何约束模型,根据微面方向积分导出了节理岩体的宏观弹塑性增量本构关系. 编制了节理岩体微面模型的MARC有限元子程序,对节理岩体的单轴拉伸、压缩试验和泥浆压力作用下的井壁稳定问题进行了数值模拟研究. 数值计算结果表明,该模型能很好地揭示载荷作用下节理岩体的各向异性非弹性变形和次生节理演化过程.      

不同围压下含天然贯通节理岩石卸载破坏机理研究

二郎山特长高速公路隧道断裂带较多,受此影响,隧道开挖后岩爆灾害十分严重．从此隧道中取样制备成含天然贯通节理试件,进行常规单轴压缩室内试验,获取基本力学参数和破坏模式．本文以室内实验结果为依据,确定数值试验时所采用的岩石和节理的力学参数,利用RFPA软件开展数值试验,研究了不同围压同轴向荷载下卸掉围压诱发岩石失稳破坏机理．试验结果表明,五种不同围压(5、10、15、20、25 MPa)卸载后应力-应变曲线均呈“断崖式”跌落,试样均突然破坏,与现场岩爆情况吻合;受贯通节理影响,不同围压试样的具体破坏形态、声发射数量最大值出现时刻有所差异;在卸载阶段五种试样声发射累积数量都突然急剧增大．     

金华山软岩铁路隧道施工过程围岩屈服接近度分析

隧道施工过程中围岩处于复杂应力状态下,隧道围岩屈服区演化特征的确定对于围岩稳定性分析和开挖支护方案优化具有重要的意义。采用屈服接近度指标衡量围岩破坏接近程度可以合理地描述复杂应力状态下围岩的应力危险性,对Mohr-Coulomb类岩体材料的屈服接近度函数进行了相应的推导,并在非线性有限元用户子程序上编程予以实现。介绍了赣州-龙岩铁路DKl33+095～DKl38+237段软弱围岩单线隧道正台阶步施工方案以及湿喷纤维混凝土支护方案。为了对该隧道施工过程中隧道围岩屈服区的演化特征进行合理评价,采用非线性有限元法对软弱围岩条件下的铁路隧道施工过程进行了数值模拟,分析了施工过程中隧道围岩屈服接近度分布特征,判定了隧道台阶步施工过程中隧道围岩的稳定性。分析结果表明:该隧道施工过程中围岩破坏区主要发生在下台阶步施工过程中;屈服接近度指标比传统的塑性区分布提供的信息更加丰富,有利于工程技术人员定量地评价隧道开挖支护方案。     

共面闭合断续节理岩体直剪强度特性研究

介绍了节理面和岩桥各自的抗剪强度机制,引入法向变形协调条件,基于Mohr-Coulomb理论,推导了共面闭合断续节理岩体的直剪强度公式。模型试验发现,剪切破坏面以拉剪复合破坏为主,同时岩块中伴随大量的拉张微裂隙。试样的强度和变形具有明显的阶段性,全应力应变曲线主要经历了线弹性增长、节理面错动、次生裂纹起裂稳态扩展、节理面贯通破坏和残余强度5个阶段。对比发现,理论计算结果与试验值吻合较好。     

Comportement élastoplastique homogeneisé d'un milieu rocheux fracture

The overall behaviour of a periodic medium made up of a rock matrix crossed by one or several networks of plane parallel joints is examined from a micromechanical point of view. It is assumed that the rock matrix as well as the joints exhibit a perfect plastic behaviour. The localization within the elementary cell is shown to be of the Reuss type, the microscopic stress field being uniform. The macroscopic behaviour is therefore perfectly plastic. The macroscopic elastic stiffness, possibly nonlinear, is derived from those of the joints and matrix. The macroscopic yield criterion is obtained from the intersection of the matrix and joint criteria. If the normality rule is valid for the constituants, it applies at the macroscopic scale as well.     

An empirical statistical constitutive relationship for rock joint shearing considering scale effect

The scale effect of rock joint shearing is of great significance in rock engineering. Most existing shear constitutive models could describe the pre- and post-peak deformation of rock joints, but only in one particular scale, that is, those existing models will fail to depict the rock joint shearing in different length scales. Therefore, this study aims to establish a constitutive relationship for rock joints with considering the scale effect. Based on the assumption of a random statistical distribution of rock material strength and statistical mesoscopic damage theory, damage variables are defined as the ratio of the number of damaged elements to the total number in the shear process. Together with the nonlinear relationship between the microelement failure and the joint scale, an empirical statistical constitutive relationship for joint is established. And then, the determination method of constitutive relationship parameters and the variation laws with the scale are discussed. Results show that the predicted results of the proposed empirical relationship not only agree well with the experimental results but also fully describe nonlinear deformation, pre-peak softening, post-peak softening, residual stage, and other mechanical properties of the shear deformation of joint with different dimensions, thereby demonstrating the rationality of the constitutive relationship. The physical meaning of the constitutive relationship parameters is clear, and the expressions of the constitutive relationship parameters can be deduced from the experimental results. In addition, the influence of scale effect on the shear deformation of rock joints can be quantified using parameters, which help accurately describe the action form of scale effect.     

高静水压力下Mohr–Coulomb准则的拓展研究

深部开采时极端环境下的岩体高应力和高地压是影响工程安全的主要因素。本文指出了Mohr–Coulomb准则（简称M–C准则）在高静水压力下无法判断岩石材料发生屈服破坏的问题,开展了岩样在高应力下的三轴压缩实验,观察了高静水压力下岩石材料的破坏现象,推导了高静水压力条件下M–C准则的拓展方程。研究结果显示,与现有M–C准则不同的是,材料剪切强度随轴压和围压之差增大到某一峰值时将逐渐减小,岩样在高静水压力下也可发生屈服破坏,M–C准则拓展方程与实验结果基本吻合。同时,本文探讨了低静水压力下M–C屈服面的下限和高静水压力下M–C屈服面的上限。研究成果可为深部工程的安全高效开展提供理论参考。

     

Modeling rock failure using the numerical manifold method followed by the discontinuous deformation analysis

A complete rock failure process usually involvesopening/sliding of preexisting discontinuities as well as fracturing in intact rock bridges to form persistent failure surfaces and subsequent motions of the generated rock blocksThe recently developed numerical manifold method(NMM)has potential for modelling such a complete failure processHowever,the NMM suffers one limitation,i.e.,unexpectedmaterial domain area change occurs in rotation modellingThis problem can not be easily solved because the rigidbody rotation is not represented explicitly in the NMM.Thediscontinuous deformation analysis(DDA) is specially developed for modelling discrete block systems.The rotationinduced material area change in the DDA modelling canbe avoided conveniently because the rigid body rotation isrepresented in an explicit form.In this paper,a transitiontechnique is proposed and implemented to convert a NMMmodelling to a DDA modelling so as to simulate a completerock failure process entirely by means of the two methods,in which the NMM is adopted to model the early fracturingas well as the transition from continua to discontinua,whilethe DDA is adopted to model the subsequent motion of thegenerated rock blocks.Such a numerical approach also improves the simulation efficiency greatly as compared with acomplete NMM modelling approach.The fracturing of arock slab with pre-existing non-persistent joints located ona slope crest and the induced rockfall process are simulated.The validity of the modelling transition from the NMM tothe DDA is verified and the applicability of the proposed numerical approach is investigated.     

非充填岩石节理的动态剪切力学行为实验研究进展

岩石节理的动态剪切力学特性是岩体力学的基本问题之一,在地震工程、采矿工程、隧道工程等诸多领域有广泛应用。获取准确的岩石节理动态剪切力学参数是认识节理剪切力学行为的基础,国内外学者经过持续探索,研发了一系列动态剪切实验设备,形成了以传统定速直剪和循环剪切为主的实验技术体系。近几年发展的冲击直剪实验技术使这一体系更加完善。本文针对非充填岩石节理的动态剪切力学特性室内实验研究,首先系统阐述了相关实验技术的特点及其发展,然后总结了岩石节理动态剪切强度和变形特征的研究成果,最后提出值得进一步探索的问题。

     

花岗岩破坏过程能量演化机制与能量屈服准则

为了明确岩石破坏的能量演化特性，结合单轴实验和颗粒流程序获得花岗岩的细观力学参数，进行不同应力状态的花岗岩实验，研究不同围压下花岗岩破坏过程的能量演化机理并推导能量屈服准则。获得以下主要结论:花岗岩破坏过程中低围压下内部损伤出现较早而高围压较晚，表明低围压花岗岩内部损伤是渐进发展过程，而高围压下内部损伤一旦出现便快速发展破坏；高围压花岗岩峰值前一定应变范围弹性应变能基本保持不变，吸收的能量全部转化为耗散能，表明高围压破坏时花岗岩内部损伤程度严重；弹性应变能经历不断积累并达到弹性储能极限而后减小的变化过程，而弹性储能极限与围压之间存在线性变化规律，因此高围压下岩体开挖卸荷时极易诱发大量弹性应变能的急剧释放，引起围岩失稳甚至发生岩爆；花岗岩峰值破坏时的能量比与围压无关，为一定值；基于能量原理导出了能量屈服准则，该准则包含岩性参数和所有主应力，能够综合反映岩石破坏影响因素。     

Loading rate and confining pressure effect on dilatancy,acoustic emission,and failure characteristics of fissured rock with two pre-existing flaws

Investigating the dilatancy, acoustic emission and failure characteristics of fissured rock are significant to ensure their geotechnical stability. In this paper, the uniaxial and triaxial compression experiments with AE monitoring under different loading rates were carried out on fissured rock specimens with the same geometrical distribution of two pre-existing flaws. The dilatancy and AE activity of these specimens were discussed, and the effects of the confining pressure and loading rate on the mechanical parameters and failure characteristics were analyzed. The results show that the exponential strength criterion is more suitable than the Mohr–Coulomb strength criterion to characterize the strength characteristics of fissured rock. The crack evolution and failure characteristics of fissured rock specimens are more complicated than those of intact rock specimens. The failure characteristics of the fissured rock follow the tensile shear coalescence model, crack branching occurs with increasing the loading rate, and the multi-section coalescence model is verified with increasing the confining pressure. The phenomena of stress drop and yield platform usually occur after the dilatancy onset, the specimen does not fail instantaneously, and the propagation and coalescence of cracks cause a sharp increase in the AE signals, circumferential strain, and volumetric strain.     

Experimental investigation of jointed rock breaking under a disc cutter with different confining stresses

Extensive and detailed investigations have been made to better understand the rock-breaking mechanism of the tunnel boring machine (TBM) disc cutter, but the crack propagation and failure modes induced by the disc cutter when the confining stresses and joint characteristics vary have not been comprehensively investigated. To address this area of research, a triaxial testing machine (TRW-3000) is modified to investigate the effect of different confining stresses (0, 2.5, 5, 7.5 and 10 MPa) on the rock breaking of different joint angles (0°, 30°, 60°, and 90°) induced by the disc cutter. In this series of tests, the crack propagation and failure modes of the intact and jointed rock with different confining stresses are analysed. During the experiments, four different types of failure modes have been observed. The failure mode is affected by the joint orientation at low confining stress. The existence of joints has no obvious effect on the failure mode when the confining stress increases to a certain extent.     

Yield surfaces of various periodic metal honeycombs at intermediate relative density

Initial yield surfaces are derived for several periodic metal honeycomb cell structures with sufficiently high relative density that failure occurs by plastic yielding. Both in-plane stress states (normal stresses perpendicular to cell axes, with in-plane shear) and triaxial stress states with one principal stress direction along the cell axes are considered. Beam/column and plate/shell yield criteria are adopted to address general in-plane loading and 3D triaxial loading, respectively, accounting for combined cell wall stretching and bending as appropriate. Cell wall behavior is assumed to be elastic-perfectly plastic. The initial yield surfaces for different periodic cell structures are systematically compared. Some issues related to the initial yield surfaces of various honeycombs are discussed, including dependencies on relative density and in-plane and out-of-plane applied stresses, as well as the influence of joints between cell walls.     

DAMAGE MODEL FOR HARDENING AND SOFTENING MATERIAL IN GENERAL STATE OF STRESS

The present paper is aimed to simulate progression of damage,hardeningand softening response in brittle materials such as concrete or rock in general state ofstress.Similar shape of surfaces for yield,failure and damage progressing areavailable,and softening strain is treated as plasticity.Then,the proposed model isapplied to solving several boundary value problems.     

DEM analysis of the effect of joint geometry on the shear behavior of rocks

In order to comprehensively investigate the effect of different joint geometries on the shear behavior of rocks, the Distinct Element Method (DEM) was utilized with a new bond contact model. A series of direct shear tests on coplanar and non-coplanar jointed rocks was simulated using the PFC2D software, which incorporates our bond contact model. Both coplanar jointed rocks with different joint persistence and non-coplanar ones with different joint inclinations were simulated and investigated numerically. The numerical results were compared and discussed with relevant laboratory tests as well as some reported numerical works. The results show that for coplanar jointed rocks, the peak shear stress decreases nonlinearly with the joint persistence, and the failure process can be divided into four stages: elastic shearing phase, crack propagation, failure of rock bridges, and residual phase. For non-coplanar jointed rocks, as the absolute value of the inclination angle of the rock joints increases, its shear strength increases, changing the failure patterns and the length of new fractures between existing cracks. When the absolute value increases from 15° to 30°, the average shear capacity increases the most as 39%, while the shear capacity increases the least as 2.9% when the absolute value changes from 45° to 60°. There is a good consistency of the failure patterns obtained from experiments and numerical tests. All these demonstrate that the DEM can be further applied to rock mechanics and practical rock engineering with confidence in the future.     

STRENGTH PROPERTIES OF JOINTED ROCK MASSES BASED ON THE HOMOGENIZATION METHOD

This paper aims to determine the strength properties of jointed rock masses by means of the homogenization method.To reflect the microstructure of jointed rock masses,a representative element volume (R...     

岩体风化的综合分带研究

岩体的风化不仅会引起岩石物质成份、化学成份变化 ,而且也引起岩体裂隙、岩体完整性的改变。因而风化岩体中裂隙数量、岩体块度的变化与岩体的风化程度具有较好的对应关系。论文研究了用岩体裂隙间距、岩体的完整性指标、岩石质量指标对岩体风化程度进行分带 ,较好地将岩体风化分带与岩体结构、岩体工程特性紧密地结合起来。在岩体风化程度的定量划分上作了新的探索。     

A dynamic damage constitutive model for a rock mass with non-persistent joints under uniaxial compression

Most problems faced by the practicing rock mass engineering involve the evaluation of rock mass dynamic strength and deformability. As part of a rock mass, the mesoscopic flaws such as the microcracks and the macroscopic ones such as the joints both inherently affect the rock mass dynamic strength and deformational behavior. Nearly none of the existing models can handle the co-effect of these two kinds of flaws on the rock mass dynamic mechanical behavior. This study focusses on the rock mass with multi-sets of non-persistent joints and establishes a mathematical model accounting for the anisotropy in dynamic strength and deformability induced by the joints. Accordingly, an approach incorporating the existing models or methods to enable perfect simulation of the dynamic stress-strain relationship of a rock mass is proposed, in which the joint geometrical parameters such as the joint length and dip angle, the strength ones such as the joint internal friction and the deformational ones such as the joint normal and shear stiffness can all be taken into account. In order to investigate the validity of the proposed model, a series of calculation examples have been made and the results fits very well with the theoretical ones.     

高层建筑结构边节点抗震性能研究

通过7根留有施工缝的高层建筑结构边节点的低周反复抗震性能试验,研究了轴压比、节点核心区的混凝土强度等级、柱中混凝土在梁中的延伸长度等对梁柱边节点抗震性能的影响,对构件的破坏特征、承载能力、延性性能、滞回曲线和骨架曲线进行了对比分析。试验结果表明:所有试验构件均为梁端受弯破坏;柱中混凝土在梁中的延伸长度对骨架曲线的形态、屈服荷载和最大荷载都没有显著影响;但是延伸长度对节点的延性性能是有影响的,延伸长度为0.5h(h为梁高)的边节点构件的位移延性系数小于延伸长度为1.0h和1.5h的构件。     

岩石分形节理粗糙性对应力场影响的光弹模拟研究

节理的粗糙性是影响岩体力学特性的重要因素。现有的众多的研究结果表明：不规则的节理面具有很好的自相似特征，可以用分形几何去描述，节理面的分形维数是表征节理面粗糙度（ＪＲＣ）恰当的统计量。基于以上观点，为了能够精确地控制节理面的粗糙性，本文以Ｍａｎｄｅｌｂｒｏｔｗｅｉｅｒｓｔｒａｓｓ函数生成不同分维的分形曲线来模拟实际的粗糙节理面，制成光弹实验试样进行多组的单压和压剪实验，通过光弹条纹和接触点的变化来研究不规则的节理对于岩体变形，应力场的影响，得出了一些有益的结论．