岩土中的剪切带局部化问题研究:回顾与展望

回顾了圆弧滑动面理论的产生及其在土坡抗滑动稳定分析和极限承载力计算中的应用，并指出了圆弧滑动面理论和刚塑性理论及极限平衡条件的关系及其局限性。介绍了剪切带局部化问题的研究现状，包括一些热点研究领域和最新研究成果。着重介绍了用子负荷面模型模拟超固结黏性土剪切带局部化和用动态剪切带单元模拟摩尔一库仑材料剪切带局部化的最新研究成果。对剪切带局部化问题研究提出了几个主要发展方向。     

梯度塑性的有限元分析及应变局部化模拟

对梯度塑性连续体提出了一个有限元方法．内状态变量的Ｌａｐｌａｃｉａｎ的确定基于它在求积点邻域的最小二乘方多项式近似．具体地考虑了具有一点求积和Ｈｏｕｒｇｌａｓｓ控制特点的基于胡海昌－Ｗａｓｈｉｚｕ变分原理的混合应变元和单元平均意义下的ｖｏｎ－Ｍｉｓｅｓ屈服准则．解析地导出了梯度塑性下一致性单元切线刚度矩阵和速率本构方程的一致性积分算法．在所建议的非局部化途径中求积点的一致性条件在非局部化意义下逐点精确满足．数值例题表明所提出的非经典连续体的有限元方法求解应变局部化问题的有效性     

绝热剪切研究的意义和现状

简述了绝热剪切现象及其涉及的领域，指出了绝热剪切研究的意义和它重要的工程应用价值，对绝热剪切研究物现状作了扼要的总结。     

边坡稳定性评价结果的表达与边坡稳定判据

本文比较全面系统地总结分析了目前边坡工程中常用的各种稳定性评价结果的表达方式, 即各种边坡稳定判据。它们主要包括：(1)安全系数；(2)可靠度或破坏概率；(3)边坡岩体的位移、应力、位移速度等；(4)定性经验结论；(5)干扰能量；(6)声发射率等六种。在此基础上, 本文分析了各种判据的特点及其适用条件等。     

块体金属玻璃的剪切带行为

0 引言玻璃态物质以纷繁多样的形式广泛存在于自然与科技技术领域[1-3].除了人们熟知的门窗上的硅酸盐无机玻璃、各种塑料制品的高聚物玻璃外,玻璃态还与光纤通讯、生物制品和生化药剂的保鲜存储、极端干燥条件下昆虫活性的保持等这些鲜为人知的方面密切相关.     

非晶合金剪切带动力学行为研究

剪切带是一种材料塑性变形高度局域化的变形模式,广泛存在于非晶体系的形变中,控制着这些无序体系失稳、灾难性断裂行为.传统的非晶体系如岩石,胶体,玻璃和聚合物等因较差的力学性能以及过于复杂的结构而不利于剪切带的实验研究.近几十年来,非晶合金的出现极大丰富了剪切带的研究,推进了对剪切带的认识.通过大量非晶合金中剪切带的实验和理论研究,人们发现剪切带行为具有空间不均匀性和时间不连续性的特征,表现出复杂的动力学特征,和自然界以及物理系统中许多复杂体系的动力学行为相似.同时,剪切带的性质尤其是其动力学行为对非晶合金的宏观力学行为和性能有重要的影响,对理解这类材料的微观变形机理也起着重要的作用.本文结合团队近年来在非晶合金剪切带行为方面的研究结果,对剪切带的运动行为和物理机制进行介绍,包剪切带间歇性运动行为、以及间歇性运动在表征其动力学性质中的作用以及物理机制,以及剪切带的自组织临界行为、物理机制等.最后对非晶合金剪切带行为研究中亟需解决的问题进行了总结和展望.     

梯度塑性的有限元分析及应变局部化模拟

对梯度塑性连续体提出了一个有限元方法．内状态变量的Ｌａｐｌａｃｉａｎ的确定基于它在求积点邻域的最小二乘方多项式近似．具体地考虑了具有一点求积和Ｈｏｕｒｇｌａｓｓ控制特点的基于胡海昌－Ｗａｓｈｉｚｕ变分原理的混合应变元和单元平均意义下的ｖｏｎ－Ｍｉｓｅｓ屈服准则．解析地导出了梯度塑性下一致性单元切线刚度矩阵和速率本构方程的一致性积分算法．在所建议的非局部化途径中求积点的一致性条件在非局部化意义下逐点精确满足．数值例题表明所提出的非经典连续体的有限元方法求解应变局部化问题的有效性     

非晶合金剪切带动力学行为研究

剪切带是一种材料塑性变形高度局域化的变形模式,广泛存在于非晶体系的形变中,控制着这些无序体系失稳、灾难性断裂行为.传统的非晶体系如岩石,胶体,玻璃和聚合物等因较差的力学性能以及过于复杂的结构而不利于剪切带的实验研究.近几十年来,非晶合金的出现极大丰富了剪切带的研究,推进了对剪切带的认识.通过大量非晶合金中剪切带的实验和理论研究,人们发现剪切带行为具有空间不均匀性和时间不连续性的特征,表现出复杂的动力学特征,和自然界以及物理系统中许多复杂体系的动力学行为相似.同时,剪切带的性质尤其是其动力学行为对非晶合金的宏观力学行为和性能有重要的影响,对理解这类材料的微观变形机理也起着重要的作用.本文结合团队近年来在非晶合金剪切带行为方面的研究结果,对剪切带的运动行为和物理机制进行介绍,包剪切带间歇性运动行为、以及间歇性运动在表征其动力学性质中的作用以及物理机制,以及剪切带的自组织临界行为、物理机制等.最后对非晶合金剪切带行为研究中亟需解决的问题进行了总结和展望.     

30CrNi3MoV钢热塑剪切带内的应变和应变速率

本文提出了３０ＣｒＮｉ３ＭｏＶ低合金钢正交切削的试验结果和计算规则，锯齿状切屑上热塑剪切带内的应变和应变速率的模型及计算公式。计算结果表明正交切削试验中出现的热塑剪切带的切应变可达２０００％应变速率高达１０￣５ｓ￣（－１）。     

表面加工塑性层对金属柱壳剪切带自组织单旋起始的影响

在外爆加载金属柱壳高速坍塌过程中, 发生塑性变形失稳形成的剪切带具有高度的自组织特征, 甚至出现剪切带排列的单旋现象—剪切带在顺时针和逆时针两个方向呈现一个方向占优的现象. 柱壳在坍塌时, 最大剪切应力位于柱壳内表面, 剪切带的形核及扩展行为受内表面材料介观状态的影响显著. 本文通过选材和控制柱壳加工工艺, 获得了内表面具有不同厚度塑性层的20钢柱壳, 采用厚壁圆筒实验技术, 研究了表面加工塑性层对金属柱壳绝热剪切带自组织单旋现象起始的影响规律及其物理机制. 研究结果表明, 金属柱壳内表面加工塑性层显著改变了试样剪切带的起始条件, 沿顺时针或逆时针方向排列的剪切带形核数量在总剪切带数量中所占比例取决于表面加工塑性层的厚度和晶粒取向, 具有单一晶粒拉伸方向的较厚塑性层样品更容易形成单向螺旋剪切带结构. 在相同变形条件下, 随着塑性层厚度增加, 剪切带平均形核速率和扩展速率增大, 剪切带平均间距减小. 结果可为理解金属柱壳在高速塌陷过程中绝热剪切带占优取向现象提供有价值的参考.      

On criteria for dynamic adiabatic shear band propagation

In this work, we postulate the physical criterion for dynamic shear band propagation, and based on this assumption, we implement a numerical algorithm and a computation criterion to simulate initiation and propagation of dynamic adiabatic shear bands (ASBs). The physical criterion is based on the hypothesis that material inside the shear band region undergoes a dynamic recrystallization process during deformation under high temperature and high strain-rate conditions. In addition to providing a new perspective to the physics of the adiabatic shearbanding process and identifying material properties that play a crucial role in defining the material's susceptibility to ASBs, the proposed criterion is instrumental in numerical simulations of the propagation of ASBs when multi-physics models are adopted to describe and predict the complex constitutive behavior of ASBs in ductile materials. Systematic and large scale meshfree simulations have been conducted to test and validate the proposed criterion by examining the formation, propagation, and post-bifurcation behaviors of ASBs in two materials, 4340 steel and OFHC copper. The effects of heat conduction, in particular the length scale introduced by heat conduction, are also studied. The results of the numerical simulations are compared with experimental observations and a close agreement is found for various characteristic features of ASBs, such as the shear band width, speed of propagation, and maximum temperature.     

Adiabatic shear band localization of inelastic single crystals in symmetric double-slip process

Summary The main objective of the present paper is the development of a viscoplastic regularization procedure valid for an adiabatic dynamic process for multi-slips of single crystals. The next objective is to focus attention on the investigation of instability criteria, and particularly on shear band localization conditions.To achieve this aim, an analysis of acceleration waves is given, and advantage is taken of the notion of the instantaneous adiabatic acoustic tensor. If zero is an eigenvalue of the acoustic tensor, then the associated discontinuity does not propagate, and one speaks of a stationary discontinuity. This situation is referred to as the strain localization condition, and corresponds to a loss of hyperbolicity of the dynamical equations. It has been proved that for an, adiabatic process of rate-dependent (elastic-viscoplastic) crystal, the wave speed of discontinuity surface always remains real and different from zero. It means that for this case the initial-value problem is well-posed. However, for an adiabatic process of rate-independent(elastic-plastic) crystal, the wave speed of discontinuity surface can be equal zero. Then the necessary condition for a localized plastic deformation along the shear band to be formed is as follows: the determinant of the instantaneous adiabatic acoustic tensor is equal to zero. This condition for localization is equivalent to that obtained by using the standard bifurcation method. Based on this idea, the conditions for adiabatic shear band localization of plastic deformation have been investigated for single crystals. Particular attention has been focused on the discussion of the influence of thermal expansion, thermal plastic, softening and spatial covariance effects on shear band localization criteria for a planar model of an f.c.c. crystal undergoing symmetric primary-conjugate double slip. The results obtained have been compared with available experimental observations.Finally, it is noteworthy that the viscoplasticity regularization procedure can be used in the developing of an unconditionally stable numerical integration algorithm for simulation of adiabatic inelastic flow processes in ductile single crystals, cf. [21].The paper has been prepared within research programme sponsored by the Committee of Scientific Research under Grant 3 P404 031 07.     

On evolution of thermo-plastic shear band

The present paper briefly reviews analytical studies of the evolution of thermoplastic shear band, i.e. emergence from uniform deformation, post-instability growth and late stage behaviour. The case studied is the simple shear of temperature and rate-dependent materials with heat transfer. Uniform mode exists before a critical state, if no heat flows out of testpiece. Upon reaching the critical state, bifurcation appears as a result of disturbances, which leads to instability and the formation of narrow shear band. Initially, the band, due to temperature disturbance, can shrink with increasing temperature and strain rate owing to unsteady flow. Then heat conduction dominates and causes the shear band to expand. The postmortem appearance of thermo-plastic shear band manifests itself as balance of plastic work rate and heat diffusion. Melting may also take place within the band.     

The mechanical condition of shear band bifurcation

Based on the understanding of the role played by the strain-softening effect in the formation of shear band bifurcation, this paper investigates (a) What is the most favourable condition that stimulates the occurrence of shear band? (b) With what model and characterizing parameters can the curved type of band bifurcation be simulated?     

Deformation localization and shear band fracture in strong anisotropy sheet tension

The tensile deformation localization and the shear band fracture behaviors of sheet metals with strong anisotropy are numerically simulated by using Updating Lagrange finite element method, Quasi-flow plastic constitutive theory^[1] and B-L planar anisotropy yield criterion^[2]. Simulated results are compared with experimental ones. Very good consistence is obtained between numerical and experimental results. The relationship between the anisotropy coefficientR and the shear band angle θ is found. The project supported by the National Natural Science Foundation of China and the Excellent Youth Teacher Foundation of the State Education Commission of China     

On coupled gradient-dependent plasticity and damage theories with a view to localization analysis

Combinations of gradient plasticity with scalar damage and of gradient damage with isotropic plasticity are proposed and implemented within a consistently linearized format. Both constitutive models incorporate a Laplacian of a strain measure and an internal length parameter associated with it, which makes them suitable for localization analysis.The theories are used for finite element simulations of localization in a one-dimensional model problem. The physical relevance of coupling hardening/softening plasticity with damage governed by different damage evolution functions is discussed. The sensitivity of the results with respect to the discretization and to some model parameters is analyzed. The model which combines gradient-damage with hardening plasticity is used to predict fracture mechanisms in a Compact Tension test.     

Dislocation structure of shear bands in single crystals

A mathematical model is proposed for the development of a shear band in crystals. The model is based on the mechanism of double cross-slips of screw-dislocation segments. Equations are derived to study instability of the uniform distribution of dislocations. A solution is found in the form of a traveling wave, which describes the shear-band structure. __________ Translated from Prikladnaya Mekhanika i Tekhnicheskaya Fizika, Vol. 47, No. 6, pp. 102–113, November–December, 2006.     

材料的率相关与梯度二、四阶耦合模型的内尺度律与稳定性研究

在率相关与梯度塑性二阶耦合本构模型的基础上,提出了二、四阶率相关与梯度塑性耦合模型。采用简谐波的分析方法对材料的应变局部化及材料的稳定性进行了研究,得到了二、四阶耦合模型在一维情况下的内尺度律的变化及材料稳定性的关系,得到了波长变化的上下界及材料稳定性的条件;并对其进行了对比性研究,得到材料稳定点移动的规律。     

Prediction of incipient shear band trajectories in a thick wall cylinder explosion test

A simple but precise and physical mechanism-based mathematical expression is proposed to predict shear band trajectories in thick wall cylinders subject to external surrounding pressure. The expression is based on the Coulomb-Mohr fracture criterion and can be applied to various compression-sensitive materials, especially ceramics. The predicted result closely matches the experimental observations, which makes this method quite useful in testing material behavior. This expression also permits the extraction of the parameter μ in the Coulomb-Mohr criterion from experimental observations. Furthermore, no pre-assumptions or after-test measurement are necessary in order to carry out the prediction. The only two values needed to conduct the prediction are the initial inner radius and the friction coefficient μ. A comparison between the newly proposed model and existing theory is made to reveal their relations and demonstrate the effectiveness of the newly derived mathematical expression.     

有限元边坡稳定分析方法及其应用

本文介绍了一种基于有限元应力分析的边坡稳定评价方法,讨论了边坡稳定安全系数定义的物理意义,介绍了搜索最危险滑动面的广义数学规划命题和模式搜索方法,同时给出了该方法的计算结果与其它方法计算结果的对比算例以及该方法的应用实例。