共查询到19条相似文献,搜索用时 132 毫秒
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微裂缝演化(损伤)引起的各向异性和单边效应,对于混凝土材料和结构的变形和内力有非常重要的影响. 在描述单边效应时,已有的各向异性损伤模型均会得出与热力学基本原理相矛盾的结论即损伤卸载时能量耗散不为零. 基于不可逆热力学和内变量理论,直接以材料柔度张量的增量作为损伤内变量,建立了各向异性单边损伤模型的一般形式,给出了热力学相容的投影算子,推导了模型的率本构关系.文中详细发展了模型的Newton-Raphson数值实现算法及其算法一致性模量,建立了合理的损伤准则和演化法则并应用于混凝土材料. 数值模拟结果初步验证了建议模型的有效性. 需要说明的是,模型完全构筑于热力学基础上,无需引入应变 等效或应变能等效等经验性假定. 相似文献
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近场动力学(简称PD)理论通过域内积分建立物质基本运动方程。不同于传统理论中通过微分建立运动方程的方法,该理论对场函数没有连续性的要求,因而适合求解各类不连续问题。基于此,本文建立了正交各向异性单层板PD理论模型,进而引入单层板层间作用,发展了正交各向异性层合板PD模型及其损伤模型,并模拟了各向同性与各向异性层合板冲击损伤;通过对比分析,对模型的有效性进行了验证。 相似文献
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根据柔性路面在交通荷载作用下的力学响应特点,推导了一个各向异性疲劳损伤本构方程,并基于ABAQUS软件及其二次开发平台,建立了考虑各向异性疲劳损伤的路面结构有限元模型。通过建立的模型计算车辆作用下路面结构的疲劳寿命,其结果与试验数据吻合良好,误差最高仅为3.8%,证明该模型精确可靠。最后,分析了疲劳损伤的演化规律,以及路面结构参数对疲劳性能的影响。结果表明,路面纵向疲劳损伤演化速率比横向大得多,随着车辆循环作用,路面结构的各向异性逐渐增强,进而又加剧疲劳损伤的演化。另外,沥青层越厚、土基弹性模量越大,路面疲劳损伤演化得越慢;而当土基较弱、沥青层较薄时,增加级配碎石层厚度可以显著延缓柔性路面的疲劳开裂。 相似文献
4.
含正交排列夹杂和缺陷材料的等效弹性模量和损伤 总被引:3,自引:0,他引:3
研究含正交排列夹杂和缺陷材料的等效弹性模量和损伤,推导了以Eshelby-Mori-Tanaka方法求解多相各向异性复合材料等效弹性模量的简便计算公式,针对含三相正交椭球状夹杂的正交各向异性材料,得到了由细观参量(夹杂的形状、方位和体积分数)表示的等效弹性模量的解析表达式.在此基础上,提出了一个宏细观结合的正交各向异性损伤模型,从而建立了以细观量为参量的含损伤材料的应力应变关系.最后,对影响材料损伤的细观结构参数进行了分析. 相似文献
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结构钢损伤本构关系的研究 总被引:3,自引:0,他引:3
回顾了结构钢损伤模型的发展史,提出了一种新的本构模型-结构钢弹塑性各向异性损伤本构模型,该模型采用混合强化准则,考虑Bauschinger效应,屈服平台、硬化(软化)效应及损伤和损伤演化影响。算例分析结果表明本文模型能够客观地反映结构钢在循环荷载作用下的工作性能、适用于进行钢结构及构件在循环荷载作用下弹塑性反应分析。 相似文献
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在软土各向异性弹塑性损伤模型的基础上,把小应变模型扩展到有限应变模型,推导出不排水平面应变条件下的剪切带形成条件,分析K0固结状态下各向异性损伤对剪切带形成的影响.以上海软土为例,分析临界状态参数β=0.9时,损伤变量D1,D2的不同组合的剪切角和简单剪切模量与有效平均主应力比(g/p')的关系曲线.计算结果表明,损伤变量越大,越接近不稳定状态,垂直方向损伤对剪切带的影响比水平方向的强烈. 特别指出无论土为横观各向同性损伤的情况,还是各向异性损伤的情况,在本文研究的条件下,不稳定状态(g/p'为最小值)相应两个剪切角约在50°和130°,这对研究弹塑性损伤对剪切带形成与变化有指导意义. 相似文献
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采用宏观HILL模型和晶体塑性模型对面心立方单晶(FCC)材料的非均匀交形进行了数值模拟,意在比较两种不同尺度的模型对塑性各向异性的描述能力的差异。为了使两种模型具有可比性,对于FCC单晶材科,本文提出一种用晶体塑性模型来确定HILL模型中各向异性参数的标定方法。数值分析表明,两类模型对单晶体塑性各向异性的描述能力存在着差异。对FCC单晶材料,HILL模型对各向异性的预测能力没有晶体塑性模型细致,晶体塑性模型更能追踪塑性各向异性的变化。但两种模型对应力应变响应预测的趋势是一致的。对两种模型描述的差异,做了详细的分析。 相似文献
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一个描述脆性材料非线性行为的损伤力学模型 总被引:1,自引:0,他引:1
提出了一个分析和描述脆性材料各向异性损伤的宏观力学模型。在小变型的情况下,利用损伤面和损伤势的概念以及材料性能和材料受损后的弹性响应取决于损伤变量而与加载路径无关的假设,文中导出材料弹性损伤的一般本构关系及联系材料系数与损伤面和损伤势的表达式。当损伤面和损伤势的构造确定后,建立了损伤变量的演变方程和材料性能的变化规律。文中以两种具体材料为例说明该理论模型的应用. 相似文献
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An elasto-anisotropic damage constitutive model for concrete is developed in this work. Disregarding the coupling between the isotropic and the anisotropic damage, the isotropic damage variables are defined as functions of the microcrack fractal dimension, and the anisotropic parts are expressed by the lengths of cracks in concrete which various in different directions. The Helmholtz free energy is decomposed into the elastic deforming, damage and irreversible deforming components, with the last component used to replace the plastic deformation. Therefore the damage constitutive formulas for concrete are derived based on continuum damage mechanics. Evolution laws for both isotropic and anisotropic damage variables are derived, in which the anisotropic parts are obtained by modifying an empirical model. The critical fracture stress and the fracture toughness are investigated for materials with a single fractal crack based on the fractal geometry and the Griffith fracture criterion. Numerical computation is conducted for concrete under the uniaxial and the biaxial compression. The results indicate that the material stiffness degradation can be well addressed when the anisotropic damage is incorporated; the irreversible deformation is greatly related to the behavior of the descending branch beyond the peak load. The validation of the presented model is proofed by comparing results with the experimental data. This model provides an approach to link the macro properties of a material with its micro-structure change. 相似文献
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Based on a dissipation inequality at finite strains and the effective stress concept, a Chaboche-type infinitesimal viscoplastic
theory is extended to finite-strain cases coupled with anisotropic damage. The anisotropic damage is described by a rank-two
symmetric tensor. The constitutive law is formulated in the corotational material coordinate system. Thus, the evolution equations
of all internal variables can be expressed in terms of their material time derivatives. The numerical algorithm for implementing
the material model in a finite element programme is also formulated, and several numerical examples are shown. Comparing the
numerical simulations with experimental observations indicates that the present material model can describe well the primary,
secondary and tertiary creep. It can also predict the anisotropic damage modes observed in experiments correctly. 相似文献
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《International Journal of Plasticity》1999,15(11):1197-1215
In single crystals, the process of creep damage is generally anisotropic. Indeed, the damage evolution does not only depend on the loading conditions, but also on the lattice orientation. And the current state of damage has an anisotropic influence on the effective stress state, so that it is represented by a tensorial damage variable. Based on the continuum damage mechanics theory, a creep damage model for F.C.C. single crystals has been developed and implemented in a three-dimensional anisotropic creep model. It is shown that the resulting material model is capable of describing the orientation dependence of the creep and damage evolution of nickel-based superalloys in the high temperature regime. 相似文献
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In this paper, the stress deformation constitutive relations for continua are discussed and a stress deformation constitutive relation expressed by functional tensorial expression is found. When we study the anisotropic damage of anisotropic materials either from a macroscopic continuum mechanics model or from a microdefect model, there exists a limit to the order of a damage tensor, and the condition under which the damage variable may be described by a tensor lower than those of the highest order is found. 相似文献
15.
《International Journal of Solids and Structures》2014,51(25-26):4357-4372
The motivating key for this work was the absence of a phenomenological model that can reasonably predict a variety of non-proportional experimental data on the anisotropic Mullins effect for different types of rubber-like materials. Hence, in this paper, we propose a purely phenomenological direction dependent orthotropic model that can describe the anisotropic Mullins behaviour with permanent set and, has orthotropic invariants that have a clear physical interpretation. The formulation is based on an orthotropic principal axis theory recently developed for nonlinear elastic problems. A damage function and a direction dependent damage parameter are introduced in the formulation to facilitate the analysis of anisotropic stress softening in rubber-like materials. A direction dependent free energy function, written explicitly in terms of principal stretches, is postulated. The proposed theory is able to predict and compares well with experimental data available in the literature for different types of rubberlike materials. 相似文献
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On the basis of the strong discontinuity analysis, a discrete model expressed in terms of traction vector-displacement jump has been constructed from a continuous model expressed in terms of stress–strain law. In the first part of the paper, this approach has been extended to a class of anisotropic continuum damage constitutive models [1]. In this second part of the paper, the proposed class of discrete anisotropic damage constitutive models is particularized. More precisely, a micromechanical-based anisotropic damage constitutive model is derived. This model accounts in a natural manner for particular crack families orientation. The aims of this paper are (i) to illustrate the capabilities of the proposed discrete enhanced model in reproducing the induced anisotropy appearing in quasi-brittle materials when cracking and (ii) to assess the numerical robustness of the time integration scheme. For this purpose, two numerical examples at the material point level are exposed after a brief presentation of the time integration scheme. The correspondence between the continuous and the discrete model as well as the induced anisotropy features are emphasized. 相似文献
18.
《International Journal of Solids and Structures》1999,36(12):1719-1734
In this paper, an anisotropic damage model is established in strain space to describe the behaviour of geomaterials under compression-dominated stress fields. The research work focuses on rate-independent and small-deformation behaviour during isothermal processes. It is emphasized that the damage variables should be defined microstructurally rather than phenomenologically for geomaterials, and a second-order fabric tensor is chosen as the damage variable. Starting from it, a one-parameter damage-dependent elasticity tensor is deduced based on tensorial algebra and thermodynamic requirements ; a fourth-order damage characteristic tensor, which determines anisotropic damaging, is deduced within the framework of Rice, 1971 normality structure in Part II of this paper. An equivalent state is developed to exclude the macroscopic stress⧹strain explicitly from the relevant constitutive equations. Finally, some numerical results are worked out to illustrate the mechanical behaviour of this model. 相似文献
19.
《Acta Mechanica Solida Sinica》2016,(4)
To consider the anisotropic damage in fatigue, an improved boom-panel model is presented to simulate a representative volume element(RVE) in the framework of continuum damage mechanics. The anisotropic damage state of the RVE is described by the continuity extents of booms and panels, whose damage evolutions are assumed to be isotropic. The numerical implementation is proposed on the basis of damage mechanics and the finite element method. Finally,the approach is applied to the fatigue life prediction of 2A12-T4 aluminium alloy specimen under cyclic loading of tension-torsion. The results indicate a good agreement with the experimental data. 相似文献