有限元计算细观力学对复合材料力学行为的数值分析

有限元计算细观力学的发展是近十年来细观计算力学发展的主要特征和推动力．本文综述了有限元计算细观力学近十年来应用于复合材料力学行为分析研究方面的进展．介绍了基本的数值模型和计算方法,重点评述了强度和损伤等协同效应问题上的最新研究成果．最后对有限元计算细观力学应用于材料设计的前景做了展望      

低密度开孔泡沫材料力学模型的理论研究进展

开孔泡沫材料主要用于隔音、减振和填充方面，对其力学行为进行理论描述，探讨力学性能与密度及复杂微结构的关系具有十分重要的学术价值和工程意义．为了促进国内泡沫材料力学的发展和交流，文中对低密度开孔泡沫材料力学模型的研究历史进行了简要回顾，重点介绍了能较好地反映开孔泡沫材料真实胞体结构特点的十四面体胞体模型和随机胞体模型，并报道了近年来基于十四面体胞体模型和随机胞体模型研究低密度开孔泡沫材料力学行为的一些理论工作、同时，也对国内的一些相关研究情况进行了简要评述，指出了该领域今后的一些研究方向．     

多尺度复合材料力学研究进展

多尺度复合材料力学是运用多尺度分析思想研究空间分布非均匀材料力学性能的学科.近年来,多组分、多层级先进材料的蓬勃发展和微纳米实验观测手段的不断进步,有力地推动了该学科的研究.论文围绕非均匀材料力学性能的多尺度分析,首先从微纳米尺度到宏观尺度综述了常用的理论分析方法;接着分别针对非均匀连续介质和离散体系介绍了常用的多尺度计算模拟方法;然后结合本课题组在纳米复合材料、抗冲击吸能材料、随机网络材料和多层级自相似材料等方面的研究工作,举例说明了如何综合运用多种方法对各种复杂材料系统进行多尺度分析;最后,展望了该领域还需进一步发展和完善的若干方向.     

有限元计算细观力学对复合材料力学行为的数值分析

有限元计算细观力学的发展是近十年来细观计算力学发展的主要特征和推动力．本文综述了有限元计算细观力学近十年来应用于复合材料力学行为分析研究方面的进展．介绍了基本的数值模型和计算方法，重点评述了强度和损伤等协同效应问题上的最新研究成果．最后对有限元计算细观力学应用于材料设计的前景做了展望     

关于复合材料力学几个基本问题的研究

复合材料力学是一种两层次的力学理论，相（材料）通过复合（效应、工艺）形成复合材料。复合效应分为混合效应和协同效应，其相应的混合律和协同律是复合材料力学理论的奠基石，前者已形成理论体系，后者有待形成体系。本文所论及的随机扩大临界核理论可解释多种形式的协同效应。此外，本文还讨论了几个有关的力学问题。     

轴压圆柱壳后屈曲的有限元分析

采用流动的曲线坐标建立了大位移下的样条曲壳元，利用它分析了轴压圆柱壳的后屈曲问题。一个跨越和求取分支点的技巧和对弧长法的一个改进在文中提出。计算所得的载荷－轴向缩短曲线较解析解更接近于实验结果，所得的后屈曲波形也和实验相当符合。     

基于图像分析法的水稻茎秆力学性能测量与分析

水稻茎秆力学性能的准确描述是水稻抗倒伏力学分析的关键。由于茎秆是由生物活性材料组成的形状不规则柔性结构,传统的测试方法难以对其力学性能进行准确测量。以南方水稻为研究对象,采用拉伸试验机对水稻茎秆进行了拉伸试验。首先采用传统的应变片方法测量应变,继而探索采用图像分析法实现非接触、高精度地测量水稻茎秆的截面尺寸、拉伸变形。用数字摄像机记录不同荷载水平下试件表面的数字图像,采用数字图像相关分析法(DIC)进行分析,通过两种方法计算茎秆的轴向应变;将完成拉伸实验的试件切片,采集其横截面的数字图像,通过数字图像分析技术得到其几何特性,并对大量实验数据进行了统计分析,实现了对水稻茎秆弹性模量、抗弯刚度等的合理描述。实验结果表明,采用传统的应变片测量求得的水稻茎秆的弹性模量的离散性极大,超出样本差异性的范围,而采用数字图像分析方法得到的弹性模量、抗弯刚度的结果有一定的离散性,但分布比较合理,比较准确地反映了水稻茎秆相关的力学性能。     

简论岩体的力学模型

从岩体的地质特征和力学行为出发，分别讨论岩体的力学模型，运用劳丹的科学合理性模式分析连续介质和不连续介质两类力学模型的作用和地位，提出两类模型不是对产的而是互补的，今后的发展是建立既能反映性又能反映不连续性的统一的岩体力学模型。     

扁拱跳跃屈曲的突变模型

文中建立的正弦形扁拱跳跃屈曲变模型可以清晰地阐明扁拱失稳的物理意义。给出拱失稳临界力，参量间的一些关系式及一个有兴趣的比较结果。     

基于边界位移的复合材料力学参数无损反演方法

非均质材料参数识别在工程学、医学以及生物力学等众多领域具有重要意义.目前求解材料参数识别这类反问题主要采用优化方法,通常需要已知结构的全场位移信息,使含有位移的目标函数最小化,从而获得材料参数分布.然而在实际工程中,结构内部的位移较难测量且测量精度低.因此,本文拟提出一类仅利用边界位移就能进行非均质材料参数分布反演的方...     

短柱型复合材料加筋壁板轴向压缩破坏分析方法研究

复合材料加筋结构可作为航空结构中的承力部件,其损伤与破坏对航空器的结构安全和服役性能至关重要。本文通过试验和数值仿真手段研究了短柱型复合材料结构压缩失效机理和极限承载力。通过短柱型单加筋板的轴向压缩破坏试验,分析梳理出界面脱粘和材料压溃两种典型失效形式;分别建立加筋板壳单元模型和实体单元模型,引入内聚力模型和Hashin准则描述界面脱粘效应与材料破坏,结果表明壳单元模型配合内聚力模型和Hashin准则可以有效地预测加筋板的极限承载力。分别讨论了加筋板长度、筋条高度、筋条/蒙皮刚度比等参数对加筋板的屈曲承载力的影响,为短柱型复合材料加筋壁板压缩损伤与破坏预测分析提供有益的参考。     

大型沉井结构施工力学模型的研究

大型沉井结构是当今应用较广的基础工程，由于沉井结构的规模大，工区土层复杂，存在有许多不确定性因素。使得施工过程的力学模型比较难确定。迄今尚缺乏可供借鉴的理论研究。由于施工的关键是保证沉井的均匀下沉，控制终沉和防止突沉，为此，建立合适的施工力学模型以预测下沉量和开挖量之间的关系就十分必要，考虑到混凝土沉井在土体中下沉时，其本身的变形很小，可以忽略其影响，本文从多自由度刚体运动的角度，建立沉井下沉过程的动态力学模型。为验证所建模型的正确性，本文对一实际工程进行了数值仿真计算。并将计算结果与实测结果进行了对比。结果表明，所建立的力学模型能较好地反映沉井下沉的工程实际，因而可以应用该模型对沉井下沉进行预测分析。从而有助于指导沉井的实际施工。     

Modified Three-Dimensional Formulations of Bending Problems of Homogeneous Plates and Beams under Complex Fixing Conditions

Modified three-dimensional formulations of bending problems of homogeneous elastic plates and beams are considered. Modification of the known three-dimensional formulations reduces to using additional constraints imposed on displacement functions. An advantage of the formulations proposed is that complex fixing conditions of plates and beams can be taken into account.     

Semianalytic Finite-Element Method in Problems of Nonlinear Continuum Mechanics

A technique for solving problems of nonlinear continuum mechanics associated with contact interaction, plastic distortion, and continuous and discrete fracture of spatial bodies is developed based on the semianalytic finite-element method generalized to noncanonical bodies. Solutions are obtained to new applied problems in various branches of technology. Compared with the traditional FEM, the technique is highly efficient—the amount of computation needed to solve spatial problems reduces by several orders of magnitude     

基于材料力学弯曲理论求解非线性梁的探讨

基于材料力学弯曲理论,利用广义变分原理研究了非线性本构关系静不定梁支承反力的求解,指出了有关文献求解非线性本构关系静不定梁支承反力存在的错误．研究结果表明：本构关系为的静不定梁弯曲时,会同时存在曲率为正、曲率为负的梁段．当n为奇数时,曲率为正梁段的余能表达形式与曲率为负的余能表达式相同．当n为偶数时,曲率为正梁段的余能表达式与曲率为负梁段的余能表达式则不相同,存在正负号的差异．     

Mircopolar Model of Fracture for Composite Material

Failure of a composite is a complex process accompanied by irreversible changes in the microstructure of the material. Microscopic mechanisms are known of the accumulation of damage and failure of the type of localized and multiple ruptures of the fibers delamination along interphase boundaries, and also mechanisms associated with fracture of fibers. In this work, we propose a mathematical model of the local mechanism of failure of a composite material randomly reinforced with a system of short fibers. We implement the Cosserat moment model of crack tip for filament material, reinforced with whiskers or in fiber- reinforced polycrystalline materials. It is assumed that the angular distribution of the fibers is isotropic and the elastic characteristics of the fibers are considerably higher than the elastic constants of the matrix. We implement the homogenization procedure for the effective Cosserat constants similarly to the effective elastic constants. The singular solution in the vicinity of the crack tip in the Cosserat moment model is found. Using this solution, we examine the bending stresses in the filaments due to effective moment stresses in the material. The constructed model describes the phenomenon of fracture of the fibers occurring during crack propagation in those composites. The following assumptions are used as the main hypotheses for the micromechanical model. The matrix contains a nucleation crack. When the load is increased the crack grows and its boundary comes into contact with the reinforcing fibers. A further increase of the stress causes bending of the fiber. When~the fiber curvature reaches a specific critical value, the fiber ruptures. If the stress at infinity is given, the fibers no longer delay the development of failure during crack propagation The degree of bending distortion of the fiber in the vicinity of the boundary of the crack is determined by the moment model of the material. The necessity to take into account the moment stresses in the failure theory of the reinforced material was stressed in [Muki and Sternberg (1965) Zeitschrift f angew Math und Phys 16:611–615; Garajeu and Soos (2003) Math Mech Solids 8(2):189–218; Ostoja-Starzewski et al (1999) Mech Res Commun 26:387–396]. The moment Cosserat stresses were accounted also for inhomogeneous biomechanical materials by Buechner and Lakes (2003) Bio Mech Model Mechanobiol 1: 295–301. We should also mention the important methodological studies [Sternberg and Muki (1967) J Solids Struct 1:69–95; Atkinson and Leppington (1977) Int J Solids Struct 13: 1103–1122] concerned with the moment stresses in homogeneous fracture mechanics.     

Design Models in Linearized Solid Mechanics

The paper is devoted to design models in linearized solid mechanics     

Models in the Engineering Mechanics of Polymer-Matrix Composite Systems

This paper discusses the complete system of structural, thermochemical, and mechanical-mathematical models that describe all the phenomena accompanying the formation of polymer-matrix composite materials (PCMs) and structures made of them. The issues of optimizing design engineering and modeling the postprocess behavior of PCM structures are addressed     

Bending of Composite Plates under Static and Dynamic Loading

The stationary bending of a two-dimensional elastic system of joined rectangular plates with different mechanical properties and boundary conditions is studied. A technique for solving the corresponding problem is proposed. It is based on approximate approaches in combination with a generalization of the force method. It is established that the static strain state of the system is essentially dependent on the difference between the elastic moduli of the constituent plates. It is also shown that with certain boundary conditions, the dependence of the first resonant frequency on the relative position of plates along the contact line is nonmonotonic__________Translated from Prikladnaya Mekhanika, Vol. 41, No. 1, pp. 77–84, January 2005.     

Nonlinear Deformation and Stability of Elliptic Cylindrical Shells under Torsion and Bending

The problem of nonlinear deformation and buckling of noncircular cylindrical shells under combined loading is solved by the variational finite-element method in the displacement formulation. A numerical algorithm for solving the problem is proposed. Stability of cylindrical shells with an elliptic cross-sectional contour under a combined action of torsion and bending is analyzed. The effect of cross-sectional ellipticity and nonlinear prebuckling deformation on the critical loads and buckling mode is studied.