实验数据反演识别分析方法与力学表征

本文给出了两类基于实验(实测)数据的反演识别方法,简述了其在界面力学性能及工程实测数据分析中的应用.在粘接界面力学性能的反演识别实验研究中,基于不同加载速率的实验曲线,结合参数化界面力学模型,通过反演识别给出粘接界面力学性能参数,并对识别结果的适定性进行独立的实验验证;在基于工程实测数据的反演识别与力学建模方面,在分析盾构装备载荷特点的基础上,对海量的实测数据统计分类,提出了力学量纲分析的建模方法,并应用于盾构掘进载荷的反演识别研究.     

纤维增强复合材料界面的力学行为

研究材料的界面和表面的力学行为与破坏机理,是当代材料科学、力学、物理学的前沿课题之一,而复合材料界面问题更有其自身的特殊性和复杂性。本文结合笔者的研究工作重点讨论了纤维复合材料界面力学的共性问题,阐述了复合材料界面的性质、复合材料界面的力学模型和理论、界面力学表征的实验研究、界面损伤破坏机理、界面对复合材料力学性能的影响等5个方面。     

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基于应用影响线函数由监测效应反演荷载的理论分析,提出了通过构造监测截面监测力 学量影响线函数,建立监测力学量与桥上车辆荷载的关系式,应用监测信息反演过桥车 辆荷载的荷载识别方法. 实例结果表明该方法能有效地识别桥上车辆荷载载重.     

一种预测颗粒增强复合材料界面力学性能的新方法

界面在颗粒增强复合材料中起到传递载荷的关键作用, 界面性能对复合材料整体力学行为产生重要影响. 然而由于复合材料内部结构较为复杂, 颗粒与基体间的界面强度和界面断裂韧性难以确定, 尤其是法向与切向界面强度的分别预测缺乏有效方法. 本文以氧化锆颗粒增强聚二甲基硅氧烷(PDMS)复合材料为研究对象, 提出一种预测颗粒增强复合材料界面力学性能的新方法. 首先, 实验获得纯PDMS基体材料及单颗粒填充PDMS试样的单轴拉伸应力$\!-\!$应变曲线, 标定出PDMS基体材料的单轴拉伸超弹性本构关系; 其次, 建立与单颗粒填充试样一致的有限元模型, 选择特定的黏结区模型描述界面力学行为, 通过样品不同阶段拉伸力学响应的实验与数值结果对比, 分别给出颗粒与基体界面的法向强度、切向强度及界面断裂韧性; 进一步应用标定的界面力学参数, 开展不同尺寸及不同数目颗粒填充试样的实验与数值结果比较, 验证界面性能预测结果的合理性. 本文提出的界面力学性能预测方法简便、易操作、精度高, 对定量预测颗粒增强复合材料的力学性能具有一定帮助, 亦对定量预测纤维增强复合材料的界面性能具有一定参考意义.      

基于等效阻尼理论的金属橡胶弹性迟滞力学模型及实验研究

针对弹性多孔金属橡胶非线性迟滞特性力学行为,将迟滞恢复力-位移曲线分解为非线性单值曲线和椭圆,并将等效阻尼理论用于动态力学性能参数识别,从而建立了一种新型的适用于黏弹性阻尼材料的宏观唯象力学模型。采用不同相对密度的环形金属橡胶进行动态实验测试,以验证理论模型的准确性,结果表明该模型可将具有非线性特性的金属橡胶系统进行降阶处理,提高金属橡胶力学模型的预测效率,并能很好地描述金属橡胶的迟滞力学行为。另外,研究了在不同激励频率条件下金属橡胶的阻尼耗能特性。实验结果表明:在高频加载的条件下,黏性阻尼系数对动态加载频率不敏感,阻尼耗能与加载幅值之间呈线性正相关。基于等效阻尼理论的弹性迟滞力学模型具有一定的普适性,可进一步推广应用于类似弹性多孔材料的力学性能表征,为其工程应用提供理论基础。     

电子散斑干涉法在研究双材料界面力学行为中的应用

对于复合材料，界面往往是重要的组成部分，也是缺陷极易发生甚至断裂破坏的地方，从而影响材料整体的力学行为。为了考察不同界面缺陷形式以及材料层厚对界面力学行为的影响，应用电子散斑干涉法对金属基上烤瓷的双材料试件进行了实验研究，部分试件与云纹干涉法结果也进行了比较。实验结果表明具有垂直界面裂纹的试件梁抵抗破坏能力大大削弱，而界面处无缺陷的力学性能较好，其中又以金属层与烤瓷层厚比在3附近的较为理想，实验也表明电子散斑干涉法适用于测量绝对或相对微小的位移，灵敏度达到微米级。     

粘弹性岩体力学模型识别与参数反演解析方法研究

本文基于圆形和非圆形隧道围岩粘弹性位移反演分析解析方法的最新进展，根据隧道围岩力学参数解析解的反演规律，提出了五个粘弹性力学模型识别与参数定理，并通过算例和工程实例对所给出的定理作了必要的验证。     

有机玻璃力学性能的研究现状

有机玻璃作为飞机风挡与舱盖的主要材料,对其力学性能研究尤为重要.综述了国内外学者对有机玻璃力学性能的研究现状:在理论方面,总结了目前对有机玻璃的黏弹性、非弹性、屈服应力与模量-温度关系等本构模型的成果;在实验方面,阐述了近年以准静态、动态及断裂实验为主的研究;在模拟方面,举例说明在分子模拟和有限元模拟中的应用.最后指出了有机玻璃在力学研究方面的发展方向.     

基于光学和探针技术的微纳米固体实验力学研究进展

本文综述了近期微纳米固体实验力学在检测技术和设备平台方面的进展,尤其是基于光学和扫描探针平台的实验技术、方法和相关应用。探讨了不同检测技术的优势以及局限性,涉及微纳米实验力学检测中夹持、加载以及微力与微变形的检测与识别。通过相关的研究事例,介绍巧妙、创新的检测技术和系统在微纳米实验中的重要性,以及微尺度检测中所特有的检测系统与检测对象间的耦合关联等特点。     

植物纤维增强复合材料力学高性能化与多功能化研究

论文从植物纤维的微观结构、化学组成以及力学性能入手,针对植物纤维增强复合材料的界面性能,综述了国内外采用植物纤维表面处理方法来提升复合材料力学性能的研究进展,分析了所遇到的瓶颈,并进一步从复合材料结构设计的角度出发,充分利用植物纤维独特的多层次、多尺度的微观结构特点,通过揭示植物纤维增强复合材料多层次、多尺度的界面力学损伤破坏机制,实现了植物纤维增强复合材料的界面调控和力学高性能化。在此基础上,提出了植物纤维增强复合材料兼顾阻燃和声学性能的结构设计原则和特有的界面力学研究方法。此外,也介绍了相关基础研究成果在航空、轨道交通等领域的示范应用,并针对实现绿色复合材料的结构功能一体化的应用提出了未来研究方向。     

Inverse parameter identification of cohesive zone model for simulating mixed-mode crack propagation

Inverse analysis is widely applied to the identification of material properties or model parameters. In order to improve the computational efficiency of the inverse method based on the genetic algorithm, an interpolation scheme upon the response surface constructed by the finite element simulation has been adopted in this paper. Meanwhile, a gradual homogenization treatment scheme has also been presented to improve the convergence of the inverse method based on the Kalman filter algorithm. Both methods are proven effective in dealing with the single-objective inverse problem. However, literature studies show that the adoption of multiple types of experimental information is useful to improve the accuracy of inverse analysis. In this case, it turns into a multiple-objective inverse problem. Our practice proved that the above-mentioned two methods might not yield a proper result if the sensitivity issue of different types of information is not considered. Therefore, another multi-objective inverse method, in combination of the above two optimization algorithms and a weight-estimating scheme that can consider such sensitivity, has been further presented. Finally, by using a mixed-mode crack propagation simulation and two types of experimental information (loading-displacement response curve and crack path profile), the parameters of the cohesive zone model were inversely identified and its simulation results are in good agreement with the experiment.     

混凝土破坏理论研究进展

本文综述了混凝土的材料性质、破坏特点及机理,回顾了断裂力学与损伤力学在混凝土材料破坏研究中的应用,对当前混凝土破坏研究的主要问题和今后方向进行了讨论与展望。      

岩石裂纹演化及其力学特性的研究进展

综述评介了岩石裂纹（缺陷）演化及其力学特性研究的近期进展．其内容包括：微细观裂纹演化及其力学特性,时间相关性,裂纹扩展与岩石破坏,并结合某些工程问题进行了讨论．     

Identification of Mechanical Material Behavior Through Inverse Modeling and DIC

Inverse methods offer a powerful tool for the identification of the elasto-plastic material parameters. One of the advantages with respect to classical material testing is the fact that those inverse methods are able to deal with heterogeneous deformation fields. The basic principle of the inverse method that is presented in this paper, is the comparison between experimentally measured strain fields and those computed by the finite element (FE) method. The unknown material parameters in the FE model are iteratively tuned so as to match the experimentally measured and the numerically computed strain fields as closely as possible. This paper describes the application of an inverse method for the identification of the hardening behavior and the yield locus of DC06 steel, based on a biaxial tensile test on a perforated cruciform specimen. The hardening behavior is described by a Swift type hardening law and the yield locus is modeled with a Hill 1948 yield surface.     

Mechanical Characterization of Coatings Using Microbeam Bending and Digital Image Correlation Techniques

A new technique for characterizing end-supported microbeams of coating materials is presented. Microbeams are fabricated using micro-EDM machining to isolate the material under investigation from the underlying substrate. Three- and four-point bending is realized by a custom-built microspecimen testing system, and digital image correlation is employed to capture full-field strains and displacements in theses microbeams. These experiments provide the foundation for the use of finite element modeling and inverse methods to determine the mechanical properties (elastic moduli, strength, interfacial toughness) of the coatings. Here, the experimental details of the microbeam bending experiments are explained, discussed and illustrated through application to a multilayered metal/oxide/ceramic thermal barrier coating system commonly used in aero-turbines.     

Debonding of graded coatings under in-plane compression

Graded materials are multiphase composites with continuously varying thermophysical properties. The concept provides material scientists and engineers with an important tool to develop new materials tailored for some specific applications. One such application of this new class of materials is as top coats or interfacial regions in thermal barrier systems. A widely observed failure mode in these layered materials is known to be interfacial cracking that leads to spallation. In many cases it is the buckling instability of coating under mechanically or thermally induced compressive stresses that triggers spallation. Under in-plane loading since the linear elastic small deformation theory gives only a trivial solution, in this study the plane strain interface crack problem for a graded coating bonded to a homogeneous substrate is formulated by using a kinematically nonlinear continuum theory. Both the instability and the postbuckling problems are considered. The main objective of the study is the investigation of the influence of material nonhomogeneity, kinematic nonlinearity and plate approximation on the critical instability load and on such fracture mechanics parameters as strain energy release rate, stress intensity factors and crack opening displacements.     

非完整系统力学积分方法的某些进展

本文介绍非完整系统力学积分理论的某些近代发展,包括经典积分的推广,Lagrange力学逆问题,Hamilton-Jacobi方法的推广,场方法的推广,不变度量方法以及其它方法,并给出本问题未来发展方向的建议.      

生物力学进展和趋向(续)

三、运动关节力学运动关节(diarthrodial joint)的功能在于使动物能灵巧地运动肢体。译成力学术语就是:传递载荷,吸收冲击、振动,承受相当高的应力,且运动时摩擦系数很小。L.L.Malcom曾精细地测量过牛肱关节的摩擦系数,在正应力1—20kg/cm~2的范围内,动摩擦系数为0.0025—0.0040,而最好的工程材料的摩擦系数为0.01—0.05,整整差一个量级。      

Micromechanics of substrate-supported thin films

The mechanical properties of metallic thin films deposited on a substrate play a crucial role in the performance of micro/nano-electromechanical systems (MEMS/NEMS) and flexible electronics. This article reviews ongoing study on the mechanics of substrate-supported thin films, with emphasis on the experimental characterization techniques, such as the rule of mixture and X-ray tensile testing. In particular, the determination of interfacial adhesion energy, film deformation, elastic properties and Bauschinger effect are discussed.     

Thermal stresses in a viscoelastic three-phase composite cylinder

A thermoviscoelastic analysis of a three-phase composite cylinder is presented in this work. The solutions of the heat conduction and thermoelastic problem for three dissimilar media are derived based on the method of analytic continuation associated with the alternation technique. A rapidly convergent series solution for both the temperature and stress field, which is expressed in terms of an explicit general term of the corresponding homogeneous potential, is obtained in an elegant form. The hereditary integral in conjunction with the Kelvin–Maxwell model is applied to simulate the thermoviscoelastic properties while a thermorheologically simple material is considered. According to the correspondence principle, the Laplace transformed thermoviscoelastic solution is directly determined from the corresponding thermoelastic one. The real time solution can then be solved numerically by taking inverse Laplace transform. Finally, some typical examples of interfacial stresses are discussed.