基于奇异强度因子的V型切口应力场和N-SIF评估方法

根据线弹性断裂力学理论,V形切口处的应力场具有奇异性,应力值趋于无穷大,峰值应力不能直接用于评定疲劳强度。通过引入了奇异强度因子“as”,单边缺口应力分布和缺口应力强度因子(N-SIF)的半解析公式被推导。考虑张开角和几何尺寸等因素,基于奇异强度因子拟合得到了切口应力评估的简易公式,可用于切口应力场和N-SIF值的快速评估。将简易公式评估结果与有限元结果以及传统文献结果进行对比分析,结果表明,本文简易公式可以准确地预报拉伸载荷下单边V型切口角平分线上的应力场和N-SIF值,实现了切口试样应力场的快速评估。     

两相材料V形切口应力强度因子边界元分析

建立了边界元法计算两相材料粘结V形切口奇异应力场的新途径。在V形切口尖端挖出一小扇形,将该扇形弧线边界的位移和面力表示为有限项奇性指数和特征角函数的线性组合,其组合系数即为广义应力强度因子,将该组合回代到在被挖去小扇形后的剩余结构内建立的边界积分方程,离散后可求解出组合系数,获得两相材料粘结V形切口尖端的应力强度因子。算例证明了本文方法的有效性。     

插值矩阵法分析双材料平面V形切口奇异阶

对二维V形切口问题提出奇异阶分析的一个新方法.首先,以V形切口尖端附近位移场沿其径向渐近展开为基础,将其线弹性理论控制方程转换成切口尖端附近关于周向变量的常微分方程组特征值问题,然后将数值求解两点边值问题的插值矩阵法进一步拓展为求解一般常微分方程组特征值问题,插值矩阵法是在离散节点上采用微分方程中待求函数的最高阶导数作为基本未知量.由此,V形切口的应力奇性阶问题通过插值矩阵法获得,同时相应的切口附近位移场和应力场特征向量一并求出.     

非奇异应力对中央含V形切口试样断裂性能的影响

采用Williams渐近展开式表达V形切口尖端附近区域的位移场和应力场,将其代入弹性力学基本方程中,应力奇异性指数及其对应的位移和应力角函数由求解常微分方程组获得。由于在远离切口尖端的区域无应力奇异性,将切口尖端应力奇异性区域移出后,应用边界元法分析无应力奇异性的剩余结构;将Williams渐近展开式与弹性力学边界积分方程结合,解出切口尖端附近应力奇异性区域的各应力场渐近展开项系数,从而获得切口尖端附近区域的完整应力场;基于此,研究了非奇异应力项对中央含V形切口试样的表观断裂韧度和临界荷载预测值的影响。结果表明:考虑非奇异应力项时,脆性断裂的表观断裂韧度和临界荷载的预测值要比忽略非奇异应力项时的预测值更接近实验值。     

基于应力比值法的V形切口应力强度因子分析

本文基于有限元分析技术建立了一种应力比值方法,用于计算V形切口的应力强度因子。该方法不需要在V形切口尖端采用反映应力奇异性的奇异单元。求解时,首先给定参考问题的广义应力强度因子,然后利用待求问题的应力值与参考问题的应力值之间的比值来求解待求问题的广义应力强度因子。算例采用切口尖端应力方法分析了平板的V形切口问题。计算结果表明,该方法计算精度较高,能够方便地用于求解相关的工程问题。     

V形切口应力强度因子的一种边界元分析方法

将V形切口结构分成围绕切口尖端的小扇形和剩余结构两部分. 尖端处扇形域应力场表示成关于尖端距离$\rho$的渐近级数展开式,从线弹性理论方程推导出了一组分析平面V形切口奇异性的常微分方程特征值问题,通过求解特征方程,得到前若干个奇性指数和相应的特征向量. 再将切口尖端的位移和应力表示为有限个奇性阶和特征向量的组合. 然后用边界元法分析挖去小扇形后的剩余结构. 将位移和应力的线性组合与边界积分方程联立,求解获得切口根部区域的应力场、应力幅值系数和整体结构的位移和应力. 从而准确计算出平面V形切口的奇异应力场和应力强度因子.      

正交异性材料V型切口反对称变形下的尖端场

基于正交各向异性材料弹性平面问题的通解,导出了正交各向异性材料奇异点附近的位移场和奇异应力场的解析表达式,由此给出了反对称变形模态下V型切口尖端附近的位移场和奇异应力场的解析解,通过算例难证,解析解与有限元解吻合得非常好.研究结果表明,正交各向异性材料V型切口尖端附近的应力奇异性不仅与切口的张角有关,还与材料的弹性常数有关.     

含界面裂纹Reissner板弯曲问题分析的奇异单元

首先,采用特征函数渐近展开法,推导了Reissner板弯曲界面裂纹尖端附近位移场渐近展开的前两阶显式表达式,并利用所获得的位移场渐近表达式构造了一种可用于Reissner板弯曲界面裂纹分析的奇异单元。然后,将该奇异单元与外部的常规有限单元相结合,开展了含界面裂纹Reissner板弯曲断裂问题的数值分析。奇异单元可以较好地描述裂纹尖端附近的内力场与位移场,其优势是它与常规单元进行连接时不需要使用过渡单元,并且可以直接给出应力强度因子等断裂参数的高精度数值结果。最后,通过两个数值算例验证了本文方法的有效性。     

垂直于界面V型缺口尖端的应力奇异性及其应用

基于双材料垂直于界面V型缺口理论,给出了单一材料和双材料裂纹问题、V型缺口问题应力强度因子的统一定义,得到了应力外推法计算双材料K_I的公式,数值算例验证了本文方法的有效性.以双材料单向拉伸和三点弯曲模型为对象,深入研究了双材料中弹性模量、泊松比、缺口深度、缺口张角对缺口尖端奇异应力场的影响,获得了一定范围内各种参数变化对缺口尖端奇异应力场的影响规律,为异体材料形成的V型缺口在应力断料中的应用提供了必要的参考依据.     

12结点三维等参奇异单元的构造和应用

通过改变三维8结点六面体等参单元的结点位置、结点数目和形函数,构造了一种12结点三维等参奇异单元,该单元的应力场具有1/(√r)奇异性,可以模拟裂缝前沿的奇异应力场;该单元的位移模式在其中两个坐标方向是线性变化的,因此,该单元与线性单元连接时不需要过渡单元,仍能保证交界面位移协调,克服了20结点三维等参奇异单元不能与线性单元协调连接的缺陷;文章最后将该奇异单元布置在裂缝前沿,应用有限元法计算了三点弯曲梁预制裂缝前沿的应力强度因子,该结果与规范公式计算值基本一致.     

A singular element for calculating the stress intensity factor

This paper proposes a new type of special element (sectorial singular element) for calculating the linear elastic stress intensity factor. The shape of element not only accords with the demands of finite element analysis, but also coincides with the theory of linear elastic fracture mechanics. The accuracy and economy of the result in this paper are satisfactory.     

拉伸载荷作用下共面表面裂纹间应力强度因子影响系数的有限元分析

采用参数化有限元方法,结合节点力法和循环迭代算法,对一有限厚矩形板表面有两个相邻共面半椭圆表面裂纹在拉伸载荷作用下进行了求解,得到了两裂纹在不同形状和相隔距离时的应力强度因子的影响系数,计算结果对含三维广布裂纹结构的剩余强度和疲劳寿命有参考意义.     

Three-dimensional elliptic crack under impact loading

The dynamic stress intensity factor of a three-dimensional elliptic crack under impact loading is determined with the finite element method. The computation results can take into account the influence of time and the ratio of the wave speeds on the stress intensity factor. The present method is suitable not only for three-dimensional dynamic crack, but also for three-dimensional dynamic contact. Project supported by the National Natural Science Foundation of China (No. K19672007).     

A precise singular finite element for crack analysis

The multi-variable finite element algorithm based on the generalized Galerkin’smethod is more flexible to establish a finite element model in the continuum mechanies.Byusing this algorithm and numerical tests a new singular finite element for elasto-plasticfracture analysis has been formulated.The results of numerical tests show that the newelement possesses high accuracy and good performance.Some rules for formulating amulti-variable singular finite element are also discussed in this paper.     

拉伸荷载下分支裂隙破坏机理研究

为研究拉伸荷载下分支裂隙对破坏模式的影响,保持主裂隙参数不变,改变分支裂隙倾角和长度,利用扩展有限元方法模拟了弯折裂隙的动态扩展,总结了分支裂隙参数变化对破坏模式的影响.利用ABAQUS中的轮廓积分计算了分支裂隙尖端应力强度因子,并根据最大周向应力准则计算起裂角.结果表明:拉伸荷载下分支裂隙出现三种破坏模式;分支裂隙倾...     

METHOD TO CALCULATE STRESS INTENSITY FACTOR OF V-NOTCH IN BI-MATERIALS

Based on Zak＇s stress function, the eigen-equation of stress singularity ofbi-materials with a V-notch was obtained. A new definition of stress intensity factor for a perpendicular interfacial V-notch of bi-material was put forward. The effects of shear modulus and Poisson＇s ratio of the matrix material and attaching material on eigen-values were analyzed. A generalized expression for calculating/（i of the perpendicular V-notch of bi-materials was obtained by means of stress extrapolation. Effects of notch depth, notch angle and Poisson＇s ratio of materials on the singular stress field near the tip of the V-notch were analyzed systematically with numerical simulations. As an example, a finite plate with double edge notches under uniaxial uniform tension was calculated by the method presented and the influence of the notch angle and Poisson＇s ratio on the stress singularity near the tip of notch was obtained.     

A numerical method for Cauchy principal value of singular integral under parametric transformation in BEM

A numerical method for the Cauchy principal value of the singular integral in BEM is developed using the concept of finite part integration under integral variable transformation. It is applied to the numerical integration on isoparametric element successfully, as shown in the examples in this paper.The project supported by National Natural Foundation of China.     

辛奇异元方法与含裂纹结构加固问题分析

本文借助于辛体系本征解展开原理和辛共轭正交关系,提出一种辛奇异元模型.并结合有限元软件形成一种新的数值方法和对含裂纹结构分析思路.其最大优势在于:直接给出裂纹的应力强度因子;不受单元网格密度的局限;不受路径的影响.利用该奇异元对含裂纹结构加固问题进行分析,发现了一些特殊的规律.为含裂纹结构加固技术提供依据.     

Mixed-mode thermal stress intensity factors from the finite element discretized symplectic method

A finite element discretized symplectic method is introduced to find the thermal stress intensity factors (TSIFs) under steady-state thermal loading by symplectic expansion. The cracked body is modeled by the conventional finite elements and divided into two regions: near and far fields. In the near field, Hamiltonian systems are established for the heat conduction and thermoelasticity problems respectively. Closed form temperature and displacement functions are expressed by symplectic eigen-solutions in polar coordinates. Combined with the analytic symplectic series and the classical finite elements for arbitrary boundary conditions, the main unknowns are no longer the nodal temperature and displacements but are the coefficients of the symplectic series after matrix transformation. The TSIFs, temperatures, displacements and stresses at the singular region are obtained simultaneously without any post-processing. A number of numerical examples as well as convergence studies are given and are found to be in good agreement with the existing solutions.