各向异性半平面问题的复应力函数基本解

应用复变函数Ｃａｕｃｈｙ积分的方法，对于各向异性半平面边界为自由或固定两种情形，分别导出了其在任意集中力或集中力偶作用下的复应力函数基本解，其特例与前人结果一致     

等参数正交异性板平面问题的解法

关于文中指出了现有文献中具有等值复参数正交异性板的平面问题的一些错误，给出了相应正确的应力场和位移场表达式；并提出一种以各向同性板平面问题比拟正交异性板平面问题的方法。     

含两个圆孔的正交异性板孔口补强应力分析

应用数学弹性力学和Ｆａｂｅｒ级数展开的方法，对于含有两个圆孔，且孔周各补强一弹性加强环的正交异性板，给出了其在无限远处均布的外力作用下，环及板内的应力场解；其特例与前人结果一致。     

An Interface Inclusion between Two Dissimilar Piezoelectric Materials

The generalized two-dimensional problem of a dielectric rigid line inclusion, at the interface between two dissimilar piezoelectric media subjected to piecewise uniform loads at infinity, is studied by means of the Stroh theory. The problem was reduced to a Hilbert problem, and then closed-form expressions were obtained, respectively, for the complex potentials in piezoelectric media, the electric field inside the inclusion and the tip fields near the inclusion. It is shown that in the media, all field variables near the inclusion-tip show square root singularity and oscillatory singularity, the intensity of which is dependent on the material constants and the strains at infinity. In addition, it is found that the electric field inside the inclusion is singular and oscillatory too, when approaching the inclusion-tips from inside the inclusion.     

压电体内孔边裂纹的应力强度因子

本文研究含有Ⅲ型孔边裂纹压电弹性体的反平面问题.根据Muskhelishvili的数学弹性力学理论,并利用保角变换和Cauchy积分的方法,对含有圆孔孔边单裂纹和双裂纹的压电弹性体分别进行了分析.基于电不可穿透裂纹模型,得到了在反平面剪力和面内电载荷的共同作用下裂纹尖端应力强度因子的解析解.最后,通过数值算例,讨论了应力强度因子随裂纹长度变化的规律.结果表明:应力强度因子随着裂纹和孔的相对尺寸的增加而增加,并且单边裂纹的应力强度因子要比双边裂纹的应力强度因子大.     

GREEN＇S FUNCTIONS OF INTERNAL ELECTRODES BETWEEN TWO DISSIMILAR PIEZOELECTRIC MEDIA

The generalized 2-D problem of a half-infinite interfacial electrode layer between two arbitrary piezoelectric half-spaces is studied. Based on the Stroh formalism,exact expressions for the Green‘ s functions of a line force, a line charge and a line electric dipole applied at an arbitrary point near the electrode edge, were presented, respectively.The corresponding solutions for the intensity factors of fields were also obtained in an explicit form. These results can be used as the foundational solutions in boundary element method (BEM) to solve more complicated fracture problems of piezoelectric composites.