Wave propagation in a transversely isotropic microstretch elastic solid

Baljeet Singh, Manisha Goyal
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引用次数: 2

Abstract

The theory of microstretch elastic bodies was first developed by Eringen (1971, 1990, 1999, 2004). This theory was developed by extending the theory of micropolar elastcity. Each material point in this theory has three deformable directors.

The governing equations of a transversely isotropic microstretch material are specialized in x-z plane. Plane wave solutions of these governing equations results into a bi-quadratic velocity equation. The four roots of the velocity equation correspond to four coupled plane waves which are named as Coupled Longitudinal Displacement (CLD) wave, Coupled Longitudinal Microstretch (CLM) wave, Coupled Transverse Displacement (CTD) wave and Coupled Transverse Microrotational (CTM) wave. The reflection of Coupled Longitudinal Displacement (CLD) wave is considered at a stress-free surface of half-space of material. The appropriate displacement components, microrotation component and microstretch potential for incident and four reflected waves in half-space are formulated. These solutions for incident and reflected waves satisfy the boundary conditions at a stress free surface of half-space and we obtain a non-homogeneous system of four equations in four reflection coefficients (or amplitude ratios) along with Snell’s law for the present model.

The speeds of plane waves are computed by Fortran program of bi-quadratic velocity equation for relevant physical constants of the material. The reflection coefficients of various reflected waves are also computed by Fortran program of Gauss elimination method. The speeds of plane waves are plotted against angle of propagation direction with vertical axis. The reflection coefficients of various reflected waves are plotted against the angle of incidence. These variations of speeds and reflection coefficients are also compared with those in absence of microstretch parameters.

For a specific material, numerical simulation in presence as well as in absence of microstretch shows that the coupled longitudinal displacement (CLD) wave is fastest wave and the coupled transverse microrotational (CTM) is observed slowest wave. The coupled longitudinal microstretch (CLM) wave is an additional wave due to the presence of microstretch in the medium. The presence of microstretch in transversely isotropic micropolar elastic solid affects the speeds of plane waves and the amplitude ratios of various reflected waves.

74J

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横向各向同性微拉伸弹性固体中的波传播
微拉伸弹性体理论最早由Eringen(1971, 1990, 1999, 2004)提出。该理论是由微极弹性理论扩展而来的。这个理论中的每个物质点都有三个可变形的指导者。横向各向同性微拉伸材料的控制方程专门用于x-z平面。这些控制方程的平面波解得到双二次速度方程。速度方程的四个根对应于四个耦合平面波,分别为耦合纵向位移(CLD)波、耦合纵向微拉伸(CLM)波、耦合横向位移(CTD)波和耦合横向微旋转(CTM)波。研究了耦合纵向位移波在材料半空间无应力表面的反射。推导了半空间入射波和四反射波的适当位移分量、微旋转分量和微拉伸势。这些入射波和反射波的解满足半空间无应力表面的边界条件,并根据斯涅尔定律得到了具有四种反射系数(或振幅比)的四方程的非齐次系统。根据材料的相关物理常数,用双二次速度方程的Fortran程序计算了平面波的速度。用高斯消元法的Fortran程序计算了各种反射波的反射系数。平面波的速度与传播方向的夹角以纵轴表示。各种反射波的反射系数随入射角绘制。这些速度和反射系数的变化也比较了没有微拉伸参数时的变化。对于某一特定材料,在存在微拉伸和不存在微拉伸的情况下,数值模拟结果表明,耦合纵向位移(CLD)波是最快波,耦合横向微旋转(CTM)波是最慢波。耦合纵向微拉伸波(CLM)是由于介质中存在微拉伸而产生的附加波。横向各向同性微极性弹性固体中微拉伸的存在影响平面波的速度和各种反射波的振幅比[j]
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