半渗透裂缝压电材料移动 DBY-PS 模型内部电位移的数值解法

Vikram Singh, Kamlesh Jangid
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摘要

在这项研究中,我们使用 Dugdale-Barenblatt 屈服(DBY)模型和极化饱和(PS)模型分析了无限长压电双电层界面上的移动裂纹。为了模拟移动裂纹问题,Yoffe 型裂纹在无限长的压电双电层界面上以亚音速匀速移动。假定裂纹面是半渗透的,在双电层的边界上施加平面内的电应力和平面外的机械应力。由于施加了机电载荷,裂纹扩展,形成了机械屈服区和电饱和区。为了阻止裂纹进一步扩展,需要在裂纹扩展区施加机械屈服应力和饱和电位移。为了对这一问题进行分析和数值计算,利用傅立叶变换和 Copson 方法将混合边界值问题转化为一组耦合的第二类弗雷德霍姆积分方程(FIEs)。在半渗透裂缝条件下,电饱和区(ESZ)的长度(无论是较长、较短还是等于机械屈服区(MYZ))的闭式分析表达式显示了对外部机电载荷的依赖性。利用数值离散化和二分法定义了求解电裂缝条件参数(ECCP)的算法。举例说明证明了所提出的技术对 Yoffe 型移动裂缝的有效性和适用性。数值结果显示了 ECCP 的收敛性。此外,数值结果还显示了机械区和电气区长度以及能量释放率(ERR)如何受到电气和机械载荷、带材厚度和裂纹速度的影响。此外,机械屈服区的大小始终受到电气载荷的影响,而机械载荷对电气饱和区的影响取决于非线性区的相对大小。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Numerical solution for the interior electric displacement of the moving DBY‐PS model for semi‐permeable cracked piezoelectric material
In this study, we analysed a moving crack at the interface of an infinitely long piezoelectric bilayer using the Dugdale–Barenblatt yield (DBY) model and the polarisation saturation (PS) model. To model the moving crack problem, a Yoffe‐type crack moves at a constant subsonic speed on the interface of an infinitely long piezoelectric bilayer. The crack faces are assumed to be semi‐permeable, and at the boundary of the bilayer, in‐plane electrical and out‐of‐plane mechanical stresses are applied. Due to the application of electro‐mechanical loads, cracks propagate, mechanical yielding zones and electric saturation zones are developed. To arrest the crack from further propagation, mechanical yield stress and saturation electric displacement are applied at the developed zones. To address this problem analytically and numerically, the mixed boundary value problem is transformed into a set of coupled Fredholm integral equations (FIEs) of the second kind using the Fourier transform and the Copson method. The closed‐form analytical expressions for the length of the electrical saturation zone (ESZ), whether longer, shorter or equal to the mechanical yielding zone (MYZ), show dependence on external electro‐mechanical loads under semi‐permeable crack conditions. The algorithm to solve the electric crack condition parameter (ECCP) has been defined using numerical discretization and the bisection method. Illustrative examples demonstrate the proposed technique's effectiveness and suitability for Yoffe‐type moving cracks. The numerical results show the convergence of the ECCP. Furthermore, the numerical results show how mechanical and electrical zone lengths and energy release rate (ERR) are affected by electrical and mechanical loads, strip thickness and crack velocity. In addition, the size of the mechanical yielding zone is consistently promoted by electrical load, while the promotion or prevention of the electrical saturation zone by mechanical load depends on the relative sizes of the nonlinear zones.
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