A Crack Induced by a Thin Rigid Inclusion Partly Debonded from the Matrix

IF 0.8

The quarterly journal of mechanics and applied mathematics Pub Date : 2017-03-01 DOI:10.1093/qjmam/hbx003

Y. A. Antipov;S. M. Mkhitaryan

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引用次数: 9

Abstract

The interaction of a thin rigid inclusion with a finite crack is studied. Two plane problems of elasticity are considered. The first one concerns the case when the upper side of the inclusion of length $2b$ is completely debonded from the matrix, and the crack formed symmetrically penetrates into the medium; its length is $2a>2b$ . In the second model, the upper side of the inclusion is partly separated from the matrix, and $a<b$ . It is shown that both problems are governed by singular integral equations that share the same kernel but have different right-hand sides, and their solution satisfy different additional conditions. Derivation of a closed-form solution to these integral equations is one of the main results of the article. The solution is found by reducing the integral equation to a vector Riemann–Hilbert problem with the Chebotarev–Khrapkov matrix coefficient. A feature of the method proposed is that the vector Riemann–Hilbert problem is set on a finite segment, while the original Khrapkov method of matrix factorization is developed for a closed contour. In the case, when the crack and inclusion lengths are the same, the solution is derived by passing to the limit $b/a\to 1$ . It is demonstrated that the limiting case $a=b$ is unstable, and when $a<b$ and the crack tips approach the inclusion ends, the crack tends to accelerate in order to penetrate into the matrix. It is shown that the stresses and the tangential derivative of the displacement have the square root singularity at the crack and the inclusion tips. The stresses and the displacement derivative are monotonic at the external singular points, $\pm a$ and $\pm b$ for Models 1 and 2, and oscillate in small neighborhoods of the internal singular points, $|x/a-b/a|<\varepsilon$ and $|x/b-a/b|<\varepsilon$ , for the first and second problems, respectively, and $0<\varepsilon\le 10^{-6}$ . The potential energy release rate and the Griffith crack growth criterion are established for both models.

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由薄的刚性夹杂物部分脱离基体而引起的裂纹

研究了薄刚性夹杂与有限裂纹的相互作用。考虑了弹性力学的两个平面问题。第一种情况涉及长度为$2b$的夹杂物的上侧与基体完全脱粘，并且对称形成的裂纹渗透到介质中的情况；其长度为$2a>；2b美元。在第二模型中，夹杂物的上侧部分地与矩阵分离，并且$a<；b$。结果表明，这两个问题都是由具有相同核但不同右手边的奇异积分方程控制的，并且它们的解满足不同的附加条件。导出这些积分方程的闭式解是本文的主要结果之一。通过将积分方程简化为具有Chebotarev–Khrapkov矩阵系数的向量Riemann–Hilbert问题，找到了解。所提出的方法的一个特点是，向量黎曼-希尔伯特问题设置在有限段上，而矩阵分解的原始Khrapkov方法是针对闭合轮廓开发的。在这种情况下，当裂纹和夹杂物长度相同时，通过将极限$b/a\传递到1$来导出解。证明了限制情形$a=b$是不稳定的，当$a<；b$并且裂纹尖端接近夹杂物末端，裂纹倾向于加速以渗透到基体中。结果表明，应力和位移的切向导数在裂纹和夹杂物尖端具有平方根奇异性。模型1和2的应力和位移导数在外部奇异点$\pm a$和$\pm b$处是单调的，并且在内部奇异点的小邻域$|x/a-b/a|<；\varepsilon$和$|x/b-a/b|<；\varepsilon$，分别用于第一和第二问题，以及$0<；\varepsilon \le 10^｛-6｝$。建立了两种模型的势能释放率和Griffith裂纹扩展准则。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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The quarterly journal of mechanics and applied mathematics

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