Time dependent crack growth in ceramic matrix composites with creeping fibers

Acta Metallurgica et Materialia Pub Date : 1995-11-01 DOI:10.1016/0956-7151(95)00103-3

M.R. Begley , B.N. Cox , R.M. McMeeking

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引用次数: 28

Abstract

Crack growth in ceramic matrix composites with creeping fibers has been investigated using a time dependent bridging law to describe the effect of fibers bridging a matrix crack. The fibers were assumed to creep linearly and the matrix was assumed to be elastic. Time dependent crack growth was predicted assuming that matrix crack growth occurs when the stress intensity factor at the matrix crack tip reaches a constant critical value. Crack growth rates are presented as a function of crack length and time. Domains of stable and unstable crack growth are outlined. The solutions illustrate that stable crack growth consists of a relatively brief period of decerelation followed by acceleration to large crack lengths, with crack velocity approaching constancy only at loads very near the matrix cracking stress and for very long cracks. Finally, the time needed to grow a long matrix crack is compared with a rough estimate for the time needed to rupture fibers. A transition is expected from life dominated by matrix crack growth at low stress to life dominated by fiber creep rupture after crack growth at higher stresses.

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蠕变纤维陶瓷基复合材料裂纹扩展的时间依赖性

本文研究了蠕变纤维陶瓷基复合材料的裂纹扩展，并采用随时间变化的桥接定律来描述纤维在基体裂纹中的桥接效应。假定纤维是线性蠕变的，假定基体是弹性的。假设裂纹尖端应力强度因子达到恒定临界值时，基体裂纹扩展发生，并预测裂纹扩展随时间的变化。裂纹扩展速率表示为裂纹长度和时间的函数。概述了稳定和不稳定裂纹扩展的区域。这些解表明，稳定的裂纹扩展包括相对较短的减速期，然后加速到较大的裂纹长度，裂纹速度只有在非常接近基体裂纹应力和非常长的裂纹时才接近恒定。最后，将长基体裂纹生长所需的时间与纤维断裂所需时间的粗略估计进行了比较。预期寿命由低应力下基体裂纹扩展为主过渡到高应力下裂纹扩展后纤维蠕变断裂为主。

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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Acta Metallurgica et Materialia

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