Phase field thermal shock analysis of rotating porous cracked pretwisted FGM microblade using exact shear correction factor

Shashank Pandey
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Abstract

The present work is an attempt to develop a simple and accurate finite element formulation for the thermal shock analysis of the rotating porous cracked pretwisted functionally graded material (FGM) microblade using modified coupled stress theory in conjunction with phase-field and first-order shear deformation theory (FSDT). The physical neural surface is taken as the reference plane and the exact value of the shear correction factor is calculated from the shear stiffness. The elastic properties are assumed to be temperature-dependent and the upper ceramic layer is subjected to a high thermal shock whereas the bottom metallic layer is maintained at room temperature or is thermally insulated. The governing differential equation for the present analysis is derived using Hamilton’s principle and Newmark average acceleration method is used to obtain the transient response of the rotating porous cracked pretwisted FGM microblade subjected to thermal shock. The results obtained from the present finite element formulation are first validated with several benchmark examples available in the literature. New results are presented investigating the effect of crack depth, crack location, crack angle, rotational velocity and material scale ratio on the transient response of the cracked rotating porous pretwisted FGM microblade subjected to thermal shock. It is shown here that the parameters like crack depth, crack location and crack angle have a significant influence on the transient response of the rotating porous cracked pretwisted FGM microblade.
使用精确剪切校正因子对旋转多孔裂纹预扭曲 FGM 微刀进行相场热冲击分析
本研究试图利用修正耦合应力理论,结合相场和一阶剪切变形理论(FSDT),为旋转多孔裂纹预扭曲功能分级材料(FGM)微刀片的热冲击分析开发一种简单而精确的有限元公式。以物理神经面为参考平面,根据剪切刚度计算剪切修正系数的精确值。假设弹性特性与温度有关,上层陶瓷层受到高热冲击,而下层金属层保持室温或隔热。利用汉密尔顿原理推导出本分析的支配微分方程,并使用纽马克平均加速度方法获得旋转多孔裂纹预扭曲 FGM 微刀在受到热冲击时的瞬态响应。首先用文献中的几个基准实例验证了本有限元计算方法得出的结果。新结果研究了裂纹深度、裂纹位置、裂纹角度、旋转速度和材料比例比对受热冲击的多孔裂纹旋转预扭曲 FGM 微叶片瞬态响应的影响。结果表明,裂纹深度、裂纹位置和裂纹角度等参数对旋转多孔裂纹预扭曲 FGM 微叶片的瞬态响应有显著影响。
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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