An analytical investigation of elastic-plastic deformation of FGM hollow rotors under a high centrifugal effect

IF 3.4 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY
Shams Torabnia, Sepideh Aghajani, Mohammadreza Hemati
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引用次数: 4

Abstract

Functionally graded material shafts are the main part of many modern rotary machines such as turbines and electric motors. The purpose of this study is to present an analytical solution of the elastic-plastic deformation of functionally graded material hollow rotor under a high centrifugal effect and finally determine the maximum allowed angular velocity of a hollow functionally graded material rotating shaft. Introducing non-dimensional parameters, the equilibrium equation has been analytically solved. The results for variable material properties are compared with the homogeneous rotor and the case in which Young’s modulus is the only variable while density and yield stress are considered to be constant. It is shown that material variation has a considerable effect on the stress and strain components and radial displacement. Considering variable density and yield stress causes yielding onset from inner, outer, or simultaneously from both inner and outer rotor shaft radius in contrast to earlier researches that modulus of elasticity was the only variable. The effects of the density on the failure of a functionally graded material elastic fully plastic in a hollow rotating shaft are investigated for the first time in this study with regard to Tresca’s yield criterial. Numerical simulations are used to verify the derived formulations which are in satisfying agreement.

Abstract Image

高离心作用下FGM空心转子弹塑性变形分析研究
功能分级的材料轴是许多现代旋转机械的主要部分,如涡轮机和电动机。本研究的目的是给出功能梯度材料空心转子在高离心作用下弹塑性变形的解析解,并最终确定空心功能梯度材料旋转轴的最大允许角速度。引入无因次参数,对平衡方程进行了解析求解。可变材料性能的结果与均匀转子和杨氏模量是唯一变量而密度和屈服应力被认为是恒定的情况进行了比较。结果表明,材料的变化对应力应变分量和径向位移有相当大的影响。考虑变密度和屈服应力导致屈服从内、外或同时从内、外转子轴半径开始,而不是将弹性模量作为唯一变量。本文首次根据Tresca屈服准则,研究了弹塑性功能梯度材料在空心转轴中密度对其破坏的影响。数值模拟验证了所得公式的一致性。
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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来源期刊
CiteScore
8.60
自引率
0.00%
发文量
1
审稿时长
13 weeks
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