用管弯头有限元公式研究转轴的动力特性

Q2 Materials Science

Engineering Solid Mechanics Pub Date : 2022-01-01 DOI:10.5267/j.esm.2022.1.001

M. Sajjadpour, S. H. Kordkheili

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引用次数: 0

摘要

旋转轴在各种工业中有着广泛的应用，特别是在航空航天工业中，如发动机、压缩机和涡轮机。由于旋转轴对转子规格和支承等不同参数的敏感性，研究人员对旋转轴的动态特性进行了大量的研究。本文采用管弯头单元，推导出一种特殊的有限元公式来研究存在支承间隙时转轴的动力特性。所提出的单元由四个节点组成，具有24个自由度，这也考虑了剪切和陀螺仪效应。在有限元分析框架内，本文的重点是提出一种公式来解释具有较少数量元素的旋转轴的动态行为。该单元在有限元程序中实现，然后用于对一些旋转轴实例进行建模和分析。为了验证所开发的公式，结果与文献中报道的其他方案的结果进行了比较。

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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An investigation on dynamic behavior of rotating shafts using a pipe elbow finite element formulation

Rotating shafts have a vast application in various industries especially in the aerospace industry such as engines, compressors and turbines. The researchers have performed considerable efforts on the rotating shafts’ dynamic behavior because of their sensitivity to the rotor specifications and different parameters such as supports. In this paper by employing a pipe elbow element, an especial finite element formulation is derived to investigate dynamic behavior of rotating shaft in the presence of support clearance. The proposed element consists of four nodes with twenty-four degrees of freedom, which also accounts for the shear and gyroscopic effects. Within a finite element analysis framework, the focus of the paper is proposing a formulation to account for the dynamic behavior of a rotating shaft with much less number of elements. The element is implemented in a finite element code and then is used to model and analyze some rotating shaft examples. In order to verify the developed formulation, results are compared with those obtained from other schemes reported in the literature.

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来源期刊

Engineering Solid Mechanics Materials Science-Metals and Alloys

CiteScore

3.00

自引率

0.00%

发文量

期刊介绍： Engineering Solid Mechanics (ESM) is an online international journal for publishing high quality peer reviewed papers in the field of theoretical and applied solid mechanics. The primary focus is to exchange ideas about investigating behavior and properties of engineering materials (such as metals, composites, ceramics, polymers, FGMs, rocks and concretes, asphalt mixtures, bio and nano materials) and their mechanical characterization (including strength and deformation behavior, fatigue and fracture, stress measurements, etc.) through experimental, theoretical and numerical research studies. Researchers and practitioners (from deferent areas such as mechanical and manufacturing, aerospace, railway, bio-mechanics, civil and mining, materials and metallurgy, oil, gas and petroleum industries, pipeline, marine and offshore sectors) are encouraged to submit their original, unpublished contributions.