INVESTIGATION ON THE STEADY-STATE RESPONSES OF ASYMMETRIC ROTORS

被引：48

作者：

KANG, Y

SHIH, YP

LEE, AC

机构：

[1] Department of Mechanical Engineering, National Chiao Tung University

来源：

JOURNAL OF VIBRATION AND ACOUSTICS-TRANSACTIONS OF THE ASME | 1992年 / 114卷 / 02期

关键词：

D O I：

10.1115/1.2930249

中图分类号：

O42 [声学];

学科分类号：

070206 ; 082403 ;

摘要：

This paper is to generalize the previous work by utilizing finite element formulation to accommodate the effects of both deviatoric inertia and stiffness due to asymmetry of flexible shaft and disk. A Timoshenko beam element is employed to simulate rotor-bearing systems by taking the gyroscopic moment, rotary inertia, shear deformation of shaft and, asymmetry of disk and shaft into account. Internal damping is not included but the extension is straightforward. Eulerian angles are used to describe the orientations of shaft element and disk, by which, in opposite to the vectorial approach, the mathematical formulation will be symmetric for angular displacements in two directions. The effects of the angle between the major axes of shaft and disk, deviatoric inertia of the asymmetric shaft, and characteristics of bearing on synchronous critical and subcritical speeds are estimated in conjunction with the harmonic balance method. Numerical examples show that the resonant speeds, at which peak responses occur, change due to various angles between major axes, asymmetry of shaft, stiffness, and damping of bearing.

引用

页码：194 / 208

页数：15

共 15 条

[1]

Ardayfio D., Frohrib D.A., Instabilities of an Asymmetric Rotor with Asymmetric Shaft Mounted on Symmetric Elastic Supports, ASME Journal of Engineering for Industry, pp. 1161-1165, (1976)

[2]

Brosens P.J., Crandall S.H., Whirling of Unsymmetrical Rotor, ASME Journal of Applied Mechanics, pp. 355-362, (1961)

[3]

Genta G., Whirling of Unsymmetrical Rotors: A Finite Element Approach Based on Complex Co-ordinates, Journal of Sound and Vibration, 124, 1, pp. 27-53, (1988)

[4]

Greenhill L.M., Bickford W.B., Nelson H.D., A Conical Beam Finite Element for Rotor Dynamics Analysis, ASME Journal of Vibration, Acoustics, Stress, and Reliability in Design, 107, pp. 421-430, (1985)

[5]

Hayashi C., Nonlinear Oscillation in Physical System, (1964)

[6]

Meirovitch L., Methods of Analytical Dynamics, (1970)

[7]

Nelson H.D., McVaugh J.M., The Dynamics of Rotor-Bearing Systems Using Finite Elements, ASME Journal of Engineering for Industry, 98, 2, pp. 593-600, (1976)

[8]

Nelson H.D., A Finite Rotating Shaft Element Using Timoshenko Beam Theory, ASME, Journal of Mechanical Design, 102, pp. 793-803, (1980)

[9]

Ozgiiven N.H., Ozkan L.Z., Whirl Speeds and Unbalance Response of Multi-Bearing Rotors Using Finite Elements, ASME Journal of Vibration, Acoustics, Stress, and Reliability in Design, 106, pp. 72-79, (1984)

[10]

Parszewskl Z.A., Krodkiewski J.M., Rucinksi J., Parametric Instabilities of Rotor-Support Systems with Asymmetric Stiffness and Damping Matrices, Journal of Sound and Vibration, 109, 1, pp. 111-125, (1986)

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