Detailed deduction and analysis of the general analytical model of coupling vibration in a rotor system

被引：0

作者：

Wu M. ^{[1
]}

Yang S.-B. ^{[1
]}

Bao W. ^{[1
]}

Yang J.-F. ^{[1
,2
]}

机构：

[1] School of Energy Science and Engineering, Harbin Institute of Technology, Harbin

[2] Institute of Engineering Thermophysics, Chinese Academy of Science, Beijing

来源：

Hangkong Dongli Xuebao/Journal of Aerospace Power | 2017年 / 32卷 / 05期

关键词：

Analytical solution; Coupling vibration; Nonlinear scale factor; Rotor system; Transient time scale factor;

D O I：

10.13224/j.cnki.jasp.2017.05.012

中图分类号：

学科分类号：

摘要：

Based on the mechanism of linear and nonlinear forces on the rotor system, the linear scale factor, nonlinear scale factor and coupling ratio was introduced as characteristic parameters, the general expressions of damping and stiffness forces were established, so a general form of linear and nolinear coupling vibration model was formulated. Considering a single-disc rotor system excited only by mass unbalance force, the steady-state and transient-state solutions were derived through multi-scale method. The analysis on the analytical solutions showed the vibration mechanism of linear and nonlinear coupling effects and responses. The influence of transient time scale factor on responses was analyzed through numerical calculation. When transient time scale factor was larger, the transient-state solution decayed faster, approaching the steady-state solution closer. The amplitude-frequency characteristics were also analyzed by the short time Fourier transform of the steady-state solution. It can be seen that the first harmonic generation has nonlinear characteristics and the third harmonic generation has double-peak characteristics, further elaborating the influences of nonlinear scale factor on the coupling vibration of the rotor system. © 2017, Editorial Department of Journal of Aerospace Power. All right reserved.

引用

页码：1112 / 1119

页数：7

共 16 条

[1] Meng G., Meng Q., Zhan S., Et al., Suggestion on the study of dynamics and control in key equipments, Advances in Mechanics, 37, 1, pp. 135-141, (2007)
[2] Shi L., A review and forecasting of the ship's propelling system development, Ship Science and Technology, 24, 3, pp. 45-56, (2002)
[3] Meng G., Retrospect and prospect to the research on rotor dynamics, Journal of Vibration Engineering, 15, 1, pp. 1-9, (2002)
[4] Yang J., Yang S., Chen C., Et al., Research on sliding bearing and rotor system stability, Journal of Aerospace Power, 23, 8, pp. 1420-1426, (2008)
[5] Yang J., Wu M., Single-disc rotor nonlinear vibration model and mechanism, Journal of Aerospace Power, 27, 8, pp. 1738-1745, (2012)
[6] Huang W., Wu X., Jiao Y., Et al., Review of nonlinear rotor dynamics, Journal of Vibration Engineering, 13, 4, pp. 497-509, (2000)
[7] Wu M., Yang J., The research on single-disc rotor nonlinear vibration model and mechanism, Advanced Engineering Forum, 2-3, pp. 954-959, (2012)
[8] Lund J.W., The stability of an elastic rotor in journal bearings with flexible damped supports, Journal of Applied Mechanics, 32, 4, pp. 911-918, (1965)
[9] Glienicke J., Han D.C., Leonhard M., Practical determination and use of bearing dynamic coefficients, Tribology International, 13, 6, pp. 297-309, (1980)
[10] Alford J., Protecting turbomachinery from self-excited rotor whirl, Journal of Engineering for Power, 87, 4, pp. 333-344, (1965)

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