TY - GEN
T1 - Experimental Study on Internal Friction Induced Vibrations of a High-Speed Turbine Rotor-Bearing System
AU - Ma, Ruixian
AU - Guo, Zhaoyuan
AU - Liu, Zhansheng
AU - Liao, Mingfu
N1 - Publisher Copyright:
© 2022, The Author(s), under exclusive license to Springer Nature Singapore Pte Ltd.
PY - 2022
Y1 - 2022
N2 - Internal friction may induce instability of a high-speed turbine rotor-bearing system. The effects of relative slippage between the inner ring of a ball bearing and the shaft on the vibration and stability of a practical high-speed turbine are experimentally studied. The features of the rotor include a cantilevered large mass and the rigid body mode of the first order critical speed. Clearance and transition fits of the bearing and the shaft are considered, together with the variations of tightening torque acted on the locking nut. The dynamic features of vibrations under each condition are analyzed in detail. For clearance fit with standard tightening torque, a “switch” rotating speed is observed at which both the dominant vibration frequency and amplitude change dramatically. Half-frequency whirl entrainment is captured. The “switch” speed and predominate subharmonic frequency induced by internal friction are all increased with amplified tightening torque. For transition fit, instability is also observed for standard tightening torque. In such case, vibrations are always dominated by the fundamental frequency component, however, two “switch” speeds are captured in terms of vibration amplitudes. The time waveforms, spectrums and orbits vary significantly within the range of the two “switch” speeds. With speed increasing above the second “switch” speed, the rotor becomes stable again. Using larger tightening torque is able to suppress the internal friction. The present studies provide elaborated features of internal friction induced vibration, which are highly potentially useful for rotor fault diagnosis.
AB - Internal friction may induce instability of a high-speed turbine rotor-bearing system. The effects of relative slippage between the inner ring of a ball bearing and the shaft on the vibration and stability of a practical high-speed turbine are experimentally studied. The features of the rotor include a cantilevered large mass and the rigid body mode of the first order critical speed. Clearance and transition fits of the bearing and the shaft are considered, together with the variations of tightening torque acted on the locking nut. The dynamic features of vibrations under each condition are analyzed in detail. For clearance fit with standard tightening torque, a “switch” rotating speed is observed at which both the dominant vibration frequency and amplitude change dramatically. Half-frequency whirl entrainment is captured. The “switch” speed and predominate subharmonic frequency induced by internal friction are all increased with amplified tightening torque. For transition fit, instability is also observed for standard tightening torque. In such case, vibrations are always dominated by the fundamental frequency component, however, two “switch” speeds are captured in terms of vibration amplitudes. The time waveforms, spectrums and orbits vary significantly within the range of the two “switch” speeds. With speed increasing above the second “switch” speed, the rotor becomes stable again. Using larger tightening torque is able to suppress the internal friction. The present studies provide elaborated features of internal friction induced vibration, which are highly potentially useful for rotor fault diagnosis.
KW - Internal friction
KW - Rotor-bearing system
KW - Stability
KW - Vibration
UR - http://www.scopus.com/inward/record.url?scp=85116450925&partnerID=8YFLogxK
U2 - 10.1007/978-981-16-5912-6_77
DO - 10.1007/978-981-16-5912-6_77
M3 - 会议稿件
AN - SCOPUS:85116450925
SN - 9789811659119
T3 - Lecture Notes in Electrical Engineering
SP - 1044
EP - 1061
BT - Advances in Applied Nonlinear Dynamics, Vibration and Control - 2021 - The proceedings of 2021 International Conference on Applied Nonlinear Dynamics, Vibration and Control, ICANDVC 2021
A2 - Jing, Xingjian
A2 - Ding, Hu
A2 - Wang, Jiqiang
PB - Springer Science and Business Media Deutschland GmbH
T2 - International Conference on Applied Nonlinear Dynamics, Vibration and Control, ICANDVC 2021
Y2 - 23 August 2021 through 25 August 2021
ER -