Vibration Behavior of Rotating Shaft Due to Contact With Casing

“…Contact mode solutions are obtained for a series of test cases involving two-degree-of-freedom and multimode rotor systems, which illustrate how the amplitude, phase and stability of the contact mode are related. Analytical predictions are compared with the experimental results of Tamura et al [16] and exhibit the same characteristic orbits and spectral features of the recorded displacement signals. The manner in which the stationary frame rotor response is dependent on the forcing amplitude is also investigated.…”

“…To compare the analytical results with those obtained from experiment, the study of Tamura et al [16] is now considered. In this paper, test results were presented for a symmetric rotor with a large centrally mounted disc, surrounded by a resiliently mounted annular casing having a small radial clearance.…”

“…The focus of the present study is the fourth type of rotor response, which involves repeated periodic contacts between the rotor and surround where the frequency of contact is not simply a harmonic or subharmonic of the rotational frequency. These types of vibration modes have previously been identi ed through a combination of numerical simulation and experimental testing, including a rotor on bearings with discontinuous stiffness characteristics [15] and a rotor making contact with its casing [16]. In these systems, the bearing characteristics are approximately radially isotropic and the periodic contacts produce a forward or backward 'bouncing' whirl behaviour of the rotor.…”

“…In general, the motion of the rotor does not exhibit any periodicity in the stationary frame although the rotor vibration contains components at the synchronous frequency as well as additional components at harmonics of a distinct non-synchronous frequency, previously referred to as spectral 'side-bands' [15]. It is apparent from experimental studies that periodic contact modes can play an important role in the transition of rotor behaviour from stable forward whirl to unstable backward whirl, which can be highly damaging [16,18,19]. Therefore, understanding the factors that determine the fourth type of behaviour is important if the conditions for destructive rotor response are to be avoided.…”

Asynchronous periodic contact modes for rotor vibration within an annular clearance

“…Contact mode solutions are obtained for a series of test cases involving two-degree-of-freedom and multimode rotor systems, which illustrate how the amplitude, phase and stability of the contact mode are related. Analytical predictions are compared with the experimental results of Tamura et al [16] and exhibit the same characteristic orbits and spectral features of the recorded displacement signals. The manner in which the stationary frame rotor response is dependent on the forcing amplitude is also investigated.…”

“…To compare the analytical results with those obtained from experiment, the study of Tamura et al [16] is now considered. In this paper, test results were presented for a symmetric rotor with a large centrally mounted disc, surrounded by a resiliently mounted annular casing having a small radial clearance.…”

“…The focus of the present study is the fourth type of rotor response, which involves repeated periodic contacts between the rotor and surround where the frequency of contact is not simply a harmonic or subharmonic of the rotational frequency. These types of vibration modes have previously been identi ed through a combination of numerical simulation and experimental testing, including a rotor on bearings with discontinuous stiffness characteristics [15] and a rotor making contact with its casing [16]. In these systems, the bearing characteristics are approximately radially isotropic and the periodic contacts produce a forward or backward 'bouncing' whirl behaviour of the rotor.…”

“…In general, the motion of the rotor does not exhibit any periodicity in the stationary frame although the rotor vibration contains components at the synchronous frequency as well as additional components at harmonics of a distinct non-synchronous frequency, previously referred to as spectral 'side-bands' [15]. It is apparent from experimental studies that periodic contact modes can play an important role in the transition of rotor behaviour from stable forward whirl to unstable backward whirl, which can be highly damaging [16,18,19]. Therefore, understanding the factors that determine the fourth type of behaviour is important if the conditions for destructive rotor response are to be avoided.…”

Asynchronous periodic contact modes for rotor vibration within an annular clearance

“…The transition from forward to backward whirl usually involves a series of bouncing motions. In some cases, these bouncing motions can persist indefinitely without the rotor progressing to continuous rub (Tamura et al 2002;. A method to predict steady bouncing whirl motions in radially isotropic rotor-stator systems has been proposed by .…”

On stability of rotordynamic systems with rotor–stator contact interaction

Rolling contact whirling motion of a rotating shaft supported by a repulsive magnetic bearing and a rotatable backup bearing (Influences of friction coefficient and damping)