Elimination of friction-induced vibration of a propulsion shafting system by auxiliary electromagnetic suspension

Qin, Hui; Yang, Dequan; Zheng, Hongbo; Zhang, Zhiyi

doi:10.1177/1077546319900605

Cited by 11 publications

(5 citation statements)

References 24 publications

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“…But the active control of a rotor system is much centered on reducing the rotor vibration often caused by the unbalance whereas the active control of a shafting system is expected to suppress the vibration of the supports of the shaft. This paper studies the effectiveness of active magnetic bearing in lateral vibration suppression in a shafting system and it is a follow-up to the theoretic research conducted by Qin et al, 25 in which an active magnetic bearing is applied near the stern bearing and the ability of the active magnetic bearing to reduce the friction between the shaft and the stern bearing and eliminate the friction-induced vibration is theoretically proved. As a further study of the electromagnetic suspension, the dynamic model of a shafting system is formulated using the Timoshenko beam theory and Hamilton's principle and the performance of position control is analyzed.…”

Section: Introductionmentioning

confidence: 95%

Suppression of lateral vibration in a shafting system via an auxiliary active magnetic bearing with position control

Yang

Qin

Xie

et al. 2022

Proceedings of the Institution of Mechanical Engineers, Part C:

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The bearings in a shafting system are important paths for the lateral vibration of the shaft to transmit to the hull structure and induce underwater sound. An auxiliary active magnetic bearing for suppressing the lateral vibration at the stern support of a shafting system is investigated. The active magnetic bearing situated close to the stern bearing generates electromagnetic forces to support the shaft, which decreases the contact stiffness as well as the friction between the shaft and the stern bearing and accordingly reduces the stern support acceleration. A dynamic model is established using the Timoshenko beam theory and Hamilton’s principle and the performance of the active magnetic bearing in vibration suppression of the shafting system is evaluated with position control. An experimental system is also built to verify the effectiveness of the active magnetic bearing. Numerical and experimental results have shown that the active magnetic bearing is able to suppress the stern support acceleration responses after the shaft is suspended by the active magnetic bearing. Moreover, the orbit of the shaft center is controlled as well.

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Section: Introductionmentioning

confidence: 95%

Suppression of lateral vibration in a shafting system via an auxiliary active magnetic bearing with position control

Yang

Qin

Xie

et al. 2022

Proceedings of the Institution of Mechanical Engineers, Part C:

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“…Active vibration control methods introduce a secondary control input adjusted by an active controller in real-time for eliminating the vibration responses of the propulsion shafting system. A range of strategies has been carried out in the last decades (Baz et al, 1990;Breńkacz et al, 2021;Caresta and Kessissoglou, 2012;Lewis and Allaire, 1987;Lewis et al, 1989aLewis et al, , 1989bPan et al, 2008aPan et al, , 2008bQin et al, 2019Qin et al, , 2020. Lewis and Allaire (1987) and Lewis et al (1989aLewis et al ( , 1989b employed an auxiliary magnetic bearing inserted in parallel with the thrust bearing of the shaft, providing a low dynamic stiffness on the longitudinal vibration isolations.…”

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

An adaptive feedforward method in active vibration control for the propulsion shafting system

Duan,

Ni,

Zhang

et al. 2023

Journal of Vibration and Control

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This paper proposes a new adaptive feedforward control method for the rejection of multiple periodic disturbances in the propulsion shafting system. The active vibration control scheme of the propulsion shafting system is established by employing the equivalent-input-disturbance principle which reduces the complexity of the control system in applications. The adaptive control algorithm is designed by taking the scale transformation procedure and the frequency-tracking technique into consideration. The scale transformation normalizes the iso-surface of the optimization function by the frequency response characteristics of the control channel, which immensely improves the convergence rate of the control algorithm for multi-harmonic disturbance. Moreover, the adaptive controller tracks the fluctuating frequencies in a direct method, enhancing the efficiency and robustness of the algorithm for eliminating time-varying disturbances. Finally, numerical simulation and experimental validation are carried out to show that the proposed method has good performance on the application of the active vibration control of the propulsion shafting system.

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“…Caresta 23 used inertial actuators which are mounted at the prow to reduce the sound radiation of a submarine hull subjected to the lateral propeller forces. Qin et al 24,25 applied an auxiliary magnetic bearing to suppress lateral vibration transmission in a propulsion shafting system, and the numerical results show that the equivalent stiffness and damping of the support can be changed, resulting in reduced vibration and sound radiation of the hull. Zhu et al 26 proposed an AOS (Active Orthogonal Support) to suppress the lateral vibration transmission via the stern bearing in the shafting system.…”

Section: Introductionmentioning

confidence: 99%

Experiments on vibration transmission control in a shaft-hull system excited by propeller forces via an activemulti-strut assembly

Xie

Ren

Zhu

et al. 2022

Proceedings of the Institution of Mechanical Engineers, Part M:

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The active control of lateral vibration transmission in a shaft-hull system with an active multi-strut assembly was investigated experimentally. The lateral vibration of the shafting system excited by the propeller forces transmits to the hull structure through the active multi-strut assembly, and the embedded actuator in each strut generates control forces to suppress vibration transmission. Modal testing was conducted and the characteristics of the hull structure were obtained. The excitation was exerted by two shakers mounted on the stern bearing housing. The performance of vibration suppression was verified for two control strategies that use three and six error transducers, respectively. Experimental results have demonstrated that the active multi-strut assembly in combination with the adaptive control method is able to suppress the vibration transmission from the shaft to the hull, and accordingly reduces the vibration of the hull surface. Moreover, the control strategy using six error transducers is of stronger cross coupling in the control channels as compared to that using three error transducers, which consequently makes it harder to implement active control.

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Elimination of friction-induced vibration of a propulsion shafting system by auxiliary electromagnetic suspension

Cited by 11 publications

References 24 publications

Suppression of lateral vibration in a shafting system via an auxiliary active magnetic bearing with position control

Suppression of lateral vibration in a shafting system via an auxiliary active magnetic bearing with position control

An adaptive feedforward method in active vibration control for the propulsion shafting system

Experiments on vibration transmission control in a shaft-hull system excited by propeller forces via an activemulti-strut assembly

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