A novel lever-type vibration isolator with eddy current damping

•A lever-type vibration isolator (LVI) is proposed, modeled, and analyzed.•Transmissibility and natural frequency decrease with the increase in lever ratio.•Eddy current damping (ECD) can improve vibration isolation performance of the LVI.•Tip mass of the lever is beneficial for vibration isolation...

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Bibliographic Details
Published in:Journal of sound and vibration 2021-03, Vol.494, p.115862, Article 115862
Main Authors: Yan, Bo, Wang, Zhihao, Ma, Hongye, Bao, Huihuang, Wang, Ke, Wu, Chuanyu
Format: Article
Language:English
Subjects:
Amplitudes
Cross-sections
Damping
Design optimization
Eddy current damping
Eddy currents
Effects
Isolator
Lever-type vibration isolator
Material properties
Permanent magnets
Resonant frequencies
Springs (elastic)
Studies
Vibration
Vibration analysis
Vibration control
Vibration isolation
Vibration isolators
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Summary:•A lever-type vibration isolator (LVI) is proposed, modeled, and analyzed.•Transmissibility and natural frequency decrease with the increase in lever ratio.•Eddy current damping (ECD) can improve vibration isolation performance of the LVI.•Tip mass of the lever is beneficial for vibration isolation of the LVI-ECD.•Material properties and cross-section have little effect on isolation performance. This study proposes a lever-type vibration isolator with eddy current damping (LVI-ECD), which can broaden the isolation band by adjusting the lever ratio and improve the vibration suppression performance with eddy current damping (ECD). The LVI-ECD composes of a lever with a permanent magnet (PM) at the tip of the lever, a load plate, a base plate and springs, etc. The relative motion between the PM and the conductive base and load plates induces ECD, which can be amplified by the lever structure and thus to generate nonlinear damping effect. The theoretical models of the lever-type vibration isolator (LVI) and LVI-ECD are established and the amplitude frequency relationship considering nonlinear damping is deduced. The effects of the lever ratio, tip mass, material property and cross-section of the lever, geometric parameters of the PM and excitation amplitude on the vibration isolation performance of the LVI-ECD are analyzed. The analytical predictions are consistent with the experimental results, which demonstrates that the peak transmissibility and natural frequency decrease with the increase of the lever ratio. ECD can further improve the vibration suppression performance in the resonance region. The transmissibility tends to be flat with the increase of the lever ratio in the isolation region. The vibration isolation performance can be also improved by increasing the tip mass of the lever. The material property and cross-section of the lever have little effect on vibration isolation. This study provides a guideline to design, model and optimize a passive damped lever-type vibration isolator. [Display omitted]
ISSN:0022-460X
1095-8568
DOI:10.1016/j.jsv.2020.115862