Influence of Smart Spring Support Parameters on Vibration Characteristics of Three Support Shafting
Open Access
- 2 November 2020
- journal article
- research article
- Published by MDPI AG in Applied Sciences
- Vol. 10 (21), 7752
- https://doi.org/10.3390/app10217752
Abstract
Smart spring support is a kind of active damping device based on piezoelectric material. It can effectively suppress the vibration of a shaft system in an overly critical state by changing the stiffness and damping of the support. The support parameters have a significant impact on the vibration of the system. By studying the influence of the smart spring support parameters on the vibration characteristics of the transmission shaft system, the support parameters can be configured more reasonably so that the vibration of the transmission system can be reduced as much as possible. Based on the finite element method, this paper studies the influence of the stiffness, damping and mass of the smart spring support on the vibration characteristics of the three-support shafting. Firstly, the smart spring shafting test bed is built, and the vibration reduction performance test of the smart spring is carried out to verify the damping effect of the smart spring. Then, the shafting dynamic model is established by the finite element method, and the inherent characteristics of the system are analyzed. Finally, the influence of the stiffness, damping, mass and other parameters of the smart spring support on the dynamic response of the system is studied. The results show that increasing the stiffness of the smart spring support can effectively reduce the vibration amplitude of the system. The damping of the smart spring support has no obvious effect on the vibration of the shafting. The smaller the mass of the smart spring support, the more favorable the system is.This publication has 7 references indexed in Scilit:
- Study on the Vibration Active Control of Three-Support Shafting with Smart Spring While Accelerating over the Critical SpeedApplied Sciences, 2020
- Dynamic Response of an Unbalanced Rigid Rotor Bearing System With a Nonlinear Hydrodynamic ForceJournal of Computational and Nonlinear Dynamics, 2018
- Design optimization of rotor-bearing system considering critical speed using Taguchi methodProceedings of the Institution of Mechanical Engineers, Part E: Journal of Process Mechanical Engineering, 2015
- Analysis Behavior of a Rig Shafting Vibration Set Changes Bearing ParametersApplied Mechanics and Materials, 2013
- Experimental Investigation on Modal Signature of Smart Spring/Helicopter Blade SystemJournal of Aircraft, 2008
- Active control of vibration using a fuzzy control methodJournal of Sound and Vibration, 2004
- Dynamic modelling and stability of hingeless helicopter blades with a smart springThe Aeronautical Journal, 2004