Nonlinear vibration and stability analysis of a dual-disk rotor-bearing system under multiple frequency excitations

This paper aims to investigate the nonlinear vibration characteristics and stability of a dual-disk rotor-bearing system under multi-frequency excitations. A 4-degree-of-freedom dynamic model is established using the assumed mode method, considering the bearing’s cubic nonlinearity. The system is so...

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Veröffentlicht in:	Nonlinear dynamics 2024-08, Vol.112 (15), p.12815-12846
Hauptverfasser:	Lin, Rongzhou, Hou, Lei, Zhong, Shun, Chen, Yushu
Format:	Artikel
Sprache:	eng
Schlagworte:	Automotive Engineering Broken symmetry Classical Mechanics Control Dynamic models Dynamical Systems Eigenvalues Engineering Excitation Hopf bifurcation Investigations Jacobi matrix method Jacobian matrix Mechanical Engineering Nonlinear response Nonlinearity Original Paper Parameters Resonance Rotor-bearing systems Stability analysis Vibration Vibration analysis
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creator	Lin, Rongzhou Hou, Lei Zhong, Shun Chen, Yushu
description	This paper aims to investigate the nonlinear vibration characteristics and stability of a dual-disk rotor-bearing system under multi-frequency excitations. A 4-degree-of-freedom dynamic model is established using the assumed mode method, considering the bearing’s cubic nonlinearity. The system is solved using the multiple scale method combined with arc-length continuation. The stability of the system’s solutions is determined by solving the eigenvalues of the Jacobian matrix of the averaged equations. The nonlinear vibration characteristics and stability of the dual-disk rotor system under simultaneous resonance conditions are obtained. The results show that changes in system parameters can lead to Saddle-Node and Hopf bifurcations, as well as the occurrence of multi-valued solutions and symmetry-breaking phenomena. Additionally, simultaneous resonance leads to interaction between the two modes, where the relative positions of the resonance peaks of these modes influence the system’s dynamic behavior. Variations in system parameters can alter the relative positions of resonance peaks, leading to more complex effects on nonlinear responses. This research provides significant insights into the dynamic behavior of the dual-disk rotor-bearing system under multi-frequency excitations, which is meaningful for designing and optimizing rotor systems.
doi_str_mv	10.1007/s11071-024-09731-4
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A 4-degree-of-freedom dynamic model is established using the assumed mode method, considering the bearing’s cubic nonlinearity. The system is solved using the multiple scale method combined with arc-length continuation. The stability of the system’s solutions is determined by solving the eigenvalues of the Jacobian matrix of the averaged equations. The nonlinear vibration characteristics and stability of the dual-disk rotor system under simultaneous resonance conditions are obtained. The results show that changes in system parameters can lead to Saddle-Node and Hopf bifurcations, as well as the occurrence of multi-valued solutions and symmetry-breaking phenomena. Additionally, simultaneous resonance leads to interaction between the two modes, where the relative positions of the resonance peaks of these modes influence the system’s dynamic behavior. Variations in system parameters can alter the relative positions of resonance peaks, leading to more complex effects on nonlinear responses. 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A 4-degree-of-freedom dynamic model is established using the assumed mode method, considering the bearing’s cubic nonlinearity. The system is solved using the multiple scale method combined with arc-length continuation. The stability of the system’s solutions is determined by solving the eigenvalues of the Jacobian matrix of the averaged equations. The nonlinear vibration characteristics and stability of the dual-disk rotor system under simultaneous resonance conditions are obtained. The results show that changes in system parameters can lead to Saddle-Node and Hopf bifurcations, as well as the occurrence of multi-valued solutions and symmetry-breaking phenomena. Additionally, simultaneous resonance leads to interaction between the two modes, where the relative positions of the resonance peaks of these modes influence the system’s dynamic behavior. 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A 4-degree-of-freedom dynamic model is established using the assumed mode method, considering the bearing’s cubic nonlinearity. The system is solved using the multiple scale method combined with arc-length continuation. The stability of the system’s solutions is determined by solving the eigenvalues of the Jacobian matrix of the averaged equations. The nonlinear vibration characteristics and stability of the dual-disk rotor system under simultaneous resonance conditions are obtained. The results show that changes in system parameters can lead to Saddle-Node and Hopf bifurcations, as well as the occurrence of multi-valued solutions and symmetry-breaking phenomena. Additionally, simultaneous resonance leads to interaction between the two modes, where the relative positions of the resonance peaks of these modes influence the system’s dynamic behavior. Variations in system parameters can alter the relative positions of resonance peaks, leading to more complex effects on nonlinear responses. This research provides significant insights into the dynamic behavior of the dual-disk rotor-bearing system under multi-frequency excitations, which is meaningful for designing and optimizing rotor systems.</abstract><cop>Dordrecht</cop><pub>Springer Netherlands</pub><doi>10.1007/s11071-024-09731-4</doi><tpages>32</tpages><orcidid>https://orcid.org/0000-0003-0271-7323</orcidid></addata></record>
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subjects	Automotive Engineering Broken symmetry Classical Mechanics Control Dynamic models Dynamical Systems Eigenvalues Engineering Excitation Hopf bifurcation Investigations Jacobi matrix method Jacobian matrix Mechanical Engineering Nonlinear response Nonlinearity Original Paper Parameters Resonance Rotor-bearing systems Stability analysis Vibration Vibration analysis
title	Nonlinear vibration and stability analysis of a dual-disk rotor-bearing system under multiple frequency excitations
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