Nonlinear dynamic analysis of spindle system considering thermal-solid coupling

During spindle operation, bearings play a supporting role and are subject to dynamic forces and thermal deformation, resulting in structural changes. The main spindle system’s thermal and dynamic properties will be impacted by the bearing structure alteration, and two influence each other with the e...

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Published in	Nonlinear dynamics Vol. 113; no. 7; pp. 6049 - 6073
Main Authors	Wei, Yuan, Xu, Fanyi
Format	Journal Article
Language	English
Published	Dordrecht Springer Netherlands 01.04.2025 Springer Nature B.V
Subjects	Accuracy Applications of Nonlinear Dynamics and Chaos Theory Bearings Bifurcations Classical Mechanics Contact angle Control Coupling Deformation Dynamic characteristics Dynamical Systems Friction Heat conductivity Load Lubricants & lubrication Magnetic pull Mathematical analysis Nonlinear dynamics Numerical methods Physics Physics and Astronomy Reynolds number Statistical Physics and Dynamical Systems Temperature Velocity Vibration Thermal network Nonlinear behavior Spindle Thermal-solid coupling
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ISSN	0924-090X 1573-269X
DOI	10.1007/s11071-024-10490-5

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Abstract	During spindle operation, bearings play a supporting role and are subject to dynamic forces and thermal deformation, resulting in structural changes. The main spindle system’s thermal and dynamic properties will be impacted by the bearing structure alteration, and two influence each other with the existence of a coupling relationship. This paper considers thermal-solid coupling effect, studies influence of nonlinear characteristics on system, creates a spindle model and examines the system architecture. Subsequently, calculations are made for the spindle system heat production and transport, the temperature and deformation of system primary node are examined using the thermal network method, and the results are applied to the calculation of the bearing nonlinear restoring force and the motor unbalanced magnetic pulling force. In addition, considering spindle structure, the concentrated mass approach is used to create nonlinear dynamics analysis model for spindle, and the system model is solved to study its nonlinear dynamics behavior by the numerical method. Spindle system dynamic properties under various influencing variables, such as rotational speed, unbalanced mass, bearing stiffness, and so on, are finally examined, and the linear and nonlinear movements of the spindle system under various operating situations are observed, using bifurcation diagrams and frequency domain waterfall diagrams. This spindle model examines and discusses how system performance varies with different factors and thermal impacts, which can more clearly illustrate how temperature and other factors affect the system dynamic properties and serve as a useful design reference for the system. Graphical abstract
AbstractList	During spindle operation, bearings play a supporting role and are subject to dynamic forces and thermal deformation, resulting in structural changes. The main spindle system’s thermal and dynamic properties will be impacted by the bearing structure alteration, and two influence each other with the existence of a coupling relationship. This paper considers thermal-solid coupling effect, studies influence of nonlinear characteristics on system, creates a spindle model and examines the system architecture. Subsequently, calculations are made for the spindle system heat production and transport, the temperature and deformation of system primary node are examined using the thermal network method, and the results are applied to the calculation of the bearing nonlinear restoring force and the motor unbalanced magnetic pulling force. In addition, considering spindle structure, the concentrated mass approach is used to create nonlinear dynamics analysis model for spindle, and the system model is solved to study its nonlinear dynamics behavior by the numerical method. Spindle system dynamic properties under various influencing variables, such as rotational speed, unbalanced mass, bearing stiffness, and so on, are finally examined, and the linear and nonlinear movements of the spindle system under various operating situations are observed, using bifurcation diagrams and frequency domain waterfall diagrams. This spindle model examines and discusses how system performance varies with different factors and thermal impacts, which can more clearly illustrate how temperature and other factors affect the system dynamic properties and serve as a useful design reference for the system. During spindle operation, bearings play a supporting role and are subject to dynamic forces and thermal deformation, resulting in structural changes. The main spindle system’s thermal and dynamic properties will be impacted by the bearing structure alteration, and two influence each other with the existence of a coupling relationship. This paper considers thermal-solid coupling effect, studies influence of nonlinear characteristics on system, creates a spindle model and examines the system architecture. Subsequently, calculations are made for the spindle system heat production and transport, the temperature and deformation of system primary node are examined using the thermal network method, and the results are applied to the calculation of the bearing nonlinear restoring force and the motor unbalanced magnetic pulling force. In addition, considering spindle structure, the concentrated mass approach is used to create nonlinear dynamics analysis model for spindle, and the system model is solved to study its nonlinear dynamics behavior by the numerical method. Spindle system dynamic properties under various influencing variables, such as rotational speed, unbalanced mass, bearing stiffness, and so on, are finally examined, and the linear and nonlinear movements of the spindle system under various operating situations are observed, using bifurcation diagrams and frequency domain waterfall diagrams. This spindle model examines and discusses how system performance varies with different factors and thermal impacts, which can more clearly illustrate how temperature and other factors affect the system dynamic properties and serve as a useful design reference for the system. Graphical abstract
Author	Wei, Yuan Xu, Fanyi
Author_xml	– sequence: 1 givenname: Yuan surname: Wei fullname: Wei, Yuan email: ywei56@shu.edu.cn organization: School of Mechatronic Engineering and Automation, Shanghai University – sequence: 2 givenname: Fanyi surname: Xu fullname: Xu, Fanyi organization: School of Mechatronic Engineering and Automation, Shanghai University
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SubjectTerms	Accuracy Applications of Nonlinear Dynamics and Chaos Theory Bearings Bifurcations Classical Mechanics Contact angle Control Coupling Deformation Dynamic characteristics Dynamical Systems Friction Heat conductivity Load Lubricants & lubrication Magnetic pull Mathematical analysis Nonlinear dynamics Numerical methods Physics Physics and Astronomy Reynolds number Statistical Physics and Dynamical Systems Temperature Velocity Vibration
Title	Nonlinear dynamic analysis of spindle system considering thermal-solid coupling
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