Predictive capability of various linearization approaches for floating-ring bearings in nonlinear dynamics of turbochargers

Dyk, Štěpán; Smolík, Luboš; Rendl, Jan

doi:10.1016/j.mechmachtheory.2020.103843

Cited by 15 publications

(7 citation statements)

References 28 publications

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“…Based on the mathematical model of the above Formulas (1), ( 2), ( 6) and ( 9), the parameters were taken into dimensionless equations, using the standard four-order Runge-Kutta method to perform numerical calculation. The structure parameters of the floating ring bearing-rotor system and floating ring used in this study are shown in Tables 1 and 2, which are derived from references [4,5]. The relative clearance value is the ratio of the oil-film clearance value and the shaft radius in the floating ring bearing.…”

Section: Numerical Simulation and Results Analysismentioning

confidence: 99%

“…This work aims to evaluate dimension parameters of FRB in the stability analysis of rotating systems supported by FRB. For the dynamic problems of floating ring bearings, researchers have proposed several simplified linear methods to analyze the dynamic characteristics of bearings [5]. The multi-scale finite-element method is used to establish the dynamic model of floating ring bearings, in which paper, the calculation results are compared with the test results to verify its correctness.…”

Section: Introductionmentioning

confidence: 99%

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Performance of Relative Clearance Ratio of Floating Ring Bearing for Turbocharger-Rotor System Stability

2021

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The floating ring bearing (FRB) has been widely used in the field of high-speed rotating machinery such as turbochargers, aviation engines and so on, because of its simple structure, high efficiency and low power consumption. In order to obtain the best ratio between inter-oil clearance and shaft radius of the floating ring bearing necessitates the design reference of dimensional parameters for the design of floating ring bearings. This study, based on the transfer-matrix method, developed the dynamic model of the floating ring bearing-rotor system, and, using the Runge–Kutta analysis method for floating ring bearings, the influence of oil film relative clearance ratio of floating rings on rotor system stability was analyzed and studied. The optimum clearance ratio between inner oil film and the shaft of floating ring bearings is λ = 0.01. This research can provide some theoretical support for the design of parameters and fault diagnosis of rotor floating ring bearing systems.

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Section: Numerical Simulation and Results Analysismentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Performance of Relative Clearance Ratio of Floating Ring Bearing for Turbocharger-Rotor System Stability

2021

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“…Furthermore, the obtained results for both cases, constant and variable rotor-bearing velocity, show a transient state of the identifiers before the convergence to the estimated values of stiffness and damping bearing parameters. This behavior is due to the sample time used in the numerical simulations of the identifiers for solving the iterated integrals of Equations ( 15) and (24), which utilize the trapezoidal rule. According to Kharab and Guenther [41], this method presents major calculation errors in comparison with other integration methods.…”

Section: Discussionmentioning

confidence: 99%

“…These linear force coefficients are derived from the assumption of small amplitude motions about an equilibrium position [22] and have been used to study the dynamic responses and analyze the stability of rotor systems supported by oil-lubricated tilting-pad bearings, cylindrical bearings and foil bearings, as pointed out in [23] and references within. Recently, Dyk et al [24] presented diverse linearization methods in the stability analysis of rotating systems supported on floating ring bearing (FRBs), demonstrating the usefulness of the linear force coefficients to predict the dynamic behavior of non-linear systems such as turbochargers supported by FRBs.…”

Section: Introductionmentioning

confidence: 99%

An Algebraic Approach for Identification of Rotordynamic Parameters in Bearings with Linearized Force Coefficients

et al. 2021

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In this work, a novel methodology for the identification of stiffness and damping rotordynamic coefficients in a rotor-bearing system is proposed. The mathematical model for the identification process is based on the algebraic identification technique applied to a finite element (FE) model of a rotor-bearing system with multiple degree-of-freedom (DOF). This model considers the effects of rotational inertia, gyroscopic moments, shear deformations, external damping and linear forces attributable to stiffness and damping parameters of the supports. The proposed identifier only requires the system’s vibration response as input data. The performance of the proposed identifier is evaluated and analyzed for both schemes, constant and variable rotational speed of the rotor-bearing system, and numerical results are obtained. In the presented results, it can be observed that the proposed identifier accurately determines the stiffness and damping parameters of the bearings in less than 0.06 s. Moreover, the identification procedure rapidly converges to the estimated values in both tested conditions, constant and variable rotational speed.

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“…Peixoto et al [18] studied the influence of temperature on vibration characteristics of the turbocharger rotor system. Dyk et al [19] proposed and analyzed several linearization methods of forces acting on floating ring bearings and proved the nonlinear vibration of the rotor system in combination with campbell diagram. Yongfeng et al [20] used the polynomial chaos expansion method to describe the uncertainty of hollow shaft cracked rotor system.…”

Section: Introductionmentioning

confidence: 99%

The Influence of Ring‐Speed Ratio Dynamic Change on Nonlinear Vibration Response of High‐Speed Turbocharger Rotor System

Bin

Zhang

Yang³

et al. 2021

Shock and Vibration

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The ring-speed ratio is a comprehensive dynamic index of floating ring bearing structure and operating parameters, which directly affects the dynamic behavior of the turbocharger rotor system. The cross stiffness of ring-speed ratio and floating ring bearing and the work of oil film force are analyzed. The influence of dynamic ring-speed ratio change on the vibration response of floating ring bearing was studied. The finite element model of the rotor-floating ring bearing system is constructed; its model parameters are verified through the measured critical rotor speed. Newmark integral method is used to analyze the nonlinear transient response. The results show that when the ring-speed ratio is between 0.18 and 0.24, the rotor is in a good operating state; when it increases from 0.24 to 0.36, the rotor vibration is dominated by frequency division, and the system will be less stable. The square of the ring-speed ratio is inversely proportional to the rotational speed of the journal where the subfrequency vibration occurs. It helps to know the nonlinear vibration by judging the journal speed when the rotor vibration occurs in subfrequency. The conclusion provides a reference for the mechanical dynamics design and intelligent management and maintenance of this kind of turbine rotors.

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Predictive capability of various linearization approaches for floating-ring bearings in nonlinear dynamics of turbochargers

Cited by 15 publications

References 28 publications

Performance of Relative Clearance Ratio of Floating Ring Bearing for Turbocharger-Rotor System Stability

Performance of Relative Clearance Ratio of Floating Ring Bearing for Turbocharger-Rotor System Stability

An Algebraic Approach for Identification of Rotordynamic Parameters in Bearings with Linearized Force Coefficients

The Influence of Ring‐Speed Ratio Dynamic Change on Nonlinear Vibration Response of High‐Speed Turbocharger Rotor System

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