Turbocharger Dynamic Analysis: Advanced Design Simulation in Time Domain Using CFD Predicted Thermal Boundary Conditions

Hydrodynamic bearings are commonly used to support fast rotating rotors. Due to their nonlinear bearing properties, they strongly influence the rotor response behaviour, which can be observed by the occurrence of sub-harmonic oscillations. The appearance of sub-synchronous vibrations depends on the operating bearing conditions, which are determined by the kinematics of bearing partners, the thermodynamic processes and especially the occurrence of cavitation. In this contribution, the rotor response behaviour of a full-floating ring supported Jeffcott-rotor is investigated under the consideration of lubricant film cavitation. The two-phase model is applied as a mass-conserving cavitation theory and compared with the assumptions of Half-Sommerfeld.

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Run up simulation of a full-floating ring supported Jeffcott-rotor considering two-phase flow cavitation

Ziese

Nitzschke

Woschke

2020

Arch Appl Mech

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Turbocharger Dynamic Analysis: Advanced Design Simulation in Time Domain Using CFD Predicted Thermal Boundary Conditions

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Run up simulation of a full-floating ring supported Jeffcott-rotor considering two-phase flow cavitation

Run up simulation of a full-floating ring supported Jeffcott-rotor considering two-phase flow cavitation

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