Litcius/Paper detail

Parametric Study of Flexure Pivot Bearing Induced Thermal Bow-Rotor Instability (Morton Effect)

Dongil Shin, Junho Suh, Alan Palazzolo

2021Journal of Tribology10 citationsDOI

Abstract

Abstract This paper investigates the journal asymmetric temperature-induced thermal bow vibration of a rotor, as supported by a flexure pivot journal bearing (FPJB). Thermal bow-induced vibration, known as the Morton effect (ME), is caused by non-uniform viscous heating of the journal, and the resulting thermal bow often causes increasing vibration amplitudes with the time-varying phase. Full FPJB’s structural and thermal finite element models are developed and integrated into the flexible rotor model. The model is validated by comparing its predicted ME response with experimental results. An FPJB model, which uses predicted “equivalent” radial and tilting stiffness of the bearing, is compared with the full finite element method (FEM)-based model. The impact of FPJB’s design parameters such as web thickness, bearing material, and housing thicknesses are investigated with parametric studies. The results show that FPJB parameter values may have a major effect on the speed range of ME vibration, and its severity.

Topics & Concepts

Finite element methodVibrationBearing (navigation)Parametric statisticsStructural engineeringRotor (electric)ThermalStiffnessMaterials scienceInstabilityMechanicsEngineeringPhysicsMechanical engineeringAcousticsMathematicsThermodynamicsAstronomyStatisticsTribology and Lubrication EngineeringMagnetic Bearings and Levitation DynamicsGear and Bearing Dynamics Analysis
Parametric Study of Flexure Pivot Bearing Induced Thermal Bow-Rotor Instability (Morton Effect) | Litcius