NON-LINEAR VIBRATION ANALYSIS AND SUBHARMONIC WHIRL FREQUENCIES OF THE JEFFCOTT ROTOR MODEL

In this paper a dynamic formulation is presented for the coupled textile-rotor system. Both the partial differential equation for the textile thread and the ordinary differential equation for the rotor whirling vibration are derived by Hamilton's principle. When the textile is wound either on or off

A multiple harmonic balance method is presented in this paper for obtaining the internal resonant steady state vibration of a Jeffcott rotor with a piecewise-linear non-linearity at the bearing support. The method utilizes the hypertime concept, which isolates each frequency component of a response

The method of multiple scales is developed to analyze the free and forced vibration of non-linear rotor-bearing systems. The rotating shaft is described by the Timoshenko beam theory which considers the effect of the rotary inertia and shear deformation. A non-linear bearing pedestal model is assume

This paper presents the dynamic responses of the coupled textile/rotor system by finite element analysis. When textile is wound either on or off the rotor, the system is non-conservative because mass, inertia and eccentricity of the unbalance of rotor change with time, and also the length of textile

O'Reilly and Holmes [1] performed experiments and analysis of non-linear motion of a string subjected to vertical oscillation of one end. Their analysis suggested that differences between theoretical and experimental results were mainly due to uncertainty in the assumed form for the forcing function

We have attempted to express the frequency response functions of a linear and a quadratic non-linear system in terms of spectral vectors. These vector notations convey the system characteristics in physically realisable measures. One of the valuable tools to verify the non-linear system features is