GEOMETRICALLY NON-LINEAR DYNAMIC MODEL OF A ROTATING FLEXIBLE ARM

A mathematical model for a #exible arm undergoing large planar #exural deformations, continuously rotating under the e!ect of a hub torque and supported by a #exible base is developed. The position of a typical material point along the span of the arm is described using the inertial reference frame

The non-linear, moderately large amplitude #exural free vibrations of an arm clamped with a setting angle to a rigid rotating hub are studied. The shear deformation and rotary inertia e!ects are assumed to be negligible, but account is taken of axial inertia, non-linear curvature and the inextensibi

The dynamic stability behavior of a rotating blade subjected to axial periodic forces is studied by Lagrange's equation and a Galerkin finite element method. The effects of geometric non-linearity, shear deformation and rotary inertia are considered. The iterative method is used to get the mode shap

A comparative modelling of a flexible rotating beam has been considered in this study. The dynamic model is based on a beam with either isotropic material or composite material. The composite beam is considered as orthotropic fiber-reinforced and symmetrically laminated. Both small linear as well as

A clamped-free flexible arm rotating in a horizontal plane and carrying a moving mass is studied in this paper. The arm is modelled by the Euler-Bernoulli beam theory in which rotatory inertia and shear deformation effects are ignored. The assumed mode method in conjunction with Hamilton's principle

A geometrically non-linear model of the rotating shaft is introduced, which includes KaH rman non-linearity, non-linear curvature e!ects, large displacements and rotations as well as gyroscopic e!ects. Through applying Timoshenko-type assumptions, the shear e!ects are also included in the model. Con