NEW ADMISSIBLE FUNCTIONS FOR THE DYNAMIC ANALYSIS OF A SLEWING FLEXIBLE BEAM

A new finite element beam formulation for modelling flexible multibody systems undergoing large rigidbody motion and large deflections is developed. In this formulation, the motion of the 'nodes' is referred to a global inertial reference frame. Only Cartesian position co-ordinates are used as degre

Vibration analysis of high speed and light weight mechanism systems must consider the mechanisms as elastic bodies in order to accurately predict their performance of specified functions. A general model to describe the elastic motion of a mechanism can be properly established with the use of standa

A dynamic Green function approach is used to determine the response of a simply supported Bernoulli-Euler beam of finite length subject to a moving mass traversing its span. The proposed method produces a simple matrix expression for the deflection of the beam. The efficiency and simplicity of the m

This paper presents a new Dynamic Finite Element (DFE) formulation for the vibrational analysis of spinning beams. A non-dimensional formulation is adopted, and the frequency dependent trigonometric shape functions are used to find a simple frequency dependent element stiffness matrix which has both

In this paper, a method is proposed for modelling large de#ection beam response involving multiple vibration modes. Signi"cant savings in computational time can be obtained compared with the direct integration non-linear "nite element method. The de#ections from a number of static non-linear "nite e