Finite element formulation of rigid body motion in dynamic analysis of mechanisms

The work presented in this paper is based on an existing comprehensive formulation for rotating #exible systems. In the existing formulation the #exible degrees of freedom (d.o.f.) are represented by an analytically computed modal basis and the coupling matrices between the rigid-and the #exible-bod

A procedure for the finite element computation of the limit load of rigid-perfectly plastic solids is presented. The approach is based on the kinematic theorem of limit analysis, which is formulated so as to reduce the problem to the search of the essentially free minimum of a convex, but not everyw

For the finite element analysis of metal forming processes, a method based on the equilibrium of nodal forces is proposed by assuming the deforming metal to be a slightly compressible rigid-plastic material. As an extension of the method, a formulation for finite deformation is derived on the basis

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