Search Results

This paper discusses a new Department of Defense (DoD) initiative focused on the development of new generation of MBS computer software that have capabilities and features that are not provided by existing MBS software technology. This three-decade old technology fails to meet new challenges of developing more detailed models in which the effects of significant changes in geometry and large deformations cannot be ignored. New applications require accurate continuum mechanics based vehicle/soil interaction models, belt and chain drive models, efficient and accurate continuum based tire models, cable models used in rescue missions, models that accurately capture large deformations due to thermal and excessive loads, more accurate bio-mechanics models for ligaments, muscles, and soft tissues (LMST), etc.

In this investigation, a new nonlinear finite element dynamic model for the analysis of three-dimensional belt drives and rubber chains in multibody tracked vehicles is developed. In the model developed in this investigation, belts and rubber chains are modeled as continuous deformable bodies using the finite element absolute nodal coordinate formulation (ANCF). Using this finite element formulation, nonlinear material constitutive equations can be used in a straight forward manner with structural elements such as beams and plates. In this study, a Mooney-Rivlin constitutive law that assumes incompressibility of the material is used to model the elastic behavior of the belts and rubber chains.

In this paper, a three dimensional finite element method is developed for the dynamic and vibration analysis of the rear axle system. The method allows for the dynamic modeling of several components of the axle system including the input shaft, the output shafts, the control arms, track bar, tires, bearings, bushings, and helical springs and dashpots of the suspension system. The input and output shafts, the control arms, and the track bar are modeled using three dimensional finite elements. Beam elements, each of which has two nodes and twelve degrees of freedom, are used in the finite element discretization. The formulation developed in this paper takes into account the effect of the angular velocities of the rotating input and output shafts. It is shown in this investigation that in order to model the effect of the angular velocities of the rotating shafts, a non-conventional finite element formulation must be used.