In this thesis, some of the phenomena occurring in plates and cylindrical bars subjected to dynamic loading are investigated. Numerical simulations using a dynamic finite element code are performed for a number of different sized specimens with various initial surface imperfections. Typically imposed loading velocities are in the range 10m/s<v_0<50m/s. The specimens are either subjected to tensile or to compressive loading.



Effects of inertia are examined by introducing an artificial volume load, representing the hydrostatic pressure that follows a homogeneous deformation of a cylindrical bar where no necking is accounted for. The influence of elastic unloading is studied by comparing the necking patterns obtained for cylindrical bars, using two different material models,



J_2-flow theory and J_2-deformation theory. The deformation developments for the specimens of interest are visualized using a contour plot method denoted q-plot.



In the case of dynamic buckling of plates, the visualized results using the q-plot method are compared with that obtained using a direct geometrical method, denoted geo-plot. Ductile fracture is simulated by using cohesive elements, included in the original finite element mesh after a prescribed state of deformation is reached. Fracture is controlled by



the cohesive law, whereas the constitutive relation for the bulk material is chosen as J_2-flow



theory.