Experimental hypervelocity impact effects on simulated planetesimal materials

Impact of materials at high velocity results in big craters, large deformations of structures and, at very high velocities, in a phase transition of the materials. Therefore a computational simulation of these events demands a stable and highly elaborate numerical method. A code used for this applic

SPH (Smooth Particle Hydrodynamics) is a relatively new gridless Lagrangian numerical technique which offers advantages over more established grid based Lagrange and Euler methods. An SPH capability implemented into the AUTODYN-2D software has been used to simulate hypervelocity impacts on thin Whip

KERNEL code is based on the SPH-method (Smoothed Particles Hydrodynamics) and assigned to obtain prompt two-and three-dimensional solutions of perforation and damage of multilayered and multisheet bumpers under high-and hypervelocity impact of the single particles. Numerical investigation of rod par

In this study, an existing penetration equation, which was originally designed to give the penetration depth of spherical projectiles at hypervelocity into semi-infinite metallic targets, was modified to give the penetration depths of rotationally symmetric ellipsoid shaped projectiles into semi-inf

On behalf of the European Space Agency, Centre d'Etudes de Gramat (CEG) has performed works aiming at modeling the behavior under hypervelocity impacts of an Aerospatiale ~ developed composite material called AQr0. A model including a multiphase equation of state and a porous material behavior has b