High Velocity Impact DynamicsJonas A. Zukas This compendium of mathematical techniques for the modeling and simulation of high-velocity impacts presents the various analytical and experimental aspects of impact dynamics and describes the responses of a variety of materials and structures under impact. Coverage is extended beyond that of the author's Impact Dynamics and deals with new topics in impacts involving inert materials, including the dynamic response to energetic and inert materials. Treatment uses classical mechanics along with the conservation laws, combined with failure analysis. |
Contents
Introduction to Impact Phenomena | 1 |
Material Failure at High Strain Rates | 65 |
Material Characterization at High Strain Rates | 127 |
Copyright | |
11 other sections not shown
Common terms and phrases
adiabatic adiabatic shear alloy aluminum analysis ballistic limit calculated compression conical constant constitutive equation copper crack crater cylinder damage deformation density developed diameter ductile dynamic effects elastic Engng equation experiments explosive Finite Element fracture fracture mechanics fragment free surface function high strain rates high velocity Hugoniot hydrodynamic Hypervelocity impact events impact velocity initial interaction Laboratory Lagrangian limit velocity liner loading Mader mass material behavior Material model measured Mech Mechanics metal nucleation numerical parameters particle velocity penetration velocity perforation Phys plastic wave plate impact plots plug pressure problems projectile Rajendran rate sensitivity Recht residual rigid sabot semi-infinite shaped charge shear band shock wave shown in Figure simulation spall strain rate strength stress wave stress-strain curve target material temperature tensile terminal ballistic theory thickness tion tungsten uniaxial strain uniaxial stress V₁ viscosity void wave propagation yield strength yield stress Zukas