Predictive Modeling of Dynamic Processes

This work provides an overview of hydrocode technology, applicable to a variety of industries and areas of engineering design. It successfully blends crash simulations with hydrocode technology, and offers an explanation of the fundamental code components.

Predictive Modeling of Dynamic Processes provides an overview of hydrocode technology, applicable to a variety of industries and areas of engineering design. Covering automotive crash, blast impact, and hypervelocity impact phenomena, this volume offers readers an in-depth explanation of the fundamental code components. Chapters include informative introductions to each topic, and explain the specific requirements pertaining to each predictive hydrocode.

Successfully blending crash simulation, hydrocode technology and impact engineering, this volume fills a gap in the current competing literature available.

Provides an overview of a variety of crash and impact simulations Discusses a wide spectrum of impact problems from low velocity impact to hyper-velocity impact Successfully blends crash simulations with hydrocode technology Includes supplementary material: sn.pub/extras

Klappentext

Predictive Modeling of Dynamic Processes provides an overview of numerical simulation technology, applicable to a variety of industries and areas of engineering design. Covering automotive crash, blast, impact, and hypervelocity impact phenomena, this volume offers readers an in-depth explanation of the simulation potential for research and development. Chapters include informative introductions to each topic, and explain the specific requirements pertaining to a predictive numerical methodology.

Successfully blending basics of material modeling, crash simulation and impact engineering, this volume fills a gap in the current competing literature available.

Inhalt
I Simulation of Automotive Crash Processes.- Simulation of Recoverable Foams under Impact Loading.- The Numerical Simulation of Foam #x2013; An Example of Inter-Industrial Synergy.- Influence of Hardening Relations on Forming Limit Curves Predicted by the Theory of Marciniak, Kuczy#x0144;ski, and Pokora.- The Challenge to Predict Material Failure in Crashworthiness Applications: Simulation of Producibility to Serviceability.- Cohesive Zone Modeling for Adhesives.- Modeling the Plasticity of Various Material Classes with a Single Quadratic Yield Function.- On the Computation of a Generalised Dynamic J-Integral and its Application to the Durability of Steel Structures.- II Numerical Modeling of Blast and Impact Phenomena.- The MAX-Analysis: New Computational and Post-Processing Procedures for Vehicle Safety Analysis.- 10 Years RHT: A Review of Concrete Modelling and Hydrocode Applications.- Numerical Simulations of the Penetration of Glass Using Two Pressure-Dependent Constitutive Models.- On the main mechanisms in ballistic perforation of steel plates at sub-ordnance impact velocities.- Dimensioning of concrete walls against small calibre impact including models for deformable penetrators and the scattering of experimental results.- Numerical Analysis of Fluiddynamic Instabilities and Pressure Fluctuations in the Near Field of a Detonation.- Numerical Simulation of Muzzle Exit and Separation Process for Sabot#x2013;Guided Projectiles at M #x003E; 1.- Numerical Analysis of the Supercavitating Flow about blunt Bodies.- Numerical Analysis Method for the RC Structures Subjected to Aircraft Impact and HE Detonation.- Groundshock Displacements#x2013;Experiment and Simulation.- III Numerical Simulation of Hypervelocity Impact Effects.- Hypervelocity Impact Induced ShockWaves and Related Equations of State.- Artificial Viscosity Methods forModelling Shock Wave Propagation.- Review of Development of the Smooth Particle Hydrodynamics (SPH) Method.- Assessing the Resiliency of Composite Structural Systems and Materials Used in Earth-Orbiting Spacecraft to Hypervelocity Projectile Impact.- Numerical Simulation in Micrometeoroid and Orbital Debris Risk Assessment.- Numerical Modeling of Crater Formation by Meteorite Impact and Nuclear Explosion.