Large deformation processes of solids : from fundamentals to numerical simulation and engineering applications

Reflecting two decades of research and development by the author and his group at the Institute of Computer Applications (ICA), Stuttgart University, this volume explores the computer simulation of large deformation processes. It covers material processing and describes several related industrial applications. A CD-ROM listing industrial and laboratory applications of process simulation and containing colour illustrations is included. Designed as an accompanying text for advanced courses on computational solid mechanics, this book will also be valuable to professional engineers who require further grounding in this area.

• Matrix notation: Definitions
• Matrix algebra. Description of material motion: Definition of kinematic variables
• Static variables
• Variation of the reference system
• Static equilibrium
• Virtual power of the forces
• Vectorial arrangement of stress and strain
• The systematics of the finite element method
• Dynamic equations
• Bibliography. Elastic deformations: Description of elastic material behaviour
• Solution of elastic nonlinear problems
• Elastic structures
• Dynamics in elasticity
• Bibliography. Inelastic deformation processes: Description of inelastic material
• Determination of the velocity field
• The process of deformation
• Time dependent boundary conditions
• Adaptive discretization
• Bibliography. Application of inelastic deformation processes in engineering: Superplastic forming
• Plastic deformation
• Paste extrusion
• Impact dynamics
• Bibliography. Thermomechanically coupled deformation processes: Non-isothermal deformation
• Deformation and thermodynamics
• Finite element representation of the thermal problem
• Solution for the transient temperature
• Solution of the thermomechanically coupled problem
• Application to the hot working of metals
• Splashing of ceramic droplets
• Bibliography. Process design and related topics: Task definition
• Objective functions and sensitivity analysis
• Optimization of the process
• Inverse problems
• Extensions
• Bibliography. Solution of coupled systems: Coupled systems
• Interacting processes
• Solution of interacting systems
• Domain decomposition
• Issues of distributed computing
• Bibliography. Elastoplasticity: Implications of elastic constituents
• Description of elastic-plastic material
• Thermodynamics
• Damage in elastic-plastic materials
• Plastic anisotropy
• Considerations on uniqueness and stability
• Bibliography. Problems with random variables: Task description and overview
• A primer on multivariate statistics
• Analysis of stochastic deformation processes
• Design with random parameters
• Exploration by synthetic sampling
• Bibliography.