Structural plasticity : theory, problems, and CAE software

This book is designed for use as a supplement to the textbook "Plasticity for Structural Engineers" by W.F. Chen and D.J. Han (Springer-Verlag, 1988) or other plasticity texts. The purpose is to help students and structural engineers learn and practice how to solve typical engineering plasticity problems in general and, more importantly, how to use computers to solve plasticity problems in structural engineering in particular. To this end, specific numerical algorithms in the computer software implementation of the theory together with actual code development are given. A number of solved and supplementary problems are provided, as well as two computer-aided-education (CAE) programs, to enhance the students' understanding of these subjects.

1 One-Dimensional Stress-Strain Analysis.- 1.1 Uniaxial Behaviors.- 1.2 Basic Relations.- 1.3 Idealized Stress-Strain Relationships.- 1.4 Hardening Rules.- 1.5 Stress-Strain Response Problems.- 1.6 Fixed-End Bar Problems.- 1.7 Stepped and Tapped Bar Problems.- 1.8 Three-Bar Structure Problems.- 1.9 Three-Bar Truss Problems.- 2 One-Dimensional Stress-Strain Analysis Software.- 2.1 Formulation of PLASTIC1.- 2.2 Algorithms.- 2.3 Implementation of PLASTIC1.- 2.4 User's Manual of PLASTICI.- 2.5 Problems Associated with Hardening Parameters.- 2.6 Problems Associated with Hardening Rules.- 2.7 Source Code Listing of PLASTIC1.- 3 Elastic Stress and Strain Analysis.- 3.1 Stress Tensor.- 3.2 Principal Stresses and Stress Invariants.- 3.3 Deviatoric Stress Tensor and Its Invariants.- 3.4 Geometric Representation of Stress States.- 3.5 Equilibrium Equations.- 3.6 Strain Tensor.- 3.7 Principal Strains and Strain Invariants.- 3.8 Deviatoric Strain Tensor and Its Invariants.- 3.9 Compatibility Equations.- 3.10 Generalized Hooke's Law.- 3.11 Decomposition of Stress-Strain Relations.- 3.12 Basic Equations in Cylindrical and Spherical Coordinates.- 4 Yield Criteria.- 4.1 Representation of Yield Criteria.- 4.2 Hydrostatic-Pressure-Independent Materials.- 4.3 Hydrostatic-Pressure-Dependent Materials.- 4.4 Tresca and von Mises Problems.- 4.5 Mohr-Coulomb Problems.- 4.6 Drucker-Prager Problems.- 4.7 Tension Cut-Off Problems.- 5 Perfectly Plastic Stress Analysis.- 5.1 General Aspects.- 5.2 Loading Criterion.- 5.3 Plastic Potential and Flow Rule.- 5.4 Complete Perfectly Plastic Constitutive Relation.- 5.5 Thin-walled Vessel Problems.- 5.6 Plastic Zone Near Crack Tip Problems.- 5.7 Thick-walled Vessel Problems.- 5.8 Incremental Stress-Strain Relation Problems.- 5.9 Source Code Listing of PLASTIC_ZONE.- 6 Hardening Plastic Stress Analysis.- 6.1 Introduction.- 6.2 Deformational Theory.- 6.3 Loading Surfaces and Loading Criteria.- 6.4 Flow Rules.- 6.5 Hardening Rules.- 6.6 Effective Stress and Effective Plastic Strain.- 6.7 Incremental Stress-Strain Relationships.- 6.8 Problems Using Incremental Theory.- 6.9 Problems Using Deformational Theory.

This book is designed for use as a supplement to the textbook "Plasticity for Structural Engineers" by W.F.Chen and D.J.Han The book is designed to help students and structural engineers learn how to solve typical engineering plasticity problems in general and, more importantly, how to use computers to solve plasticity problems in structural engineering in particular. To this end, specific numerical algorithms in the computer software implementation of the theory together with actual code development are given. A number of solved and supplementary problems are provided, as well as two computer-aided-education (CAE) programs, to enhance the students' understanding of these subjects. This supplement, reference manual on structural mechanics, fracture mechanics, and engineering mechanics is intended for structural and civil engineers, aeronautical, mechanical and materials engineers.

• One dimensional stress-strain analysis
• one-dimensional stress-strain analysis software
• elastic stress and strain analysis
• yield criteria
• perfectly plastic stress analysis
• hardening plastic stress analysis.