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## Details

Document Type: | Book |
---|---|

All Authors / Contributors: |
Mehrdad Negahban |

ISBN: | 9780849372308 0849372305 |

OCLC Number: | 795123509 |

Notes: | Includes index. |

Description: | xxiv, 759 pages : illustrations ; 26 cm |

Contents: | Plasticity In The 1-D BarIntroduction to Plastic Response The Bar and The Continuum Assumption Motion and Temperature of Points on a Bar Stretch Ratio, Strain, Velocity Gradient, Temperature Gradient Superposition of Deformations Elastic, Plastic, and Thermal Strains Examples of Constitutive Models Mechanical Theory of Rate-Independent PlasticityMechanical Models for Plasticity Temperature-Dependent Plasticity An Infinitesimal Theory of Thermoplasticity Rate-Dependent Models for Plasticity Load Control as Opposed to Strain Control Numerical Integration of Constitutive Equations The Balance Laws Thermodynamic Restrictions on Constitutive Equations Heat Generation and Flow Equilibrium and Quasi-Equilibrium Problems Dynamic Loading Problems: Numerical SolutionDealing with Discontinuities: Jump Conditions Plastic Drawing of Bars Elastic and Plastic (Shock) Waves in a Bar General Comment on Selection of Moduli Notation and Summary Vectors and Tensors Matrix algebra Vectors Tensors Tensor calculus Notation Describing Motion, Deformation and Temperature Position, Velocity, Acceleration And Temperature Configurations of Material Bodies Streamlines and Pathlines Deformation Gradient and Temperature Gradient Stretch and Strain TensorsVelocity Gradient Relative Deformation Triaxial Extension, Simple Shear, Bending and Torsion Small Deformations Notation Elastic, Plastic And Thermal DeformationElastic and Plastic Deformation Gradients Elastic and Plastic Strains Elastic and Plastic Velocity Gradients Infinitesimal Elastic and Plastic Deformations Large Rigid Body Rotations Thermal Deformation and Thermal Strain Notation Traction, Stress and Heat Flux The Traction Vector The Relation between Tractions on Different SurfacesThe Stress Tensor Isotropic Invariants and the Deviatoric Stress Examples of Elementary States of Stress True Stress as Opposed to Engineering Stress The Piola-Kirchhoff, Rotated and Convected Stresses Heat Flux Notation Balance Laws and Jump ConditionsIntroduction Transport Relations Conservation of Mass Balance of Linear Momentum Balance of Angular Momentum Balance of Work snd Energy Entropy and the Entropy Production Inequality Heat Flow and Thermodynamic Processes Infinitesimal Deformations The Generalized Balance Law Jump Conditions Perturbing a Motion Initial and Boundary Conditions Notation Infinitesimal Plasticity A Mechanical Analog for Plasticity Elastic Perfectly-Plastic Response Common Assumptions Von Mises Yield Function with Combined Isotropic and Kinematic Hardening Thermoplasticity Free-Energy of Quadratic Form Scalar Stress and Hardening Functions Multiple Elements in Parallel Multiple Elements in Series Rate-Dependent Plasticity Deformation Plasticity Notation Solutions for Infinitesimal PlasticityHomogeneous Deformations Torsion-Extension of a Thin Circular Cylindrical Tube Compression in Plane Strain Bending Torsion of Circular Members Unloading Torsion of Prismatic Sections Non-Uniform Loading of Bars Cylindrical and Spherical Symmetry Two-Dimensional Problems Heat and Its Generation First-Gradient Thermo-Mechanical Materials First-Gradient Theories Superposition of Pure Translations Superposition of Rigid Body Rotations Material Symmetry First-Gradient State Variable Models Higher Gradient and Non-Local Models Notation Elastic And Thermoelastic Solids The Thermoelastic Solid The Influence of Pure Rigid-Body Translation on the Constitutive Response The Influence of Pure Rigid-Body Rotation on the Constitutive Response Material Symmetry Change of Reference Configuration A Thermodynamically Consistent Model Models Based on Fe And FÓ¨ Specific Free-Energy of Quadratic Form in Strain Heat Generation and Heat Capacity Material Constraints Multiple Material Constraints Superposition of Deformations Notation Finite Deformation Mechanical Theory of Plasticity General Mechanical Theory of Plasticity Rigid Body Motions Material Symmetry Stress Depending Only on Elastic Deformation GradientStress Depending on both Elastic Deformation and Plastic Strain General Comments Deformation Plasticity Notation Thermoplastic Solids A Simple Thermo-Mechanical Analog Thermoplasticity Thermodynamic Constraint Isotropic Examples with J2 Type Yield Functions Superposition of Rigid Body Motions Material Symmetry An Initially Isotropic Material Models Depending on Cp Heat Generation and Heat Flow Specific Free-Energy of Quadratic Form in StrainPlasticity Models Based on Green Strains Heat Flux Vector Material Constraints Models Based on F = FefÓ©fp Notation Viscoelastic Solids One-Dimensional Linear Viscoelasticity One-Dimensional Nonlinear Viscoelasticity Three-Dimensional Linear Viscoelasticity A One-Element Thermo-Viscoelastic Model Multi-Element Thermodynamic Viscoelastic Model Initially Isotropic Models: Free-Energy and Thermodynamic Stresses Quasi-Linear Viscoelastic Model Material Constraints Models Based on F = FefÓ©fve Notation Rate-Dependent Plasticity Infinitesimal Mechanical and Thermo-Mechanical Models with Viscoplastic Flow Nonlinear Thermoelastic-Viscoplastic Model Single-Element Viscoelastic-Viscoplastic Full Viscoelastic-Viscoplastic Model Material Constraints Models Based on F = FefÓ©fvp Notation Crystal plasticity Crystal Structures and Slip Systems Elastic Crystal Distortion Kinematics of Single-Crystal Deformation Resolved Shear Stress and Overstress Yield Function Thermo-Mechanical Models Rate-Dependent Models Notation A Representation of functions Isotropic Transversely Isotropic Orthotropic B Representation for fourth order constants Isotropic Transversely Isotropic Crystal Classes C Basic Equations Basic Equations Curvilinear Coordinates Rectangular Coordinates Cylindrical Coordinates Spherical Coordinates Index |

Responsibility: | Mehrdad Negahban. |

## Reviews

*Editorial reviews*

Publisher Synopsis

"an excellent text for a graduate-level course in plasticity...the approach and selection of topics are appropriate for the audience. ... Professor Negahban has done an excellent job in presenting a unified approach to include thermal effects in the theory of finite deformation of plastic solids. The simple thermo-mechanical analog presented at the beginning of the chapter is also very instructive to the reader. {presented figures are] particularly helpful in understanding the mechanisms in a simple (one-dimensional) setting ... The learning features included in this chapter are excellent (the figures are clear and illustrative). The table of contents is well-balanced and very clear...The in-depth and unified approach to many topics discussed in the text (e.g., thermoplasticity under finite deformation) is of particular interest..."-Ken Zuo, University of Alabama in Huntsville, USA"... takes a modern, in depth approach to the subject of thermoplasticity. The chapters are written to be somewhat self-contained. .... can be adapted to satisfy a variety of courses and subjects. The author has done an admirable job of pointing out how the text would satisfy these competing requirements."-Ronald E. Smelser, The University of North Carolina at Charlotte, USA Read more...

*User-contributed reviews*