Multiscale modelling in sheet metal forming. ([2016])
- Record Type:
- Book
- Title:
- Multiscale modelling in sheet metal forming. ([2016])
- Main Title:
- Multiscale modelling in sheet metal forming
- Further Information:
- Note: Dorel Banabic, editor.
- Editors:
- Banabic, D (Dorel)
- Contents:
- Preface; Contents; Contributors; 1 Plastic Behaviour of Sheet Metals; 1.1 Anisotropy of Sheet Metals; 1.1.1 Uniaxial Characteristics of Plastic Anisotropy; 1.1.2 Biaxial Characteristics of Plastic Anisotropy; 1.2 Classical Yield Criteria for Anisotropic Sheet Metals; 1.2.1 Hill (1948) Yield Criterion; 1.2.2 Barlat (1989) Yield Criterion; 1.3 BBC (2005) Yield Criterion; 1.3.1 Equation of the Yield Surface; 1.3.2 Flow Rule Associated to the Yield Surface; 1.3.3 BBC (2005) Equivalent Stress; 1.3.4 Identification Procedure; 1.3.5 Theoretical Yield Stress in Pure Tension 1.3.6 Theoretical Coefficient of Uniaxial Plastic Anisotropy1.3.7 Theoretical Yield Stress in Biaxial Tension Along RD and TD; 1.3.8 Theoretical Coefficient of Biaxial Plastic Anisotropy; 1.3.9 Identification Constraints; 1.3.10 Particular Formulations of the BBC (2005) Yield Criterion; 1.4 BBC (2008) Yield Criterion; 1.4.1 BBC 2008 Equivalent Stress; 1.4.2 Basic Identification Procedure; 1.4.3 Enhanced Identification Procedure; 1.5 3D Extensions of the BBC (2005, 2008) Yield Criteria; 1.6 Advanced Anisotropic Yield Criteria; 1.6.1 Barlat Yield Criteria; 1.6.2 Cazacu-Barlat Yield Criteria 1.6.3 Vegter Yield Criterion1.7 Recommendations on the Choice of the Yield Criteria; 1.8 Perspectives; References; 2 Crystallographic Texture and Plastic Anisotropy; 2.1 The Structure of Polycrystalline Materials; 2.2 Definition of Crystallographic Texture; 2.2.1 Crystal Orientation; 2.3 Experimental Determination of Textures;Preface; Contents; Contributors; 1 Plastic Behaviour of Sheet Metals; 1.1 Anisotropy of Sheet Metals; 1.1.1 Uniaxial Characteristics of Plastic Anisotropy; 1.1.2 Biaxial Characteristics of Plastic Anisotropy; 1.2 Classical Yield Criteria for Anisotropic Sheet Metals; 1.2.1 Hill (1948) Yield Criterion; 1.2.2 Barlat (1989) Yield Criterion; 1.3 BBC (2005) Yield Criterion; 1.3.1 Equation of the Yield Surface; 1.3.2 Flow Rule Associated to the Yield Surface; 1.3.3 BBC (2005) Equivalent Stress; 1.3.4 Identification Procedure; 1.3.5 Theoretical Yield Stress in Pure Tension 1.3.6 Theoretical Coefficient of Uniaxial Plastic Anisotropy1.3.7 Theoretical Yield Stress in Biaxial Tension Along RD and TD; 1.3.8 Theoretical Coefficient of Biaxial Plastic Anisotropy; 1.3.9 Identification Constraints; 1.3.10 Particular Formulations of the BBC (2005) Yield Criterion; 1.4 BBC (2008) Yield Criterion; 1.4.1 BBC 2008 Equivalent Stress; 1.4.2 Basic Identification Procedure; 1.4.3 Enhanced Identification Procedure; 1.5 3D Extensions of the BBC (2005, 2008) Yield Criteria; 1.6 Advanced Anisotropic Yield Criteria; 1.6.1 Barlat Yield Criteria; 1.6.2 Cazacu-Barlat Yield Criteria 1.6.3 Vegter Yield Criterion1.7 Recommendations on the Choice of the Yield Criteria; 1.8 Perspectives; References; 2 Crystallographic Texture and Plastic Anisotropy; 2.1 The Structure of Polycrystalline Materials; 2.2 Definition of Crystallographic Texture; 2.2.1 Crystal Orientation; 2.3 Experimental Determination of Textures; 2.4 Texture and Properties of Materials; 2.5 Plasticity of Polycrystalline Materials; 2.5.1 The Taylor Model (Full-Constraints); 2.5.2 Special Plasticity Parameters; 2.5.3 Plasticity of Cubic Metals; 2.5.4 Deformation Hardening; 2.5.5 Plasticity of Macroscopic Bodies 2.6 Parameterization of the Texture Function2.7 Other Modes of Plasticity; References; 3 Multiscale Modelling of Mechanical Anisotropy; 3.1 Introduction; 3.2 Multiscale Frameworks in Crystal Plasticity; 3.2.1 Statistical Crystal Plasticity; 3.2.1.1 Sachs-Type Models; 3.2.1.2 Taylor-Type Models; 3.2.1.3 Grain Interaction Models; 3.2.1.4 Self-consistent Schemes; 3.2.2 Full-Field Approaches; 3.2.2.1 Crystal Plasticity Finite Element Method; 3.2.2.2 Crystal Plasticity FFT; 3.3 Multi-scale Modelling of Plastic Anisotropy; 3.3.1 Direct Micro-Macro Coupling; 3.3.1.1 Embedded Full-Field Models 3.3.1.2 Embedded Mean-Field Models3.3.1.3 Embedded Reduced Texture Models; 3.3.2 Hierarchical Coupling; 3.3.2.1 Database and Sampling Techniques; 3.3.2.2 Spectral Crystal Plasticity (SCP); 3.3.3 Yield Criteria Based on Crystal Plasticity; 3.3.3.1 Yield Criteria Defined by Interpolation; 3.3.3.2 Yield Criteria Defined by Approximation; 3.3.3.3 Evolving BBC2008 Yield Criterion; 3.3.4 Other Concepts in Multi-scale Modelling of Plastic Anisotropy; Acknowledgments; References; 4 Modelling the Voids Growth in Ductile Fracture; 4.1 Models for Ductile Fracture; 4.1.1 Void Shape Effects … (more)
- Publisher Details:
- Switzerland : Springer
- Publication Date:
- 2016
- Extent:
- 1 online resource (xi, 405 pages)
- Subjects:
- 620.1/66
Engineering
Sheet-metal -- Mathematical models
Sheet-metal work
Multiscale modeling
TECHNOLOGY & ENGINEERING / Engineering (General)
TECHNOLOGY & ENGINEERING / Reference
Multiscale modeling
Sheet-metal work
Technology & Engineering -- Material Science
Technology & Engineering -- Nanotechnology & MEMS
Testing of materials
Precision instruments manufacture
Manufactures
Surfaces (Physics)
Technology & Engineering -- Manufacturing
Production engineering
Electronic books - Languages:
- English
- ISBNs:
- 9783319440705
3319440705 - Related ISBNs:
- 9783319440682
3319440683 - Notes:
- Note: Includes bibliographical references and index.
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- British Library HMNTS - ELD.DS.363736
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