Mechanics of materials in modern manufacturing methods and processing techniques / edited by Vadim V. Silberschmidt.

Format:

Book

Contributor:

Silberschmidt, Vadim V.

ScienceDirect (Online service)

Series:

Elsevier series in mechanics of advanced materials.

Elsevier series in mechanics of advanced materials

Language:

English

Subjects (All):

Materials--Mechanical properties.

Materials.

Physical Description:

1 online resource.

Place of Publication:

Amsterdam : Elsevier, 2020.

System Details:

text file

Contents:

Front Cover

Mechanics of Materials in Modern Manufacturing Methods and Processing Techniques

Copyright Page

Contents

List of contributors

About the Series editors

1 Modeling of metal forming: a review

1.1 Introduction

1.2 Modeling issues in various metal forming processes

1.2.1 Forging

1.2.2 Rolling

1.2.3 Wire drawing

1.2.4 Extrusion

1.2.5 Deep drawing

1.2.6 Bending

1.3 Various modeling techniques

1.3.1 Slab method

1.3.2 Slip-line field method

1.3.3 Visioplasticity

1.3.4 Upper bound method

1.3.5 Finite difference method

1.3.6 Finite element method

1.3.7 Meshless method

1.3.8 Molecular dynamics simulation

1.3.9 Soft computing

1.4 Inverse modeling

1.5 Modeling of microstructure and surface integrity

1.6 A note on multiscale modeling of metal forming

1.7 Challenging issues

1.8 Conclusion

References

2 Finite element method modeling of hydraulic and thermal autofrettage processes

2.1 Introduction

2.1.1 Hydraulic autofrettage

2.1.2 Swage autofrettage

2.1.3 Explosive autofrettage

2.1.4 Thermal autofrettage

2.1.5 Rotational autofrettage

2.2 Numerical modeling of elastic-plastic problems

2.2.1 Yield criteria and hardening behavior of the material

2.2.1.1 The von Mises yield criterion

2.2.1.2 Tresca yield criterion

2.2.2 Approaches for numerical modeling of elastic-plastic problems

2.3 FEM formulation using updated Lagrangian method

2.3.1 Derivation of the weak form of the equilibrium equation

2.3.2 Formulation of elemental equations

2.3.3 Solution method

2.4 Typical results of FEM modeling of hydraulic and thermal autofrettage

2.4.1 Results of hydraulic autofrettage

2.4.1.1 Results for plane stress condition of hydraulic autofrettage

2.4.1.2 Results for plane strain end condition of hydraulic autofrettage

2.4.2 Results of thermal autofrettage

2.4.2.1 Results for plane stress end condition of thermal autofrettage

2.4.2.2 Results for open-ended condition of thermal autofrettage

2.5 Conclusion

3 Mechanics of hydroforming

3.1 Introduction

3.2 Modeling of plastic deformation in tube hydroforming

3.2.1 Rotationally symmetrical tube expansion

3.2.2 Hydroforming of polygonal cross sections

3.2.3 Hydroforming of tube branches

3.3 Determination of forming limits in tube hydroforming

3.3.1 Necking and bursting

3.3.2 Wrinkling and buckling

3.4 Design of loading paths

3.5 Conclusion

4 Electromagnetic pulse forming

4.1 Process classification

4.2 Process principle and major process variants

4.2.1 General setup and process principle

4.2.2 Major process variants

4.2.2.1 Electromagnetic pulse compression

4.2.2.2 Electromagnetic pulse expansion

4.2.2.3 Electromagnetic pulse forming of flat and preformed sheet metal

Notes:

Includes index.

Electronic reproduction. Amsterdam Available via World Wide Web.

ISBN:

9780128182338

0128182334

Publisher Number:

99987369572

Access Restriction:

Restricted for use by site license.