Natural Element Method for the Simulation of Structures and Processes

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Klappentext Computational mechanics is the discipline concerned with the use of computational methods to study phenomena governed by the principles of mechanics. Before the emergence of computational science (also called scientific computing) as a "third way" besides theoretical and experimental sciences, computational mechanics was widely considered to be a sub-discipline of applied mechanics. It is now considered to be a sub-discipline within computational science.This book presents a recent state of the art on the foundations and applications of the meshless natural element method in computational mechanics, including structural mechanics and material forming processes involving solids and Newtonian and non-Newtonian fluids. Zusammenfassung Computational mechanics is the discipline concerned with the use of computational methods to study phenomena governed by the principles of mechanics. Before the emergence of computational science (also called scientific computing) as a "third way" besides theoretical and experimental sciences, computational mechanics was widely considered to be a sub-discipline of applied mechanics. It is now considered to be a sub-discipline within computational science.This book presents a recent state of the art on the foundations and applications of the meshless natural element method in computational mechanics, including structural mechanics and material forming processes involving solids and Newtonian and non-Newtonian fluids. Inhaltsverzeichnis Foreword ix Acknowledgements xi Chapter 1. Introduction 1 1.1. SPH method 3 1.2. RKPM method 5 1.3. MLS based approximations 10 1.4. Final note 11 Chapter 2. Basics of the Natural Element Method 13 2.1. Introduction 13 2.2. Natural neighbor Galerkin methods 14 2.3. Exact imposition of the essential boundary conditions 22 2.4. Mixed approximations of natural neighbor type 27 2.5. High order natural neighbor interpolants 40 Chapter 3. Numerical Aspects 49 3.1. Searching for natural neighbors 49 3.2. Calculation of NEM shape functions of the Sibson type 52 3.3. Numerical integration 71 3.4. NEM on an octree structure 80 Chapter 4. Applications in the Mechanics of Structures and Processes 93 4.1. Two- and three-dimensional elasticity 93 4.2. Indicators and estimators of error: adaptivity 96 4.3. Metal extrusion 107 4.4. Friction stir welding 113 4.5. Models and numerical treatment of the phase transition: foundry and treatment of surfaces 123 4.6. Adiabatic shearing! cutting! and high speed blanking 136 Chapter 5. A Mixed Approach to the Natural Elements 159 5.1. Introduction 159 5.2. The Fraeijs de Veubeke variational principle for linear elastic problems 161 5.3. Field decomposition 164 5.4. Discretization 166 5.5. Discretized equations 170 5.6. Matrix solution for linear elastic problems 172 5.7. Numerical integration 176 5.8. Linear elastic patch tests 178 5.9. Application 1: pure bending of a linear elastic beam 182 5.10. Application 2: square domain with circular hole 185 5.11. Mixed approach to nonlinear problems 187 5.12. Step-by-step solution of the discretized nonlinear equations 192 5.13. Example of an elastoplastic material 195 5.14. Application: pure bending of an elastoplastic beam 196 5.15. Conclusion 199 Chapter 6. Flow Models 201 6.1. Natural element method in fluid mechanics: updated Lagrangian approach 201 6.2. Free and moving surfaces 202 6.3. Short-fiber suspensions flow 206 6.4. Breaking dam problem 208 6.5. Multi-scale approaches 209 Chapter 7. Conclusion 225 Bibliography 227 Index 239 ...

List of contents

Foreword ix

Acknowledgements xi

Chapter 1. Introduction 1

1.1. SPH method 3

1.2. RKPM method 5

1.3. MLS based approximations 10

1.4. Final note 11

Chapter 2. Basics of the Natural Element Method 13

2.1. Introduction 13

2.2. Natural neighbor Galerkin methods 14

2.3. Exact imposition of the essential boundary conditions 22

2.4. Mixed approximations of natural neighbor type 27

2.5. High order natural neighbor interpolants 40

Chapter 3. Numerical Aspects 49

3.1. Searching for natural neighbors 49

3.2. Calculation of NEM shape functions of the Sibson type 52

3.3. Numerical integration 71

3.4. NEM on an octree structure 80

Chapter 4. Applications in the Mechanics of Structures and Processes 93

4.1. Two- and three-dimensional elasticity 93

4.2. Indicators and estimators of error: adaptivity 96

4.3. Metal extrusion 107

4.4. Friction stir welding 113

4.5. Models and numerical treatment of the phase transition: foundry and treatment of surfaces 123

4.6. Adiabatic shearing, cutting, and high speed blanking 136

Chapter 5. A Mixed Approach to the Natural Elements 159

5.1. Introduction 159

5.2. The Fraeijs de Veubeke variational principle for linear elastic problems 161

5.3. Field decomposition 164

5.4. Discretization 166

5.5. Discretized equations 170

5.6. Matrix solution for linear elastic problems 172

5.7. Numerical integration 176

5.8. Linear elastic patch tests 178

5.9. Application 1: pure bending of a linear elastic beam 182

5.10. Application 2: square domain with circular hole 185

5.11. Mixed approach to nonlinear problems 187

5.12. Step-by-step solution of the discretized nonlinear equations 192

5.13. Example of an elastoplastic material 195

5.14. Application: pure bending of an elastoplastic beam 196

5.15. Conclusion 199

Chapter 6. Flow Models 201

6.1. Natural element method in fluid mechanics: updated Lagrangian approach 201

6.2. Free and moving surfaces 202

6.3. Short-fiber suspensions flow 206

6.4. Breaking dam problem 208

6.5. Multi-scale approaches 209

Chapter 7. Conclusion 225

Bibliography 227

Index 239

About the author

Francisco Chinesta, born in 1966 in Valencia (Spain), obtained his M.S. in Mechanical Engineering (1990) and later his Ph.D. degree supervised at the ENS Cachan in France. He is currently Professor of Computational Mechanics at the Ecole Centrale of Nantes (France) and titular of the EADS Corporate Foundation International Chair on Advanced Modeling of Composites Manufacturing Processes.

Summary

Computational mechanics is the discipline concerned with the use of computational methods to study phenomena governed by the principles of mechanics. Before the emergence of computational science as a "third way" besides theoretical and experimental sciences, computational mechanics was widely considered to be a sub-discipline of applied mechanics.