Description

Book Synopsis

Complex behavior models (plasticity, cracks, visco elascticity) face some theoretical difficulties for the determination of the behavior law at the continuous scale. When homogenization fails to give the right behavior law, a solution is to simulate the material at a meso scale in order to simulate directly a set of discrete properties that are responsible of the macroscopic behavior. The discrete element model has been developed for granular material. The proposed set shows how this method is capable to solve the problem of complex behavior that are linked to discrete meso scale effects.



Table of Contents

LIST OF FIGURES ix

LIST OF TABLES xv

PREFACE xvii

INTRODUCTION xxi

CHAPTER 1. STATE OF THE ART: DISCRETE ELEMENT MODELING 1

1.1. Introduction 1

1.2. Classification of discrete methods 3

1.2.1. Quantum mechanical methods 4

1.2.2. Atomistic methods 5

1.2.3. Mesoscopic discrete methods 8

1.3. Discrete element method for continuous materials 16

1.4. Discrete-continuum transition: macroscopic variables 17

1.4.1. Stress tensor for discrete systems 18

1.4.2. Strain tensor for discrete systems 21

1.5. Conclusion 31

CHAPTER 2. DISCRETE ELEMENT MODELING OF MECHANICAL BEHAVIOR OF CONTINUOUS MATERIALS 33

2.1. Introduction 33

2.2. Explicit dynamic algorithm 35

2.3. Construction of the discrete domain 37

2.3.1. The cooker compaction algorithm 39

2.3.2. Geometrical characterization of the discrete domain 44

2.4. Mechanical behavior modeling 56

2.4.1. Cohesive beam model 58

2.4.2. Calibration of the cohesive beam static parameters 64

2.4.3. Calibration of the cohesive beam dynamic parameters 79

2.5. Conclusion 87

CHAPTER 3. DISCRETE ELEMENT MODELING OF THERMAL BEHAVIOR OF CONTINUOUS MATERIALS 93

3.1. Introduction 93

3.2. General description of the method 95

3.2.1. Characterization of field variable variation in discrete domain 95

3.2.2. Application to heat conduction 96

3.3. Thermal conduction in 3D ordered discrete domains 97

3.4. Thermal conduction in 3D disordered discrete domains 100

3.4.1. Determination of local parameters for each discrete element 102

3.4.2. Calculation of discrete element transmission surface 103

3.4.3. Calculation of local volume fraction 104

3.4.4. Interactions between each discrete element and its neighbors 105

3.5. Validation 106

3.5.1. Cylindrical beam in contact with a hot plane 106

3.5.2. Dynamically heated sheet 107

3.6. Conclusion 113

CHAPTER 4. DISCRETE ELEMENT MODELING OF BRITTLE FRACTURE 115

4.1. Introduction 115

4.2. Fracture model based on the cohesive beam bonds 118

4.2.1. Fracture criterion 118

4.2.2. Calibration 120

4.2.3. Convergence study 123

4.2.4. Validation 125

4.3. Fracture model based on the virial stress 132

4.3.1. Fracture criterion 132

4.3.2. Calibration 134

4.3.3. Convergence study 134

4.3.4. Validation 136

4.4. Conclusion 137

CONCLUSION 141

BIBLIOGRAPHY 145

INDEX 161

Discrete Element Method to Model 3D Continuous

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    A Hardback by Mohamed Jebahi, Damien Andre, Inigo Terreros

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      Publisher: ISTE Ltd and John Wiley & Sons Inc
      Publication Date: 20/03/2015
      ISBN13: 9781848217706, 978-1848217706
      ISBN10: 1848217706
      Also in:
      Materials science

      Description

      Book Synopsis

      Complex behavior models (plasticity, cracks, visco elascticity) face some theoretical difficulties for the determination of the behavior law at the continuous scale. When homogenization fails to give the right behavior law, a solution is to simulate the material at a meso scale in order to simulate directly a set of discrete properties that are responsible of the macroscopic behavior. The discrete element model has been developed for granular material. The proposed set shows how this method is capable to solve the problem of complex behavior that are linked to discrete meso scale effects.



      Table of Contents

      LIST OF FIGURES ix

      LIST OF TABLES xv

      PREFACE xvii

      INTRODUCTION xxi

      CHAPTER 1. STATE OF THE ART: DISCRETE ELEMENT MODELING 1

      1.1. Introduction 1

      1.2. Classification of discrete methods 3

      1.2.1. Quantum mechanical methods 4

      1.2.2. Atomistic methods 5

      1.2.3. Mesoscopic discrete methods 8

      1.3. Discrete element method for continuous materials 16

      1.4. Discrete-continuum transition: macroscopic variables 17

      1.4.1. Stress tensor for discrete systems 18

      1.4.2. Strain tensor for discrete systems 21

      1.5. Conclusion 31

      CHAPTER 2. DISCRETE ELEMENT MODELING OF MECHANICAL BEHAVIOR OF CONTINUOUS MATERIALS 33

      2.1. Introduction 33

      2.2. Explicit dynamic algorithm 35

      2.3. Construction of the discrete domain 37

      2.3.1. The cooker compaction algorithm 39

      2.3.2. Geometrical characterization of the discrete domain 44

      2.4. Mechanical behavior modeling 56

      2.4.1. Cohesive beam model 58

      2.4.2. Calibration of the cohesive beam static parameters 64

      2.4.3. Calibration of the cohesive beam dynamic parameters 79

      2.5. Conclusion 87

      CHAPTER 3. DISCRETE ELEMENT MODELING OF THERMAL BEHAVIOR OF CONTINUOUS MATERIALS 93

      3.1. Introduction 93

      3.2. General description of the method 95

      3.2.1. Characterization of field variable variation in discrete domain 95

      3.2.2. Application to heat conduction 96

      3.3. Thermal conduction in 3D ordered discrete domains 97

      3.4. Thermal conduction in 3D disordered discrete domains 100

      3.4.1. Determination of local parameters for each discrete element 102

      3.4.2. Calculation of discrete element transmission surface 103

      3.4.3. Calculation of local volume fraction 104

      3.4.4. Interactions between each discrete element and its neighbors 105

      3.5. Validation 106

      3.5.1. Cylindrical beam in contact with a hot plane 106

      3.5.2. Dynamically heated sheet 107

      3.6. Conclusion 113

      CHAPTER 4. DISCRETE ELEMENT MODELING OF BRITTLE FRACTURE 115

      4.1. Introduction 115

      4.2. Fracture model based on the cohesive beam bonds 118

      4.2.1. Fracture criterion 118

      4.2.2. Calibration 120

      4.2.3. Convergence study 123

      4.2.4. Validation 125

      4.3. Fracture model based on the virial stress 132

      4.3.1. Fracture criterion 132

      4.3.2. Calibration 134

      4.3.3. Convergence study 134

      4.3.4. Validation 136

      4.4. Conclusion 137

      CONCLUSION 141

      BIBLIOGRAPHY 145

      INDEX 161

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