Zhaochun Yang
Material Modeling in Finite Element Analysis (eBook, PDF)
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Zhaochun Yang
Material Modeling in Finite Element Analysis (eBook, PDF)
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This book introduces how to model different materials. It consists of four main parts: 1) metals, 2) elastomers, 3) soils, and 4) modern materials. Each part starts with the structure and function of different materials and then follows the corresponding material models. All modeling files are provided in the appendixes of the book.
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This book introduces how to model different materials. It consists of four main parts: 1) metals, 2) elastomers, 3) soils, and 4) modern materials. Each part starts with the structure and function of different materials and then follows the corresponding material models. All modeling files are provided in the appendixes of the book.
Dieser Download kann aus rechtlichen Gründen nur mit Rechnungsadresse in A, B, BG, CY, CZ, D, DK, EW, E, FIN, F, GR, HR, H, IRL, I, LT, L, LR, M, NL, PL, P, R, S, SLO, SK ausgeliefert werden.
Produktdetails
- Produktdetails
- Verlag: Taylor & Francis
- Seitenzahl: 326
- Erscheinungstermin: 10. Oktober 2019
- Englisch
- ISBN-13: 9781000690712
- Artikelnr.: 57899029
- Verlag: Taylor & Francis
- Seitenzahl: 326
- Erscheinungstermin: 10. Oktober 2019
- Englisch
- ISBN-13: 9781000690712
- Artikelnr.: 57899029
Z. Yang received his PhD in Mechanical Engineering from the University of Pittsburgh in 2004. Since 2005, he has worked for big companies and national labs like Nation Energy Technology Laboratory. He has been in the field of finite element analysis over 18 years and gained much experience, especially in material modeling. Up to now, he has published twelve journal papers. In 2019, CRC Press published his first book "Finite Element Analysis for Biomedical Engineering Applications."
Part I METALS. 2. Structure and Material Properties of Metals. 3. Some
Plastic Material Models of Metals and Definition of Their Parameters. 4.
Simulation of Metal Forming. 5. Simulation of Ratcheting. 6. Influence of
Temperature on Material Properties. 7. Simulation of Creep. Part II
POLYMERS. 8. Structure and Material Features of Polymers. 9.
Hyperelasticity. 10. Viscoelasticity of Polymers. 11. Mullins Effect. 12.
Usermat for Hyperelsastic Materials. Part III SOILS. 13. Soil Introduction.
14. Cam Clay Model. 15. Drucker-Prager Model. 16. Mohr-Coulomb Model. 17.
Jointed Rock Model. 18. Consolidation of Soils. Part IV MODERN MATERIALS.
19. Composite Materials. 20. Functionally Graded Materials. 21. Shape
Memory Alloys. 22. Simulation of Piezoelectricity. 23. Nanomaterials. Part
V RETROSPECTIVE. 24. Retrospective. APPENDICES 1 Input file of
curve-fitting of the Chaboche model in Section 3.3. 2. Input file of the
forming process model in Section 4.2. 3. Input file of the ratcheting model
in Section 5.2. 4. Input file of the combustion chamber model in Section
6.2. 5. Input file of the bolt model under pretension in Section 7.2. 6.
Input file of curve-fitting of the Ogden model in Section 9.3. 7. Input
file of the rubber rod model under compression in Section 9.4. 8. Input
file of the liver soft tissue model in Section 10.4. 9. Input file of the
rubber tire damage model in section 11.3. 10. Input file of UserHyper in
Section 12.2. 11. Input file of the tower subsidence model in Section 14.3.
12 Input file of the soil-arch interaction model in Section 15.2. 13 Input
file of the slope stability model in Section 16.3. 14 Input file of the
tunnel excavation model in Section 17.3. 15 Input file of the settlement
model in Section 18.3. 16 Input file of the composite damage model in
Section 19.3. 17 Input file of the SLB model in Section 19.4. 18 Input file
of the spur gear model with FGM in Section 20.3. 19 Input file of the
orthodontic wire model in Section 21.2. 20 Input file of the vacuum tight
shape memory flange model in Section 21.3. 21 Input file of the
piezoelectric microaccelerometer model in Section 22.4. 22 Input file of
the contact model in Section 23.2.
Plastic Material Models of Metals and Definition of Their Parameters. 4.
Simulation of Metal Forming. 5. Simulation of Ratcheting. 6. Influence of
Temperature on Material Properties. 7. Simulation of Creep. Part II
POLYMERS. 8. Structure and Material Features of Polymers. 9.
Hyperelasticity. 10. Viscoelasticity of Polymers. 11. Mullins Effect. 12.
Usermat for Hyperelsastic Materials. Part III SOILS. 13. Soil Introduction.
14. Cam Clay Model. 15. Drucker-Prager Model. 16. Mohr-Coulomb Model. 17.
Jointed Rock Model. 18. Consolidation of Soils. Part IV MODERN MATERIALS.
19. Composite Materials. 20. Functionally Graded Materials. 21. Shape
Memory Alloys. 22. Simulation of Piezoelectricity. 23. Nanomaterials. Part
V RETROSPECTIVE. 24. Retrospective. APPENDICES 1 Input file of
curve-fitting of the Chaboche model in Section 3.3. 2. Input file of the
forming process model in Section 4.2. 3. Input file of the ratcheting model
in Section 5.2. 4. Input file of the combustion chamber model in Section
6.2. 5. Input file of the bolt model under pretension in Section 7.2. 6.
Input file of curve-fitting of the Ogden model in Section 9.3. 7. Input
file of the rubber rod model under compression in Section 9.4. 8. Input
file of the liver soft tissue model in Section 10.4. 9. Input file of the
rubber tire damage model in section 11.3. 10. Input file of UserHyper in
Section 12.2. 11. Input file of the tower subsidence model in Section 14.3.
12 Input file of the soil-arch interaction model in Section 15.2. 13 Input
file of the slope stability model in Section 16.3. 14 Input file of the
tunnel excavation model in Section 17.3. 15 Input file of the settlement
model in Section 18.3. 16 Input file of the composite damage model in
Section 19.3. 17 Input file of the SLB model in Section 19.4. 18 Input file
of the spur gear model with FGM in Section 20.3. 19 Input file of the
orthodontic wire model in Section 21.2. 20 Input file of the vacuum tight
shape memory flange model in Section 21.3. 21 Input file of the
piezoelectric microaccelerometer model in Section 22.4. 22 Input file of
the contact model in Section 23.2.
Part I METALS. 2. Structure and Material Properties of Metals. 3. Some
Plastic Material Models of Metals and Definition of Their Parameters. 4.
Simulation of Metal Forming. 5. Simulation of Ratcheting. 6. Influence of
Temperature on Material Properties. 7. Simulation of Creep. Part II
POLYMERS. 8. Structure and Material Features of Polymers. 9.
Hyperelasticity. 10. Viscoelasticity of Polymers. 11. Mullins Effect. 12.
Usermat for Hyperelsastic Materials. Part III SOILS. 13. Soil Introduction.
14. Cam Clay Model. 15. Drucker-Prager Model. 16. Mohr-Coulomb Model. 17.
Jointed Rock Model. 18. Consolidation of Soils. Part IV MODERN MATERIALS.
19. Composite Materials. 20. Functionally Graded Materials. 21. Shape
Memory Alloys. 22. Simulation of Piezoelectricity. 23. Nanomaterials. Part
V RETROSPECTIVE. 24. Retrospective. APPENDICES 1 Input file of
curve-fitting of the Chaboche model in Section 3.3. 2. Input file of the
forming process model in Section 4.2. 3. Input file of the ratcheting model
in Section 5.2. 4. Input file of the combustion chamber model in Section
6.2. 5. Input file of the bolt model under pretension in Section 7.2. 6.
Input file of curve-fitting of the Ogden model in Section 9.3. 7. Input
file of the rubber rod model under compression in Section 9.4. 8. Input
file of the liver soft tissue model in Section 10.4. 9. Input file of the
rubber tire damage model in section 11.3. 10. Input file of UserHyper in
Section 12.2. 11. Input file of the tower subsidence model in Section 14.3.
12 Input file of the soil-arch interaction model in Section 15.2. 13 Input
file of the slope stability model in Section 16.3. 14 Input file of the
tunnel excavation model in Section 17.3. 15 Input file of the settlement
model in Section 18.3. 16 Input file of the composite damage model in
Section 19.3. 17 Input file of the SLB model in Section 19.4. 18 Input file
of the spur gear model with FGM in Section 20.3. 19 Input file of the
orthodontic wire model in Section 21.2. 20 Input file of the vacuum tight
shape memory flange model in Section 21.3. 21 Input file of the
piezoelectric microaccelerometer model in Section 22.4. 22 Input file of
the contact model in Section 23.2.
Plastic Material Models of Metals and Definition of Their Parameters. 4.
Simulation of Metal Forming. 5. Simulation of Ratcheting. 6. Influence of
Temperature on Material Properties. 7. Simulation of Creep. Part II
POLYMERS. 8. Structure and Material Features of Polymers. 9.
Hyperelasticity. 10. Viscoelasticity of Polymers. 11. Mullins Effect. 12.
Usermat for Hyperelsastic Materials. Part III SOILS. 13. Soil Introduction.
14. Cam Clay Model. 15. Drucker-Prager Model. 16. Mohr-Coulomb Model. 17.
Jointed Rock Model. 18. Consolidation of Soils. Part IV MODERN MATERIALS.
19. Composite Materials. 20. Functionally Graded Materials. 21. Shape
Memory Alloys. 22. Simulation of Piezoelectricity. 23. Nanomaterials. Part
V RETROSPECTIVE. 24. Retrospective. APPENDICES 1 Input file of
curve-fitting of the Chaboche model in Section 3.3. 2. Input file of the
forming process model in Section 4.2. 3. Input file of the ratcheting model
in Section 5.2. 4. Input file of the combustion chamber model in Section
6.2. 5. Input file of the bolt model under pretension in Section 7.2. 6.
Input file of curve-fitting of the Ogden model in Section 9.3. 7. Input
file of the rubber rod model under compression in Section 9.4. 8. Input
file of the liver soft tissue model in Section 10.4. 9. Input file of the
rubber tire damage model in section 11.3. 10. Input file of UserHyper in
Section 12.2. 11. Input file of the tower subsidence model in Section 14.3.
12 Input file of the soil-arch interaction model in Section 15.2. 13 Input
file of the slope stability model in Section 16.3. 14 Input file of the
tunnel excavation model in Section 17.3. 15 Input file of the settlement
model in Section 18.3. 16 Input file of the composite damage model in
Section 19.3. 17 Input file of the SLB model in Section 19.4. 18 Input file
of the spur gear model with FGM in Section 20.3. 19 Input file of the
orthodontic wire model in Section 21.2. 20 Input file of the vacuum tight
shape memory flange model in Section 21.3. 21 Input file of the
piezoelectric microaccelerometer model in Section 22.4. 22 Input file of
the contact model in Section 23.2.