Practical micromechanics of composite materials / Jacob Aboudi, Steven M. Arnold, Brett A. Bednarcyk.

Format:

Book

Author/Creator:

Aboudi, Jacob, 1935- author.

Arnold, S. M., author.

Bednarcyk, Brett A., author.

Language:

English

Subjects (All):

Composite materials--Mechanical properties.

Composite materials.

Micromechanics--Mathematics.

Micromechanics.

Mathematics.

Physical Description:

xiv, 400 pages : illustrations (some color) ; 23 cm

Place of Publication:

Oxford, United Kingdom : Butterworth-Heinemann, 2021.

Contents:

Machine generated contents note: 1. Introduction

1.1. Introduction

1.2. Fundamentals of composite materials and structures

1.3. Modeling of composites

1.4. MATLAB code

1.5. Description of the book layout

1.6. Suggestions of how to use the book

References

2. Lamination theory using macromechanics

2.1. Introduction

2.2. Linear thermoelastic behavior

2.3. Lamination theory

2.4. MATLAB implementation of classical lamination theory

2.5. Laminate example problems

2.6. Laminate notation and classification

2.7. Summary

2.8. Exercises

3. Closed form micromechanics

3.1. Introduction

3.2. Fundamentals of the mechanics of multiphase materials

3.3. Strain and stress concentration tensors for two-phase composites

3.4. The Voigt approximation

3.5. The Reuss approximation

3.6. Eshelby equivalent inclusion method: the dilute case

3.7. The Mori-Tanaka (MT) method

3.8. The method of cells for continuously fiber-reinforced materials (doubly periodic)

3.9. Thermomechanical effects

3.10. Numerical methods

3.11. MATLAB implementation of stand-alone micromechanics and micromechanics-based CLT

3.12. Example micromechanics problems

3.13. Summary

3.14. Exercises

3.15. Appendix: Establishment of Eq. (3.88)

4. Failure criteria and margins of safety

4.1. Failure criteria

4.2. Margins of safety (MoS)

4.3. MATLAB implementation of margins of safety calculation

4.4. Examples problems

4.5. Summary

4.6. Exercises

5. The generalized method of cells (GMC) micromechanics theory

5.1. Geometry and basic relations

5.2. Interfacial displacement continuity conditions

5.3. Interfacial continuity of tractions

5.4. Overall mechanical constitutive law

5.5. Thermomechanical effects

5.6. MATLAB implementation

5.7. Example problems

5.8. Advanced topics

5.9. Summary

5.10. Exercises

6. The high-fidelity generalized method of cells (HFGMC) micromechanics theory

6.1. Geometry and second-order displacement expansion

6.2. Local governing equations

6.3. Interfacial continuity and periodicity conditions

6.4. Overall mechanical system of equations

6.5. The mechanical strain concentration tensor

6.6. The effective mechanical properties

6.7. Thermomechanical effects

6.8. Contrast between HFGMC and finite-element analysis

6.9. MATLAB implementation

6.10. Example problems

6.11. Summary

6.12. Advanced topics

6.13. Exercises

7. Progressive damage and failure

7.1. MATLAB implementation

7.2. Pathological mesh dependence in HFGMC

7.3. Constituent strength consistency

7.4. PMC example problems

7.5. CMC example problems

7.6. Concluding remarks

7.7. Progressive damage self-learning

References.

Notes:

Includes bibliographical references.

Other Format:

Print version: Aboudi, Jacob Practical Micromechanics of Composite Materials

ISBN:

0128206373

9780128206379

OCLC:

1226564646