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Mechanics of composite materials : a unified micromechanical approach /
In the last decade the author has been engaged in developing a micromechanical composite model based on the study of interacting periodic cells. In this two-phase model, the inclusion is assumed to occupy a single cell whereas the matrix material occupies several surrounding cells. A prominent featu...
| Clasificación: | Libro Electrónico |
|---|---|
| Autor principal: | |
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
Amsterdam ; New York :
Elsevier,
1991.
|
| Colección: | Studies in applied mechanics ;
29. |
| Temas: | |
| Acceso en línea: | Texto completo Texto completo |
Tabla de Contenidos:
- Front Cover; Mechanics of Composite Materials: A Unified Micromechanical Approach; Copyright Page; Dedication; Preface; Table of Contents; CHAPTER 1. FUNDAMENTALS OF THE MECHANICS OF COMPOSITES; 1.1 INTRODUCTION; 1.2 REPRESENTATIVE VOLUME ELEMENT; 1.3 VOLUMETRIC AVERAGING; 1.4 HOMOGENEOUS BOUNDARY CONDITIONS; 1.5 AVERAGE STRAIN THEOREM; 1.6 AVERAGE STRESS THEOREM; 1.7 EFFECTIVE ELASTIC MODULI; 1.8 RELATIONS BETWEEN AVERAGES
- DIRECT APPROACH; 1.9 RELATIONS BETWEEN AVERAGES
- ENERGY APPROACH; REFERENCES; CHAPTER 2. BASIC MODELS IN THE MECHANICS OF COMPOSITES; 2.1 INTRODUCTION.
- 2.2 the voigt approximation2.3 the reuss approximation; 2.4 hill's theorem; 2.5 the dilute approximation; 2.6 the composite spheres model; 2.7 the self-consistent scheme; 2.8 the generalized self-consistent scheme; 2.9 the differential scheme; 2.10 the mori-tanaka theory; 2.11 eshelby equivalent inclusion method; references; chapter 3. the micromechanical method of cells; 3.1 introduction; 3.2 the method of cells for fiber-reinforced materials; 3.3 coefficients of thermal expansion; 3.4 hill's relations; 3.5 thermal conductivities; 3.6 specific heats.
- 3.7 the method of cells for short-fiber composites3.8 randomly reinforced materials; 3.9 periodically bilaminated materials; 3.10 conclusions; references; chapter 4. strength and fatigue failure; 4.1 introduction; 4.2 micromechanics prediction of composite failure; references; chapter 5. viscoelastic behavior of composites; 5.1 introduction; 5.2 linearly viscoelastic composites; 5.3 thermoviscoelastic behavior of composites; 5.4 nonlinear viscoelastic behavior of composites; references; chapter 6. nonlinear behavior of resin matrix composites; 6.1 introduction; 6.2 macromechanical analysis.
- 6.3 micromechanical analysisreferences; chapter 7. initial yield surfaces of metal matrix composites; 7.1 the initiation of yielding in isotropic materials; 7.2 initial yielding of metal matrix composites; 7.3 investigation of the convexity of initial yield surfaces; references; chapter 8. inelastic behavior of metal matrix composites; 8.1 introduction; 8.2 constitutive equations of plasticity; 8.3 unified theories of viscoplasticity; 8.4 bodner-partom viscoplastic equations; 8.5 inelastic behavior of laminated media; 8.6 inelastic behavior of fibrous composites.
- 8.7 matrix mean-field and local-field8.8 subsequent yield surfaces prediction of metal matrix composites; 8.9 metal matrix composite laminates; 8.10 short-fiber metal-matrix composites; references; chapter 9. imperfect bonding in composites; 9.1 introduction; 9.2 general considerations; 9.3 the flexible interface imperfect bonding model; 9.4 periodically bilaminated materials; 9.5 fiber-reinforced materials; 9.6 short-fiber and particulate composites; 9.7 the coulomb frictional law for the modeling of interfacial damage in composites; references; index.