Screen LibraryAdvanced mechanics of composite materials and structures /
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| Main Authors: | |
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| Corporate Authors: | |
| Group Author: | |
| Published: |
Elsevier,
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| Publisher Address: | Amsterdam, Netherlands : |
| Publication Dates: | [2018] |
| Literature type: | eBook |
| Language: | English |
| Edition: | Fourth edition. |
| Subjects: | |
| Online Access: |
https://www.sciencedirect.com/science/book/9780081022092 |
| Carrier Form: | 1 online resource (856 pages) : illustrations |
| Bibliography: | Includes bibliographical references and indexes. |
| ISBN: |
9780081022108 0081022107 |
| Index Number: | TA418 |
| CLC: | TB33 |
| Contents: |
Front Cover; Advanced Mechanics of Composite Materials and Structures; Copyright Page; Contents; Preface; Introduction; 1 Mechanics of a Unidirectional Ply; 1.1 Ply Architecture; 1.2 Fiber-Matrix Interaction; 1.2.1 Theoretical and Actual Strength; 1.2.2 Statistical Aspects of Fiber Strength; 1.2.3 Stress Diffusion in Fibers Interacting Through the Matrix; 1.2.4 Fracture Toughness; 1.3 Micromechanics of a Ply; 1.4 Mechanical Properties of a Ply Under Tension, Shear, and Compression; 1.4.1 Longitudinal Tension; 1.4.2 Transverse Tension; 1.4.3 In-Plane Shear; 1.4.4 Longitudinal Compression 1.4.5 Transverse Compression1.5 Interlaminar Stiffness and Strength; 1.6 Hybrid Composites; 1.7 Composites With High Fiber Fraction; 1.8 Limitations of the Phenomenological Homogeneous Model of a Ply; References; 2 Mechanics of a Composite Layer; 2.1 Isotropic Layer; 2.1.1 Linear Elastic Model; 2.1.2 Nonlinear Models; 2.2 Unidirectional Orthotropic Layer; 2.2.1 Linear Elastic Model; 2.2.2 Nonlinear Models; 2.3 Unidirectional Anisotropic Layer; 2.3.1 Linear Elastic Model; 2.3.2 Nonlinear Models; 2.4 Orthogonally Reinforced Orthotropic Layer; 2.4.1 Linear Elastic Model; 2.4.2 Nonlinear Models 2.4.3 Composites With Controlled Cracks2.4.4 Two-Matrix Composites; 2.4.5 Two-Matrix Composite Made by Three-Dimensional Printing; 2.5 Angle-Ply Orthotropic Layer; 2.5.1 Linear Elastic Model; 2.5.2 Nonlinear Models; 2.5.3 Free-Edge Effects; 2.6 Layer Made by Angle-Ply Circumferential Winding; 2.7 Fabric Layers; 2.8 Spatially Reinforced Layers and Bulk Materials; References; 3 Mechanics of Laminates; 3.1 Stiffness Coefficients of a Nonhomogeneous Anisotropic Layer; 3.2 Stiffness Coefficients of a Homogeneous Layer; 3.3 Stiffness Coefficients of a Laminate; 3.4 Symmetric Laminates 3.5 Engineering Stiffness Coefficients of Orthotropic Laminates3.6 Quasi-Homogeneous Laminates; 3.6.1 Laminate Composed of Identical Homogeneous Layers; 3.6.2 Laminate Composed of Inhomogeneous Orthotropic Layers; 3.6.3 Laminate Composed of Angle-Ply Layers; 3.6.4 Fiber Metal Laminates; 3.7 Quasi-Isotropic Laminates in the Plane Stress State; 3.8 Antisymmetric Laminates; 3.9 Sandwich Structures; 3.10 Coordinate of the Reference Plane; 3.11 Stresses in Laminates; References; 4 Failure Criteria and Strength of Laminates; 4.1 Failure Criteria for an Elementary Composite Layer or Ply 4.1.1 Maximum Stress and Strain Criteria4.1.2 Approximation Strength Criteria; 4.1.3 Tensor Strength Criteria; 4.1.4 Interlaminar Strength; 4.2 Practical Recommendations; 4.3 Examples; 4.4 Allowable Stresses for Laminates Consisting of Unidirectional Plies; 4.5 Progressive Failure: General Approach to Modeling and Analysis; 4.5.1 Constitutive Equations; 4.5.2 Plastic Model; 4.5.3 Damage Model; 4.5.3.1 Damage Initiation and Propagation Criteria; 4.5.3.2 Damage Evolution; 4.5.4 Numerical Implementation; 4.5.4.1 Integration Algorithm; 4.5.4.2 Consistent Tangent Stiffness Matrix |