Book contents
- Frontmatter
- Contents
- Preface
- 1 Stress and Strain
- 2 Elasticity
- 3 Mechanical Testing
- 4 Strain Hardening of Metals
- 5 Plasticity Theory
- 6 Strain Rate and Temperature Dependence of Flow Stress
- 7 Slip and Crystallographic Textures
- 8 Dislocation Geometry and Energy
- 9 Dislocation Mechanics
- 10 Mechanical Twinning and Martenitic Shear
- 11 Hardening Mechanisms in Metals
- 12 Discontinuous and Inhomogeneous Deformation
- 13 Ductility and Fracture
- 14 Fracture Mechanics
- 15 Viscoelasticity
- 16 Creep and Stress Rupture
- 17 Fatigue
- 18 Residual Stresses
- 19 Ceramics and Glasses
- 20 Polymers
- 21 Composites
- 22 Mechanical Working
- APPENDIX I Miller Indices
- APPENDIX II Stereographic Representation of Orientations
- Index
21 - Composites
Published online by Cambridge University Press: 05 June 2012
- Frontmatter
- Contents
- Preface
- 1 Stress and Strain
- 2 Elasticity
- 3 Mechanical Testing
- 4 Strain Hardening of Metals
- 5 Plasticity Theory
- 6 Strain Rate and Temperature Dependence of Flow Stress
- 7 Slip and Crystallographic Textures
- 8 Dislocation Geometry and Energy
- 9 Dislocation Mechanics
- 10 Mechanical Twinning and Martenitic Shear
- 11 Hardening Mechanisms in Metals
- 12 Discontinuous and Inhomogeneous Deformation
- 13 Ductility and Fracture
- 14 Fracture Mechanics
- 15 Viscoelasticity
- 16 Creep and Stress Rupture
- 17 Fatigue
- 18 Residual Stresses
- 19 Ceramics and Glasses
- 20 Polymers
- 21 Composites
- 22 Mechanical Working
- APPENDIX I Miller Indices
- APPENDIX II Stereographic Representation of Orientations
- Index
Summary
Introduction
Throughout history, mankind has used composite materials to achieve combinations of properties that could not be achieved with individual materials. The Bible describes mixing of straw with clay to make tougher bricks. Concrete is a composite of cement paste, sand, and gravel. Today, poured concrete is almost always reinforced with steel rods. Other examples of composites include steel-belted tires, asphalt blended with gravel for roads, plywood with alternating directions of fibers, and fiberglass-reinforced polyester used for furniture, boats, and sporting goods. Composite materials offer combinations of properties otherwise unavailable.
The reinforcing material may be in the form of particles, fibers, or sheet laminates.
Fiber-Reinforced Composites
Fiber composites may also be classified according to the nature of the matrix and the fiber. Examples of a number of possibilities are listed in Table 21.1.
Various geometric arrangements of the fibers are possible. In two-dimensional products, the fibers may be unidirectionally aligned, at 90 degrees to one another in a woven fabric or cross-ply, or randomly oriented (Figure 21.1). The fibers may be very long or chopped into short segments. In thick objects, short fibers may be random in three dimensions. The most common use of fiber reinforcement is to impart stiffness (increased modulus) or strength to the matrix. Toughness may also be of concern.
- Type
- Chapter
- Information
- Mechanical Behavior of Materials , pp. 363 - 384Publisher: Cambridge University PressPrint publication year: 2009