Mechanical Behavior of Materials: Second EditionThis outstanding text offers a comprehensive treatment of the principles of the mechanical behavior of materials. Appropriate for senior and graduate courses, it is distinguished by its focus on the relationship between macroscopic properties, material microstructure, and fundamental concepts of bonding and crystal structure. The current, second edition retains the original editions extensive coverage of nonmetallics while increasing coverage of ceramics, composites, and polymers that have emerged as structural materials in their own right and are now competitive with metals in many applications. It contains new case studies, includes solved example problems, and incorporates real-life examples.
|
From inside the book
Results 1-5 of 78
... steels has been added . Off - axis behavior of aligned fiber composites is now treated in more detail ( Chap . 6 , Composite Materials ) , and there is more discussion on " Modern " composites in this chapter . Chapter 7 ( High ...
... Steel Wire / B. Steel Martensites / C. Ausformed Steels / D. Microalloyed Steels / E. Precipitation - Hardened Aluminum Alloys 5.10 Summary 231 6.1 Introduction 6 Composite Materials 6.2 Basic Principles of Reinforcement 6.3 Particle ...
... steel , which exhibits a yield point . Plastic flow initiates at the upper yield point ( UYP ) . It continues at the lower one ( LYP ) . At LYP , permanent deformation is heterogeneously distributed along the sample length . A ...
... steel this strain is the Lüders strain noted in Fig . 1.10 ) . Plastic deformation is heterogeneously distributed along the gage length of the steel during this initial stage of plastic deformation . A small permanently deformed vol ...
... Steel 1000 02 140 • Copper HAA Δ Nickel 오 Tresca von Mises 01 Ov Figure 1.11 ( c ) 2 ( a ) The Tresca yield condition for biaxial loading . Stress combinations lying within the solid lines do not result in plastic flow ; those without ...
Contents
1 | |
44 | |
85 | |
Plastic Deformation in Single and Polycrystalline Materials | 140 |
Strengthening of Crystalline Materials | 175 |
Composite Materials | 244 |
HighTemperature Deformation of Crystalline Materials | 293 |
Deformation of Noncrystalline Materials | 354 |
Toughening Mechanisms and the Physics of Fracture | 454 |
HighTemperature Fracture | 522 |
Fatigue of Engineering Materials | 566 |
Embrittlement | 630 |
Cellular Solids | 686 |
Name Index | 718 |
Specific Substance Index | 721 |
Subject Index | 727 |