Failure of Materials in Mechanical Design: Analysis, Prediction, PreventionFailure of Materials in Mechanical Design: Analysis, Prediction, Prevention, 2nd Edition, covers the basic principles of failure of metallic and non-metallic materials in mechanical design applications. Updated to include new developments on fracture mechanics, including both linear-elastic and elastic-plastic mechanics. Contains new material on strain and crack development and behavior. Emphasizes the potential for mechanical failure brought about by the stresses, strains and energy transfers in machine parts that result from the forces, deflections and energy inputs applied. |
Contents
The Role of Failure Prevention Analysis | 1 |
Strength and Deformation of Engineering Metals | 16 |
Index | 17 |
Critical Resolved Shearing Stress for Slip | 26 |
Grain Boundary Sliding and Diffusional | 32 |
Dislocation Motion | 43 |
State of Stress | 90 |
Relationships Between Stress and Strain | 112 |
Maximum Normal Stress Multiaxial | 239 |
Concepts of Cumulative Damage Life Prediction | 255 |
Use of Statistics in Fatigue Analysis | 333 |
Fatigue Testing Procedures and Statistical | 374 |
LowCycle Fatigue | 393 |
Stress Concentration | 414 |
Creep Stress Rupture and Fatigue | 459 |
Fretting Fretting Fatigue and Fretting Wear | 504 |
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Common terms and phrases
alloy aluminum alloy behavior calculated column components compressive stress constant corrosion crack growth creep strain Cycles to failure cyclic stress defined determined dislocation ductile effects elastic engineering equation estimate experimental expression failure mode Fatigue Crack fatigue failure fatigue limit fatigue strength fatigue stress fatigue testing fracture mechanics fretting fretting fatigue fretting wear function impact loading initial K₁ low-cycle fatigue machine magnitude material mean stress metal method modulus multiaxial nonzero mean normal stress notch number of cycles Omax percent plane plane strain plastic deformation plastic strain plate plot produce ratio S-N curve safety factor shearing stress shown in Figure specimen steel strain amplitude strain energy strain range stress amplitude stress concentration factor stress level stress rupture stress theory stress-strain stress-strain curve struck end surface temperature tensile tension titanium torsional total strain uniaxial versus wave front yield strength zero