Mechanical MetallurgyThis bestselling metallurgy text examines the behaviour of materials under stress and their reaction to a variety of hostile environments. It covers the entire scope of mechanical metallurgy, from an understanding of the continuum description of stress and strain, through crystalline and defect mechanisms of flow and fracture, and on to a consideration of major mechanical property tests and the basic metalworking process. It has been updated throughout, and optimised for metric (SI) units . End-of-chapter study questions are included. |
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Page 221
... fiber strengthening the high modulus fibers carry essentially all of the load . The matrix serves to transmit the load to the fibers , to protect fibers from surface damage , and to separate the individual fibers and blunt cracks which ...
... fiber strengthening the high modulus fibers carry essentially all of the load . The matrix serves to transmit the load to the fibers , to protect fibers from surface damage , and to separate the individual fibers and blunt cracks which ...
Page 222
... fibers , and if we multiply by the total length of composite this represents the volume fraction of fibers , f ,. In a similar way A / A represents fm , and f + fm = 1. Therefore c - σ1 = 0ƒfƒ + omfm = 0ƒfƒ + ( 1 − ƒƒ ) σm = ( 6-40 ) ...
... fibers , and if we multiply by the total length of composite this represents the volume fraction of fibers , f ,. In a similar way A / A represents fm , and f + fm = 1. Therefore c - σ1 = 0ƒfƒ + omfm = 0ƒfƒ + ( 1 − ƒƒ ) σm = ( 6-40 ) ...
Page 223
... fibers and the matrix undergo plastic deformation . Since many of the high strength - high modulus fibers like boron are brittle , they fracture on entering stage 3 , but metal wire fibers show this region . Finally , in stage 4 the ...
... fibers and the matrix undergo plastic deformation . Since many of the high strength - high modulus fibers like boron are brittle , they fracture on entering stage 3 , but metal wire fibers show this region . Finally , in stage 4 the ...
Contents
Introduction | 3 |
Stress and Strain Relationships for Elastic Behavior | 17 |
Metallurgical Fundamentals | 101 |
Copyright | |
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alloy aluminum angle annealed ASME ASTM atoms axis behavior billet brittle fracture Burgers vector cold-worked components compression constant crack creep cycles decrease determined diameter direction dislocation line ductile edge dislocation elastic elongation embrittlement energy engineering equation extrusion factor failure fatigue limit fibers Figure flow curve flow stress force forging friction given grain boundaries hot-working hydrostatic increase indentation lattice length load machining martensite material matrix maximum measured mechanical metallurgical Metals Park modulus necking notch occurs particles percent plane-strain plastic deformation plastic strain pressure produce properties ratio recrystallization reduction region residual stresses rolling screw dislocation shear stress sheet shown in Fig slip plane slip systems Society for Metals specimen steel strain hardening strain rate stress-strain curve structure surface temperature tensile strength tensile stress tensor thickness tool torsion Trans usually velocity workpiece yield strength yield stress York