Deformation and Fracture Mechanics of Engineering MaterialsUpdated to reflect recent developments in our understanding of deformation and fracture processes in structural materials. This completely revised reference includes new sections on isostress analysis, modulus of rupture, creep fracture micromechanicsms, and many more. |
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Page 10
3 , typical normal and shear strain components may be given by ( 1 - 9a ) ( 1 - 9b
) av Yxy = tana + tanß = ( 1 - 9c ) Әх ду with the other normal and shear strains
defined in similar fashion . When multiaxial stresses are applied , the total strain
in ...
3 , typical normal and shear strain components may be given by ( 1 - 9a ) ( 1 - 9b
) av Yxy = tana + tanß = ( 1 - 9c ) Әх ду with the other normal and shear strains
defined in similar fashion . When multiaxial stresses are applied , the total strain
in ...
Page 118
2 The crystals have a normal cross - sectional area of 122 x 10 - 6 m2 . 0 = angle
between loading axis and normal to slip plane = angle between loading axis and
slip direction F = force acting on crystal when yielding begins ( a ) Name the ...
2 The crystals have a normal cross - sectional area of 122 x 10 - 6 m2 . 0 = angle
between loading axis and normal to slip plane = angle between loading axis and
slip direction F = force acting on crystal when yielding begins ( a ) Name the ...
Page 245
Regarding this point , Sternstein " 4 found that under multiaxial stress conditions ,
glassy polymers could yield by two distinct mechanisms : normal yielding (
crazing ) and shear yielding ( Fig . 6 . 29 ) . For the biaxial stress case , shear
yielding ...
Regarding this point , Sternstein " 4 found that under multiaxial stress conditions ,
glassy polymers could yield by two distinct mechanisms : normal yielding (
crazing ) and shear yielding ( Fig . 6 . 29 ) . For the biaxial stress case , shear
yielding ...
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addition alloy aluminum applied associated atoms behavior brittle ceramics Chapter component composite constant contains corresponding crack creep critical crystal curve decrease defined deformation depends described determined developed direction discussed dislocation edge effect elastic embrittlement energy engineering example factor failure fiber FIGURE fracture fracture surface fracture toughness given grain boundaries greater growth important increasing initial involves Kıc lattice length load lower material matrix maximum mechanisms Metals modulus necessary normal notch Note occur orientation parallel particles permission phase plane plastic plate polymer produce properties reduced region relation relative represents Reprinted resistance respectively response result revealing rupture sample shear showing shown in Fig slip Society solid solution specimen steel strain strength strengthening stress stress level structure surface Table temper temperature tensile thermal thickness toughness transition twin values volume yield strength
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Bibliographic information
| Title | Deformation and Fracture Mechanics of Engineering Materials |
| Author | Richard W. Hertzberg |
| Edition | 4, illustrated |
| Publisher | Wiley, 1996 |
| Original from | the University of Michigan |
| Digitized | 6 Dec 2007 |
| ISBN | 0471012149, 9780471012146 |
| Length | 786 pages |
| Subjects | › › Science / Chemistry / General Science / Nanoscience Technology & Engineering / Engineering (General) Technology & Engineering / Fracture Mechanics Technology & Engineering / Materials Science / General |
| Export Citation | BiBTeX EndNote RefMan |