Fatigue of engineering plastics |
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Page 115
Also, the model is concerned with conditions of plane stress where az = 0 (see
Fig. 3.2). As such, the model describes the condition associated with craze
formation at a crack tip in that (1) the craze assumes the shape of a narrow plastic
strip; ...
Also, the model is concerned with conditions of plane stress where az = 0 (see
Fig. 3.2). As such, the model describes the condition associated with craze
formation at a crack tip in that (1) the craze assumes the shape of a narrow plastic
strip; ...
Page 163
Fig. 4.13 Discontinuous crack growth process. (a) Composite micrograph of PVC
showing position of craze (j) and crack ([) tip at given cyclic intervals; (b) model of
discontinuous cracking process [R. W. Hertzberg and J. A. Manson, J. Mater.
Fig. 4.13 Discontinuous crack growth process. (a) Composite micrograph of PVC
showing position of craze (j) and crack ([) tip at given cyclic intervals; (b) model of
discontinuous cracking process [R. W. Hertzberg and J. A. Manson, J. Mater.
Page 165
Finally a critical condition is reached when the next fibril would break ; the
remaining fibrils would no longer be capable of absorbing the additional load
and the entire craze zone would suddenly rupture. The presumed relative
constancy of ...
Finally a critical condition is reached when the next fibril would break ; the
remaining fibrils would no longer be capable of absorbing the additional load
and the entire craze zone would suddenly rupture. The presumed relative
constancy of ...
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Contents
Fatigue Crack Propagation | 74 |
Fatigue Fracture Micromechanisms in Engineering Plastics | 146 |
Composite Systems | 184 |
Copyright | |
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Common terms and phrases
adhesive amplitude ASTM ASTM STP Bucknall carbon cfrp component Composite Materials composites constant crack growth rates crack length crack tip craze crystalline cyclic loading da/dN decrease deformation discontinuous growth bands discussed ductile effect elastic elastic modulus energy epoxy fatigue behavior fatigue crack growth fatigue crack propagation fatigue failure fatigue fracture fatigue response fatigue tests FCP behavior FCP rates fibers flaw fracture mechanics fracture surface fracture toughness frequency sensitivity hysteresis hysteretic heating increase J. A. Manson Kambour laminates loading cycles M. D. Skibo material matrix mean stress modulus molecular weight notched nylon 66 plastic zone PMMA polyacetal polycarbonate polymeric solids polystyrene properties PVDF R. W. Hertzberg Rabinowitz rubber S-N curve samples Section semicrystalline shown in Fig specimen spherulite static stress intensity factor stress level striation studies temperature rise tensile test frequency thermal failure tion toughening unnotched values viscoelastic yield strength
Bibliographic information
| Title | Fatigue of engineering plastics |
| Authors | Richard W. Hertzberg, John A. Manson |
| Contributor | John A. Manson |
| Edition | illustrated |
| Publisher | Academic Press, 1980 |
| Original from | the University of Michigan |
| Digitized | 30 Nov 2007 |
| ISBN | 0123435501, 9780123435507 |
| Length | 295 pages |
| Subjects | › Plastics Plastics - Fatigue Technology & Engineering / Engineering (General) Technology & Engineering / General Technology & Engineering / Materials Science |
| Export Citation | BiBTeX EndNote RefMan |