Fatigue of Engineering Plastics |
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Page 27
... fatigue response . 1.5.6 Competitive Events in Fracture Whatever the precise mechanisms that control ductility , significant effects of structure and morphology exist . Ductility tends to decrease as one moves upward in Table 1.1 , i.e. ...
... fatigue response . 1.5.6 Competitive Events in Fracture Whatever the precise mechanisms that control ductility , significant effects of structure and morphology exist . Ductility tends to decrease as one moves upward in Table 1.1 , i.e. ...
Page 88
... fatigue response . Since the materials shown in Table 3.4 differ with regard to their relative viscoelastic response , different strain rate effects may be expected . However , as pointed out earlier , while the waveform experi- ments ...
... fatigue response . Since the materials shown in Table 3.4 differ with regard to their relative viscoelastic response , different strain rate effects may be expected . However , as pointed out earlier , while the waveform experi- ments ...
Page 227
... fatigue response in composites , for these differences must reflect differences in the nature and distribution of flaws that are introduced adventitiously during the fabrication of nominally similar composites . Statistical Aspects of ...
... fatigue response in composites , for these differences must reflect differences in the nature and distribution of flaws that are introduced adventitiously during the fabrication of nominally similar composites . Statistical Aspects of ...
Contents
Fatigue Crack Propagation | 74 |
Fatigue Fracture Micromechanisms in Engineering Plastics | 146 |
Composite Systems | 184 |
Copyright | |
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adhesive ASTM ASTM STP Bucknall carbon cfrp component composites constant crack growth rate crack length crack tip craze crystalline cyclic loading da/dN decrease deformation discontinuous growth bands discussed ductile dynamic mechanical effect elastic elastic modulus energy epoxy fatigue behavior fatigue crack growth fatigue crack propagation fatigue failure fatigue fracture fatigue tests FCP behavior FCP rates fibers flaw fracture mechanics fracture surface fracture toughness frequency sensitivity hysteresis hysteretic heating increase J. A. Manson Kambour Kmax laminates loading cycles M. D. Skibo material matrix mean stress mm/cycle 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 shear shown in Fig specimen spherulite static strain stress intensity factor stress level striations studies temperature rise tensile test frequency thermal failure tion toughening unnotched values viscoelastic yield strength