Toughening Mechanisms in the High Strain Rate Deformation of Rubber-modified Polymer GlassesCornell University, 1993 - 728 pages |
From inside the book
Results 1-3 of 76
Page 186
Donald Joseph Buckley. Strains and Strain Rates From Figure 2.8 ( b ) , it can be seen that the total strain has reached ca. 5 % , or 3 % plastic strain , at the onset of crazing . The contribution from the noncrazing mechanisms is ...
Donald Joseph Buckley. Strains and Strain Rates From Figure 2.8 ( b ) , it can be seen that the total strain has reached ca. 5 % , or 3 % plastic strain , at the onset of crazing . The contribution from the noncrazing mechanisms is ...
Page 293
Donald Joseph Buckley. 3.4 RESULTS Strain Rate Regimes While the mean strain rates for the impact and creep tests differ considerably , the spread in strain rates for each material and ... higher strain rates of હુ ( c ) ( b ) ( a ) 293.
Donald Joseph Buckley. 3.4 RESULTS Strain Rate Regimes While the mean strain rates for the impact and creep tests differ considerably , the spread in strain rates for each material and ... higher strain rates of હુ ( c ) ( b ) ( a ) 293.
Page 321
Donald Joseph Buckley. due to ligament shear if this mechanism is operative at these strain rates . If ligament deformation were occurring , we would expect a larger contribution from this process at higher wf , since the ligament width ...
Donald Joseph Buckley. due to ligament shear if this mechanism is operative at these strain rates . If ligament deformation were occurring , we would expect a larger contribution from this process at higher wf , since the ligament width ...
Contents
Chapter 1 | 10 |
Chapter 2 | 148 |
EFFECT OF RUBBER PHASE GEOMETRY AND MATRIX | 264 |
Copyright | |
2 other sections not shown
Common terms and phrases
ABS materials behavior cavitation component constant volume craze fibrils crazes and voids creep tests deformation fractions deformation mechanisms density detector dilation diode array detector ductile due to crazing E. J. Kramer electron energy equation extension ratio gauge length high strain rates HIPS materials image intensifier Impact Creep impact event impact tests increase interparticle ligaments interparticle spacing ionization monitor ligament width load mass thickness measurements method micrograph microtomed molecular weight occurs optical parameters particle diameter pixel plastic strains plotted polymer polymer glasses Porod primary beam regions rubber particles rubber phase rubber weight fraction rubber-modified polymers sample SAXS scattered intensity scattering pattern scattering vector shear banding shear deformation shear yielding shown in Figure small angle strain at fracture strain due strain rate stress concentration structure tensile creep tensile direction tensile impact total strain toughening transmitted intensity volume fraction volume of crazes x-ray yield stress