The effects of fracture mechanics parameters on the stress-cracking behavior of high-density polyethylene
- 1 June 1989
- journal article
- research article
- Published by Taylor & Francis in Journal of Macromolecular Science, Part B
- Vol. 28 (2) , 235-249
- https://doi.org/10.1080/00222348908215221
Abstract
Stress intensity factor (KI)-crack speed (c·) plots for the high-density polyethylene-10% detergent (Igepal) system have been obtained to investigate the effect of fracture mechanics test variables such as load level, specimen geometry, and dimension on the crack growth behavior. Fracture mechanics appeared to be valid at low KI levels. However, at high KI values, the data showed that linear elastic fracture mechanics failed to describe the crack growth behavior. Williams' flow model was not successful in explaining a number of regions which were obtained in a KI -·c plot. Craze formation at the crack tip enhances the crack speed at high KI levels.Keywords
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