Experimental and theoretical fracture toughness investigation of PUR foams under mixed mode I+III loading

• Published in: Polymer testing Vol. 67; pp. 75 - 83
• Main Authors: Aliha, M.R.M., Linul, E., Bahmani, A., Marsavina, L.
• Format: Journal Article
• Language: English
• Published: Barking Elsevier Ltd 01.05.2018; Elsevier BV
• Subjects: Crack initiation; Crack propagation; Deformation mechanisms; Deformation resistance; Density; Density effect; Experiments; Failure mechanisms; Foams; Fracture mechanics; Fracture toughness; Fracture toughness experiments; Mixed mode I/III; Plastic foams; Polyurethane; Rigid polyurethane foams; Service life; Sliding; Theoretical evaluation; Theoretical physics; Rigid polyurethane foams; Mixed mode I/III; Density effect; Theoretical evaluation; Fracture toughness experiments
• ISSN: 0142-9418; 1873-2348
• DOI: 10.1016/j.polymertesting.2018.02.015

Foam materials can be subjected to tensile and out-of-plane sliding deformation during their service life. Hence, catastrophic brittle fractures initiated from the pre-existing cracks under combined influence of modes I and III is one of the possible failure mechanism in rigid foams. However, at the best knowledge of authors there are no mixed mode (I + III) fracture toughness data for foam materials in the literature. To fill this research gap, in this research unique and new sets of mixed mode I/III fracture toughness data (i.e. KIc and KIIIc) are obtained and reported for the first time for PUR foam materials with different densities. The fracture experiments were conducted using “edge notched disc bend” (ENDB) specimen which has been recently developed for conducting mixed mode I/III investigations by the authors. Based on the obtained results, by increasing the contribution of out-of-plane sliding deformation the fracture growth resistance of the tested foams was decreased, such that the ratio of pure mode III fracture toughness over pure mode I fracture toughness (KIIIc/KIc) is about 0.65. Furthermore, by increasing the foam density the mixed mode fracture toughness envelope (KIc - KIIIc) becomes greater for all mode mixities. Indeed, when the density increases from 100 to 300 kg/m3, the corresponding modes I and III fracture toughness values increase up to 400%. Meanwhile, the experimental fracture toughness results are predicted very well using the maximum tangential strain density. •Edge notched disc bend specimens of PUR foams were experimentally investigated in mixed mode I+III.•The effective mixed mode I/III fracture toughness value was decreased by moving from pure mode I to pure mode III.•The maximum tangential strain energy density criterion applied successfully to predict mixed mode I/III fracture.