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A new mixed mode I/II failure criterion for laminated composites considering fracture process zone

•A mixed mode I/II failure criterion was proposed for prediction of the crack growth in orthotropic materials.•The newly proposed criterion considers the absorbed energy in the fracture process zone by defining a suitable damage factor.•The applicability of the new criterion was investigated in both...

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Bibliographic Details
Published in:Theoretical and applied fracture mechanics 2018-12, Vol.98, p.48-58
Main Authors: Daneshjoo, Z., Shokrieh, M.M., Fakoor, M., Alderliesten, R.C.
Format: Article
Language:English
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Summary:•A mixed mode I/II failure criterion was proposed for prediction of the crack growth in orthotropic materials.•The newly proposed criterion considers the absorbed energy in the fracture process zone by defining a suitable damage factor.•The applicability of the new criterion was investigated in both laminated composites and wood species.•The new criterion was more compatible with the nature of the failure phenomena in orthotropic materials. In this paper, by considering the absorbed energy in the fracture process zone and extension of the minimum strain energy density theory for orthotropic materials, a new mixed mode I/II failure criterion was proposed. The applicability of the new criterion, to predict the crack growth in both laminated composites and wood species, was investigated. By defining a suitable damage factor and using the mixed mode I/II micromechanical bridging model, the absorbed energy in the fracture process zone was considered. It caused the new criterion to be more compatible with the nature of the failure phenomena in orthotropic materials, unlike available ones that were conservative. A good agreement was obtained between the fracture limit curves extracted by the present criterion and the available experimental data. The theoretical results were also compared with those of the minimum strain energy density criterion to show the superiority of the newly proposed criterion.
ISSN:0167-8442
1872-7638
DOI:10.1016/j.tafmec.2018.09.004