Probabilistic strength based matrix crack evolution model in multi-directional composite laminates under fatigue loading

•Matrix crack evolution prediction in multi-directional composite laminates under fatigue loading is considered.•Cracked laminate stresses estimated using oblique co-ordinate based shear lag analysis.•Weibull probabilistic strength based criterion for matrix crack initiation is considered.•Matrix cr...

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Bibliographic Details
Published in:International journal of fatigue 2018-12, Vol.117, p.135-147
Main Authors: Jagannathan, N., Gururaja, S., Manjunatha, C.M.
Format: Article
Language:English
Subjects:
Analytical modelling
Catalytic cracking
Computer simulation
Crack initiation
Crack propagation
Degradation
Density
Evolution
Fatigue
Fatigue cracks
Fatigue failure
Fatigue life
Fracture mechanics
Laminates
Layers
Materials fatigue
Mathematical models
Matrix cracking
Matrix cracks
Palmgren-Miner rule
Parameters
Polymer matrix composites
Polymer-matrix composites (PMCs)
Statistical analysis
Stiffness
Strength
Stress intensity factors
Threshold stress
Weibull distribution
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Summary:•Matrix crack evolution prediction in multi-directional composite laminates under fatigue loading is considered.•Cracked laminate stresses estimated using oblique co-ordinate based shear lag analysis.•Weibull probabilistic strength based criterion for matrix crack initiation is considered.•Matrix crack growth rate - modeled using Paris law based on effective stress intensity factor.•Crack density evolution is simulated and compared with experimental values. A model to predict the matrix crack evolution in multi-directional (MD) polymer matrix composite laminates under in-plane fatigue loading is presented in the current work. Unlike matrix crack evolution under static loading, the matrix cracks in off-axis plies do not form tunneling cracks under fatigue loading; rather, they initiate and grow with increasing load cycles. A probabilistic strength based criterion for matrix crack initiation in off-axis plies based on a Weibull distribution for in situ ply strength variation has been used. An oblique co-ordinate based shear lag analysis has been used to estimate the stresses in the cracked laminate. Smith Watson Topper (SWT) parameter has been used to model the number of cycles to initiate the first matrix crack, and log-normal probability distribution has been used to handle the scatter in crack initiation life. The matrix crack growth rate has been modeled using Paris law based on mixed mode effective stress intensity factor. Using the crack initiation curve and strength degradation based on Palmgren-Miner damage rule, new crack initiation has been simulated. Few parameters needed for the threshold stress intensity and saturation crack spacing have been identified from a reference stress data of cross-ply laminate. The crack density evolution has been simulated for cross-ply and MD-laminates under various constant amplitude in-plane fatigue stress levels. The matrix crack density evolution and its stiffness degradation predictions with the number of cycles have been compared with existing experimental values. A good correlation is found to exist between the experimental data and predictions for both cross-ply and MD-laminates.
ISSN:0142-1123
1879-3452
DOI:10.1016/j.ijfatigue.2018.08.016