Modeling Progressive Damage in Composites via Continuum Displacement Discontinuities Vipul Ranatunga...
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Transcript of Modeling Progressive Damage in Composites via Continuum Displacement Discontinuities Vipul Ranatunga...
Modeling Progressive Damage in Composites via Continuum
Displacement Discontinuities
Vipul Ranatunga
Miami University
Brett A. Bednarcyk
Steven M. Arnold
NASA Glenn Research Center, Cleveland, OH
Objective of the Research
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Investigate an existing MAC/GMC debonding model as a method for simulating delamination with bonded composite joints
Outline
• Overview of the displacement discontinuity model and MAC/GMC unit-cell architecture
• Comparison of VCCT, Cohesive, and MAC/GMC simulation results for opening and shearing crack propagation modes
• Prediction of the crack propagation path for an eccentrically loaded 3-point bend specimen
• Conclusion and future work
3
Delamination Modes
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Mode I (Opening)
Mode II (Shearing) Mode III (Tearing)
Ref. 1
Ref. 1Ref. 1
Reference 1: Villaverde, PhD Dissertation, Unv. Girona, Spain.
Double cantilever beam (DCB) test
End-notch flexure (ENF) test
MAC/GMC Repeated Unit Cell Architecture
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www.bren.ucsb.edu/facilities/MEIAF/images.html
Square fiber, square pack
Repeated Unit Cell with effective properties
Approximately circular fiber, square pack
For simplicity, this research used repeated unit cells with effective properties
Debonding Faces
Displacement Discontinuity Model
• Debonding interface is modeled by imposing discontinuity in a given displacement component across the interface
» j - normal or transverse direction
» Rj is a proportionality constant that may consider as a flexibility for the interface
• Explicit time-dependence of the Rj parameter in the model is expressed in an exponential form
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jj B, - model parameters which define the unloading of the interfacial stresses
- Normal and shear debond strengthsdb
ndb ,
Mode I Delamination: DCB Test
Material properties of AS4/3501-6
Plane-strain finite element model Unidirectional fibers aligned with the length direction (Y)
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4”
1.15”
0.12”
Applied displacements +/- 0.05”
Fixed BCDebond interface
MAC/GMC RUC
Y
X
E1 / ksi E2 / ksi E3 / ksi G12 / ksi G13 / ksi G23 / ksi
21,500 1640 1640 870 870 522
12 = 13 23GIC/ in-lb/in2
GIC/ in-lb/in2
GIC/ in-lb/in2
0.27 0.45 0.468 3.17 3.17 1.8
Sn/ psi Ss/ psi St / psi K1 / psi K2 / psi K3 / psi
3576 12600 12600 1.37e9 1.37e9 1.37e9
Through thickness 0.3”
VCCT and MAC/GMC Models
• An excellent agreement between VCCT & MAC/GMC is observed • Extended crack length:
• VCCT: 0.28” • MAC/GMC: 0.30”
8
Comparison of Stresses
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Cohesive Model VCCT Model MAC/GMC Model
Model Total CPU Time/sMAC/GMC Model 1423 VCCT Model 3241 Cohesive Model 14, 806
Mode II Delamination: End-Notch Flexure (ENF) Test
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U1=U2=U3=0
Displacement 0.2”
2t
Crack tip 0.5L F
w =0a0 c0
u, w =0
U2=U3=0
Ref. 2
Reference 2: Song, et.al, Abaqus User Conference, 2008
Problems Associated with Cohesive/VCCT Model
• Length of the cohesive zone under Mode-I loading
• Need minimum of 3 elements in the cohesive zone to represent the fracture energy accurately– Cohesive zone length of 0.0003” (0.007mm)– Resulting element length 0.0001” (0.0025mm)
• Selection of interfacial strength values along the normal and shear directions are challenging
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• Selection of Interfacial Penalty Stiffness (K)– High enough to prevent introducing artificial compliance– High value can lead to numerical problems
• Softening behavior and stiffness degradation leads to severe convergence difficulties– Viscous regularization: introduces localized damping to overcome
convergence difficulties– Automatic stabilization of unstable quasi-static problems through
volume-proportional damping• Need to compare the energy consumed as the ‘damping energy’ with
total strain energy to ensure that the damping energy is not too high
12Ref. 2: Song, et al. Abaqus User Conf. (2008)
Ref. 2
Problems Associated with Cohesive/VCCT Model
Effect of Mesh Size on MAC/GMC
• Stiffness of the entire element reduces as the crack progresses between the two layers
• A larger crack opening (compared to a crack tip) is created and the mesh has to be fine enough to represent the propagating crack front.
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• Refined mesh along the crack front makes debonding more localized
• Loss of element stiffness will not create a large (unrealistic) crack opening
Eccentrically Loaded 3-Point Bend Test
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1.8 in
Reference 3: Rudraraju et. al, 50th AIAA ASME/ASCE/AHS/ASC SDM Conference, 2009.
Ref. 3
Ref. 3
In FEA simulations, effective properties are used with fibers going in the thickness direction
• Combined shear and normal loading on the bend specimen• Crack path is not know a priori• VCCT or cohesive elements are not suitable for modeling this problem
Uncoupled Normal and Shear
• Found that the normal and shear debonding are uncoupled
• Introduced Hashin’s failure criterion for coupling interface normal and shear stresses
• Element stiffness degrades if the stresses at the interface satisfy this condition
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12
23
2
21
2
22
sdb
sdb
ndb
tSideF
12
32
2
31
2
33
sdb
sdb
ndb
tTopF
Prediction of Crack Path with MAC/GMC
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Crack Propagation
17
Conclusion
• An approach based on a continuum level interfacial displacement discontinuities has been compared to the VCCT and cohesive element approaches
• MAC/GMC debonding model is considerably more robust and simpler to apply than VCCT and cohesive elements, while producing similar results
• This approach is far less sensitive to the finite element model control parameters
• Significant advantage over number of elements used in cohesive approach and the computational time required
• MAC/GMC has the potential to predict the crack path
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Issues and Future Work
• Mesh dependence and the blunting of the crack tip
• Explicit time dependence of the debonding model
• Fiber-matrix debonding coupled with matrix cracking
• Application to bonded composite joints
19
Acknowledgments
• NASA Summer Faculty Fellowship Program, supported through Advanced Composite Technology (ACT) program.
• Software and hardware resources from Research Computing Support Group at Miami University
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Thank You!