This example verifies the use of
Abaqus
to predict mixed-mode multidelamination in a layered composite specimen.
Cohesive elements, connector elements, traction-separation in
contact, and a crack propagation analysis with
VCCT
criterion are used for this purpose.
The example studied is the one that
appears in Alfano (2001). The results presented are compared against the
experimental results included in that reference, taken from Robinson (1999).
The model with cohesive elements is analyzed in
Abaqus/Standard
as well as
Abaqus/Explicit
and uses a damaged, linear elastic constitutive model. The model with
VCCT
criterion is also analyzed in both
Abaqus/Standard
and
Abaqus/Explicit
to predict debond growth. In addition, the model with
VCCT
criterion in
Abaqus/Standard
is analyzed using the Paris law to assess the fatigue life when it is subjected
to sub-critical cyclic displacement loading.
Geometry and model
The problem geometry and loading are depicted in
Figure 1:
a layered composite specimen, 200 mm long, with a total thickness of 3.18 mm
and a width of 20 mm, loaded by equal and opposite displacements in the
thickness direction at one end. The maximum displacement value is set equal to
20 mm in the monotonic loading case. In the low-cycle fatigue analysis, cyclic
displacement loading with a peak value of 1 mm is specified. The thickness
direction is composed of 24 layers. The model has two initial cracks: the first
(of length 40 mm) is positioned at the midplane of the specimen at the left
end, and the second (of length 20 mm) is located to the right of the first and
two layers below.
When cohesive elements are used, the problem is modeled in both two and
three dimensions, using solid elements to represent the bulk behavior and
cohesive elements to capture the potential delamination at the interfaces
between the 10th and 11th layers and between the 12th and 13th layers, counting
from the bottom. In the two-dimensional finite element model the top part of
the specimen (consisting of 12 layers), the middle section (2 layers), and the
bottom part (10 layers) are each modeled with a mesh of 1 × 200 CPE4I elements in
Abaqus/Standard
and CPE4R elements in
Abaqus/Explicit.
In both
Abaqus/Standard
and
Abaqus/Explicit
the initially uncracked portions of the two interfaces are modeled by one layer
each of COH2D4 elements that share nodes with the adjacent solid elements. A
similar, matching mesh is adopted for the equivalent three-dimensional model,
where the corresponding element types used areC3D8I and COH3D8 in
Abaqus/Standard
and C3D8R and COH3D8 in
Abaqus/Explicit,
with one element in the width direction. The nodes where the equal and opposite
displacements are prescribed are constrained in the length direction of the
specimen; these are the only boundary conditions in the two-dimensional case.
For the equivalent three-dimensional model all the nodes are also constrained
in the width direction to simulate the plane strain effect. In addition,
contact is defined between the open faces of the second, pre-existing crack to
avoid penetrations if the faces are compressed against each other during the
analysis.
In
Abaqus/Standard,
when the surface-based traction-separation capability available with the
contact pair algorithm is used, the problem is modeled in both two and three
dimensions. In
Abaqus/Explicit
the problem is modeled in three dimensions since surface-based
traction-separation is available with the general contact algorithm, which is
available only for three-dimensional models. The models are very similar to
those created for use with cohesive elements, as described in the previous
paragraph, except that the cohesive elements are replaced with cohesive
surfaces.
When the
VCCT
debond method is used, the problem is modeled in two dimensions in
Abaqus/Standard
but in three dimensions in
Abaqus/Explicit.
The models created above can also be adopted. Instead of using cohesive
elements or traction-separation in contact in
Abaqus/Standard,
you can activate the crack propagation capability with the
VCCT
criterion. The same model is also used in a low-cycle fatigue analysis. When
the same model is analyzed using
Abaqus/Explicit,
the
VCCT
criterion is obtained by assigning contact clearances, specifying cohesive
behavior properties, and specifying crack propagation criteria with general
contact.
When connector elements are used, the problem is modeled only in two
dimensions in
Abaqus/Standard.
Two node-based surfaces are generated: one along the top surface of the tenth
layer and the other along the bottom surface of the eleventh layer. Both
surfaces are tied to adjacent layers using surface-based tie constraints. CARTESIAN connector elements are used to bond the two node-based
surfaces together to represent the interface. For the interface between the
twelfth and thirteenth layers, matched solid element nodes along the interface
are connected directly using connector elements.
Material
The material data given in Alfano (2001) for the bulk material composite
properties are
GPa,
GPa,
GPa, ,
,
,
GPa,
GPa, and
GPa.
The response of the cohesive elements in the model is specified through the
cohesive section definition as a “traction-separation” response type. The
elastic properties of the cohesive layer material are specified in terms of the
traction-separation response with stiffness values
MPa,
MPa, and
MPa. The quadratic traction-interaction failure criterion is selected for
damage initiation in the cohesive elements; and a mixed-mode, energy-based
damage evolution law based on a power law criterion is selected for damage
propagation. The relevant material data are as follows:
MPa,
MPa,
MPa,
× 103 N/m,
× 103 N/m,
0.80 × 103 N/m, and .
The same damage initiation criterion and damage evolution law with the same
damage data are used for the surface-based traction-separation approach.
However, in the absence of cohesive elements, their thickness is accounted for
by scaling the elastic properties by a factor of 0.0132 × 10–3
(since the cohesive elements have a thickness of 0.0132 mm), and the properties
are specified as
64,200 GPa,
64,200 GPa, and
64,200 GPa.
For the
VCCT
debond approach, the BK mixed-mode failure law
is used with the same critical energy release rates as those used for cohesive
elements; i.e.,
× 103 N/m,
× 103 N/m, and
0.80 × 103 N/m. The exponent of the
BK law is specified as
.
When the low-cycle fatigue analysis using the Paris law is performed, the
additional relevant data are as follows: ,
,
4.88 × 10−6, ,
,
and .
Force-based damage initiation and a tabular form of motion-based damage
evolution are used to define the connector damage mechanisms. Initiation forces
are calculated based on the value of
given above for cohesive elements. For example, the initiation force for the
lower interface is calculated as 66 N, which is equal to
× A. The interface area over one cohesive element,
A, is 20 × 10−6. The stiffnesses of the
connector elements are calculated as
× 109 N/m, where L is the thickness of the
cohesive element. To improve the convergence behavior of this model, viscous
regularization has been applied.
Results and discussion
The plots of the prescribed displacement versus the corresponding reaction
force for the delamination problem are presented in
Figure 2
and compared with the experimental results included in Alfano (2001). Both the
Abaqus/Standard
and
Abaqus/Explicit
results displayed in the graph are from the two-dimensional analyses. The
results from the equivalent three-dimensional models are almost identical to
their two-dimensional counterparts and are not included in
Figure 2.
It can be seen from
Figure 2
that the curve produced using the surface-based traction-separation approach is
nearly the same as that obtained using cohesive elements. Both curves have good
agreement with the experimental results up to an applied displacement of
approximately 20 mm; then, a sharp drop in the reaction force is observed at
this point by the
Abaqus
analysis, after which the reaction force values appear to be underpredicted by
approximately 30% when compared to the experimental data. The reason for this
deviation, which appears to coincide with the simultaneous propagation of both
of the cracks, is related to the sudden failure of a relatively large number of
cohesive elements in a very short period of time. On the other hand, the data
predicted using the
VCCT
debond method agree well with the experimental results, without the sharp drop
previously noted. While the
Abaqus/Explicit
results, both with cohesive elements as well as from the three-dimensional
model with surface-based traction-separation, follow the same pattern as the
Abaqus/Standard
results, they are not as smooth due to inertia effects. A second-order
Butterworth-type filter was applied to the nodal reaction force history output
from the
Abaqus/Explicit
analysis to eliminate high-frequency oscillations from the response curve.
Figure 3
shows the results using cohesive elements from a series of
Abaqus/Standard
analyses incorporating a viscous regularization scheme to improve convergence
and demonstrates the effect on the predicted results of the choice of the
viscosity parameter, μ. Larger values of μ, while providing better convergence,
affect the results more than smaller viscosity values. The appropriate value of
the viscosity parameter that results in the right balance between improved
convergence behavior of the nonlinear system and accuracy of the results is
problem dependent and requires judgement on the part of the user. In the
cohesive zone approach to modeling delamination, the complex fracture process
at the micro-scale is modeled using only a few macroscopic parameters (such as
peak strength and fracture energy). While viscous regularization is not
intended to be used to model rate effects, it does provide an additional
parameter that can be “fitted” to the material model at hand. For the
particular delamination problem analyzed, as can be seen from
Figure 3,
a larger value of μ causes the first peak of the reaction force curve to be
higher than the experimental value and predicts a milder and smoother drop in
the reaction force following the peak compared to the experimental data.
However, the results with viscous regularization (for example, the curve for μ
= 1.0 × 10−4 in
Figure 3)
appear to match the experiments better for prescribed displacement values
greater than 20 mm.
Figure 2
also shows the results from the analysis using connector elements to model the
bonded interfaces. The same trend of delamination is observed as seen in the
experimental data.
Figure 4
illustrates the effect of viscous regularization. In one case a viscous
regularization factor of 0.0008 and maximum degradation factor of 0.99 are
used. In the other case the values are 0.0005 and 0.9, respectively. As can be
seen in
Figure 4,
a larger value of viscous regularization causes the peak of the reaction force
to be higher.
Figure 5
illustrates how the ratio of the peak reaction force over the corresponding
peak prescribed displacement (stiffness) degrades as a function of the cycle
number after using the direct cyclic approach. Similar results are obtained
when using the general and simplified fatigue crack growth approaches.
A comparison of the deformed configurations between the three-dimensional
Abaqus/Explicit
model and the two-dimensional
Abaqus/Standard
model is shown in
Figure 6.
Figure 7
depicts the delamination of both the top and bottom layers obtained from the
Abaqus/Explicit
and
Abaqus/Standard
analyses. A comparison of reaction forces versus displacement, illustrated in
Figure 8,
verifies the consistency in predicting the debond growth of both analyses.
Inertia effects were observed in
Abaqus/Explicit
later in the analysis when both bonded layers started to debond. Although the
forces are not as smooth, they follow the same pattern as the
Abaqus/Standard
results.
Abaqus/Standard
two-dimensional model using the Paris law to analyze the fatigue delamination
growth using the simplified fatigue crack growth approach.
Abaqus/Standard
two-dimensional model using connector elements and a viscous regularization
factor of 0.0008.
References
Alfano, G., and M. A. Crisfield, “Finite
Element Interface Models for the Delamination Analysis of Laminated Composites:
Mechanical and Computational
Issues,” International Journal for Numerical
Methods in
Engineering, vol. 50, pp. 1701–1736, 2001.
Robinson, P., T. Besant, and D. Hitchings, “Delamination
Growth Prediction Using a Finite Element
Approach,” 2nd ESIS TC4 Conference on
Polymers and Composites, Les Diablerets,
Switzerland, 1999.