Q2. What future works have the authors mentioned in the paper "Mechanical analysis of a mixed mode debonding test for composite pavements" ?
In looking to future studies, additional simulations for the purpose of introducing, under loading points of the specimen, an initial crack at the bottom of the concrete layer into the model should help determine the exact cracking and debonding mechanisms of these specimens.
Q3. What is the role of modulus between layers in the performance of the bond?
The modulus ratio between layers, due to the variation in temperatureeffect and the loading rate on mechanical properties of bituminous material as well as to the position of the load close to the vertical crack, plays an important role in the long-term performance of the bond [3-4].
Q4. What is the main reason for the debonding between pavement layers?
During the pavement service life however, due to the structural heterogeneity of multilayer systems, debonding between pavement layers can occur, especially near the edges or vertical cracks through one layer.
Q5. What type of test can simulate the interface stress in cracked pavements?
A specific elastic Multiparticular Model which can simulate the 3D interface stress in crackedpavements [33] may be used in this investigation.
Q6. How many emulsions were used to cover the concrete layer?
The emulsion, i.e. 0.4 kg/m² of residual binder, was applied to the concrete layer and left for 24 hours before being covered by the bituminous material layer.
Q7. How many tests have been performed on each interface?
Under the same controlled displacement rate (0.7 mm/min) as for previous results, only one test on each interface has been performed at a lower temperature, i.e. set around 5°C (Fig. 12).
Q8. What type of interface is used for a bituminous material?
The type II interface corresponds to a bituminous material with the cement concrete material being bonded by means of a tack coat layer.
Q9. How long is the test duration determined by the experimental results?
From these loads, the test duration is determined by reviewing the experimental time-load result; it amounts to roughly 5.3 s for the two specimens tested at high and low temperature.
Q10. What is the M4 model for the pavement bending problem?
The M4 selected herein for the pavement bending problem contains five kinematic fields per layer i ( { }ni ,...,1∈ , where n denotes the total number of layers): average plane displacements ( )yxU i ,α ; the average out-of-plane displacement ( )yxU i ,3 ; and average rotations ( )yxi ,αΦ , where ( )yx, represent the layer's plane coordinates and the α-plane directions { }( )2,1∈α .
Q11. What is the tensile stress intensity at the bottom of the concrete layer?
In Figure 5a, as length a2 increases, the tensile stress intensity at the bottom of concrete layer 2 increases under loading point C and the interface normal and shear stresses increase at the edge (x = L-a2) (Fig. 5b).
Q12. What was the first validation for the modeling?
In [35,51], the modeling was first validated for tests on bi-layer specimen composed of aluminum as the first layer and PVC as the second.