Linear viscoelastic behavior of asphalt mixes from dynamic frequency response functions |
| |
| Authors: | Jean-Claude Carret Herve Di Benedetto Cedric Sauzeat |
| |
| Institution: | LTDS (UMR CNRS 5513), University of Lyon/ENTPE, Rue M. Audin, 69518, Vaulx en Velin, France |
| |
| Abstract: | In the small strain domain, asphalt mixes (AM) have a linear viscoelastic (LVE) behavior that is strongly dependent on frequency and temperature. The maximum ratio of modulus values can be up to 1000, and traditional elastic analyses are not pertinent. The possibility to characterize AM from frequency response functions (FRFs) was studied. A new optimization process using the finite element method (FEM) has been developed to back-calculate the LVE properties of AM from FRFs. The numerical optimization process was applied to a reference material with averaged LVE properties determined from tension-compression tests performed on a wide variety of AM types. The LVE properties were modeled considering the 3-Dim version of the model 2S2P1D (2 Springs, 2 Parabolic elements, and 1 Dashpot). Reference FRFs for the considered reference material were obtained from FEM simulations. Three different configurations that may be of interest for practical tests were studied at five different temperatures. The proposed numerical optimization method consists in performing separate optimizations at each temperature to obtain the LVE properties for the considered temperature. Then values obtained at each temperature are considered to optimize 2S2P1D and Williams Landel Ferry (WLF) Equation constants to simulate the global LVE behavior of the material. The accuracy of the process was assessed regarding both the calculated FRFs and the complex modulus evaluation. Results indicate that the proposed optimization process converges almost perfectly towards the reference FRFs. The simulated complex modulus values are also in very good agreement with the values of the reference material. |
| |
| Keywords: | asphalt mixes complex modulus finite element method frequency response functions linear viscoelasticity optimization process |
|
|
