Farhad Salour Doctoral Thesis
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46 7.4. Paper VI Rutting is one of the main distress modes in flexible pavements. In thin pavement structures, rutting is often associated with accumulation of permanent deformation in unbound layers under repeated loads. Realistic prediction of surface rutting requires models that can reliably capture the cumulative plastic deformation of pavement unbound layers under repetitive traffic loads. Paper VI presents an evaluation of several models that incorporate the time-hardening concept for prediction of permanent deformation of unbound materials using data from tests conducted on two different silty sand subgrade materials. The time-hardening concept was adopted on the Tseng and Lytton (1989), Gidel et al. (2001) and the Korkiala-Tanttu (2005) permanent deformation models so that the data from the multistage RLT tests could be used for the evaluation. These permanent deformation models combine the influence of the number of load applications with the effect of material stress state. The details of these modified models are presented below. The modified Tseng and Lytton (1989) model assumes a direct relationship between the permanent strain and the resilient strain and is presented as follows: ) ( 0 1 ˆ eq i i i N N N r i p e N [9] where, i p ˆ is the accumulated permanent deformation and i r is the resilient strain in the stress path i . The 0 , and are material parameters and eq i N is defined as follows: 1 1 ˆ ln o r p eq i i i N [10] The modified Gidel et al. (2001) model additionally requires shear strength parameters (obtained from static triaxial tests) and is rewritten as followed: 1 max, max, max, max, 1 0 100 1 ˆ i i i u a i B eq i i p p q p s m p L N N N N i [11] where 0 , B and u are material parameters. max p and max q are the maximum applied hydrostatic stress and deviator stress, respectively, and max max max, q p L i . The parameters m and s are the slope and the intercept of the Mohr-Coulomb failure line in the q p space, respectively, obtained from static triaxial tests. a p is the reference stress, here selected as100 kPa. 47 B i i i u a i p eq i p q p s m p L N i 1 1 max, max, max, max, 0 1 ˆ 1 100 [12] The modified Korkiala-Tanttu (2005) model for multistage test procedure is presented as follows: i i b eq i i p R A R N N N C N i ) ( ˆ 1 [13] b i i p eq i CR R A N i 1 ) ( ˆ 1 [14] where C is material parameter and i R is the shear stress ratio of the deviator stress in the stress path i to the deviator stress at failure. A is the maximum theoretical value for the shear stress ratio and parameter b is recommended as follows (Korkiala-Tanttu, 2005): d cR b [15] where c and d are material parameters. In all of the equations above, the subscript i refers to the th i stress path . The multistage repeated load triaxial (RLT) tests were carried out on two silty sand subgrades at four different moisture contents. The test data were then used to optimize the material parameters for each predictive model and moisture content. The calibrated model curves and the measured data together with the shakedown ranges are presented in Figures 31 and 32. |