Farhad Salour Doctoral Thesis
particle interlock strength (Lekarp et al., 2000; Ekblad and Isacsson, 2006). In
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particle interlock strength (Lekarp et al., 2000; Ekblad and Isacsson, 2006). In fine-grained materials and subgrade soils, in addition to the lubricating effect, pore water usually affects the effective stress of the soil structure due to a decrease in pore suction which will result in decreased reduction in material stiffness. In materials with low permeability that are exposed to frequent heavy traffic stress loads, pore pressure build-up may also take place which can result in considerable bearing capacity loss (Yang et al., 2008; Cary and Zapata, 2011; Nowamooz et al., 2011). All other factors remaining unchanged, an increase in moisture content results in larger resilient and plastic strains and accelerate the rate of distresses in pavement structures (ARA, 2004). Pavement moisture content and its influence on the behaviour of unbound materials has been the subject of many laboratory-based and field investigations. Some of the moisture related studies found in the literature are presented below. 6.1. Laboratory-based investigation and measurements Conventional repeated load triaxial testing In pavement engineering, the mechanical response of the pavement materials are traditionally characterized using the total stress approach. In spite of the fact that pavement unbound layers are usually in partially saturated conditions, the effect of soil suctions is not generally considered. At laboratory scale, the material mechanical response is widely characterized using RLT tests. When using the conventional total stress approach, the effect of moisture content on the mechanical behaviour of unbound materials is generally taken into account later in the design process using adjusting models (described later). Ekblad and Isacsson (2006) investigated the influence of moisture on the resilient properties of coarse-grained granular materials with different grading using a large scale 32 triaxial cell. They monitored the moisture content of the specimen using two TDR probes buried in the specimen. They reported a significant loss in the resilient modulus with increase in moisture content, particularly in specimens with high fines content. The effect of moisture content on the resilient modulus was considerably less in specimens with coarser grading. Andrei (2003) conducted an extensive laboratory test program using the RLT method for both coarse-grained and fine-grained materials. The materials used in the study consisted of four base and four subgrade materials that are typically encountered in Arizona. The RLT tests were conducted at different moisture contents and compaction degrees to develop a resilient modulus predictive model that could estimate changes in the resilient modulus as a function of compaction degree, stress level and moisture content. Considerable changes in the resilient modulus were observed due to moisture content variations. Plastic subgrade materials were in particular very sensitive to moisture and the resilient modulus variations from 14 to more than 1350 MPa were observed due to changes in moisture content. However, for non-plastic soil and base material, the impact was much less. These materials exhibited up to three times higher resilient modulus values as the moisture content was reduced compared to the optimum moisture content. M R -Moisture adjustment models Several models have been developed to incorporate the effect of moisture content and its variations when predicting the resilient modulus of unbound pavement materials. Most of the developed models are based on laboratory testing of unbound materials at differing moisture contents. A simple approach that has gained popularity over the recent years is the predictive M R -Moisture model proposed in Mechanistic-Empirical Pavement Design Guide (ARA, 2004). This one-dimensional model directly incorporates variations in the moisture content to the resilient modulus of unfrozen unbound materials using an adjustment factor given as the following: )) ( ) exp(ln( 1 log opt s R R S S k a b a b a M M opt [8] where opt R R M M = resilient modulus ratio; R M is the resilient modulus at a given time and opt R M is the resilient modulus at a reference condition. Further is a = minimum of ) log( opt R R M M , b = maximum of ) log( opt R R M M , s k = regression parameter and ) ( opt S S = variation of degree of saturation expressed in decimal. 33 This empirical model and its regression parameters were developed through extensive laboratory triaxial tests conducted by Andrei (2003). Figure 16 shows the M R -Moisture model for both the fine-grained and coarse-grained materials proposed in MEPGD. Yüklə 4,52 Mb. Dostları ilə paylaş:
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