Farhad Salour Doctoral Thesis
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4.2.
Seasonal variation in thin flexible pavements structural stiffness Most of the thin flexible pavement structures in cold regions experience considerable seasonal variations in stiffness (Simonsen and Isacsson, 1999). The conceptual overall seasonal variation in bearing capacity of the pavements in cold regions includes a significant increase in stiffness during the winter period. Besides the stiffness variation of the asphalt concrete layer due to seasonal temperature changes, pavement unbound materials also exhibit considerable seasonal variations due to the freezing and thawing effects (Saarenketo and Aho, 2005). Frost penetration in the pavement structures creates strong bonds between the unbound particles as the moisture surrounding the particles freezes. This results in a very stiff matrix of granular material and subgrade soil particles (Simonsen et al., 2002). Therefore, during the frost period, pavements exhibit high overall stiffness and can usually support heavy traffic axle loads without any problem. This increase in the overall stiffness of the pavement system due to frost penetration depends on many factors such as the depth of the frost zone, material properties and the pre-freezing moisture content. The frost depth and length of the frost period depends on the geographical position and the climate of the road section. This condition usually lasts throughout the winter period. However, short thawing periods can occur if the air temperature rises above zero degrees Celsius (0°C). The surface intermittent thawing can penetrate up to a few decimetres in depth and cause a temporary decrease in the unbound granular layer stiffness. The length of the surface thawing can vary from a few hours up to a few days, depending on the weather condition. As the air temperature drops to below freezing temperature, the surface thaws refreeze and the layers regain their high stiffness. 19 The major thaw weakening phase, often referred as structural thaw weakening, occurs when thawing penetrates deeper into the pavement structure or in the subgrade soil. During this period all the segregation ice lenses that were generated during the freezing period convert back into the liquid form as the temperature deeper in the pavement structure rises to above freezing values. A considerable amount of excess moisture is usually released in the pavement structure. Since thawing is a top-bottom process, the moisture content of the thawed sections above the thawing ice lenses can be significantly high since draining paths are trapped (Simonsen and Isacsson, 1999; Saarenketo and Aho, 2005). As this section is surrounded by the asphalt concrete layer at the top and the thawing ice lenses at the bottom, hydrostatic pore pressures can be built up due to heavy traffic load passages. This can cause pumping of the fines of the material as moisture flows to the sides and therefore loss of support. The spring-thaw period is usually followed by a “recovery” period during which the bearing capacity of the pavement system is recovered. In granular base and subbase layers, the stiffness of the material is usually regained shortly after the spring-thaw period is over as the excess moisture drains and the layer recovers. This is due to the relatively high permeability in the granular materials. However, in subgrade soils, the recovery period usually takes place over a much longer time, especially if the fines content of the material is high (e.g. moraines, silty and clayey materials). Full recovery of subgrade soils can take from a few weeks up to a few months, depending on the material permeability and the drainage condition of the pavement structure. Figure 10 illustrates the principal changes in overall stiffness of pavements in cold regions. Yüklə 4,52 Mb. Dostları ilə paylaş:
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