Farhad Salour Doctoral Thesis
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- FIGURE 17. Location of the Torpsbruk test site along county road 126 in southern Sweden.
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7.
Summary of the Papers 7.1. Paper I and II The appended papers present environmental data measurements, analyses and findings from the field studies carried out in the Torpsbruk test site along county road 126 in southern Sweden (Figure 17). The pavement structure consists of a 100 mm thick HMA layer (dense graded mix, 16 mm maximum grain size and 160/220 bituminous binder penetration grade) with 160 mm crushed gravel base and 300 mm natural sandy gravel subbase layers. The subgrade soil at the test section is classified as sandy silt material with more than 25% fines content resting on bedrock layer at 3.0 to 3.5 m depth. Pavement environmental factor data collection mainly consisted of groundwater level sensors (six groundwater rods with automatic data logger in the transverse direction of the road), subsurface volumetric moisture content sensors (four moistures rods each consisting of four sensors with automatic data logger) and temperature sensors (one frost rod). A schematic overview of the test site instrumentation is illustrated in Figure 18. The structural response of the pavement was measured using a trailer-mounted KUAB FWD device with multilevel loads. FIGURE 17. Location of the Torpsbruk test site along county road 126 in southern Sweden. 36 FIGURE 18. Schematic overview of the pavement instrumentations (GW: groundwater probes, MC: Moisture content probes). Paper I mainly focuses on investigating the structural behaviour of the pavement system during the spring-thaw period in 2010 (Figure 19). During the study period, the pavement profile subsurface temperature and moisture content were measured and the structural behaviour of the pavement was assessed using frequent FWD measurements. Figure 20 shows the deflection basin variations during the thawing and the recovery periods in 2010. As thaw penetrated the pavement structure, the moisture that was accumulated in the pavement structure during the freezing period in the form of ice lenses converted back into the liquid phase. Thaw penetration broke down the particle ice-bonds which also releases excess moisture into the pavement system. This resulted in a considerable decrease in the overall stiffness of the pavement system (Figure 20, left). As the excess moisture was further drained out from the pavement structure, the unbound layers regained their pre-freezing stiffness and the pavement recovered (Figure 20, right). |