Farhad Salour Doctoral Thesis
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Summary and Conclusions In cold regions, climatic factors can significantly affect the mechanical behaviour of unbound materials which can influence the overall performance of a pavement. Climate-related pavement deterioration imposes considerable maintenance and rehabilitation efforts on road authorities as well as on public expenditure. In pavement unbound materials, moisture content and temperature (sub-zero temperature) are the two main climatic parameters influencing the mechanical behaviour of unbound layers. Environmental factors, their interaction with pavements and their influence on material behaviour are highly complex in nature. Despite the considerable number of studies that have been conducted during past years, fundamental understating of material behaviour and modelling with respect to environmental factor effects is still lacking. Many studies on stress and moisture dependency of unbound materials are conducted through laboratory experiments which may not fully represent the field conditions. The research work presented in the first part of this thesis intended to provide more insight into pavement in situ environmental factors, unbound material stiffness behaviour and their interaction through field studies. For the field investigation, the Torpsbruk test site was instrumented with moisture, temperature and groundwater level probes and the mechanical behaviour of the pavement was assessed using an FWD device with multilevel impact loads. The pavement environment and structural behaviour were assessed during a spring-thaw period as well as a case study in which the groundwater level at the test site was changed by manipulating the drainage system. The second part of this thesis was mainly based on laboratory investigations through RLT tests using a modified triaxial chamber that allowed for pore suctions measurements throughout the test. The laboratory investigation of moisture effects on pavement unbound materials were based on developing an enhanced approach in predicting the stiffness of the material using principles of soil mechanics for partially saturated conditions and incorporating soil suction in the resilient modulus constitutive models. The permanent deformation properties of the subgrade materials and their sensitivity to moisture content variation have been less studied despite their importance in formation of rut depths in thin flexible pavements. The study conducted here showed the feasibility of using the multistage RLT test for evaluating the permanent deformation properties of fine-grained subgrades. Furthermore, predictive models that were based on multistage RLT tests and the time-hardening approach were developed. This can significantly reduce the time and effort required for conducting permanent deformation tests. The work summarized in this thesis covers different aspects of moisture effects on pavement unbound materials, using both field and laboratory studies. The main findings 52 from each individual study are given in the summary of the respective appended papers. In brief, some of the major finding of the studies can be summarized as the following. From both the field measurements (spring-thaw and groundwater level variations) and the laboratory-based studies it was observed that the moisture content has a significant effect on the mechanical response of the unbound materials and subgrade. In general, as moisture content increased, the stiffness of unbound materials and their resistance to withstand accumulation of permanent deformation decreased. The field measurements at the instrumented test section in Torpsbruk indicated the feasibility and potential of using in situ measurements to better understand the seasonal environmental effects on pavement performance. Even though field studies and instrumentation can be quite challenging and costly, the outcome of these studies can be very valuable and of great interest for developing response models (i.e. moisture-stiffness models). Field measurements can provide in-depth information about the stress and moisture dependency of the material that is so far mainly studied in the laboratory and may not fully represent in situ conditions. Concerning seasonal variation in the resilient modulus due to moisture changes, it was observed from the laboratory study (using RLT tests on two silty sand subgrades) that matric suction could be used and incorporated into the prediction models. Matric suction is the state variable with highest relevance to unsaturated soil mechanics and is highly dependent on the soil structure moisture content. Since moisture content is the main environmentally driven factor affecting the behaviour of unbound layers with a high fines content and subgrade soils, matric suction can be incorporated into the resilient modulus models. Regarding the permanent deformation study, the multistage RLT tests and modelling procedure based on the time-hardening approach were selected. This allowed for more comprehensive study of the material stress dependency compared to the conventional single stage RLT procedures. The multistage RLT test procedure enabled testing the material under a wider range of stresses with considerably less laboratory effort and time. This study also showed the significance of moisture content on the permanent deformation behaviour of the two different silty sand subgrade materials that were tested. Yüklə 4,52 Mb. 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