Abstract
When temperatures drop to significantly low levels, road pavements are subjected to thermally-induced stresses, resulting in the appearance of thermal cracking, among other distresses. In these situations, polymers can be used as asphalt binder modifiers to improve certain asphalt binder properties, such as elastic recovery, cohesion, and ductility. Polymers also minimize some of the problems of asphalt mixtures, such as thermal and fatigue cracking and permanent deformation. This work’s objective was to study the behavior of asphalt mixtures at low temperatures, mainly when using modified binders. Thus, three binders were selected and tested: a standard 50/70 penetration grade bitumen and two polymer-modified binders (PMB), obtained by adding, respectively, 2.5% and 5.0% of styrene–butadiene–styrene (SBS) in the 50/70 pen grade bitumen. Then, the PMBs were incorporated into stone mastic asphalt mixtures (namely SMA 11), which were subjected to low-temperature mechanical tests based on the most recent European Standards. The asphalt binders and mixtures evaluated in this work were tested for thermal cracking resistance, creep, elastic recovery, cohesive strength, and ductility strength. Overall, it is concluded that the studied asphalt mixtures with PMB, with just 2.5% SBS, performed adequately at low temperatures down to −20 °C.
Highlights
This paper aims to evaluate the influence of asphalt binder and its modification in the asphalt mixtures’ low-temperature performance
Stone mastic asphalt (SMA) was selected for this study as an excellent example of the current type of asphalt mixtures used in cold climate regions
The mixture reached a maximum strain level of 5.79‰ and recovered 0.63‰, which results in a recovery of only 11% of the maximum deformation. These results indicate that this asphalt mixture most likely will not present deformation issues at very low temperatures
Summary
This paper aims to evaluate the influence of asphalt binder and its modification in the asphalt mixtures’ low-temperature performance. Several laboratory methods and techniques were used to characterize the asphalt binders and obtain the tensile strength properties of asphalt mixtures at cold temperatures. Stone mastic asphalt (SMA) was selected for this study as an excellent example of the current type of asphalt mixtures used in cold climate regions. Styrene (SBS) modification of asphalt binder and its effect on the low-temperature performance of SMA were evaluated. This paper should contribute to depict as closely as possible the actual conditions and behavior to which asphalt pavements are subjected when low temperatures are present, thereby expanding the current knowledge about the variables involved in the process. This work aims to add some knowledge on the response to challenges transport infrastructures face in regions with cold climates
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