Research on high-temperature rheological performance of fiber reinforced high-viscosity asphalt mastics: Fid-Bau Portal

Research on high-temperature rheological performance of fiber reinforced high-viscosity asphalt mastics

Chen, Long / Chen, Jingyun / Li, Mingliang / Li, Jun / Li, Yuhua

Highlights • High-temperature rheological properties of HVAM with different types of fibers were investigated. • The increased specific surface area of fillers helps to improve the deformation recovery ability of HVAM. • Increasing the amount of fiber within a certain range is helpful to improve the rutting resistance of HVAM . • The enhancement of the fiber to the HVAM is more obvious in the low frequency.

Abstract High-temperature performance of high-viscosity asphalt mastic containing fiber additive were studied by means of rheological analysis. The effects of two types of asphalt, two types of fillers, and two types of fibers with three fiber contents on the high-temperature rheological properties of asphalt mastic were evaluated by temperature sweep test, multiple stress creep recovery test, and frequency sweep test using a dynamic shear rheometer. The master curve of fiber reinforced high-viscosity asphalt mastic and phase angle were constructed using 2S2P1D model. The results show that the nature of asphalt plays a leading role in improving the resistance to deformation of asphalt mastic at high temperature, compared with the type of mineral powder. For the short-term aging asphalt mastic, with temperature increasing, the unrecoverable creep compliance gradually increases and the differences between asphalt mastic with different fiber contents also become greater. The creep recovery rate of mastic with basalt fiber is much higher than that of polyester fiber under the same conditions. For long-term aging asphalt mastic, compared with increasing fiber content, the fiber type has more significant influence on the storage modulus. 2S2P1D model can well fit the master curve of the complex modulus of fiber reinforced high-viscosity asphalt mastic, but poorly fit with the phase angle. From master curves, it finds that the enhancement of the fiber to mastic is prominent in the low frequency which is corresponding to the extreme high-temperature condition.