Performance of epoxy asphalt binder containing warm-mix asphalt additive

Sasobit has been widely applied as warm-mix asphalt (WMA) additive in an environment friendly and energy saving pavement construction. Epoxy asphalt (EA) has been extensively used on the pavement of steel bridge decks. In the present paper, Sasobit was introduced into warm-mix epoxy asphalt binder (...

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Bibliographic Details
Published inThe international journal of pavement engineering Vol. 22; no. 2; pp. 223 - 232
Main Authors Gong, Jie, Liu, Ya, Jiang, Yongjia, Wang, Qingjun, Xi, Zhonghua, Cai, Jun, Xie, Hongfeng
Format Journal Article
LanguageEnglish
Published Abingdon Taylor & Francis 28.01.2021
Taylor & Francis LLC
Subjects
Asphalt
Asphalt pavements
Binders (materials)
Bridge decks
Crystal structure
Crystallinity
Damping
damping properties
Epoxy asphalt
Glass transition temperature
Lamellar structure
Mechanical properties
Morphology
Pavement construction
Pavements
Phase separation
Steel bridges
Tensile strength
Thermal stability
Viscosity
warm-mix asphalt additive
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Summary:Sasobit has been widely applied as warm-mix asphalt (WMA) additive in an environment friendly and energy saving pavement construction. Epoxy asphalt (EA) has been extensively used on the pavement of steel bridge decks. In the present paper, Sasobit was introduced into warm-mix epoxy asphalt binder (WEAB) to prepare Sasobit modified WEAB. The effect of Sasobit on the viscosity, thermal, damping and mechanical properties and morphology of the neat WEAB were investigated using various characterisation techniques. Sasobit significantly lowered the viscosity of the neat WEAB and prolonged the operational lifetime for mixture pavement. Sasobit lowered the glass transition temperature of the neat WEAB. Sasobit slightly decreases the damping properties and thermal stability of the neat WEAB. However, Sasobit increased the tensile strength of the neat WEAB. The crystalline network structures of Sasobit formed in asphalts were clearly observed. The lamellar crystalline structure of Sasobit turned to gel-like structure in curly ribbon shape with an increase of the WMA additive contents. Reaction-induced phase separation occurred in the neat WEAB and Sasobit modified WEABs. No crystalline network structures of Sasobit were observed in the dispersed asphalt phase of the modified WEABs. Sasobit decreased the size of asphalt particles in the continuous epoxy phase.
ISSN:1029-8436
1477-268X
DOI:10.1080/10298436.2019.1597272