Effects of kneading and impact action on the movement of aggregates in asphalt mixtures during compaction: Fid-Bau Portal

Effects of kneading and impact action on the movement of aggregates in asphalt mixtures during compaction

Li, Yupeng / Jiang, Wei / Xiao, Jingjing / Zhao, Funan / Zhang, Shuangjiao / Xing, Chengwei / Yuan, Dongdong

Highlights • Effects of kneading and impact action during compaction process were investigated. • X-ray CT was utilized to analyze and separate the components of specimens. • Compaction processes of the Marshall and SGC method were simulated with DEM. • The trajectories of aggregates were affected by location and compaction methods.

Abstract Current studies on the movement of asphalt mixture components and the formation of internal structures during compaction are lacking. Therefore, this article focuses on the effect of compaction and compaction methods on the movement and contact of mixture components. First, models of asphalt mixtures were established based on X-ray computed tomography (X-CT) and the discrete element method (DEM). Subsequently, compaction processes of the Marshall and Superpave gyratory compactor (SGC) method were simulated, and the model was verified using monitoring results of the smart rock. Finally, the macroscopic air voids, component contacts, and coarse aggregate trajectories were recorded and analyzed. The results showed that, in the early compaction stages, the compactness of the Marshall specimen increased rapidly, which also led to more resistance. The number of contact points and the contact force inside specimens gradually increased with compaction; however, the rate of this increase was different. The trajectories of coarse aggregates were affected by their location and compaction methods, especially the distance to the impacted side and to the center of the cross-section. An edge effect, namely lower compactness at the edges may also be caused by this difference. The movement of aggregates inside the Marshall specimen mainly occurred in the direction of impact. The kneading effect of the SGC method made aggregate particles move and rotate periodically, and compaction efficiency in the later stages was higher.