Mesoscale Numerical Analysis of Fiber-Reinforced Sand with Different Fiber Orientations Subjected to Seepage-Induced Erosion Based on DEM

This paper focuses on the effect of fiber orientation on the resistance of seepage-induced erosion in fiber-reinforced sand. To clarify the discrepancy and mechanism of different-oriented fibers improving the resistance of the sand matrix, a series of DEM-Darcy coupling simulations were conducted. The microscopic parameters of fiber-reinforced sand were confirmed by the rigorous calibration procedure. The fibers perpendicular to the seepage direction were found to increase the difficulty of moving fluid through the specimen and significantly reduce the erosion rate of the specimen. These macroscopic behaviors acquired corresponding explanations at the mesoscopic scale, including the evolution of fiber-sand contact orientation, coordination number, average normal contact force, tensile force, and energy dissipation. According to the simulation results, it is found that the highest proportion of tensile force in perpendicular fibers can reach 80%, while the parallel fibers are only 40%, which indicates that the perpendicular fibers have a significant netting effect. The mesoscopic behaviors reasonably revealed the role of the fibers with different orientations on the sand matrix during the seepage. This study is beneficial for further understanding the mechanical behaviors of fiber-reinforced sand under seepage-induced erosion in safety engineering.

Automated summary

This paper investigates the impact of fiber orientation on the resistance of seepage-induced erosion in fiber-reinforced sand. DEM-Darcy coupling simulations were carried out to understand the discrepancy and mechanism of different-oriented fibers improving the resistance of the sand matrix. The results revealed that fibers perpendicular to the seepage direction impeded fluid flow and reduced erosion significantly. Mesoscopic behaviors, such as fiber-sand contact orientation, coordination number, average normal contact force, tensile force, and energy dissipation, explained these macroscopic behaviors. The study provides insights into the mechanical behaviors of fiber-reinforced sand in seepage-induced erosion for safety engineering.