CNRS, Aix-Marseille Univ., IUSTI UMR 7343, 13453, Marseille, France.
CNRS, Aix-Marseille Univ., Centrale Marseille, M2P2 UMR 7340, 13451, Marseille, France.
Phys Rev E. 2018 Feb;97(2-1):022903. doi: 10.1103/PhysRevE.97.022903.
In a dry granular flow, size segregation had been shown to behave differently for a mixture containing a few large particles with a size ratio above 5 [N. Thomas, Phys. Rev. E 62, 961 (2000)1063-651X10.1103/PhysRevE.62.961]. For moderately large size ratios, large particles migrate to an intermediate depth in the bed: this is called "intermediate segregation." For the largest size ratios, large particles migrate down to the bottom of the flow: this is called "reverse segregation," in contrast with surface segregation. As the reversal and intermediate depth values depend on the fraction of particles, this numerical study mainly uses one single large tracer. Small fractions of large beads are also computed showing the link between single tracer behavior and collective segregation process. For each device (half-filled rotating tumbler and rough plane), two (2D) and three (3D) dimensional cases are distinguished. In the tumbler, the trajectories of a large tracer show that it reaches a constant depth during the flowing phase. For large size ratios, this depth is intermediate. A progressive sinking of the depth is obtained when the size ratio is increased. The largest size ratios correspond to tracers being at the bottom of the flowing layer. All 3D simulation results are in quantitative agreement with the experimental surface, intermediate, and reverse-segregation results. In the flow down a rough incline, a large tracer reaches an equilibrium depth during flow. For large size ratios, the depth is inside the bed, at an intermediate position, and for the largest size ratios, this depth is reverse, located near the bottom. Results are slightly different for a thin or a thick flow. For 3D thick flows, the reversal between surface and bottom positions occurs within a short range of size ratios: no tracer stabilizes near half-height and two reachable intermediate depth layers exist, below the surface and above the bottom reverse layer. For 3D thin flows, all intermediate depths are reachable by a tracer, depending on the size ratio. The numerical study of larger fractions of tracers (5% or 10%) shows the three segregation patterns (surface, intermediate, reverse) corresponding to the three types of equilibrium depth. The reversal is smoother than for a single tracer, and happens around the size ratio 4.5, in good agreement with experiments.
在干颗粒流中,已经表明混合物中含有几个尺寸比大于 5 的大颗粒时,尺寸分离的行为会有所不同[N. Thomas, Phys. Rev. E 62, 961 (2000)1063-651X10.1103/PhysRevE.62.961]。对于中等大小的尺寸比,大颗粒迁移到床层的中间深度:这称为“中间分离”。对于最大尺寸比,大颗粒迁移到流动的底部:这称为“反向分离”,与表面分离相反。由于反转和中间深度值取决于颗粒的分数,因此这项数值研究主要使用单个大示踪剂。还计算了小分数的大珠子,以显示单个示踪剂行为和集体分离过程之间的联系。对于每个设备(半满旋转摇床和粗糙平面),区分了二维(2D)和三维(3D)两种情况。在摇床中,大示踪剂的轨迹表明,在流动阶段,它达到一个恒定的深度。对于较大的尺寸比,这个深度是中间的。当尺寸比增加时,深度逐渐下降。最大尺寸比对应于示踪剂位于流动层的底部。所有 3D 模拟结果都与实验的表面、中间和反向分离结果定量一致。在粗糙倾斜面上的流动中,大示踪剂在流动过程中达到平衡深度。对于较大的尺寸比,深度在床层内,处于中间位置,对于最大的尺寸比,深度是反向的,位于底部附近。对于薄或厚的流动,结果略有不同。对于 3D 厚的流动,在表面和底部位置之间发生反转的尺寸比范围很小:没有示踪剂在半高附近稳定,存在两个可达到的中间深度层,位于表面下方和底部反转层上方。对于 3D 薄的流动,取决于尺寸比,所有中间深度都可以由示踪剂达到。对较大分数(5%或 10%)的示踪剂的数值研究显示了三种分离模式(表面、中间、反向),它们对应于三种平衡深度。反转比单个示踪剂更平滑,大约在尺寸比 4.5 处发生,与实验结果吻合良好。
