Pohlman Nicholas A, Ottino Julio M, Lueptow Richard M
Department of Mechanical Engineering, Northern Illinois University, DeKalb, Illinois 60015, USA.
Phys Rev E Stat Nonlin Soft Matter Phys. 2009 Sep;80(3 Pt 1):031302. doi: 10.1103/PhysRevE.80.031302. Epub 2009 Sep 10.
The characteristics of steady granular flow in quasi-two-dimensional rotating tumblers have been thoroughly investigated and are fairly well understood. However, unsteady time-varying flow has not been studied in detail. The linear response of granular flow in quasi-two-dimensional rotating tumblers is presented for periodic forcing protocols via sinusoidal variation in the rotational speed of the tumbler and for step changes in rotational speed. Variations in the tumbler radius, particle size, and forcing frequency are explored. Similarities to steady flow include the fastest flow occurring at the free surface of the flowing layer and an instantaneous approximately linear velocity profile through the depth. The flowing layer depth varies by 2-5 particle diameters between minimum and maximum rotation rates. However, unsteady forcing also causes the flow to exhibit dynamic properties. For periodic rotational speeds, the phase lag of the flowing layer depth increases linearly with increasing input forcing frequency up to nearly 2.0 rad over 0-20 cycles per tumbler revolution. The amplitude responses of the velocity and shear rate show a resonance behavior unique to the system level parameters. The phase lag of all flow properties appears to be related to the number of particle contacts from the edge of the rotating tumbler. Characterization via step changes in rotational speed shows dynamic properties of overshoot (up to 35%) and rise times on the order of 0.2-0.7 s. The results suggest that the unsteady granular flow analysis may be beneficial for characterizing the "flowability" and "rheology" of granular materials based on particle size, moisture content, or other properties.
准二维旋转转筒中稳定颗粒流的特性已得到深入研究且相当清楚。然而,非稳态时变流尚未得到详细研究。本文通过转筒转速的正弦变化给出了准二维旋转转筒中颗粒流在周期性强迫协议下的线性响应,以及转速的阶跃变化。探讨了转筒半径、颗粒尺寸和强迫频率的变化。与稳定流的相似之处包括最快的流发生在流动层的自由表面,以及贯穿深度的瞬时近似线性速度分布。在最小和最大转速之间,流动层深度变化2 - 5个颗粒直径。然而,非稳态强迫也会使流表现出动态特性。对于周期性转速,流动层深度的相位滞后随着输入强迫频率的增加而线性增加,在每个转筒旋转0 - 20个周期内,相位滞后接近2.0弧度。速度和剪切速率的振幅响应显示出系统级参数特有的共振行为。所有流动特性的相位滞后似乎与来自旋转转筒边缘的颗粒接触数量有关。通过转速的阶跃变化进行表征显示出超调(高达35%)和上升时间约为0.2 - 0.7秒的动态特性。结果表明,非稳态颗粒流分析可能有助于基于颗粒尺寸、含水量或其他特性来表征颗粒材料的“流动性”和“流变学”。