Mixing-phase model for shear-induced contractive/dilative effects in unsteady water-sediment mixture flows

IF 4 2区 环境科学与生态学 Q1 WATER RESOURCES
S. Martínez-Aranda, J. Fernández-Pato, P. García-Navarro
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引用次数: 0

Abstract

Among the geophysical surface processes, mud and debris flows show one of the most complex and challenging behaviour for scientists and modellers. These flows consist of highly-unsteady gravity-driven movements of water-sediment mixtures with non-Newtonian rheology where the solid concentration could be about 40%–80% of the flow volume and which occur along steep and irregular terrains. Furthermore, the appearance of dynamic pressures in the fluid filling the intergranular pores increases the complexity and dominates the behaviour of the fluidized water-sediment material, leading to the appearance of significant density gradients during the movement. The dynamic pressure in the pore-fluid changes the effective normal stress within the mobilized material, affecting the frictional shear stress between grains and leading to the solid phase dilation/contraction. This must be properly accounted for when developing realistic models for water-sediment surface flows. In this work, a novel physically-based approach for modelling multi-grain dense-packed water-sediment flows is presented. A novel closure formulation for the pressure distribution within the pore-fluid during the movement of dense-packed water-sediment materials has been derived. This closure allows to relate the appearance of shear-induced dynamic pore pressures to the contractive/dilative behaviour of the solid aggregate. The resultant system of depth-averaged conservation laws includes continuity of the density-variable water-sediment material and the different solid classes transported in the flow, as well as the linear momentum equation for the fluidized bulk material, and it is solved using a well-balanced fully-coupled Finite Volume (FV) method. The resultant simulation tool is faced to synthetic, laboratory and real-scale benchmark cases to test its robustness and accuracy. The presence of dynamic pore pressures within the pore-fluid leads to the appearance of a deviatoric contribution to the solid flux, which causes the shear-induced separation of the solid and liquid phases and sustains the flow mobility for long distances, as it has been observed in real mud and debris events.

非稳定水沙混合物流中剪切诱导收缩/扩张效应的混合相模型
在地球物理表面过程中,泥流和碎屑流的行为对科学家和建模人员来说是最复杂和最具挑战性的。这些泥石流由具有非牛顿流变学的水-沉积物混合物的高度非稳定重力驱动运动组成,其中固体浓度可能占泥石流体积的 40%-80% 左右,并且发生在陡峭和不规则的地形上。此外,充满晶间孔隙的流体中出现的动态压力增加了流化水-沉积物的复杂性,并主导了流化水-沉积物的行为,导致运动过程中出现明显的密度梯度。孔隙流体中的动态压力会改变流动材料内部的有效法向应力,影响颗粒之间的摩擦剪应力,导致固相扩张/收缩。在开发逼真的水-沉积物表面流动模型时,必须适当考虑到这一点。本研究提出了一种基于物理的新方法,用于模拟多颗粒致密堆积水-沉积物流动。针对致密堆积水-沉积物运动过程中孔隙流体内部的压力分布,我们提出了一种新颖的闭合公式。该闭合公式可将剪切引起的动态孔隙压力的出现与固体集料的收缩/疏松行为联系起来。由此得出的深度平均守恒定律系统包括密度可变的水沉积材料和在流动中传输的不同固体类别的连续性,以及流化散体材料的线性动量方程,并使用平衡良好的全耦合有限体积(FV)方法进行求解。结果模拟工具可用于合成、实验室和实际规模的基准案例,以测试其稳健性和准确性。孔隙流体中动态孔隙压力的存在会导致固体流量出现偏差,从而引起固相和液相的剪切分离,并使流体的流动性保持较长的距离,这在实际的泥石流事件中已经观察到。
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来源期刊
Advances in Water Resources
Advances in Water Resources 环境科学-水资源
CiteScore
9.40
自引率
6.40%
发文量
171
审稿时长
36 days
期刊介绍: Advances in Water Resources provides a forum for the presentation of fundamental scientific advances in the understanding of water resources systems. The scope of Advances in Water Resources includes any combination of theoretical, computational, and experimental approaches used to advance fundamental understanding of surface or subsurface water resources systems or the interaction of these systems with the atmosphere, geosphere, biosphere, and human societies. Manuscripts involving case studies that do not attempt to reach broader conclusions, research on engineering design, applied hydraulics, or water quality and treatment, as well as applications of existing knowledge that do not advance fundamental understanding of hydrological processes, are not appropriate for Advances in Water Resources. Examples of appropriate topical areas that will be considered include the following: • Surface and subsurface hydrology • Hydrometeorology • Environmental fluid dynamics • Ecohydrology and ecohydrodynamics • Multiphase transport phenomena in porous media • Fluid flow and species transport and reaction processes
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