A three-layer model for the dam-break flow of particulate suspensions driven by sedimentation

arXiv - PHYS - Geophysics Pub Date : 2024-08-13 DOI:arxiv-2408.06980

Andrea Bondesan, Laurence Girolami, François James, Loïc Rousseau

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Abstract

We introduce a system of Saint-Venant-type equations to model laboratory experiments of dam-break particle-laden flows. We explore homogeneous and non-cohesive liquid-solid suspensions of monodispersed glass beads that propagate as single-phase flows, forming a progressively growing deposit of particles at the bottom of a smooth channel and creating a thin layer of pure liquid at the surface. The novelty of this model is twofold. First, we fully characterize the first-order behavior of these flows (mean velocity, runout distances and deposits geometry) through the sole sedimentation process of the grains, thus avoiding the use of any artificial friction to stop the flow. The model remains very simple and turns out to be effective despite the complex nature of interactions involved in these phenomena. Secondly, the sedimentation dynamics of the grains is observed to not being mainly affected by the flow, but remains comparable to that measured in static suspensions. The mathematical model is validated by comparing the experimental kinematics and deposit profiles with the simulations. The results highlight that this simplified model is sufficient to describe the general features of these flows as well as their deposit morphology, provided that the settling rate is adjusted starting from a critical value of the Reynolds number where the flow agitation begins to significantly delay the mean sedimentation velocity.

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由沉积作用驱动的颗粒悬浮物破坝流动的三层模型

我们引入了一个圣文式方程组来模拟实验室的破坝颗粒流实验。我们探讨了由单分散玻璃珠组成的均质和非粘性液固悬浮液，这些悬浮液以单相流的形式传播，在光滑通道的底部形成逐渐增长的颗粒沉积，并在表面形成一薄层纯液体。该模型的新颖之处有两点。首先，我们通过颗粒的唯一沉积过程完全描述了这些流动的一阶行为（平均速度、流出距离和沉积物的几何形状），从而避免了使用任何人工摩擦来阻止流动。尽管这些现象涉及复杂的相互作用，但该模型仍然非常简单有效。其次，观察到颗粒的沉积动力学并不主要受流动的影响，而是与在静态悬浮液中测得的结果相当。通过将实验运动学和沉积剖面与模拟结果进行比较，验证了该数学模型。结果表明，只要从雷诺数的临界值开始调整沉降速度，流体搅拌开始显著延迟平均沉降速度，这个简化模型就足以描述这些流体的一般特征及其沉积形态。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Geophysics

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