Saltation of particles in turbulent channel flow

Ji, Chunning; Munjiza, Ante; Avital, Eldad; Xu, Dong; Williams, John

doi:10.1103/physreve.89.052202

Cited by 57 publications

(52 citation statements)

References 42 publications

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“…An IBM algorithm ties the two solvers together. This FSI methodology has already been successfully implemented for a range of problems from bio-fluids of red blood cells flow [18,19] and urine flow in the ureter [20] to sediment [21,22] and marine tidal turbines [10]. In this section, the main points of the method are highlighted, where further details are given in Refs.…”

Section: Methodsmentioning

confidence: 99%

Fluid–structure interaction of flexible submerged vegetation stems and kinetic turbine blades

et al. 2019

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A fluid-structure interaction (FSI) methodology is presented for simulating elastic bodies embedded and/or encapsulating viscous incompressible fluid. The fluid solver is based on finite volume and the large eddy simulation approach to account for turbulent flow. The structural dynamic solver is based on the combined finite element method-discrete element method (FEM-DEM). The two solvers are tied up using an immersed boundary method (IBM) iterative algorithm to improve information transfer between the two solvers. The FSI solver is applied to submerged vegetation stems and blades of small-scale horizontal axis kinetic turbines. Both bodies are slender and of cylinder-like shape. While the stem mostly experiences a dominant drag force, the blade experiences a dominant lift force. Following verification cases of a single-stem deformation and a spinning Magnus blade in laminar flows, vegetation flexible stems and flexible rotor blades are analysed, while they are embedded in turbulent flow. It is shown that the single stem's flexibility has higher effect on the flow as compared to the rigid stem than when in a dense vegetation patch. Making a marine kinetic turbine rotor flexible has the potential of significantly reducing the power production due to undesired twisting and bending of the blades. These studies point to the importance of FSI in flow problems where there is a noticeable deflection of a cylinder-shaped body and the capability of coupling FEM-DEM with flow solver through IBM.

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Section: Methodsmentioning

confidence: 99%

Fluid–structure interaction of flexible submerged vegetation stems and kinetic turbine blades

et al. 2019

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“…To resolve the flow around beds composed of spherical particles, Ji et al . () used the immersed boundary method (IBM). The method was originally developed by Peskin () to simulate the blood flow within a human heart.…”

Section: Introductionmentioning

confidence: 99%

“…However, it is noted that this numerical approach cannot provide much insight on the fluid flow in between the single particles, as the interaction between sediment particles and fluid is simulated without resolving the flow around the particle. To resolve the flow around beds composed of spherical particles, Ji et al (2014) used the immersed boundary method (IBM). The method was originally developed by Peskin (1972) to simulate the blood flow within a human heart.…”

Section: Introductionmentioning

confidence: 99%

Understanding heavy mineral enrichment using a three‐dimensional numerical model

2017

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Layered deposits of relatively light and heavy minerals can be found in many aquatic environments. Quantification of the physical processes which lead to the fine‐scale layering of these deposits is often limited with flumes or in situ field experiments. Therefore, the following research questions were addressed: (i) how can selective grain entrainment be numerically simulated and quantified; (ii) how does a mixed bed turn into a fully layered bed; and (iii) is there any relation between heavy mineral content and bed stability? Herein, a three‐dimensional numerical model was used as an alternative measure to study the fine‐scale process of density segregation during transport. The three‐dimensional model simulates particle transport in water by combining a turbulence‐resolving large eddy simulation with a discrete element model prescribing the motion of individual grains. The granular bed of 0·004 m in height consisted of 200 000 spherical particles (D50 = 500 μm). Five suites of experiments were designed in which the concentration ratio of heavy (5000 kg m−3) to light particles (i.e. 2560 kg m−3) was increased from 6%, 15%, 35%, 60% to 80%. All beds were tested for 10 sec at a predefined flow speed of 0·3 m sec−1. Analysis of the particle behaviour in the interior of the beds showed that the lighter particles segregated from the heavy particles with increasing time. The latter accumulated at the bottom of the domain, forming a layer, whereas the lighter particles were transported over the layer forming sweeps. Particles below the heavy particle layer indicated that the layer was able to armour the particles below. Consequentially, enrichment of heavy minerals in a layer is controlled by the segregation of a heavy mineral fraction from the light counterpart, which enhances current understanding of heavy mineral placer formation.

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“…(16.1) should be supplemented with the trajectory equation, equation for the particle rotation and with the sub-model for the flow velocity, which for simplicity in such models has usually been described by the logarithmic law. However, ideally, the velocity field should be resolved and coupled with the particle motion, as done for example by Ji et al (2014). Initially, the main purpose of constructing the Lagrangian models was the accurate calculation of the amount of transported sediment, mostly in bedload.…”

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confidence: 99%

Lagrangian Modelling of Saltating Sediment Transport: A Review

Bialik

2015

Rivers – Physical, Fluvial and Environmental Processes

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One hundred years of research on the saltation in rivers, both experimental and numerical, has allowed for a fairly good improvement of our knowledge of the physics of the saltation process. Lagrangian modelling has played a huge role in this field and has made it possible to apply the knowledge obtained in the analysis of processes associated with the movement of sediment particles. The present paper briefly reviews the current state-of-the-art of the Lagrangian modelling of saltating grains in open channels and highlights recent findings in three areas in which employment of the Lagrangian models of saltation improve our understanding of sediment transport in rivers, namely: initial motion of saltating grains, diffusion of particles and calculation of the bedload transport rate. The particular challenges in all of these research areas are discussed and future ways forward are presented.

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Saltation of particles in turbulent channel flow

Cited by 57 publications

References 42 publications

Fluid–structure interaction of flexible submerged vegetation stems and kinetic turbine blades

Fluid–structure interaction of flexible submerged vegetation stems and kinetic turbine blades

Understanding heavy mineral enrichment using a three‐dimensional numerical model

Lagrangian Modelling of Saltating Sediment Transport: A Review

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