对基底水平变化多样的易侵蚀河床上的溃坝流进行数值研究

IF 2.3 4区环境科学与生态学 Q3 WATER RESOURCES

Journal Of Hydrology And Hydromechanics Pub Date : 2024-02-08 DOI:10.2478/johh-2023-0040

Alireza Khoshkonesh, Blaise Nsom, Saeid Okhravi, Fariba Ahmadi Dehrashid, Payam Heidarian, Silvia DiFrancesco

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引用次数: 0

摘要

本研究旨在全面研究两种不同可侵蚀河床上的基底水平差异和材料成分对坝体断裂波演变的影响。利用流体体积（VOF）方法，我们跟踪了自由表面平流，并利用文献中的实验数据再现了波浪演变。为了验证模型，我们对网格分辨率、湍流模拟方法和床面负荷传输方程进行了全面的敏感性分析。与其他方法相比，大涡流模拟（LES）、非平衡沉积通量和 van Rijn（1984 年）床面负荷公式的实施产生了更高的精度。研究结果强调了底质水平差异和物质组成对断坝形态动力学特征的重要影响。基底水平差异的减小会导致流速、波前进程、自由表面高度、基底侵蚀和其他相关参数的降低。事实证明，最初的空气夹带在波浪前沿非常明显，说明沿底部界面存在明显的水气相互作用。随着基底水平差异翻了两番，希尔兹参数降低了三分之一，在波前观察到的近床浓度最高。这项研究为我们提供了新的视角，使我们了解到影响溃坝波传播和形态变化的各种因素之间复杂的相互作用，从而加深了我们对这一错综复杂现象的理解。

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Numerical investigation of dam break flow over erodible beds with diverse substrate level variations

This study aimed to comprehensively investigate the influence of substrate level difference and material composition on dam break wave evolution over two different erodible beds. Utilizing the Volume of Fluid (VOF) method, we tracked free surface advection and reproduced wave evolution using experimental data from the literature. For model validation, a comprehensive sensitivity analysis encompassed mesh resolution, turbulence simulation methods, and bed load transport equations. The implementation of Large Eddy Simulation (LES), non-equilibrium sediment flux, and van Rijn’s (1984) bed load formula yielded higher accuracy compared to alternative approaches. The findings emphasize the significant effect of substrate level difference and material composition on dam break morphodynamic characteristics. Decreasing substrate level disparity led to reduced flow velocity, wavefront progression, free surface height, substrate erosion, and other pertinent parameters. Initial air entrapment proved substantial at the wavefront, illustrating pronounced air-water interaction along the bottom interface. The Shields parameter experienced a one-third reduction as substrate level difference quadrupled, with the highest near-bed concentration observed at the wavefront. This research provides fresh insights into the complex interplay of factors governing dam break wave propagation and morphological changes, advancing our comprehension of this intricate phenomenon.

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来源期刊

Journal Of Hydrology And Hydromechanics 环境科学-水资源

CiteScore

4.20

自引率

5.30%

发文量

审稿时长

>12 weeks

期刊介绍： JOURNAL OF HYDROLOGY AND HYDROMECHANICS is an international open access journal for the basic disciplines of water sciences. The scope of hydrology is limited to biohydrology, catchment hydrology and vadose zone hydrology, primarily of temperate zone. The hydromechanics covers theoretical, experimental and computational hydraulics and fluid mechanics in various fields, two- and multiphase flows, including non-Newtonian flow, and new frontiers in hydraulics. The journal is published quarterly in English. The types of contribution include: research and review articles, short communications and technical notes. The articles have been thoroughly peer reviewed by international specialists and promoted to researchers working in the same field.