防汛堤防稳定试验研究

IF 2.4 Q2 GEOSCIENCES, MULTIDISCIPLINARY
Sohail Iqbal, Norio Tanaka
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引用次数: 0

摘要

防洪堤与自然环境浑然一体。这些堤坝是重要的屏障,减轻了洪水的灾难性影响,保护了社区和生态系统。它们的设计不仅有助于控制水流,而且确保对当地环境和生物多样性的破坏最小。本研究使用d50 = 0.9 mm的均匀无粘性砂来研究单个联合堤防(透水和不透水)附近的局部冲刷过程,模拟了洪水情景。实验表明,最大冲刷深度可能发生在堤坝的上游边缘,类似于在明渠中缩小的堤坝周围观察到的局部冲刷。堤坝下游的冲刷孔越小越浅,围绕着它的马蹄形漩涡也是如此。此外,通过组合不同形状的桩,改变堤防周围的水流,以减少马蹄涡,从而使堤防前端的冲刷长度和深度分别减少48%,上游和下游堤防-墙交界处的冲刷长度和深度分别减少45%和65%。相反,堤防下游的沉降高度对渗透作用呈反比作用,严重损害堤防体系。联合堤防通过减少堤防周围形成的水流漩涡,证明了它们减轻冲刷的能力。建议的解决方案可以减缓迅速恶化的速度,并保护堤坝和其他河流管理基础设施免受洪水造成的破坏。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
An Experimental Investigation on Dike Stabilization against Floods
A flood protection dike blends seamlessly with natural surroundings. These dikes stand as vital shields, mitigating the catastrophic effects of floods and preserving both communities and ecosystems. Their design not only aids in controlling water flow but also ensures minimal disruption to the local environment and its biodiversity. The present study used a uniform cohesionless sand with d50 = 0.9 mm to investigate the local scour process near a single combined dike (permeable and impermeable), replicating a flooding scenario. The experiments revealed that the maximum scour depth is likely to occur at the upstream edge of the dike, resembling a local scour observed around a scaled-down emerged dike in an open channel. The scour hole downstream of the dike gets shallower as it gets smaller, as do the horseshoe vortices that surround it. Additionally, by combining different pile shapes, the flow surrounding the dike was changed to reduce horseshoe vortices, resulting in scour length and depth reductions of 48% at the nose and 45% and 65% at the upstream and downstream dike–wall junction, respectively. Contrarily, the deposition height downstream of the dike had a reciprocal effect on permeability, which can severely harm the riverbank defense system. The combined dike demonstrates their ability to mitigate scour by reducing the flow swirls formed around the dike. The suggested solutions can slow down the rapid deterioration and shield the dike and other river training infrastructure from scour-caused failures.
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来源期刊
Geosciences (Switzerland)
Geosciences (Switzerland) Earth and Planetary Sciences-Earth and Planetary Sciences (all)
CiteScore
5.30
自引率
7.40%
发文量
395
审稿时长
11 weeks
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