Self-aeration on large dam spillways during major floods

IF 2.4 3区 环境科学与生态学 Q2 ENGINEERING, CIVIL Journal of Hydro-environment Research Pub Date : 2024-03-16 DOI:10.1016/j.jher.2024.03.002
Hubert Chanson
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Abstract

In a spillway chute flow, the upstream flow is typically non-aerated and the flow becomes self-aerated when the turbulent stresses acting next to the water surface exceeds the combined resistance of gravity and surface tension. The inception region of air entrainment is a rapidly-varied region characterised by the transition from a monophase water to two-phase air–water flow. In this contribution, field observations were conducted at large dam spillways during major flood events, with a focus on prototype data for discharges between 100 m3/s and 6,000 m3/s and Reynolds numbers between 2.6 × 106 to 1.1 × 108. The onset of self-aeration was a complicated three-dimensional transient process, and the dimensionless location of the inception region was a function of the Reynolds number. Surface velocities obtained with an optical technique showed that the streamwise surface velocities were close to theoretical estimates, and the streamwise surface turbulent intensities in excess of 100 %, consistent with self-aerated measurements in laboratory. The current findings yield a couple of seminal questions: (a) what do we know about prototype spillway operation during major floods? (b) how large the Reynolds number of a prototype flow needs to be truly representative of large dam spillway self-aerated flows during major flood events?

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大洪水期间大型水坝溢洪道的自曝气功能
在溢流槽水流中,上游水流通常是非气流,当作用在水面附近的湍流应力超过重力和表面张力的综合阻力时,水流就会自发气流。空气夹带的起始区域是一个快速变化的区域,其特点是从单相水流过渡到气水两相流。在本文中,我们在大洪水期间对大型水坝溢洪道进行了实地观测,重点是流量在 100 立方米/秒至 6,000 立方米/秒之间、雷诺数在 2.6 × 106 至 1.1 × 108 之间的原型数据。自曝气的起始是一个复杂的三维瞬态过程,起始区域的无量纲位置是雷诺数的函数。利用光学技术获得的表面速度显示,流向表面速度接近理论估计值,流向表面湍流强度超过 100%,与实验室自曝气测量结果一致。目前的研究结果提出了几个重要问题:(a) 我们对大洪水期间原型溢洪道的运行了解多少?(b) 原型水流的雷诺数需要多大才能真正代表大洪水期间大型水坝溢洪道的自曝流?
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来源期刊
Journal of Hydro-environment Research
Journal of Hydro-environment Research ENGINEERING, CIVIL-ENVIRONMENTAL SCIENCES
CiteScore
5.80
自引率
0.00%
发文量
34
审稿时长
98 days
期刊介绍: The journal aims to provide an international platform for the dissemination of research and engineering applications related to water and hydraulic problems in the Asia-Pacific region. The journal provides a wide distribution at affordable subscription rate, as well as a rapid reviewing and publication time. The journal particularly encourages papers from young researchers. Papers that require extensive language editing, qualify for editorial assistance with American Journal Experts, a Language Editing Company that Elsevier recommends. Authors submitting to this journal are entitled to a 10% discount.
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