A numerical study of diversion flow to determine the optimum flow system in open channels

Water Practice & Technology Pub Date : 2024-03-06 DOI:10.2166/wpt.2024.056

T. Alfatlawi, A. H. Hussein

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Abstract

The term ‘branching flow’ describes water extraction from streams or main channels via secondary lateral channels. Through using 3D model simulation, the aims to identify the ideal angle of diversion based on the maximum flow rate to the branching channel and the minimum zone of separation size attained at the entrance channel for the eight grades (900, 750, 600, 450, 300, 250, 200, and 150). An experimental study has previously been confirmed, and this paper provides a comprehensive implementation of the numerical solution (finite volume) using Flow 3D version 11.0.4 software. The validation study was conducted at the Babylon University/College of Engineering /Laboratory of the fluid. The study presented results for many different flow discharge ratios depending on two inflow discharges (12.5 and 18.5 L/s). The comparison between the numerical model and the experimental results revealed statistically a good agreement. The final results demonstrated that a diversion angle of 250 had the most significant optimum angle with the maximum discharge ratio, a minimum separation zone size, and minimum energy losses. Furthermore, the flow rate peaks in the bifurcating channel (5.76 and 8.11 L/s), which accounts for roughly 46.06 and 43.83%, respectively, from the main channel flow.

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对分流进行数值研究，以确定明渠中的最佳水流系统

支流 "一词是指通过次级侧向渠道从溪流或主渠道取水。通过使用三维模型模拟，本文旨在确定理想的分流角度，该角度基于分流渠道的最大流速以及八个等级（900、750、600、450、300、250、200 和 150）的入口渠道所达到的最小分离区尺寸。之前的实验研究已经证实了这一点，本文使用 Flow 3D 11.0.4 版软件提供了数值解决方案（有限体积）的全面实施。验证研究在巴比伦大学/工程学院/流体实验室进行。研究结果显示，根据两个流入流量（12.5 和 18.5 升/秒），得出了许多不同的流量排放比。数值模型与实验结果之间的比较表明，两者在统计上非常吻合。最终结果表明，分流角为 250 的最佳分流角具有最大的排流比、最小的分离区尺寸和最低的能量损失。此外，分叉水道的流量达到峰值（5.76 和 8.11 L/s），分别约占主渠道流量的 46.06% 和 43.83%。

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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Water Practice & Technology

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