确定倾斜水槽闸门下游的水流模式,有 3 种不同的倾斜角度。

Djoni Irianto, Naufal Dhiya Ulhaq
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引用次数: 0

摘要

倾斜水槽中的水流在观测时经常会发生变化。这种现象与水流穿过明渠时渠道底面角度的变化密切相关,这种变化是由水利研究人员输入水源或从水库抽水造成的。水流通过明渠时,会受到渠道底面轮廓和各种角度的影响。当给定一定的排水量时,可以在水面上观察到可见的水流形态,而水面上不可见的水流被称为能量栅线(EGL)。如果不对渠道中产生的能量进行测量,可能会导致水跳。可以通过观察结构化水跃来了解发生的流动模式。为避免出现未被发现的水流模式,需要采用水力结构,其中之一就是下方开口的水闸,俗称水闸。这种水闸易于操作,既可以手动操作,也可以在有多余水源的情况下操作。由于水闸下游的水深和水位跃差的影响,计算运行所需的水量具有挑战性。通常情况下,水力跃差往往会忽略这些测量值,这在高峰流量条件下供水过剩时会成为一个障碍。为了解决这个问题,有必要使用一种被称为水闸的仪器进行模型试验,这种仪器可以产生水力跃层。这一研究领域需要在实验室中进一步探索。设备中的水闸模型配有仪器、各种闸门开口和可调节的加压水闸,流速可测量。为了使用流量表测量仪器分析跃层高度、水流模式和流速,研究人员使用三种特定的闸门开口进行了试验,测试并测量了渠道底坡不同位置的深度(Y)。测试从闸门开度为 0.5、0.75 和 1.00 开始,读取仪器读数,将闸门位置从深度 2 厘米移动到最高深度 5 厘米。水闸仪器是一种手动操作的滑动闸门式仪器,研究人员将水闸仪器的测试结果绘制成图表,对每个闸门开口进行了三次测试,并在测试仪器上抽水、记录和绘制仪器显示的深度值、跳跃长度和移动时间。水闸试验分析的后续建议旨在为水利工程规划提供信息,表明在特定条件下各种坡度的试验结果具有不同的深度值和跳跃时间(t)。此外,研究人员还确定了模型闸门的定位,可用于确定跳闸后的水深(Y)(厘米)。这项实验室研究涉及一个水道模型。本研究的目的是在期刊上发表一篇文章,介绍模拟结果,以确定在具有三种不同底坡角(5°、15°、25°)的渠道中出现的水流模式。研究结果将以表格和图表的形式呈现,然后记录在提交给国际期刊的文章中。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
DETERMINATION OF FLOW PATTERNS OCCURRING AT THE DOWNSTREAM OF A TILTING FLUME CHANNEL GATE WITH 3 VARIATIONS OF INCLINATION ANGLES.
Flow that occurs in the tilting flume channel often changes when observed. This phenomenon is closely related to the variation in the channel's bottom angle as it crosses the open channel, resulting from water input supply or water supply from reservoirs pumped by water researchers. The flow of water through the open channel is influenced by the presence of the channel's bottom surface profile and various angles. When a certain discharge is given, visible flow patterns can be observed on the water surface, while the unseen flow above the water surface is referred to as the Energy Gride Line (EGL). If the energy that occurs in the channel is not measured, it may lead to water jumping. The structured water jump can be observed to understand the flow patterns that occur. To avoid undetected flow patterns, hydraulic structures are required, one of which is a water gate with an opening below, commonly known as a Sluice Gate. This water gate is easily operable, either manually or with the availability of excess water supply. Calculating the operational water requirements can be challenging due to the influence of the depth and jumps occurring downstream of the gate. Often, the hydraulic jump's differences tend to overlook these measurements, which can become a hindrance when there is an excess water supply during peak flow conditions. To address this issue, it is necessary to conduct a model test using an instrument known as the Sluice Gate, which generates hydraulic jumps. This area of research needs further exploration in the laboratory. The Sluice Gate model in the equipment is equipped with instruments, various gate openings, and adjustable pressurized water gates with measurable flow rates. To analyze the jump height, flow patterns, and velocity using a flow watch measuring instrument, the researchers conducted tests with three specific gate openings, testing and measuring the depths (Y) at different positions of the channel's bottom slope. The test started with gate openings of 0.5, 0.75, and 1.00, reading the instrument, moving the gate positions from a depth of 2 cm to the highest depth of 5 cm. Graphing the test results of the Sluice Gate apparatus, which is a sliding gate-type apparatus manually operated, the researchers conducted three tests for each gate opening with pumping, recording, and mapping the depth values, jump lengths, and travel times from the instrument on the testing apparatus. The subsequent recommendation of the Sluice Gate test analysis is intended to provide information for water construction planning, indicating that the test results with various slopes under certain conditions have different depth values and jump times (t). Furthermore, the researchers determine the positioning of the model gate, which can be used to determine the water depth (Y) after jumping (cm). This laboratory research involves a channel model. The objective of this study is to publish a journal article presenting the simulation results determining the flow patterns occurring in the channel with three different bottom slope angles (5°, 15°, 25°). The results will be presented in tables and graphs and then documented in an article submitted to an international journal.
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