Chuan Wang , Yu Hao , Yang Yang , Hui Wang , Yulong Yao , Xionghuan Chen
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引用次数: 0
Abstract
Pulsed buoyancy jet diffusion dilution is characterized by low cost and high efficiency, so it is widely used in wastewater discharge dilution projects. This study, based on three-dimensional numerical simulations, investigates the effects of stroke ratio (1.71 ≤ L/D ≤ 8.57), velocity ratio (2.4 ≤ R ≤ 12), and duty cycle (0.17 ≤ η ≤ 0.83) on the diffusion of low-frequency pulsed buoyant triple jets. A large number of simulations were conducted for each parameter, and the concentration field, vorticity field, and flow field at different sections during the initial stage of the jet were analyzed. The results reveal the evolution patterns of the vortex structure in pulsed triple buoyant jets and their diffusion characteristics. The vortex structure at the initial stage of the jet exhibits continuous vortex ring characteristics, which later evolve into a vortex street and counter-rotating vortex pair (CVP) combination structure. Meanwhile, the buoyancy effect enhances the development and diffusion of the vortex structure in both the X and Z directions. As the stroke ratio decreases, the wastewater concentration distribution becomes more concentrated, and the dynamic interaction between the jets intensifies. The increase in duty cycle enhances the interaction between the jets, significantly improving the horizontal diffusion capacity, but the vertical penetration depth is less than that of continuous jets. The Strouhal number (St) is composed of the stroke ratio, velocity ratio, and duty cycle. These three parameters control the motion state of pulsed jets in the crossflow. The established relationships and equations arising from this research offer vital reference values for predicting sewage leakage and wastewater diffusion in engineering applications, contributing substantively to the theoretical framework governing multiple buoyant jets.
脉冲浮力射流扩散稀释法具有成本低、效率高的特点,因此被广泛应用于污水排放稀释工程中。本研究基于三维数值模拟,研究了冲程比(1.71 ≤ L/D ≤ 8.57)、速度比(2.4 ≤ R ≤ 12)和占空比(0.17 ≤ η ≤ 0.83)对低频脉冲浮力三重射流扩散的影响。针对每个参数进行了大量模拟,分析了射流初始阶段不同截面的浓度场、涡度场和流场。结果揭示了脉冲三浮力射流中涡旋结构的演变规律及其扩散特性。射流初始阶段的涡旋结构呈现连续涡环特征,随后演变为涡街和反旋转涡对(CVP)组合结构。同时,浮力效应增强了涡流结构在 X 和 Z 两个方向上的发展和扩散。随着冲程比的减小,废水浓度分布变得更加集中,喷流之间的动态相互作用也随之增强。增加占空比可增强喷流之间的相互作用,显著提高水平扩散能力,但垂直穿透深度小于连续喷流。斯特劳哈尔数(St)由冲程比、速度比和占空比组成。这三个参数控制着横流中脉冲射流的运动状态。这项研究建立的关系和方程式为预测工程应用中的污水渗漏和废水扩散提供了重要的参考价值,对管理多浮力射流的理论框架做出了重大贡献。
期刊介绍:
Ocean Engineering provides a medium for the publication of original research and development work in the field of ocean engineering. Ocean Engineering seeks papers in the following topics.