Time-resolved visualization of an impinging jet subjected to bi-modal forcing

IF 1.7 4区 计算机科学 Q3 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS
Basil Abdelmegied, Ahmed Naguib
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Abstract

High-speed flow visualization is utilized to study the effect of bi-modal forcing on an axisymmetric impinging jet at Reynolds number, based on the jet exit velocity and diameter, of \({\mathrm{Re}}_{D}=4233\). The forcing involves excitation using two frequencies simultaneously: the fundamental and subharmonic frequencies of the initial instability of the jet shear layer. The focus of the study is on the effect of the intermodal phase \(\phi\) while utilizing the same modal amplitude ratio and forcing level. The natural jet and the jet forced using pure harmonic forcing at the fundamental and the subharmonic frequency are also studied as benchmark cases for bi-modal forcing. Results show that all modes of forcing accelerate the development of the jet vortex structure by producing two vortex pairings ahead of the impingement plate. This double-paired structure is rarely seen in the natural jet and is promoted the most under pure subharmonic forcing and bi-modal forcing. The intermodal phase is found to have a strong effect with the double-paired structure exhibiting symmetry and high cycle-to-cycle repeatability at \(\phi \approx 150^\circ -165^\circ\), or significant asymmetry and disorganization at \(\phi \approx 90^\circ -105^\circ\). The main distinction between bi-modal forcing at \(\phi \approx 150^\circ -165^\circ\) and pure subharmonic forcing is that the double-paired vortex structure is more persistent and has better repeatability in the former case. With subharmonic forcing alone, the vortex structure exhibits some random switching between the symmetric double-paired structure and the asymmetric structure. Overall, the promotion of double pairing leads to faster narrowing of the jet core and stronger vortex–wall interaction.

Graphical Abstract

Abstract Image

受双峰强迫的冲击射流的时间分辨可视化
基于\({\mathrm{Re}}_{D}=4233\)射流出口速度和直径,利用高速流动可视化技术研究了双峰强迫对雷诺数下轴对称冲击射流的影响。强迫包括同时使用两个频率的激励:射流剪切层初始不稳定的基频和次谐波频率。研究的重点是在使用相同的模态振幅比和强迫水平时,多式相\(\phi\)的影响。本文还研究了自然射流和纯谐波强迫在基频和次谐波频率下强迫射流作为双峰强迫的基准情况。结果表明:各作用力模式均通过在撞击板前方产生两对涡对来加速射流涡结构的发展;这种双对结构在自然射流中很少出现,在纯次谐波强迫和双峰强迫下促进最多。发现多模态相对双对结构有很强的影响,在\(\phi \approx 150^\circ -165^\circ\)处表现出对称性和高循环到循环的可重复性,或在\(\phi \approx 90^\circ -105^\circ\)处表现出明显的不对称性和无序性。\(\phi \approx 150^\circ -165^\circ\)双模态强迫与纯次谐波强迫的主要区别在于,前者双对涡结构更持久,具有更好的可重复性。在单次谐波作用下,涡旋结构在对称双对结构和非对称双对结构之间表现出一定的随机切换。总的来说,双对的促进导致射流核心变窄更快,涡壁相互作用更强。图形摘要
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来源期刊
Journal of Visualization
Journal of Visualization COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS-IMAGING SCIENCE & PHOTOGRAPHIC TECHNOLOGY
CiteScore
3.40
自引率
5.90%
发文量
79
审稿时长
>12 weeks
期刊介绍: Visualization is an interdisciplinary imaging science devoted to making the invisible visible through the techniques of experimental visualization and computer-aided visualization. The scope of the Journal is to provide a place to exchange information on the latest visualization technology and its application by the presentation of latest papers of both researchers and technicians.
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