High fidelity simulation on the breakup and deformation characteristics of liquid jet in crossflow with rectangular nozzles

IF 1 4区工程技术 Q4 ENGINEERING, CHEMICAL

Atomization and Sprays Pub Date : 2023-01-01 DOI:10.1615/atomizspr.2023048593

Meng Shao, Zhixia He, Qian Wang

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Abstract

In this article, high fidelity simulation of liquid jet in crossflow was carried out to investigate the breakup features and deformation characteristics of liquid column with different nozzles in primary breakup. Water as the jet liquid is injected into crossflow from circular and rectangular nozzles. Air velocity ranges from 40 m/s to 80 m/s. The results indicated that at the smaller air velocity, the surface breakup was mainly affected by the sharp angle of rectangular nozzles. And for all nozzles, the breakup regime of liquid column was very similar due to the reason that the final shape of cross section was similar, which was bow. While the air velocity across the sides of liquid column dominated the surface breakup at the higher air velocity. The transformation of breakup regimes was accelerated as the width of rectangular nozzles increased in the column breakup. In contrast to circular nozzles, for rectangular nozzles the deflection of thin edges on the lateral sides of liquid column was avoided, thus preventing the shrinkage of liquid column during injection. The difference of breakup regime for the nozzles may be due to the difference of air velocity in the flow direction of liquid column. Besides, the difference of windward trajectory between rectangular nozzles with the different widths was decreased as the air velocity increased.

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矩形喷嘴横流中液体射流破裂与变形特性的高保真仿真

本文对横流中液体射流进行了高保真仿真，研究了不同喷嘴下液体柱初次破碎时的破碎特征和变形特征。水作为射流液体从圆形和矩形喷嘴注入到横流中。风速范围为40 ~ 80米/秒。结果表明，在较小的风速下，矩形喷嘴的尖角主要影响表面破碎;对于所有的喷嘴来说，由于最终的截面形状都是相似的，即弓形，所以液柱的破碎状态非常相似。而在高气流流速下，液柱两侧的气流速度对表面破碎起主导作用。随着矩形喷管宽度的增大，柱状破碎过程中破碎形式的转变加快。与圆形喷嘴相比，矩形喷嘴避免了液柱侧面薄边的偏转，从而防止了注射过程中液柱的收缩。不同喷嘴的破碎状态的不同可能是由于液柱流动方向上气流速度的不同造成的。此外，不同宽度矩形喷嘴迎风轨迹的差异随着风速的增大而减小。

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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来源期刊

Atomization and Sprays 工程技术-材料科学：综合

CiteScore

2.10

自引率

16.70%

发文量

审稿时长

1.7 months

期刊介绍： The application and utilization of sprays is not new, and in modern society, it is extensive enough that almost every industry and household uses some form of sprays. What is new is an increasing scientific interest in atomization - the need to understand the physical structure of liquids under conditions of higher shear rates and interaction with gaseous flow. This need is being met with the publication of Atomization and Sprays, an authoritative, international journal presenting high quality research, applications, and review papers.