喷油器喷嘴中的喷流初级破裂与涡流诱导串空化耦合

Wei Guan, Yunlong Huang, Zhixia He, Genmiao Guo, Chuqiao Wang, Dominique Thévenin
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引用次数: 0

摘要

燃油喷射的一次破裂在很大程度上取决于高压燃油喷射器喷嘴中的喷嘴内空化现象。然而,人们对喷嘴内涡旋诱导串型空化引起的燃料喷射一次破裂的机理关注有限。本研究利用大涡模拟和流体体积模拟喷嘴内串式空化流,并同时模拟近喷嘴喷气初破过程,旨在揭示串式空化对喷气初破的影响。数值结果与实验数据在串空化强度、射流界面拓扑和喷射扩散角等方面吻合良好。数值研究表明,射流的外表面经历了开尔文-赫尔姆霍兹不稳定性,导致燃料膜表面产生了圆周和轴向表面波。随后,燃料膜表面逐渐起皱,形成多条韧带和大液滴。在射流的内侧,负压引起的空气反吸及其与射流核心的空化蒸汽的相互作用导致蒸汽气泡溃散。由此产生的压力波和微射流促进了液膜从射流内表面脱离。对enstrophy传输方程的分析表明,下游串空化射流破裂背后的驱动机制是巴氏转矩项,它负责产生一连串较小的涡旋结构。这种效应比涡旋拉伸和扩张项更重要。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Primary breakup of a jet coupled with vortex-induced string cavitation in a fuel injector nozzle
Fuel jet primary breakup strongly depends on the in-nozzle cavitation phenomena found in the high-pressure fuel injector nozzle. Nevertheless, limited attention has been paid to the mechanism of fuel jet primary breakup induced by in-nozzle vortex-induced string-type cavitation. This study involves simulations of in-nozzle string cavitating flow and simultaneously near-nozzle jet primary breakup process using large eddy simulation and volume of fluid, aiming at revealing the effects of string cavitation on jet primary breakup. The numerical results are in good agreement with experimental data in terms of string cavitation intensity, interfacial topology of jet, and spray spreading angle. The numerical investigations indicate that the external surface of the jet experiences Kelvin–Helmholtz instabilities, which results in the development of circumferential and axial surface waves at the fuel film surface. Subsequently, the fuel film surface undergoes progressive wrinkling, resulting in its breakup into multiple ligaments and large droplets. On the internal side of the jet, back-suction of air caused by negative pressure and its interaction with cavitation vapor at the core of the jet lead to the collapse of vapor bubbles. The resulting pressure waves and micro-jets facilitate the detachment of liquid sheets from the internal surface of the jet. Analysis of the enstrophy transport equation indicates that the driving mechanism behind string cavitation jet breakup further downstream is the baroclinic torque term, which is responsible for the generation of a cascade of smaller vortical structures. This effect dominates over vortex stretching and dilatation terms.
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