气液同轴双离心式喷嘴宏观雾化特性实验研究

张涛; 王福顺; 况付毫; 李润东; 贺业光; 官吏男; 李维仲

引用本文:

【打印本页】【HTML】【下载PDF全文】【查看/发表评论】【EndNote】【RefMan】【BibTex】

←前一篇|后一篇→

过刊浏览高级检索

本文已被：浏览 313次下载 68次	码上扫一扫！
分享到：微信更多字体:加大+\|默认\|缩小-
气液同轴双离心式喷嘴宏观雾化特性实验研究
张涛^1,2，王福顺¹，况付毫¹，李润东¹，贺业光¹，官吏男²，李维仲²
1.沈阳航空航天大学能源与环境学院，辽宁沈阳 110136;2.大连理工大学海洋能源利用与节能教育部重点实验室，辽宁大连 116024

摘要:

为掌握燃气轮机燃烧室喷嘴的雾化规律并优化其雾化效果，本文以液态水为工质，对新型气液同轴双离心式喷嘴雾化特性展开实验研究。利用粒子图像测速法研究了改变气、液进口压力对雾化液滴速度场、雾化锥角和液膜破碎长度的影响，通过分析雾化图像对喷嘴的雾化机制进行探究。结果表明，液体进口压力不变时，气体进口压力增加可使雾化状态由空心锥状向实心锥状过渡，同时液膜破碎依次经历了表面波主导破碎、波动雾化破碎以及气动雾化破碎三种模式。液体进口压力为0.7MPa时，气体进口压力增大，雾化模式由表面波破碎向波动雾化破碎过渡，雾化液锥收缩，液膜受气动力作用向下游展开，液膜破碎长度呈先增大后减小的规律。雾化处于气动雾化破碎模式时，雾化锥角逐渐稳定。对喷嘴下游40mm处液滴速度值分析表明，随着液压增大，有/无气旋对雾化液滴速度增幅稳定在8%。

关键词: 气液同轴双离心式喷嘴粒子图像测速法液膜破碎长度雾化锥角液滴速度场

DOI：10.13675/j.cnki.tjjs.2208011

分类号:V231.1

基金项目:海洋能源利用与节能教育部重点实验室（大连理工大学）开放基金资助项目（LOEC-202006）；辽宁省教育厅基础研究资助项目（JYT2020041）。

Experimental Study on Macro-Spray Characteristics of Gas-Liquid Double Swirl Coaxial Injectors

ZHANG Tao^1,2, WANG Fu-shun¹, KUANG Fu-hao¹, LI Run-dong¹, HE Ye-guang¹, GUAN Li-nan², LI Wei-zhong²

1.College of Energy and Environment，Shenyang Aerospace University，Shenyang 110136，China;2.Key Laboratory of Ocean Energy Utilization and Energy Conservation of Ministry of Education， Dalian University of Technology，Dalian 116024，China

Abstract:

In order to grasp the atomization law of injector and optimize its spray effect in gas turbine combustion chamber， a new gas-liquid double swirl coaxial injector was employed to investigate spray characteristics under the working medium of water. The effects of gas and liquid inlet pressure on the velocity field of spray droplets， spray cone angle， and liquid film breakup length were studied using particle image velocimetry， and the spray mechanism of the injector was investigated by analyzing spray visualizations. The results showed that when the liquid inlet pressure kept constant， the atomization state changed from a hollow cone to a solid cone with the increase of gas inlet pressure. Meanwhile the liquid film breakup experienced three modes of surface wave dominated breakup， fluctuating spray breakup and pneumatic spray breakup in turn. When the liquid inlet pressure was 0.7MPa， the spray breakup mode changed from surface wave breakup to fluctuating spray breakup and the spray liquid cone shrinked with the increase of gas inlet pressure. Meanwhile， the liquid film was expanded downstream by the aerodynamic effect， and its breakup length increased first and then decreased. When the atomization was in the pneumatic spray breakup mode， the spray cone angle was gradually stabilized. The analysis of droplet velocity values at 40mm downstream of the injector showed that the growth rate of droplet velocity stabilized at 8% with/without cyclone as the liquid inlet pressure increased.

Key words: Gas-liquid double swirl coaxial injectors Particle image velocimetry Breakup length of liquid film Spray cone angle Droplet velocity field