热传导对气-液射流界面不稳定性的作用机理研究

王志亮; 周哲玮

热传导对气-液射流界面不稳定性的作用机理研究

上海大学上海市应用数学和力学研究所, 上海 200072

基金项目: 国家自然科学基金资助项目(19772026);上海市科委重点基金项目;上海市宝钢集团资助项目;上海市重点学科建设资助项目

详细信息

作者简介:
王志亮(1974- ),男,湖北麻城人,博士(E-mail:wangzl-one@sina.com.cn).

中图分类号: O358
计量
- 文章访问数: 2251
- HTML全文浏览量: 114
- PDF下载量: 587
- 被引次数: 0
出版历程
- 收稿日期: 2001-11-05
- 修回日期: 2003-04-12
- 刊出日期: 2003-07-15

Effect of Heat Exchange on the Interfacial Instability of Gas-Liquid Jet

Shanghai Institute of Applied Mathematics and Mechanics, Shanghai University, Shanghai 200072, P. R. China

摘要

摘要: 研究了平面分层气-液射流在非线性温度分布条件下的界面不稳定性性质.考虑了气体的可压缩性、液体的粘性、以及气体热导率和密度随温度变化等事实.并应用正则模态方法将问题转化为四阶变系数常微分方程,用数值积分和多重打靶法对模型的空间模式进行了计算,研究了不稳定模态随各物理参量的变化趋势.计算表明模型所体现的不稳定性特征与其它模型的计算结果是一致的.同时计算还得出气体和液体的温差越小、雷诺数越大、热导率变大均将有利于液体射流有效雾化的结果.该结论与HJE.Co.Inc(Glens Falls,NY,USA)的实验数据是定性吻合的.
- 热传导 /
- 射流 /
- 界面不稳定性 /
- 喷射雾化
Abstract: The classical linear instability theory was applied to the planar stratified two-layers flow with high speed compressible gas layer impacting on incompressible viscous liquid layer.The walls were kept at different temperatures,resulting in heat transfer across the layers.The thermal conductivity and the density of the gas were alerted when the temperature changes.After some treatment,a four-order stiff ordinary differential equation was derived,and numerical integration and multi-shooting method were used to solve this equation for its spatial mode calculation.The numerical results of characteristic parameters show good coincidence with other models.At the same time,when the wall temperature ratio decreases,as well as the Reynold number and the gas thermal conductivity change increases,the atomization would be more efficient and producing finer droplets.And the results show good fit with the experimental datum of HJE.Co.Inc(Glens Falls,NY,USA).
- heat exchange /
- jet /
- interfacial instability /
- spray forming

HTML全文

参考文献(10)

[1]	王善春.我国钢铁粉末的发展和展望[J].粉末冶金工业,2001,10(2):25-31.
[2]	Taylor G I.Generation of rippless by wind blowing over viscous fluid[A].In:Batchelor G K,Ed.The Scientific Papers of G I Taylor[C].Cambridge,England:Cambridge University Press,1965,3:952.
[3]	Bradley D.On the atomization of liquid by high-velocity gases(Ⅰ) &(Ⅱ)[J].Phys Fluids,1973,6:1724-2267.
[4]	Leib S J,Goldstein M E.The generation of capillary instabilities of a liquid jet[J].J Fluid Mech,1986,168:479.
[5]	Lin S P,Kang D J.Atomization of a liquid jet[J].Phys Fluids,1987,30(7):2000.
[6]	Lin S P,Lian Z W.Mechanisms of the breakup of liquid jet[J].AIAA Journal,1990,28(1):120.
[7]	Berger S A.Initial-value stability analysis of a liquid jet[J].SIAM J Appl Math,1988,48(5):973.
[8]	ZHOU Zhe-wei,TANG Xiao-dong.The effect of the pulsation in gas flow on the stability of melted metal jet[A].In:Appear as C D.Fourth International Conference on Spray Forming USA[C].University of Marylaad,1999,35-41.
[9]	马峥,周哲玮.气流雾化问题中的流动稳定性研究[J].应用数学和力学,1998,20(10):991-996.
[10]	Joseph,Tunick,Strauss.Hotter gas increases atomization efficiency[R].Metal Powder Report,Nov,1999:24-32.