期刊文献+

超声速气流中液体横向射流的非定常特性与振荡边界模型 被引量:7

Unsteady oscillation distribution model of liquid jet in supersonic crossflows
下载PDF
导出
摘要 针对液体圆柱射流垂直喷入超声速横向气流中的非定常分布特性开展实验研究,并建立穿透深度方向上的射流振荡分布模型.利用脉冲激光背景成像方法 "冻结"拍摄马赫2.1(Ma=2.1)气流中煤油射流/喷雾瞬态图像,结合最大类间方差法(Otsu)和Canny算法提取瞬态图像特征,基于统计方法并引入间歇因子(γ)定量描述射流振荡分布特性;通过研究多参数协同作用下的射流振荡分布规律,提出振荡分布数学模型,研究的参数变量包括超声速来流总压(642—1010 k Pa)、液体喷注压降(0.36—4.61 MPa)、液体喷嘴流道直径(0.48 mm/1.0 mm/1.25 mm/1.52 mm)、距离喷嘴的流向距离(10—125 mm)以及液气动量通量比(0.11—7.49).研究中利用射流振荡分布模型成功预测出水射流在Ma=2.1气流中的的振荡分布,预测分布与实验结果符合良好. Unsteady distribution of spray is experimentally studied when a round liquid jet is injected into a supersonic crossflow vertically.An oscillation distribution model for the liquid column and spray is established.Tyndall scattering caused by the sol medium is put forward to eliminate the interference effect of monochromatic laser passing through the supersonic gas flow field.The scattering causes the disordering of laser propagation direction and phase,thus makes the planar light source uniform and eliminate the interference effect of laser at the same time.Then a uniform light source is formed and can be set as the uniform background with a pulse width of 7 ns.The camera,with dimension of CCD pixel space of 4000 × 2672 pixel,is located directly in front of planar light source,and the shooting area is between both.The frozen liquid jet/spray images with high spatiotemporal resolution are captured using the pulsed laser background imaging(PLBI) method in supersonic crossflows.And the drag phenomenon caused by the too-long exposure time in the ordinary and traditional high-speed imaging process is avoided.Based on the maximizing inter-class variance method(Otsu) and Canny method,the out boundary of liquid jet/spray are extracted from an instantaneous image.A dimensionless parameter named intermittency factor(the logogram is r) is defined and used to quantitatively analyze the oscillation distribution characteristics of jet/spray.The intermittency factor of the whole spray field could be calculated by sample probability statistic method.An empirical jet/spray oscillation distribution model,in supersonic crossflows,is summarized based on parameter studies.Various conditions are studied,including stagnation pressure range of gas(642 k Pa to 1010 k Pa),practical pressure range(0.36 MPa to 4.61 MPa),nozzle diameters(0.48 mm/1.0 mm/1.25 mm/1.52 mm),distances down from nozzle(10 mm to 125 mm),and jet-gas momentum flux ratio range(0.11 to 7.49).The empirical model is used to predict the oscillation distribution of water jet penetrated in a Ma2.1supersonic crossflow.It is indicated that the predictive result matches well with the experimental result.It could be concluded that the PLBI method presented in this paper reasonably utilizes the high energy and short pulse characteristics of the laser to successfully complete the "frozen" image of liquid jet/spray under the condition of supersonic crossflow.The dimensionless parameter ‘r' defined in the study can be used to quantitatively analyze the oscillation distribution characteristics of jet/spray well.This study has important significance for understanding the diffusion characteristics of liquid jet in supersonic crossflows.
出处 《物理学报》 SCIE EI CAS CSCD 北大核心 2016年第9期178-186,共9页 Acta Physica Sinica
基金 国家自然科学基金(批准号:11472303) 新世纪优秀人才支持计划(批准号:NCET-13-0156)资助的课题~~
关键词 超燃冲压发动机 振荡分布 超声速横向气流 液体射流 scramjet engine oscillation distribution supersonic crossflow liquid jet
  • 相关文献

参考文献1

二级参考文献32

  • 1Rayleigh L 1883 Proc.London Math.Soc.14 170.
  • 2Taylor G I 1950 Proc.R.Soc.London Ser.A 201 192.
  • 3Buchler J R,Livio M,Colgate S A 1980 Space Science Rev.27 571.
  • 4Keskinen M J,Ossakow S L,Szuszczewicz E P,Holmes J C 1981 J.Geophys.Res.86 5785.
  • 5Jia G,Xiong J,Dong J Q,Xie Z Y,Wu J.2012.Chin.Phys.B 21 095202.
  • 6Rayleigh L 1900 Scientific Papers II (Cambridge: Cambridge University Press) p200.
  • 7Inogamov N A,Abarzhi S I 1995 Physica D 87 339.
  • 8Abarzhi S I.1999.Phys.Rev.E 59 1729.
  • 9Layzer D 1955 Astrophys.J.122 1.
  • 10Oron D,Arazi L,Kartoon D,Rikanati A,Alon U,Shvarts D.2001.Phys.Plasmas 8 2883.

共引文献5

同被引文献51

引证文献7

二级引证文献34

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部