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采用离心喷嘴的单凹腔驻涡燃烧室点火与贫熄特性 被引量:11

Ignition and Lean Blowout Characteristics of a Single-Cavity Trapped Vortex Combustor Utilizing Pressure Swirl Atomizer
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摘要 为了研究单凹腔驻涡燃烧室的点火和贫油熄火特性,设计了一个带扩压器和内外机匣的单凹腔驻涡燃烧室矩形试验件,采用试验研究和半经验分析相结合的方法对其点火和贫油熄火进行了研究。试验在常压状态下进行,采用RP3航空煤油作为燃料,所用供油喷嘴为空心锥离心喷嘴,试验中的进口空气温度在287-487K变化,进口空气流量在0.2109-0.4219kg/s变化,对应进口马赫数从0.15变化到0.31。结果表明:单凹腔驻涡燃烧室的点火和贫油熄火油气比均随着燃烧室进口温度和进口流量的增加而减小,单凹腔驻涡燃烧室的点火油气比比贫油熄火油气比约大50%。经过半经验分析,得到了影响单凹腔点火和熄火的综合参数A,该参数能够较好地解释和评价各种因素对贫油熄火的影响。 A rectangular single-cavity trapped vortex combustor(STVC)comprising casing and diffuser was designed,and ignition and lean blowout characteristic experiments were accomplished at atmospheric pressure, and semi-analytical results were obtained. Aviation kerosene RP3 was employed as fuel,and cone-shaped pres?sure swirl atomizer was used for fuel supply. In all the operating conditions,inlet temperature of the combustor varies from 287K up to 487K,and inlet air mass flow rate ranges from 0.2109kg/s up to 0.4219kg/s,the corre?sponding Mach number ranges from 0.15 to 0.31. It is revealed that the fuel air ratios of ignition and lean blowout decrease while inlet temperature and air mass flow rate increase,and the former is approximately 50%more than the latter. A synthesized parameter,that affects ignition and lean blowout characteristics of the single-cavity trapped vortex combustor,is derived in a semi-empirical method. This parameter can well interpret and estimate the effects of various factors on lean blowout.
作者 吴泽俊 何小民 洪亮 薛冲 金义
机构地区 南京航空航天大学能源与动力学院/江苏省航空动力系统重点实验室
出处 《推进技术》 EI CAS CSCD 北大核心 2015年第4期601-607,共7页 Journal of Propulsion Technology
基金 江苏省普通高校研究生科研创新计划资助项目(CXLX12_0167)
关键词 单凹腔驻涡燃烧室 点火 贫油熄火 油气比 有效蒸发常数 Single-cavity trapped vortex combustor Ignition Lean blowout Fuel air ratio Effective evapo-ration constant
分类号 V231.3 [航空宇航科学与技术—航空宇航推进理论与工程]
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参考文献23

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二级参考文献23

  • 1马文杰,樊未军,侯木玉,杨茂林.空气分级对燃烧室燃烧及污染物排放的影响[J].燃烧科学与技术,2004,10(4):345-349. 被引量:5
  • 2樊未军,严明,易琪,杨茂林.富油/快速淬熄/贫油驻涡燃烧室低NO_x排放[J].推进技术,2006,27(1):88-91. 被引量:31
  • 3樊未军,易琪,严明,杨茂林.驻涡燃烧室凹腔双涡结构研究[J].中国电机工程学报,2006,26(9):66-70. 被引量:46
  • 4何小民,姚锋.流动和油气参数对驻涡燃烧室燃烧性能的影响[J].航空动力学报,2006,21(5):810-813. 被引量:20
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  • 7Burrus D L, Johnson A W, Roquemore W M, et al. Performance assessment of a prototype trapped vortex combustor concept for gas turbine applieation[R]. ASME Paper 2001-GT-0087,2001.
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  • 9Hendricks R C,Shouse D T,Roquemore W M,et al. Experimental and computational study of trapped vortex combustor sector rig with tri pass diffuser[R]. NASA/ TM 2004 -212507,2004.
  • 10Straub D L,Casleton K H,Lewis R E,et al. Assessment of rich burn, quick mix, lean-burn trapped vortex combustor for stationary gas turbines[J].Journal of Engineering for Gas Turbine and Power,2005,127(1):36-41.

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