期刊文献+

飞行参数对液体火箭尾焰红外辐射特性的影响 被引量:19

Influence of Flight Parameters on the Infrared Radiation of a Liquid Rocket Exhaust Plume
原文传递
导出
摘要 为了研究飞行参数对液体火箭尾焰红外辐射特性的影响,利用FLUENT软件计算不同飞行参数下的尾焰流场,利用HITEMP数据库计算燃气的辐射参数,使用有限体积法(FVM)计算尾焰在2.0~5.0μm波段光谱辐射特性。据此研究了火箭飞行高度和飞行速度对尾焰2.0~5.0μm波段光谱辐射强度以及2.5~3.0μm和4.2~4.7μm两个波段辐射强度影响。研究表明,飞行高度和速度对液体火箭尾焰红外辐射强度的影响主要是通过改变流场的温度和尺寸实现的。飞行速度不变,在0~40km范围内,随着飞行高度的增加,尾焰辐射强度呈增大趋势,并且在4.2~4.7μm波段的辐射强度增幅较大;飞行高度不变,随着飞行速度的增加,尾焰辐射强度呈先减小后稳定趋势,且2.5~3.0μm波段的辐射强度减幅较大。 Aimed at studying the influence of flight parameters on the infrared radiation of a liquid rocket exhaust plume, the FLUENT software is used to calculate the flow field of an exhaust plume under several different flight parameters, then the HITEMP database is adopted to calculate the radiation parameters and the finite volume method (FVM) is used to calculate the infrared radiation between 2 μm and 5 μm. Based on this work, the influences of the altitude and velocity on the spectral radiation intensity as well as 2.5 - 3.0μm and 4.2 - 4.7 μm band radiation intensity are studied. It is found that, the influences of flight parameters on the infrared radiation are exerted by changing the temperature and size of the exhaust plume flow field. At the same velocity, as the altitude increases from 0 to 40 km, the infrared radiation intensities increase gradually, and the band radiation of 4. 2- 4.7 μm increases faster. At the same altitude, as the Mach number increases, the infrared radiation intensity decreases at first and then becomes stable, and the band radiation of 2.5-3.0 μm decreases faster.
出处 《光学学报》 EI CAS CSCD 北大核心 2013年第4期1-7,共7页 Acta Optica Sinica
基金 国家重点实验室基金(10J006)资助课题
关键词 红外辐射 飞行参数的影响 有限体积法 液体火箭尾焰 流场 infrared radiation influence of flight parameters finite volume method liquid rocket exhaust plumes flow field
  • 相关文献

参考文献18

  • 1H. F. Nelson. Infrared radiation signature of tactical rocket exhausts [C]. St. Louis, Missouri: AIAA, 1985: AIAA-82-0913.
  • 2W. C. Rochelle. Review of Thermal Radiation from Liquid and Solid Propellant Rocket Exhausts [R]. Huntsville: Marshall Space Flight Center, 1967.
  • 3S. T. Surzhikov. Monte-Carlo Simulation of Plumes Spectral Emission [R]. Institute for Problems in Mechanics Russian Academy of Sciences (IPMech RAS), 2006.
  • 4J. E. Reardon, Y. C. Lee. A Computer Program for Thermal Radiation from Gaseous Rocket Exhuast Plumes (GASRAD) [R]. NASA-CR-161496, 1980.
  • 5C. B. Ludwig, W. Malkmus, J. Walker. The standardized infrared radiation mode [C]. AIAA, 1981: AIAA-81-1051.
  • 6L. H. Liu. Backward Monte Carlo method based on radiation distribution factor [J]. AIAA J. Thermophys., 2004, 18(4): 151-153.
  • 7阮立明,齐宏,王圣刚,杨昌鹏.导弹尾喷焰目标红外特性的数值仿真[J].红外与激光工程,2008,37(6):959-962. 被引量:32
  • 8金伟,凌永顺,吕相银.卫星轨控推进器尾焰红外辐射的数值模拟[J].光电工程,2010,37(10):6-10. 被引量:3
  • 9张小英,朱定强,蔡国飙.固体火箭羽流红外特性的DOM法模拟及高度影响研究[J].宇航学报,2007,28(3):702-706. 被引量:20
  • 10S. Feng, W. Nie, Q. Xie et al. Numerical simulation of flow field and radiation of an aluminized solid-opellant rocket multiphase exhaust plume [C]. Miami, FL: AIAA, 2007:AIAA 2007-4415.

二级参考文献22

共引文献73

同被引文献344

引证文献19

二级引证文献101

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