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Volume 34 Issue 8
Aug.  2008
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Journal of Beijing University of Aeronautics and Astronautics  > 2008  >  34(8): 907-910.
Wang Liao, Wei Baoxi, Zhang Chengliang, et al. Experimental investigation of kerosene supersonic combustion based on cavity flameholder[J]. Journal of Beijing University of Aeronautics and Astronautics, 2008, 34(8): 907-910. (in Chinese)
Citation: Wang Liao, Wei Baoxi, Zhang Chengliang, et al. Experimental investigation of kerosene supersonic combustion based on cavity flameholder[J]. Journal of Beijing University of Aeronautics and Astronautics, 2008, 34(8): 907-910. (in Chinese)
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Experimental investigation of kerosene supersonic combustion based on cavity flameholder

  • School of Astronautics, Beijing University of Aeronautics and Astronautics, Beijing 100191, China

  • Received Date: 20 Jul 2007
  • Publish Date: 31 Aug 2008
    Abstract
  • Experimental investigation of kerosene supersonic combustion was performed on direct-connect supersonic combustion test facility by using four different configurations of cavity flameholders and multi-diameter kerosene injectors. Kerosene equivalence ratio varies from 0.24 to 1.32 and polite hydrogen equivalence ratio was 0.53. Successful ignition and sustain combustion were achieved in multi-test conditions. The distribution of wall static pressure was measured to validate the combustion performances under different test conditions. The experimental results show the four cavity flameholders used in the test have excellent flame holding effects. The configuration of cavity has great influence on the ignition of kerosene in supersonic airstream.Larger length depth ratio was better for the kerosene ignition, and with several cavities, kerosene can achieve self-ignition without pilot hydrogen. equivalence ratio is the most important influencing factor of kerosene combustion capabilities. At same kerosene equivalence ratio, higher injection pressure can improve the kerosene combustion effects.

     

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  • [1] Tishkoff J M, Drummond J P, Edwards T, et al. Future directions of supersonic combustion research: air force /NASA workshop on supersonic combustion . AIAA-97-1017,1997 [2] Baurle R A, Gruber M R, A study of recessed cavity flowfields for supersonic combustion applications . AIAA-98-0938,1998 [3] Ben-Yakar A, Hanson R. Cavity flameholders for ignition and flame stabilization in scramjets: review and experimental study . AIAA-98-3122,1998 [4] Stallings R L Jr, Wilcox F J Jr. Experimental cavity pressure distributions at supersonic speeds . NASA TP22683 ,1987 [5] Gruber M R, Baurle R A. Fundamental studies of cavity-based flameholder concepts for supersonic combustors .AIAA-99-2248,1999 [6] Veretennicov V G, Autoignition study on kerosene in supersonic flow technical report on scientific and research work . NO.F61780-96-W0286,1996 [7] Wu P K, Kirkendall K A, Fuller R P. Spray structures of liquid jets atomized in subsonic rossflows[J]. Journal of Propulsion and Power, 1998,13(2): 173-182 [8] Lin K C, Kennedy P J. Penetration heights of liquid jets in high-speed crossflows .AIAA-2002-0873, 2002
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