Spectroscopy and Spectral Analysis, Volume. 34, Issue 3, 582(2014)
Research on Diagnosis of Gas-Liquid Detonation Exhaust Based on Double Optical Path Absortion Spectroscopy Technique
The effect detection of detonation exhaust can provide measurement data for exploring the formation mechanism of detonation, the promotion of detonation efficiency and the reduction of fuel waste. Based on tunable diode laser absorption spectroscopy technique combined with double optical path cross-correlation algorithm, the article raises the diagnosis method to realize the on-line testing of detonation exhaust velocity, temperature and H2O gas concentration. The double optical path testing system is designed and set up for the valveless pulse detonation engine with the diameter of 80 mm. By scanning H2O absorption lines of 1343nm with a high frequency of 50 kHz, the on-line detection of gas-liquid pulse detonation exhaust is realized. The results show that the optical testing system based on tunable diode laser absorption spectroscopy technique can capture the detailed characteristics of pulse detonation exhaust in the transient process of detonation. The duration of single detonation is 85 ms under laboratory conditions, among which supersonic injection time is 57 ms and subsonic injection time is 193 ms. The valveless pulse detonation engine used can work under frequency of 11 Hz. The velocity of detonation overflowing the detonation tube is 1 172 m·s-1, the maximum temperature of detonation exhaust near the nozzle is 2 412 K. There is a transitory platform in the velocity curve as well as the temperature curve. H2O gas concentration changes between 0~7% during detonation under experimental conditions. The research can provide measurement data for the detonation process diagnosis and analysis, which is of significance to advance the detonation mechanism research and promote the research of pulse detonation engine control technology.
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Lv Xiao-jing, LI Ning, WENG Chun-sheng. Research on Diagnosis of Gas-Liquid Detonation Exhaust Based on Double Optical Path Absortion Spectroscopy Technique[J]. Spectroscopy and Spectral Analysis, 2014, 34(3): 582
Received: Jun. 4, 2013
Accepted: --
Published Online: Mar. 14, 2014
The Author Email: Xiao-jing Lv (lvxiaojing2008@163.com)