Analyses and Application of Gas Sampling to Scramjet Engine Testing

Gas sampling has been used in combustor studies and in scramjet engine testing. Because the gas sampling is based on the assumption that the gas composition is frozen in the sampling process, the critical Damkohler numbers necessary to quench reactions in the gas-sampling probes were evaluated using...

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Veröffentlicht in:	Journal of propulsion and power 1999-07, Vol.15 (4), p.572-577
Hauptverfasser:	Mitani, Tohru, Takahashi, Masahiro, Tomioka, Sadatake, Hiraiwa, Tetsuo, Tani, Kouichiro
Format:	Artikel
Sprache:	eng
Schlagworte:	Calculations Computer simulation Engine tests Gas sampling Gases Mathematical models Reaction kinetics Reynolds number Sampling Supersonic aircraft Supersonic combustion ramjet engines
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container_end_page	577
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container_title	Journal of propulsion and power
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creator	Mitani, Tohru Takahashi, Masahiro Tomioka, Sadatake Hiraiwa, Tetsuo Tani, Kouichiro
description	Gas sampling has been used in combustor studies and in scramjet engine testing. Because the gas sampling is based on the assumption that the gas composition is frozen in the sampling process, the critical Damkohler numbers necessary to quench reactions in the gas-sampling probes were evaluated using a reduced kinetic model. The phase plane analysis showed that reactions in probes can be extinguished if the probe Damkohler number is less than about 10. The analytical results were confirmed by numerical calculations using full kinetics. The shock swallowing into sampling probes was examined using numerical simulations for the low-Reynolds-number flow. These theoretical results were verified by experiments using four kinds of probes with various configurations in a Mach 2.5 supersonic combustor. Based on the results, fine sampling probes with a tip diameter of less than 0.3 mm are recommended for scramjet testing. Based on these calibration studies, gas sampling was successfully applied to scramjet engine testing under a flight Mach number up to 8, to reveal interesting features in the internal flow in swept-back engines. (Author)
doi_str_mv	10.2514/2.5465
format	Article
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Because the gas sampling is based on the assumption that the gas composition is frozen in the sampling process, the critical Damkohler numbers necessary to quench reactions in the gas-sampling probes were evaluated using a reduced kinetic model. The phase plane analysis showed that reactions in probes can be extinguished if the probe Damkohler number is less than about 10. The analytical results were confirmed by numerical calculations using full kinetics. The shock swallowing into sampling probes was examined using numerical simulations for the low-Reynolds-number flow. These theoretical results were verified by experiments using four kinds of probes with various configurations in a Mach 2.5 supersonic combustor. Based on the results, fine sampling probes with a tip diameter of less than 0.3 mm are recommended for scramjet testing. Based on these calibration studies, gas sampling was successfully applied to scramjet engine testing under a flight Mach number up to 8, to reveal interesting features in the internal flow in swept-back engines. 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Based on these calibration studies, gas sampling was successfully applied to scramjet engine testing under a flight Mach number up to 8, to reveal interesting features in the internal flow in swept-back engines. 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Because the gas sampling is based on the assumption that the gas composition is frozen in the sampling process, the critical Damkohler numbers necessary to quench reactions in the gas-sampling probes were evaluated using a reduced kinetic model. The phase plane analysis showed that reactions in probes can be extinguished if the probe Damkohler number is less than about 10. The analytical results were confirmed by numerical calculations using full kinetics. The shock swallowing into sampling probes was examined using numerical simulations for the low-Reynolds-number flow. These theoretical results were verified by experiments using four kinds of probes with various configurations in a Mach 2.5 supersonic combustor. Based on the results, fine sampling probes with a tip diameter of less than 0.3 mm are recommended for scramjet testing. 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subjects	Calculations Computer simulation Engine tests Gas sampling Gases Mathematical models Reaction kinetics Reynolds number Sampling Supersonic aircraft Supersonic combustion ramjet engines
title	Analyses and Application of Gas Sampling to Scramjet Engine Testing
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