posted on 2019-09-27, 12:41authored byJianfu Zhao, Lei Zhou, Lijia Zhong, Xiaojun Zhang, Jiaying Pan, Rui Chen, Haiqiao Wei
In the present work, end-gas autoignition formation, and the effects of oxygen concentration on
the flame/shock waves propagation and pressure oscillation, are investigated in a self-designed
constant-volume chamber equipped with a perforated plate. A hydrogen–oxygen–nitrogen mixture
with adjustable oxygen to nitrogen ratio is chosen as the test fuel. In an oxygen-enriched condition,
the probability of an end-gas autoignition occurrence increasessignificantly. End-gas autoignition with
detonation development is further investigated, with a special emphasis on the stochasticity of the
detonation development. In a low-oxygen condition, detonation occurs randomly owing to its
stochastic physical behavior. However, when the oxygen concentration increases to 28%, the stochastic
factors have a lower impact, and the detonation occurrence is certain. Nevertheless, the pressure and
pressure oscillation in the autoignition exhibit random behaviors and are unrelated to the oxygen
concentration. The variation tendency of the flame tip velocity remains constant under different
oxygen concentrations. However, an increase in the oxygen concentration improves the flame tip
velocity, thereby inducing stronger shock waves and promoting autoignition. Based on the start time
of the autoignition, two types of autoignition modes were identified: Mode 1 and Mode 2. In Mode 2,
the unburnt mixture experiences merely one compression by the shock wave before autoignition and
only occurs under high oxygen concentrations of 27%–28%. Under equal oxygen concentrations, the
pressure and pressure oscillation of Mode 2 are higher than those of Mode 1 owing to the larger amount
2
of unburnt mixture. Finally, the exhaust gas was introduced into the initial unburnt mixture to
investigate the effect of an inert gas on the combustion.
Funding
National Science Fund for Distinguished Young Scholars (Grant No. 29 51825603)
National Natural Science Foundation of China (Grant No. 91741119, 51606133)
State Key Laboratory of Explosion Science and Technology (Beijing Institute of Technology (KFJJ18-09M).
History
School
Aeronautical, Automotive, Chemical and Materials Engineering
This paper was accepted for publication in the journal Combustion and Flame and the definitive published version is available at https://doi.org/10.1016/j.combustflame.2019.08.040