TY - JOUR
T1 - A DNS study of detonation in H2/O2 mixture with variable-intensity turbulences
AU - Suzuki, Sou
AU - Iwata, Kazuya
AU - Kai, Reo
AU - Kurose, Ryoichi
N1 - Publisher Copyright:
© 2024
PY - 2024/1
Y1 - 2024/1
N2 - Direct numerical simulation with a detailed chemical reaction mechanism is performed for detonation-turbulence interaction in a stoichiometric hydrogen/oxygen mixture. Three turbulences are introduced into detonation with different intensities which are defined by turbulent Reynolds number and turbulent Mach number. The results show that turbulent flow corrugates both shock and flame fronts and makes cellular structures obscure and randomized. The strongest turbulence distorts the shock so strongly that the transverse wave is unclear and cellular structure is destroyed. Time-averaged one-dimensional profiles demonstrate that turbulence promotes the reaction progress. Stronger turbulence produces more intermediate species, by which the chemical reaction reaches completion more rapidly. The turbulent combustion regime indicates that small eddies intrude the flame structure, for which unburned gas pockets are broken into pieces and consumed rapidly. It is consistent with the tendency of the probability density function of induction length, which has only one peak in a smaller value under stronger turbulences, whereas two peaks under the weakest turbulence and without turbulence. Turbulence increases the peak pressure on one-dimensionally averaged structure except for the case where the cellular structure is destroyed. Averaged detonation velocity is strongly correlated with the magnitude of peak pressure, which is the lowest in the strongest turbulence, whereas its deviation increases with turbulent intensities. The absence of the cellular structure, which has been confirmed in optical measurements of rotating detonation engines, could be attributed to the collapse of the cellular structure observed in the strongest turbulence.
AB - Direct numerical simulation with a detailed chemical reaction mechanism is performed for detonation-turbulence interaction in a stoichiometric hydrogen/oxygen mixture. Three turbulences are introduced into detonation with different intensities which are defined by turbulent Reynolds number and turbulent Mach number. The results show that turbulent flow corrugates both shock and flame fronts and makes cellular structures obscure and randomized. The strongest turbulence distorts the shock so strongly that the transverse wave is unclear and cellular structure is destroyed. Time-averaged one-dimensional profiles demonstrate that turbulence promotes the reaction progress. Stronger turbulence produces more intermediate species, by which the chemical reaction reaches completion more rapidly. The turbulent combustion regime indicates that small eddies intrude the flame structure, for which unburned gas pockets are broken into pieces and consumed rapidly. It is consistent with the tendency of the probability density function of induction length, which has only one peak in a smaller value under stronger turbulences, whereas two peaks under the weakest turbulence and without turbulence. Turbulence increases the peak pressure on one-dimensionally averaged structure except for the case where the cellular structure is destroyed. Averaged detonation velocity is strongly correlated with the magnitude of peak pressure, which is the lowest in the strongest turbulence, whereas its deviation increases with turbulent intensities. The absence of the cellular structure, which has been confirmed in optical measurements of rotating detonation engines, could be attributed to the collapse of the cellular structure observed in the strongest turbulence.
KW - Detonation
KW - Direct numerical simulation
KW - Hydrogen
KW - Turbulence
UR - http://www.scopus.com/inward/record.url?scp=85198729595&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=85198729595&partnerID=8YFLogxK
U2 - 10.1016/j.proci.2024.105337
DO - 10.1016/j.proci.2024.105337
M3 - Article
AN - SCOPUS:85198729595
SN - 1540-7489
VL - 40
JO - Proceedings of the Combustion Institute
JF - Proceedings of the Combustion Institute
IS - 1-4
M1 - 105337
ER -