Numerical investigation of oblique detonation structure in hydrogen-oxygen mixtures with Ar dilution

Two combustible mixtures, H₂-O₂-Ar and H₂-O₂-N₂, are widely used in detonation research, but only the latter has been employed in oblique detonation wave (ODW) studies. In this study, ODWs in H₂-O₂-Ar are simulated to investigate their structural characteristics using reactive Euler equations with a detailed chemistry model. Similar to ODWs in H₂-O₂-N₂ mixtures, two observed structures are dependent on incident Mach numbers. However, in mixtures of 2H₂ + O₂ + 7Ar, the structures are sensitive to inflow static pressure P₀, different from the structures in H₂-O₂-N₂ mixtures. Based on flow field analysis, the ratio of induction and heat release zone lengths R_L is proposed to model the difference induced by dilution gas. Generally, R_L is large in N₂ diluted mixtures but small in Ar diluted mixtures. Low R_L indicates that induction is comparable with the heat release zone and easily changed, resulting in pressure-sensitive structures. When the dilution gas changes gradually from N₂ to Ar, the ratio R_L increases slowly at first and then declines rapidly to approach a constant. The variation rule of R_L is analyzed and compared with results from calculations of a constant volume explosion, demonstrating how different dilution gases influence ODW structures.