Numerical Study of Disturbance Resistance of Oblique Detonation Waves

Liu, Yu; Xiao, Baoguo; Wang, Lan; Wang, Chao

doi:10.1155/2020/8876637

Cited by 2 publications

(1 citation statement)

References 35 publications

(42 reference statements)

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“…In this study, the Adaptive Mesh Refinement Object-oriented C++ (AMROC) [27][28][29] based on the Structured Adaptive Mesh Refinement (SAMR) solver was used with a detailed reaction model, which has been efficiently used for various shock-induced combustion studies and detonation-based simulation problems [15,30,31]. In various numerical studies, AMROC has been successfully used for ODW simulations with a two-step mechanism [32][33][34], as well as detailed chemical kinetics [15]. In the current study, the simulations are performed by solving two-dimensional time-dependent compressible reactive multi-species Euler equations with detailed chemical kinetics for various incoming flows.…”

Section: Methodsmentioning

confidence: 99%

Oblique Detonation Wave Control with O3 and H2O2 Sensitization in Hypersonic Flow

Vashishtha

Panigrahy²,

Campi³

et al. 2022

Energies

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This numerical study investigates the effects of adding a small amount of ignition promoters for controlling the wedge-induced oblique shock wave (OSW) to oblique detonation wave (ODW) transition in a premixed hydrogen–air mixture at hypersonic speeds. The time-dependent two-dimensional compressible Euler equations for multiple thermally perfect species with a reactive source term are solved using adaptive mesh refinement and detailed chemical kinetics. The wedge with a fixed angle of 26∘ exhibits abrupt to smooth transitions for freestream Mach numbers 7–9 (speeds 2.8–3.2 km/s) at a pressure of 20 kPa and a temperature of 300 K. The small amount (1000 PPM by vol.) of H2O2 and O3 is found to be effective at significantly reducing the initiation length for the oblique detonation transition for all Mach numbers, which suggests a practical approach to increase the operating flight range for oblique detonation wave engine with a finite length wedge. At Mach number 8, the abrupt OSW to ODW transition turns towards a smooth transition with a small amount of H2O2 and O3 addition. Comparatively, O3 addition was found to be effective in reducing the ODW initiation length by promoting reactivity behind even a weaker oblique shock at low Mach number 7, for abrupt transition, while H2O2 addition was more effective than O3 at high Mach numbers 8 and 9, during a smooth transition. The maximum 73% and 80% reduction in initiation length of ODW was observed with 10,000 PPM H2O2 and O3 addition, respectively, during an abrupt OSW to ODW transition at Mach 7.

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Section: Methodsmentioning

confidence: 99%

Oblique Detonation Wave Control with O3 and H2O2 Sensitization in Hypersonic Flow

Vashishtha

Panigrahy²,

Campi³

et al. 2022

Energies

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Numerical investigation on movement of triple points on oblique detonation surfaces

Yang

Chen

et al. 2022

Physics of Fluids

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Normal detonation wave in a gaseous mixture is a transient, multidimensional structure containing triple points (TPs) that collide in pairs and then propagate oppositely. However, the TPs on an oblique detonation wave (ODW) almost propagate along the same direction in most studies. In this study, the reactive Euler equations coupled with a two-step induction-reaction kinetic model are used to solve two-dimensional wedge-induced ODW. Two novel movement patterns are observed in most cases. Results show that the TPs of the ODW can propagate upstream and even stand on the wave surface. The movement patterns of TPs include downstream, upstream, and steady according to their propagation direction relative to the wedge. We find that the ratio of the post-ODW flow speed Uτ to the transverse wave speed UT dominates the TP movement types. When the speed ratio Uτ/ UT is approximately equal to 1, the TPs can stand on the wave surface. Above unity, downstream TPs form, and upstream TPs correspond to a value smaller than 1. Furthermore, the inflow Mach number has little influence on UT, while Uτ changes significantly. This is largely due to the high sensitivity of the ODW angle to the inflow. The high heat release rate benefits upstream TPs, and steady TPs form under a large wedge angle. The results are confirmed by varying the inflow Mach number, wedge angle, and chemical parameters.

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Numerical Study of Disturbance Resistance of Oblique Detonation Waves

Cited by 2 publications

References 35 publications

Oblique Detonation Wave Control with O3 and H2O2 Sensitization in Hypersonic Flow

Oblique Detonation Wave Control with O3 and H2O2 Sensitization in Hypersonic Flow

Numerical investigation on movement of triple points on oblique detonation surfaces

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