| Dynamic interaction patterns of oblique detonation waves with boundary layers in hypersonic reactive flows | |
Sun, Jie; Yang PF(杨鹏飞) ; Chen, Zheng
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| Source Publication | COMBUSTION AND FLAME
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| 2025-01 | |
| Volume | 271Pages:113832 |
| ISSN | 0010-2180 |
| Abstract | Due to their high thermal cycle efficiency and compact combustor, oblique detonation engines hold great promise for hypersonic propulsion. Previous numerical simulations of oblique detonation waves have predominantly solved the Euler equations, disregarding the influence of viscosity and boundary layers. This work aims to study how the interaction between the oblique detonation wave and the boundary layer influences the detonation wave structures in confined spaces. Two-dimensional numerical simulations considering detailed chemistry are performed in a stoichiometric H2/air mixture. The results indicate that the wedge-induced oblique detonation wave generates a strong adverse pressure gradient upon impacting the upper wall, leading to boundary layer separation. The separation zone subsequently induces an oblique shock wave near the upper wall, and an increase in separation angle will cause the transition from an oblique shock wave to an oblique detonation wave. The formation of the separation zone reduces the actual flow area and may even lead to flow choking; its obstructive effect is similar to that of the Mach stem in inviscid flow. To establish a connection between the viscous recirculation zone and the inviscid Mach stem, we introduce a dimensionless parameter, eta , based on the inviscid assumption. It is defined as the ratio of the inviscid Mach stem height to the channel entrance height. This parameter can be used to identify three wave systems in a viscous flow field: separation shock-dominated wave systems, separation detonation-dominated wave systems, and unstable Mach stem- dominated wave systems. Among these, the appearance of detonation Mach stems leads to flow choking, and the shock-detonation wave system continually moves upstream, ultimately causing the failure of the oblique detonation combustion. The findings of this study provide new insights into the investigation of the influence of viscosity on the flow structure of oblique detonation waves. |
| Keyword | Oblique detonation wave Boundary layer Flow separation Choked flow |
| DOI | 10.1016/j.combustflame.2024.113832 |
| Indexed By | SCI ; EI |
| Language | 英语 |
| WOS ID | WOS:001350436400001 |
| WOS Research Area | Thermodynamics ; Energy & Fuels ; Engineering |
| WOS Subject | Thermodynamics ; Energy & Fuels ; Engineering, Multidisciplinary ; Engineering, Chemical ; Engineering, Mechanical |
| Funding Organization | National Natural Science Foundation of China {12202014] ; Science Foundation for Young Scientists of State Key Laboratory of High Temperature Gas Dynamics {2023QN09] |
| Classification | 一类/力学重要期刊 |
| Ranking | 1 |
| Contributor | Yang PF |
| Citation statistics | |
| Document Type | 期刊论文 |
| Identifier | http://dspace.imech.ac.cn/handle/311007/97166 |
| Collection | 高温气体动力学国家重点实验室 |
| Affiliation | 1.【Sun, Jie & Yang, Pengfei & Chen, Zheng】 Peking Univ, Coll Engn, CAPT, SKLTCS,HEDPS, Beijing 100871, Peoples R China 2.【Yang, Pengfei】 Chinese Acad Sci, State Key Lab High Temp Gas Dynam, Inst Mech, Beijing 100190, Peoples R China |
| Recommended Citation GB/T 7714 | Sun, Jie,Yang PF,Chen, Zheng. Dynamic interaction patterns of oblique detonation waves with boundary layers in hypersonic reactive flows[J]. COMBUSTION AND FLAME,2025,271:113832.Rp_Au:Yang PF |
| APA | Sun, Jie,杨鹏飞,&Chen, Zheng.(2025).Dynamic interaction patterns of oblique detonation waves with boundary layers in hypersonic reactive flows.COMBUSTION AND FLAME,271,113832. |
| MLA | Sun, Jie,et al."Dynamic interaction patterns of oblique detonation waves with boundary layers in hypersonic reactive flows".COMBUSTION AND FLAME 271(2025):113832. |
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