Experimental Investigation on Two-Phase Rotating Detonation Fueled by Kerosene in a Hollow Directed Combustor

Xue, Sainan; Ying, Zhuojun; Ma, Haitao; Zhou, Changsheng

doi:10.3389/fenrg.2022.951177

Front. Energy Res.

2022

DOI: 10.3389/fenrg.2022.951177

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Experimental Investigation on Two-Phase Rotating Detonation Fueled by Kerosene in a Hollow Directed Combustor

Sainan Xue

Zhuojun Ying²,

Haitao Ma³

et al.

Abstract: The operating characteristic of two-phase rotating detonation fueled by kerosene in a hollow combustor with the isolation section is experimentally studied. When the air mass flow rate is 1.5 kg/s, the equivalence ratio is 0.98, and the total temperature of the mixture is 650 K, the stable rotating detonation wave (RDW) is obtained, which verifies the feasibility of the designed two-phase rotating detonation combustor (RDC). It is found that there is a high-frequency oblique shock induced by the upstream rotat… Show more

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Cited by 8 publications

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“…Although research on disk-shaped combustors began in the 1960s (Voitsekhovskii et al, 1969), there have been few related studies due to the complex shockwave system (Xia et al, 2022). The hollow combustor with a relatively simple structure has also been rarely studied (Meng et al, 2022;Xue et al, 2022). However, annular combustors have been a mainstream research object in RDEs, and relevant studies are extensive (Zhou et al, 2018;Kawasaki et al, 2019;Dunn et al, 2020).…”

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Experimental study on the rotating detonation engine based on a gas mixture

Xue

Zhang

Yang³

et al. 2023

Front. Energy Res.

Self Cite

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A direct connection test of a rotating detonation engine was conducted. The outer and inner diameters of the annular combustors were 206 and 166 mm, respectively. High enthalpy air was used as an oxidizer, and a mixture of hydrogen, carbon monoxide, and methane was used as fuel with a volume fraction of 5/4/1. The mixture was injected through small holes, and air was injected through annular slots. The effects of combustor length, width of annular slots, and the equivalent ratio on formation, development, propagation, and flameout of rotating detonation waves were analyzed, and several modes of rotating detonation were observed. It was found that when the width of the air annular slot was within the range of 3–5 mm, the pressure of the detonation wave was augmented with an increased slot width. As width increased, detonation waves became unstable. In study test conditions, an annular slot width of 6 mm was the critical condition for the formation of stable detonation. When the slot width was 4 mm and combustor length 160 mm, the phenomena of the conversion between single and double waves, double-wave collision, and conversion of the propagation direction occurred at different equivalent ratios. When the equivalent ratio was 1.2/1 and the slot width was within the range of 3–6 mm, the slot width was inversely related to the detonation wave velocity. When the slot width was 4 mm and the equivalent ratio was 1.0/1–1.2/1, the slot width was positively correlated with the detonation wave velocity. When the combustor length was shortened to 80 mm, the propagation mode of the detonation wave was changed to a single wave first and then to a double wave in the same direction, and the velocity reduced from 1130.69 to 1024.16 m/s. The injector used in the test inhibited the propagation of back pressure from the combustor.

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confidence: 99%

Experimental study on the rotating detonation engine based on a gas mixture

Xue

Zhang

Yang³

et al. 2023

Front. Energy Res.

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Air-breathing rotating detonation engine supplied with liquid kerosene: propulsive performance and combustion stability

Perkowski,

Bilar,

Augustyn

et al. 2024

Shock Waves

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Experimental results are presented for a rotating detonation engine supplied with liquid kerosene and preheated air without liquid or gaseous additions to the propellant mixture. Various combustion modes for the generic combustor geometry design were observed—from deflagration, through pulsed combustion and high-frequency instabilities, to stable detonation propagation. Attention was paid to detonation stability (if present), its characteristics, and the propulsive performance of the combustor with a focus on specific thrust and pressure gain through thrust and outlet total pressure measurement. These parameters measured for the observed modes were compared. The stability of the detonation combustion proved not to be critical to achieve high performance of the combustion chamber. For example, high performance was achieved for combustion modes with high-frequency instabilities.

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Investigation of multi-stage evaporation and wave multiplicity of two-phase rotating detonation waves fueled by ethanol

Li,

Lei,

Yao

et al. 2023

Acta Astronautica

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Experimental Investigation on Two-Phase Rotating Detonation Fueled by Kerosene in a Hollow Directed Combustor

Cited by 8 publications

References 21 publications

Experimental study on the rotating detonation engine based on a gas mixture

Experimental study on the rotating detonation engine based on a gas mixture

Air-breathing rotating detonation engine supplied with liquid kerosene: propulsive performance and combustion stability

Investigation of multi-stage evaporation and wave multiplicity of two-phase rotating detonation waves fueled by ethanol

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