The re-initiation of cellular detonations downstream of an inert layer
The re-initiation of cellular detonations downstream of an inert layer
The current work aims to examine how the nature of cellular instabilities controls the re-initiation capability and dynamics of a gaseous detonation transmitting across a layer of inert (or non-detonable) gases. This canonical problem is tackled via computational analysis based on the two-dimensional, reactive Euler equations. Two different chemical kinetic models were used, a simplified two-step induction-reaction model and a detailed model for hydrogen-air. For the two-step model, cases with relatively high and low activation energies, representing highly and weakly unstable cellular detonations, respectively, are considered. For the weakly unstable case, two distinct types of re-initiation mechanisms were observed. (1) For thin inert layers, at the exit of the layer the detonation wave front has not fully decayed and thus the transverse waves are still relatively strong. Detonation re-initiation in the reactive gas downstream of the inert layer occurs at the gas compressed by the collision of the transverse waves, and thus is referred to as a cellular-instability-controlled re-initiation. (2) If an inert layer is sufficiently thick, the detonation wave front has fully decayed to a planar shock when it exits the inert layer, and re-initiation still occurs downstream as a result of planar shock compression only, which is thus referred to as a planar-shock-induced re-initiation. Between these two regimes there is a transition region where the wave front is not yet fully planar, and thus perturbations by the transverse waves still play a role in the re-initiation. For the highly unstable case, re-initiation only occurs via the cellular-instability-controlled mechanisms below a critical thickness of the inert layer. Additional simulations considering detailed chemical kinetics demonstrate that the critical re-initiation behaviors of an unstable stoichiometric mixture of hydrogen-air at 1 atm and 295 K are consistent with the finding from the two-step kinetic model for a highly unstable reactive mixture.
Detonation re-initiation, cellular instabilities, detonation in non-uniform media, gap test for gaseous detonation, inert layer
3127-3135
Tang-Yuk, Kelsey C.
cd1669c2-683e-4dc8-a4f5-14d128a28be1
Lee, John H.S.
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Ng, Hoi Dick
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Deiterding, Ralf
ce02244b-6651-47e3-8325-2c0a0c9c6314
Mi, XiaoCheng
67401559-3612-4c4f-a666-ca2954e8b5b8
7 June 2023
Tang-Yuk, Kelsey C.
cd1669c2-683e-4dc8-a4f5-14d128a28be1
Lee, John H.S.
b40c55df-deb0-46d8-ab63-61458d8c35ec
Ng, Hoi Dick
a01c36c4-8982-4976-ab0e-b2113ff0da4f
Deiterding, Ralf
ce02244b-6651-47e3-8325-2c0a0c9c6314
Mi, XiaoCheng
67401559-3612-4c4f-a666-ca2954e8b5b8
Tang-Yuk, Kelsey C., Lee, John H.S., Ng, Hoi Dick, Deiterding, Ralf and Mi, XiaoCheng
(2023)
The re-initiation of cellular detonations downstream of an inert layer.
Proceedings of the Combustion Institute, 39 (3), .
(doi:10.1016/j.proci.2022.08.045).
Abstract
The current work aims to examine how the nature of cellular instabilities controls the re-initiation capability and dynamics of a gaseous detonation transmitting across a layer of inert (or non-detonable) gases. This canonical problem is tackled via computational analysis based on the two-dimensional, reactive Euler equations. Two different chemical kinetic models were used, a simplified two-step induction-reaction model and a detailed model for hydrogen-air. For the two-step model, cases with relatively high and low activation energies, representing highly and weakly unstable cellular detonations, respectively, are considered. For the weakly unstable case, two distinct types of re-initiation mechanisms were observed. (1) For thin inert layers, at the exit of the layer the detonation wave front has not fully decayed and thus the transverse waves are still relatively strong. Detonation re-initiation in the reactive gas downstream of the inert layer occurs at the gas compressed by the collision of the transverse waves, and thus is referred to as a cellular-instability-controlled re-initiation. (2) If an inert layer is sufficiently thick, the detonation wave front has fully decayed to a planar shock when it exits the inert layer, and re-initiation still occurs downstream as a result of planar shock compression only, which is thus referred to as a planar-shock-induced re-initiation. Between these two regimes there is a transition region where the wave front is not yet fully planar, and thus perturbations by the transverse waves still play a role in the re-initiation. For the highly unstable case, re-initiation only occurs via the cellular-instability-controlled mechanisms below a critical thickness of the inert layer. Additional simulations considering detailed chemical kinetics demonstrate that the critical re-initiation behaviors of an unstable stoichiometric mixture of hydrogen-air at 1 atm and 295 K are consistent with the finding from the two-step kinetic model for a highly unstable reactive mixture.
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Accepted/In Press date: 11 August 2022
e-pub ahead of print date: 23 October 2022
Published date: 7 June 2023
Additional Information:
Funding Information:
Kelsey Tang-Yuk was supported by the Fonds de recherche du Québec - Nature et technologies, file number 270439.
Publisher Copyright:
© 2022 Elsevier Inc. All rights reserved.
Keywords:
Detonation re-initiation, cellular instabilities, detonation in non-uniform media, gap test for gaseous detonation, inert layer
Identifiers
Local EPrints ID: 470544
URI: http://eprints.soton.ac.uk/id/eprint/470544
ISSN: 1540-7489
PURE UUID: cc6192bf-0e27-4a1f-8bb0-8f5bf5eb0c8c
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Date deposited: 12 Oct 2022 16:47
Last modified: 17 Mar 2024 03:39
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Contributors
Author:
Kelsey C. Tang-Yuk
Author:
John H.S. Lee
Author:
Hoi Dick Ng
Author:
XiaoCheng Mi
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