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Main Authors: Yang, Hongxia, Wang, Wentian, Zangane, Farzane, Cheevers, Kevin, Maley, Logan, Radulescu, Matei
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2401.08951
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author Yang, Hongxia
Wang, Wentian
Zangane, Farzane
Cheevers, Kevin
Maley, Logan
Radulescu, Matei
author_facet Yang, Hongxia
Wang, Wentian
Zangane, Farzane
Cheevers, Kevin
Maley, Logan
Radulescu, Matei
contents The attenuation and quenching of H$_2$/O$_2$ detonations transmitted across a column of cylinders were studied experimentally and analytically at sub-atmospheric pressures. Two distinct transmission regimes were observed: successful transmission and complete quenching. The transition between the two regimes was found to correlate with the ratio of inter-cylinder separation distance (b) to a characteristic detonation scale for large blockage ratios (BRs), with critical limits comparable with those previously reported for detonation diffraction from slots. Based on available cell size measurements, the critical transmission limit was $b/λ=4.5\pm3$. The proposed theoretical model based on Whitham's geometric shock dynamics confirmed the equivalence between the detonation diffraction at abrupt area changes and around cylinders with large BRs. Complete quenching observed experimentally was accounted for by the weak transmitted shock strength upon detonation failure. For the tested BRs, the transmitted shock speed ranged between 50% and 60% of the Chapman-Jouguet detonation speed. As a result, the post-shock temperatures fell below the cross-over regime for hydrogen ignition, leading to very long ignition delay times ($t_i$) despite the temperature rise induced by Mach reflection. The long $t_i$ suppressed auto-ignition, while the high isentropic exponent prevented further convective mixing required for re-initiation. This explained the fundamental difference between arresting hydrogen and hydrocarbon detonations, for which transmitted fast flames punctuated by auto-ignition events were always observed. The transmitted shock strength was found to be well-predicted by our previous self-similar multiple discontinuity gas-dynamic model. Over a very narrow range near the critical conditions, both hot spot re-ignition and detonation re-initiation from Mach shock reflections were observed.
format Preprint
id arxiv_https___arxiv_org_abs_2401_08951
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Detonation attenuation and quenching in hydrogen mixtures after the interaction with cylinders
Yang, Hongxia
Wang, Wentian
Zangane, Farzane
Cheevers, Kevin
Maley, Logan
Radulescu, Matei
Fluid Dynamics
The attenuation and quenching of H$_2$/O$_2$ detonations transmitted across a column of cylinders were studied experimentally and analytically at sub-atmospheric pressures. Two distinct transmission regimes were observed: successful transmission and complete quenching. The transition between the two regimes was found to correlate with the ratio of inter-cylinder separation distance (b) to a characteristic detonation scale for large blockage ratios (BRs), with critical limits comparable with those previously reported for detonation diffraction from slots. Based on available cell size measurements, the critical transmission limit was $b/λ=4.5\pm3$. The proposed theoretical model based on Whitham's geometric shock dynamics confirmed the equivalence between the detonation diffraction at abrupt area changes and around cylinders with large BRs. Complete quenching observed experimentally was accounted for by the weak transmitted shock strength upon detonation failure. For the tested BRs, the transmitted shock speed ranged between 50% and 60% of the Chapman-Jouguet detonation speed. As a result, the post-shock temperatures fell below the cross-over regime for hydrogen ignition, leading to very long ignition delay times ($t_i$) despite the temperature rise induced by Mach reflection. The long $t_i$ suppressed auto-ignition, while the high isentropic exponent prevented further convective mixing required for re-initiation. This explained the fundamental difference between arresting hydrogen and hydrocarbon detonations, for which transmitted fast flames punctuated by auto-ignition events were always observed. The transmitted shock strength was found to be well-predicted by our previous self-similar multiple discontinuity gas-dynamic model. Over a very narrow range near the critical conditions, both hot spot re-ignition and detonation re-initiation from Mach shock reflections were observed.
title Detonation attenuation and quenching in hydrogen mixtures after the interaction with cylinders
topic Fluid Dynamics
url https://arxiv.org/abs/2401.08951