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Keywords
(6)
Hot Spot
Initial Condition
Kinetics
Deflagration To Detonation Transition
Essentially Non Oscillatory
Shock Wave
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Shock-induced ignition with single step Arrhenius kinetics
Shock-induced ignition with single step Arrhenius kinetics,10.1016/j.ijhydene.2010.04.138,International Journal of Hydrogen Energy,J. Melguizo-Gavilan
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Shock-induced ignition with single step Arrhenius kinetics
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J. Melguizo-Gavilanes
,
N. Rezaeyan
,
M. Tian
,
L. Bauwens
Shock-initiated ignition is studied numerically for single step Arrhenius kinetics. This is relevant to hydrogen safety, because hydrogen detonates easily, and detonation in shocked mixture may occur in
deflagration to detonation transition
scenarios, due to shock reflections on obstacles subsequent to flame acceleration. Simulation of ignition behind a shock moving into combustible mixture is difficult because of the singular nature of the initial conditions. The solution method includes two components. First, space as an independent variable is replaced by the ratio space over time, and second, initial conditions at a small non-zero time are used, obtained in closed form from short time asymptotics. This way, the initial singularity is effectively removed and the early process is well resolved. This method was used to study how the leading shock strength, and the heat release, affects the shock-initiated ignition process. The Essentially Non-Oscillatory algorithm used captures ignition,
hot spot
growth, birth of a secondary shock and transition into a detonation. Results show that for weaker shock cases as well as for higher heat release the evolution is more rapid, that a secondary shock forms closer to the contact surface and quickly becomes a detonation wave.
Journal:
International Journal of Hydrogen Energy - INT J HYDROGEN ENERG
, vol. 36, no. 3, pp. 2374-2380, 2011
DOI:
10.1016/j.ijhydene.2010.04.138
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References
(11)
Shock-Generated Ignition: The Induction Zone
(
Citations: 27
)
P. A. Blythe
,
D. G. Crighton
Journal:
Proceedings of The Royal Society A: Mathematical, Physical and Engineering Sciences
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Ignition between a shock and a contact surface: Influence of the downstream temperature
(
Citations: 5
)
Luc Bauwens
Journal:
Proceedings of The Combustion Institute - PROC COMBUST INST
, vol. 28, no. 1, pp. 653-661, 2000
Shock formation ahead of hot spots
(
Citations: 3
)
Luc Bauwens
,
Zhe Liang
Journal:
Proceedings of The Combustion Institute - PROC COMBUST INST
, vol. 29, no. 2, pp. 2795-2802, 2002
Unsteady Gasdynamic Evolution of an Induction Domain Between a Contact Surface and a Shock Wave. I: Thermal Runaway
(
Citations: 6
)
Mark Short
,
J. William Dold
Journal:
Siam Journal on Applied Mathematics - SIAMAM
, vol. 56, no. 5, 1996
Ignition of thermally sensitive explosives between a contact surface and a shock
(
Citations: 3
)
Gary J. Sharpe
,
Mark Short
Journal:
Physics of Fluids - PHYS FLUIDS
, vol. 19, 2007