Numerical studies of a thermokinetic model for oscillatory cool flame and complex ignition phenomena in ethanal oxidation under well-stirred flowing conditions

doi:10.1098/rspa.1989.0029

Cited by 13 publications

(1 citation statement)

References 32 publications

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“…The hydrogen abstraction reaction of acetaldehyde (reaction R35) as well as the intramolecular hydrogen shift reaction of the dihydroperoxy radical and its consumption reaction (reactions R36 and R37) was also considered, as described in ref . Besides, some low-temperature reactions about acetaldehyde oxidation (reactions R38–R60), derived from refs and were supplemented as well.…”

Section: Development and Validation Of The Improved Dee Mechanismmentioning

confidence: 99%

Improved Kinetic Mechanism for Diethyl Ether Oxidation with a Reduced Model

et al. 2017

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An improved diethyl ether (DEE) reaction mechanism consisting of 174 species and 973 reactions has been proposed. The present model is derived from an original model of Yasunaga et al. [A multiple shock tube and chemical kinetic modeling study of diethyl ether pyrolysis and oxidationYasunagaK.GillespieF.SimmieJ. M.CurranH. J.KuraguchiY.HoshikawaH.YamaneM.HidakaY. Yasunaga, K. Gillespie, F. Simmie, J. M. Curran, H. J. Kuraguchi, Y. Hoshikawa, H. Yamane, M. Hidaka, Y. J. Phys. Chem. A201011490989109]. On the basis of shock tube results in the temperature range of 900–1900 K, pressure range of 1–40 bar, and equivalence ratios of 0.5–2 as well as rapid compression machine (RCM) measurements of a stoichiometric DEE/O2/inert gas mixture at temperatures of 500–900 K and pressures of 3–4 bar, the ignition delay times (IDTs) were validated. Two-stage ignition at temperatures below 650 K and negative temperature coefficient (NTC) behavior at temperatures between 621 and 746 K are observed. In addition, the freely propagating flame velocities of a stoichiometric DEE/air mixture were validated at various temperatures as well. Using directed relation graph (DRG)-based methods for the improved mechanism reduction, a reduced mechanism composed of 80 species and 329 reactions has been achieved. Calculations for IDTs, laminar flame velocities, and temperature and species profiles using the reduced mechanism show very close agreement with those obtained using the improved mechanism. Meanwhile, sensitivity analyses of the burning velocity and IDT for the improved and reduced mechanisms were performed. Competing reactions related to DEE + OH and consumption of C2H5OC2H4s and HO2 were identified as being important for IDTs at various temperatures.

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Section: Development and Validation Of The Improved Dee Mechanismmentioning

confidence: 99%

Improved Kinetic Mechanism for Diethyl Ether Oxidation with a Reduced Model

et al. 2017

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A novel, thermal instability in a ‘semi‐batch’ reactor

Gray

Coppersthwaite

Griffiths

1993

Process Safety Progress

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An unusual type of oscillatory, thermal instability in a reaction which takes place in a semi‐batch reactor, (i.e., when one reactant is admitted slowly to the reaction vessel and mixes with another reactant already present in the system) is investigated experimentally and theoretically. We show not only that oscillatory temperature changes may occur that are sufficiently large to constitute a formidable explosion hazard but also that the conditions under which such a hazard may take place could be entered unwittingly, in a mistaken belief that a move away from a potentially hazardous zone is being made. The theoretical background is formulated analytically in the context of a first order exothermic reaction. However, from the experimental study of the exothermic gaseous reaction between hydrogen and chlorine, we confirm the existence of oscillations and we show that the main features predicted by the simple theory transpose to more complex kinetic systems. In this particular system, temperature changes in excess of 200 K were measured in the unstable oscillatory region. The experimental study is linked to the theoretical foundations through numerical modelling of the non‐isothermal process, based on a detailed kinetic mechanism of the H2 + Cl2 reaction. Similar oscillatory phenomena are also shown by numerical simulation to be possible in a semi‐batch reactor in an exothermic reaction between two liquids.

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