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Experimental and numerical investigation of the gas‐phase effectiveness of phosphorus compounds
Author(s) -
Bouvet Nicolas,
Linteris Gregory,
Babushok Valeri,
Takahashi Fumiaki,
Katta Viswanath,
Krämer Roland
Publication year - 2015
Publication title -
fire and materials
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.482
H-Index - 58
eISSN - 1099-1018
pISSN - 0308-0501
DOI - 10.1002/fam.2319
Subject(s) - dimethyl methylphosphonate , extinguishment , combustion , phosphorus , chemistry , bromine , methane , diffusion flame , diffusion , analytical chemistry (journal) , combustor , phase (matter) , chemical engineering , inorganic chemistry , environmental chemistry , organic chemistry , thermodynamics , physics , political science , law , engineering
Summary The effectiveness of phosphorus‐containing compounds as gas‐phase combustion inhibitors varies widely with flame type. To understand this behavior, experiments are performed with dimethyl methylphosphonate (DMMP) added to the oxidizer stream of methane–air co‐flow diffusion flames (cup‐burner configuration). At low volume fraction, phosphorus (via DMMP addition) is shown to be about four times as effective as bromine (via Br 2 addition) at reducing the amount of CO 2 required for extinguishment; however, above about 3000 μL/L to 6000 μL/L, the marginal effectiveness of DMMP is approximately zero. In contrast, the diminished effectiveness does not occur for Br 2 addition. To explore the role of condensation of active phosphorus‐containing compounds to the particles, laser‐scattering measurements are performed. Finally, to examine the behavior of the flame stabilization region (which is responsible for extinguishment), premixed burning velocity simulations with detailed kinetics are performed for DMMP addition to methane–air flames. Analyses of the numerical results are performed to understand the variation in the inhibition mechanism with temperature, agent loading, and stoichiometry, to interpret the loss of effectiveness for DMMP in the present experiments. Copyright © 2015 John Wiley & Sons, Ltd.

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