Inhibition of premixed and nonpremixed flames with phosphorus-containing compounds

The inhibition/extinction of various flames—premixed stoichiometric C 3H 8/air, nonpremixed counterflow CH 4/O 2/N 2, and nonpremixed coflow n-heptane/air cup-burner flames doped with a number of phosphorus-containing compounds (PCCs)—has been investigated experimentally. More than 20 PCCs (organic...

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Bibliographic Details
Published in:Proceedings of the Combustion Institute 2005-01, Vol.30 (2), p.2345-2352
Main Authors: Shmakov, A.G., Korobeinichev, O.P., Shvartsberg, V.M., Knyazkov, D.A., Bolshova, T.A., Rybitskaya, I.V.
Format: Article
Language:English
Subjects:
Burning velocity
Extinction strain rate
Inhibition
Phosphorus-containing compounds
Suppression
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Summary:The inhibition/extinction of various flames—premixed stoichiometric C 3H 8/air, nonpremixed counterflow CH 4/O 2/N 2, and nonpremixed coflow n-heptane/air cup-burner flames doped with a number of phosphorus-containing compounds (PCCs)—has been investigated experimentally. More than 20 PCCs (organic phosphates, phosphonates, phosphates) and their fluorinated derivatives were studied. All PCCs exhibited similar dependencies in burning velocities, extinction strain rates, and extinction volume fractions of CO 2 upon PCC loading in the range of mole fractions of 0–7000 ppm within an experimental deviation of ± 5%. This confirms that the inhibition effectiveness of the PCCs is influenced by the phosphorus content in the PCC molecule rather than by the structure of the molecule. The burning velocity of a stoichiometric C 3H 8/air mixture and the extinction strain rate of a nonpremixed counterflow CH 4/O 2/N 2 flame doped with trimethylphosphate were calculated. Satisfactory agreement between experimental and modeling results confirms the conclusion that the reactions of phosphorus oxyacids with radicals are responsible for flame inhibition.
ISSN:0082-0784
1540-7489
DOI:10.1016/j.proci.2004.07.003