This paper presents experimental and modeling results for laminar prem
ixed methane-air flames inhibited by the fluoroethanes C2F6, C2HF5, an
d C2H2F4, and experimental results for the fluoropropanes C3F8 and C3H
F7. The modeling results are in good agreement with the measurements w
ith respect to reproducing flame speeds. For the fluoroethanes, calcul
ated flame structures are used to determine the reaction pathways for
inhibitor decomposition and the mechanisms of inhibition, as well as t
o explain the enhanced soot formation observed for the inhibitors C2HF
5, C2H2F4, and C3HF7. The agents reduce the burning velocity of rich a
nd stoichiometric flames primarily by raising the effective equivalenc
e ratio and lowering the adiabatic flame temperature. For lean flames,
the inhibition is primarily kinetic, since inhibitor reactions help t
o maintain the final temperature. The peak radical concentrations are
reduced beyond that due to the temperature effect through reactions of
fluorinated species with radicals. (C) 1998 by The Combustion Institu
te.