Transition from turbulence-dominated to instability-dominated combustion regime in lean hydrogen-air flames

Abstract

Recent complex-chemistry direct numerical simulations of lean hydrogen-air flames propagating in forced turbulence in a box were continued by switching-off the turbulence forcing. Results show that a decrease in burning velocity UT(t), caused by the turbulence decay, is reversed when the turbulence becomes weak and a peak of UT(t) appears, with the peak magnitudes and associated Karlovitz numbers being similar in two different cases. These results (i) are attributed to activation of laminar flame instabilities, which have been suppressed by intense turbulence, and (ii) are argued to indicate that the instabilities can substantially affect UT in sufficiently weak turbulence only.