Abstract

The effects of heat release on interactions between vorticity (ω) and strain rate (s) in turbulent premixed CH4/O2/N2 counterflow flames are investigated using simultaneous OH laser-induced fluorescence (LIF) and tomographic particle image velocimetry (TPIV) measurements. A comparison between the flames and a corresponding turbulent non-reacting variable density N2-vs-products counterflow reveals the impact of heat release on vorticity-strain rate alignment statistics. Vorticity and strain rate statistics in the flames and non-reacting flow are conditioned on distance from the local flame front and gas mixing layer interface (GMLI) contours, respectively. The magnitude, alignment, and spatial distribution of the vorticity and principal strain rates (s1,s2,s3) are rather different when heat release is present. Density variations without heat release enhance the ω-s2 alignment while significantly reducing the ω-s3 alignment and modestly reducing the ω-s1 alignment. In contrast, heat release at the flame front further reduces the ω-s1 alignment but increases the ω-s3 alignment and suppresses the preferential ω-s2 alignment. Furthermore, increasing turbulence diminishes the effect of heat release on this preferential alignment. In regions with the largest vorticities, both the reacting and non-reacting counterflows show an increase in the probability of ω-s2 alignment. All counterflow cases have a net positive vortex-stretching contribution to the enstrophy production with a peak production rate at the flame front or GMLI, but the peak values depend on the density variation, heat release, and turbulence level. Elucidation of the complex interplay between these factors contributes to the understanding of the dynamics of turbulence-flame interactions.

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