Contributions of flame thickening and local extinctions to burning rate of intensely turbulent premixed flames

TL;DR

This study investigates how flame thickening and local extinctions influence the burning rate of highly turbulent hydrogen-enriched methane flames, revealing new experimental insights and developing a novel formulation that accounts for non-flamelet behavior.

Contribution

It provides the first experimental evidence of broadening reaction zones in intensely turbulent flames and introduces a new burning rate model that does not rely on the flamelet assumption.

Findings

Reaction zone broadening increases with turbulence intensity.

A new burning rate formulation correlates with reaction zone thickening.

Local extinctions decrease the burning rate, causing a bending behavior.

Abstract

Influences of reaction zone thickening and local extinctions on the burning rate of extremely turbulent hydrogen-enriched methane-air flames are investigated using simultaneous planar laser-induced fluorescence of formaldehyde molecule and hydroxyl radical as well as separate stereoscopic particle image velocimetry techniques. Karlovitz numbers upto 76 are examined. It is shown that, by increasing the turbulence intensity, the preheat and reaction zone thicknesses can increase to values that are, respectively, 6.3 and 4.9 of the corresponding laminar flames. Broadening of these zones for intensely turbulent hydrogen-enriched methane-air flames is shown experimentally for the first time. Broadening of the reaction zone suggests that the flamelet assumption used for development of the burning rate formulations may not hold. Thus, a new formulation, which does not utilize the flamelet assumption, is developed and used to calculate the burning rate of the tested flames. It is shown that, at small turbulence intensities, the burning rate values follow those of the local consumption speed, which is developed in the literature based on the flamelet assumption. However, at large turbulence intensities, the estimated burning rate features large values, and the ratio of this parameter to the local consumption speed is consistent with the ratio of the global and local consumption speeds reported in the literature. It is shown that the ratio of the normalized burning rate to the normalized local consumption speed is correlated with the broadening of reaction zone, suggesting that the disparity between the values of the burning rate and local consumption speed is linked to the reaction zone thickening. It is shown, although the flame thickening increase the burning rate, local extinctions decrease this parameter leading to the bending behavior reported in the literature.