Flame Transfer Functions and Dynamics of a Closely Confined Premixed Bluff Body Stabilized Flame With Swirl

The flame transfer function (FTF) and flame dynamics of a highly swirled, closely confined, premixed flame is studied over a wide range of equivalence ratios and bulk velocities at a fixed perturbation level at the dump plane. The operating conditions are varied to examine the ratio of flame height to velocity in scaling the FTF. The enclosure geometry is kept constant, resulting in strong flame-wall interactions for some operating conditions due to varying flame height. The resulting effect on the FTF due to changes in the effective flame confinement can therefore be studied. For sufficiently high equivalence ratio, and the resulting sufficiently small effective confinement, modulations of the FTF are observed due to interference of the perturbations created at the swirler and at the dump plane. The small length scales and high velocities result in modulations centered at high frequencies and spanning a wide range of frequencies compared to previous studies of similar phenomena. A critical point was reached for increasing effective confinement, where the modulations are suppressed. This is linked to a temporal shift in the heat release rate where the flame impinges on the combustion chamber walls. The shift reduced the expected level of interference, demonstrating effective confinement is important for the FTF response. Additionally, a distributed time lag (DTL) model with two time lags is successfully applied to the FTFs, providing a simple method to capture the two dominant time scales in the problem, recreate the FTF, and examine the effect of effective confinement.

Automated summary

The flame transfer function (FTF) and flame dynamics of a highly swirled, closely confined, premixed flame were studied over a wide range of equivalence ratios and bulk velocities, showing the importance of flame height to velocity ratio in scaling the FTF. Varying operating conditions resulted in different flame-wall interactions due to changes in flame height. For certain conditions, FTF modulations were observed due to interference of perturbations, but increasing effective confinement led to suppression of modulations. The study also successfully applied a distributed time lag (DTL) model to capture dominant time scales and examine the effect of effective confinement on the FTF response.