Effects of hydrogen addition on the forced response of H2/CH4 flames in a dual-nozzle swirl-stabilized combustor

The effects of hydrogen addition on the forced response of H-2/CH4 flames are analyzed in a dual-nozzle swirl-stabilized combustor. The hydrogen volumetric content in the fuel is varied from 0% to 40%. Flame transfer function (FTF) is used to compare the forced response of the flames. The FTF gain featuring the local maximum and minimum values, which occurred commonly in the FTFs under all hydrogen contents, is determined by two different mechanisms: the change in the flame angle and the flame roll-up phenomenon. Among two mechanisms, the flame roll-up phenomenon has a more important role in determining the FTF characteristics. In addition, hydrogen addition attenuates the local maximum gains and decreases the FTF phase slope. The change in the flame roll-up behavior, which is induced by a short and compact flame distribution at high hydrogen contents, is the primary reason of these differences in the FTF. (C) 2022 Hydrogen Energy Publications LLC. Published by Elsevier Ltd. All rights reserved.

Automated summary

The effects of hydrogen addition on the forced response of H-2/CH4 flames in a dual-nozzle swirl-stabilized combustor are analyzed. The study shows that the flame transfer function (FTF) characteristics are determined by the change in flame angle and the flame roll-up phenomenon, with the latter playing a more important role. In addition, hydrogen addition attenuates the local maximum gains and decreases the FTF phase slope. These differences are primarily attributed to the change in flame roll-up behavior induced by a short and compact flame distribution at high hydrogen contents.