Nonlinear dynamics of combustor azimuthal modes: Experiments and modeling

This paper provides an experimental and theoretical investigation of azimuthal instabilities in a lean, premixed combustor. It presents data from a high Reynolds number, industrial-scale facility with multi-ple fuel stages that enable variation of radial and azimuthal symmetries. The combustor exhibits a variety of behaviors - including standing, spinning, mixed waves, and intermittent behaviors, as well as periodic limit cycles and quasi-periodic oscillations - depending upon varying power and azimuthal symmetry. A second key objective of this paper is to present a weakly nonlinear framework that is used to under -stand and interpret these results, showing the influence of eigenmode degeneracy, background noise, and azimuthal non-uniformities in mean quantities such as temperature and flame-acoustic coupling. In par-ticular, this analysis shows the importance of the linear instability growth/damping rate and azimuthal non-uniformities in controlling the relative prominence of standing, spinning, or mixed waves at the limit cycle, as well as the preference in the spinning direction. It also shows the conditions under which single frequency or quasi-periodic oscillations are dominant, and how these are more fundamentally influenced by azimuthal non-uniformities and background noise. (c) 2021 The Combustion Institute. Published by Elsevier Inc. All rights reserved.

Automated summary

This paper investigates azimuthal instabilities in a lean, premixed combustor and presents a weakly nonlinear framework to interpret the results. It shows the importance of linear instability growth/damping rate and azimuthal non-uniformities in controlling different wave behaviors.