ABSTRACT
Given unsteady operating conditions, the combustion process in gas turbine combustor often suffers from equivalence ratio fluctuations (ERFs), which induce combustion instability. In this study, the effects of ERFs on a swirl-stabilized premixed flame were studied by large eddy simulation (LES). A new combustion model with turbulence modification and a two-step methane oxidation mechanism were employed to simulate the interaction between turbulence and chemical reactions. In this study, LES was first validated by comparing the simulation results with the corresponding experimental data of a baseline case. Furthermore, two types of ERFs with different frequencies (40 and 160 Hz) were set on the inlet surface of the combustor, and flame responses were predicted by LES. With fluctuation frequencies of 40 and 160 Hz, the inner shear layer was strengthened, and evident corresponding vortices were generated. Furthermore, a more conspicuous variation was observed at 40 Hz, and it meant that a stronger combustion instability was induced by ERFs with a lower frequency.
Acknowledgements
This work was supported by the Natural Science Foundation of Shandong Province of China (grant number ZR2021ME131).
Disclosure statement
No potential conflict of interest was reported by the author(s).
Additional information
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Notes on contributors
Chenghao Wu
Chenghao Wu (Email:[email protected]): Conceptualization, Investigation, Writing-Original Draft, Visualization.
Naiqi Li
Naiqi Li (Email:[email protected]): Investigation, Data Curation, Software.
Bin Zhang
Bin Zhang (Email:[email protected]): Conceptualization, Supervision, Resources, Funding acquisition.
Jieyu Jiang
Jieyu Jiang (Email:[email protected]): Methodology, Formal analysis, Validation.
Chunjie Sui
Chunjie Sui (Email:[email protected]): Conceptualization, Methodology, Visualization, Formal analysis, Writing - review & editing.