Large Eddy Simulation of a dual swirl gas turbine combustor: Flame/flow structures and stabilisation under thermoacoustically stable and unstable conditions

Large Eddy Simulation of a dual swirl gas turbine combustor: Flame/flow structures and stabilisation under thermoacoustically stable and unstable conditions

A laboratory gas turbine model combustor with dual-swirler configuration is investigated using Large Eddy Simulation (LES) with a flamelet subgrid combustion model. Two partially premixed methane/air flames with different equivalence ratio and thermal power are simulated: one stably burning with an...

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Bibliographic Details
Published in:Combustion and flame Vol. 203; pp. 279 - 300
Main Authors: Chen, Zhi X., Langella, Ivan, Swaminathan, Nedunchezhian, Stöhr, Michael, Meier, Wolfgang, Kolla, Hemanth
Format: Journal Article
Language:English
Published: New York Elsevier Inc 01-05-2019
Elsevier BV
Subjects:
Aerodynamics
Anchoring
Combustion chambers
Computational fluid dynamics
Computer simulation
Dual swirl
Equivalence ratio
Gas turbine model combustor
Gas turbines
Large Eddy Simulation
Partially premixed combustion
Pressure oscillations
Self-excited thermoacoustic instability
Shape
Simulation
Stability
Stagnation
Thermal simulation
Thermoacoustics
Vortices
Dual swirl
Gas turbine model combustor
Partially premixed combustion
Large Eddy Simulation
Self-excited thermoacoustic instability
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Summary:A laboratory gas turbine model combustor with dual-swirler configuration is investigated using Large Eddy Simulation (LES) with a flamelet subgrid combustion model. Two partially premixed methane/air flames with different equivalence ratio and thermal power are simulated: one stably burning with an elongated V-shape and another undergoing pronounced thermoacoustic oscillations exhibiting a flat shape. Additionally, both flames feature a hydrodynamic instability in the form of a precessing vortex core (PVC). Detailed comparisons between experimental and LES results show that the different flow and reaction zone structures in these two flames are reproduced well. The various flow dynamics resulting from the PVC and thermoacoustic oscillations are also captured accurately in the simulation. Further analyses on the lifted swirl flame stabilisation using phase averaged statistics at the PVC frequencies reveal that the PVC-induced stagnation points provide an anchoring mechanism for both the stable and unstable flames, although in the latter case large self-excited pressure oscillations are present. It is found that the PVC is significantly influenced by these oscillations, being axially stretched and compressed at high and low pressures, respectively. However, the formation of flame leading edge due to the PVC is robust during these unstable processes and the azimuthal movement of the leading point is found to be strongly correlated with the rotation of the PVC in both flames, further confirming the vital role of the PVC in the stabilisation process of these lifted swirl flames.
ISSN:0010-2180
1556-2921
DOI:10.1016/j.combustflame.2019.02.013