Coupled interactions of a helical precessing vortex core and the central recirculation bubble in a swirl flame at elevated power density

The PRECCINSTA GTMC was studied at elevated pressure and power density with 6 kHz stereoscopic particle image velocimetry (SPIV), OH* chemiluminescence (CL), and 100 kHz dynamic pressure measurements. This technically premixed, swirl stabilized flame exhibited self-excited thermoacoustic oscillation...

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Bibliographic Details
Published inCombustion and flame Vol. 202; pp. 119 - 131
Main Authors Zhang, Robert, Boxx, Isaac, Meier, Wolfgang, Slabaugh, Carson D.
Format Journal Article
LanguageEnglish
Published New York Elsevier Inc 01.04.2019
Elsevier BV
Subjects
Bubbles
Chemiluminescence
Combustion
Combustion dynamics
Dynamic pressure
Gas turbine
Gas turbine engines
High pressure
Laser diagnostics
Organic chemistry
Oscillations
Particle image velocimetry
Shear layers
Stereoscopy
Swirling
Thermoacoustics
Turbulent swirl flame
Velocity distribution
Gas turbine
Combustion dynamics
Turbulent swirl flame
Laser diagnostics
High pressure
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Summary:The PRECCINSTA GTMC was studied at elevated pressure and power density with 6 kHz stereoscopic particle image velocimetry (SPIV), OH* chemiluminescence (CL), and 100 kHz dynamic pressure measurements. This technically premixed, swirl stabilized flame exhibited self-excited thermoacoustic oscillations with limit-cycle behavior. A helical precessing vortex core (PVC) was detected within the inner shear layer, between the central recirculation bubble (CRB) and the reactant jets. The PVC was found to be the delineating flow feature for combustion dynamics even at elevated pressure. Sparse dynamic mode decomposition (DMD) of the velocity fields deconvolved the dynamics into a thermoacoustic and PVC mode. The precession of the PVC was at a non-harmonic frequency to the thermoacoustic oscillations, and at least twice that of findings at atmospheric conditions. Nevertheless, the continuous and persistent structure of the PVC allows it promote unsteady heat release to sustain the thermoacoustic cycle. The three dimensional structure of the reactant jets, central recirculation bubble, and PVC was reconstructed by double phase conditioning the reconstructed velocity field. The surface of the CRB was observed to transition between asymmetric and symmetric states depending on the thermoacoustic phase. Analysis of the swirling strength values on the CRB surface indicates the interaction strength between the hydrodynamic structures of the PVC and CRB. When this coupling is large, the heat release determined by the mean OH*-CL intensity is maximum. These findings indicate a critical role of the PVC and CRB interaction on combustion in unstable swirl flames at conditions closer to those found in a modern gas turbine engine.
ISSN:0010-2180
1556-2921
DOI:10.1016/j.combustflame.2018.12.035