Effects of Continuous Volumetric Direct-Coupled Nonequilibrium Atmospheric Microwave Plasma Discharge on Swirl-Stabilized Premixed Flames

The effect of continuous volumetric direct-coupled nonequilibrium atmospheric microwave plasma discharge on swirl-stabilized premixed methane-air flames was investigated using quantitative OH planar laser-induced fluorescence and spectrally resolved emission. The plasma discharge was found to influe...

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Bibliographic Details
Published in:IEEE transactions on plasma science 2016-01, Vol.44 (1), p.39-48
Main Authors: Rajasegar, Rajavasanth, Mitsingas, Constandinos M., Mayhew, Eric K., Hammack, Stephen, Hyungrok Do, Tonghun Lee
Format: Article
Language:English
Subjects:
Aerodynamics
Atmospherics
Combustion
Density
Direct microwave coupling
Discharge
Discharges (electric)
Dynamics
Effects
Electrodes
Electromagnetic heating
Electronics
Electrostatic discharges
Flame stability
Furnaces
lean blow out
Microwave plasmas
nonequilibrium effects
OH planar laser-induced fluorescence (OH-PLIF)
ohmic heating
Plasma measurements
Plasma physics
plasma-assisted combustion
Plasmas
swirl stabilization
Vibration
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Summary:The effect of continuous volumetric direct-coupled nonequilibrium atmospheric microwave plasma discharge on swirl-stabilized premixed methane-air flames was investigated using quantitative OH planar laser-induced fluorescence and spectrally resolved emission. The plasma discharge was found to influence the dynamics of flame stabilization, i.e., plasma-assisted flames stabilized in the quiescent center body wake were relatively stable while swirl flames stabilized in the active inner shear layer were prone to local extinction due to aerodynamic shear. At coupled plasma powers corresponding to less than 3% of the thermal power output, in addition to the improved flame stability, significant improvement in the lean blow-out limit (~ 43%) and OH number density (~150%) was observed. The enhancements are shown to be nonequilibrium plasma effects and not predominantly ohmic heating as significant equivalence ratio dependence of OH number density in plasma-assisted flames was observed. Spectrographic measurements indicated nitrogen vibrational temperatures as high as 6100 K, suggesting both vibrational and electronic excitation of nitrogen molecules in the presence of a plasma discharge. The activation of highly reactive species through vibrational-vibrational relaxation and direct impact dissociation accelerates the combustion chemistry. It is demonstrated that microwave direct plasma coupling can drastically enhance the dynamic flame stability of swirl-stabilized flames, especially at very lean operating conditions.
ISSN:0093-3813
1939-9375
DOI:10.1109/TPS.2015.2499754