Instability and electrical response of small laminar coflow diffusion flames under AC electric fields: Toroidal vortex formation and oscillating and spinning flames

by Y. Xiong, S. Chung, M. Cha
Year: 2017 ISSN: DOI:10.1016/j.proci.2016.06.022

Bibliography

Instability and electrical response of small laminar coflow diffusion flames under AC electric fields: Toroidal vortex formation and oscillating and spinning flames

Y. Xiong, S. Chung, M. Cha

Proceedings of the Combustion Institute, 36 (1),1621-1628, (2017)

Abstract

Pub_2017_IAE

 

Dynamical and electrical responses of a small coflow diffusion flame were investigated by applying a high-voltage alternating current (AC), to a fuel jet nozzle. High-speed imaging and electrical diagnostics were adopted to capture flame dynamics and electrical signals, such as voltage (Vac), frequency (fac) and current (Iac). In the Vac–fac domain of 0–5 kV and 0–5 kHz, AC-driven instabilities, resulting in various flame modes such as an oscillation, pinch-off and spinning of flames were identified. Characteristic frequency of each mode was determined and a visualization of near-nozzle flow structures suggested a close causality of initial counter-rotating vortices (inner and outer toroidal vortices – ITV and OTV), to the other observed flame. An axisymmetric ITV shedding was identified within oscillating and pinch-off modes, while asymmetric ITV shedding was identified with the spinning mode. Integrated electric power over several AC periods correlated well with variation in the flame surface area for these instabilities, demonstrating that measured electric power is a potential indicator of combustion instabilities in electric-field-assisted combustion.

Keywords

Jet diffusion flame Alternating current Toroidal vortex Ionic wind