4.6 Article

The effects of turbulence on the lean blowout mechanisms of bluff-body flames

Journal

PROCEEDINGS OF THE COMBUSTION INSTITUTE
Volume 38, Issue 4, Pages 6317-6325

Publisher

ELSEVIER SCIENCE INC
DOI: 10.1016/j.proci.2020.06.138

Keywords

Lean blowout; Bluff-body flames; Turbulent flames; Flame stabilization and extinction

Funding

  1. Air Force Office of Scientific Research [19RT0258/FA9550-19-0322, FA9550-16-1-0044]

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Experimental investigation shows that the lean blowout process of premixed bluff-body flames is influenced by turbulence intensity. As turbulence levels increase, the blowout mechanism becomes more dependent on flame-turbulence interactions rather than flame and shear layer interactions. High turbulence conditions lead to flame-eddy interactions augmenting flame stretching and ultimately resulting in blowout.
The lean blowout mechanisms of premixed bluff-body flames are experimentally investigated at various turbulence intensities. Turbulence levels are varied using a novel turbulence generator, which combines static grid and fluidic jet impingement techniques. Three different turbulence levels are probed to study their effects on lean blowout. The three conditions span across the combustion regime diagram, from flamelets to broken reactions. For all three turbulence levels, the lean blowout process is induced through controlled fuel flow rate reduction. The transient blowout process is captured using three simultaneous high-speed diagnostic systems: particle image velocimetry (PIV), stereoscopic PIV (SPIV), and C 2 */CH * species measurements. The two PIV systems are used to resolve the instantaneous velocity and vorticity fields, and the C 2 */CH * species diagnostics allow for global equivalence ratios to be evaluated throughout the duration of blowout. The results show that the dynamics of lean blowout vary with turbulence intensity. At low turbulence levels, the flame experiences a global effect where the flame boundary interacts with the shear layer vorticity. This imparts high strain rates along the length of the flame, leading to blowout. As turbulence levels increase, the blowout mechanism becomes less dependent on flame and shear layer interactions and more driven by flame?turbulence interactions. At high turbulence conditions, flame-eddy interactions within the freestream augment flame stretching via increased flame straining and small-scale flame corrugations. Increased flame stretching disrupts the flame stabilization process, and ultimately results in blowout. ? 2020 The Combustion Institute. Published by Elsevier Inc. All rights reserved.

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