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Effect of burner geometry on swirl stabilized methane/air flames : A joint LES/OH-PLIF/PIV study

Liu, X. LU ; Elbaz, A. M. ; Gong, C. LU ; Bai, X. S. LU ; Zheng, H. T. and Roberts, W. L. (2017) In Fuel 207. p.533-546
Abstract

Large eddy simulation (LES) using a transported PDF model and OH-PLIF/PIV experiments were carried out to investigate the quarl effects on the structures of swirl stabilized methane/air flames. Two different quarls were investigated, one straight cylindrical quarl and one diverging conical quarl. The experiments show that the flames are significantly different with the two quarls. With the straight cylindrical quarl a compact blue flame is observed while with the diverging conical quarl the flame appears to be long and yellow indicating a sooty flame structure. The PIV results show the formation of a stronger flow recirculation inside the diverging conical quarl than that in the straight quarl. LES results reveal further details of the... (More)

Large eddy simulation (LES) using a transported PDF model and OH-PLIF/PIV experiments were carried out to investigate the quarl effects on the structures of swirl stabilized methane/air flames. Two different quarls were investigated, one straight cylindrical quarl and one diverging conical quarl. The experiments show that the flames are significantly different with the two quarls. With the straight cylindrical quarl a compact blue flame is observed while with the diverging conical quarl the flame appears to be long and yellow indicating a sooty flame structure. The PIV results show the formation of a stronger flow recirculation inside the diverging conical quarl than that in the straight quarl. LES results reveal further details of the flow and mixing process inside the quarl. The results show that with the diverging quarl vortex breakdown occurs much earlier towards the upstream of the quarl. As a result the fuel is convected into the air flow tube and a diffusion flame is stabilized inside the air flow tube upstream the quarl. With the straight quarl, vortex breakdown occurs at a downstream location in the quarl. The scalar dissipation rate in the shear layer of the fuel jet is high, which prevents the stabilization of a diffusion flame in the proximity of the fuel nozzle; instead, a compact partially premixed flame with two distinct heat release layers is stablized in a downstream region in the quarl, which allows for the fuel and air to mix in the quarl before combustion and a lower formation rate of soot. The results showed that the Eulerian Stochastic Fields transported PDF method can well predict the details of the swirl flame dynamics.

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author
; ; ; ; and
organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
Burner quarl, Flame structures, LES, PIV/OH-PLIF, Swirl stabilized flames
in
Fuel
volume
207
pages
14 pages
publisher
Elsevier
external identifiers
  • scopus:85021670527
  • wos:000405809300054
ISSN
0016-2361
DOI
10.1016/j.fuel.2017.06.092
language
English
LU publication?
yes
id
0f468714-9818-4e98-8740-870634690211
date added to LUP
2017-07-18 11:13:34
date last changed
2024-04-14 14:18:12
@article{0f468714-9818-4e98-8740-870634690211,
  abstract     = {{<p>Large eddy simulation (LES) using a transported PDF model and OH-PLIF/PIV experiments were carried out to investigate the quarl effects on the structures of swirl stabilized methane/air flames. Two different quarls were investigated, one straight cylindrical quarl and one diverging conical quarl. The experiments show that the flames are significantly different with the two quarls. With the straight cylindrical quarl a compact blue flame is observed while with the diverging conical quarl the flame appears to be long and yellow indicating a sooty flame structure. The PIV results show the formation of a stronger flow recirculation inside the diverging conical quarl than that in the straight quarl. LES results reveal further details of the flow and mixing process inside the quarl. The results show that with the diverging quarl vortex breakdown occurs much earlier towards the upstream of the quarl. As a result the fuel is convected into the air flow tube and a diffusion flame is stabilized inside the air flow tube upstream the quarl. With the straight quarl, vortex breakdown occurs at a downstream location in the quarl. The scalar dissipation rate in the shear layer of the fuel jet is high, which prevents the stabilization of a diffusion flame in the proximity of the fuel nozzle; instead, a compact partially premixed flame with two distinct heat release layers is stablized in a downstream region in the quarl, which allows for the fuel and air to mix in the quarl before combustion and a lower formation rate of soot. The results showed that the Eulerian Stochastic Fields transported PDF method can well predict the details of the swirl flame dynamics.</p>}},
  author       = {{Liu, X. and Elbaz, A. M. and Gong, C. and Bai, X. S. and Zheng, H. T. and Roberts, W. L.}},
  issn         = {{0016-2361}},
  keywords     = {{Burner quarl; Flame structures; LES; PIV/OH-PLIF; Swirl stabilized flames}},
  language     = {{eng}},
  month        = {{11}},
  pages        = {{533--546}},
  publisher    = {{Elsevier}},
  series       = {{Fuel}},
  title        = {{Effect of burner geometry on swirl stabilized methane/air flames : A joint LES/OH-PLIF/PIV study}},
  url          = {{http://dx.doi.org/10.1016/j.fuel.2017.06.092}},
  doi          = {{10.1016/j.fuel.2017.06.092}},
  volume       = {{207}},
  year         = {{2017}},
}