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Numerical computations and optical diagnostics of unsteady partially premixed methane/air flames

Nogenmyr, Karl-Johan LU ; Kiefer, J.; Li, Zhongshan LU ; Bai, Xue-Song LU and Aldén, Marcus LU (2010) In Combustion and Flame 157(5). p.915-924
Abstract
The structures and dynamics of unsteady laminar partially premixed methane/air Bunsen flames are studied by means of numerical simulations, OH and CH PLIF imaging, and high speed chemiluminescence imaging employing a high framing speed intensified charge coupled device camera. The Bunsen burner has a diameter of 22 mm. Rich methane/air mixtures with an equivalence ratio of 1.5 are injected from the burner into atmosphere at different flow speeds ranging from 0.77 to 1.7 m/s, with Reynolds numbers based on the nozzle flow ranging from I 100 to 2500. The numerical simulations are based on a two-scalar flamelet manifold tabulation approach. Detailed chemistry is used to generate the flamelet manifold tabulation which relates the species... (More)
The structures and dynamics of unsteady laminar partially premixed methane/air Bunsen flames are studied by means of numerical simulations, OH and CH PLIF imaging, and high speed chemiluminescence imaging employing a high framing speed intensified charge coupled device camera. The Bunsen burner has a diameter of 22 mm. Rich methane/air mixtures with an equivalence ratio of 1.5 are injected from the burner into atmosphere at different flow speeds ranging from 0.77 to 1.7 m/s, with Reynolds numbers based on the nozzle flow ranging from I 100 to 2500. The numerical simulations are based on a two-scalar flamelet manifold tabulation approach. Detailed chemistry is used to generate the flamelet manifold tabulation which relates the species concentrations, reaction rates, temperature and density to a distance function G and mixture fraction Z. Two distinct reaction zones are identified using CH and OH PLIF imaging and numerical simulations; one inner reaction zone corresponds to premixed flames on the rich side of the mixture and one outer reaction zone corresponds to mixing controlled diffusion flames on the lean side of the mixture. Under normal gravity conditions both the inner premixed flames and the outer diffusion flames are unsteady. The outer diffusion flames oscillate with a flickering frequency of about 15 Hz, which slightly increases with the burner exit velocity. The inner premixed flames are more random with much more small-scale wrinkling structures. Under zero gravity conditions the outer diffusion flames are stable whereas the inner premixed flames are unstable and highly wrinkled. It appears that the outer diffusion flames are governed by the Rayleigh-Taylor instability whereas the inner premixed flames are dictated by Landau-Darrieus instability. The two-scalar flamelet approach is shown to capture the basic structures and dynamics of the investigated unsteady partially premixed flames. (C) 2009 The Combustion Institute. Published by Elsevier Inc. All rights reserved. (Less)
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author
organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
Buoyancy, Instabilities, Partially premixed flames, Double-flame structure, Planar laser-induced fluorescence
in
Combustion and Flame
volume
157
issue
5
pages
915 - 924
publisher
Elsevier
external identifiers
  • wos:000275687600008
  • scopus:77349105126
ISSN
0010-2180
DOI
10.1016/j.combustflame.2009.11.012
language
English
LU publication?
yes
id
b1ad2aba-10c8-40d0-bae1-d682aa9c1ea1 (old id 1588092)
date added to LUP
2010-04-22 10:55:02
date last changed
2018-05-29 09:55:33
@article{b1ad2aba-10c8-40d0-bae1-d682aa9c1ea1,
  abstract     = {The structures and dynamics of unsteady laminar partially premixed methane/air Bunsen flames are studied by means of numerical simulations, OH and CH PLIF imaging, and high speed chemiluminescence imaging employing a high framing speed intensified charge coupled device camera. The Bunsen burner has a diameter of 22 mm. Rich methane/air mixtures with an equivalence ratio of 1.5 are injected from the burner into atmosphere at different flow speeds ranging from 0.77 to 1.7 m/s, with Reynolds numbers based on the nozzle flow ranging from I 100 to 2500. The numerical simulations are based on a two-scalar flamelet manifold tabulation approach. Detailed chemistry is used to generate the flamelet manifold tabulation which relates the species concentrations, reaction rates, temperature and density to a distance function G and mixture fraction Z. Two distinct reaction zones are identified using CH and OH PLIF imaging and numerical simulations; one inner reaction zone corresponds to premixed flames on the rich side of the mixture and one outer reaction zone corresponds to mixing controlled diffusion flames on the lean side of the mixture. Under normal gravity conditions both the inner premixed flames and the outer diffusion flames are unsteady. The outer diffusion flames oscillate with a flickering frequency of about 15 Hz, which slightly increases with the burner exit velocity. The inner premixed flames are more random with much more small-scale wrinkling structures. Under zero gravity conditions the outer diffusion flames are stable whereas the inner premixed flames are unstable and highly wrinkled. It appears that the outer diffusion flames are governed by the Rayleigh-Taylor instability whereas the inner premixed flames are dictated by Landau-Darrieus instability. The two-scalar flamelet approach is shown to capture the basic structures and dynamics of the investigated unsteady partially premixed flames. (C) 2009 The Combustion Institute. Published by Elsevier Inc. All rights reserved.},
  author       = {Nogenmyr, Karl-Johan and Kiefer, J. and Li, Zhongshan and Bai, Xue-Song and Aldén, Marcus},
  issn         = {0010-2180},
  keyword      = {Buoyancy,Instabilities,Partially premixed flames,Double-flame structure,Planar laser-induced fluorescence},
  language     = {eng},
  number       = {5},
  pages        = {915--924},
  publisher    = {Elsevier},
  series       = {Combustion and Flame},
  title        = {Numerical computations and optical diagnostics of unsteady partially premixed methane/air flames},
  url          = {http://dx.doi.org/10.1016/j.combustflame.2009.11.012},
  volume       = {157},
  year         = {2010},
}