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Effect of partial premixing on stabilization and local extinction of turbulent methane/air flames

Baudoin, Eric LU ; Bai, Xue-Song LU ; Yan, Beibei LU ; Liu, C. ; Yu, R. LU ; Lantz, Andreas LU ; Hosseini, Seyed Mohammad LU ; Li, B. ; Elbaz, A. and Sami, M. , et al. (2013) In Flow, Turbulence and Combustion 90(2). p.269-284
Abstract
Abstract in Undetermined
The stabilization characteristics and local extinction structures of partially premixed methane/air flames were studied using simultaneous OH-PLIF/PIV techniques, and large eddy simulations employing a two-scalar flamelet model. Partial premixing was made in a mixing chamber comprised of two concentric tubes, where the degree of partial premixing of fuel and air was controlled by varying the mixing length of the chamber. At the exit of the mixing chamber a cone was mounted to stabilize the flames at high turbulence intensities. The stability regime of flames was determined for different degree of partial premixing and Reynolds numbers. It was found that in general partially premixed flames at low Reynolds... (More)
Abstract in Undetermined
The stabilization characteristics and local extinction structures of partially premixed methane/air flames were studied using simultaneous OH-PLIF/PIV techniques, and large eddy simulations employing a two-scalar flamelet model. Partial premixing was made in a mixing chamber comprised of two concentric tubes, where the degree of partial premixing of fuel and air was controlled by varying the mixing length of the chamber. At the exit of the mixing chamber a cone was mounted to stabilize the flames at high turbulence intensities. The stability regime of flames was determined for different degree of partial premixing and Reynolds numbers. It was found that in general partially premixed flames at low Reynolds numbers become more stable when the level of partial premixing of air to the fuel stream decreases. At high Reynolds numbers, for the presently studied burner configuration there is an optimal partial premixing level of air to the fuel stream at which the flame is most stable. OH-PLIF images revealed that for the stable flames not very close to the blowout regime, significant local extinction holes appear already. By increasing premixing air to fuel stream successively, local extinction holes grow in size leading to eventual flame blowout. Local flame extinction was found to frequently attain to locations where locally high velocity flows impinging to the flame. The local flame extinction poses a future challenge for model simulations and the present flames provide a possible test case for such study. (Less)
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organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
Partially premixed flames, Flame stabilization, Local quenching, Flame holes
in
Flow, Turbulence and Combustion
volume
90
issue
2
pages
269 - 284
publisher
Springer
external identifiers
  • wos:000315042000004
  • scopus:84878444856
ISSN
1573-1987
DOI
10.1007/s10494-012-9414-z
language
English
LU publication?
yes
id
604bff98-5f9a-4961-9939-3eaaab482252 (old id 3290426)
date added to LUP
2016-04-01 10:05:00
date last changed
2022-04-19 22:28:17
@article{604bff98-5f9a-4961-9939-3eaaab482252,
  abstract     = {{Abstract in Undetermined<br/>The stabilization characteristics and local extinction structures of partially premixed methane/air flames were studied using simultaneous OH-PLIF/PIV techniques, and large eddy simulations employing a two-scalar flamelet model. Partial premixing was made in a mixing chamber comprised of two concentric tubes, where the degree of partial premixing of fuel and air was controlled by varying the mixing length of the chamber. At the exit of the mixing chamber a cone was mounted to stabilize the flames at high turbulence intensities. The stability regime of flames was determined for different degree of partial premixing and Reynolds numbers. It was found that in general partially premixed flames at low Reynolds numbers become more stable when the level of partial premixing of air to the fuel stream decreases. At high Reynolds numbers, for the presently studied burner configuration there is an optimal partial premixing level of air to the fuel stream at which the flame is most stable. OH-PLIF images revealed that for the stable flames not very close to the blowout regime, significant local extinction holes appear already. By increasing premixing air to fuel stream successively, local extinction holes grow in size leading to eventual flame blowout. Local flame extinction was found to frequently attain to locations where locally high velocity flows impinging to the flame. The local flame extinction poses a future challenge for model simulations and the present flames provide a possible test case for such study.}},
  author       = {{Baudoin, Eric and Bai, Xue-Song and Yan, Beibei and Liu, C. and Yu, R. and Lantz, Andreas and Hosseini, Seyed Mohammad and Li, B. and Elbaz, A. and Sami, M. and Li, Zhongshan and Collin, Robert and Chen, G. and Fuchs, Laszlo and Aldén, Marcus and Mansour, M.S.}},
  issn         = {{1573-1987}},
  keywords     = {{Partially premixed flames; Flame stabilization; Local quenching; Flame holes}},
  language     = {{eng}},
  number       = {{2}},
  pages        = {{269--284}},
  publisher    = {{Springer}},
  series       = {{Flow, Turbulence and Combustion}},
  title        = {{Effect of partial premixing on stabilization and local extinction of turbulent methane/air flames}},
  url          = {{http://dx.doi.org/10.1007/s10494-012-9414-z}},
  doi          = {{10.1007/s10494-012-9414-z}},
  volume       = {{90}},
  year         = {{2013}},
}