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NUMERICAL STUDY OF TURBULENT LEAN PREMIXED METHANE-AIR FLAMES

Year 2016, Issue: 1, 26 - 33, 01.03.2016

Abstract

Lean Premixed Combustion (LPC) is recently proposed in gas turbine combustors which have been operated
traditionally in the non-premixed mode. In this method, fuel and air are mixed before entering the combustor.
With LPC, the flame temperature is reduced due to the operating with excess air conditions. Thus, thermal NOx
can be reduced to negligible levels at these lean conditions. On the other hand, the local and global flame
extinction risks and therefore flame instabilities may arise because of operating at fuel-lean conditions near the
lean flammability limit. In order to control such flames, both their chemical kinetics and flame propagation
properties should be investigated in detail, mainly for various equivalence ratios.
In this study, the numerical simulations based on experimental data obtained from the combustion chamber
setup of the ICARE are performed. The experimental results concern turbulent premixed methane-air flames
stabilized on a Bunsen type burner; they are obtained by LDA for the cold and hot flow velocity statistics and by
laser induced Mie and Rayleigh scattering techniques for flame front statistics. The operating conditions in
experiments are chosen to be close to the gas turbine combustor operating conditions. Numerical simulations
are performed by using the Fluent® software. Both the analysis of the flow and turbulence properties of the
chamber by using the k-ε turbulence model and its variants and the premixed flame properties of the methane/air
mixtures are investigated. The influence of the equivalence ratio on the flame properties is examined as well. It
is observed that increase in equivalence ratio results in decrease in the flame length and the flame brush
thickness. Similar tendencies are observed in the experiments. Flame front properties are examined with the
combustion model provided by the Fluent® software, namely Zimont premixed model, and y the well-known CFM
turbulent premixed combustion model. Satisfactory results are obtained.

Year 2016, Issue: 1, 26 - 33, 01.03.2016

Abstract

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Details

Other ID JA92AC47CC
Journal Section Articles
Authors

Baris Yılmaz This is me

Sibel Özdoğan This is me

Iskender Gökalp This is me

Publication Date March 1, 2016
Published in Issue Year 2016 Issue: 1

Cite

APA Yılmaz, B., Özdoğan, S., & Gökalp, I. (2016). NUMERICAL STUDY OF TURBULENT LEAN PREMIXED METHANE-AIR FLAMES. Uluslararası Yakıtlar Yanma Ve Yangın Dergisi(1), 26-33.
AMA Yılmaz B, Özdoğan S, Gökalp I. NUMERICAL STUDY OF TURBULENT LEAN PREMIXED METHANE-AIR FLAMES. FCE Journal. March 2016;(1):26-33.
Chicago Yılmaz, Baris, Sibel Özdoğan, and Iskender Gökalp. “NUMERICAL STUDY OF TURBULENT LEAN PREMIXED METHANE-AIR FLAMES”. Uluslararası Yakıtlar Yanma Ve Yangın Dergisi, no. 1 (March 2016): 26-33.
EndNote Yılmaz B, Özdoğan S, Gökalp I (March 1, 2016) NUMERICAL STUDY OF TURBULENT LEAN PREMIXED METHANE-AIR FLAMES. Uluslararası Yakıtlar Yanma Ve Yangın Dergisi 1 26–33.
IEEE B. Yılmaz, S. Özdoğan, and I. Gökalp, “NUMERICAL STUDY OF TURBULENT LEAN PREMIXED METHANE-AIR FLAMES”, FCE Journal, no. 1, pp. 26–33, March 2016.
ISNAD Yılmaz, Baris et al. “NUMERICAL STUDY OF TURBULENT LEAN PREMIXED METHANE-AIR FLAMES”. Uluslararası Yakıtlar Yanma Ve Yangın Dergisi 1 (March 2016), 26-33.
JAMA Yılmaz B, Özdoğan S, Gökalp I. NUMERICAL STUDY OF TURBULENT LEAN PREMIXED METHANE-AIR FLAMES. FCE Journal. 2016;:26–33.
MLA Yılmaz, Baris et al. “NUMERICAL STUDY OF TURBULENT LEAN PREMIXED METHANE-AIR FLAMES”. Uluslararası Yakıtlar Yanma Ve Yangın Dergisi, no. 1, 2016, pp. 26-33.
Vancouver Yılmaz B, Özdoğan S, Gökalp I. NUMERICAL STUDY OF TURBULENT LEAN PREMIXED METHANE-AIR FLAMES. FCE Journal. 2016(1):26-33.