A Model of Turbulent Burning Velocity Taking the Preferential Diffusion Effect into Consideration
Hiroyuki Kido,Masaya Nakahara +1 more
TLDR
In this article, a model which takes the preferential diffusion effect into consideration, is proposed to predict the premixed turbulent burning velocity, using the local burning velocity as a reference instead of the original laminar burning velocity.Abstract:
In our previous work, we found that the preferential diffusion in a turbulent flame played an important role in its turbulent combustion characteristics, and estimated the local burning velocity in premixed turbulent combustion experimentally, taking account of the preferential diffusion effect. In this study, a model, which takes the preferential diffusion effect into consideration, is proposed to predict the premixed turbulent burning velocity, using the local burning velocity as a reference instead of the original laminar burning velocity. The model can be explained as follows. The turbulence affects the turbulent burning velocity by increasing the flame surface area and stretching the flame. Consequently, the turbulent burning velocity and quenching limit are determined by the balance of both effects. The predicted velocities are compared with the measured turbulent burning velocities where the fuel, equivalence ratio and the laminar burning velocity were varied extensively. As a result, quantitative accuracy of this simple model is confirmed.read more
Citations
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Molecular transport effects on turbulent flame propagation and structure
Andrei Lipatnikov,Jerzy Chomiak +1 more
TL;DR: In this paper, the effects of molecular transport on turbulent flame propagation and structure are critically discussed and the results of relevant studies of perturbed laminar flames (unstable flames, flame balls, flames in vortex tubes) are reviewed.
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Fuel flexibility, stability and emissions in premixed hydrogen-rich gas turbine combustion: Technology, fundamentals, and numerical simulations
Soufien Taamallah,Konstantina Vogiatzaki,Fahad M. Alzahrani,Esmail M. A. Mokheimer,Mohamed A. Habib,Ahmed F. Ghoniem +5 more
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Influence of local flame displacement velocity on turbulent burning velocity
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Turbulent flame stabilization modes in premixed swirl combustion: Physical mechanism and Karlovitz number-based criterion
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Syngas Mixture Composition Effects Upon Flashback and Blowout
TL;DR: In this paper, the Damkohler number scalings were used to predict blowoff equivalence ratios to within 10% for H2 /CO/CH4 mixtures.
References
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