The Prediction of Burner Stability Limits
- 1 December 1984
- journal article
- research article
- Published by Taylor & Francis in Combustion Science and Technology
- Vol. 42 (1) , 67-86
- https://doi.org/10.1080/00102208408960369
Abstract
A flame extinction model is incorporated in a computational procedure containing the “k-ϵ-g” model of turbulence and applied to the prediction of burner stability features of some furnace trials performed at the International Flame Research Foundation. The fuels are low calorific value gases. As a prelude to the application, the lifting of and blow off of turbulent jet diffusion flames are examined as well as the stability behaviour of baffle stabilized premixed flames. The extinction model presumes that reaction will cease when the diffusional rate between the fine turbulence scales exceeds the reaction rate, both of which quantities are simply characterized. Its performance across the range of flows studied is remarkably good. Diffusion flame blow off is well represented by straightforward considerations of jet similarity and fuel stoichi-ometry.Keywords
This publication has 7 references indexed in Scilit:
- Liftoff characteristics of turbulent jet diffusion flamesAIAA Journal, 1983
- Local Quenching Due to Flame Stretch and Non-Premixed Turbulent CombustionCombustion Science and Technology, 1983
- Fluctuating temperature measurements in turbulent jet diffusion flameCombustion and Flame, 1982
- Extinction in Turbulent Reacting FlowsCombustion Science and Technology, 1978
- The numerical computation of turbulent flowsComputer Methods in Applied Mechanics and Engineering, 1974
- Prediction of burning velocities of carbon monoxide-hydrogen-air flamesCombustion and Flame, 1967
- The stabilization mechanism of lifted diffusion flamesCombustion and Flame, 1966