Flamelet Motion in Premixed Turbulent Axisymmetric Rod-Stabilized and Bunsen Flames

A four-element electrostatic probe was employed to examine flamelet motion in axisymmetric propane-air flames at normal atmospheric pressure and temperature. Besides a number of turbulent (rim-stabilized) Bunsen flames, a turbulent V-shaped flame, stabilized by a vertical rod placed along the axis o...

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Bibliographic Details
Published in:Combustion science and technology 2010-01, Vol.182 (1), p.1-38
Main Authors: Furukawa, Junichi, Hashimoto, Hideki, Williams, Forman A.
Format: Article
Language:English
Subjects:
Applied sciences
Atmospheric pressure
Axisymmetric
Bunsen flame
Combustion
Correlation analysis
Electrostatic probe
Electrostatics
Energy
Energy. Thermal use of fuels
Equipments for energy generation and conversion: thermal, electrical, mechanical energy, etc
Exact sciences and technology
Flamelet movement
Fluid dynamics
Fluid flow
Furnaces. Firing chambers. Burners
Gaseous fuel burners and combustion chambers
Laminar
Measurement
Propane
Temperature
Turbulence
Turbulent flow
Turbulent premixed flame
V flame
Velocity
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Summary:A four-element electrostatic probe was employed to examine flamelet motion in axisymmetric propane-air flames at normal atmospheric pressure and temperature. Besides a number of turbulent (rim-stabilized) Bunsen flames, a turbulent V-shaped flame, stabilized by a vertical rod placed along the axis of the Bunsen-type burner, was investigated. Measurements were conducted at three different positions in the Bunsen flames (i.e., one on the centerline and two off axis, the lowest being at half the height of the centerline position) and at two positions in the V flame (roughly corresponding to the off-axis positions of the Bunsen flames). For the Bunsen flames, measurements were made at three different propane-air equivalence ratios, two of them (one lean and the other rich) having the same laminar burning velocity. To aid in interpretation of the propane-air results for these last two measurements, Bunsen-flame measurements also were made for two (lean and rich) pairs of methane-air flames having the same laminar burning velocities. Fuel flow rates and turbulence intensities and scales were essentially the same in all experiments (fully developed turbulent pipe flow at a Reynolds number of 7000, with a ratio of mean velocity to laminar burning velocity on the order of ten). In all cases, scatterplots for flamelet velocity vectors were obtained when flamelets passed the probe in the direction of fresh-to-burnt mixtures and, separately, of burnt-to-fresh mixtures. Correlations between magnitudes and directions of flamelet velocities were measured, and probability distributions were generated for magnitudes and for directions of flamelet velocities. The results showed significant differences in distributions of magnitudes and of directions for fresh-to-burnt and for burnt-to-fresh passage. They also showed differences between the lean and rich propane flames but not between the lean and rich methane-flame pairs, the characteristics of which tended to resemble those of the lean propane flames. Finally, flamelet motions for the V flame were noticeably different in many respects from those for the Bunsen flames, as explained by the different effects of thermal expansion on the mean flow in the two configurations, the fresh mixture being radially on the inner side of the Bunsen flames and on the outer side of the V flame. The exceptional characteristics of rich propane were explained by nonlinear enhancement of the average flamelet burning velocity through preferentia
ISSN:0010-2202
1563-521X
DOI:10.1080/00102200903192253