Your search keyword '"Laminar counterflow"' showing total 2 results

1. Effects of fuel droplet size distribution on soot formation in spray flames formed in a laminar counterflow.

Author

Hayashi, Jun, Fukui, Junichi, and Akamatsu, Fumiteru

Subjects

DROPLETS, PARTICLE size distribution, FUEL, SPRAYING, FLAME, LAMINAR flow, COUNTERFLOWS (Fluid dynamics)

Abstract

Abstract: The effects of fuel droplet size distribution of the fuel spray on the soot formation of spray flames, which is stabilized in a laminar counterflow field, were investigated numerically and experimentally. To investigate the effects of droplet size distribution of fuel spray on soot formation, fuel sprays with quasi-mono-dispersed droplet size distribution (QM-DSD) spray and poly-dispersed droplet size distribution (P-DSD) spray were generated using a frequency-tunable vibratory orifice atomizer. The differences in the spray flame structures and soot formation characteristics between QM-DSD and P-DSD were examined in detail using an experiment with two-dimensional laser induced incandescence of soot and using three-dimensional direct numerical simulations (3D-DNS) employing a CIP method. Results showed that the soot formation area in the cases of P-DSD decreased compared to the cases of the QM-DSD under the same Sauter mean diameter (SMD) condition. This tendency was caused by differences of the flame structures. The results of the fuel and oxygen concentration and temperature obtained from the 3D-DNS indicated that the portion of the premixed-like flame structure increased in the case of P-DSD. As a result, the combustion reaction region of the spray flames is enlarged in axis direction in the case of P-DSD in the counterflow field. [Copyright &y& Elsevier]

Published

2013

2. NUMERICAL STUDY OF STRUCTURES OF LAMINAR OPPOSED FLOW PREMIXED METHANE-HYDROGEN-AIR FLAMES AT LOW STRAIN RATE

Author

Deshpande Shrikrishna, Vasudevan Raghavan, and R. Sreenivasan

Subjects

Premixed flame, Materials science, Laminar flame speed, Flame structure, Diffusion flame, Laminar flow, Mechanics, Strain rate, Methane, Reaction rate, chemistry.chemical_compound, chemistry, Air mixtures, Chemical mechanism, Detailed chemical kinetic, Equivalence ratios, Experimental data, Flame zones, Fuel mixtures, Laminar counterflow, Lean mixtures, Low strain rates, Methane-air, Numerical investigations, Numerical models, Numerical studies, Opposed flow, Opposed flow flames, Optically thin radiation model, Parametric study, Premixed, Reaction steps, Reaction zones, Side streams, Species concentration, Submodels, Volumetric fractions, Combustors, Computer simulation, Hydrogen, Mixtures, Numerical methods, Reaction rates, General Environmental Science

Abstract

Numerical investigation of laminar counterflow premixed methane-hydrogen-air flames at a low strain rate is presented. Simulations are carried out with a numerical model incorporated with C2 chemical mechanism having 25 species and 121 reaction steps, and with an optically thin radiation submodel. The numerical model is validated using the experimental data reported in the literature in terms of temperature and species concentrations in flames from opposed flow premixed methane-air and hydrogen-air streams. Parametric studies are performed for opposed flowing methanehydrogen and air mixtures. A premixed methane-hydrogen and air with a rich mixture equivalence ratio (1.75) flows from the top duct, and one having a lean mixture equivalence ratio (0.25) flows from the bottom duct. The volumetric fraction of hydrogen in the fuel mixture has been varied from 20 to 80%. The strain rate used in the present study is kept constant at 50 s -1. Variation of velocity, temperature, species concentrations, and net reaction rates of oxygen, methane and hydrogen along the axis for various cases are presented and discussed in detail. Double flame zones are observed for all the cases. The addition of hydrogen to the rich side stream is seen to be effective in modifying the extents of both reaction zones. The reaction rate of methane is seen to be enhanced with the addition of hydrogen. � 2011 by Begell House, Inc.

Published

2011