TY - CONF
T1 - Chemiluminescent OH* and CH* flame structure and aerodynamic scaling of weakly buoyant, nearly spherical diffusion flames
AU - Yoo, S. W.
AU - Law, C. K.
AU - Tse, S. D.
N1 - Funding Information:
It is a pleasure to acknowledge the assistance of Mr. D. L. Zhu and Mr. E. W. Christiansen in the experimental and computational aspects of the investigation, Drs. K. Sacksteder and D. Feikema of NASA-Glenn for the arrangements of equipments and for helpful discussions, and Dr. G. Smith of SRI for invaluable guidance in modeling the chemiluminescent species. This work was supported by the NASA Microgravity Combustion Program.
PY - 2002
Y1 - 2002
N2 - Normal-gravity experiments were conducted with "inverse" diffusion flames of small density difference with their surrounding ambient to study low Grashof number (Gr) flames that were several centimeters in diameter. The intensity of buoyancy was minimized by ejecting diluted air from a porous, spherical burner into a lower-density fuel atmosphere of hydrogen and methane at reduced pressures (< 0.25 atm). For the hydrogen flames, the comparison was very satisfactory, hence substantiating the adequacy of the chemistry and the experimental approach. For hydrogen/methane flames, OH* chemiluminescence exhibited two peaks, demonstrating the importance of the H + O + M ⇌ OH* + M reaction in addition to the CH + O2 ⇌ OH* + CO reaction. The hydrogen/methane flames also experienced a mild degree of buoyancy, which shifted the peak OH* and CH* locations from the calculated values. Through a separate experimental investigation, the effects of weak buoyancy, based on the flame dimension, scale with Gr1/2 were determined, and was in accord with the low Gr scaling for heat transfer phenomena. The associated correction explained the shifts in the locations of the experimental OH* and CH* peaks. Original is an abstract.
AB - Normal-gravity experiments were conducted with "inverse" diffusion flames of small density difference with their surrounding ambient to study low Grashof number (Gr) flames that were several centimeters in diameter. The intensity of buoyancy was minimized by ejecting diluted air from a porous, spherical burner into a lower-density fuel atmosphere of hydrogen and methane at reduced pressures (< 0.25 atm). For the hydrogen flames, the comparison was very satisfactory, hence substantiating the adequacy of the chemistry and the experimental approach. For hydrogen/methane flames, OH* chemiluminescence exhibited two peaks, demonstrating the importance of the H + O + M ⇌ OH* + M reaction in addition to the CH + O2 ⇌ OH* + CO reaction. The hydrogen/methane flames also experienced a mild degree of buoyancy, which shifted the peak OH* and CH* locations from the calculated values. Through a separate experimental investigation, the effects of weak buoyancy, based on the flame dimension, scale with Gr1/2 were determined, and was in accord with the low Gr scaling for heat transfer phenomena. The associated correction explained the shifts in the locations of the experimental OH* and CH* peaks. Original is an abstract.
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M3 - Paper
AN - SCOPUS:0036943890
SP - 110
T2 - 29th International Symposium on Combustion
Y2 - 21 July 2002 through 26 July 2002
ER -