1. Numerical modeling of buoyant ethanol-air wick diffusion flames
- Author
-
H.-Y. Lyu and L.-D. Chen
- Subjects
Chemistry ,General Chemical Engineering ,Diffusion flame ,General Physics and Astronomy ,Energy Engineering and Power Technology ,Numerical modeling ,Thermodynamics ,General Chemistry ,Pressure dependence ,Combustion ,Similarity solution ,Aspect ratio (image) ,Fuel Technology ,Diffusion (business) - Abstract
A numerical model based on a conserved-scalar approach is presented for buoyant ethanol-air wick diffusion flames at atmospheric and subatmospheric conditions. The model incorporates an equation that describes the interface condition of wick combustion. The prediction yields similarity solutions for flat-plate ethanol-air wick diffusion flames, but not for cylindrical wick diffusion flames. The flat-plate solution yields a mass burning rate per unit surface area following the x −1 4 dependence of the classical similarity solution, where x is the streamwise distance. A pressure dependence of P0.644 is predicted for the flat-plate overall mass burning rate, in agreement with the P 2 3 dependence reported in the literature. The cylindrical wicks have a mass burning rate per unit surface area that deviates from the x −1 4 dependence. The predicted mass burning rate, however, does not substantially deviate from the flat-plate solution for cylinders with a moderate aspect ratio (of the order one). The deviation in mass burning rate is most pronounced when needle-like cylinders are considered. The variable-property effects are also examined. The results show that the Chapman gas and constant-Prandtl-number assumptions are not adequate for wick diffusion flames, even at the subatmospheric-pressure condition studied.
- Published
- 1991
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