论文信息 - A numerical investigation of combustion parameters in various industrial furnaces

A numerical investigation of combustion parameters in various industrial furnaces

A computational fluid dynamics (CFD) code, developed at Argonne national laboratory to simulate turbulent mixing, combustion reaction, radiation heat transfer, and pollutant kinetics of combustion flow, has been used to study various melting furnaces. The code employs an integral approach to incorporate a lumped combustion reaction model in the flow calculation and a separate hybrid technique to perform pollutant kinetics calculations. The CFD code has been validated with experimental data collected from industrial furnaces and then used for a parametric study of various furnace geometries and operation conditions. The furnace configuration greatly effected the flow property distribution as well as the combustion efficiency. The air injection velocity effected the flow penetration and the species mixing. The injection angle also significantly effected the species mixing. And finally, the equivalence ratio effected the temperature and pollutant concentrations. The study demonstrates that CFD can be a useful tool for analyzing the flow field of the combustion space in industrial furnaces.

S.-L. Chang | K. Scheeringa | C.Q. Zhou

[1] Chenn Q. Zhou,et al. Validation of the Combustion Space Simulation of a Glass Furnace Model , 2001, Heat Transfer: Volume 4 — Combustion and Energy Systems.

[2] M. Petrick,et al. Investigation of Spectral Radiation Heat Transfer and NOx Emission in a Glass Furnace , 2000, Combustion, Fire, and Computational Modeling of Industrial Combustion Systems.

[3] Marcos S. P. Gomes,et al. The Influence of Oxygen Injection Configuration in the Performance of an Aluminum Melting Furnace , 1999, Heat Transfer: Volume 2.

[4] Robert C. Steele,et al. Development of a Five-Step Global Methane Oxidation–NO Formation Mechanism for Lean-Premixed Gas Turbine Combustion , 1998 .

[5] Ian M. Kennedy,et al. Models of soot formation and oxidation , 1997 .

[6] S. A. Lottes,et al. Integral Combustion Simulation of a Turbulent Reacting Flow in a Channel with Cross-Stream Injection , 1993 .

[7] M. Fairweather,et al. Predictions of radiative transfer from a turbulent reacting jet in a cross-wind , 1992 .

[8] Kambiz Vafai,et al. Numerical heat transfer , 1990 .

[9] R. Bui,et al. Performance analysis of the aluminum casting furnace , 1988 .

[10] K. Rhee,et al. A useful integral function and its application in thermal radiation calculations , 1983 .

[11] D. Edwards,et al. Radiative flame cooling for reduction of nitric oxide emissions , 1974 .