论文信息 - Simulations of cavity-stabilized flames in supersonic flows using reduced chemical kinetic mechanisms

Simulations of cavity-stabilized flames in supersonic flows using reduced chemical kinetic mechanisms

Abstract : The VULCAN CFD code integrated with a reduced chemical kinetic mechanism was applied to simulate cavity-stabilized ethylene-air flames and to predict flame stability limits in supersonic flows based on an experimental study. A 15-step reduced kinetic mechanism for ethylene was systematically developed through skeletal reduction with a directed relation graph and time scale reduction based on quasi-steady state assumptions. The accuracy of the reduced kinetic mechanism and its implementation in the VULCAN code were demonstrated in an auto-ignition problem with a range of parameters. 3D simulations were then carried out for cavity-stabilized flames at different fuel flow rates and turbulent Schmidt numbers. For comparison with the performance of the present reduced mechanism, a 3- and a 10-step global kinetic model were applied to simulate the same cavity combustor, and the results show that the 15-step reduced model predicts experimental results much better than the 3- and 10-step models. The importance of including accurate chemical kinetics in CFD simulations is therefore demonstrated.

[1] Campbell D. Carter,et al. Stability limits of cavity-stabilized flames in supersonic flow , 2005 .

[2] Campbell D. Carter,et al. Mixing and combustion studies using cavity-based flameholders in a supersonic flow , 2004 .

[3] R. A. Baurle,et al. Analysis of dual-mode hydrocarbon scramjet operation at Mach 4-6.5 , 2001 .

[4] R. Mercier,et al. Hypersonic Technology (HyTech) Program overview , 1998 .

[5] Vitali V. Lissianski,et al. Combustion chemistry of propane: A case study of detailed reaction mechanism optimization , 2000 .

[6] D. Singh,et al. Quasiglobal reaction model for ethylene combustion , 1994 .

[7] Hassan Hassan,et al. Analysis of Supersonic Combustors with Swept Ramp Injectors , 1997 .

[8] D. Kenzakowski,et al. Scalar Variance Transport in the Turbulence Modeling of Propulsive Jets , 1999 .

[9] N.-S. Liu,et al. The development of a variable Schmidt number model for jet-in-crossflows using genetic algorithms , 1999 .

[10] F. Billig,et al. Supersonic combustion experiments with a cavity-based fuel injector , 1999 .

[11] Andrew Hsu,et al. Application of genetic algorithms to the development of a variable Schmidt number model for jet‐in‐crossflows , 2001 .

[12] J. A. White,et al. A Psuedo-Temporal Multi-Grid Relaxation Scheme for Solving the Parabolized Navier-Stokes Equations , 1999 .