Modeling of Soot Formation in Gas Burner Using Reduced Chemical Kinetics Coupled with CFD Code
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[1] P. Glarborg,et al. Experimental and Kinetic Modeling Study of C2H4 Oxidation at High Pressure , 2009 .
[2] Mingchuan Zhang,et al. Extended Application of the Moving Flame Front Model for Combustion of a Carbon Particle with a Finite-Rate Homogenous Reaction , 2010 .
[3] P. Glarborg,et al. Experimental and Numerical Investigation of Gas-Phase Freeboard Combustion. Part 1: Main Combustion Process , 2009 .
[4] Masoud Rahimi,et al. Numerical Investigation of Fuel Dilution Effects on the Performance of the Conventional and the Highly Preheated and Diluted Air Combustion Furnaces , 2009 .
[5] C. Togbé,et al. Experimental and Modeling Study of the Kinetics of Oxidation of Butanol−n-Heptane Mixtures in a Jet-stirred Reactor , 2009 .
[6] R. Reitz,et al. A reduced chemical kinetic model for IC engine combustion simulations with primary reference fuels , 2008 .
[7] Jacqueline H. Chen,et al. Three-dimensional direct numerical simulation of soot formation and transport in a temporally evolving nonpremixed ethylene jet flame , 2008 .
[8] B. Lakatos,et al. Re-pyrolysis of recycled hydrocarbon gas-mixtures: A simulation study , 2008 .
[9] K. Cen,et al. Determination of Hydrogen Production from Rich Filtration Combustion with Detailed Kinetics Based CFD Method , 2008 .
[10] A. Ciajolo,et al. Effect of Fuel/Air Ratio and Aromaticity on Sooting Behavior of Premixed Heptane Flames , 2007 .
[11] J. Ervin,et al. Use of Measured Species Class Concentrations with Chemical Kinetic Modeling for the Prediction of Autoxidation and Deposition of Jet Fuels , 2007 .
[12] B. Jiang,et al. Study on NOx Formation in CH4/Air Jet Combustion , 2006 .
[13] Hongsheng Guo,et al. Numerical study on the influence of hydrogen addition on soot formation in a laminar ethylene-air diffusion flame , 2006 .
[14] Hongsheng Guo,et al. Effects of radiation model on the modeling of a laminar coflow methane/air diffusion flame , 2004 .
[15] María U. Alzueta,et al. An Augmented Reduced Mechanism for Methane Combustion , 2004 .
[16] B. Adams,et al. CFD Simulations of Supersonic Combustion Using Reduced Mechanisms and ISAT , 2003 .
[17] Hongsheng Guo,et al. Numerical modelling of soot formation and oxidation in laminar coflow non-smoking and smoking ethylene diffusion flames , 2003 .
[18] Ö. Gülder,et al. The flame preheating effect on numerical modelling of soot formation in a two-dimensional laminar ethylene–air diffusion flame , 2002 .
[19] S. Tiwari,et al. Combustion characteristics of ethylene in scramjet engines , 2002 .
[20] F. Williams,et al. Ethylene Ignition and Detonation Chemistry, Part 2: Ignition Histories and Reduced Mechanisms , 2002 .
[21] F. A. Williams,et al. Ethylene Ignition and Detonation Chemistry, Part 1: Detailed Modeling and Experimental Comparison , 2002 .
[22] C. Sung,et al. Development of comprehensive detailed and reduced reaction mechanisms for combustion modeling , 2002 .
[23] C. Law,et al. Complex CSP for chemistry reduction and analysis , 2001 .
[24] Epaminondas Mastorakos,et al. Global reduced mechanisms for methane and hydrogen combustion with nitric oxide formation constructed with CSP data , 1999 .
[25] Y. Hidaka,et al. Shock-tube and modeling study of ethylene pyrolysis and oxidation , 1999 .
[26] James A. Miller,et al. Kinetic modeling of hydrocarbon/nitric oxide interactions in a flow reactor , 1998 .
[27] Wright-Patterson Afb,et al. Kinetic Modeling of Ethylene Oxidation in High Speed Reacting Flows , 1997 .
[28] Pierre Rouchon,et al. Kinetic scheme reduction via geometric singular perturbation techniques , 1996 .
[29] Klaas R. Westerterp,et al. Influence of reaction products on the selective oxidation of ethene , 1996 .
[30] D. Hainsworth,et al. Soot and carbon deposition mechanisms in ethene/air flames , 1995 .
[31] N. Marinov,et al. ETHYLENE OXIDATION IN A WELL-STIRRED REACTOR , 1994 .
[32] Ulrich Maas,et al. Simplifying chemical kinetics: Intrinsic low-dimensional manifolds in composition space , 1992 .
[33] K. M. Leung,et al. A simplified reaction mechanism for soot formation in nonpremixed flames , 1991 .
[34] I. Fells,et al. A study of the gas flow occurring in oxyhydrogen detonations, using a magnetohydrodynamic method of measurement , 1970 .
[35] H. F. Calcote,et al. Effect of Molecular Structure on Burning Velocity. , 1959 .
[36] Guy Marin,et al. Development of reduced combustion mechanisms for premixed flame modeling in steam cracking furnaces with emphasis on NO emission , 2006 .
[37] R. Axelbaum,et al. A theoretical study on soot inception in spherical burner-stabilized diffusion flames , 2005 .
[38] Chul Han Kim,et al. Soot surface growth and oxidation in laminar diffusion flames at pressures of 0.1–1.0 atm , 2004 .
[39] Phillip R. Westmoreland,et al. Modeling ethylene combustion from low to high pressure , 2002 .
[40] K. Kailasanath,et al. Flow-field effects on soot formation in normal and inverse methane–air diffusion flames , 2001 .
[41] M. Smooke,et al. EXPERIMENTAL AND COMPUTATIONAL STUDY OF TEMPERATURE, SPECIES, AND SOOT IN BUOYANT AND NON-BUOYANT COFLOW LAMINAR DIFFUSION FLAMES , 2000 .
[42] Chung King Law,et al. An augmented reduced mechanism for methane oxidation with comprehensive global parametric validation , 1998 .
[43] Marshall B. Long,et al. Experimental and computational study of CH, CH*, and OH* in an axisymmetric laminar diffusion flame , 1998 .
[44] D. Singh,et al. Quasiglobal reaction model for ethylene combustion , 1994 .
[45] Chung King Law,et al. A Compilation of Experimental Data on Laminar Burning Velocities , 1993 .
[46] S. H. Lam,et al. A study of homogeneous methanol oxidation kinetics using CSP , 1992 .
[47] Chung King Law,et al. Experimental and numerical determination of laminar flame speeds: Mixtures of C2-hydrocarbons with oxygen and nitrogen. (Reannouncement with new availability information) , 1990 .
[48] J.-Y. Chen,et al. A General Procedure for Constructing Reduced Reaction Mechanisms with Given Independent Relations , 1988 .