Numerical simulation of CO formation and reduction on flame propagation due to heat loss through the cooled wall

Energy - Tập 236 - Trang 121352 - 2021
Keita Yunoki1,2, Reo Kai1, Shinpei Inoue1, Ryoichi Kurose1
1Department of Mechanical Engineering and Science, Kyoto University, Kyoto-daigaku-Katsura, Nishikyo-ku, Kyoto 615-8540, Japan
2Research & Innovation Center, Mitsubishi Heavy Industries, Ltd., 2-1-1 Shinhama, Arai-cho, Takasago-shi, Hyogo, 676-8686, Japan

Tài liệu tham khảo

Fukuba Y, 2017, Experimental and numerical investigation OF dln combustor for a heavy-duty gas turbine

Tada, 2018, Expanding fuel flexibility IN mhps’ dry low nox combustor, Proceed ASME Turbo Expo

Fujimoto, 2018, Technology application to mhps large flame F series gas turbine, Proceed ASME Turbo Expo, 2018

Cabot, 2004, Experimental study of lean premixed turbulent combustion in a scale gas turbine chamber, Exp Therm Fluid Sci, 28, 683, 10.1016/j.expthermflusci.2003.12.001

Mann, 2014, Transient flame–wall interactions: experimental analysis using spectroscopic temperature and CO concentration measurements, Combust Flame, 161, 2371, 10.1016/j.combustflame.2014.02.008

Yunoki, 2013, Numerical simulation of turbulent combustion flows for coaxial jet cluster burner, power2013-98143

Koganezawa, 2007, Full scale testing of a cluster nozzle burner for the advanced humid air turbine, GT2007-27737, Proceed ASME Turbo EXPO, 2007

Yunoki, 2018, Large eddy simulation to predict flame front position for turbulent lean premixed jet flame at high pressure, Proceed ASME Turbo EXPO, 2018

Yunoki, 2016, Large eddy simulation of a multiple-injection dry low NOx combustor for hydrogen-rich syngas fuel at high pressure, Proceed ASME Turbo EXPO, 2016

Tachibana, 2015, Experimental and numerical investigation of thermo-acoustic instability in a liquid-fuel aero-engine combustor at elevated pressure: validity of large-eddy simulation of spray combustion, Combust Flame, 162, 2621, 10.1016/j.combustflame.2015.03.014

Nishiie, 2015, Large-eddy simulation of turbulent spray combustion field of full annular combustor for aircraft engine, Proceed Int Gas Turb Congr, 2015

Hirano, 2015, Large-eddy simulation of turbulent combustion in multi combustors for l30a gas turbine engine, Proceed ASME Turbo EXPO, 2015

Moriai, 2013, Large-eddy simulation of turbulent spray combustion in a subscale aircraft jet engine combustor - predictions of no and soot concentrations, J Eng Gas Turbines Power, 135, 10.1115/1.4024868

Ihme, 2008, Modeling of radiation and nitric oxide formation in turbulent nonpremixed flames using a flamelet/progress variable formulation, Phys Fluids, 20, 10.1063/1.2911047

Sethian, 1996

Willams, 1985, 99

Oijen, 2000, Modeling of pre-mixed laminar flames using flamelet-generated manifolds, Combust Sci Technol, 161, 113, 10.1080/00102200008935814

Fiorina, 2003, Modelling non-adiabatic partially premixed flames using flame-prolongation of ILDM, Combust Theor Model, 7, 449, 10.1088/1364-7830/7/3/301

Proch, 2015, Modeling heat loss effects in the large eddy simulation of a model gas turbine combustor with premixed flamelet generated manifolds, Proc Combust Inst, 35, 3337, 10.1016/j.proci.2014.07.036

Fiorina, 2015, Challenging modeling strategies for LES of non-adiabatic turbulent stratified combustion, Combust Flame, 162, 4264, 10.1016/j.combustflame.2015.07.036

Patangi, 2014, LES of premixed methane flame impinging on the wall using non-adiabatic flamelet generated manifold (FGM) approach, Flow, Turbul Combust, 92, 805, 10.1007/s10494-013-9526-0

Honzawa, 2019, Large-eddy simulation of ammonia/methane/air combustion using non-adiabatic flamelet generated manifold approach, Energy, 186, 115771, 10.1016/j.energy.2019.07.101

Pitsch, 2006, Large-eddy simulation of turbulent combustion, Annu Rev Fluid Mech, 38, 453, 10.1146/annurev.fluid.38.050304.092133

Knudsen, 2015, Modeling partially premixed combustion behavior in multiphase LES, Combust Flame, 162, 159, 10.1016/j.combustflame.2014.07.013

R, 1989

Smith

Pitsch, 1998

Kishimoto, 2017, Application of a non-adiabatic flamelet/progress-variable approach to Large Eddy Simulation of H2/O2 combustion under a pressurized condition, J Heat Tran, 139, 124501

Kai, 2019, Validity of non-adiabatic FGM approach for numerical simulation of flame propagation in the vicinity of the wall, Proceed Int Gas Turb Congr, 2019

Yunoki, 2020, Numerical simulation of CO concentration on flame propagation in the vicinity of the wall -validity of non-adiabatic FGM approach, Int J Gas Turb Propul Power Syst, 11

Peters, 1999, The turbulent burning velocity for large scale and small scale turbulence, J Fluid Mech, 384, 107, 10.1017/S0022112098004212

Rogallo, 1981, 81315

Hara, 2015, Direct numerical simulation of a pulverized coal jet flame employing a global volatile matter reaction scheme based on detailed reaction mechanism, Combust Flame, 162, 4391, 10.1016/j.combustflame.2015.07.027

Pillai, 2019, Combustion noise analysis of a turbulent spray flame using a hybrid DNS/APE-RF approach, Combust Flame, 200, 168, 10.1016/j.combustflame.2018.10.041

Muto, 2018, Numerical simulation of soot formation in pulverized coal combustion with detailed chemical reaction mechanism, Adv Powder Technol, 29, 1119, 10.1016/j.apt.2018.02.002

Kitano, 2015, Effect of pressure oscillations on flashback characteristics in a turbulent channel flow, Energy Fuels, 29, 6815, 10.1021/acs.energyfuels.5b01687

Kurose

Titarev, 2005, Weno schemes based on upwind and centred tvd fluxes, Comput Fluids, 34, 705, 10.1016/j.compfluid.2004.05.009

Gottlieb, 1998, Total variation diminishing Runge-Kutta schemes, Math Comput Am Math Soc, 67, 73, 10.1090/S0025-5718-98-00913-2

Thông tin
Thông tin xuất bản

Energy

Tập 236

121352

Thông tin tác giả