| 1 |
Numerical and experimental investigation of partial oxidation of methane in a porous media to achieve optimum hydrogen production
Shahnazari MR, Moosavi MH, Saberi A
Energy Sources Part A-recovery Utilization and Environmental Effects, 42(5), 625, 2020 |
| 2 |
Over-rich combustion of CH4, C2H6, and C3H8 +air premixed flames investigated by the heat flux method and kinetic modeling
Han XL, Wang ZH, He Y, Wang SX, Zhu YQ, Konnov AA
Combustion and Flame, 210, 339, 2019 |
| 3 |
Super-adiabatic flame temperatures in premixed methane flames: A comparison between oxy-fuel and conventional air combustion
Stelzner B, Weis C, Habisreuther P, Zarzalis N, Trimis D
Fuel, 201, 148, 2017 |
| 4 |
Super-adiabatic combustion in Al2O3 and SiC coated porous media for thermoelectric power conversion
Mueller KT, Waters O, Bubnovich V, Orlovskaya N, Chen RH
Energy, 56, 108, 2013 |
| 5 |
FROM THE GENERALIZED BOUSSINESQ APPROXIMATION TO THE MARGINALLY SUPER-ADIABATIC LIMIT
Manela A, Frankel I
Chemical Engineering Communications, 197(1), 51, 2010 |
| 6 |
Filtration combustion characteristics of low calorific gas in SiC foams
Zheng CH, Cheng LM, Li T, Luo ZY, Cen KF
Fuel, 89(9), 2331, 2010 |
| 7 |
A numerical study on the effect of hydrogen/reformate gas addition on flame temperature and NO formation in strained methane/air diffusion flames
Guo HS, Neill WS
Combustion and Flame, 156(2), 477, 2009 |
| 8 |
Determination of hydrogen production from rich filtration combustion with detailed kinetics based CFD method
Li GN, Zhou H, Qian XP, Cen KF
Chinese Journal of Chemical Engineering, 16(2), 292, 2008 |
| 9 |
Effects of pressure and preheat on super-adiabatic flame temperatures in rich premixed methane/air flames
Liu FS, Gulder OL
Combustion Science and Technology, 180(3), 437, 2008 |
| 10 |
Stationary and traveling hot spots in the catalytic combustion of hydrogen in monoliths
Yakhnin V, Menzinger M
Chemical Engineering Science, 57(21), 4559, 2002 |
