| 1 |
New extended eddy dissipation concept model for flameless combustion in furnaces
Romero-Anton N, Huang X, Bao HS, Martin-Eskudero K, Salazar-Herran E, Roekaerts D
Combustion and Flame, 220, 49, 2020 |
| 2 |
Modeling of the gas-phase combustion of a grate-firing biomass furnace using an extended approach of Eddy Dissipation Concept
Farokhi M, Birouk M
Fuel, 227, 412, 2018 |
| 3 |
Analysis of the Eddy Dissipation Concept formulation for MILD combustion modelling
Lewandowski MT, Ertesvag IS
Fuel, 224, 687, 2018 |
| 4 |
Enhancement of the acetylene and ethylene yields from ethane by partially decoupling the oxidation and pyrolysis reactions
Zhang Q, Luo JJ, Chen TW, Wang JF, Wang TF
Chemical Engineering and Processing, 122, 447, 2017 |
| 5 |
Numerical study of natural gas reforming by non-catalytic partial oxidation based on the Virtuhcon Benchmark
Voloshchuk Y, Vascellari M, Hasse C, Meyer B, Richter A
Chemical Engineering Journal, 327, 307, 2017 |
| 6 |
Comprehensive numerical study of the Adelaide Jet in Hot-Coflow burner by means of RANS and detailed chemistry
Li ZY, Cuoci A, Sadiki A, Parente A
Energy, 139, 555, 2017 |
| 7 |
A computational study of a small-scale biomass burner: The influence of chemistry, turbulence and combustion sub-models
Farokhi M, Birouk M, Tabet F
Energy Conversion and Management, 143, 203, 2017 |
| 8 |
Extension of the Eddy Dissipation Concept for turbulence/chemistry interactions to MILD combustion
Parente A, Malik MR, Contino F, Cuoci A, Daily BB
Fuel, 163, 98, 2016 |
| 9 |
MODELING LIFTED JET FLAMES IN A HEATED COFLOW USING AN OPTIMIZED EDDY DISSIPATION CONCEPT MODEL
Evans MJ, Medwell PR, Tian ZF
Combustion Science and Technology, 187(7), 1093, 2015 |
| 10 |
EXPERIMENTAL AND NUMERICAL INVESTIGATION OF THE INFLUENCE OF THE AIR PREHEATING TEMPERATURE ON THE PERFORMANCE OF A SMALL-SCALE MILD COMBUSTOR
Verissimo AS, Rocha AMA, Coelho PJ, Costa M
Combustion Science and Technology, 187(11), 1724, 2015 |
