| 1 |
Numerical study on laminar flame velocity of hydrogen-air combustion under water spray effects
Gai GD, Kudriakov S, Rogg B, Hadjadj A, Studer E, Thomine O
International Journal of Hydrogen Energy, 44(31), 17015, 2019 |
| 2 |
Modelling heat loss effects in high temperature oxy-fuel flames with an efficient and robust non-premixed flamelet approach
Wollny P, Rogg B, Kempf A
Fuel, 216, 44, 2018 |
| 3 |
FEM-simulation of laminar flame propagation II: Twin and triple flames in counterflow
Michaelis B, Rogg B
Combustion Science and Technology, 177(5-6), 955, 2005 |
| 4 |
PDF transport equations for two-phase reactive flows and sprays
Zhu M, Bray KNC, Rumberg O, Rogg B
Combustion and Flame, 122(3), 327, 2000 |
| 5 |
Full PDF modelling of reactive sprays via an evaporation-progress variable
Rumberg O, Rogg B
Combustion Science and Technology, 158, 211, 2000 |
| 6 |
Experimental and numerical studies of a triple flame
Kioni PN, Bray KNC, Greenhalgh DA, Rogg B
Combustion and Flame, 116(1-2), 192, 1999 |
| 7 |
Convective burning of gaseous fuel pockets and supercritical droplets
Daou J, Rogg B
Combustion and Flame, 115(1-2), 145, 1998 |
| 8 |
The modelling and measurement of local flame surface orientation in turbulent premixed flames
Zhang Y, Bray KNC, Rogg B
Combustion Science and Technology, 137(1-6), 347, 1998 |
| 9 |
Influence of the Earth Gravity on Laminarly Premixed Combustion
Daou J, Rogg B
Chemie Ingenieur Technik, 69(8), 1134, 1997 |
| 10 |
Effect of sprays of water and NaCl-water solution on the extinction of laminar premixed methane-air counterflow flames
Zheng R, Bray KNC, Rogg B
Combustion Science and Technology, 126(1-6), 389, 1997 |
