| 1 |
An experimental/numerical investigation of the role of the quarl in enhancing the blowout limits of swirl-stabilized turbulent non-premixed flames
Elbaz AM, Yu S, Liu X, Bai XS, Khesho I, Roberts WL
Fuel, 236, 1226, 2019 |
| 2 |
Velocity and stretch characteristics at the leading edge of an aerodynamically stabilized flame
Chterev I, Emerson B, Lieuwen T
Combustion and Flame, 193, 92, 2018 |
| 3 |
Effect of burner geometry on swirl stabilized methane/air flames: A joint LES/OH-PLIF/PIV study
Liu X, Elbaz AM, Gong C, Bai XS, Zheng HT, Roberts WL
Fuel, 207, 533, 2017 |
| 4 |
Coupled dynamics of lift-off and precessing vortex core formation in swirl flames
An Q, Kwong WY, Geraedts BD, Steinberg AM
Combustion and Flame, 168, 228, 2016 |
| 5 |
Conditional flow field statistics of jet-in-hot-coflow flames
Oldenhof E, Tummers MJ, van Veen EH, Roekaerts DJEM
Combustion and Flame, 160(8), 1428, 2013 |
| 6 |
Liftoff height behavior in a non-premixed turbulent hydrogen jet with coaxial air
Oh J, Yoon Y
Fuel, 91(1), 134, 2012 |
| 7 |
Laser-based investigations of flow fields and OH distributions in impinging flames of domestic cooker-top burners
Makmool U, Jugjai S, Tia S, Laoonual Y, Vallikul P, Fungtammasan B
Fuel, 90(3), 1024, 2011 |
| 8 |
Nitrogen dilution effect on flame stability in a lifted non-premixed turbulent hydrogen jet with coaxial air
Oh J, Khan QS, Yoon Y
Fuel, 89(7), 1492, 2010 |
| 9 |
Flame stabilization in a lifted non-premixed turbulent hydrogen jet with coaxial air
Oh J, Yoon Y
International Journal of Hydrogen Energy, 35(19), 10569, 2010 |
