| 1 |
Accurate Numerical Integration of beta-PDF for the Flamelet Approach
Matsushita Y, Malalasekera W, Akaotsu S, Matsukawa Y, Aoki H
Journal of Chemical Engineering of Japan, 53(9), 494, 2020 |
| 2 |
Analysis of LES-based combustion models applied to an acetone turbulent spray flame
Sacomano FL, Kadavelil J, Staufer M, Sadiki A, Janicka J
Combustion Science and Technology, 191(1), 54, 2019 |
| 3 |
The effects of flue-wall design modifications on combustion and flow characteristics of an aluminum anode baking furnace-CFD modeling
Tajik AR, Shamim T, Zaidani M, Abu Al-Rub RK
Applied Energy, 230, 207, 2018 |
| 4 |
Simulating turbulence-radiation interactions using a presumed probability density function method
Ren T, Modest MF, Haworth DC
International Journal of Heat and Mass Transfer, 121, 911, 2018 |
| 5 |
A priori filtered chemical source term modeling for LES of high Karlovitz number premixed flames
Lapointe S, Blanquart G
Combustion and Flame, 176, 500, 2017 |
| 6 |
Large eddy simulation of two isothermal and reacting turbulent separated oxy-fuel jets
Hidouri A, Chrigui M, Boushaki T, Sadiki A, Janicka J
Fuel, 192, 108, 2017 |
| 7 |
Presumed PDF modeling of microjet assisted CH4-H-2/air turbulent flames
Chouaieb S, Kriaa W, Mhiri H, Bournot P
Energy Conversion and Management, 120, 412, 2016 |
| 8 |
Computing supersonic non-premixed turbulent combustion by an SMLD flamelet progress variable model
Coclite A, Cutrone L, Gurtner M, De Palma P, Haidn OJ, Pascazio G
International Journal of Hydrogen Energy, 41(1), 632, 2016 |
| 9 |
RANS modelling of a lifted H-2/N-2 flame using an unsteady flamelet progress variable approach with presumed PDF
Naud B, Novella R, Pastor JM, Winklinger JF
Combustion and Flame, 162(4), 893, 2015 |
| 10 |
MODELING OF THE INFLUENCE OF MIXTURE FRACTION FLUCTUATIONS ON BURNING RATE IN PARTIALLY PREMIXED TURBULENT FLAMES
Lipatnikov AN, Huang C
Combustion Science and Technology, 187(4), 594, 2015 |
