| 1 |
대향류 확산 화염 모델에서의 압력 및 산소분율에 따른 연소 특성 변화에 관한 수치해석 연구
박진제, 이영재
Clean Technology, 27(1), 93, 2021 |
| 2 |
Large eddy simulation of the unstable flame structure and gas-to-liquid thermal feedback in a medium-scale methanol pool fire
Ahmed MM, Trouve A
Combustion and Flame, 225, 237, 2021 |
| 3 |
Investigation of PAH and soot formation in a dimethyl ether (DME) laminar coflow diffusion flame
Li TJ, Mitra T, Chu C, Yuan Y, Thomson MJ
Combustion and Flame, 223, 437, 2021 |
| 4 |
Explosion effect of vapor-liquid two-phase n-heptane at various initial temperatures
Song YF, Zhang Q
Process Safety and Environmental Protection, 145, 303, 2021 |
| 5 |
Chemical effects of hydrogen addition on soot formation in counterflow diffusion flames: Dependence on fuel type and oxidizer composition
Xu L, Yan FW, Wang Y, Chung SH
Combustion and Flame, 213, 14, 2020 |
| 6 |
Spatial distribution of spectrally emitting species in a nitromethane-air diffusion flame and comparison with kinetic models
Sheehe SL, Jackson SI
Combustion and Flame, 213, 184, 2020 |
| 7 |
Edge flames in mixing layers: Effects of heat recirculation through thermally active splitter plates
Lu ZB, Matalon M
Combustion and Flame, 217, 262, 2020 |
| 8 |
Large eddy simulation of turbulent diffusion jet flames based on novel modifications of flamelet generated manifolds
Zadsirjan S, Tabejamaat S, Abtahizadeh E, van Oijen J
Combustion and Flame, 216, 398, 2020 |
| 9 |
The role of differential diffusion during early flame kernel development under engine conditions - part I: Analysis of the heat-release-rate response
Falkenstein T, Rezchikova A, Langer R, Bode M, Kang S, Pitsch H
Combustion and Flame, 221, 502, 2020 |
| 10 |
The role of differential diffusion during early flame kernel development under engine conditions - part II: Effect of flame structure and geometry
Falkenstein T, Chu HC, Bode M, Kang S, Pitsch H
Combustion and Flame, 221, 516, 2020 |
