Soot formation in laminar diffusion flames of natural gas with hydrocarbon and air additive

被引:0
|
作者
L. M. Borodina
M. S. Nemirovskii
P. A. Tesner
机构
[1] Institute for Natural Gases and Gas Technologies,
来源
Combustion, Explosion and Shock Waves | 1999年 / 35卷
关键词
Flare; Acetylene; Shock Tube; Soot Particle; Soot Formation;
D O I
暂无
中图分类号
学科分类号
摘要
It is shown that when acetylene, ethylene, hexane, octane, benzene, and naphthalene are introduced into natural gas, new soot particles are not formed in laminar diffusion flames and the hydrocarbon additives are expended only in particle growth. A similar effect, referred to as the inhibition of soot formation, has been observed previously during isothermal pyrolysis of hydrocarbon mixtures. Introducing air into the gas sharply reduces the yield of soot. Complete cessation of soot production, as observed from the disappearance of the luminous flame tip, corresponds to an air/natural gas ratio of 2.1.
引用
收藏
页码:8 / 11
页数:3
相关论文
共 50 条
  • [31] Pressure effect on soot formation in turbulent diffusion flames
    Roditcheva, OV
    Bai, XS
    CHEMOSPHERE, 2001, 42 (5-7) : 811 - 821
  • [32] Aspects of modeling soot formation in turbulent diffusion flames
    Mauss, Fabian
    Netzell, Karl
    Lehtiniemi, Harry
    COMBUSTION SCIENCE AND TECHNOLOGY, 2006, 178 (10-11) : 1871 - 1885
  • [33] Uncertainty analysis of soot formation in laminar flames simulated with a sectional method
    Su, Xingyu
    Cleary, Matthew J.
    Zhou, Hua
    Ren, Zhuyin
    Masri, Assaad R.
    COMBUSTION AND FLAME, 2024, 265
  • [34] Detailed kinetic modeling of soot aggregate formation in laminar premixed flames
    Balthasar, M
    Frenklach, M
    COMBUSTION AND FLAME, 2005, 140 (1-2) : 130 - 145
  • [35] Burning characteristics and soot formation in laminar methyl methacrylate pool flames
    Shanmugasundaram, Dakshnamurthy
    Kumran, Selvaraj Muthu
    Trubachev, Stanislav A.
    Bespalova, Anna
    Korobeinichev, Oleg P.
    Shmakov, Andrey G.
    Raghavan, Vasudevan
    COMBUSTION THEORY AND MODELLING, 2020, 24 (06) : 1153 - 1178
  • [36] The impact of detailed multicomponent transport and thermal diffusion effects on soot formation in ethylene/air flames
    Dworkin, S. B.
    Smooke, M. D.
    Giovangigli, V.
    PROCEEDINGS OF THE COMBUSTION INSTITUTE, 2009, 32 : 1165 - 1172
  • [37] Numerical and experimental study of soot formation in laminar diffusion flames burning simulated biogas fuels at elevated pressures
    Charest, Marc R. J.
    Guelder, Oemer L.
    Groth, Clinton P. T.
    COMBUSTION AND FLAME, 2014, 161 (10) : 2678 - 2691
  • [38] Soot surface reactivity during surface growth and oxidation in laminar diffusion flames
    Khosousi, Ali
    Dworkin, Seth B.
    COMBUSTION AND FLAME, 2015, 162 (12) : 4523 - 4532
  • [39] Soot formation and temperature field structure in co-flow laminar methane-air diffusion flames at pressures from 10 to 60 atm
    Joo, Hyun I.
    Guelder, Oemer L.
    PROCEEDINGS OF THE COMBUSTION INSTITUTE, 2009, 32 : 769 - 775
  • [40] Soot formation in diffusion oxygen-enhanced biodiesel flames
    Merchan-Merchan, Wilson
    McCollam, Stephen
    Pugliese, Juan Felipe Correa
    FUEL, 2015, 156 : 129 - 141
12345