Velocity of deflagration combustion at high pressures and temperatures

被引:0
|
作者
A. A. Vasiliev
A. V. Trilis
机构
[1] Lavrentyev Institute of Hydrodynamics SB RAS,
来源
Thermophysics and Aeromechanics | 2013年 / 20卷
关键词
normal velocity of flame; visible velocity of flame; detonation velocity; adiabat of energy release; detonation branch of adiabat; deflagration branch; combustion;
D O I
暂无
中图分类号
学科分类号
摘要
The article presents additional calculated data on combustion velocity for typical gas mixtures at pressures up to 6000 atm and temperatures up to 4000 K. It was determined that combustion velocity is mainly influenced by initial temperature, and the dependence on pressure is rather low. For fuel-oxygen and air-fuel mixtures in three-dimensional space (pressure-temperature-velocity of deflagration combustion), we have found a single surface of combustion velocities and continuous dependence of flame velocity on initial conditions.
引用
收藏
页码:605 / 612
页数:7
相关论文
共 50 条
  • [21] Deflagration Dynamics of Methane-Air Mixtures in Closed Vessels at Elevated Temperatures
    Porowski, Rafal
    Kowalik, Robert
    Nagy, Stanislaw
    Gorzelnik, Tomasz
    Szurlej, Adam
    Grzmiaczka, Malgorzata
    Zielinska, Katarzyna
    Dahoe, Arief
    ENERGIES, 2024, 17 (12)
  • [22] Combustion-resistance of silicon-based ceramics and composites at very high oxygen pressures
    A. Sayir
    F. S. Lowery
    Journal of Materials Science, 2004, 39 : 5979 - 5985
  • [23] Auto-ignition kinetics of ammonia and ammonia/hydrogen mixtures at intermediate temperatures and high pressures
    He, X.
    Shu, B.
    Nascimento, D.
    Moshammer, K.
    Costa, M.
    Fernandes, R. X.
    COMBUSTION AND FLAME, 2019, 206 : 189 - 200
  • [24] A Comprehensive Kinetic Modeling of Ignition of Syngas-Air Mixtures at Low Temperatures and High Pressures
    Cavaliere, D. E.
    de Joannon, M.
    Sabia, P.
    Sirignano, M.
    D'Anna, A.
    COMBUSTION SCIENCE AND TECHNOLOGY, 2010, 182 (4-6) : 692 - 701
  • [25] Fluorescence spectroscopy of anisole at elevated temperatures and pressures
    Tran, K. H.
    Morin, C.
    Kuehni, M.
    Guibert, P.
    APPLIED PHYSICS B-LASERS AND OPTICS, 2014, 115 (04): : 461 - 470
  • [26] Evolving Smart Model to Predict the Combustion Front Velocity for In Situ Combustion
    Ahmadi, Mohammad Ali
    Masoumi, Mohammad
    Askarinezhad, Reza
    ENERGY TECHNOLOGY, 2015, 3 (02) : 128 - 135
  • [27] A study on the effect of different diluents on laminar burning velocity and flame stability of oxy-n-dodecane mixtures at elevated pressures and temperatures
    Rajesh, Natarajan
    Zheng, Shu
    Prathap, Chockalingam
    COMBUSTION AND FLAME, 2023, 255
  • [28] Experimental and kinetic modeling studies on the auto-ignition of methyl crotonate at high pressures and intermediate temperatures
    Vallabhuni, S. K.
    Johnson, P. N.
    Shu, B.
    Narayanaswamy, K.
    Fernandes, R. X.
    PROCEEDINGS OF THE COMBUSTION INSTITUTE, 2021, 38 (01) : 223 - 231
  • [29] OH time-histories during oxidation of n-heptane and methylcyclohexane at high pressures and temperatures
    Vasu, Subith S.
    Davidson, David F.
    Hanson, Ronald K.
    COMBUSTION AND FLAME, 2009, 156 (04) : 736 - 749
  • [30] Cell formation effects on the burning speeds and flame front area of synthetic gas at high pressures and temperatures
    Askari, Omid
    Elia, Mimmo
    Ferrari, Matthew
    Metghalchi, Hameed
    APPLIED ENERGY, 2017, 189 : 568 - 577
12345