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稀释气体对甲烷层流预混火焰燃烧速度的影响 被引量:7

Effects of Diluents Addition on Laminar Burning Velocity of Premixed Methane Flames
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摘要 基于GRI-Mech 3.0详细化学反应机理,利用预混燃烧模型(PREMIX Code)研究了甲烷-空气-稀释气层流预混火焰燃烧特性及火焰结构.重点探讨了不同化学当量比(0.5~1.5)、初始压力(0.05~0.40MPa)、稀释气体种类(N2,CO2及H2O)和稀释摩尔比(0~0.35)对甲烷-空气-稀释气混合气层流预混火焰结构、层流燃烧速度、火焰厚度的影响.研究结果表明:随着稀释比的增加,层流燃烧速度逐渐变小,火焰厚度增大,火焰流动不稳定性得到抑制;CO2作为稀释气时对层流燃烧速度及火焰厚度影响最为显著.随着初始压力提高,层流燃烧速度及火焰厚度均变小;进一步提高初始压力,对火焰厚度影响并不明显. Based on the GRI-Mech 3.0 mechanism,the premixed laminar combustion characteristics of methane-air-diluent mixtures were investigated by using PREMIXED Code.Several fundamental parameters,such as flame structure,laminar burning velocity,and flame thickness,were calculated at different equivalence ratios,initial pressures,and dilution ratios.It was found that increasing the dilution ratio in the mixture would lead to a decrease in laminar burning velocity and an increase of flame thickness.As a result,the hydrodynamic instability of methane-air laminar flame was suppressed with the addition of diluents,especially in the condition of CO2 dilution.When the initial pressure increased,the laminar burning velocity and flame thickness decreased accordingly.However,a further increase of the initial pressure did not have much effect on the flame thickness.
作者 曹甄俊 朱彤
机构地区 同济大学机械工程学院
出处 《同济大学学报(自然科学版)》 EI CAS CSCD 北大核心 2011年第10期1557-1562,共6页 Journal of Tongji University:Natural Science
基金 国家自然科学基金(50206014) 上海市教育委员会曙光计划(05SG23)
关键词 甲烷 层流预混火焰 层流火焰燃烧速度 稀释 methane laminar premixed flame laminar burning velocity dilution
分类号 TK16 [动力工程及工程热物理—热能工程]
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参考文献3

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  • 1Blarigan P V,Keller J O.A Hydrogen Fuelled In ternal Combustion Engine Designed for Single Speed/Power Operation[J].International Journal of Hydrogen Energy,2002,23(7):603-609.
  • 2Akansu S O,Dulger A,Kahraman N,et al.Inter nal Combustion Engines Fueled by Natural Gas Hy drogen Mixtures[J].International Journal of Hydrogen Energy,2004,29(14):1 527-1 539.
  • 3Bradley D,Hicks R A,Lawes M,et al.The Meas urement of Laminar Burning Velocities and Mark stein Numbers for Iso-Octane-Air and Iso-Octane-nHeptane-Air Mixtures at Elevated Temperatures and Pressures in an Explosion Bomb[J].Combustion and Flame,1998,115(1/2):126-144.
  • 4Yu G,Law C K,Wu C K.Laminar Flame Speeds of Hydrogen Air Mixtures with Hydrogen Addition[J].Combustion andFlame,1986,63(1/2):339-347.
  • 5Van Maaren A,Thung D S,Goey L P H.Measurement of Flame Temperature and Adiabatic Burning Velocity of Methane/Air Mixtures[J].Combustion Sci Technol,1994(96):327-344.
  • 6Gu X J,Haq M Z,Lawes M,et al.Laminar Burning Velocity and Markstein Lengths of Methane Air Mixtures[J].Combustion and Flame,2000,121(1/ 2):41-58.
  • 7Bradley D,Gaskell P H,Gu X J.Burning Velocities,Markstein Lengths,and Flame Quenching for Spherical Methane-Air Flames:A Computational Study[J].Combustion and Flame,1996,104(1/2):176-198.
  • 8Liao S Y,Jiang D M,Gao J,et al.Measurements of Markstein Numbers and Laminar Burning Velocities for Liquefied Petroleum Gas Air Mixtures[J].Fuel,2004,83(10):1 281-1 288.
  • 9Lamoureux N,Djebay li-Chaumeix N,Paillard C E.Laminar Flame Velocity Determination for H2-Air He-CO2 Mixtures Using the Spherical Bomb Method[J].Experimental Thermal and Fluid Science,2003,27(4):385-393.
  • 10Liao S Y,Jiang D M,Gao J,et al.Measurements of Markstein Numbers and Laminar Burning Velocities for Natural Gas-Air Mixtures[J].Energy & Fuels,2004,18(2):316-326.

共引文献81

同被引文献53

  • 1贾宝山,温海燕,梁运涛,王小云.煤矿巷道内N_2及CO_2抑制瓦斯爆炸的机理特性[J].煤炭学报,2013,38(3):361-366. 被引量:37
  • 2徐景德,徐胜利,杨庚宇.矿井瓦斯爆炸传播的试验研究[J].煤炭科学技术,2004,32(7):55-57. 被引量:64
  • 3陈晓坤,林滢,罗振敏,邓军.水系抑制剂控制瓦斯爆炸的实验研究[J].煤炭学报,2006,31(5):603-606. 被引量:34
  • 4Candel S, Durox D, Schuller T. Advances in Combustionand Propulsion Applications [J]. European Journal of Me-chanics -B/Fluids, 2013, 40(7): 87-106.
  • 5Berta P, Durox D. Structure of Partially Premixed n-Heptane-Air Counterflow Flames [J]. Proceedings of theCombustion Institute, 2005, 30(1): 447-453.
  • 6Figura L, Alessandro,et al. Laminar Counterflow SteadyDiffusion Flames Under High Pressure (P<3 MPa) Con-ditions [J]. Combustion and Flame, 2012,159(1): 142—150.
  • 7Mikami M, Mizutay Y, et al. Flame Structure and Stabi-lization of Lean-Premixed Sprays in a Counterflow WithLow-Volatility Fuel [J]. Proceedings of the CombustionInstitute, 2009, 32(2): 234—248.
  • 8Hiroaki W, Ryoichi K, et al. Characteristics of Flameletsin Spray Flames Formed in a Laminar Counterfiow [J].Combustion and Flame, 2007, 148(4); 234-248.
  • 9Cardona C A, Amell A A, Laminar Burning Velocityand Interchangeability Analysis of Biogas/CsH8/H2 WithNormal and Oxygen-Enriched Air [J]. International Jour-nal of Hydrogen Energy, 2013, 38(19): 7994-8001.
  • 10Yepes H A, Amell A A, Laminar Burning Velocity WithOxygen-Enriched Air of Syngas Produced From BiomassGasification [J]. International Journal of Hydrogen Energy[J]. 2013,38(18): 7519-7527.

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同济大学学报(自然科学版)
2011年 第10期

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