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湍流扩散火焰中氮氧化物排放的数值研究 被引量:3

Numerical investigation of nitrogen oxides emission from turbulent non-premixed flames
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摘要 对一系列具有不同Reynolds数的湍流甲烷射流扩散火焰中氮氧化物的排放进行了数值模拟, 以考察湍流对氮氧化物排放的影响. 采用一个双尺度的k ε湍流模型计算速度场, 将概率密度函数 (PDF) 方法和 Lagrang ian火焰面模型相结合求解标量场, 燃料甲烷的氧化过程和氮氧化物的生成过程采用详细的 GRI Mech 3 0 机理描述. 将氮氧化物的计算结果和实验数据进行了比较, 并探讨了 Reynolds数、标量耗散和火焰面时间对氮氧化物排放的影响. 发现计算结果和实验数据符合较好, 计算模型正确预测了氮氧化物的生成量随着 Reynolds数的增加而减少的趋势. Nitrogen oxides emission from a series of turbulent methane jet non-premixed flames with different Reynolds number was numerically simulated, in order to investigate the influence of turbulence on the formation of nitrogen oxides. A two-scale k-Ε turbulence model was adopted to calculate turbulent velocity field, and the probability density function (PDF) method was combined with the Lagrangian flamelet model to predict the turbulent scalar fields. Detailed chemical reaction mechanism GRI-Mech 3.0 was incorporated to describe methane oxidation and nitrogen oxides formation. The comparisons between nitrogen oxides predictions and measurements were made, and the influence of Reynolds number, scalar dissipation and flamelet time on the formation of nitrogen oxides was discussed. The numerical results were in good agreement with the measurements, and the trend that nitrogen oxides emission decreased with the increase of Reynolds number in the experiment was reasonably represented by the present numerical models.
作者 王海峰 陈义良
机构地区 中国科学技术大学热科学和能源工程系
出处 《化工学报》 EI CAS CSCD 北大核心 2005年第2期209-214,共6页 CIESC Journal
基金 国家重点基础研究发展规划项目 (G1999022207) 国家自然科学基金项目 (50206021 50076043).~~
关键词 湍流扩散火焰 氮氧化物 双尺度k-ε湍流模型 PDF方法 Lagrangian火焰面模型 Computer simulation Gas emissions Mathematical models Methane Nitrogen oxides Probability density function Reynolds number Turbulent flow
分类号 V231.2 [航空宇航科学与技术—航空宇航推进理论与工程]
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参考文献12

  • 1王海峰,陈义良,蔡晓丹,李艺.湍流射流扩散火焰的层流火焰面模拟[J].推进技术,2003,24(1):58-62. 被引量:15
  • 2Peters N.Laminar diffusion flamelet models in non-premixed turbulent combustion.Prog. Energy Combust. Sci.,1984,10:319-339.
  • 3Pope S B.PDF methods for turbulent reactive flow. Prog. Energy Combust. Sci.,1985,11:119-192.
  • 4Klimenko A Y, Bilger R W.Conditional moment closure for turbulent combustion.Prog. Energy Combust. Sci.,1999,25:595-687.
  • 5Barlow R S, Frank J H.Effects of turbulence on species mass fractions in methane/air jet flames.Proceedings of Combustion Institute,1998,27:1087-1095.
  • 6Pitsch H, Chen M, Peters N.Unsteady flamelet modeling of turbulent hydrogen-air diffusion flames.Proceedings of Combustion Institute,1998,27:1057-1064.
  • 7Barths H, Peters N, Brehm N, Mack A, Pfitzner M.Simulation of pollutant formation in a gas-turbine combustion using unsteady flamelets.Proceedings of Combustion Institute,1998,27:1841-1847.
  • 8Kim S W, Chen C P.A multiple-time-scale turbulence model based on variable partitioning of the turbulent kinetic energy spectrum.Numerical Heat Transfer, Part B,1989,16:193-211.
  • 9Gregory P S, David M G, Michael F, Nigel W M, Boris E, Mikhail G, Thomas B, Ronald K H, Soonho S, William C G, Vitali V L, Qin Z.GRI-mech:an optimized detailed chemical reaction mechanism for methane combustion and NO formation and reburning.http://www.me.berkeley.edu/grimech.
  • 10王海峰 陈义良.Unsteady flamelet modeling of turbulent non-premixed flame[A].中国工程热物理学会编.中国工程热物理学会燃烧学术会议论文集[C].Shanghai,2003.135-142.

二级参考文献12

  • 1蔡晓丹,陈义良.双时间尺度湍流模型的应用[J].工程热物理学报,1994,15(4):387-390. 被引量:6
  • 2Williams F A. Progress in Knowledge of Flamelet Structure and Extinction. Prog. Energy Combust. Sci., 2000,26:657-682.
  • 3Peters N. Laminar Diffusion Flamelet Models in Non- premixed Turbulent Combustion. Prog. Energy Combust.Sci., 1984, 10:319-339.
  • 4Pitsch H, Peters N. A Consistent Flamelet Formulation for Non-premixed Combustion Considering Differential Diffusion Effects. Combust. & Flame, 1998, 114: 26-40.
  • 5Barths H, Peters N, Brehm N, et al. Simulation of Pollutant Formation in a Gas-turbine Combustor Using Unsteady Flamelets. In: Proc. of the Twenty-Seventh Symposium (International) on Combustion. The Combustion Institute, 1998. 1841-1847.
  • 6Barlow B. S, Karpetis A N, Frank J H. Scalar Profiles and NO Formation in Laminar Opposed-flow Partially Premixed Methane/Air Flames. Combust. & Flame, 2001,127:2102-2118.
  • 7Radhakrishnan K, Hindmarsh A C. Description and Use of LSODE, the Livermore Solver for Ordinary Differential Equations. Livermore National Laboratory Report,UCRL- 1D-113855, 1993.
  • 8Kee R J, Rupley F M, Miller J A. CHEMKIN-II: A Fortran Chemical Kinetics Package for the Analysis of Gasphase Chemical Kinetic. Sandia Report, SAND89-8009,1989.
  • 9Sung C J, Liu J B, Law C K. Structural Response of Counterflow Diffusion Flames to Strain Rate Variations.Combnst. & Flame, 1995, 102:481-492.
  • 10董刚,刘宏伟,陈义良.通用甲烷层流预混火焰半详细化学动力学机理[J].燃烧科学与技术,2002,8(1):44-48. 被引量:48

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化工学报
2005年 第2期

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