COMPUTATIONAL FLUID DYNAMICS MODELING TOWARD CLEAN COMBUSTION

IF 1.3 Q3 THERMODYNAMICS Computational Thermal Sciences Pub Date : 2012-01-01 DOI:10.1615/COMPUTTHERMALSCIEN.2012004160

K. Dinesh, M. Kirkpatrick, A. Odedra

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Abstract

A turbulent hydrogen-air nonpremixed jet flame is studied using three-dimensional large eddy simulation (LES) and laminar flamelet model based on detailed chemical kinetics. The LES solves the governing equations on a structured Cartesian grid using a finite volume method, with turbulence and combustion modelling based on the localised dynamic Smagorinsky model and the steady laminar flamelet model respectively. The LES results are validated against experimental measurements and overall the LES yields good qualitative and quantitative agreement with the experimental observations. Analysis showed that the LES gives good prediction of the flow field, flame temperature and major species. The three-dimensional transient LES demonstrates the variation of low and high temperature structures and both transient and mean predictions show that the high temperature regions and combustion product appear close to the jet centreline. The present findings provide useful details on fundamental issues of turbulence-chemistry interactions of hydrogen combustion and help to identify potential pathways for combustion modelling towards clean combustion.

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面向清洁燃烧的计算流体动力学建模

采用三维大涡模拟(LES)和基于详细化学动力学的层流火焰模型，对氢-空气非预混射流湍流火焰进行了研究。该系统采用有限体积法在结构笛卡尔网格上求解控制方程，湍流和燃烧模型分别基于局部动态Smagorinsky模型和稳定层流小火焰模型。LES的结果与实验测量结果进行了验证，总的来说，LES与实验观察结果在定性和定量上都很一致。分析表明，该方法能较好地预测火焰的流场、火焰温度和主要物质。三维瞬态LES显示了低温和高温结构的变化，瞬态和平均预测都表明高温区域和燃烧产物出现在靠近射流中心线的地方。本研究结果为氢燃烧的湍流-化学相互作用的基本问题提供了有用的细节，并有助于确定清洁燃烧的燃烧建模的潜在途径。

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来源期刊

Computational Thermal Sciences THERMODYNAMICS-

CiteScore

2.70

自引率

6.70%

发文量