Large eddy simulation of turbulent premixed and stratified combustion using flame surface density model coupled with tabulation method

被引：0

作者：

Zhou YU ^{[1
]}

Hongda ZHANG ^{[2
]}

Taohong YE ^{[1
]}

Minming ZHU ^{[1
]}

机构：

[1] Department of Thermal Science and Energy Engineering, University of Science and Technology of China

[2] Shenyang Engine Research Institute, Aero Engine (Group) Corporation of China

来源：

AppliedMathematicsandMechanics(EnglishEdition) | 2018年 / 39卷 / 12期

关键词：

large eddy simulation(LES); flame surface density(FSD) model; tabulation; premixed combustion; stratified combustion;

D O I：

暂无

中图分类号：

O643.21 [];

学科分类号：

070304 ; 081704 ;

摘要：

Large eddy simulations(LESs) are performed to investigate the Cambridge premixed and stratified flames, SwB1 and SwB5, respectively. The flame surface density(FSD) model incorporated with two different wrinkling factor models, i.e., the Muppala and Charlette2 wrinkling factor models, is used to describe combustion/turbulence interaction, and the flamelet generated manifolds(FGM) method is employed to determine major scalars. This coupled sub-grid scale(SGS) combustion model is named as the FSD-FGM model. The FGM method can provide the detailed species in the flame which cannot be obtained from the origin FSD model. The LES results show that the FSD-FGM model has the ability of describing flame propagation, especially for stratified flames. The Charlette2 wrinkling factor model performs better than the Muppala wrinkling factor model in predicting the flame surface area change by the turbulence.The combustion characteristics are analyzed in detail by the flame index and probability distributions of the equivalence ratio and the orientation angle, which confirms that for the investigated stratified flame, the dominant combustion modes in the upstream and downstream regions are the premixed mode and the back-supported mode, respectively.

引用

页码：1719 / 1736

页数：18

共 24 条

[1]

Large eddy simulation of aircraft wake vortex with self-adaptive grid method[J]. Mengda LIN,Guixiang CUI,Zhaoshun ZHANG.Applied Mathematics and Mechanics(English Edition). 2016(10)

[2]

Large eddy simulation of turbulent lifted flame in a hot vitiated coflow using tabulated detailed chemistry[J] . Hongda Zhang,Zhou Yu,Taohong Ye,Majie Zhao,Ming Cheng.Applied Thermal Engineering . 2018

[3] Large eddy simulation of turbulent premixed combustion using tabulated detailed chemistry and presumed probability density function [J].

Zhang, Hongda ;

Han, Chao ;

Ye, Taohong ;

Ren, Zhuyin .

JOURNAL OF TURBULENCE, 2016, 17 (03) :327-355

[4]

Numerical study of laminar flame speed of fuel-stratified hydrogen/air flames[J] . Xian Shi,Jyh-Yuan Chen,Zheng Chen.Combustion and Flame . 2015

[5] Large Eddy Simulations of a turbulent premixed swirl flame using an algebraic scalar dissipation rate closure [J].

Butz, David ;

Gao, Yuan ;

Kempf, Andreas M. ;

Chakraborty, Nilanjan .

COMBUSTION AND FLAME, 2015, 162 (09) :3180-3196

[6]

Partial premixing and stratification in turbulent flames[J] . A.R. Masri.Proceedings of the Combustion Institute . 2015 (2)

[7]

Numerical study of methane/air jet flame in vitiated co-flow using tabulated detailed chemistry[J] . Chao Han,Pei Zhang,TaoHong Ye,YiLiang Chen.Science China Technological Sciences . 2014 (9)

[8]

Validation and Implementation of algebraic LES modelling of Scalar Dissipation Rate for reaction rate closure in turbulent premixed combustion[J] . T. Ma,Y. Gao,A.M. Kempf,N. Chakraborty.Combustion and Flame . 2014

[9]

Numerical analysis of the Cambridge stratified flame series using artificial thickened flame LES with tabulated premixed flame chemistry[J] . Fabian Proch,Andreas M. Kempf.Combustion and Flame . 2014

[10]

A filtered-laminar-flame PDF sub-grid scale closure for LES of premixed turbulent flames. Part I: Formalism and application to a bluff-body burner with differential diffusion[J] . Suresh Nambully,Pascale Domingo,Vincent Moureau,Luc Vervisch.Combustion and Flame . 2014

← 1 2 3 →