Numerical study of methane/air jet flame in vitiated co-flow using tabulated detailed chemistry 被引量：7

Numerical study of methane/air jet flame in vitiated co-flow using tabulated detailed chemistry

导出

摘要 Two different combustion models,the autoignition(AI)model and flamelet/progress variable(FPV)model,have been applied to study the auto-ignition process of methane/air jet flame in vitiated co-flow.A priori study was conducted to test the validity of the two models.Results show that the different range of predicted reaction rates is mainly responsible for their different performances in large eddy simulation(LES)studies.In this paper,beta PDF was used to model the mixture fraction distribution,while two different shapes of PDF,delta function and beta function,were applied for the reaction progress.Compared to the FPV model,the AI model combined with beta function for reaction progress could capture the auto-ignition process and predict the exact lifted height.Also the results indicate that the variance of reaction progress plays an important role in predicting the flame lifted height.

作者 HAN Chao ZHANG Pei YE TaoHong CHEN YiLiang

机构地区 Department of Thermal Science and Energy Engineering

出处《Science China(Technological Sciences)》 SCIE EI CAS 2014年第9期1750-1760,共11页 中国科学（技术科学英文版）

基金 supported by the National Natural Science Foundation of China(Grant Nos.51176178 and 50936005)

关键词 large eddy simulation flamelet/progress variables AUTOIGNITION vitiated co-flow flame 喷射火焰数值模拟空气甲烷化学表格反应速率点火过程

分类号 TQ038 [化学工程]

引文网络
相关文献

参考文献33

1Christo F C, Dally B B. Modeling turbulent reacting jets issuing into a hot and diluted coflow. Combust Flame, 2005, 142: 117-129.
2Ihme M, Yee C S. LES flamelet modeling of a three-stream MILD combustor: analysis of flame sensitivity to scalar inflow conditions. Proc Combust Inst, 2011, 33: 1309-1317.
3Dally B B, Karpetis A N, Barlow R S. Structure of turbulent non-premixed jet flames in a diluted hot coflow. Proc Combust Inst, 2002, 29: 1147-1154.
4Cabra R, Chen J Y, Dibble R W, et al. Lifted methane-air jet flames in a vitiated coflow. Combust Flame, 2005, 143: 491-506.
5Bilger R W, Pope S B, Bray K N C, et al. Paradigms in turbulent combustion research. Proc Combust Inst, 2005, 30: 21-42.
6Pitsch H. Large-eddy simulation of turbulent combustion. Ann Rev Fluid Mech, 2006, 38: 453-482.
7Pierce C D, Moin P. Progress-variable approach for large-eddy simulation of non-premixed turbulent combustion. J Fluid Mech, 2004, 504: 73-97.
8Pitsch H, Steiner H. Large-eddy simulation of a turbulent piloted methane/air diffusion flame (Sandia flame D). Phys Fluids, 2000, 12: 2541-2554.
9Jha P K, Groth C P T. Tabulated chemistry approaches for laminar flames: Evaluation of flame-prolongation of ILDM and flamelet methods. Combust Theor Model, 2012, 16: 31-57.
10Verhoeven L M, Ramaekers W J S, Van Oijen J A, et al. Modeling non-premixed laminar co-flow flames using flamelet-generated manifolds. Combust Flame, 2012, 159: 230-241.

同被引文献29

1ZOU Jian-feng,ZHENG Yao,LIU Ou-zi.Simulation of turbulent combustion in DLR Scramjet[J].Journal of Zhejiang University-Science A(Applied Physics & Engineering),2007,8(7):1053-1058. 被引量：2
2WANG XiaoWei,CAI GuoBiao,GAO YuShan,HUO HongFa.High flowrate injector with gaseous hydrogen and gaseous oxygen[J].Science China(Technological Sciences),2011,54(11):2958-2973. 被引量：1
3ZHAO YuXin,YI ShiHe,TIAN LiFeng,HE Lin,CHENG ZhongYu.The fractal measurement of experimental images of supersonic turbulent mixing layer[J].Science China(Physics,Mechanics & Astronomy),2008,51(8):1134-1143. 被引量：24
4Bing Ge Shu-Sheng Zang.Experimental Study on the Interactions for Bluff-body and Swirl in Stabilized Flame Process[J].Journal of Thermal Science,2012,21(1):88-96. 被引量：5
5WANG XiaoWei,CAI GuoBiao,HUO HongFa.Numerical study of high-pressure GO_2/GH_2 combustion of a single-element injector[J].Science China(Technological Sciences),2012,55(10):2757-2768. 被引量：1
6DANG GuoXin,ZHONG FengQuan,CHEN LiHong,CHANG XinYu.Numerical investigation on flow and convective heat transfer of aviation kerosene at supercritical conditions[J].Science China(Technological Sciences),2013,56(2):416-422. 被引量：12
7LI ZhiWei,HUAI WenXin,QIAN ZhongDong.Large eddy simulation of a round jet into a counterflow[J].Science China(Technological Sciences),2013,56(2):484-491. 被引量：4
8XU MinYi,ZHANG JianPeng,MI JianChun,NATHAN G J,KALT P A M.PIV measurements of turbulent jets issuing from triangular and circular orifice plates[J].Science China(Physics,Mechanics & Astronomy),2013,56(6):1176-1186. 被引量：7
9ZHANG ZhengGang,XU KaiLiang,TA DeAn,WANG WeiQi.Joint spectrogram segmentation and ridge-extraction method for separating multimodal guided waves in long bones[J].Science China(Physics,Mechanics & Astronomy),2013,56(7):1317-1323. 被引量：10
10WANG HongBo,WANG ZhenGuo,SUN MingBo,QIN Ning.Hybrid Reynolds-averaged Navier-Stokes/large-eddy simulation of jet mixing in a supersonic crossflow[J].Science China(Technological Sciences),2013,56(6):1435-1448. 被引量：1

引证文献7

1XU KeKe,MENG Hua.Analyses of surrogate models for calculating thermophysical properties of aviation kerosene RP-3 at supercritical pressures[J].Science China(Technological Sciences),2015,58(3):510-518. 被引量：7
2YANG Zhi,GONG Mao Qiong,ZHOU Yuan,DONG Xue Qiang,LI Xiao Dong,LI Hui Ya,WU Jian Feng.Vapor-liquid equilibria of CH_4, CO_2 and their binary system CH_4 + CO_2: A comparison between the molecular simulation and equation of state[J].Science China(Technological Sciences),2015,58(4):650-658. 被引量：1
3ZHANG HongDa,HAN Chao,YE TaoHong,ZHANG JiMin,CHEN YiLiang.Large eddy simulation of unconfined turbulent swirling flow[J].Science China(Technological Sciences),2015,58(10):1731-1744. 被引量：5
4DAI Jian,YU NanJia,CAI GuoBiao.Investigation of non-premixed flame combustion characters in GO_2/GH_2 shear coaxial injectors using non-intrusive optical diagnostics[J].Science China(Physics,Mechanics & Astronomy),2015,58(12):167-179. 被引量：2
5Cao Changmin,Ye Taohong,Zhao Majie.Large eddy simulation of hydrogen/air scramjet combustion using tabulated thermo-chemistry approach[J].Chinese Journal of Aeronautics,2015,28(5):1316-1327. 被引量：7
6唐鹏,张宏达,叶桃红,于洲.拉伸层流预混火焰化学热力学建表方法研究[J].推进技术,2017,38(5):1093-1099.
7Zhou YU,Hongda ZHANG,Taohong YE,Minming ZHU.Large eddy simulation of turbulent premixed and stratified combustion using flame surface density model coupled with tabulation method[J].Applied Mathematics and Mechanics(English Edition),2018,39(12):1719-1736. 被引量：1

二级引证文献23

1LIU YangWei,YAN Hao,FANG Le,LULiPeng,LI QiuShi,SHAO Liang.Modified k-ω model using kinematic vorticity for corner separation in compressor cascades[J].Science China(Technological Sciences),2016,59(5):795-806. 被引量：7
2Liu Yangwei,Yan Hao,Liu Yingjie,Lu Lipeng,Li Qiushi.Numerical study of corner separation in a linear compressor cascade using various turbulence models[J].Chinese Journal of Aeronautics,2016,29(3):639-652. 被引量：14
3汪秋笑,黄东欣,孟华.甲烷-液氧超临界压力非预混湍流燃烧的数值模拟[J].航空学报,2016,37(7):2132-2143. 被引量：3
4NIU JingLong,SHI Yan,CAO ZhiXin,CAI MaoLin,CHEN Wei,ZHU Jian,XU WeiQing.Study on air flow dynamic characteristic of mechanical ventilation of a lung simulator[J].Science China(Technological Sciences),2017,60(2):243-250. 被引量：8
5于洲,张宏达,叶桃红,唐鹏.基于火焰面密度的湍流分层燃烧大涡模拟[J].推进技术,2018,39(3):565-574. 被引量：2
6黄世璋,阮波,高效伟,刘华雩.超临界压力下碳氢燃料裂解与流动传热模拟的快速算法[J].航空学报,2018,39(4):90-103. 被引量：2
7沈欢,张子健,刘云峰,姜宗林.超燃冲压发动机推进性能理论分析[J].气体物理,2018,3(1):12-19. 被引量：4
8韩树焘,林洁,俞南嘉,张洋.气氧/气甲烷同轴剪切双喷嘴仿真研究[J].火箭推进,2018,44(3):68-75. 被引量：2
9孙星,徐可可,孟华.超临界压力正癸烷在螺旋管中传热与裂解吸热现象的数值模拟[J].化工学报,2018,69(A01):20-25. 被引量：3
10于洲,黄立航,叶桃红,朱旻明.高雷诺数湍流非预混火焰及NO生成的大涡模拟[J].空气动力学学报,2020,38(3):629-640. 被引量：1

1姜斌,梁红英,黄国强,李鑫钢.Study on NO_x Formation in CH_4/Air Jet Combustion[J].Chinese Journal of Chemical Engineering,2006,14(6X):723-728.
2黄山.沸腾炉点火的理论与实践[J].铜业工程,2000(4):10-13.
3ZHAO PingHui, YE TaoHong, ZHU MinMing, JIANG Hai & CHEN YiLiang Thermal Science & Energy Engineering Department, University of Science & Technology of China, Hefei 230027, China.Numerical investigation on hydrogen production by CH_4-Rich combustion in an alumina foam[J].Science China(Technological Sciences),2009,52(10):2960-2966. 被引量：3
4金加胜,梅金珂,王志远,李文海,陈之专.采用先进优化技术提高5000t/d烧成系统技术性能[J].新世纪水泥导报,2016,22(5):34-36.
5张五交,李爱民.造气分厂“1·16”吹风气燃烧炉爆炸事故[J].化工安全与环境,2011(15):5-5.
6吴婉娥,裴明敬,郭耳铃,赵鹏,毛根旺.硼颗粒在固冲环境中点火过程影响因素的数值模拟[J].火炸药学报,2008,31(3):79-82. 被引量：5
7单彦广,俞昌铭.喷射火焰环境下液化气容器的热响应[J].燃烧科学与技术,1999,5(4):375-379. 被引量：9
8Cai Xiulan,Li Guangyan,Lin Weiming.Effects of Promoters on the Ignition Process over NiO/Al_2O_3 Catalyst for Autothermal Reforming of Methane to Hydrogen[J].China Petroleum Processing & Petrochemical Technology,2014,16(3):56-62. 被引量：1
9马亮,曹立勇,何榕.Numerical study of pore structure effect on SO_2–CaO reactions[J].Chinese Journal of Chemical Engineering,2015,23(4):652-658.
10秦益鹏.银河集团180kt/a硫铁矿制酸沸腾炉硫磺点火实践[J].硫酸工业,2010(6).

Science China(Technological Sciences)

2014年第9期

浏览历史

内容加载中请稍等...

Numerical study of methane/air jet flame in vitiated co-flow using tabulated detailed chemistry 被引量：7

参考文献33

同被引文献29

引证文献7

二级引证文献23

相关作者

相关机构

相关主题

浏览历史