甲烷掺混对乙烯扩散火焰中PAH及碳烟生成的影响机理

摘要
图/表
参考文献(0)
相关文章 (15)

全文: PDF (4112 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要以甲烷掺混乙烯对冲扩散火焰为研究载体,基于火焰多参数试验测量数据,分析了两种常用于模拟预测多环芳烃（polycyclic aromatic hydrocarbon，PAH）及碳烟生成的反应动力学机理,即气相化学反应机理（KAUST PAH mechanism 2,KM2）和AramcoMech机理.研究结果表明：两种机理均能较准确地预测甲烷掺混乙烯扩散火焰的热化学结构；两种机理关于甲烷掺混对PAH及碳烟生成的影响预测效果不佳；两种机理均未能预测甲烷掺混对乙烯火焰中PAH及碳烟生成的抑制行为；通过比较两种机理中PAH及碳烟生成路径的异同,发现两种机理均高估了炔丙基自由基（C3H3·）生成对甲烷掺混的敏感性；火焰多参数测量数据有助于进一步优化和验证甲烷燃料的反应机理.

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	王祯
	江鹏
	周梦祥
	王宇

关键词 ：甲烷, 乙烯, 多环芳香烃, 碳烟, 反应机理

Abstract：The reaction kinetics mechanisms of KAUST PAH mechanism 2（KM2） and AramcoMech are commonly used to simulate and predict the generation of polycyclic aromatic hydrocarbon(PAH) and soot. The two kinetics mechanisms were evaluated based on the flame multiparameter measurement data using methane mixed with ethylene opposed diffusion flame as research carrier. The results show that the two mechanisms can accurately predict the thermochemical structure of methane mixed with ethylene diffusion flame. However, the prediction performance of the influence of methane mixing on PAH and soot generation is poor. Neither mechanism fails to predict the inhibition of PAH and soot generation in methane mixed with ethylene flame. Comparing the similarities and differences of PAH and soot generation paths between the two mechanisms, it is found that both mechanisms overestimate the sensitivity of propargyl radical（C3H3·）generation to methane blending. The flame multiparameter measurement data are helpful to further optimize and verify the reaction mechanism of methane fuel.

Key words： methane ethylene PAH soot kinetic mechanism

基金资助:国家自然科学基金资助项目(51976142)

作者简介: 王祯(1997—)，女，湖北天门人，硕士研究生(18696498873@163.com)，主要从事燃烧与碳烟排放的研究. 王宇(1985—)，男，安徽六安人，教授，博士生导师(通信作者，yu.wang@whut.edu.cn)，主要从事燃烧能源理论及工程应用研究.

引用本文:

王祯, 江鹏, 周梦祥, 王宇. 甲烷掺混对乙烯扩散火焰中PAH及碳烟生成的影响机理[J]. 江苏大学学报（自然科学版）, 2024, 45(6): 716-724. WANG Zhen, JIANG Peng, ZHOU Mengxiang, WANG Yu. Formation mechanism of PAH and soot in diffusion flames of ethylene with methane addition[J]. Journal of Jiangsu University(Natural Science Eidtion) , 2024, 45(6): 716-724.

链接本文:

http://zzs.ujs.edu.cn/xbzkb/CN/ 或 http://zzs.ujs.edu.cn/xbzkb/CN/Y2024/V45/I6/716

［1］	SU Z W, YING Y Y, CHEN C, et al. Effects of diluent gases on sooting transition process in ethylene counterflow diffusion flames[J]. RSC Advances, 2022,12(28):18181-18196.
［2］	WANG Y, CHUNG S H. Soot formation in laminar counterflow flames[J]. Progress in Energy and Combustion Science, DOI:10.1016/j.pecs.2019.05.003.
［3］	WANG Y, RAJ A, CHUNG S H. Soot modeling of counterflow diffusion flames of ethylenebased binary mixture fuels[J]. Combustion and Flame, 2015,162(3):586-596.
［4］	YOON S S, LEE S M, CHUNG S H. Effect of mixing methane, ethane, propane, and propene on the synergistic effect of PAH and soot formation in ethylenebase counterflow diffusion flames[J]. Proceedings of the Combustion Institute, 2004,30(1):1417-1424.
［5］	YAN F W, XU L, WANG Y, et al. On the opposing effects of methanol and ethanol addition on PAH and soot formation in ethylene counterflow diffusion flames[J]. Combustion and Flame, 2019,202:228-242.
［6］	ZHAO X, XU L, CHEN C, et al. Experimental and numerical study on sooting transition process in isooctane counterflow diffusion flames: diagnostics and combustion chemistry[J]. Journal of the Energy Institute, 2021,98:282-293.
［7］	HWANG J Y, LEE W, KANG H G, et al. Synergistic effect of ethylenepropane mixture on soot formation in laminar diffusion flames[J].Combustion and Flame, 1998,114(3/4):370-380.
［8］	WANG W, XU L, YAN J, et al. Temperature dependence of the fuel mixing effect on soot precursor formation in ethylenebased diffusion flames[J]. Fuel, DOI:10.1016/j.fuel.2020.117121.
［9］	王薇,徐磊,周梦祥,等. 乙烯部分预混火焰中苯的生成机理[J]. 江苏大学学报(自然科学版), 2021,42(1): 98-104.
	WANG W, XU L, ZHOU M X, et al. Formation mechanism of benzene in partially premixed ethylene flame[J]. Journal of Jiangsu University (Natural Science Edition), 2021,42(1):98-104.(in Chinese)
［10］	何志霞,卢鹏,玄铁民,等. 柴油两段喷射碳烟生成的光学测试研究[J]. 工程热物理学报,2021,42(8):2162-2168.
	HE Z X, LU P, XUAN T M, et al. Optical study on soot production in doubleinjection of diesel spring[J]. Journal of Engineering Thermophysics, 2021,42(8):2162-2168.(in Chinese)
［11］	JIANG P, ZHOU M X, WEN D X, et al. An experimental multiparameter investigation on the thermochemical structures of benchmark ethylene and propane counterflow diffusion flames and implications to their numerical modeling[J]. Combustion and Flame, DOI:10.1016/j.combustflame.2021.111622.
［12］	WANG Y, RAJ A, CHUNG S H. A PAH growth mechanism and synergistic effect on PAH formation in counterflow diffusion flames[J]. Combustion and Flame, 2013,160(9):1667-1676.
［13］	METCALFE W K, BURKE S M, AHMED S S, et al. A hierarchical and comparative kinetic modeling study of C1-C2 hydrocarbon and oxygenated fuels[J]. International Journal of Chemical Kinetics, 2013,45(10):638-675.
［14］	孟忠伟,李健,杜雨恒,等.热老化对碳烟颗粒氧化特性的影响[J].江苏大学学报(自然科学版),2018,39(6):647-652.
	MENG Z W, LI J, DU Y H, et al. Influence of thermal aging on oxidation performance of soot[J]. Journal of Jiangsu University (Natural Science Edition), 2018,39(6):647-652.(in Chinese)
［15］	WEN D X, WANG Y. Spatially and temporally resolved temperature measurements in counterflow flames using a single interband cascade laser[J]. Optics Express, 2020,28(25):37879-37902.
［16］	FIGURA L, CARBONE F, GOMEZ A. Challenges and artifacts of probing highpressure counterflow laminar diffusion flames[J]. Proceedings of the Combustion Institute, 2015,35(2):1871-1878.
［17］	JAHANGIRIAN S, MCENALLY C S, GOMEZ A. Experimental study of ethylene counterflow diffusion flames perturbed by trace amounts of jet fuel and jet fuel surrogates under incipiently sooting conditions[J]. Combustion and Flame, 2009,156(9):1799-1809.
［18］	ZABETI P. Gaseous species measurements of alternative jet fuels in sooting laminar coflow diffusion flames[D]. Toronto, CAN: University of Toronto, 2017.
［19］	YAN F W, ZHOU M X, XU L, et al. An experimental study on the spectral dependence of light extinction in sooting ethylene counterflow diffusion flames[J]. Experimental Thermal and Fluid Science, 2019,100:259-270.
［20］	ZHOU J W, ZHOU M X, MA L H, et al. Slight asymmetry induces significant distortion of soot volume fraction measurements in counterflow diffusion flames with diffuse backillumination imaging[J]. Optics Express, 2022,30(5):6671-6689.
［21］	ZHOU J W, ZHOU M X, MA L H, et al. Planar light extinction measurement of soot volume fraction in laminar counterflow diffusion flames[J]. Frontiers in Mechanical Engineering, DOI:10.3389/fmech.2021.720917.
［22］	ZHOU C W, LI Y, BURKE U, et al. An experimental and chemical kinetic modeling study of 1,3butadiene combustion: ignition delay time and laminar flame speed measurements[J]. Combustion and Flame, 2018,197:423-438.