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- 2017
臭氧对甲烷/空气层流火焰传播速度影响规律
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Abstract:
摘要: 为提高气体机稀薄燃烧时的燃烧性能,解决天然气发动机在稀薄燃烧情况下点火能量高以及火焰传播速度慢的问题,利用强氧化性的臭氧对燃料进行改质,进而提高天然气燃烧性能。通过Chemkin软件研究臭氧添加对甲烷层流火焰传播速度的影响,并对臭氧助燃的化学机理进行数值分析。试验结果表明:添加臭氧后,层流火焰传播速度增加,在稀薄混合气条件下增加量更明显。在不同温度及压力条件下,掺加臭氧均能增加层流火焰传播速度,最大可增加36%。分析表明:掺加臭氧能明显提升自由基及中间产物的生成量,进而提高甲烷层流火焰传播速度。
Abstract: A new method was proposed to improve lean burn combustion performance of natural gas engine and to solve the problems of high ignition energy and slow flame speed of combustion of natural gas in lean burn condition by using the ozone with strong oxidation. The influence of ozone addition on laminar flame speed was studied and numerical analysis of chemical mechanism was carried out using Chemkin software. Results showed that laminar flame speed increased with ozone addition and improvement was more obvious with lean mixture. Moreover, laminar flame speed could be increased in different temperature and pressure situation with ozone addition and the maximum increment of laminar flame speed could reach 36%.The concentration of free radicals and intermediate products increased obviously with ozone addition and then improved the combustion characteristics of methane
| [1] | 周镇,艾育华,孔文俊.高压下合成气层流火焰传播特性的实验研究[J].工程热物理学报,2013,34(8):1560-1564. ZHOU Zhen, AI Yuhua, KONG Wenjun. Experimental investigation on laminar flame characteristics of syngas at elevated pressures[J]. Journal of Engineering Thermophysics, 2013, 34(8):1560-1564. |
| [2] | LEE S, PARK S, KIM C, et al. Comparative study on EGR and lean burn strategies employed in an SI engine fueled by low calorific gas[J]. Applied Energy, 2014, 129(15):10-16. |
| [3] | BAGIROV H, CAN(·overI), ?NER C, et al. Experimental investigation the effects of mixture impoverished on the specific fuel consumption, engine performance and exhaust emissions a pre-combustion chamber gasoline engine[J].Journal of the Energy Institute, 2015, 88(3):205-208. |
| [4] | 李晓晖. 甲烷/空气混合燃气激光诱导等离子体点火研究[D].哈尔滨:哈尔滨工业大学航天学院,2014 LI Xiaohui. Research on laser induced plasma ignition of methane/air mixtures[D]. Harbin: School of Astronautics, Harbin Institute of Technology, 2014. |
| [5] | 樊永胜. 生物质真空热解及催化转化制备生物油的基础研究[D].镇江:江苏大学,2016. FAN Yongsheng. Basic study on vacuum pyrolysis and catalytic transformation of biomass for preparation of bio-oil[D]. Zhenjiang: Jiangsu University, 2016. |
| [6] | 彭杨茗,汪春梅,姚登举,等. 臭氧对天然气 HCCI 发动机燃烧影响的数值研究[J]. 内燃机与动力装置2016,33(4): 1673-6397. PENG Yangming, WANG Chunmei, YAO Dengju, et al. A numerical study of the effect of ozone additive on the nature gas fueled HCCI engine[J]. Internal Combustion Engine & Power Plant, 2016, 33(4):1673-6397. |
| [7] | NISHIDA H, TACHIBANA T. Homogeneous charge compression ignition of natural gas/air mixture with ozone addition[J]. J Propuls Power, 2006, 2(1):151-157. |
| [8] | FOUCHER F, HIGELIN P, MOUNAM R C, et al. Influence of ozone on thecombustion of n-heptane in a HCCI engine[J]. Proc Combust Inst, 2013, 4(2):3005-3012. |
| [9] | SARATHY S M, WESTBOOK C K, DACAUT P, et al. Comprehensive chemical kinetic modeling of the oxidation of 2-methylalkanes from C<sub>7</sub> to C<sub>20</sub>[J]. Combustion and Flance, 2011, 158(12):2338-2357. |
| [10] | 冷锁林.天然气汽车发动机内催化燃烧研究[D].重庆:重庆大学动力工程学院,2005. LENG Suolin. The investigation of engine catalytic combustion in the natural gas car[D].Chongqing: College of Power Engineering, Chongqing University, 2005. |
| [11] | 葛文庆,刘梁,孙宾宾,等.电控燃料喷射大功率气体发动机的试验研究[J].中国石油大学学报(自然科学版),2013,37(4):129-132. GE Wenqing, LIU Liang, SUN Binbin, et al. Experimental study on heavy-duty gas engine with electronically controlled fuel injection device[J]. Journal of China University of Petroleum(Edition of Natural Science), 2013, 37(4):129-132. |
| [12] | 纪少波,季魁玉,程勇,等.海喷射持续期对大功率气体机影响规律分析[J].农业机械学报,2016,47(1):344-348. JI Shaobo, JI Kuiyu, CHENG Yong, et al. Influence of injection duration on high power multi-injection gas engine[J]. Transactions of the Chinese Society of Agricultural Machinery, 2016, 47(1):344-348. |
| [13] | BHASKOR J B, UJJWAL K S.Optimisation of injection timing and compression ratio of a raw biogas powered dual fuel diesel engine[J].Applied Thermal Engineering, 2016, 92(5):111-121. |
| [14] | IBRAHIM A, BARI S. A comparison between EGR and lean-burn strategies employed in a natural gas SI engine using a two-zone combustion model[J].Energy Conversion and Management, 2009, 50(12):3129-3139. |
| [15] | 林峰,杨强,王琼,等. 天然气发动机点火系统研发的理论与实践[J]. 现代车用动力,2014,154(2):5-8. LIN Feng, YANG Qiang, WANG Qiong, et al. Theory and practice of research and development on ignition system for natural gas engine[J]. Mordern Vehicle Power, 2014, 154(2):5-8. |
| [16] | 熊长君. 大型天然气发动机工作循环数值模拟分析[D]. 大连:大连理工大学,2013. XIONG Changjun. The working cycle simulation of a large natural gas engine[D]. Dalian: Dalian University of Technology, 2014. |
| [17] | YAMADA H, YOSHII M, TEZAKI A. Chemical mechanistic analysis of additive effects in homogeneous charge compression ignition of dimethyl ether[J]. Proc Combust Inst, 2005, II(2):2773-2780. |
| [18] | HALTER F, HIGELIN P, DAGAUT P. Experimental and detailed kinetic modeling study of the effect of ozone on the combustion of methane[J]. Energy & Fuels, 2011, 25(7):2909-2916. |
| [19] | 李鹏飞,费立群,金仁瀚,等.高密度烃层流火焰传播速度试验研究[J].推进技术,2015,36(8):1193-1198. LI Pengfei, FEI Liqun, JIN Renhan, et al. Experimental research of laminar flame speed of high density hydrocarbon[J]. Journal of Propulsion Technology, 2015, 36(8):1193-1198. |
| [20] | 马秋菊,张奇,庞磊.甲烷-空气最小点火能量预测理论模型[J]. 高压物理学报, 2012,26(3):301-305. MA Qiuju, ZHANG Qi, PANG Lei. Theoretical model of methane-air minimum ignition energy prediction[J]. Chinese Journal of High Pressure Physics, 2012, 26(3):301-305. |
| [21] | KORB B, KAWAUCHI S, WACHTMEISTER G.Influence of hydrogen addition on the operating range, emissions and efficiency in lean burn natural gas engines at high specific loads[J].Fuel, 2015, 164(15):410-418. |
| [22] | WANG Quangang, WANG Bin, YAO Chunde, et al. Study on cyclic variability of dual fuel combustion in a methanol fumigated diesel engine[J].Fuel, 2016,164(15):99-109. |
