[1]尹国明,刘有飞,夏永俊,等.含灰烟气循环煤粉富氧燃烧中超细颗粒物生成特性研究[J].热力发电,2018,(10):18-23.[doi:10.19666/j.rlfd.201801030]
 YIN Guoming,LIU Youfei,XIA Yongjun,et al.Formation characteristics of ultra fine particles during oxy-coal combustion with flue gas recirculation[J].Thermal Power Generation,2018,(10):18-23.[doi:10.19666/j.rlfd.201801030]
点击复制

含灰烟气循环煤粉富氧燃烧中超细颗粒物生成特性研究

参考文献/References:

[1] XU M H, YAN R, ZHENG C G, et al. Status of trace element emission in a coal combustion process: a review [J]. Fuel Processing Technology, 2003, 85(2): 215-237.
[2] WANG H L, HAO Z P, ZHUANG Y H, et al. Characterization of inorganic components of size-segregated particles in the flue gas of a coal-fired power plant[J]. Energy & Fuels, 2008, 22(3): 1636-1640.
[3] 徐静颖, 斯俊平, 刘小伟, 等. 燃煤PM2.5炉内控制研究进展[J]. 热力发电, 2013, 42(8): 1-12.
XU Jingying, SI Junping, LIU Xiaowei, et al. PM2.5 reduction in furnace during coal combustion[J]. Thermal Power Generation, 2013, 42(8): 1-12.
[4] 王超, 刘小伟, 吴建群, 等. 220 MW热电联产锅炉中痕量元素的迁移及分布[J]. 化工学报, 2014, 65(9): 3604-3608.
WANG Chao, LIU Xiaowei, WU Jianqun, et al. Migration and distribution characteristics of trace elements in 220 MW cogeneration boiler[J]. CIESC Journal, 2014, 65(9): 3604-3608.
[5] WANG C, LIU X W, LI D, et al. Effect of H2O and SO2 on the distribution characteristics of trace elements in particulate matter at high temperature under oxy-fuel combustion[J]. International Journal of Greenhouse Gas Control, 2014, 23(23): 51-60.
[6] 靳星. 静电除尘器内细颗粒物脱除特性的技术基础研究[D]. 北京: 清华大学, 2013: 3-4.
JING Xing. Research on the capture technology of fine particles in electrostatic precipitator[D]. Beijing: Tsinghua University, 2013: 3-4.
[7] 祁建民, 杨志超, 陈强. 静电除尘和电袋除尘技术研究对比分析[J]. 环境研究与检测, 2015, 28(1): 42-45.
QI Jianmin, YANG Zhichao, CHEN Qiang. The contrast between electrostatic and fabric composite filter[J]. Environmental Research and Testing, 2015, 28(1): 42-45.
[8] 洪亮, 王礼鹏, 祁慧, 等. 细颗粒物团聚性能实验研究[J]. 热力发电, 2014, 43(9): 124-128.
HONG Liang, WANG Lipeng, QI Hui, et al. Experimental research on agglomeration characteristics of fine particulate matters in Shajiao C Power Plant[J]. Thermal Power Generation, 2014, 43(9): 124-128.
[9] KANNICHE M, GROS-BONNIVARD R, JAUD P, et al. Pre-combustion post-combustion and oxy-combustion in thermal power plant for CO2 capture[J]. Applied Thermal Engineering, 2010, 30(1): 53-62.
[10] TAN Y, CROISET E, DOUGLAS M A, et al. Combustion characteristics of coal in a mixture of oxygen and recycled flue gas[J]. Fuel, 2006, 85(4): 507-512.
[11] SHENG C, LI Y, LIU X W, et al. Ash particle formation during O2/CO2 combustion of pulverized coals[J]. Fuel Processing Technology, 2007, 88(11/12):1021-1028.
[12] MORRIS W J, YU D X, WENDT J O L. A comparison of soot, fine particle and sodium emissions for air- and oxy-coal flames with recycled flue gases of various compositions[J]. Proceedings of the Combustion Institute, 2013, 34(2): 3453-3461.
[13] WANG X F, DAUKORU S M, TORKAMANI S, et al. Role of exhaust gas recycle on submicrometer particle formation during oxy-coal combustion[J]. Proceedings of the Combustion Institute, 2013, 34(2): 3479-3487.
[14] LIU X W, XU M H, YAO H, et al. Effect of combustion parameters on the emission and chemical composition of particulate matter during coal combustion[J]. Energy & Fuels, 2007, 21(1): 157-162.
[15] DAUKORU S M. The role of flue-gas recycle in submicrometer particle formation during oxy-combustion of american and Chinese coals[D]. Washington: Washington University, 2010: 36-40.
[16] MCLAUGHLIN J. The removal of volatile alkali salt vapours from hot coal-derived gases[D]. Guildford: University of Surrey, 1990: 61-68.
[17] LOWE A J, MCCAFFREY D J A, RICHARDS D G, et al. An investigation into the effectiveness of fireside fuel additives[J]. Fuel Processing Technology, 1993, 36(1): 47-53.
[18] KYI S, CHADWICK B L. Screening of potential mineral additives for use as fouling preventatives in Victorian brown coal combustion[J]. Fuel, 1999, 78(7): 845-855.
[19] EDDINGS E G, SAROFIM A F, LEE C M, et al. Trends in predicting and controlling ash vaporization in coal-fired utility boilers[J]. Fuel Process Technology, 2001, 71: 39-51.
[20] LIU Y, CHE D, XU T. Catalytic reduction of SO2 during combustion of typical chinese coals[J]. Fuel Processing Technology, 2002, 79(2): 157-169.
[21] IBARRA J, PALACIOS J, ANDR?S A M D. Analysis of coal and char ashes and their ability for sulphur retention[J]. Fuel, 1989, 68(7): 861-867.
(责任编辑 李园)

相似文献/References:

[1]徐朝芬,胡 松,孙学信,等.热重-红外联用技术在煤燃烧特性研究中的应用[J].热力发电,2005,(03):0.
[2]蔡 铭,徐明厚,乔 瑜,等.燃煤烟气中痕量元素的形态及其分析方法[J].热力发电,2004,(08):0.
[3]周飞,牛胜利,韩奎华,等.丙酸改性钙基固硫剂在煤燃烧过程中固硫特性研究[J].热力发电,2012,(08):24.
 ZHOU Fei,NIU Shengli,HAN Kuihua,et al.SULPHUR RETENTION CHARACTERISTIC OF CALCIUMBASED SULPHURFIXING AGENT MODIFIED BY PROPIONIC ACID DURING COAL COMBUSTION[J].Thermal Power Generation,2012,(10):24.
[4]黄天旭,王聪玲,谭厚章.燃烧器配风方式对NOx排放影响的试验研究[J].热力发电,2008,(05):36.
[5]邓建军,李洪林.煤中氮元素化学赋存形态及热迁徙规律的研究进展[J].热力发电,2008,(03):12.
[6]徐 旭,严建华,葛 俊,等.燃煤飞灰中重金属元素分布规律的试验研究[J].热力发电,2002,(01):0.
[7]周桂萍,叶春松.火电厂二氧化硫排放量试验研究[J].热力发电,2003,(05):0.
[8]骆仲泱,毛玉如,吴学成,等.O2/CO2气氛下煤燃烧特性试验研究与分析[J].热力发电,2004,(06):0.
[9]王 臣,徐明厚,刘 晶,等.基于量子化学的燃煤过程痕量元素反应机理研究及其进展[J].热力发电,2005,(04):0.
[10]谭增强,牛国平.烟气汞脱除的研究进展[J].热力发电,2013,(10):1.
 TAN Zengqiang,NIU Guoping.Research progress of mercury removal in flue gas[J].Thermal Power Generation,2013,(10):1.

备注/Memo

尹国明(1965—),男,硕士,高级工程师,主要研究方向为热能工程,634097177@qq.com。

更新日期/Last Update: 2018-09-29