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环境工程学报 2014

介质阻挡放电协同Ag/Al2O3 对NOx脱除的影响

朱翔宇,孙保民,王东,张婷婷,汪涛,肖海平,韩高岩

Keywords: 介质阻挡放电,Ag/Al2O3,协同,NOx脱除,乙烯

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Abstract:

为有效去除发电厂烟气中产生的NOx，利用介质阻挡放电（DBD）产生低温等离子体并结合催化剂Ag/Al2O3进行烟气脱硝实验，研究了在加入乙烯的条件下，平均负载量、催化温度和装置的布置方式对NOx脱除的影响。结果表明，随着负载的增多，NO脱除率呈现先增大后减小的趋势，5种负载量中最佳为1.76%；随着催化温度的升高，NO脱除率同样呈现先增大后减小的趋势，最佳的催化温度为150℃左右；3种不同布置方式对NO和NOx脱除有明显差别，单独催化剂在NO和NOx的脱除率都比较低；单独介质阻挡放电NO脱除率很高，但是NOx很却很低；而两者结合在NO和NOx都达到了很好的效果。

References

[1]	Bamwenda G.R., Obuchi A., Ogata A., et al. An FTIR study of the species adsorbed on a Rh/Al2O3 catalyst in the selective reduction of NO by propylene. Chemistry Letters, 1994, 23(11): 2109-2112
[2]	Kim M.K., Kim P.S., Baik J.H., et al. De NOx performance of Ag/Al2O3 catalyst using simulated diesel fuel-ethanol mixture as reductant. Applied Catalysis B: Environmental, 2011, 105(1/2): 1-14
[3]	Gaffney J.S.,Marley N.A. The impacts of combustion emissions on air quality and climate from coal to biofuels and beyond. Atmospheric Environment, 2009, 43(1):23-36
[4]	范红玉.等离子体催化低温脱除氮氧化物和苯的研究.大连:大连理工大学博士学位论文,2009 Fan H.Y. Plasma catalytic removal of nitrogen oxides and benzene at low temperature. Dalian: Doctoral Dissertation of Dalian University of Technology, 2009(in Chinese)
[5]	关绣娟,叶代启,黄海保.介质阻挡放电-催化降解空气中甲苯的研究. 环境工程学报,2008,2(7):977-982 Guan X.J., Ye D.Q., Huang H.B. Study on toluene destruction in air stream by dielectric barrier discharge combined with catalytic system. Chinese Journal of Environmental Engineering, 2008, 2(7): 977-982(in Chinese)
[6]	黄炯,杨利娴,龙丽萍,等.介质阻挡放电联合催化臭氧化降解甲苯.环境工程学报,2010,4(6):1373-1378 Huang J.,Yang L.X., Long L.P., et al. Decomposition of toluene by dielectric barrier discharge combined with catalytic ozonation. Chinese Journal of Environmental Engineering, 2010, 4(6): 1373-1378(in Chinese)
[7]	柯锐,李俊华,郝吉明,等.低温等离子体协同Ag/Al2O3选择性催化丙烯还原氮氧化物反应的原位红外光谱研究.催化学报,2005,26(11):951-955 Ke R.,Li J.H., Hao J.M.,et al. In situ DRIFTS study on non-thermal plasma-assisted NOx reduction by propene over Ag/Al2O3 catalyst. Chinese Journal of Catalysis, 2005, 26(11): 951-955(in Chinese)
[8]	孙琪.富氧条件下等离子体与催化活化协同脱除氮氧化物研究.大连:大连理工大学博士学位论文,2004 Sun Q.NOx removal by synergistic effects of plasmas and catalysts in the presence of excess oxygen. Dalian: Doctoral Dissertation of Dalian University of Technology, 2004(in Chinese)
[9]	杜旭,孙保民,肖海平,等.介质阻挡放电条件下添加乙烯对NO氧化影响的试验研究.动力工程学报,2011,31(11):882-886 Du X., Sun B.M., Xiao H.P., et al.. Influence of ethylene on NO oxidation in a dielectric barrier discharge reactor. Journal of Chinese Society of Power Engineering, 2011, 31(11): 882-886(in Chinese)
[10]	Shimizu K., Shibata J., Yoshida H., et al. Silver-alumina catalysts for selective reduction of NO by higher hydrocarbons: Structure of active sites and reaction mechanism. Applied Catalysis B: Environmental, 2001, 30(1/2): 151-162
[11]	Martnez-Arias A., Fernandez-Garca M.,Iglesias-Juez A., et al. Study of the lean NOx reduction with C3H6 in the presence of water over silver/alumina catalysts prepared from inverse microemulsions. Applied Catalysis B: Environmental, 2000, 2(1): 29-41
[12]	Penetrante B.M., Brusasco R.M., Merritt B.T., et al. Plasma-assisted catalytic reduction of NOx. International Fall Fuels and Lubricants Meeting and Exposition, San Francisco, October 19-22, 1998, SAE Paper 982508
[13]	Nie Y., Wang J.Y, Zhong K., et al. Synergy study for plasma-facilitated C2H4 selective catalytic reduction of NOx Over Ag/γ-Al2O3 catalyst. IEEE Transactions on Plasma Science, 2007, 35(3): 663-669
[14]	Tsang W., Herron J.T. Chemical kinetic data base for propellant combustion. I. Reactions involving NO, NO2, HNO, HNO2, HCN and N2O. Journal of Physical and Chemical Reference Data, 1991, 20(4): 609-663
[15]	Tsang W., Hampson R.F. Chemical kinetic data base for combustion chemistry. Part I. Methane and related compounds. Journal of Physical Reference Data, 1986,15(3):1087-1279
[16]	Atkinson R., Baulch D.L., Cox R.A., et al. Evaluated kinetic, photochemical and heterogeneous data for atmospheric chemistry: Supplement V, IUPAC subcommittee on gas kinetic data evaluation for atmospheric chemistry. Journal of Physical and Chemical Reference Data, 1997, 26(3): 521-1011
[17]	Atkinson R., Baulch D.L., Cox R.A., et al. Evaluated kinetic and photochemical data for atmospheric chemistry: Volume I: Gas phase reactions of Ox, HOx, NOx and SOx species. Atmospheric Chemistry and Physics, 2004, 4(6): 1461-1738
[18]	Khacef A., Cormier J.M., Pouvesle J.M. NOxremediation in oxygen-rich exhaust gas using atmospheric pressure non-thermal plasma generated by a pulsed nanosecond dielectric barrier discharge. Journal of Physics D: Applied Physics, 2002, 35(13): 1491-1498
[19]	Shimizu K., Shibata J., Yoshida H., et al. Silver-alumina catalysts for selective reduction of NO by higher hydrocarbons: Structure of active sites and reaction mechanism. Applied Catalysis B:Environmental, 2001, 30(1/2): 151-162
[20]	Yu Y.B., He H., Feng Q.C. Novel enolic surface species formed during partial oxidation of CH3CHO, C2H5OH, and C3H6 on Ag/Al2O3: An in situ DRIFTS study. Journal of Physical Chemistry, 2003, 107(47): 13090-13092
[21]	Yan Y., Yu Y.B., He H., et al. Intimate contact of enolic species with silver sites benefits the SCR of NOx by ethanol over Ag/Al2O3. Journal of Catalysis, 2012, 293: 13-26

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