Paper Titles

Probe into CO₂-Coal Interactions with Differential Scanning Calorimetry
p.1286

Effects of Static Magnetic Field on Phosphate Buffer Solution
p.1293

Methanol Electro-Oxidation Using RuRh@Pt/C
p.1297

Effect of Catalysts on Oxidation of Ruqigou Coal with NaOCl
p.1303

Research of the SNCR Process and its Application
p.1307

A Novel Process Simulation Study of Coalbed Methane Enrichment by Solvent
p.1315

Direct-Drive Permanent Magnet Synchronous Motor in the Application of New Energy Vehicles
p.1321

Experiment Research of the Influence of Bio-Diesel on the Number and Size Distribution of PM Emissions of Diesel Engine
p.1325

Research on the Data Management of Electric Vehicle Charging Equipment Testing Platform
p.1332

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 953-954Research of the SNCR Process and its Application

Research of the SNCR Process and its Application

Article Preview

Abstract:

The principles of SNCR process and factors affecting the denitrification efficiency are described in details. The efficiency and cost of SNCR and SCR processes are briefly compared. SNCR process has advantages of short construction period, low investment cost and so on. If the discharge standard is hard to meet, coupling SNCR with other NO_x control methods can be considered to reduce NO_x emission. Based on the complex circumstance of units in China, SNCR process is very suitable for application in industry.

You might also be interested in these eBooks

Advanced Energy Technology

Info:

Periodical:

Advanced Materials Research (Volumes 953-954)

Pages:

1307-1314

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.953-954.1307

Citation:

Cite this paper

Online since:

June 2014

Authors:

Zhong Li, Xue Min Liu, Ding Hua Yang, Wen Jun Qin, Gen Sheng Yang, Da Long Zhang*

Keywords:

Combination Technologies, Costs, Influencing Factor, Principles, SNCR

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

© 2014 Trans Tech Publications Ltd. All Rights Reserved

Share:

Citation:

* - Corresponding Author

[1] W. Zheng: Principium Research of SNCR De NOx Process (Tongji University, Shanghai 2007).

[2] J. Cheng and C.L. Wang: Energy Environmental Protection Vol. 27 (2013), p.18.

[3] Q. Li: Development of Selective Non-Catalytic Reduction for NOx Emission Control in a Circulating Fluidized Bed Boiler (Tsinghua University, Beijing 2013).

[4] Z.H. Luo and E.L. Wang: Journal of Power Engineering Vol. 28 (2008), p.442.

[5] R.K. Lyon and J.P. Longwell, in: The Proceedings of NOx Control Technology Seminar, San Francisco, CA, US (1976).

[6] L.J. Muzio, J.K. Arand and M.K. L, in: 17th Symposium (International) on Combustion, Combustion Institute, Pittsburgh (1978), p.89.

[7] R.K. Lyon: Hydrocarbon Processing Vol. 58 (1979), p.109.

[8] B.E. Hurst: Glass Technology Vol. 24 (1983), p.97.

[9] P. Lodder and J.B. Lefers: The Chemical Engineering Journal Vol. 30 (1985), p.161.

[10] M.A.I. Robin, H.J. Price and R.T. Squires, in: Joint EPA/EPRI Symp. on Stationary Combustion NOx Control (1991), p.99.

[11] J.A. Caton, I.J.K. Narney and C. Cariappa, et al: The Canadian Journal of Chemical Engineering Vol. 73 (1995), p.345.

[12] A.M.G. Gentemann and J.A. Caton, in: 2nd Joint Meeting of the United States Sections of the Combustion Institute 2001 Spring Technical Conference, The Oakland Marriott City Center, Oakland, CA, US (2001).

[13] L.J. Muzio, J.K. Arand and D.P. Teixeira, in: 16th Symposium (International) on Combustion, The Combustion Institute (1976), p.199.

[14] Z.H. Wang, J.H. Zhou and H. Zhou, et al: Journal of Zhejiang University (Engineering Science) Vol. 38 (2004), p.495.

[15] L. Liang, S.E. Hui and S. Pan, et al: Fuel Vol. 120 (2014), p.38.

[16] D. Lucas and N.J. Brown, et al: Combustion and Flame Vol. 47 (1982), p.219.

[17] D. Wenli, K. Dam-Johansen, K. Ostergaard: The Influence of Additives on Selective Non-Catalytic Reduction of Nitric Oxide with NH3. Beijing: ACHEMASIA (1989).

[18] J.H. Nylander, M.N. Mansour and R.B. Douglas, in: EPA/EPRI Joint Symposium on Stationary Combustion NOx Control, San Francisco (1989), p.35.

DOI: 10.1016/0004-6981(89)90027-9

[19] D.G. Jones, L.J. Muzio, and E. Stocker, et al, in: 82nd APCA Meeting and Exhibition, Anaheim, CA (1989), p.21.

[20] N. Irfan: Control of Gaseous Emissions by Flue Gas Treatment (The University of Leads, Leeds 1995).

[21] Q. Li, Y.X. Wu and H.R. Yang, et al: CIESC Journal Vol. 64 (2013), p.1789.

[22] R.K. Lyon: International Journal of Chemical Kinetics Vol. 8 (1976), p.315.

[23] X. Huang, H. Liu and S.H. Wu, et al: Power System Engineering Vol. 24 (2008), p.12.

[24] D. Wu, G.X. Zhang and Z.H. Chi, et al: Power System Engineering Vol. 28 (2012), p.14.

[25] T. Lu, S.Y. Jia and X.Y. Li: Modern Electric Power Vol. 21 (2004), p.17.

[26] Y. Su: Cogeneration Power Technology Vol. 102 (2009), p.40.

[27] K. Xiang: Thermal Power Generation Vol. 40 (2011), p.1.

[28] Y.G. Zhou and S.G. Wang: Thermal Power Generation Vol. 41 (2012), p.1.

[29] X.F. Cai and X.Y. Li: Electric Power Environmental Protection Vol. 24 (2008), p.26.

[30] S.L. Chen, R.K. Lyon and W.R. Seeker: Environ. Progress Vol. 10 (1991), p.182.

[31] M.U. Alzueta, H. Rojel and P.G. Kristensen, et al: Energy Fuels Vol. 11 (1997), p.716.

[32] X.H. Han, X.L. Wei and U. Schnell, et al: Combustion and Flame Vol. 132 (2003), p.374.

[33] W.X. Wang, Z.J. Xiao and H.X. Xia: Electric Equipment Vol. 7 (2006), p.1.

[34] J.G. Kuang: Study of Technical Theory of High Efficiency Air Staging Combustion Controling NOx Emissions (Shanghai Jiao Tong University, Shanghai 2010).

[35] P.Q. Liu: Simulation Research of Denitration in a 450t/H Boiler by Combining Air Classification and SNCR Technology (Harbin Institute of Technology, Harbin 2013).