The Research of SCR Catalyst for Elemental Mercury Conversion in Coal-Fired Flue Gas

Qiang Zhang; Wei Guo Pan; Rui Tang Guo

doi:10.4028/www.scientific.net/AMR.864-867.1470

Paper Titles

Removal of Phosphate Anions from Aqueous Solutions Using Dolomite as Adsorbent
p.1454

Experimental Research of Spouted Particulate Electrodes on Removal of Copper Wastewater
p.1458

Study on the Treatment of Nickel-Containing Wastewater by Spouted Bed Particulate Electro-Deposition
p.1462

Countermeasures of Non-Point Source Pollution Prevention and Control in Wohushan Waterhead Area
p.1466

The Research of SCR Catalyst for Elemental Mercury Conversion in Coal-Fired Flue Gas
p.1470

Review of Denitration by SNCR in Cement Kilns
p.1474

Treatment of Simulated Ballast Water Using Combined Photocatalysis and Ozonation Process
p.1478

A Short Review of the Effect of Temperature on Soluble Microbial Products in the Membrane Bioreactor Systems
p.1482

Laboratory Investigation of the Phosphorus Removal of Two Aquatic Plants
p.1486

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 864-867The Research of SCR Catalyst for Elemental Mercury...

The Research of SCR Catalyst for Elemental Mercury Conversion in Coal-Fired Flue Gas

Abstract:

To control mercury pollution has become a major issue nowadays. The SCR systems in power plant can oxide the elemental mercury into oxidized mercury, which can be removed by WFGD, it became a very feasible measures to control mercury pollution. The core part of SCR system is SCR catalyst. The influence of different metal composition and modification of SCR catalyst and the gas composition in simulative flue gas for the efficiency of the conversion of elemental mercury are introduced ,for sifting the catalyst with high efficiency for mercury conversion under the condition of low temperature.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Advanced Materials Research (Volumes 864-867)

Pages:

1470-1473

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.864-867.1470

Citation:

Cite this paper

Online since:

December 2013

Authors:

Qiang Zhang*, Wei Guo Pan, Rui Tang Guo

Keywords:

Catalyst, Low Temperature, Mercury Conversion, SCR

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] YanCao: Energy Fuels, Vol21, Issue 1, 2007 : 145-156.

Google Scholar

[2] Niksa, Fujiwara: Journal of the Air and Waste Management Association, Vol55 , Issue 12, 2002: 1866～1875.

Google Scholar

[3] EomY, Jeon S H, Ngo T A: Catal Lett, Vol121, 2008: 219-225.

Google Scholar

[4] YiZhao, XiaojieMa: Industrial Safety and Environmental Protection, Vol35, Issue 3, 2009: 14-16.

Google Scholar

[5] QianWang: Boiler technology, Vol1, 2008: 69-76.

Google Scholar

[6] QirongWu, YunguiDu, HuaNie: Thermal Power Generation, Vol41, Issue 1, 2012: 8-11.

Google Scholar

[7] HongminYang, WeipingPan: Journal of environment sciences, Vol19, 2007: 181-184.

Google Scholar

[8] Sheng He．experiment and mechanism research of mercury catalytic oxidation in coal-fired flue gas, inchinese[D] . zhejiang university, (2009).

Google Scholar

[9] HongtaoLiu: oxidation and adsorption experiments of mercury in the SCR system, in chinese[D]. huazhong university of science and technology, (2007).

Google Scholar

[10] JieChen: study on zero-valent mercury catalytic oxidation of titanium matrix composite catalyst, inchinese[D]. Shanghai Jiao Tong University, (2011).

Google Scholar

[11] Jianfeng Li: Chinese Journal of Environmental Engineering, inchinese, Vol4, Issue5, 2010: 1143-1146.

Google Scholar

[12] Jianfeng Li, NaiqiangYan : Environ. Sci. Technol, Vol44, 2012: 426-431.

Google Scholar

[13] HiroyukiK, ShunU, Naoki S: Fuel Processing Technology, Vol90, 2009: 947-951.

Google Scholar

[14] Naiqiang Yan : Environmental Science & Technology, Vol45, 2011: 5723-5730.

Google Scholar

[15] HailongLi: Environmental Science & Technology, Vol45, 2011: 7394-7400.

Google Scholar

[16] QiWan, LeiDuan: Catalysis Today, Vol175, 2011: 189– 195.

Google Scholar

[17] JiangkunXie, NaiqiangYan: ResChemIntermed, Vol38, 2012: 2511–2522.

Google Scholar