Paper Titles

Experimental Studies on Enhanced Coagulation of Tail Water
p.1478

Gasoline Vapor Recovery Based on Integrated Technology of Absorption-Adsorption
p.1482

Treatment of UDMH Waste Water by Microwave Catalytic Oxidation Process
p.1486

Effect of PH on PCP Remediation by Smectite Supported Pd⁰/Fe⁰
p.1490

A Review on Research of Carbonaceous and Carbon-Supported Sorbents for Flue Gas Desulfurization
p.1497

A Type of Rainwater Ecological Treatment Technology: Rainwater Biofiltration System
p.1502

Elaboration and Characterization of an Activated Carbon from Diss and Esparto Grass for the Wastewater Treatment
p.1508

Removal of Astrazon Yellow 7GL from Aqueous Solutions by Adsorption onto Waste Wood Powder: Kinetic and Equilibrium Studies
p.1515

Experimental Research on the Emission Characteristics of City Taxies
p.1529

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 295-298A Review on Research of Carbonaceous and...

A Review on Research of Carbonaceous and Carbon-Supported Sorbents for Flue Gas Desulfurization

Article Preview

Abstract:

The development of flue gas desulphurization technologies and the control and reduction of SO2 pollution from coal combustion have become a hot research topic due to environmental concerns. Carbonaceous and carbon supported desulfurizing sorbents have highly porous structures, large specific surface area and low production costs and can be widely used as desulfurizer. This paper provides a comprehensive review of carbonaceous and carbon-based desulfurizing sorbents, including active components, compositions of raw gas and effects of process operation conditions. It can be concluded that the use of char supported metal desulfurizing sorbents for removing sulfur dioxide from flue gas is a promising technology. Different aspects of applications of carbonaceous and carbon-supported desulfurization sorbents are discussed in detail.

You might also be interested in these eBooks

Progress in Environmental Protection and Processing of Resource

Info:

Periodical:

Applied Mechanics and Materials (Volumes 295-298)

Pages:

1497-1501

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.295-298.1497

Citation:

Cite this paper

Online since:

February 2013

Authors:

Jin Xiao Dou, Jiang Long Yu, Chao Ling Song, Feng Kui Yin

Keywords:

Activated Carbon, Activated-Char, Flue Gas Desulfurization, Supported Sorbent

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

© 2013 Trans Tech Publications Ltd. All Rights Reserved

Share:

Citation:

[1] Z.H. Li,G.J. Shang and C.H. Li: Journay of Taiyuan University of Technology. Vol. 33(2002), p.179.

[2] C. Moreno-Castilla, F. Carrasco-Marin and E. Utrera-Hidalgo: Langmuir. Vol. 9(1993), p.1378.

[3] Y. Liu Z.D. Cao,Q. Tang and S. Wang: Journal of Xi'an Jiaotong University. Vol. 38(2004), p.73.

[4] C.S. Zhang and M.J. Shao: J. Chin. Electr. Microse. Soc. Vol. 23(2004), p.459.

[5] X.M. Shan, M.H. Du, S.Q. Zhu and W.H. Zhang: Coal Conversion. Vol. 26(2003), p.32.

[6] P. Davini: Carbon. Vol. 39(2001), p.419.

[7] P. Davini: Carbon. Vol. 28(1999), p.565.

[8] K.X. Li,L.C. Ling,L. Liu B.J. Zhang and Z.Y. Liu: Acta Scientiae Circumstantiae. Vol. 21(2001), p.74.

[9] A. Lisovskii,R. Semiat and C. Aharont: Carbon. Vol. 35(1997), p.1639.

[10] C.H. He,J.M. Zheng and X.Q. Ruan: Chemical Industry and Engineering. Vol. 19(2002), p.96.

[11] P. Davini: Carbon. Vol. 31(1993), p.47.

[12] H.Y. Shao: A study on SO2 and NO removal with activated-carbon in circulating fluidized bed, Master Thesis. Shandong University. (2008).

[13] J.W. Wang Z.D. Cao and Z.G. Zhang: Boiler Technology. Vol. 35(2004), p.67.

[14] Q. Tang and Z.G. Zhang: Thermal Power Generation. Vol. 12(2003), p.53.

[15] Q. Tang: Experimental investigation of the SO2 and NOx binary gas competitive adsorption, Master Thesis. Xian Jiaotong University. (2003).

[16] Y.G. Luo D.Q. Li and Y.P. Yang: Journal of engineering for thermal energy and power. Vol. 16(2001), p.444.

[17] I. Mochida,K. Kuroda and S. Miyamoto: Energy&Fuel. Vol. 11(1997), p.272.

[18] A. A. Lizzio and J. A DeBarr: Fuel. Vol. 75(1996) , p.1515.

[19] K.X. Li,L.C. Ling,Y. Song,L. Liu B.J. Zhang and Z.Y. Liu: Environmental Chemistry. Vol. 18(1999) p.205.

[20] S.J. Liu, Z.Y. Liu, Z.P. Zhu and H.X. Niu: Coal Conversion. Vol. 23(2000), p.53.

[21] S.J. Liu Z.Y. Liu Z.P. Zhu and H.X. Niu: Environmental Science. Vol. 21(2000), p.32.

[22] X.M. Fei: Removal of low concentration SO2 with activated-carbon, Master Thesis, Dalian University of Tcchnolygy. (2006).

[23] P.Y. Zhang: Denitrification and adsorption of mercury by catalytic activated-carbon, Master Thesis, Huazhong University of Science and Technlogy. (2004).

[24] G.J. Shang,Z. Yang and M.Q. Miao: Journal of Taiyuan University of Technology. Vol. 38 (2007), p.229.

[25] S.Y. Zhang T.Y. Zhu Z.Y. Yang,H. Lu,J.J. Huang and Y. Wang: Jouranl of Combustion Science and Technology. Vol. 8(2002), p.38.

[26] Q.Y. Liu C.H. Li and Y.X. Li: Carbon. Vol. 41(2003), p.2217.

[27] W.T. Wang C.H. Li and Z.F. Yan: Catalysis Today. 158(2010), p.235.

[28] J. Yu, F. Yin, S. Wang, L. Chang and S. Gupta. Fuel, 2013 (In press).

[29] Y.M. Yu, R.L. Guo and C.H. Li: Journal of Fuel Chemistry and Technology. Vol. 39(2011), p.385.