Performance of palm shell activated carbon impregnated with CeO2 and V2O5 catalyst in simultaneous removal of So2 and NO

Journal of Applied Sciences

Volumn 10, Issue 12, 2010, Pages 1052-1059

  Sumathi, S ^a   Bhatia, S ^a   Lee, K T ^a   Mohamed, A R ^a  

^a SCHOOL OF CHEMICAL ENGINEERING   (Malaysia)

Author keywords

Cerium; No; Palm shell; Simultaneous; Vanadium

Indexed keywords

ACTIVATED CARBON; CALCINATION; CERIUM; NOBELIUM; SORPTION; SULFUR DIOXIDE;

CALCINATION PROCEDURES; CALCINATION TEMPERATURE; PALM SHELL; PALM SHELL-ACTIVATED CARBON; SIMULTANEOUS; SIMULTANEOUS REMOVAL; SORPTION CAPACITIES; WEIGHT PERCENTAGES;

VANADIUM;

EID: 77953490386     PISSN: 18125654     EISSN: 18125662     Source Type: Journal    
DOI: 10.3923/jas.2010.1052.1059     Document Type: Article

References (42)

1. Aroua, M.K., W.M.A.W. Daud, C.Y. Yin and D. Adinata, 2008. Adsorption capacities of carbon dioxide, oxygen, nitrogen and methane on carbon molecular basket derived from polyethyleneimine impregnation on microporous palm shell activated carbon. Separation Purification Technol., 62: 609-613.
2. 2 sorbent. Ph.D. Thesis, Universiti Sains Malaysia.
3. x adsorption properties of activated carbons obtained from a pitch containing iron derivatives. Carbon, 39: 2173-2179.
4. 2 activation for removal of gaseous pollutants. Mater. Lett, 55: 334-339.
5. Guo, J. and A.C. Lua, 2002b. Microporous activated carbons prepared from palm shell by thermal activation and their application to sulphur dioxide adsorption. J. Coll. Interface Sci., 251: 242-247.
6. 2S) by activated carbons derived from oil-palm shell. Carbon, 45: 330-336.
7. x reduction by carbon infporting metals. Applied Catalysis B: Environ., 20: 267-275.
8. Ioannidou, O. and A. Zabaniotou, 2007. Agricultural residues as precursors for activated carbon production - A review. Renewable Sustainable Energy Rev., 11: 1966-2005.
9. Ishizuka, T., H. Tsuchiai, T. Murayama, T. Tanaka and H. Hattori, 2000. Preparation of active adsorbent for dry-type flue gas desulfurization from calcium oxide, coal fly ash and gypsum. Ind. Eng. Chem. Res., 39: 1390-1396.
10. 2-based oxides in the three-way catalysis. Catalysis Today, 50: 285-298.
11. Klose, W. and S. Rincon, 2007. Adsorption and reaction of NO on activated carbon in the presence of oxygen and water vapour. Fuel, 86: 203-209.
12. 3 as reducing agent. Fuel, 83: 875-884.
13. Lazaro, M.J., M.E. Galvez, C. Ruiz, R. Juan and R. Moliner, 2006. Vanadium loaded carbon-based catalysts for the reduction of nitric oxide. Applied Catalysis B: Environ., 68: 130-138.
14. 2/silica fume sorbents for low-temperature flue gas desulfurization. Chem. Eng. Sci., 58: 3659-3668.
15. 3 catalyst. Catalysis Today, 147: S285-S289.
16. Lua, A.C. and J. Guo, 2001. Preparation and characterization of activated carbons from oil-palm stones for gas-phase adsorption. Coll. Surfaces A: Physicochem. Eng. Aspects, 179: 151-162.
17. 2 removal. Fuel Process. Technol, 89: 242-248.
18. x with NH3 over nomex TM rejects-based activated carbon fiber composite-infported manganese oxides Part II. Effect of procedures for impregnation and active phase formation. Applied Catalysis B: Environ., 34: 55-71.
19. Mehandjiev, D., M. Khristova and E. Bekyarova, 1996. Conversion of NO on Co-impregnated active carbon catalysts. Carbon, 34: 757-762.
20. Mehandjiev, D., E. Bekyarova and M. Khristova, 1997. Study of Ni-impregnated active carbon II. Catalytic behaviour in NO conversion. J. Coll. Interface Sci., 192: 440-446.
21. x over activated carbon fibers. Carbon, 38: 227-239.
22. Muniz, J., G. Marban and A.B. Fuertes, 1999. Low temperature selective catalytic reduction of NO over polyarylamide-based carbon fibers. Applied Catalysis B: Environ., 23: 25-35.
23. x emissions from coal combustion by calcium magnesium acetate. Fuel, 83: 149-155.
24. x. Bull. Chem. Soc. Jap., 53: 3356-3360.
25. 2 reduction. Environ. Sci. Technol., 42: 2509-2514.
26. 2 catalyst. J. Catalysis, 217: 434-441.
27. 2 and NO selective adsorption properties of coal-based activated carbons. Fuel, 84: 461-465.
28. x reaction. Catalysis Today, 107-108: 168-174.
29. Rodriguez-Reinoso, F., 1998. The role of carbon materials in heterogeneous catalysis. Carbon, 36: 159-175.
30. 2 highly dispersed on activated carbon. Mater. Res. Bull., 43: 1850-1857.
31. Sumathi, S., S. Bhatia, K.T. Lee and A.R. Mohamed, 2009a. Optimization of microporous palm shell activated carbon production for flue gas desulphurization: Experimental and statistical studies. Bioresour. Technol, 100: 1614-1621.
32. x of flue gas at low temperature. Sci. China Series E: Technol. Sci., 52: 198-203.
33. 2 and NO simultaneous removal from simulated flue gas over cerium-infported palm shell activated at lower temperatures-role of cerium on NO removal. Energy Fuels, 24: 427-431.
34. 2. Fuel, 88: 1687-1691.
35. x reduction. 1. Preparation and characterization of coal char impregnated with model vanadium components and petroleum coke ash. Fuel, 81: 1281-1296.
36. 2 and NO removal. Chem. Eng. Sci., 59: 5283-5290.
37. 2 and NO removal at low temperatures. Carbon, 42: 423-460.
38. Zazo, J.A., A.F. Fraile, A. Rey, A. Bahamonde, J.A. Casas and J.J. Rodriguez, 2009. Optimizing calcination temperature of Fe/activated carbon catalysts for CWPO. Catalysis Today, 143: 341-346.
39. 2 and NO from flue gas with calcium-based sorbent at low temperature. Ind. Eng. Chem. Res., 45: 6099-6103.
40. 3 at low temperatures. Applied Catalysis B: Environ., 23: L229-L233.
41. 3 over an activated carbon-infported copper oxide catalysts at low temperatures. Applied Catalysis B: Environ., 26: 25-35.
42. 2 on modified activated carbon sorbent from flue gases. Energy Conversion Manage., 46: 2173-2184.