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Current Management Status of Mercury Emissions from Coal Combustion Facilities: International Regulations, Sampling Methods, and Control Technologies  

Lee, Sung-Jun (Department of Chemical Engineering, University of Utah, Salt Lake City)
Pudasainee, Deepak (Department of Environmental Engineering, Yonsei University)
Seo, Yong-Chil (Department of Environmental Engineering, Yonsei University)
Publication Information
Journal of Korean Society for Atmospheric Environment / v.24, no.E1, 2008 , pp. 1-11 More about this Journal
Abstract
Mercury (Hg), which is mainly emitted from coal-fired power plants, remains one of the most toxic compounds to both humans and ecosystems. Hg pollution is not a local or regional issue, but a global issue. Hg compounds emitted from anthropogenic sources such as coal-fired power plants, incinerators, and boilers, can be transported over long distances. Since the last decade, many European countries, Canada, and especially the United States, have focused on technology to control Hg emissions. Korea has also recently showed an interest in managing Hg pollution from various combustion sources. Previous studies indicate that coal-fired power plants are one of the major sources of Hg in Korea. However, lack of Hg emission data and feasible emission controls have been major obstacles in Hg study. In order to achieve effective Hg control, understanding the characteristics of current Hg sampling methods and control technologies is essential. There is no one proven technology that fits all Hg emission sources, because Hg emission and control efficiency depend on fuel type, configuration of air pollution control devices, flue gas composition, among others. Therefore, a broad knowledge of Hg sampling and control technologies is necessary to select the most suitable method for each Hg-emitting source. In this paper, various Hg sampling methods, including wet chemistry, dry sorbents trap, field, and laboratory demonstrated control technologies, and international regulations, are introduced, with a focus on coal-fired power plants.
Keywords
Mercury (Hg); Hg sampling method; Hg control technology; Coal-fired power plants; Coal combustion; Air Pollution Control Devices (APCDs);
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  • Reference
1 Brunette, B., E. Prestbo, and N. Bloom (2004) Mercury speciation in coal combustion flue gas: Flue gas Adsorbent Mercury Speciation (FAMS) method, DOE/NETL Hg Measurements Workshop, Pittsburgh, PA, July 13, 2004
2 Chang, J.C.S. and S.B. Ghorishi (2003) Simulation and evaluation of elemental mercury concentration increase in flue gas across a wet scrubber, Environmental Science and Technology, 37, 5763-5766   DOI   ScienceOn
3 Laudal, D.L., J.S. Thompson, J.H. Pavlish, L.A. Brickett, and P. Chu (2004) Use of continuous mercury monitors at coal-fired utilities, Fuel Process. Technol., 85, 501-511   DOI   ScienceOn
4 Lee, C.W., R.K. Srivastava, S.B. Ghorishi, J. Karwowski, T.W. Hastings, and J.C. Hirschi (2006) Pilot- Scale study of the effect of selective catalytic reduction catalyst on mercury speciation in Illinois and powder river basin coal combustion flue gases, J. of Air & Waste Manage. Assoc., 56, 643-649   DOI   ScienceOn
5 Schmid, V. (2002) Continuous monitoring of mercury emission from stationary sources, Clean Air Engineering Inc. http://www.epamethod324. com/Reference/Library/publications/MercuryM onitoring.pdf
6 UNEP (United Nations Environment Programme) (2002) Chemicals, global mercury assessment, http:// www.chem.unep.ch/mercury/
7 US EPA (2005b) Control of mercury emission from coal fired electric utility boilers: an update, http:// www.epa.gov/ttn/atw/utility/ord_whtpaper_hgc ontroltech_oar-2002-0056-6141.pdf
8 Meischen, S.J., V.J.V. Pelt, E.A. Zarate, and E.A. Stephens Jr. (2004) Gas-phase mercury reduction to measure total mercury in the flue gas of a coal-fire boiler, J. of Air & Waste Manage. Assoc., 54, 60-67   DOI   ScienceOn
9 Senior, C.L. (2006) Oxidation of Hg across selective catalytic reduction catalysts in coal-fired power plants, J. of Air & Waste Manage. Assoc., 56, 23-31   DOI   ScienceOn
10 Lee, S.J., J.O.L. Wendt, and J. Biermann (2007) High temperature Sequestration of Elemental Mercury by Non-Carbon Based Sorbents, 6th International Symposium on Coal Combustion (ISCC), Wuhan, China, Dec. 1-4
11 Granite, E.J. and H.W. Pennline (2002) Photochemical removal of mercury from flue gas, Ind. Eng. Chem. Res., 41, 5470-5476   DOI   ScienceOn
12 US EPA, draft method 324 (2004b) Determination of vapor phase flue gas mercury emission from stationary sources using dry sorbent trap sampling, 40 CFR Part 75, Appendix K. http:// www.epa.gov/ttn/emc/proposed/m-324.pdf
13 US EPA (2002) Control of mercury emissions from coalfired electric utility boilers, EPA-600/R-01-109, http://www.epa.gov/ttn/atw/utility/ord_whtpaper _hgcontroltech_oar-2002-0056-6141.pdf
14 Linak, W.P., J.V. Ryan, B.S. Ghorishi, and J.O.L. Wendt (2001) Issues related to solution chemistry in mercury sampling impingers, J. of Air & Waste Manage. Assoc., 51, 688-698   DOI   ScienceOn
15 US EPA (1997) Mercury study report to congress, an inventory of anthropogenic mercury emissions in the United States-volume II, EPA-452/R-97- 004
16 Yang, H.-M. and W.-P. Pan (2007) Transformation of mercury speciation through the SCR system in power plants, J. Env. Sci., 19, 181-184   DOI   ScienceOn
17 Gutberlet, H. and J. Tembrink (2004) Dry sampling method used by E.ON for mercury speciation in flue gas, DOE/NETL & EPRI sponsored mercury measurements workshop, Pittsburgh, PA, Jul. 2004
18 European Union (EU) (2001) Ambient air pollution by mercury (Hg), Position Paper. http://www. europa.eu.int/comm/environment/chemicals/mer cury/index.htm
19 Laudal, D.L., J.S. Thompson, and C.A. Wocken (2004) JV 36-selective catalytic reduction mercury field sampling project, final report, http://www.netl. doe.gov/coal/E&WR/mercury/pubs/FINALT36. PDF
20 Gibb, W., W. Quick, and M. Salisbury (2003) Technology status review-monitoring and control of traceelements, Department of Trade and Industry (DTI), United Kingdom, http://www.dti.gov. uk/ energy/coal/cfft/cct/pub/pdfs/r249a.pdf
21 US EPA (2004a) EPA-FDA Joint federal advisory for mercury in Fish: "What you need to know about mercury in fish and shellfish." http://www.epa. gov/mercury/advisories.htm
22 DOE (2004) JV 36- Selective catalytic reduction mercury field sampling project? Final Report, 04-EERC- 09-01
23 Niksa, S. and N. Fujiwara (2005) A predictive mechanism for mercury oxidation on selective catalytic reduction catalyst under coal-derived flue gas, J. of Air & Waste Manage. Assoc., 55, 1866-1875   DOI   ScienceOn
24 DOE/EPRI (1996) A state-of-the art review of flue gas mercury speciation method, EPRI Report No. TR-107080
25 US EPA (2005a) News release-EPA announces first-ever rule to reduce mercury emissions from power plants, http://www.epa.gov/air/mercuryrule/ rule. htm
26 US EPA (1998) Study of hazardous air pollutant emissions from electric utility steam generating units; final report to congress 453/R-98-004a & b, http:// www.epa.gov/ttncaaa1/t3/reports/ eurtc2.pdf