Physicochemical and radiological characterization of flue gas desulfuration waste samples from Brazilian coal-fired power plants

Authors

  • Denise Fungaro Instituto de Pesquisas Energéticas e Nucleares
  • Lucas Grosche Instituto de Pesquisas Energéticas e Nucleares
  • Paulo Silva Instituto de Pesquisas Energéticas e Nucleares

DOI:

https://doi.org/10.15392/2319-0612.2023.2275

Keywords:

Coal combustion, FGD waste, Characterization

Abstract

Flue gas desulfurization (FGD) waste is an industrial by-product generated during the flue gas desulfurization process in coal-fired power plants. This by-product contain trace quantities of naturally occurring radionuclides and elements such as As, Ba, Co, Cr, Zn. The characteristics of FGD waste are important for its reuse and are mainly depend on the desulfurization process. In this work, two types of FGD materials collected from three coal-fired power plants using semi-dry and wet processes were characterized by X-Ray Diffraction (XRD), Scanning Electron Microscope (SEM), X-ray fluorescence (XFR) and particle size analysis. The radioactive content of 238U, 232Th, 228Th, 226Ra, 228Ra, 210Pb and 40K and trace elements were also determined using Neutron activation analysis and Gamma-ray spectrometry. The major constituents for all samples were Ca, Si, S, Al and Fe. Wet FGD by-product presented also high magnesium content. The wastes contain mainly semi-hydrate calcium sulfite and calcium sulfate. The particle size of FGD from semi-dry process was lower than that from the wet process. The average activity concentration of 238U, 232Th, 226Ra, 210Pb, 228Ra, 228Th and 40K varied between were 50-71, 33-42, 28-52, 113-150, 26-33, 33-39, 161-390 Bq kg-1, respectively. According to the results of leaching and solubilization tests, FGD samples were classified as non-hazardous and non-inert. The obtained data are useful for evaluation of possible applications of FGD by-products.

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References

CÓRDOBA, P. Status of Flue Gas Desulphurisation (FGD) systems from coal-fired power plants: Overview of the physic-chemical control processes of wet limestone FGDs. Fuel, v. 144, p. 274-286, 2015.

CASTRO, R. P. V; MEDEIROS, J. L.; ARAÚJO, O. Q. F.; CRUZ, M. A.; RIBEIRO, G. T.; OLIVEIRA, V. R. Fluidized bed treatment of residues of semi-dry flue gas desulfurization units of coal-fired power plants for conversion of sulfites to sulfates. Energy Convers Manag, v. 143, p. 173-187, 2017.

BIGHAM, J. M.; KOST, D. A.; STEHOUWER, R. C.; BEEGHLY, J. H.; FOWLER, R.; TRAINA, S. J.; WOLFE, W. E.; DICK, W. A. Mineralogical and engineering characteristics of dry flue gas desulfurization products. Fuel, v. 84, p. 1839-1848, 2005.

SHENG, G .H.; HUANG, P.; MOU, Y. Q.; ZHOU, C. H. Characteristics of fly ash from the dry flue gas desulfurization system for iron ore sintering plants. Environ Technol, v. 33, p. 837-844, 2012.

FUNGARO, D. A.; GROSCHE, L. C.; IZIDORO, J. C. Synthesis of Calcium Silicate Hydrate Compounds From Wet Flue Gas Desulfurization (FGD) Waste. J Appl Mater Technol, v. 1, p. 88–95, 2020.

GROSCHE, L. C.; BERTOLINI, T. C. R.; FUNGARO, D. A., Alkaline Hydrothermal Treatment of the Waste Produced in the Semi-Dry Flue Gas Desulfurization System. Int J Adv Res Chem Sci, v. 5, p. 9-19, 2018.

ROPER, A. R.; STABIN, M. G.; DELAPP, R. C.; KOSSON, D. S. Analysis of Naturally-occurring Radionuclides in Coal Combustion Fly Ash, Gypsum, and Scrubber Residue Samples. Health Phys, v.104, p. 264-269, 2013.

ROPER, A. R. Analysis of naturally occurring radionuclides in fly ash and gypsum samples. Master of Science. Vanderbilt University. 2012.

TAHA, R. Environmental and engineering properties of flue gas desulfurization gypsum. Transp Res Rec, p. 14-19, 1993.

ABNT NBR 10005 - Brazilian Association of Technical Standards - Leaching Tests, Rio de Janeiro, Brazil, p. 10, 2004.

ABNT NBR 10006 - Brazilian Association of Technical Standards - Solubilization Tests, Rio de Janeiro, Brazil, p. 2, 2004.

IAEA - International Atomic Energy Agency. Practical aspects of operating a neutron analysis laboratory. IAEA –TECDOC- 564, Vienna: IAEA, 1999, 252p.

CUTSHALL, N. H.; LARSER, I. L.; OLSEN, C. R. Direct analysis of 210Pb in sediment samples: self-absorption corrections. Nucl Instrum Methods Phys Res, v. 206, p. 309-312, 1983.

UNSCEAR - United Nations Scientific Committee on Effects of Atomic Radiation. Sources and effects of ionizing radiation. Exposures from Natural Radiation Sources, Annex B. New York: United Nations Publication, 2000.

KARDOS, R.; SAS, Z.; HEGEDUS, M.; SHAHROKHI, A.; SOMLAI, J.; KOVACS, T. Radionuclide content of NORM by-products originating from the coal-fired power plant in Oroszlány (Hungary). Radiat Prot Dosim, v. 167, p.266-269, 2015.

CÓRDOBA, S. P. Partitioning and speciation of trace elements at two coalfired power plants equipped with a wet limestone Flue Gas Desulphurisation (FGD) systems. Thesis. Universitat Politècnica de Catalunya. 2013.

CÓRDOBA, P. Partitioning and speciation of selenium in wet limestone flue gas desulphurisation systems: A review. Fuel, v. 202, p. 184-195, 2017.

FGD HANDLING - Review of handling and use of FGD material. CARRC Topical Report. U.S. Department of Energy. 2003. 43p.

KOST, D. A; BIGHAM, J. M.; STEHOUWER, R.C.; BEEGHLY, J.H.; FOWLER, R.; TRAINA, S. J.; WOLFE, W. E.; DICK, W. A. Chemical and physical properties of dry flue gas desulfurization products. J Environ Qual, v. 34 p. 676-686, 2005.

EPRI - A Review of Literature Related to the Use of Spray Dryer Absorber Material: Production, Characterization, Utilization Applications, Barriers, and Recommendations. Technical Report, ND: 1014915. 2007, 108 p.

DEPOI, F. S.; POZEBON, D.; KALKREUTH, W. D. Chemical characterization of feed coals and combustion-by-products from Brazilian power plants. Int J Coal Geol, v. 76, p. 227-236, 2008.

HANSEN, B. B.; KIIL, S., Investigation of Parameters Affecting Gypsum Dewatering Properties in a Wet Flue Gas Desulphurization Pilot Plant. Ind Eng Chem Res, v. 51, p. 10100-10107, 2012.

BAKSHI, P.; PAPPU, A; GUPTA, M. K. Flue Gas Desulphurization (FGD) Gypsum Waste -Recycling Opportunity. In: Annual Technical Volume on "Technologies for Zero Waste in India: Current and Future Challenges", Environmental Engineering Division Board, ISBN: 978-81-952159-4-2, 2021, p. 68-73.

WANG, X.; WANG, L.; WANG, Y.; TAN, R.; KE, X.; ZHOU, X.; GENG, J.; HOU, H.; ZHOU, M. Calcium Sulfate Hemihydrate Whiskers Obtained from Flue Gas Desulfurization Gypsum and Used for the Adsorption Removal of Lead. Crystals, v. 7, p. 270-290, 2017.

ABNT BR 10004 - Brazilian Association of Technical Standards - Solid Waste - Classification, Rio de Janeiro, Brazil, p. 16, 2004.

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Published

2023-06-26

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How to Cite

Physicochemical and radiological characterization of flue gas desulfuration waste samples from Brazilian coal-fired power plants. Brazilian Journal of Radiation Sciences, Rio de Janeiro, Brazil, v. 11, n. 2, p. 1–18, 2023. DOI: 10.15392/2319-0612.2023.2275. Disponível em: https://bjrs.org.br/revista/index.php/REVISTA/article/view/2275.. Acesso em: 22 nov. 2024.

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