Status of Flue Gas Desulphurisation (FGD) systems from coal-fired power plants: Overview of the physic-chemical control processes of wet limestone FGDs
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[1] G. H. Babcock,et al. Steam / its generation and use , 1972 .
[2] M. Hartman,et al. Reaction of Sulfur Dioxide with Limestone and the Influence of Pore Structure , 1974 .
[3] The Effect of Additives on Mass Transfer in CaCO3 or CaO Slurry Scrubbing of SO2 from Waste Gases , 1977 .
[5] Effect of aluminum(3+) and fluoride(1-) ions on desulfurization reaction in the limestone slurry scrubbing process , 1981 .
[6] D. Semmingsen,et al. Neutron diffraction refinement of the structure of gypsum, CaSO4.2H2O , 1982 .
[7] Buffer Additives for Lime/Limestone Slurry Scrubbing , 1982 .
[9] J. I. Joubert,et al. Combined SO2/NOx removal from flue gas , 1985 .
[10] Roger D. Griffin,et al. A new theory of dioxin formation in municipal solid waste combustion , 1986 .
[11] R. Farmer,et al. EFFECTS OF ALUMINUM/FLUORIDE CHEMISTRY IN WET LIMESTONE FLUE GAS DESULFURIZATION , 1989 .
[12] Utilization of adipic acid byproducts for energy recovery and enhancement of flue gas desulfurization , 1989 .
[13] R. Meij. The fate of mercury in coal-fired power plants and the influence of wet flue-gas desulphurization , 1991 .
[14] Growth and Structure Refinement of CaSeO4×2 H2O. , 1991 .
[15] The effects of fluoride complexes in wet limestone flue gas desulfurization , 1992 .
[16] L. Clarke,et al. The fate of trace elements during coal combustion and gasification: an overview☆ , 1993 .
[17] Mitsuru Takeshita,et al. FGD performance and experience on coal-fired plants , 1993 .
[18] W. Pan,et al. Behavior of chlorine during coal pyrolysis , 1994 .
[19] Ruud Meij,et al. Trace element behavior in coal-fired power plants , 1994 .
[20] Kurt E. Eylands,et al. High-calcium coal combustion by-products: Engineering properties, ettringite formation, and potential application in solidification and stabilization of selenium and boron , 1995 .
[21] W. Dick,et al. Minespoil amendment with dry flue gas desulfurization by-products : plant growth , 1995 .
[22] Marko Gerbec,et al. Simulation model of wet flue gas desulphurization plant , 1995 .
[23] Geoquímica y mineralogía aplicadas a estudios de impacto ambiental derivado de la combustión del carbón , 1995 .
[24] M. Babu,et al. Phase II: The age of high velocity scrubbing , 1996 .
[25] D. Spears,et al. The fate of trace elements and bulk minerals in pulverized coal combustion in a power station , 1996 .
[26] Francesco Pepe,et al. Modeling of SO2 Absorption into Limestone Suspensions , 1997 .
[27] Hans T. Karlsson,et al. Modeling the absorption of SO2 in a spray scrubber using the penetration theory , 1997 .
[28] William E. Wolfe,et al. Use of clean coal combustion by-products in highway repairs , 1997 .
[29] Hans T. Karlsson,et al. A model for prediction of limestone dissolution in wet flue gas desulfurization applications , 1997 .
[30] Michael Luckas,et al. A Heat and Mass Transfer Model for the Simulation of the Wet Limestone Flue Gas Scrubbing Process , 1998 .
[31] Kim Dam-Johansen,et al. Experimental investigation and modeling of a wet flue gas desulfurization pilot plant , 1998 .
[33] Trace Elements in Chinese Coals and their Partitioning During Coal Combustion , 1999 .
[34] A. Sarofim,et al. Emissions of mercury, trace elements, and fine particles from stationary combustion sources , 2000 .
[35] Christopher J. Zygarlicke,et al. Mercury transformations in coal combustion flue gas , 2000 .
[36] R. Meij. Composition and particle size of and exposure to coal fly ash , 2000 .
[37] Jerzy Warych,et al. Model of the Wet Limestone Flue Gas Desulfurization Process for Cost Optimization , 2001 .
[38] R Backman,et al. Trace elements in two pulverized coal-fired power stations. , 2001, Environmental science & technology.
[39] Søren Kiil,et al. Optimisation of a wet FGD pilot plant using fine limestone and organic acids , 2001 .
[40] S. Vassilev,et al. Behaviour of elements and minerals during preparation and combustion of the Pernik coal, Bulgaria , 2001 .
[41] Hirofumi Kikkawa,et al. New wet FGD process using granular limestone , 2002 .
[42] Søren Kiil,et al. Simulation studies of the influence of HCl absorption on the performance of a wet flue gas desulphurisation pilot plant , 2002 .
[43] R. Meij,et al. The Fate and Behavior of Mercury in Coal-Fired Power Plants , 2002, Journal of the Air & Waste Management Association.
[44] S. Kiil,et al. Use of spray dry absorption product in wet flue gas desulphurisation plants: pilot-scale experiments , 2002 .
[45] Steven A. Benson,et al. Status review of mercury control options for coal-fired power plants , 2003 .
[46] Søren Kiil,et al. Experimental investigation of a pilot-scale jet bubbling reactor for wet flue gas desulphurisation , 2003 .
[47] W. Voigt,et al. Crystallization and Phase Stability of CaSO4 and CaSO4 – Based Salts , 2003 .
[48] Xavier Querol,et al. Characterization of Candiota (South Brazil) coal and combustion by-product , 2004 .
[49] Ruud Meij,et al. The emissions and environmental impact of PM10 and trace elements from a modern coal-fired power plant equipped with ESP and wet FGD , 2004 .
[50] Kim Dam-Johansen,et al. Full-scale measurements of SO2 gas phase concentrations and slurry compositions in a wet flue gas desulphurisation spray absorber , 2004 .
[51] Zhongsheng Li,et al. Partitioning behaviour of trace elements in a stoker-fired combustion unit: An example using bituminous coals from the Greymouth coalfield (Cretaceous), New Zealand , 2005 .
[52] Producing Ammonium Sulfate from Flue Gas Desulfurization By-Products , 2005 .
[53] Ruud Meij,et al. Mercury emissions from coal-fired power stations: The current state of the art in the Netherlands. , 2006, The Science of the total environment.
[54] J. Alía,et al. Miscibility in the CaSO4·2H2O–CaSeO4·2H2O system: Implications for the crystallisation and dehydration behaviour , 2006 .
[55] Candace L. Kairies,et al. Mercury in gypsum produced from flue gas desulfurization , 2006 .
[56] V. Cortés,et al. Pilot-Plant Technical Assessment of Wet Flue Gas Desulfurization Using Limestone. , 2006 .
[57] X. Querol,et al. Environmental impact of a coal combustion-desulphurisation plant: abatement capacity of desulphurisation process and environmental characterisation of combustion by-products. , 2006, Chemosphere.
[58] B. Tesser,et al. Proteolysis and Characterization of Peptidases in Forage Plants , 2006 .
[59] X. Querol,et al. Stabilization of FGD gypsum for its disposal in landfills using amorphous aluminium oxide as a fluoride retention additive. , 2007, Chemosphere.
[60] Iztok Hrastel,et al. Technology Optimization of Wet Flue Gas Desulfurization Process , 2007 .
[61] Ruud Meij,et al. The emissions of heavy metals and persistent organic pollutants from modern coal-fired power stations , 2007 .
[62] X. Querol,et al. Study of the use of coal fly ash as an additive to minimise fluoride leaching from FGD gypsum for its disposal. , 2008, Chemosphere.
[63] K. Cen,et al. A model for performance optimization of wet flue gas desulfurization systems of power plants , 2008 .
[64] G. Blythe,et al. Bench-scale Kinetics Study of Mercury Reactions in FGD Liquors , 2008 .
[65] Abdul Jabbar N. Khalifa,et al. Effect of insulation thickness on the productivity of basin type solar stills: An experimental verification under local climate , 2009 .
[66] Qiang Jin,et al. Prediction of SO2 removal efficiency for wet Flue Gas Desulfurization , 2009 .
[67] New Limestone-Gypsum Flue Gas Desulfuization Technology , 2009, 2009 International Conference on Energy and Environment Technology.
[68] W. Pan,et al. Partitioning of mercury, arsenic, selenium, boron, and chloride in a full-scale coal combustion process equipped with selective catalytic reduction, electrostatic precipitation, and flue gas desulfurization systems , 2009 .
[69] Meng Zhang,et al. Hg2+ reduction and re-emission from simulated wet flue gas desulfurization liquors. , 2009, Journal of Hazardous Materials.
[70] M. Horvat,et al. Removal of Hg0 from flue gases in wet FGD by catalytic oxidation with air – An experimental study , 2010 .
[71] J. C. Ballesteros,et al. Use of FGD gypsum in fire resistant panels. , 2010, Waste management.
[72] F. J. Gutiérrez Ortiz. A simple realistic modeling of full-scale wet limestone FGD units , 2010 .
[73] M. Maroto-Valer,et al. Mercury speciation in gypsums produced from flue gas desulfurization by temperature programmed decomposition , 2010 .
[74] G. Zeng,et al. Flue gas desulphurization based on limestone-gypsum with a novel wet-type PCF device , 2011 .
[75] A. Tobías,et al. Enrichment of inorganic trace pollutants in re-circulated water streams from a wet limestone flue ga , 2011 .
[76] X. Querol,et al. Unusual speciation and retention of Hg at a coal-fired power plant. , 2012, Environmental science & technology.
[77] C. Romero,et al. Study of elemental mercury re-emission in a simulated wet scrubber , 2012 .
[78] Xavier Querol,et al. Partitioning of trace inorganic elements in a coal-fired power plant equipped with a wet Flue Gas Desulphurisation system , 2012 .
[79] Myung Gyu Lee,et al. Mineral carbonation of flue gas desulfurization gypsum for CO2 sequestration , 2012 .
[80] P. Solà. Partitioning and speciation of trace elements at two coal-fired power plants equipped with a wet limestone flue gas desulphurisation (FGD) system. , 2013 .
[81] X. Querol,et al. Influence of an aluminium additive in aqueous and solid speciation of elements in flue gas desulphurisation (FGD) system , 2013 .
[82] Control of Hg0 re-emission from gypsum slurries by means of additives in typical wet scrubber conditions , 2013 .
[83] G. Scheffknecht,et al. Impact of additives for enhanced sulfur dioxide removal on re-emissions of mercury in wet flue gas desulfurization , 2014 .
[84] Xinhua Xu,et al. The relationship between speciation and release ability of mercury in flue gas desulfurization (FGD) gypsum , 2014 .