Page 208 - New Trends In Coal Conversion

P. 208

Technologies for control of sulfur and nitrogen compounds and particulates 171

Bell, R.D., Buckingham, F.P., 2010. An Overview of Technologies for Reduction of Oxides of
Nitrogen from Combustion Furnaces. MPR Associates.
Benson, S.A., Sondreal, E.A., Hurley, J.P., 1995. Status of coal ash behavior research. Fuel
Processing Technology 44 (1e3), 1e12.
Beychok, M.R., 1973. NO x emission from fuel combustion controlled. Oil & Gas Journal 1,
53e56.
Campbell, P.E., McMullan, J.T., Williams, B.C., 2000. Concept for a competitive coal ﬁred
integrated gasiﬁcation combined cycle power plan. Fuel 79 (9), 1031e1040.
CECO Environmental, n.d. Overﬁre Air (OFA). https://www.cecoenviro.com/overﬁre-air-ofa-
cca-combustion-systems.
Chen, W., Li, B., Zhang, S., Liu, M., Liu, J., 2017. Simulation investigation on the design and
operation strategy of a 660 MW coal-ﬁred power plant coupled with a steam ejector to
ensure NO x reduction ability. Applied Thermal Engineering 124, 1103e1111.
Chiesa, P., Kreutz, T., Lozza, G., 2005. CO 2 Sequestration from IGCC power plants by means of
metallic membranes. In: Proc. of ASME TurboExpo, Reno-Tahoe, Nevada, USA.
C ordoba, P., 2015. Status of Flue Gas Desulphurisation (FGD) systems from coal-ﬁred power
plants: Overview of the physic-chemical control processes of wet limestone FGDs. Fuel
144, 274e286.
Denton, D., Lesemann, M., Gupta, R., Gardner, B., Turk, B., 2015. RTI warm syngas clean up
technology demonstration. In: Proceedings of the 7th International Freiberg/Inner
Mongolia Conference.
Durak-C ¸ etin, Y., Sarıo glan, A., Okutan, H., 2017. Comparison of catalytic activities both for
selective oxidation and decomposition of ammonia over Fe/HZb catalyst. Journal of the
Turkish Chemical Society 4, 227e242.
EPA, 2017. United States Environmental Protection Agency. Particulate Matter (PM) Pollution.
http://www.epa.gov/pm-pollution.
EPRI, 2000. Evaluation of Innovative Fossil Fuel Power Plants with CO 2 Removal, Technical
Report 1000316.
EPRI, 2005. Financial Incentives for Deployment of IGCC: A Coal Fleet Working Paper.
European Commission, 2006. Reference Document on Best Available Techniques for Large
Combustion Plants (BREFs).
European Environmental Agency, 2016. https://www.eea.europa.eu/publications/92-9167-031-
6/page003.html.
Fan, W., Li, Y., Guo, Q., Chen, C., 2017. Coal-nitrogen release and NO x evolution in the
oxidant-staged combustion of coal. Energy 125, 417e426.
Fern andez-Miranda, N., Lopez-Anton, M.A., Díaz-Somoano, M., Martínez-Tarazona, M.R.,
2016. Mercury oxidation in catalysts used for selective reduction of NO x (SCR) in oxy-fuel
combustion. Chemical Engineering Journal 285, 77e82.
Gaudin, P., Dorge, S., Nouali, H., Kehrli, D., Michelin, L., Josien, L., Fioux, P., Vidal, L.,
Soulard, M., Vierling, M., Moli ere, M., Brilhac, J.-F., Patarin, J., 2015. Synthesis of Cu-Ce/
KIT-6 materials for SO x removal. Applied Catalysis A: General 504, 110e118.
Hasegawa, T., 2010. Gas turbine combustion and ammonia removal technology of gasiﬁed
fuels. Energies 3, 335e449.
IEA Clean Coal Centre, 2017. Fuel Gas Recirculation for NO x Control. http://www.iea-coal.org.
uk/site/ieacoal/databases/ccts/ﬂue-gas-recirculation-for-nox-control.
IEA Greenhouse Gas R & D Programme, 2003. Potential for Improvement in Gasiﬁcation
Combined Cycle Power Generation with CO 2 Capture.
Ju, Y., Lee, C.H., 2017. Evaluation of the energy efﬁciency of the Shell coal gasiﬁcation process
by coal type. Energy Conversion and Management 143, 123e136.

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