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Janusz Lasek, Radosław Lajnert, Krzysztof Głód and Jarosław Zuwała

References Bequette B.W., 2003. Process control: Modeling, design, and simulation, Prentice Hall. de Mello L.F., Gobbo R., Moure G.T., Miracca I., 2013. Oxy-combustion technology development for Fluid Catalytic Crackers (FCC) - large pilot scale demonstration. Energy Procedia, 37, 7815-7824. DOI: 10.1016/j.egypro.2013.06.562. Duan L., Sun H., Zhao C., Zhou W., Chen X., 2014. Coal combustion characteristics on an oxy-fuel circulating fluidized bed combustor with warm flue gas recycle. Fuel, 127, 47-51. DOI: 10.1016/j.fuel.2013

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Huseyin Topal and Ehsan Amirabedin

References 1. Zhu S., Lee S.W. Co-combustion performance of poultry wastes and natural gas in the advanced Swirling Fluidized Bed Combustor (SFBC). Waste Management, 2005, Nr.25, p. 511-518. 2. Kelleher B.P., Leahy J.J., Henihan A.M., O’Dwyer T.F., Sutton D., Leahy M.J. Advances in poultry litter disposal technology - a review, Bioresource Technology, 2002, Nr. 83, p. 27-36 3. Henihan A.M., Leahy M.J., Leahy J.J., Cummins E., Kelleher B.P. Emissions modeling of fluidised bed co-combustion of

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Jozef Horváth, Igor Wachter and Karol Balog

. ISBN 0-9728111-3-3 5. OSVALD, A., KORYTÁROVÁ, O. 2000. Zmeny v štruktúre vybraných ihličnatých drevín spôsobené vysokými teplotami . ( Changes in the structure of selected coniferous trees caused by high temperatures ). Vol. 1. Zvolen: TU. ISBN 80-228-0970-5 6. DEMIRBAS, A. 2004. Combustion characteristics of different biomass fuels. Prog Energy Combust Science , Vol. 30, pp. 219–230. 7. ABUELNUOR, A.A.A., WAHIDA, M.A., HOSSEINIA, S. E., SAAT, A., SAQR, K.M., SAIT and M. OSMAND, H.H. 2014. Characteristics of biomass in flameless combustion: A

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Agnieszka Kijo-Kleczkowska

References Gajewski W., Kijo-Kleczkowska A., Leszczyński J.: Analysis of cyclic combustion of solid fuels. Fuel 88 (2009), 221-234. Atesok G., Boylu F., Sikeci A. A., Dincer H.: The effect of coal properties on the viscosity of coal-water slurries. Fuel 81 (2002), 1855-1858. Boylu F., Dincer H., Atesok G.: Effect of coal particle size distribution, volume fraction and rank on the rheology of coal-water. Fuel Processing Technology (2004), 241

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Damian Łapinski and Janusz Piechna

References [1] Kurec K., Piechna J., and M¨uller N.: Numerical investigation of the radial disk internal combustion engine, POWERMEMS 2009, 0175. [2] Snyder P.H., Alparslan B., Nalim R.M.: 2002, Gas dynamics of the CVC, a novel detonation cycle, AIAA 2002-4069. [3] Piechna J.: “Numerical Analysis of Micro Ring-Engine Fluid Dynamics”, The Archive of Mechanical Engineering, 2009, Vol. LVI, Nr 2, pp. 173-189. [4] Piechna J., Dyntar D.: Hybrid wave engine concept and numerical simulation of engine

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Adam Deptuła, Dariusz Kunderman, Piotr Osiński, Urszula Radziwanowska and Radosław Włostowski

References 1. Adaileh W.M. (2013), Engine Fault Diagnosis Using Acoustic Signals, Applied Mechanics and Materials, 295-298, 2013-2020. 2. Barelli L., Bidini G., Buratti C., Mariani R. (2009), Diagnosis of internal combustion engine through vibration and acoustic pressure non-intrusive measurements, Applied Thermal Engineering, 29, 1707-1713. 3. Carlucci A.P., Chiara F.F., Laforgia D. (2006), Analysis of the relation between injection parameter variation and block vibration of an internal combustion diesel engine

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Aneta Magdziarz, Małgorzata Wilk and Monika Zajemska

References Adamczuk M., Radomiak H., 2010. The use of computer programs for the numerical modelling of combustion process and gas dynamics in heating furnaces. Archivum Combustionis , 30, 4, 451-458. Adamczuk M., Szecówka L., Radomiak H., 2009. Applied of numerical methods to environmental protection. Archiwum Spalania , 9, 13-23 (in Polish). Barneto A.G., Carmona J.A., Conesa Ferrer J.A., Diaz Blanco M.J., 2010. Kinetic study on the thermal degradation of a biomass and its

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Milada Kozubková, Jaroslav Krutil, Marian Bojko and Václav Nevrlý

.cz/seznam.htm KOZUBKOVÁ, M., BLEJCHAŘ, T., BOJKO, M. (2011). Modelování přenosu tepla a hybnosti. VŠB - TU Ostrava 173 s, Ostrava 2011 (in Czech). KOZUBKOVA, M., KRUTIL, J. (2012). Matematické modelování výbuchu metanu v rodinném domku v Kamenné u Milína pomocí SW FLUENT. The Science for Population Protection , 2012 (in print). RICHARDSON, E. S.A, CHEN, J. H. B. (2012). Application of PDF mixing models to premixed flames with differential diffusion. Combustion and Flame , Volume 159, Issue 7, pages 2398-2414. ISSN 00102180

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M. Zajemska, H. Radomiak and A. Poskart

REFERENCES [1] W. Bialik, S. Gil, P. Mocek, Prediction of CFD processes of gaseous pollutants emission in high-temperature combustion chamber, Ęnvironment 11 , 3, 3-12 (2009). [2] R. Bilbao, M.U. Alzueta, A. Millera, V. Cantín, Experimetal study and modeling of the burnout zone in the natural gas reburning process. Chemical Engineering Science 50 , 16, 2579-2587 (1995). [3] A. Bogusławski, A. Tyliszczak, S. Kubacki, Numeryczne modelowanie procesów przepływowych, Materiały dydaktyczne Wydziału Inżynierii Mechanicznej i Informatyki, www

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Wojciech Moroń, Krzysztof Czajka, Wiesław Ferens, Konrad Babul, Arkadiusz Szydełko and Wiesław Rybak

References Andersson K., Normann F., Johnsson F., Leckner C., 2008. NO emission during oxy fuel combustion of lignite. Ind Eng Chem Res. , 47, 1835 - 1845. DOI: 10.1021/ie0711832. Buhre B.J.P., Elliott L.K., Sheng C.D., Gupta R.P., Wall T.F., 2005. Oxy-fuel combustion technology for coalfired power generation. Prog. Energy Combust. Sci. , 31, 283-307. DOI: 10.1016/j.pecs.2005.07.001. Croiset E., Thambimuthu K.V., 2001. NOx and SO 2 emission from O 2 /CO 2 recycled coal combustion. Fuel , 80, 2117