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M. Musztyfaga-Staszuk and R. Honysz

. Drygała, P. Panek, Investigation of the screen printed contacts of silicon solar cells from Transmissions Line Model, Journal of Achievements in Materials and Manufacturing Engineering, JAMME, 41 1-2, 57-65 (2010). [4] L.A. Dobrzański, M. Musztyfaga, Effect of the front electrode metallisation process on electrical parameters of a silicon solar cell, Journal of Achievements in Materials and Manufacturing Engineering, 48/2, 2011, Issue 2, 115-144 (2011). L.A. Dobrzański, M. Musztyfaga, A. Drygała, W. Kwaśny, P. Panek, Structure and electrical properties of

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Rafał Litka and Sylwester Kalisz

., Zmysłowski A., 1956. Kotły parowe , Vol. I. Państwowe Wydawnictwa Techniczne, Warszawa. Patent PL 212497. A method and a biomass pyrolysis installation before the co-combustion process, especially in power boilers . Patent Office of the Republic of Poland (UPRP). Pronobis M., Wojnar W., 2013. The impact of biomass co-combustion on the erosion of boiler convection surfaces. Energy Convers. Manage. , 74, 462-470. DOI: 10.1016/j.enconman.2013.06.059. Smoot L.D., Smith P.J., 1985. Coal combustion and gasification . Plenum Press, New York. Türschmid

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Marek Juszczak

Przeróbki Węgla. Olsson M., Kjallstrand J., 2006. Low emission from wood burning in an ecolabelled residential boiler. Atmos. Environ., 40, 1148-1158. DOI:10.1016/j.atmosenv. 2005.11.008. PN-EN 303-5: 2004. Heating boilers, Part 5. Heating boilers for solid fuels, hand and automatically stocked nominal heat output of up to 300 kW. Terminology, requirements and marking. Poskrobko S., Łach J., Król D., 2010. Experimental investigation of hydrogen chloride bonding with calcium hydroxide in the furnace of a stoker-fired boiler

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W. Longa

. W. Longa, O błędach w interpretacji i zastosowaniu równania B. I. Kitajewa do obliczania wysokości strefy podgrzania żeliwiakach koksowych. Artykuł dyskusyjny Prz. Odl. 1-2, 20-29 (2007). W. Longa, Calculating the optima mount of air blast into coke cupola furnaces - cold blast with normal amount of oxygen (solving the 100 years old issue of theory and practice of cupola process. Foundry Journal of the Polish Foundrymen's Association 1-2, 8-28 (2010). W. Longa, Calculation of height and structure of melting zone

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M. Musztyfaga-Staszuk, L.A. Dobrzanski, S. Rusz and M. Staszuk

- Proceedings 16th European Photovoltaic Solar Energy Conference, Glasgow (United Kingdom), p. 1438 (2000). [4] A.S.H. Vander Heide, M.J.A.A. Goris, Contact optimisation on lowly doped emitters using the corescan on non-uniform emitter cells, Proceedings 19th European Photovoltaic Solar Energy Conference, Paris (France), 701 (2004). [5] J. Hoornstra, A. Vander Heide, J. Bultman, A. Weber, Simple, detailed & fast firing furnace temperature profiling for improved efficiency - Proceedings of the conference PVin Europe - From PVtechnology to energy

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Aivars Zandeckis, Dagnija Blumberga, Claudio Rochas, Ivars Veidenbergs and Kaspars Silins

References Blumberga D., Veidenbergs I. Slāpekļa oksīdu izmešu samazināšana. - Riga; 1992. p. 20. Miltner M., Makaruk A., Harasek M., Friedl A. CFD-modeling for the combustion of solid baled biomass. Fifth International Conference on CFD in the Process Industries, Melbourne, Australia, December 13-15, 2006. Glarborg P., Jensen A. D., Johnson J. E. Fuel nitrogen conversion in solid fuel fired system, Progress in Energy and Combustion Science, 29, 2003, p 89

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Aneta Magdziarz, Małgorzata Wilk and Monika Zajemska

.11.034. Liu H., Gibbs B.M., 2002. Modelling of NO and N 2 O emission from biomass-fired circulating fluidized bed combustors. Fuel , 81, 271-280. DOI: 10.1016/S0016-2361(01)00170-3. Ma L., Jones J.M., Pourkashanian M., Williams A., 2007. Modelling the combustion of of pulverized biomass in an industrial combustion test furnace. Fuel , 86, 1956-1965. DOI:10.1016/j.fuel.2006.12.019. Miller J.A, Bowman C.T., 1989. Mechanism and modelling of nitroagen chemistry in combustion. Prog. Energy Combust. Sci. , 15, 287-338. DOI

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Kaspars Silins

flames of refuse derived fuel. Combustion and Flame, 2009, vol 156, p. 922-927 12. Casaca, C., Costa, M . Co-combustion of biomass in a natural gas-fired furnace. Combustion Science and Technology , 2010, vol 175, N 11, p. 1953-1977. 13. Paulrud, S., Nillson, C. The effects of particle characteristics on emission from burning wood fuel powder. Fuel , 2004, vol. 83, p. 813-821. 14. Eriksson, G., Kjellström, B., Lundqvist, B. et. al. Combustion of wood hydrolysis residue in a 150 kW powder burner. Fuel , 2004, vol

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Włodzimierz K. Kordylewski, Krzysztof J. Mościcki and Karol J. Witkowski

.02.019. Frandsen F., J. van Lith S., 2009. Detailed investigation of Cl-corrosion initiated by deposits formed in biomass biomass-fired boilers, FORSKEL-5820, Final Report No.0905. Hardy T., Kordylewski W., Mościcki K., 2013. Aluminosilicate sorbents for control of KCl vapors in biomass combustion gases. J. Power Technologies, 93, 37-43. Hardy, T., 2001. Laboratory set-up for investigations of deposits of biomass-firing with selected additives in the drop-tube furnace, In: Wejkowski R., Janda T. (Eds.), R&D Project Report ECOALBOILER

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Piotr Żymełka, Daniel Nabagło, Tomasz Janda and Paweł Madejski

References [1] Modliński N., Madejski P., Janda T., Szczepanek K., Kordylewski W.: A validation of computional fluid dynamics temperature distirbution prediction in a pulverized coal boiler with acoustic temperature measurement. Energy 92(2015), 77-86. [2] Madejski P., Janda T., Modliński N., Nabagło D.: A combustion process optimization and numerical analysis for the low emission operation of pulverized coal-fired boiler. Chap. in Developments in Combustion Technology. InTechOpen, 2016, 33-76. [3] Taler J