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I. Barmina, R. Valdmanis, M. Zake, H. Kalis, M. Marinaki and U. Strautins

REFERENCES 1. Gupta, A.K., Lilley, D.G., & Syred, N. (1984). Swirl flows. Abacus Press UK , 588. 2. Sami, M., Annamalai, K., Woldridge, M. (2001). Cofiring of coal and biomass fuel blends. Prog. Energy Combustion Sci. 27 , 171–214. 3. Lawton, J., Weinberg, F.J. (1969). Electric aspects of combustion. Clarenton Press , 336–340. 4. Colannino, J. (2012). Electrodynamic combustion control, TM technology. A Clear Sign White Paper, ClearSign Combustion Corporation , Seattle. Available at www.clearsign-combustion.com 5. Swaminathan, S

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I. Barmina, A. Lickrastina, M. Zake, A. Arshanitsa, V. Solodovnik and G. Telysheva

References 1. Klass, D. L. (2004). Biomass for Renewable Energy and Fuels. Encyclopedia of Energy 1, Elsevier Inc., 193-212. 2. Nussbaumer, T. (2008). Biomass Combustion in Europe. Overview on Technologies and Regulations, Final Report 08-03, New York State Energy Research and Development Authority, NYSERDA, 97. http://www.nyserda.org/programs/environment/emep/Report%2008-03%20-%20Biomass%20Combustion%20in%20Europe-complete-after%20corrections.pdf 3. Vasilev, S., Baxter, D., Andersen, L.K. & Vasileva

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I. Barmina, R. Valdmanis and M. Zaķe

References 1. Gupta, A.K., Lilley, D.G., & Syred, N. (1984). Swirl Flows. UK: Abacus Press. 2. Meier, W., Duan, X.R., & Weigand, P. (2006). Investigations of swirl flames in a gas turbine model combustor: Turbulence-chemistry interactions. Combustion and Flame, 144, 225-236. 3. Külsheimer, C., & Büchner, H. (2002). Combustion dynamics of turbulent swirling flames, Combustion and Flame, 131, 70-84. 4. Syred, N., & Beer, J.M. (1974). Combustion in swirling flows: A review. Combustion and Flame, 23

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M. Zaķe, I. Barmina, V. Krishko, M. Gedrovics and A. Desņickis

(Oklahoma, Tulsa) http://www.primenergy.com/reference_BioMassFiring.htm Chunyang, Wu (2006). Fuel-NO x Formation during Low-Grade Fuel Combustion in a Swirling-Flow Burner. PhD Theses , Brigham Young University, 1-230. Drennan, S. (1982). First co-firing gas burner optimized on computer reduces particulate emissions 24%, saves $0.13/MMBtu. Journal Articles by Fluent Soft Users , 1-4. Babu, S. P. (2001). Role of Natural Gas in Promoting Bioenergy as a Component of the Sustainable Energy

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I. Barmina, A. Līckrastiņa, J. Valdmanis, R. Valdmanis, M. Zaķe, A. Arshanitsa, G. Telysheva and V. Solodovnik

, J., Shuttleworth, P., Deswarte, F., & Wilson, A. (2008). Microwave processing as a green and energy efficient technology of energy and chemicals from biomass and energy crops. Aspects of Applied Biology , 90 , 277-282. 10. Barmina, I., Cipijs, A., Līckrastiņa, A., Valdmanis, J. Valdmanis, R., Purmalis, M., & Zake, M. (2011). Renewable Fuel Gasification and Combustion Control by Applied AC Electric Field. In: Proceedings of 8th International Pamir Conference on Fundamental and Applied MHD , 2, 843-847. 11. Friedl, A., Padouvas, E

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Tadeusz Szumiata, Małgorzata Gzik-Szumiata, Katarzyna Brzózka, Bogumił Górka, Michał Gawroński, Ryszard Świetlik and Marzena Trojanowska

-009-9978-8. 11. Vandenberghe, R. E., de Resende, V. G., da Costa, G. M., & De Grave, E. (2010). Study of loss-on-ignition anomalies found in ashes from combustion of iron-rich coal. Fuel , 89 , 2405–2410. DOI: 10.1016/j.fuel.2010.01.022. 12. Zyryanov, V. V., Petrov, S. A., & Matvienko, A. A. (2011). Characterization of spinel and magnetospheres of coal fly ashes collected in power plants in the former USSR. Fuel , 90 , 486–492. DOI: 10.1016/j.fuel.2010.10.006.

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Justyna Lalak, Danuta Martyniak, Agnieszka Kasprzycka, Grzegorz Żurek, Wojciech Moroń, Mariola Chmielewska, Dariusz Wiącek and Jerzy Tys

References Aho M. and Silvennoinen J., 2004. Preventing chlorine deposition on heat transfer surfaces with aluminium-silicon rich biomass residue and additive. Fuel, 83, 1299-1305. Armesto L., Bahillo A., Cabanillas A., Veijonen K., Otero J., Plumed A., and Salvador L., 2003. Co-combustion of coal and olive oil industry residues in fluidized bed. Fuel, 82, 993-1000. Arvelakis S. and Frandsen F.J., 2010. Rheology of fly ashes from coal and biomass co-combustion. Fuel, 89, 3132-3140. Arvelakis S

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M. Abricka, I. Barmina, R. Valdmanis and M. Zake

References 1. Gupta, A.K., Lilley, D.G., & Syred, N. (1984). Swirl Flows. Abacus Press UK), 588 p. 2. Meier, W., Duan, X.R., & Weigand, P. (2006). Investigations of swirl flames in a gas turbine model combustor: turbulence-chemistry interactions. Combustion and Flame, 144, 225-236. 3. Külsheimer, C., & Büchner, H. (2002). Combustion dynamics of turbulent swirling flames. Combustion and Flame, 131, 70-84. 4. Driscoll, J. F., & Temme, J. (2011). Role of swirl in flame stabilization. In: 49thAIAA

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J. Kalnacs, R. Bendere, A. Murasovs, D. Arina, A. Antipovs, A. Kalnacs and L. Sprince

REFERENCES 1. Demirbas, A. (2004). Combustion characteristics of different biomass fuels. Prog. Energy Combust. Sci., 30 (2), 219–230. 2. Koppmann, R., Von Czapiewski, K., & Reid, J.S. (2005). A review of biomass burning emissions, part I: gaseous emissions of carbon monoxide, methane, volatile organic compounds and nitrogen containing compounds. Atmos. Chem. Phys. Discuss. 5 , 10455–10516. 3. Health Inspection ( in Latvian ). (n.d.) Available at http

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I. Kudrenickis and G. Klavs

energy production and waste disposal. Renewable Energy & Power Quality Journal (RE&PQJ). 10, paper No.414 (4 pages), http://www.icrepq.com/RE&PQJ-10-5.html 10. Kalnačs J. et al. (2011). Metāna (CH4) un slāpekļa oksīda (N20) emisiju faktoru noteikšana cietajiem biomasas kurināmajiem sadalījumā pa kurināmā veidiem, kā arī sadalījumā pa sadedzināšanas iekārtām, pētījuma - publiskā iepirkuma atskaite ( Methane (CH4) and nitrogen oxide (N2O) emission factor determination for solid biomass fuels broken down by type of fuel and combustion equipment), Rīga