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Veröentlichungen Dr.-Ing. M. Mancini [1] M. Mancini, R. Weber und U. Bollettini. Development of mathematical model for high temperature air combustion. In: Fluent CFD User Group meeting. Mancini40. Sheeld, England, 2001. [2] M. Mancini, R. Weber und U. Bollettini. Mathematical Models Developement for Design of HTAC Systems. In: Proceeding of the 4 th International Symposium on High Temperature Air Combustion and Gasication HTACG. W85. 2001. [3] M. Mancini und R. Weber. Formation and Destruction of Nitrogen Oxides in Combustion of Natural Gas with High Temperature Air. In: Proceedings of the 5 th International Symposium on High Temperature Air Combustion and Gasication HTACG. W89. Yokohama, Japan, Okt. 2002. [4] M. Mancini, R. Weber und U. Bollettini. Predicting NO x Emissions of a Burner Operated in Flameless Oxidation Mode. In: Proceedings of the Combustion Institute 29 (2002). W87, S. 11551163. [5] R. Weber, D. Brauckmann, R. Scholz, M. Mancini und W. vd Kamp. Numerical simulations of Cement Kiln Flames. In: 6 th European Conference on Industrial Furnaces and Boilers INFUB. W86. Lisbon, Protugal, Apr. 2002. [6] M. Mancini, P. Schwöppe und R. Weber. Examining NOx Chemistry in High Temperature Air Combustion Process. In: Proceedings of XVIII International Symposium on Combustion Processes. W92. Ustron, Sep. 2003, S. 6061. [7] R. Weber, D. Brauckmann, R. Scholz, M. Mancini und W. vd Kamp. Numerical Simulation of a Coal Fed Burner. In: Ciments, Betons, Platres, Chaux 864 (2003). Mancini35, S. 27. [8] R. Hekkens und M. Mancini. CFD modeling for high eciency combustion. In: IFRF Members Conference. Bd. 14. Mancini34. Noordwijkerhout, Niederlande, 2004. [9] C. Mayer, W. Kerschbaumer, M. Mancini und R. Weber. Experimental and numerical investigation of a heating and ignition process of pulverized coal. In: FLUENT CFD Forum. Mancini29. Frankfurt, Deutschland, Okt. 2005. [10] N. Schael, A. Szlek, K. Loeer, M. Mancini und R. Weber. HTAC Application for Solid Fuel Combustion. In: XIX International Symposium on Combustion Processes. Schael17. Wisla, Polen, 2005. [11] N. Schael, A. Szlek, R. Wilk, K. Loeer, M. Mancini und R. Weber. Mathematical Modelling of MILD/Flameless Combustion of Pulverized Coal. In: 6 th International Symposium on High Temperature Air Combustion and Gasication. W103. Essen, Okt. 2005. 1

[12] T. Kupka, M. Mancini, M. Irmer und R. Weber. Investigation of Ash Deposit Formation during Co-Firing of Coal with Sewage Sludge, Saw Dust and Refuse Derived Fuel. In: 10 th International Conference on Boiler Technology. W109. Szczyrk, Poland, 2006. [13] T. Kupka, M. Mancini und R. Weber. A CFD analysis of ash particle ow around pipes including particle impaction eciency calculation. In: Europe Conference on Industrial Furnaces and Boilers INFUB. Bd. 7. Kupka11. Porto, Portugal, Apr. 2006. [14] T. Kupka, M. Mancini und R. Weber. Experiments Supported by CFD Simulations for the Evaluation of Ash Deposit Formation during Co-Firing of Coal with Alternative Fuels. In: 23. Deutscher Flammentag - Verbrennung und Feuerung. W117. Berlin, Sep. 2007. [15] T. Kupka, K. Zajac, M. Mancini und R. Weber. A CFD Analysis of ash particle ow around pipes including particle impaction eciency calculations. In: ECOS. Mancini20. Padua, Italien, 2007. [16] T. Kupka, K. Zajac, M. Mancini und R. Weber. A laboratory method supported by simple CFD analysis for the evaluation of ash deposit formation during co- ring of coal with biomass-, bio-waste- and waste materials. In: IFRF Members Conference. Bd. 15. Zajac6. Pisa, Italien, 2007. [17] M. Mancini, P. Schwöppe und R. Weber. Inuence of the Mixing on NO x Emissions in the MILD Combustion of Natural Gas. In: 20 th International Conference on Eciency, Cost, Optimization, Simulation and Environmental Impact of Energy Systems ECOS. W111. Padova, Italy, Juni 2007. [18] M. Mancini, P. Schwöppe und R. Weber. Investigations on the modeling assumptions for NO x emissions calculations in the MILD combustion of Natural Gas. In: IFRF Members Conference. Mancini21. Pisa, Italien, 2007. [19] M. Mancini, P. Schwöppe und R. Weber. NOx prediction of MILD / FLOX combustion. In: Deutscher Flammentag Verbrennung und Feuerung. 23. Mancini15. Berlin, Deutschland, 2007. [20] M. Mancini, P. Schwöppe und R. Weber. Numerical Computation of NO x Formation in MILD Combustion of Natural Gas. In: Computational Combustion 2007 ECCOMAS Thematic Conference. W112. Delft, The Netherlands, Juli 2007. [21] M. Mancini, P. Schwöppe und R. Weber. On Mathematical Modelling of Flameless Combustion. In: Combustion and Flame 150 (2007). W119, S. 5459. [22] M. Mancini, P. Schwöppe und R. Weber. Predictions of NO x Formation in MILD/Flameless Combustion. In: 23 Deutscher Flammentag - Verbrennung und Feuerung. W115. Berlin, Sep. 2007, S. 331337. 2

[23] M. Mancini, R. Weber, N. Schael und A. Szlek. Analysis of numerical modeling in predicting chemistry and NOx in MILD combustion. In: International Symposium on Combustion Processes. Bd. 20. Schael14. Pultusk, Polen, 2007. [24] M. Mancini, G. Wecel, R. Bialecki und R. Weber. Advances in Boundary Element Method Used to Predict Radiative Heat Transfer in Flames. In: Computational Combustion 2007 ECCOMAS Thematic Conference. W113. Delft, Netherlands, Juli 2007. [25] C. Mayer, W. Kerschbaumer, M. Mancini und R. Weber. Time Dependent Simulations of Dispersion of a Cloud of Solid Particles. In: Journal of the Energy Institute 80.3 (2007). W120, S. 181183. [26] N. Schael, A. Szlek, M. Mancini und R. Weber. Analysis of High Temperature Air Combustion (HTAC) boiler for ecient and clean power production using Computational Fluid Dynamics. In: ECOS Conference on Energy Systems. Bd. 20th. Mancini16. Padova, Italien, 2007. [27] N. Schael, A. Szlek, M. Mancini und R. Weber. Application of HTAC technology in supercritical pulverized coal boiler. In: International Symposium on Combustion Processes. Bd. 20. Schael15. Pultusk, Polen, 2007. [28] N. Schael, A. Szlek, M. Mancini und R. Weber. Design of the HTAC Boiler Fired with Pulverized Coal Using Numerical Modeling Methods. In: Computational Combustion 2007 ECCOMAS Thematic Conference. W114. Delft, Netherlands, Juli 2007. [29] N. Schael, A. Szlek, M. Mancini und R. Weber. Numerical Investigation of the Conguration of a Pulverized Coal Fired Boiler Operated with HTAC Technology. In: 23. Deutscher Flammentag - Verbrennung und Feuerung. W116. Berlin, Sep. 2007. [30] G. Wecel, R. A. Bialecki und M. Mancini. BEM employing Cartesian hierarchical meshes. In: International Symposium on Radiative Transfer. Bd. 5. Mancini24. Bodrum, Türkei, 2007. [31] G. Wecel, R. A. Bialecki, M. Mancini und R. Weber. Radiative Heat Transfer in Industrial Furnaces. In: Fortschrittsberichte der Deutschen Keramischen Gesellschaft, Verfahrenstechnik, Thermische Verfahrenstechnik. Bd. 21. 1. W121. 2007, ISSN 01739913. [32] R. Worberg, R. Kim, R. Schumacher, Hermann, Scholz, Weber und Mancini. Wärmetechnik des Heat-Recovery-Ofens. In: Fachtagung Kokereitechnik. Essen, 2007. [33] T. Kupka, M. Mancini, M. Irmer und R. Weber. Investigation of ash deposit formation during co-ring of coal with sewage sludge, saw-dust and refuse derived fuel. In: Fuel 87 (2008). Kupka3, S. 28242837. 3

[34] M. Mancini, R. Weber, N. Schael und A. Szlek. CFD Method and Detailed Mechanisms Modelling in Predicting NO x in MILD Combustion. In: 7 th High Temperature Air Combustion and Gasication International Symposium. W125. Phuket, Thailand, Jan. 2008. [35] N. Schael, A. Szlek, M. Mancini und R. Weber. Application of HTAC technology in power boilers red with pulverized coal. In: High Temperature Air Combustion and Gasication International Symposium. Bd. 7. Schael10. Phuket, Thailand, 2008. [36] N. Schael, A. Szlek, M. Mancini und R. Weber. HTAC boiler red with pulverized coal for ecologic and ecient electricity production. In: Archivum Combustionis 28 (2008). Schael3, S. 105112. [37] N. Schael, A. Szlek, M. Mancini und R. Weber. Simulations of the steam power cycle with High Temperature Air Combustion (HTAC) boiler. In: ECOS. Schael7. Krakow, Polen, 2008. [38] C. Heymann, A. Richardson und M. Mancini. The impact of turbulence- and chemistry- turbulence interaction models in the simulation of oxy-fuel. In: Clean Air Conference. Mancini8. Lissabon, Portugal, Juli 2009. [39] N. Schael-Mancini, M. Mancini, A. Szlek und R. Weber. Ecological evaluation of the pulverized coal combustion in HTAC technology. In: International Conference on Optimization using Exergy-Based Methods and Computational Fluid Dynamics. W131. Berlin, Deutschland, Okt. 2009. [40] N. Schael, M. Mancini, A. Szlek und R. Weber. Mathematical modeling of MILD combustion of pulverized coal. In: Combustion and Flame 156.9 (2009), S. 1771 1784. issn: 0010-2180. doi: 10.1016/j.combustflame.2009.04.008. url: http://www.sciencedirect.com/science/article/pii/s0010218009001023. [41] N. Schael, A. Szlek, M. Mancini und R. Weber. Application of HTAC technology to pulverized coal boilers. In: Clean Air Conference. Bd. 10. Schael2. Lissabon, Portugal, 2009. [42] J. U. Wrobel, M. Mancini, R. Weber und R. Löer. An Advanced Model of Pulverized Coal Combustion for CFD Simulations. In: Proceedings of the International Conference on Exergy-Based Methods and Computational Fluid Dynamics. W129. Berlin, Deutschland, Okt. 2009. [43] N. Schael-Mancini, M. Mancini, A. Szlek und R.Weber. Novel Concept for Supercritical Boilers. In: 11th International Conference on Boiler Technology,18-22 October 2010, Poland. 2010, S. 137160. [44] N. Schael-Mancini, M. Mancini, A. Szlek und R. Weber. Novel conceptual design of a supercritical pulverized coal boiler utilizing high temperature air combustion (HTAC) technology. In: Energy 35.7 (2010), S. 2752 2760. issn: 0360-5442. doi: 10.1016/j.energy.2010.02.014. url: http://www. sciencedirect.com/science/article/pii/s0360544210000678. 4

[45] T. Jakobs, S. Fleck, M. Mancini, R. Weber und T. Kolb. Gasication of High Viscous Slurry - R & D on Atomization and Numerical Simulation. In: 36th International Technical Conference on Clean Coal and Fuel Systems, June 2011, Clearwater, Florida USA. 2011. [46] M. Mancini, R. Buczynski, R. Weber, S. Fleck, P. Stoesser und T. Kolb. Gasication of Glycol: Measurements and Mathematical Modelling. In: Tagungsband 25. Deutscher Flammentag, Karlsruhe. Sep. 2011. [47] R. Weber, M. Mancini, N. Schael-Mancini und T. Kupka. Mathematical Modelling of Ash Deposition in a Coal-Fired Experimental Reactor. In: 9th European Conference on Industrial Furnances and Boilers, 26-29 April 2011, Estoril, Portugal. 2011. [48] A. M. Beckmann, M. Mancini und R. Weber. CFD-Based Modelling of the Ash Behaviour in a Pulverized Coal Flame. In: 44. Kraftwerkstechnisches Kolloquium. 2012, P12. [49] A. M. Beckmann, M. Mancini und R. Weber. CFD Modelling of a pulverized coal ame with emphasis on predciting the ash deposition behaviour. In: Prodeedings of the Conference on Impacts of Fuel Quality on Power Production and Environment, Puchberg (AUT). 2012, PP12. [50] T. Jakobs, N. Djordjevic, S. Fleck, M. Mancini, R. Weber und T. Kolb. Gasication of high viscous slurry R & D on atomization and numerical simulation. In: Applied Energy 93.0 (2012), S. 449 456. issn: 0306-2619. doi: 10.1016/ j.apenergy.2011.12.026. url: http://www.sciencedirect.com/science/ article/pii/s0306261911008221. [51] A. Musiol, M. Mancini und R. Weber. Numerical Simulation of coal and biomass ame in a small scale combustion chamber. In: 17th IFRF Members Conference, 17-13 June 2012, Chateau de Mahers, France. 2012. [52] R. Weber, M. Mancini, N. Schael-Mancini und T. Kupka. On Importance of Fluid Dynamics in CFD Predictions of Ash Deposits. In: Prodeedings of the Conference on Impacts of Fuel Quality on Power Production and Environment, Puchberg (AUT). 2012, OP29. [53] M. Alberti, R. Weber, M. Mancini und M. Modest. Comparison of models for predicting band emissivity of carbon dioxide and water vapour at high temperatures. In: International Journal of Heat and Mass Transfer 64 (2013), S. 910 925. doi: 10.1016/j.ijheatmasstransfer.2013.05.011. [54] A. M. Beckmann, M. Mancini und R. Weber. CFD-Modellierung einer Kohlenstaubamme mit dem Fokus auf der Vorhersage der Ascheablagerung. In: VDI Berichte 2161: 26. Deutscher Flammentag - Verbrennung und Feuerung. Hrsg. von VDI Wissensforum GmbH. VDI Verlag, Düsseldorf, 2013, S. 201210. isbn: 978-3-18-092161-7. 5

[55] M. Mancini, R. Weber, P. Weigand, W. Leuckel und T. Kolb. Design of the entrained ow reactor for gasication of biomass based slurry. In: VDI Berichte 2161: 26. Deutscher Flammentag - Verbrennung und Feuerung. Hrsg. von VDI Wissensforum GmbH. VDI Verlag, Düsseldorf, 2013, S. 625 634. isbn: 978-3- 18-092161-7. [56] R. Weber und M. Mancini. Heterogene Kinetik der Koksverbrennung. In: 45. Kraftwerkstechnisches Kolloquium. Hrsg. von M. Beckmann und A. Hurtado. TK Verlag Karl Thome-Kozmiensky (Neuruppin), 2013, S. 895 911. isbn: 978-3-944310-04-6. [57] R. Weber, M. Mancini, N. Schael-Mancini und T. Kupka. On predicting the ash behaviour using Computational Fluid Dynamics. In: Fuel Processing Technology 105.0 (2013), S. 113 128. issn: 0378-3820. doi: 10.1016/j.fuproc. 2011.09.008. url: http://www.sciencedirect.com/science/article/pii/ S0378382011003225. [58] R. Weber, N. Schael-Mancini, M. Mancini und T. Kupka. Fly ash deposition modelling: Requirements for accurate predictions of particle impaction on tubes using RANS-based computational uid dynamics. In: Fuel 108 (2013), S. 586 596. issn: 0016-2361. doi: 10.1016/j.fuel.2012.11.006. url: http://www. sciencedirect.com/science/article/pii/s0016236112008824. [59] A. M. Beckmann, M. Mancini und R. Weber. Coal Ash Particle Deposition Modeling: A Closer Look at Various CFD sub-models. In: Prodeedings of the Conference on Impacts of Fuel Quality on Power Production and Environment, Snowbird (USA). 2014, S. 72. [60] A. M. Beckmann, M. Mancini und R. Weber. Investigating Ash Deposition using Down-Fired Combustion Rig. In: 12th International Conference on Boiler Technology, Szczyrk (Poland). 2014. [61] S. Brinker und R. Weber. Co-Combustion of Coal and Biomass in O2/CO2- atmosphere. In: Prodeedings of the Conference on Impacts of Fuel Quality on Power Production and Environment, Snowbird (USA). 2014, S. 47. [62] M. Alberti, R. Weber, M. Mancini, A. Fateev und S. Clausen. On the accuracy of HITEMP-2010 calculated emissivities of Water Vapor and Carbon Dioxide. In: 12 th International Conference on Energy for a Clean Environment. Portugal, 2015. [63] M. Alberti, R. Weber, M. Mancini, A. Fateev und S. Clausen. On the accuracy of HITEMP-2010 calculated emissivities of Water Vapor and Carbon Dioxide. In: 10 th International Conference on Industrial Furnaces and Boilers (INFUB-10). Portugal, 2015. [64] M. Alberti, R. Weber und M. Mancini. Bestimmung der Emissionskoezienten von Gas-Gemischen auf Grundlage von spektroskopischen Datenbanken. In: VDI Berichte 2267: 27. Deutscher Flammentag - Verbrennung und Feuerung. Hrsg. 6

von VDI Wissensforum GmbH. VDI Verlag, Düsseldorf, 2015, S. 629638. isbn: 978-3-18-092267-6. [65] M. Alberti, R. Weber und M. Mancini. Re-creating Hottel's emissivity charts for carbon dioxide and extending them to 40 bar pressure using HITEMP-2010 data base. In: Combustion & Flame 162 (2015), S. 597612. doi: 10.1016/j. combustflame.2014.09.005. [66] M. Alberti, R. Weber, M. Mancini, A. Fateev und S. Clausen. Validation of HITEMP-2010 for Carbon Dioxide and Water Vapour at high temperatures and atmospheric pressures in 4507600 cm 1 spectral range. In: Journal of Quantitative Spectroscopy & Radiative Transfer 157 (2015), S. 14 33. doi: 10.1016/ j.jqsrt.2015.01.016. [67] A. M. Beckmann, M. Mancini und R. Weber. CFD-Modellierung einer Kohlenstaubamme unter besonderer Berücksichtigung der Vorhersage von Ascheablagerungen. In: VDI Berichte 2267: 27. Deutscher Flammentag - Verbrennung und Feuerung. Hrsg. von VDI Wissensforum GmbH. VDI Verlag, Düsseldorf, 2015, S. 591608. isbn: 978-3-18-092267-6. 7

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