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Combustion Science and Technology Volume 153, 2000 - Issue 1
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Original Articles

NOX Emission Prediction from 3-D Complete Modelling to Reactor Network Analysis

D. BENEDETTO ENEL S.p.A. Thermal Research Centre - Pisa, Italia
,
S. PASINI ENEL S.p.A. Thermal Research Centre - Pisa, Italia
,
M. FALCITELLI Consorzio Pisa Ricerche - Pisa, Italia
,
C. LA MARCA Consorzio Pisa Ricerche - Pisa, Italia
&
L. TOGNOTTI Università degli Studi di Pisa - Dip. di ingegneria Chimica, Chimica Industriale e Scienza dei Materiali- Pisa, ItaliaCorrespondence[email protected]
Pages 279-294 | Received 21 Sep 1999, Published online: 17 Sep 2008

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Andres Colorado & Vincent McDonell. (2017) Exploring Computational Methods for Predicting Pollutant Emissions and Stability Performance of Premixed Reactions Stabilized by a Low Swirl Injector. Combustion Science and Technology 189:12, pages 2115-2134.
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S. Amzin & R. S. Cant. (2015) Assessment of an Equivalent Reaction Networks Approach for Premixed Combustion. Combustion Science and Technology 187:11, pages 1705-1723.
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Rahul Palulli, Kai Zhang, Simeon Dybe, Christian Oliver Paschereit & Christophe Duwig. (2024) A novel data-driven reduced order modelling methodology for simulation of humid blowout in wet combustion applications. Energy 297, pages 131310.
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Sören Dübal, Leon L. Berkel, Paulo Debiagi, Hendrik Nicolai, Tiziano Faravelli, Christian Hasse & Sandra Hartl. (2024) Chemical reactor network modeling in the context of solid fuel combustion under oxy-fuel atmospheres. Fuel 364, pages 131096.
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Rachele Lamioni, Alessandro Mariotti, Maria Vittoria Salvetti & Chiara Galletti. (2024) Chemical Reactor Network modeling of ammonia–hydrogen combustion in a gas turbine: stochastic sensitivity analysis. Applied Thermal Engineering 244, pages 122734.
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Shivansh Chaturvedi, R. Santhosh, Syed Mashruk, Rajneesh Yadav & Agustin Valera-Medina. (2023) Prediction of NOx emissions and pathways in premixed ammonia-hydrogen-air combustion using CFD-CRN methodology. Journal of the Energy Institute 111, pages 101406.
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Matteo Savarese, Alberto Cuoci, Ward De Paepe & Alessandro Parente. (2023) Machine learning clustering algorithms for the automatic generation of chemical reactor networks from CFD simulations. Fuel 343, pages 127945.
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Alessandro Parente, Matteo Savarese & Saurabh Sharma. 2023. Hydrogen for Future Thermal Engines. Hydrogen for Future Thermal Engines 269 328 .
Shokri Amzin. (2022) Computations of a Bluff-Body Stabilised Premixed Flames Using ERN Method. ChemEngineering 6:4, pages 46.
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Felix Grimm. (2022) Low-Order Reactor-Network-Based Prediction of Pollutant Emissions Applied to FLOX® Combustion. Energies 15:5, pages 1740.
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Stephen Niksa. 2022. Process Chemistry of Coal Utilization. Process Chemistry of Coal Utilization 109 176 .
Hamidreza Khodayari, Fathollah Ommi & Zoheir Saboohi. (2020) Uncertainty Analysis of the Chemical Reactor Network Approach for Predicting the Pollutant Emissions in a Double-Swirl Combustor. Journal of Energy Resources Technology 142:9.
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Hamidreza Khodayari, Fathollah Ommi & Zoheir Saboohi. (2020) A review on the applications of the chemical reactor network approach on the prediction of pollutant emissions. Aircraft Engineering and Aerospace Technology 92:4, pages 551-570.
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André A. V. Perpignan, Rishikesh Sampat & Arvind Gangoli Rao. (2019) Modeling Pollutant Emissions of Flameless Combustion With a Joint CFD and Chemical Reactor Network Approach. Frontiers in Mechanical Engineering 5.
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Xu Wen, Paulo Debiagi, Oliver T. Stein, Andreas Kronenburg, Andreas M. Kempf & Christian Hasse. (2019) Flamelet tabulation methods for solid fuel combustion with fuel-bound nitrogen. Combustion and Flame 209, pages 155-166.
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Stephen Niksa. (2019) Simulating volatiles conversion in dense burning coal suspensions. 1. Validation of chemical reaction mechanisms. Fuel 252, pages 821-831.
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Pieter DePape & Igor Novosselov. (2018) Model-Based Approach for Combustion Monitoring Using Real-Time Chemical Reactor Network. Journal of Combustion 2018, pages 1-12.
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A. Innocenti, A. Andreini, D. Bertini, B. Facchini & M. Motta. (2018) Turbulent flow-field effects in a hybrid CFD-CRN model for the prediction of NO and CO emissions in aero-engine combustors. Fuel 215, pages 853-864.
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Andrés Colorado & Vincent McDonell. (2018) Emissions and stability performance of a low-swirl burner operated on simulated biogas fuels in a boiler environment. Applied Thermal Engineering 130, pages 1507-1519.
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Meredith B. Colket. 2013. Gas Turbine Emissions. Gas Turbine Emissions 123 153 .
S. Lyra & R.S. Cant. (2013) Analysis of high pressure premixed flames using Equivalent Reactor Networks for predicting NOx emissions. Fuel 107, pages 261-268.
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Achim Wechsung & Paul I. Barton. 2013. 23rd European Symposium on Computer Aided Process Engineering. 23rd European Symposium on Computer Aided Process Engineering 319 324 .
Stephen E. Zitney. (2010) Process/equipment co-simulation for design and analysis of advanced energy systems. Computers & Chemical Engineering 34:9, pages 1532-1542.
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Ryan Zarnitz & Sarma V. Pisupati. (2007) Evaluation of the use of coal volatiles as reburning fuel for NOx reduction. Fuel 86:4, pages 554-559.
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S Niksa & G.-S Liu. (2002) Incorporating detailed reaction mechanisms into simulations of coal-nitrogen conversion in p.f. flames. Fuel 81:18, pages 2371-2385.
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M. Falcitelli, S. Pasini & L. Tognotti. (2002) Modelling practical combustion systems and predicting NOx emissions with an integrated CFD based approach. Computers & Chemical Engineering 26:9, pages 1171-1183.
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M. Falcitelli, S. Pasini, N. Rossi & L. Tognotti. (2002) CFD+reactor network analysis: an integrated methodology for the modeling and optimisation of industrial systems for energy saving and pollution reduction. Applied Thermal Engineering 22:8, pages 971-979.
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S. Niksa & G.-S. Liu. (2002) Detailed reaction mechanisms for coal-nitrogen conversion in pulverized fuel flames. Proceedings of the Combustion Institute 29:2, pages 2259-2265.
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