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Combustion Science and Technology Volume 185, 2013 - Issue 4
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Original Articles

Assessment of the Performance of Several Turbulence and Combustion Models in the Numerical Simulation of a Flameless Combustor

A. Rebola Mechanical Engineering Department, Instituto Superior Técnico, Technical University of Lisbon, Lisboa, Portugal
,
P. J. Coelho Mechanical Engineering Department, Instituto Superior Técnico, Technical University of Lisbon, Lisboa, PortugalCorrespondence[email protected]
&
M. Costa Mechanical Engineering Department, Instituto Superior Técnico, Technical University of Lisbon, Lisboa, Portugal
Pages 600-626 | Received 19 Jun 2012, Accepted 09 Oct 2012, Published online: 29 Mar 2013

Citations (41)

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Kareem I. Khidr, Yehia A. Eldrainy & Mohamed M. El-Kassaby. (2021) Investigating the Potential of Different Modeling Setups in Simulating a Flameless Furnace Using Global and Detailed Kinetic Mechanisms. Combustion Science and Technology 193:5, pages 727-761.
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Mohammadreza Farokhi & Madjid Birouk. (2019) A hybrid EDC/Flamelet approach for modelling biomass combustion of grate-firing furnace. Combustion Theory and Modelling 23:4, pages 716-747.
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Hesham M. Khalil, Yehia A. Eldrainy, Walid A. Abdelghaffar & Adel A. Abdel-Rahman. (2019) Increased heat transfer to sustain flameless combustion under elevated pressure conditions – a numerical study. Engineering Applications of Computational Fluid Mechanics 13:1, pages 782-803.
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Marco Lubrano Lavadera, M. Mustafa Kamal, Saurabh Sharma, Laura Donato, Chiara Galletti, Axel Coussement & Alessandro Parente. (2024) A combined experimental, numerical, and data consistency approach for the characterization of temperature distribution in a MILD combustion furnace. Applied Thermal Engineering 243, pages 122625.
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A K Khodir, S M El-Behery & A H Elaskary. (2023) Numerical study of inlet air conditions on methane flameless combustion characteristics. Journal of Physics: Conference Series 2616:1, pages 012019.
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Esmaeil Ebrahimi Fordoei & Fateme Ahmadi Boyaghchi. (2023) NO emission characteristics for the HTC and MILD combustion regimes with N2, N2/CO2 and CO2 diluents: effect of H2 addition to CH4. International Journal of Hydrogen Energy 48:92, pages 36185-36210.
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Ahmad Shaker, E. Ebrahimi Fordoei & Fateme Ahmadi Boyaghchi. (2023) Study of NO emission from CH4-air, oxygen-enriched, and oxy-CH4 combustion under HTC and MILD regimes: Impact of wall thermal condition in different oxidant temperature and dilution level. Energy 277, pages 127683.
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Ashkan Hosseini, Johannes L. T. Hage, Koen Meijer, Erik Offerman & Yongxiang Yang. (2023) On the Importance of Model Selection for CFD Analysis of High Temperature Gas-Solid Reactive Flow; Case Study: Post Combustion Chamber of HIsarna Off-Gas System. Processes 11:3, pages 839.
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Esmaeil Ebrahimi Fordoei & Fateme Ahmadi Boyaghchi. (2022) Influence of wall thermal conditions on the ignition, flame structure, and temperature behaviors in air-fuel, oxygen-enhanced, and oxy-fuel combustion under the MILD and high-temperature regimes. Energy 255, pages 124611.
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Amir Mardani & Aslan Nazari. (2022) Dynamic adjustment of the Eddy Dissipation Concept model for turbulent/combustion interactions in mixed combustion regimes. Combustion and Flame 241, pages 111873.
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Amirreza Mohammadpour, Kiumars Mazaheri & Alireza Alipoor. (2022) Reaction zone characteristics, thermal performance and NOx/N2O emissions analyses of ammonia MILD combustion. International Journal of Hydrogen Energy 47:48, pages 21013-21031.
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Xu Huang, Mark J. Tummers, Eric H. van Veen & Dirk J.E.M. Roekaerts. (2022) Modelling of MILD combustion in a lab-scale furnace with an extended FGM model including turbulence–radiation interaction. Combustion and Flame 237, pages 111634.
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Ivar S. Ertesvåg. (2022) Scrutinizing proposed extensions to the Eddy Dissipation Concept (EDC) at low turbulence Reynolds numbers and low Damköhler numbers. Fuel 309, pages 122032.
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Farid C. Christo, Yeshayahou Levy, Mário Costa & Gabrian A.F. Balelang. (2021) Effect of jet momentum flux and heat density on NO emission in a flameless gas turbine combustor. Aerospace Science and Technology 119, pages 107137.
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P Rijo & P J Coelho. (2021) Numerical investigation of fuel flexibility in a small-scale flameless combustor. Journal of Physics: Conference Series 2116:1, pages 012017.
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E. Ebrahimi Fordoei, Kiumars Mazaheri & Amirreza Mohammadpour. (2021) Effects of hydrogen addition to methane on the thermal and ignition delay characteristics of fuel-air, oxygen-enriched and oxy-fuel MILD combustion. International Journal of Hydrogen Energy 46:68, pages 34002-34017.
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Kai Zhang, Yazhou Shen & Christophe Duwig. (2021) Finite rate simulations and analyses of wet/distributed flame structure in swirl-stabilized combustion. Fuel 289, pages 119922.
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H.S. Awad & Yehia A. Eldrainy. (2021) Design and investigation of a central air jet flameless combustor. Alexandria Engineering Journal 60:2, pages 2291-2301.
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E. Ebrahimi Fordoei, Kiumars Mazaheri & Amirreza Mohammadpour. (2021) Numerical study on the heat transfer characteristics, flame structure, and pollutants emission in the MILD methane-air, oxygen-enriched and oxy-methane combustion. Energy 218, pages 119524.
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Michał T. Lewandowski, Alessandro Parente & Jacek Pozorski. (2020) Generalised Eddy Dissipation Concept for MILD combustion regime at low local Reynolds and Damköhler numbers. Part 1: Model framework development. Fuel 278, pages 117743.
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Mohammad Mansourian & Reza Kamali. (2019) Modifying the constant coefficients of Eddy-dissipation concept model in moderate or intense low-oxygen dilution combustion using inverse problem methodology. Acta Astronautica 162, pages 546-554.
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H A Yepes & A A Amell. (2019) Effect of turbulence model on flameless combustion simulation of a regenerative furnace. Journal of Physics: Conference Series 1257:1, pages 012016.
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Mikhail Ivankin, Alexey Nikolaev, Vladimir Sabelnikov, Anna Shiryaeva, Vadim Talyzin & Vladimir Vlasenko. (2019) Complex numerical-experimental investigations of combustion in model high-speed combustor ducts. Acta Astronautica 158, pages 425-437.
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F. Chitgarha & A. Mardani. (2018) Assessment of steady and unsteady flamelet models for MILD combustion modeling. International Journal of Hydrogen Energy 43:32, pages 15551-15563.
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Michał T. Lewandowski & Ivar S. Ertesvåg. (2018) Analysis of the Eddy Dissipation Concept formulation for MILD combustion modelling. Fuel 224, pages 687-700.
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Sangtae Jeon, Minjun Kwon & Yongmo Kim. (2018) Multi-environment PDF modeling for non-catalytic partial oxidation process under MILD oxy-combustion condition. International Journal of Hydrogen Energy 43:11, pages 5486-5500.
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V. V. Vlasenko, E. S. Matyash, S. S. Molev, V. A. Sabelnikov & V. A. Talyzin. Simulation of flow development in high-speed combustor in 2D and 3D formulations. Simulation of flow development in high-speed combustor in 2D and 3D formulations.
Hyunggeun Ji, Namsu Kim & Yongmo Kim. (2017) FGM-based non-adiabatic multi-environment PDF modeling for MILD combustion processes with the strong flow reversal. Journal of Mechanical Science and Technology 31:12, pages 6059-6068.
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Sangtae Jeon & Yongmo Kim. (2017) Multi-environment Probability Density Function Modeling for Turbulent CH 4 Flames under Moderate or Intense Low-Oxygen Dilution Combustion Conditions with Recirculated Flue Gases . Energy & Fuels 31:8, pages 8685-8697.
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Bo LiuBin-Bin BaoHong XuYuan-Hua Wang. (2017) Performance and Routes of Nitrogen Oxide Formation of MILD Forward-Flow Furnace with Reflector. Journal of Energy Engineering 143:4.
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Mohammadreza Farokhi, Madjid Birouk & Fouzi Tabet. (2017) A computational study of a small-scale biomass burner: The influence of chemistry, turbulence and combustion sub-models. Energy Conversion and Management 143, pages 203-217.
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Amir Mardani. (2017) Optimization of the Eddy Dissipation Concept (EDC) model for turbulence-chemistry interactions under hot diluted combustion of CH4/H2. Fuel 191, pages 114-129.
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Jia-qiang E, Hai-jiao Huang & Xiao-huan Zhao. (2016) Numerical investigations on effects of bluff body in flat plate micro thermo photovoltaic combustor with sudden expansion. Journal of Central South University 23:4, pages 975-982.
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Bo Liu, Yuan-Hua Wang & Hong Xu. (2015) Mild combustion in forward flow furnace of refinery-off gas for low-emissions by deflector. Applied Thermal Engineering 91, pages 1048-1058.
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Masoud Darbandi & Majid Ghafourizadeh. (2015) Solving turbulent diffusion flame in cylindrical frame applying an improved advective kinetics scheme. Theoretical and Computational Fluid Dynamics 29:5-6, pages 413-431.
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Bo Liu, Yuan-Hua Wang & Hong Xu. (2015) Numerical Study of the Effects of Reflector on Performances of a MILD Furnace with Forward Flow Configuration. Energy Procedia 75, pages 3042-3047.
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Delphine Lupant & Paul Lybaert. (2015) Assessment of the EDC combustion model in MILD conditions with in-furnace experimental data. Applied Thermal Engineering 75, pages 93-102.
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Seyed Ehsan Hosseini & Mazlan Abdul Wahid. (2014) Investigation of bluff-body micro-flameless combustion. Energy Conversion and Management 88, pages 120-128.
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Seyed Ehsan Hosseini, Ghobad Bagheri & Mazlan Abdul Wahid. (2014) Numerical investigation of biogas flameless combustion. Energy Conversion and Management 81, pages 41-50.
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Zhenfeng Mei, Pengfei Li, Feifei Wang, Jianpeng Zhang & Jianchun Mi. (2013) Influences of Reactant Injection Velocities on Moderate or Intense Low-Oxygen Dilution Coal Combustion. Energy & Fuels 28:1, pages 369-384.
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Yu Jeong Kim, Chang Bo Oh & Osamu Fujita. (2015) Prediction Performance of Chemical Mechanisms for Numerical Simulation of Methane Jet MILD Combustion. Advances in Mechanical Engineering 5, pages 138729.
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