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Combustion Science and Technology Volume 158, 2000 - Issue 1
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Original Articles

Investigation of a Turbulent Flame Speed Closure Approach for Premixed Flame Calculations

F. DINKELACKER Lehrstuhl für Technische Thermodynamik, Universität Erlangen, Am Weichselgarten 8, Erlangen, 91058, GermanyView further author information
&
S. HÖLZLER Lehrstuhl für Technische Thermodynamik, Universität Erlangen, Am Weichselgarten 8, Erlangen, 91058, Germany
Pages 321-340 | Received 01 May 2000, Published online: 15 May 2007

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Lucky Anetor, Edward E. Osakue & Christopher Odetunde. (2023) Comparative analysis of combustion dynamics using three reaction source models. Australian Journal of Mechanical Engineering 21:2, pages 460-479.
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Eike Tangermann & Michael Pfitzner. (2009) Evaluation of combustion models for combustion-induced vortex breakdown. Journal of Turbulence 10.
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Fernando Biagioli. (2006) Stabilization mechanism of turbulent premixed flames in strongly swirled flows. Combustion Theory and Modelling 10:3, pages 389-412.
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Fernando Biagioli. (2004) Position, thickness and transport properties of turbulent premixed flames in stagnating flows. Combustion Theory and Modelling 8:3, pages 533-554.
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A.N. LIPATNIKOV & J. CHOMIAK. (2001) Developing Premixed Turbulent Flames: Part I. A Self-Similar Regime of Flame Propagation. Combustion Science and Technology 162:1, pages 85-112.
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Articles from other publishers (30)

Feichi Zhang, Thorsten Zirwes, Peter Habisreuther, Nikolaos Zarzalis, Henning Bockhorn & Dimosthenis Trimis. (2020) Numerical Simulations of Turbulent Flame Propagation in a Fan-Stirred Combustion Bomb and Bunsen-Burner at Elevated Pressure. Flow, Turbulence and Combustion 106:3, pages 925-944.
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Miguel C. Franco, Rodolfo C. Rocha, Mário Costa & Mohamed Yehia. (2021) Characteristics of NH3/H2/air flames in a combustor fired by a swirl and bluff-body stabilized burner. Proceedings of the Combustion Institute 38:4, pages 5129-5138.
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V. E. Kozlov & N. S. Titova. (2019) Two-Dimensional Modeling of a V-Shaped Turbulent Methane—Air Flame. High Temperature 57:1, pages 93-99.
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Andrei N. Lipatnikov. 2018. Modeling and Simulation of Turbulent Combustion. Modeling and Simulation of Turbulent Combustion 181 240 .
Peter Katzy, Josef Hasslberger, Lorenz R. Boeck & Thomas Sattelmayer. (2017) The Effect of Intrinsic Instabilities on Effective Flame Speeds in Under-Resolved Simulations of Lean Hydrogen–Air Flames. Journal of Nuclear Engineering and Radiation Science 3:4.
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Y. Halouane & A. Dehbi. (2017) CFD simulations of premixed hydrogen combustion using the Eddy Dissipation and the Turbulent Flame Closure models. International Journal of Hydrogen Energy 42:34, pages 21990-22004.
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Salman Verma & Andrei N. Lipatnikov. (2016) Does sensitivity of measured scaling exponents for turbulent burning velocity to flame configuration prove lack of generality of notion of turbulent burning velocity?. Combustion and Flame 173, pages 77-88.
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Vladimir L. Zimont. (2016) Damköhler-Shelkin Paradox in the Theory of Turbulent Flame Propagation, and a Concept of the Premixed Flame at the Intermediate Asymptotic Stage. Flow, Turbulence and Combustion 97:3, pages 875-912.
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E. Yasari, S. Verma & A. N. Lipatnikov. (2014) RANS Simulations of Statistically Stationary Premixed Turbulent Combustion Using Flame Speed Closure Model. Flow, Turbulence and Combustion 94:2, pages 381-414.
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Pradeep Pantangi, Amsini Sadiki, Johannes Janicka, Markus Mann & Andreas Dreizler. (2014) LES of Premixed Methane Flame Impinging on the Wall Using Non-adiabatic Flamelet Generated Manifold (FGM) Approach. Flow, Turbulence and Combustion 92:4, pages 805-836.
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Roman Keppeler, Eike Tangermann, Usman Allaudin & Michael Pfitzner. (2013) LES of Low to High Turbulent Combustion in an Elevated Pressure Environment. Flow, Turbulence and Combustion 92:3, pages 767-802.
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Andrei Lipatnikov. 2012. Fundamentals of Premixed Turbulent Combustion. Fundamentals of Premixed Turbulent Combustion 324 445 .
Kristin M. Kopp-Vaughan & Michael W. Renfro. (2012) Flame Shape and Spatially Resolved Rayleigh Criterion Using Proper Orthogonal Decomposition. International Journal of Spray and Combustion Dynamics 4:3, pages 255-274.
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Chien-Chia Liu, Shenqyang Steven Shy, Ming-Wei Peng, Chien-Wen Chiu & Yi-Chih Dong. (2012) High-pressure burning velocities measurements for centrally-ignited premixed methane/air flames interacting with intense near-isotropic turbulence at constant Reynolds numbers. Combustion and Flame 159:8, pages 2608-2619.
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Pratap Sathiah, Ed Komen & Dirk Roekaerts. (2012) The role of CFD combustion modeling in hydrogen safety management—Part I: Validation based on small scale experiments. Nuclear Engineering and Design 248, pages 93-107.
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Chien-Wen Chiu, Yi-Chih Dong & Shenqyang Steven Shy. (2012) High-pressure hydrogen/carbon monoxide syngas turbulent burning velocities measured at constant turbulent Reynolds numbers. International Journal of Hydrogen Energy 37:14, pages 10935-10946.
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Federico Ghirelli. (2011) Turbulent premixed flame model based on a recent dispersion model. Computers & Fluids 44:1, pages 369-376.
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V. Moreau. (2010) Progress in the Self-Similar Turbulent Flame premixed combustion model. Applied Mathematical Modelling 34:12, pages 4074-4088.
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Kristin M. Kopp-Vaughan, Steven G. Tuttle, Michael W. Renfro & Galen B. King. (2009) Heat release and flame structure measurements of self-excited acoustically-driven premixed methane flames. Combustion and Flame 156:10, pages 1971-1982.
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F. Zhang, P. Habisreuther, M. Hettel & H. Bockhorn. (2008) Modelling of a Premixed Swirl-stabilized Flame Using a Turbulent Flame Speed Closure Model in LES. Flow, Turbulence and Combustion 82:4, pages 537-551.
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V. Moreau. (2009) A self-similar premixed turbulent flame model. Applied Mathematical Modelling 33:2, pages 835-851.
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V. L. Zimont & V. Battaglia. (2006) Joint RANS/LES Approach to Premixed Flame Modelling in the Context of the TFC Combustion Model. Flow, Turbulence and Combustion 77:1-4, pages 305-331.
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N. K. Aluri, P. K. G. Pantangi, S. P. R. Muppala & F. Dinkelacker. (2005) A Numerical Study Promoting Algebraic Models for the Lewis Number Effect in Atmospheric Turbulent Premixed Bunsen Flames. Flow, Turbulence and Combustion 75:1-4, pages 149-172.
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A. Brandl, M. Pfitzner, J. D. Mooney, B. Durst & W. Kern. (2005) Comparison of Combustion Models and Assessment of Their Applicability to the Simulation of Premixed Turbulent Combustion in IC-Engines. Flow, Turbulence and Combustion 75:1-4, pages 335-350.
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Andrei N. Lipatnikov & Jerzy Chomiak. Modeling of Turbulent Scalar Transport in Expanding Spherical Flames. Modeling of Turbulent Scalar Transport in Expanding Spherical Flames.
S.P. Reddy Muppala, Naresh K. Aluri, Friedrich Dinkelacker & Alfred Leipertz. (2005) Development of an algebraic reaction rate closure for the numerical calculation of turbulent premixed methane, ethylene, and propane/air flames for pressures up to 1.0 MPa. Combustion and Flame 140:4, pages 257-266.
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V.L. Zimont & V. Battaglia. 2005. Engineering Turbulence Modelling and Experiments 6. Engineering Turbulence Modelling and Experiments 6 905 914 .
Andrei N. Lipatnikov & Jerzy Chomiak. A Numerical Study of Weakly Turbulent Premixed Combustion with Flame Speed Closure Model. A Numerical Study of Weakly Turbulent Premixed Combustion with Flame Speed Closure Model.
Andrei N Lipatnikov. (2002) Comments on: “Premixed flames in stagnating turbulence part V—evaluation of models for the chemical source term” by K. N. C. Bray, M. Champion, and P. A. Libby. Combustion and Flame 131:1-2, pages 219-221.
Crossref
A.N. Lipatnikov & J. Chomiak. (2002) Turbulent flame speed and thickness: phenomenology, evaluation, and application in multi-dimensional simulations. Progress in Energy and Combustion Science 28:1, pages 1-74.
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