Flame Propagation through Large-Scale Vortical Flows: Effect of Equivalence Ratio

The paper presents the computational fluid dynamics (CFD) combustion modeling approach based on two combustion models. This modeling approach was applied to a hydrogen deflagration experiment conducted in a large-scale confined experimental vessel. The used combustion models were Zimont's turbulent flame-speed closure (TFC) model and Lipatnikov's flame-speed closure (FSC) model. The conducted simulations are aimed to aid identifying and evaluating the potential hydrogen risks in nuclear power plant (NPP) containment. The simulation results show good agreement with experiment for axial flame propagation using the Lipatnikov combustion model. However, substantial overprediction in radial flame propagation is observed using both combustion models, which consequently results also in overprediction of the pressure increase rate and overall combustion energy output. As assumed for a large-scale experiment without any turbulence inducing structures, the combustion took place in low-turbulence regimes, where the Lipatnikov combustion model, due to its inclusion of quasi-laminar source term, has advantage over the Zimont model.

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DNS on Autoignition and Flame Propagation of Inhomogeneous Methane–Air Mixtures in a Closed Vessel

ASME/JSME 2011 8th Thermal Engineering Joint Conference ◽

10.1115/ajtec2011-44476 ◽

2011 ◽

Author(s):

Makito Katayama ◽

Naoya Fukushima ◽

Masayasu Shimura ◽

Mamoru Tanahashi ◽

Toshio Miyauchi

Keyword(s):

Heat Release ◽

Flame Propagation ◽

Heat Release Rate ◽

Release Rate ◽

Equivalence Ratio ◽

Kinetic Mechanism ◽

Spatial Inhomogeneity ◽

Closed Vessel ◽

Isothermal Wall ◽

Detailed Kinetic Mechanism

Direct numerical simulations (DNSs) on autoignition and flame propagation of inhomogeneous methane–air mixtures in a closed vessel are conducted with considering detailed kinetic mechanism and temperature dependence of transport and thermal properties. The mixtures with spatial inhomogeneity of temperature or equivalence ratio are investigated. Periodic condition for non-heatloss cases or isothermal wall condition for heatloss cases is imposed on the boundaries. From the DNS results without heatloss, effects of spatial inhomogeneity of temperature and equivalence ratio on mean heat release rate are clarified. Increase of spatial variations of temperature or equivalence ratio suppresses drastic rise of mean heat release rate and reduces its maximum value. Autoignition process is affected by temperature more strongly than equivalence ratio. In the cases with heatloss, ignition delay increases and the maximum mean heat release rate decreases. After autoignition process, propagating flame is formed along walls. Heat transfer characteristics in a closed vessel are also discussed with combustion mechanisms.

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209 DNS of Spherical Flame Propagation in Large Scale Parallel Computing

The Proceedings of The Computational Mechanics Conference ◽

10.1299/jsmecmd.2013.26._209-1_ ◽

2013 ◽

Vol 2013.26 (0) ◽

pp. _209-1_-_209-2_

Author(s):

Shinnosuke NISHIKI ◽

Tatsuya HASEGAWA

Keyword(s):

Parallel Computing ◽

Flame Propagation ◽

Large Scale ◽

Spherical Flame ◽

Spherical Flame Propagation

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Flame Propagation from the Closed End of an Open-ended Tube: an analysis of the effects of fuel type, tube length, and equivalence ratio and an insight into flame dynamics

49th AIAA/ASME/SAE/ASEE Joint Propulsion Conference ◽

10.2514/6.2013-3656 ◽

2013 ◽

Cited By ~ 1

Author(s):

Joshua Gray ◽

Jonas P. Moeck ◽

Christian O. Paschereit

Keyword(s):

Flame Propagation ◽

Equivalence Ratio ◽

Tube Length ◽

Fuel Type ◽

Flame Dynamics ◽

Insight Into ◽

Type Tube

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Large-Scale Homogeneous Hydrogen-Air-Steam Deflagration Experiment Simulated Using Two Turbulent Flame Speed Closure Models

Volume 5: Student Paper Competition ◽

10.1115/icone24-60134 ◽

2016 ◽

Author(s):

Tadej Holler ◽

Varun Jain ◽

Ed M. J. Komen ◽

Ivo Kljenak

Keyword(s):

Flame Propagation ◽

Nuclear Power ◽

Large Scale ◽

Turbulent Flame ◽

Turbulent Flames ◽

Flame Speed ◽

Energy Output ◽

Combustion Model ◽

Turbulent Flame Speed ◽

Combustion Models

The CFD combustion modeling approach based on two combustion models was applied to a hydrogen deflagration experiment conducted in a large-scale confined experimental vessel. The used combustion models were Zimont’s Turbulent Flames Speed Closure (TFC) model and Lipatnikov’s Flame Speed Closure (FSC) model. The conducted simulations are aimed to aid identifying and evaluating the potential hydrogen risks in Nuclear Power Plant (NPP) containment. The simulation results show good agreement with experiment for axial flame propagation using the Lipatnikov combustion model. However substantial overprediction in radial flame propagation is observed using both combustion models, which consequently results also in overprediction of the pressure increase rate and overall combustion energy output. As assumed for a large-scale experiment without any turbulence inducing structures, the combustion took place in low-turbulence regimes, where the Lipatnikov combustion model, due to its inclusion of quasi-laminar source term, has advantage over the Zimont model.

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