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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July 2018
Research-Article
Hydrogen–Air–Steam Deflagration Experiment Simulated Using Different Turbulent Flame-Speed Closure Models
Holler Tadej,
Holler Tadej
Mem. ASME
Jožef Stefan Institute,
Jamova cesta 39,
Ljubljana SI-1000, Slovenia
e-mail: tadej.holler@ijs.si
Jožef Stefan Institute,
Jamova cesta 39,
Ljubljana SI-1000, Slovenia
e-mail: tadej.holler@ijs.si
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Ed M. J. Komen,
Ed M. J. Komen
Nuclear Research and Consultancy Group,
Westerduinweg 3,
Petten 1755ZG, The Netherlands
e-mail: komen@nrg.eu
Westerduinweg 3,
Petten 1755ZG, The Netherlands
e-mail: komen@nrg.eu
Search for other works by this author on:
Kljenak Ivo
Kljenak Ivo
Search for other works by this author on:
Holler Tadej
Mem. ASME
Jožef Stefan Institute,
Jamova cesta 39,
Ljubljana SI-1000, Slovenia
e-mail: tadej.holler@ijs.si
Jožef Stefan Institute,
Jamova cesta 39,
Ljubljana SI-1000, Slovenia
e-mail: tadej.holler@ijs.si
Ed M. J. Komen
Nuclear Research and Consultancy Group,
Westerduinweg 3,
Petten 1755ZG, The Netherlands
e-mail: komen@nrg.eu
Westerduinweg 3,
Petten 1755ZG, The Netherlands
e-mail: komen@nrg.eu
Kljenak Ivo
1Corresponding author.
Manuscript received September 30, 2016; final manuscript received December 21, 2017; published online May 16, 2018. Editor: Igor Pioro.
ASME J of Nuclear Rad Sci. Jul 2018, 4(3): 031009 (6 pages)
Published Online: May 16, 2018
Article history
Received:
September 30, 2016
Revised:
December 21, 2017
Citation
Tadej, H., Komen, E. M. J., and Ivo, K. (May 16, 2018). "Hydrogen–Air–Steam Deflagration Experiment Simulated Using Different Turbulent Flame-Speed Closure Models." ASME. ASME J of Nuclear Rad Sci. July 2018; 4(3): 031009. https://doi.org/10.1115/1.4039067
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