Analysis of hydrogen flame acceleration in APR1400 containment by coupling hydrogen distribution and combustion analysis codes

Abstract This study was conducted as part of the construction of an integrated system to mechanistically evaluate flame acceleration characteristics in a containment of a nuclear power plant during a severe accident. In the integrated analysis system, multi-dimensional hydrogen distribution and combustion analysis codes are used to consider three-dimensional effects of the hydrogen behaviors. GASFLOW is used for the analysis of a hydrogen distribution in the containment. For the analysis of a hydrogen combustion in the containment, an open-source CFD (computational fluid dynamics) code OpenFOAM is chosen. Data of the hydrogen and steam distributions obtained from a GASFLOW analysis are transferred to the OpenFOAM combustion solver by a conversion and interpolation process between the solvers. The combustion solver imports the transferred data and initializes the containment atmosphere as an initial condition of a hydrogen combustion analysis. The turbulent combustion model used in this study was validated by evaluating the F22 test of the FLAME experiment. The coupled analysis method was applied for the analysis of a hydrogen combustion during a station blackout accident in an APR1400. In addition, the characteristics of the flame acceleration depending on a hydrogen release location are comparatively evaluated.

[1]  Baraldi Daniele,et al.  Hydrogen Combustion with Concentration Gradients in Experiments and Simulations - Preliminary Results of ENACCEF Benchmark , 2007 .

[2]  P. Royl,et al.  GASFLOW: A Computational Fluid Dynamics Code for Gases, Aerosols, and Combustion, Volume 3: Assessment Manual , 1998 .

[3]  J. P. Magnaud,et al.  The TONUS CFD code for hydrogen risk analysis: Physical models, numerical schemes and validation matrix , 2008 .

[4]  B. Magnussen On the structure of turbulence and a generalized eddy dissipation concept for chemical reaction in turbulent flow , 1981 .

[5]  S. W. Hong,et al.  Hydrogen Mitigation Strategy of the APR1400 Nuclear Power Plant for a Hypothetical Station Blackout Accident , 2005 .

[6]  T. R. Moffette,et al.  Hydrogen Flammability Data And Application To Pwr Loss-Of-Coolant Accident , 1957 .

[7]  P. Royl,et al.  Benchmark on Hydrogen Distribution in a Containment Based on the OECD-NEA THAI HM-2 Experiment , 2011 .

[8]  D. Spalding Mixing and chemical reaction in steady confined turbulent flames , 1971 .

[9]  Sang Baik Kim,et al.  GASFLOW Validation with Panda Tests from the OECD SETH Benchmark Covering Steam/Air and Steam/Helium/Air Mixtures , 2009 .

[10]  Wolfgang Breitung,et al.  Evaluation of limits for effective flame acceleration in hydrogen mixtures , 2001 .

[11]  Robert J. Kee,et al.  PSE: a Fortran program for modeling well-stirred reactors , 1986 .

[12]  J. Chomiak,et al.  3-D Diesel Spray Simulations Using a New Detailed Chemistry Turbulent Combustion Model , 2000 .