Simulation of the OECD/NEA Sandia Fuel Project Phases I & II ignition tests with DRACCAR

Autor: O. de Luze, G. Guillard, F. Jacq
Přispěvatelé: PSN-RES/SEMIA/LIMAR, Institut de Radioprotection et de Sûreté Nucléaire (IRSN)
Rok vydání: 2018
Předmět:
Work (thermodynamics)
Nuclear engineering
02 engineering and technology
US Nuclear Regulatory Commission
01 natural sciences
7. Clean energy
010305 fluids & plasmas
law.invention
HT
Loss Of Coolant Accident
PBR
law
Phase (matter)
0202 electrical engineering
electronic engineering
information engineering
General Materials Science
Pilling and Bedworth Ratio
Safety
Risk
Reliability and Quality
Waste Management and Disposal
Flow Rate
LOCA
Sandia Fuel Pro- ject
[PHYS]Physics [physics]
Spent Fuel Pool 2
Zirconium alloy
____________________________________________________________________________________________ Abbreviations: CA
KIT
Heat Transfer
Power (physics)
Institut de Radioprotection et de Sûreté Nucléaire
IRSN
PA
Convection
DRACCAR
Nuclear and High Energy Physics
020209 energy
chemistry.chemical_element
Déformation et Renoyage d'un Assemblage de Crayons Combus- tibles pendant un Accident de Refroidissement
FR
SFP
US-NRC
0103 physical sciences
Central Assembly
Zirconium
Mechanical Engineering
Karlsruhe Institute of Technology
Ignition system
Nuclear Energy and Engineering
chemistry
Peripheral Assembly
Environmental science
Transient (oscillation)
Zdroj: Nuclear Engineering and Design
Nuclear Engineering and Design, Elsevier, 2018, 330, pp.524-537. ⟨10.1016/j.nucengdes.2018.01.047⟩
ISSN: 0029-5493
DOI: 10.1016/j.nucengdes.2018.01.047
Popis: International audience; This paper describes simulations of two ignition tests performed at full power in the frame of the Sandia Fuel Project (SFP) with the thermo-mechanical code DRACCAR v2.3. The OECD/NEA Sandia Fuel Project was built on an agreement between 12 countries from OECD, the Nuclear Energy Agency (NEA) and the US-NRC for the characterization of thermal-hydraulic and zirconium fire phenomena in pressurized-water reactor (PWR). The experimental program was split in two phases to focus at first on axial heating and burn propagation in one prototypic fuel assembly (Phase I), and then on axial and radial heating and burn propagation in 1 × 4 fuel assemblies (Phase II). DRACCAR is a simulation tool, developed at IRSN, for fuel assembly mechanical behavior and coolability assessment during a LOCA transient. The flexibility of DRACCAR allows the modeling of many kinds of geometries. Because the code is based on a 3D non-structured meshing, it can be used to model any non-axisymmetric geometry, like the 1 × 4 fuel assemblies geometry of the Phase II of the SFP program. In order to check the consistency of the modeling, we have optimized the code options to get best results for the Phase I, and applied the same options to the Phase II. Most of the DRACCAR results have been successfully checked against experimental ones, using additional code improvements. Air oxidation and breakaway modeling of the zircaloy claddings were successfully tested against the experimental results. Nevertheless parts of the experimental results of Phase II have been difficult to reproduce. As many causes could be involved in these difficulties, such as detailed evolution of the air convective loop, radiative heat transfers in the bundles, and the modeling of additional reactions of zirconium with nitrogen in places where oxygen is lacking, there is still room for improvement in the work of interpretation and modeling of the SFP tests. © 2018 Elsevier B.V.
Databáze: OpenAIRE
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