PRACTICAL EXAMPLES OF THE ANALYSIS OF SEVERE ACCIDENTS

1. Regional Workshop on Evaluation of Specific Preventative and Mitigative Accident Management Strategies PRACTICAL EXAMPLES OF THE ANALYSIS OF SEVERE ACCIDENTS Presented Dr. Chris Allison

2. Outline • Analysis of SAs • Bundle boiloff – influence of SA models • Bundle quench • CORA-13 – PWR – severe oxidation transient during reflood • TMI-2

3. Bundle Boiloff • Two identical bundles • 32 rods in 6X6 array – 0.91 m height • Boildown transient • High decay heat – 58.5 Kw (2.0 Kw/m per rod) • One bundle modeled using RELAP5 heat structure – 1D heat conduction only • One bundle modeled using SCDAP fuel rod component – 2D heat conduction, oxidation, ballooning and rupture, material liquefaction

5. Influence of SA models starting below 1500 K Fuel rod temperature above midpoint SCDAP predicted temperatures RELAP RELAP predicted temperatures Time (s)

6. Oxidation heat generation comparable to decay heat Power - Kw Decay heat Oxidation heat generation

7. Oxidation limited by Zr relocation Maximum bundle temperature - K Maximum temperature Hydrogen production – g/s Hydrogen production

8. Axial temperature distribution Temperature - K U-Zr-O relocation Dryout Bottom Top

9. Oxidation front starts above midpoint H2 generation rate – g/s Zr melt relocation

10. Ballooning and rupture occurs near 1000 K Hoop Strain Temperature

11. Zr-O-U Relocation to lower portion of bundle Fuel outer radius including frozen crust Temperature

12. CORA-13 PWR Quench • Electrically heated PWR bundle • 25 rods (16 fuel rods, 7 heated fuel rod simulators, 2 Ag-In-Cd control rods) • 1.00 m heated length • Constant steam/argon flow

13. Oxidation heat generation during reflood >> electrical heating Power - Kw Note: Electrical power shutdown prior to quench Oxidation heat generation Quench Decay heat

14. Oxidation during reflood results in temperature excursion and renewed melting Maximum bundle temperature - K Maximum temperature Hydrogen production – g/s Hydrogen production Quench

15. Axial temperature distribution Renewed heating in upper bundle due to reflood Temperature - K Bottom Top

16. Oxidation of liquid U-O-Zr signficant during reflood H2 generation rate – g/s Zr melt relocation

17. Ballooning and rupture occurs near 1200 K Hoop Strain Temperature

18. Zr-O-U Relocation to lower portion of bundle U-Zr-O freezing Ballooning Fuel outer radius including frozen crust Temperature

19. TMI-2 • The TMI-2 problem is described in the SCDAP/RELAP5/MOD3.2 reference manual (Volume V) • General description (Section 5.5) • Input model description (Appendix A.11) • TMI-2 sample problem on CD includes • Restart plot file • Sample input file (restarting after B-pump transient and formation of initial molten pool) • Sample plot input file

20. TMI-2 Core Nodalization

21. Calculated peak core temperatures and pressures for TMI-2 Temperature Pressure Core uncovery B-pump Transient ECCS Injection

22. Rapid Zircaloy oxidation resulted in initial liquefaction and relocation of core metals Liquefaction of UO2 and ZrO2 Melting of Zr Control rod melt relocation, onset of rapid oxidation Fuel temperatures

23. B-Pump Transient resulted in sharp increase in oxidation in middle of core Oxidation rate B-pump Transient Peak core temperature

24. B-Pump transient cooled lower portion of core Axial nodes 3-5 Fuel temperatures

25. Molten {(U-Zr)-O2} pool continued to grow after water injection B-pump Transient Molten pool radius in core

26. Molten (U-Zr)-O2 relocates into LP after ECCS injection Temp. of melt in LP Melt relocation into LP Height of debris in LP ECCS Injection