16 th December 2008 UK’s MELCOR and Severe Accident Activities and User Experiences Under Low UK’s MELCOR and Severe Accident Activities and User Experiences Under Low UK’s MELCOR and Severe Accident Activities and User Experiences Under Low UK’s MELCOR and Severe Accident Activities and User Experiences Under Low Flow, Low Decay Heat Conditions Flow, Low Decay Heat Conditions Flow, Low Decay Heat Conditions Flow, Low Decay Heat Conditions Presentation to European MELCOR Users Meeting Presented by Dr. Martin Turner Severe accidents – TAS, Serco
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UKs MELCOR and Severe Accident Activities M. Turner [Read … · 2020-01-09 · Suppose there is a failure of onboard safety systems, consider the accident occurring out in the middle
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16th December 2008
UK’s MELCOR and Severe Accident Activities and User Experiences Under Low UK’s MELCOR and Severe Accident Activities and User Experiences Under Low UK’s MELCOR and Severe Accident Activities and User Experiences Under Low UK’s MELCOR and Severe Accident Activities and User Experiences Under Low
� Future involvement in MELCOR use and research by Se rco
� Conclusions.
SARNET, UK and SercoSARNET, UK and SercoSARNET, UK and SercoSARNET, UK and Serco
� UK is a member of SARNET.
� National Nuclear lab and Newcastle University are actively involved in the programme
� Possibility of Serco investing in the programme.
� Winfrith site involved in CORA tests in late 1990s.
� Winfrith used MELCOR for VVER severe accident analysis in Armenia up to 2001.
� Risley involved in PHEBUS FTP1 MELCOR assessments.
� Majority of MELCOR use is presently for Naval MOD research work at Risley, Warrington.
� Newcastle University highly active in SARNET with ARTIST.
Risley, Warrington
London
Winfrith, Dorset
Newcastle
UK SubmarinesUK SubmarinesUK SubmarinesUK Submarines
� Pioneering early submarines developed and deployed in the River Thames near London in 1620s.
� First British military submarine, Holland Class lau nched in 1901.
� UK naval fleet have been nuclear powered since HMS Dreadnought in 1960.
� Naval PWR reactors are typically smaller and are di fferent to typical commercially available reactors.
Severe Accident Research in the UK for Naval FleetSevere Accident Research in the UK for Naval FleetSevere Accident Research in the UK for Naval FleetSevere Accident Research in the UK for Naval Fleet
� UK’s nuclear safety record onboard submarine’s is world class. No major nuclear related accident or contaminations.
� The UK has developed its own severe accident code, UKSA, specifically for the naval MOD severe accidents research.
� MELCOR has been shown to be a valid and important code for independent verification of UKSA.
� Much insight has been gained from using MELCOR as a secondary code.
Comparison of Key Quantities and Timings.Comparison of Key Quantities and Timings.Comparison of Key Quantities and Timings.Comparison of Key Quantities and Timings.
Event in LOCA Study UKSA MELCORTime for the hottest fuel element to reach T`C 101. 2% 100%
No. of fuel nodes covered at T`C 113.6% 100%
Time to the start of core melt 101.3% 100%
No. of fuel nodes covered at the start of fuel melt . 200% 100%
Time to the start of quenching 102.0% 100%
RPV water mass at the start of debris quenching 81. 2% 100%
Total hydrogen generated 309.2% 100%
Peak RC Pressure 107.3% 100%
Comparison of Key Quantities and Timings.Comparison of Key Quantities and Timings.Comparison of Key Quantities and Timings.Comparison of Key Quantities and Timings.
Event in ICF Study UKSA MELCORTime to First Relief Valve Lift 93.7% 100%
Time when RPV Coolant Begins to Boil 98.3% 100%
Time to core uncovery 95.3% 100%
Time to the start of core melt 98.7% 100%
Time to which molten debris first enters the lower plena 96.4% 100%
� Probabilistic Safety Assessments include the possib ility of a post-trip(SCRAM) loss of heat sink accident at low decay heats.
� Suppose there is a failure of onboard safety system s, consider the accident occurring out in the middle of an ocean.
� In such circumstances, assistance may take many hou rs-days to arrive. Accurate prediction of time to core melt, c lad rupture and containment atmosphere are needed to guide procedur e.
� Complete loss of heat sink during post-shutdown.
� This is a high pressure accident.
� The Pressure Relief System was modelled as simple f low paths which discharge water in the Containment once the p ressure reaches particular set points.
� Bulk boiling occurs.
� Core heat up due to uncovery - > oxidation reaction -> core melt, relocation and blockage.
Clad TemperatureClad TemperatureClad TemperatureClad Temperature
Pressure Offset in TimePressure Offset in TimePressure Offset in TimePressure Offset in Time
Partial Pressure of Steam
0
2000000
4000000
6000000
8000000
10000000
12000000
14000000
16000000
18000000
20000000
400000 600000 800000 1000000 1200000 1400000
time [sec]
Pre
ssur
e [P
a]
CVH-PPART.3.109
Heat Transfer Coefficients Heat Transfer Coefficients Heat Transfer Coefficients Heat Transfer Coefficients –––– problems at low flowproblems at low flowproblems at low flowproblems at low flow
� Developed flow scale factor in parenthesis is set s uch that ∆∆∆∆z = 1000m.
� Laminar Forced convection dominates in MELCOR in lo w flow regimes.
� However Ra<Ra c - for superheated steam.
� 4.36 Scale factor is user defined.
� Default of C(1212) = 4.36 also affects calculation of Sherwood Number used for calculating oxidation rate when lim ited by hydrogen diffusion.
∆++=
Pr.Re.0011.0
00826.0136.4
hD
zNu
Comparison of Nusselt’s Number correlationsComparison of Nusselt’s Number correlationsComparison of Nusselt’s Number correlationsComparison of Nusselt’s Number correlations
Clad Temperature when C1212=0Clad Temperature when C1212=0Clad Temperature when C1212=0Clad Temperature when C1212=0
� corcnv.f hard-codes pool heat transfer coefficient to 1000 W/(m 2K):C *** SHOULD EQUIVALENCE HTCONV WITH SENSITIVITY COEFFICIENT
DATA HTCONV /1000.D0/
Future of Severe Accidents Research in the UKFuture of Severe Accidents Research in the UKFuture of Severe Accidents Research in the UKFuture of Severe Accidents Research in the UK
� More active and continued roll in SARNET.
� Newcastle University heavily involved in ARTIST.
� Expertise at Newcastle in aerosol behaviour and mul ti-layer re-suspension.
� Newcastle University are committed to supporting th e SARNET community with ARTIST2.
� Imperial College look to using thermohydraulics-rea ctor physics code FLUIDICS for SARNET assessments.
� Imperial College will further develop couple balloo ning models.
Future of Severe Accidents Research in the UKFuture of Severe Accidents Research in the UKFuture of Severe Accidents Research in the UKFuture of Severe Accidents Research in the UK
� Naval research application of MELCOR, very likely t o continue, with a view in the longer term to MELCOR’s containm ent capabilities.
� UK is committed to a large scale civil nuclear prog ramme. Serco at Winfrith, the civil side of our business may loo k to a more active roll in MELCOR in the future for new build a ssessments and research.
� Possibility of using FARO tests for MELCOR assessme nts.
� New Naval severe accident research experiments plan ned.
� Broad agreement between totally independent codes, MELCOR and UKSA except in hydrogen production and rate of melt .
� COR heat transfer correlation under review for low decay heat, loss of heat sink accident.
� Questions raised in MELCOR capabilities in high hyd rogen concentrations and low flow conditions.
� Need for ballooning model is identified, but soluti ons are in development. May require to simulate the physics in MELCOR using tables.
� Serco are serious about contributing to the severe accident international community and is committed to MELCOR as an essentia l independent and extremely powerful accident analysis tool.