EXISTING GUIDANCE/ METHODOLOGY FOR SPENT FUEL POOLS

3.2EXISTING GUIDANCE/ METHODOLOGY FOR SPENT FUEL POOLS

The L2 PSA methodology mentioned e.g. in ASAMPSA2 [1] consists of the following activities:

• 
  Plant familiarization;
  
• 
  Definition of the L2 PSA objectives;
  
• 
  Accident Sequence Analysis, Analysis of Phenomena, Source Term Analysis;
  
• 
  Containment Analysis;
  
• 
  Human Reliability Analysis;
  
• 
  Systems Analysis;
  
• 
  Event Tree Modelling;
  
• 
  Quantification of Event Trees, Results, Presentation, and Interpretation;
  
• 
  Documentation.
  

“C: The PSA shall check that potential radioactive releases from the spent fuel storage pool, from the spent fuel handling facilities and from the radioactive waste storage tanks can be reasonably neglected, due to their comparatively low magnitude and to their low frequency.”

• 
  transfer canal (if applicable) between SFP and reactor building pool;
  

• 
  opened,
  
• 
  closed,
  

• 
  amount of fuel offloaded to the SFP;
  

• 
  complete core offload,
  
• 
  partial core offload,
  

• 
  reloading of new fuel;
  
• 
  fuel movement complete;
  
• 
  amount of cooling water in the SFP.
  

Note that this section covers issues that can be of interest for the SFP PSA for a plant to be commissioned or already in operation.

• 
  drain-down events/ sequences,
  
• 
  loss of cooling events/ sequences (or non-draining IEs).
  

Draining events may be caused by inappropriate operator action, seismic induced structural failures, heavy load drops, loss of coolant accidents (LOCAs), and reactor-related phenomena causing structural failure (e.g. steam explosion, hydrogen detonation). For non-draining events, the set of initiating events can be derived from an analysis of the situations leading to the temperature increase, i.e. to the loss of the cooling system, which may be due either to malfunctions in the cooling system itself or its support functions including electrical supply or the cooling chain. In L1 PSA, it is necessary to study each plant state (POS) because of the different configurations or characteristics of structural failures and support systems of electrical supply or cooling chain. Also, the timing of the release is very dependent on the sequence/ initiating event. This is also important for operator actions. However in L2 PSA it is almost irrelevant which particular combination of initiating event and failure has led to loss of cooling or draining and loss of coolant.

• 
  loss of cooling to the SFP (including failure of support systems and loss of power);
  
• 
  coolant inventory loss from the SFP;
  

• 
  heavy load drops,
  
• 
  loss of coolant accidents (LOCAs),
  
• 
  reactor-related phenomena causing structural failure,
  

• 
  reactivity accidents;
  
• 
  seismic events;
  
• 
  simultaneous failures related to the initiating event.
  

As far as criticality is concerned the following scenario can be considered: if the stored assemblies are separated by neutron absorber plates (e.g., Boral or Boraflex), loss of these plates could result in a potential criticality. The absorber plates are generally enclosed by cover plates (stainless steel or aluminium alloy). The tolerances of cover plates tend to prevent any appreciable fragmentation and movement of the enclosed absorber material. The total loss of the welded cover plate is not considered feasible.

• 
  random independent failures that challenge the cooling of used fuel in the SFP (i.e., reactor core is in a safe stable configuration),
  
• 
  common or simultaneous failures that challenge both adequate core cooling and SFP cooling,
  
• 
  consequential severe accident progression events that may lead to challenges to the integrity of the SFP and the continued cooling of used fuel.
  

According to EPRI [21] critical elements of the PSA framework need to describe the following methodology issues:

• 
  the interrelationship of the PSA logic models as they influence the probabilistic assessment of the continued cooling of the used fuel in the SFP;
  
• 
  L2 Full Power Internal Events PSA sequences transferring to the SFP event tree structures;
  
• 
  L2 Shutdown PSA sequences transferring to the SFP event tree.
  

The key phenomena for the analysis of the risk profile associated with operation of the SFP and the reactor lead to the following issues:

• 
  equipment failures;
  
• 
  containment failures;
  
• 
  inaccessibility for local actions;
  
• 
  fuel disruption;
  
• 
  reactor Building equipment failures;
  
• 
  reactor Building and SFP structural failures;
  
• 
  increase in radionuclide releases.
  

These phenomenological events are related to the postulated core/fuel melt progression within the reactor or the SFP. A general framework has been applied to pilot project to address the technical elements employed in PSA, consistent with the guidance provided in the ASME/ANS PRA Standard [26].

It seems that the increased risk associated with interactions between the reactor and containment systems, and the SFP should be treated in an integrated way. These interactions during a severe accident can have an impact on the total risk of radioactive release (in early and late phases) in the environment around the plant.

The analysis of used fuel accident scenarios requires analytical tools and methods including the following: deterministic models that address important accident progression details; realistic assessment of seismic fragilities; fault tree models focused on systems and configurations generating unwanted interactions between the event progression in the reactor cooling system and the SFP protection system; and consideration of operator actions in response to events affecting SFP cooling.
The interaction between primary containment and SFP in case when the reactor building houses the primary containment and the SFP can be of particular importance. The events involving primary containment also have the potential to cause reactor building or secondary containment challenges. In such cases, there is a potential that primary containment scenarios could lead to SFP events. Such scenarios may involve degraded conditions where reactor core damage is avoided but not SFP. On the other hand, reactor core damage events could be affected by a subsequent SFP fuel damage event initiated by primary containment failure modes.
Severe accident with containment failure as a result of a severe accident can lead to both a significant radiation release to the reactor building plus a combustible gas mixture discharge inside the building. This combination of effects is expected to fail equipment in the building and preclude access for any local actions, also limiting or precluding access to the refuel floor. As long as the SFP itself is not damaged, an extended time is available before fuel damage in the SFP would occur. However, overcoming the lack of access to the refuel floor could present a lingering problem. Solutions could be to prepare injection to the SFP prior to the containment failure, or alternatively, if an installed secure injection path is available.
The following section addresses those issues which are specific for SFD events, and which need consideration in guidance for an extended PSA.