Quantifying water in spent fuel assemblies with neutrons: A simulation-based approach

The Fukushima nuclear disaster has raised the importance on the reliability and risk research of the spent fuel pool (SFP), including the risk of internal events, fire, external hazards and so on. From a safety point of view, the low decay heat of the spent fuel assemblies and large water inventory in the SFP has made the accident progress goes very slow, but a large number of fuel assemblies are stored inside the spent fuel pool and without containment above the SFP building, it still has an unignored risk to the safety of the nuclear power plant. In this paper, a standardized approach for performing a holistic and comprehensive evaluation approach of the SFP risk based on the probabilistic safety analysis (PSA) method has been developed, including the Level 1 SFP PSA and Level 2 SFP PSA and external hazard PSA. The research scope of SFP PSA covers internal events, internal flooding, internal fires, external hazards and new risk source-fuel route risk is also included. The research will provide the risk insight of Spent Fuel Pool operation, and can help to make recommendation for the prevention and mitigation of SFP accidents which will be applicable for the SFP configuration risk management.

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Development of a Thermal Analysis Model for a Nuclear Spent Fuel Storage Cask and Experimental Verification With Prototype Testing

Journal of Engineering for Gas Turbines and Power ◽

10.1115/1.3240306 ◽

1989 ◽

Vol 111 (4) ◽

pp. 647-651 ◽

Cited By ~ 5

Author(s):

J. Y. Hwang ◽

L. E. Efferding

Keyword(s):

Thermal Analysis ◽

Storage Period ◽

Department Of Energy ◽

Pressurized Water Reactor ◽

Spent Fuel ◽

Analysis Model ◽

Pressurized Water ◽

Fuel Assemblies ◽

Spent Fuel Storage ◽

Fuel Storage

A thermal analysis evaluation is presented of a nuclear spent fuel dry storage cask designed by the Westinghouse Nuclear Components Division. The cask is designed to provide passive cooling of 24 Pressurized Water Reactor (PWR) spent fuel assemblies for a storage period of at least 20 years at a nuclear utility site (Independent Spent Fuel Storage Installation). A comparison is presented between analytical predictions and experimental results for a demonstration cask built by Westinghouse and tested under a joint program with the Department of Energy and Virginia Power Company. Demonstration testing with nuclear spent fuel assemblies was performed on a cask configuration designed to store 24 intact spent fuel assemblies or canisters containing fuel consolidated from 48 assemblies.

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Nondestructive assay of fission products in spent-fuel assemblies using gamma and photoneutron activation

Nuclear Instruments and Methods in Physics Research Section A Accelerators Spectrometers Detectors and Associated Equipment ◽

10.1016/0168-9002(90)90826-r ◽

1990 ◽

Vol 299 (1-3) ◽

pp. 463-467 ◽

Cited By ~ 5

Author(s):

L. Lakosi ◽

Á. Veres

Keyword(s):

Fission Products ◽

Spent Fuel ◽

Nondestructive Assay ◽

Fuel Assemblies

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Analysis of Differential Die Away Instrument Simulated Performance Using Boiling Water Reactor Spent Fuel Assemblies

10.2172/1131010 ◽

2014 ◽

Cited By ~ 1

Author(s):

Vladimir Henzl ◽

Holly R. Trellue ◽

Noah A. Fischer ◽

Robert A. Jr. Weldon

Keyword(s):

Boiling Water ◽

Boiling Water Reactor ◽

Spent Fuel ◽

Water Reactor ◽

Simulated Performance ◽

Fuel Assemblies

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Temperature conditions in the RBMK spent fuel pool in the event of disturbances in its cooling mode

Nuclear Energy and Technology ◽

10.3897/nucet.7.64363 ◽

2021 ◽

Vol 7 (1) ◽

pp. 9-13

Author(s):

David A. Hakobyan ◽

Victor I. Slobodchuk

Keyword(s):

Nuclear Power ◽

Power Plants ◽

Nuclear Power Plants ◽

Spent Nuclear Fuel ◽

Maximum Temperature ◽

Spent Fuel ◽

Cooling Mode ◽

Temperature Conditions ◽

Fuel Assemblies ◽

Spent Fuel Pool

The problems of reprocessing and long-term storage of spent nuclear fuel (SNF) at nuclear power plants with RBMK reactors have not been fully resolved so far. For this reason, nuclear power plants are forced to search for new options for the disposal of spent fuel, which can provide at least temporary SNF storage. One of the possible solutions to this problem is to switch to compacted SNF storage in reactor spent fuel pools (SFPs). As the number of spent fuel assemblies (SFAs) in SFPs increases, a greater amount of heat is released. In addition, no less important is the fact that a place for emergency FA discharging should be provided in SFPs. The paper presents the results of a numerical simulation of the temperature conditions in SFPs both for compacted SNF storage and for emergency FA discharging. Several types of disturbances in normal SFP cooling mode are considered, including partial loss of cooling water and exposure of SFAs. The simulation was performed using the ANSYS CFX software tool. Estimates were made of the time for heating water to the boiling point, as well as the time for heating the cladding of the fuel elements to a temperature of 650 °С. The most critical conditions are observed in the emergency FA discharging compartment. The results obtained make it possible to estimate the time that the personnel have to restore normal cooling mode of the spent fuel pool until the maximum temperature for water and spent fuel assemblies is reached.

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Criticality safety analysis of spent fuel pool for a PWR using UO2, MOX, (Th-U)O2 and (TRU-Th)O2 fuels

Brazilian Journal of Radiation Sciences ◽

10.15392/bjrs.v7i3a.833 ◽

2019 ◽

Vol 7 (3A) ◽

Author(s):

Claubia Pereira ◽

Jéssica P. Achilles ◽

Fabiano Cardoso ◽

Victor F. Castro ◽

Maria Auxiliadora F. Veloso

Keyword(s):

Normal Operation ◽

Pressurized Water Reactor ◽

Spent Fuel ◽

Pressurized Water ◽

Operation Conditions ◽

Transport Code ◽

Uranium Fuel ◽

Fuel Assemblies ◽

Spent Fuel Pool ◽

Criticality Safety

A spent fuel pool of a typical Pressurized Water Reactor (PWR) was evaluated for criticality studies when it uses reprocessed fuels. PWR nuclear fuel assemblies with four types of fuels were considered: standard PWR fuel, MOX fuel, thorium-uranium fuel and reprocessed transuranic fuel spiked with thorium. The MOX and UO2 benchmark model was evaluated using SCALE 6.0 code with KENO-V transport code and then, adopted as a reference for other fuels compositions. The four fuel assemblies were submitted to irradiation at normal operation conditions. The burnup calculations were obtained using the TRITON sequence in the SCALE 6.0 code package. The fuel assemblies modeled use a benchmark 17x17 PWR fuel assembly dimensions. After irradiation, the fuels were inserted in the pool. The criticality safety limits were performed using the KENO-V transport code in the CSAS5 sequence. It was shown that mixing a quarter of reprocessed fuel withUO2 fuel in the pool, it would not need to be resized

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