Criticality Safety and Sensitivity Analyses of PWR Spent Nuclear Fuel Repository Facilities

Presently, a criticality safety evaluation methodology for the final geological disposal of Swiss spent nuclear fuel is under development at the Paul Scherrer Institute in collaboration with the Swiss National Technical Competence Centre in the field of deep geological disposal of radioactive waste. This method in essence pursues a best estimate plus uncertainty approach and includes burnup credit. Burnup credit is applied by means of a computational scheme called BUCSS-R (Burnup Credit System for the Swiss Reactors–Repository case) which is complemented by the quantification of uncertainties from various sources. BUCSS-R consists in depletion, decay and criticality calculations with CASMO5, SERPENT2 and MCNP6, respectively, determining the keff eigenvalues of the disposal canister loaded with the Swiss spent nuclear fuel assemblies. However, the depletion calculation in the first and the criticality calculation in the third step, in particular, are subject to uncertainties in the nuclear data input. In previous studies, the effects of these nuclear data-related uncertainties on obtained keff values, stemming from each of the two steps, have been quantified independently. Both contributions to the overall uncertainty in the calculated keff values have, therefore, been considered as fully correlated leading to an overly conservative estimation of total uncertainties. This study presents a consistent approach eliminating the need to assume and take into account unrealistically strong correlations in the keff results. The nuclear data uncertainty quantification for both depletion and criticality calculation is now performed at once using one and the same set of perturbation factors for uncertainty propagation through the corresponding calculation steps of the evaluation method. The present results reveal the overestimation of nuclear data-related uncertainties by the previous approach, in particular for spent nuclear fuel with a high burn-up, and underline the importance of consistent nuclear data uncertainty quantification methods. However, only canister loadings with UO2 fuel assemblies are considered, not offering insights into potentially different trends in nuclear data-related uncertainties for mixed oxide fuel assemblies.

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The Reality of Criticality Safety Control of Spent Nuclear Fuel ; A Concept of Burnup Credit and the Topics for It’s Introduction

Journal of the Atomic Energy Society of Japan ◽

10.3327/jaesjb.51.5_391 ◽

2009 ◽

Vol 51 (5) ◽

pp. 391-395

Author(s):

Kenya SUYAMA

Keyword(s):

Nuclear Fuel ◽

Spent Nuclear Fuel ◽

Safety Control ◽

Criticality Safety

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Preliminary Assessment of Criticality Safety Constraints for Swiss Spent Nuclear Fuel Loading in Disposal Canisters

Materials ◽

10.3390/ma12030494 ◽

2019 ◽

Vol 12 (3) ◽

pp. 494

Author(s):

Alexander Vasiliev ◽

Jose Herrero ◽

Marco Pecchia ◽

Dimitri Rochman ◽

Hakim Ferroukhi ◽

...

Keyword(s):

Fuel Assembly ◽

Nuclear Fuel ◽

Spent Nuclear Fuel ◽

Operating Conditions ◽

Design Parameters ◽

Fuel Loading ◽

Pressurized Water ◽

Fuel Assemblies ◽

National Cooperative ◽

Criticality Safety

This paper presents preliminary criticality safety assessments performed by the Paul Scherrer Institute (PSI) in cooperation with the Swiss National Cooperative for the Disposal of Radioactive Waste (Nagra) for spent nuclear fuel disposal canisters loaded with Swiss Pressurized Water Reactor (PWR) UO2 spent fuel assemblies. The burnup credit application is examined with respect to both existing concepts: taking into account actinides only and taking into account actinides plus fission products. The criticality safety calculations are integrated with uncertainty quantifications that are as detailed as possible, accounting for the uncertainties in the nuclear data used, fuel assembly and disposal canister design parameters and operating conditions, as well as the radiation-induced changes in the fuel assembly geometry. Furthermore, the most penalising axial and radial burnup profiles and the most reactive fuel loading configuration for the canisters were taken into account accordingly. The results of the study are presented with the help of loading curves showing what minimum average fuel assembly burnup is required for the given initial fuel enrichment of fresh fuel assemblies to ensure that the effective neutron multiplication factor, keff, of the canister would comply with the imposed criticality safety criterion.

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Sensitivity analysis of parameters important to nuclear criticality safety of Castor X/28F spent nuclear fuel cask

Kerntechnik ◽

10.3139/124.110541 ◽

2015 ◽

Vol 80 (5) ◽

pp. 485-493 ◽

Cited By ~ 3

Author(s):

M.J. Leotlela ◽

I. Malgas ◽

E. Taviv

Keyword(s):

Sensitivity Analysis ◽

Nuclear Fuel ◽

Spent Nuclear Fuel ◽

Nuclear Criticality Safety ◽

Criticality Safety

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SFCOMPO DATABASE OF SPENT NUCLEAR FUEL ASSAY DATA – THE NEXT FRONTIER

EPJ Web of Conferences ◽

10.1051/epjconf/202124710019 ◽

2021 ◽

Vol 247 ◽

pp. 10019

Author(s):

Germina Ilas ◽

Ian Gauld ◽

Pedro Ortego ◽

Shuichi Tsuda

Keyword(s):

Nuclear Fuel ◽

Spent Nuclear Fuel ◽

Critical Evaluation ◽

Working Party ◽

Test Bed ◽

Reactor Physics ◽

Current Effort ◽

Energy Agency ◽

Physics Experiment ◽

Criticality Safety

SFCOMPO is the world’s largest database for measured spent nuclear fuel assay data. An international effort coordinated by the Nuclear Energy Agency (NEA) resulted in a significant expansion of the database and its release online in 2017 as a downloadable application. The SFCOMPO Technical Review Group (TRG) was recently formed under the direction of NEA’s Nuclear Science Committee/Working Party on Nuclear Criticality Safety and was mandated to maintain and further coordinate the development of SFCOMPO. This TRG is currently focused on (1) critical evaluation of the experimental assay data by independent experts and (2) development of benchmarks and benchmark models that can be applied to validate burnup codes. This will improve the quality and documentation of the experimental datasets and enable their use by the international community to support code validation for design and safety analysis of spent nuclear fuel transportation, storage, and repository applications. It follows the precedent and draws on the experience gained from similar NEA efforts in the International Reactor Physics Experiment Evaluation Project and the International Criticality Safety Benchmark Experiment Project. Ongoing SFCOMPO evaluations have served as a test bed to develop templates for documenting evaluations, develop review guidance, improve approaches for a global uncertainty analysis, and devise a strategy focused on providing practical information of highest value to the user community. The current effort, status, and associated challenges are discussed.

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Neutron Activation of Structural Materials of a Dry Storage System for Spent Nuclear Fuel and Implications for Radioactive Waste Management

Energies ◽

10.3390/en13205325 ◽

2020 ◽

Vol 13 (20) ◽

pp. 5325

Author(s):

Se Geun Lee ◽

Jae Hak Cheong

Keyword(s):

Radioactive Waste ◽

Waste Management ◽

Nuclear Fuel ◽

Spent Nuclear Fuel ◽

Storage Systems ◽

Storage System ◽

Residual Activity ◽

Sensitivity Analyses ◽

Dry Storage ◽

Residual Radioactivity

In order to estimate the radiological characteristics of disused dry storage systems for spent nuclear fuel, a stepwise framework to calculate neutron sources (ORIGEN-ARP), incident neutron flux and reaction rate (MCNPX), effective cross-section (hand calculation), and residual activity (ORIGEN-2) was established. Applicability of the framework was demonstrated by comparing the residual activity of a commercialized storage system, HI-STORM 100, listed in the safety analysis report and calculated in this study. For a reference case assuming an impurity-free storage system, the modified effective cross-sections were theoretically interpreted and the need for managing disused components as a radioactive waste for at least four years was demonstrated. Sensitivity analyses showed that the higher burnup induces the higher residual radioactivity, and the impurity 59Co may extend the minimum decay-in-storage period up to 51 years within the reported range of 59Co content in stainless steel. The extended long-term storage over 100 years, however, caused no significant increase in residual radioactivity. Impurity control together with appropriate decay-in-storage was proposed as an effective approach to minimize the secondary radioactive waste arising from disused dry storage systems. The results of this study could be used to optimize the decommissioning and waste management plan regarding interim storage of spent fuel.

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Post-Closure Safety Calculations for the Disposal of Spent Nuclear Fuel in a Generic Horizontal Drillhole Repository

Energies ◽

10.3390/en13102599 ◽

2020 ◽

Vol 13 (10) ◽

pp. 2599 ◽

Cited By ~ 1

Author(s):

Stefan Finsterle ◽

Richard A. Muller ◽

John Grimsich ◽

John Apps ◽

Rod Baltzer

Keyword(s):

Nuclear Fuel ◽

Spent Nuclear Fuel ◽

Uncertainty Propagation ◽

Radioactive Decay ◽

Transport Processes ◽

Sensitivity Analyses ◽

Annual Dose ◽

Performance Metric ◽

Safety Function ◽

Wide Range

The post-closure performance of a generic horizontal drillhole repository for the disposal of spent nuclear fuel (SNF) is quantitatively evaluated using a physics-based numerical model that accounts for coupled thermal-hydrological flow and radionuclide transport processes. The model incorporates most subcomponents of the repository system, from individual waste canisters to the geological far field. The main performance metric is the maximum annual dose to an individual drinking potentially contaminated water taken from a well located above the center of the repository. Safety is evaluated for a wide range of conditions and alternative system evolutions, using deterministic simulations, sensitivity analyses, and a sampling-based uncertainty propagation analysis. These analyses show that the estimated maximum annual dose is low (on the order of 10−4 mSv yr−1, which is 1000 times smaller than a typical dose standard), and that the conclusions drawn from this dose estimate remain valid even if considerable changes are made to key assumptions and property values. The depth of the repository and the attributes of its configuration provide the main safety function of isolation from the accessible environment. Long-term confinement of radionuclides in the waste matrix and slow, diffusion-dominated transport leading to long migration times allow for radioactive decay to occur within the repository system. These preliminary calculations suggest that SNF can be safely disposed in an appropriately sited and carefully constructed and sealed horizontal drillhole repository.

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