Near-Field Modelling in the Safety Assessment SR-Can

Radionuclide Transport Calculations in the Safety Assessment SR 97

MRS Proceedings ◽

10.1557/proc-663-773 ◽

2000 ◽

Vol 663 ◽

Author(s):

M. Lindgren ◽

F. Lindström

Keyword(s):

Input Data ◽

Safety Assessment ◽

Spent Nuclear Fuel ◽

Near Field ◽

Radionuclide Transport ◽

Spent Fuel ◽

Release Rates ◽

Dose Limits ◽

The Impact ◽

Different Parts

ABSTRACTThis study treats radionuclide transport calculations for a canister defect scenario in the safety assessment SR 97, which concerns a deep repository for spent nuclear fuel of the KBS-3 type in Sweden. The aims of the calculations are to:Quantitatively describe the radionuclide transport.Show the impact of uncertainty in input data and show which parameters govern the calculated release rates.Compare three different real sites in Sweden (Aberg, Beberg and Ceberg) with each other and with dose limits given in Swedish regulations (none of the sites is considered in the on-going localization process). Only briefly described in this paper.Illustrate the impact of the different barriers in the system.Deterministic calculations illustrate the radionuclide transport for reasonable conditions. Uncertainty cases show the influence of the uncertainty for data related to different parts of the repository system by systematically giving them pessimistic values while all others are reasonable. Simplified probabilistic calculations have also been performed.The analysis shows that the most important parameters in the near field are the number of defective canisters and the instant release fraction. In the far field the most important uncertainties affecting release and retention are connected to permeability and connectivity of the fractures in the rock. The dose rate in the biosphere is essentially controlled by the possibilities of dilution.The calculated maximum doses for the hypothetical repositories are well below the dose limits, and hence they meet the acceptance criteria for a deep repository for spent fuel.

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Near field evolution of a spent fuel repository in an argillaceous rock formation and impact on radionuclide migration

10.5194/egusphere-egu2020-6079 ◽

2020 ◽

Author(s):

Vanessa Montoya ◽

Orlando Silva ◽

Emilie Coene ◽

Jorge Molinero ◽

Renchao Lu ◽

...

Keyword(s):

Ion Exchange ◽

Radioactive Waste ◽

Nuclear Fuel ◽

Reactive Transport ◽

Spent Nuclear Fuel ◽

Near Field ◽

Spent Fuel ◽

Exchange Reactions ◽

Radionuclide Migration ◽

High Level

In August 2015, the German government approved the national programme for the responsible and safe management of spent nuclear fuel (SNF) and radioactive waste proposed by the Federal Ministry for the Environment, Nature Conservation, Building and Reactor Safety (BMU). The assumption is that about ~ 1 100 storage casks (10 500 tons of heavy metal) in the form of spent fuel assemblies will be generated in nuclear power plants and will have to be disposed. However, a decision on the disposal concept for high-level waste is pending and an appropriate solution has to be developed with a balance in multiple aspects. All potential types of host rocks, clay and salt stones as well as crystalline formations are under consideration. In the decision process, evaluation of the risk of different waste management options and scenarios play an enormous role in the discussion. Coupled physical and chemical processes taking place within the engineered barrier system of a repository for high-level radioactive waste will define the radionuclide mobility/retention and the possible radiological impact. The objective of this work is to assess coupled processes occurring in the near-field of a generic repository for spent nuclear fuel in a high saline clay host rock, integrating complex geochemical processes at centimetre-scale. The scenario considers that radionuclides can be released during a period of thousands of years after full saturation of the bentonite barrier and the thermal phase.Transport parameters and the discretization of the system, are implemented in a 2D axisymmetric geometry. The multi-barrier system is emplaced in clay and a solubility limited source term for the selected radionuclides is assumed. Kinetics and chemical equilibria reactions are simulated using parameters obtained from experiments. Additionally, porosity changes due to mineral precipitation/dissolution and feedback on the effective diffusion coefficient are taken into account. Protonation/deprotonation, ion exchange reactions and radionuclide inner-sphere sorption is considered.Numerical simulations show, that, when the canister corrosion starts, the redox potential decreases, magnetite precipitates and H2 is formed. Furthermore, the aqueous concentration of Fe(II) increases due to the presence of magnetite. By considering binding to montmorillonite via ion exchange reactions, the bentonite acts as a sink for Fe(II). Additionally, magnetite forms a chemical barrier offering significant sorption capacity for many radionuclides. Finally, a decrease of porosity in the bentonite/canister interface leads to a further deceleration of radionuclide migration. Due to the complexity of reactive transport processes in saline environments, benchmarking of reactive transport models (RTM) is important also to build confidence in those modelling approaches. Development of RTM benchmark procedures is part of the iCROSS project (Integrity of nuclear waste repository systems - Cross-scale system understanding and analysis) funded by both the Helmholtz Association and the Federal Ministry of Education and Research (BMBF).&#160;

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SR 97: Spent Fuel Alteration/Dissolution and the Influence of Near Field Hydrogen

MRS Proceedings ◽

10.1557/proc-663-765 ◽

2000 ◽

Vol 663 ◽

Cited By ~ 1

Author(s):

Kastriot Spahiu ◽

Patrik Sellin

Keyword(s):

Uranium Dioxide ◽

Safety Assessment ◽

Spent Nuclear Fuel ◽

Near Field ◽

Limiting Factor ◽

Water Radiolysis ◽

Spent Fuel ◽

Reducing Conditions ◽

S Matrix ◽

The Matrix

ABSTRACTA discussion of the evaluation of the source term in the SR 97 safety assessment of a deep repository for spent nuclear fuel is presented. Since the majority of the radionuclides are embedded in the uranium dioxide fuel matrix, they will be released only after the alteration/dissolution of the matrix. Therefore a description of the process of alteration/dissolution of the spent fuel matrix is needed in a safety assessment.Under normal repository conditions, i.e. reducing environment and neutral to alkaline pH, uranium dioxide has a very low solubility in water. If solubility is assumed to be the limiting factor, the dissolution of the fuel matrix will proceed very slowly due to the low water exchange in the defective canister. On this basis, a solubility-limited model for the release of the radionuclides from the fuel may be formulated.The reducing conditions can be upset by the radioactivity of the spent fuel, which generates oxidizing products through water radiolysis. This causes the oxidative alteration/dissolution of the UO2(s) matrix. A model for fuel matrix conversion resulting from radiolytic oxidative dissolution is discussed, as well as parameter variations and the associated uncertainties.In a repository the spent fuel will come in contact with groundwater after the copper canister has breached. Large amounts of hydrogen are then produced through the anoxic corrosion of the cast iron insert. Recent data on spent fuel leaching in presence of repository relevant hydrogen pressures and the implications on the actual and future spent fuel dissolution modeling will also be discussed.

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Modeling of Radionuclide Releases From the Geological Repository for RBMK-1500 Spent Nuclear Fuel in Crystalline Rocks in Lithuania

11th International Conference on Environmental Remediation and Radioactive Waste Management, Parts A and B ◽

10.1115/icem2007-7272 ◽

2007 ◽

Cited By ~ 1

Author(s):

Povilas Poskas ◽

Asta Brazauskaite

Keyword(s):

Nuclear Fuel ◽

Safety Assessment ◽

Spent Nuclear Fuel ◽

Near Field ◽

Crystalline Rocks ◽

Far Field ◽

Field Region ◽

Radionuclide Migration ◽

Channel Network ◽

Geological Repository

During 2002–2005 the assessment of possibilities for disposal of spent nuclear fuel (SNF) in Lithuania was performed with support of Swedish experts. Potential geological formations for disposal of SNF were selected, disposal concept was developed, reference disposal site was defined and preliminary generic safety assessment was performed. Performing safety assessment the analysis of radionuclides migration from the repository as well as their impact to human and environment were also very important issues. In this paper results on the analysis of the radionuclide releases from the reference geological repository site for RBMK-1500 SNF in crystalline rocks in Lithuania are presented. For radionuclide migration in the near field region of the repository integrated finite difference method and the concept of compartments were used. For radionuclide migration in the far field the discrete channel network concept was used. The assessment of radionuclide migration in the near and far field region was performed using computer codes AMRER4.5 [1] and CHAN3D [2]. The results of analysis show that most of safety relevant radionuclides of RBMK-1500 SNF are effectively retarded in the near field region. The exposure due to possible release of the radionuclides from the crystalline rocks would be dominated by 129I firstly while after app. 250 thousand years 226Ra is dominating already.

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An Automated SeaFAST ICP-DRC-MS Method for the Determination of 90Sr in Spent Nuclear Fuel Leachates

Molecules ◽

10.3390/molecules25061429 ◽

2020 ◽

Vol 25 (6) ◽

pp. 1429 ◽

Cited By ~ 1

Author(s):

Víctor Vicente Vilas ◽

Sylvain Millet ◽

Miguel Sandow ◽

Luis Iglesias Pérez ◽

Daniel Serrano-Purroy ◽

...

Keyword(s):

Nuclear Fuel ◽

Safety Assessment ◽

Analytical Approach ◽

Source Term ◽

Spent Nuclear Fuel ◽

Spent Fuel ◽

Chemical Purification ◽

Radiochemical Method ◽

Good Agreement

To reduce uncertainties in determining the source term and evolving condition of spent nuclear fuel is fundamental to the safety assessment. ß-emitting nuclides pose a challenging task for reliable, quantitative determination because both radiometric and mass spectrometric methodologies require prior chemical purification for the removal of interfering activity and isobars, respectively. A method for the determination of 90Sr at trace levels in nuclear spent fuel leachate samples without sophisticated and time-consuming procedures has been established. The analytical approach uses a commercially available automated pre-concentration device (SeaFAST) coupled to an ICP-DRC-MS. The method shows good performances with regard to reproducibility, precision, and LOD reducing the total time of analysis for each sample to 12.5 min. The comparison between the developed method and the classical radiochemical method shows a good agreement when taking into account the associated uncertainties.

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The Influence of Ligands and Precipitates on the Release of Nuclides from the Near Field under Natural Repository Conditions

MRS Proceedings ◽

10.1557/proc-663-531 ◽

2000 ◽

Vol 663 ◽

Author(s):

L. Liu ◽

I. Neretnieks

Keyword(s):

Uranium Oxide ◽

Spent Nuclear Fuel ◽

Transport Model ◽

Radiation Power ◽

Near Field ◽

Reference Scenario ◽

Spent Fuel ◽

Secondary Phases ◽

Fuel Surface ◽

Fuel Pellets

ABSTRACTOnce groundwater intrudes into a damaged canister and wets the spent fuel pellets, radiation emitted from the spent nuclear fuel splits nearby water into oxidizing and reducing species. This may lead to an oxidizing condition near the fuel pellets. As a result, uranium oxide that makes up the fuel matrix will become more soluble, and the incorporated radionuclides will be released more rapidly. The dissolution process is, however, a dynamic one that can be influenced by many factors. Of great importance are the radiation power of the fuel matrix, the concentration of ligands near the fuel surface, and the transport resistance of the near field. Consequently, the escape of nuclides from the damaged canister is dominated mainly by the intrusion of ligands, and the precipitation/dissolution of secondary phases within the fuel rods. To investigate the possible effects of ligands and precipitates, a coupled dissolution and transport model, which includes the barrier effect of the Zircaloy claddings, is developed. The application of the model to a SKB-specified reference scenario indicates that by far the largest fraction of the oxidized uranium will reprecipitate within the canister. This may significantly decrease the fuel surface available for oxidation and the water available for radiolysis. Subsequently, much less fuel matrix will be dissolved and much less of the other nuclides will be released. Simulations further identify that carbonate and silicate have the greatest influences on the formation of secondary phases, and on the release of nuclides, under natural repository conditions.

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Approaches to Safety Justification for Loading of VSC-VVER Containers in ZNPP DSFSF

Nuclear and Radiation Safety ◽

10.32918/nrs.2019.4(84).10 ◽

2019 ◽

pp. 82-87

Author(s):

Ya. Kostiushko ◽

O. Dudka ◽

Yu. Kovbasenko ◽

A. Shepitchak

Keyword(s):

Nuclear Fuel ◽

Nuclear Power ◽

Safety Assessment ◽

Power Plants ◽

Spent Nuclear Fuel ◽

Operating Conditions ◽

Spent Fuel ◽

Fuel Assemblies ◽

Fuel Storage ◽

The Government

The introduction of new fuel for nuclear power plants in Ukraine is related to obtaining a relevant license from the regulatory authority for nuclear and radiation safety of Ukraine. The same approach is used for spent nuclear fuel (SNF) management system. The dry spent fuel storage facility (DSFSF) is the first nuclear facility created for intermediate dry storage of SNF in Ukraine. According to the design based on dry ventilated container storage technology by Sierra Nuclear Corporation and Duke Engineering and Services, ventilated storage containers (VSC-VVER) filled with SNF of VVER-1000 are used, which are located on a special open concrete site. Containers VSC-VVER are modernized VSC-24 containers customized for hexagonal VVER-1000 spent fuel assemblies. The storage safety assessment methodology was created and improved directly during the licensing process. In addition, in accordance with the Energy Strategy of Ukraine up to 2035, one of the key task is the further diversification of nuclear fuel suppliers. Within the framework of the Executive Agreement between the Government of Ukraine and the U.S. Government, activities have been underway since 2000 on the introduction of Westinghouse fuel. The purpose of this project is to develop, supply and qualify alternative nuclear fuel compatible with fuel produced in Russia for Ukrainian NPPs. In addition, a supplementary approach to safety analysis report is being developed to justify feasibility of loading new fuel into the DSFSF containers. The stated results should demonstrate the fulfillment of design criteria under normal operating conditions, abnormal conditions and design-basis accidents of DSFSF components. Thus, the paper highlights both the main problems of DSFSF licensing and obtaining permission for placing new fuel types in DSFSF.

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Modeling spent nuclear fuel alteration and radionuclide migration in disposal conditions

Radiochimica Acta ◽

10.1524/ract.2006.94.9-11.787 ◽

2006 ◽

Vol 94 (9-11) ◽

Cited By ~ 10

Author(s):

Laurent de Windt ◽

H. Schneider ◽

C. Ferry ◽

H. Catalette ◽

V. Lagneau ◽

...

Keyword(s):

Reactive Transport ◽

Spent Nuclear Fuel ◽

Transport Model ◽

Near Field ◽

Radioactive Decay ◽

Steel Corrosion ◽

Spent Fuel ◽

Fuel Pellets ◽

Physico Chemical ◽

Integrated Performance

A physico-chemical model developed for spent fuel alteration was integrated in a global reactive transport model of a spent fuel disposal system, considering both decaying and stable isotopes, corroded steel canisters, bentonite backfills and a clayey host-rock. Fuel evolution took into account radiolytic-enhanced corrosion and long-term solubility-controlled dissolution as well as instantaneous release fractions. The calculations show that spent-fuel dissolution has no significant alteration effect on the near-field components except an oxidizing plume in the vicinity of the waste packages. The dissolved uranyl species, partly precipitate as schoepite on the fuel pellets, and partly diffuse in the near-field where magnetite and pyrite reduce U(VI) to yield uraninite precipitation. Under disposal conditions, preliminary calculations indicate that steel corrosion may generate sufficient dissolved hydrogen as to react with radiolytic oxidants and inhibit fuel dissolution. The formation of a protective schoepite layer could also reduce the alteration of fuel pellets. Radionuclides migration (Am, Cs, I) in the near-field is discussed in a second stage discriminating between sorption, precipitation and radioactive decay processes. The migration of Cs is translated in terms of cumulative activity profiles useful for integrated performance assessment.

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The Near-Field Transport Code Tullgarn and its Use in Performance Assessment

MRS Proceedings ◽

10.1557/proc-294-725 ◽

1992 ◽

Vol 294 ◽

Author(s):

Patrik Sellin ◽

Nils Kjellbert

Keyword(s):

Performance Assessment ◽

Near Field ◽

Steel Corrosion ◽

List Type ◽

Spent Fuel ◽

Radionuclide Migration ◽

Transport Code ◽

Damaged Zone ◽

Chain Decay ◽

Resistance Network Model

ABSTRACTThe near-field radionuclide migration code Tullgarn has been developed for performance assessment purposes. As a part of the PROPER-code package it has been successfully applied in the SKB 91 safety analysis.The features and processes included in the code are:- Radioactive chain decay- Different canister failure mechanisms (copper corrosion from sulphide attack, steel corrosion, internal overpressure and initially defective canisters) - Spent fuel dissolution. The model is based on the assumption that the dissolution rate is proportional to the α-dose rate- Transport calculations are done with a resistance-network model. Tullgarn calculates the stationary release of radionuclides from a defect in the canister through the buffer and out into a fracture in the rock or up to the damaged zone under the deposition tunnel.Tullgarn can be used as a stand-alone model for near-field release calculations or as a submodel in an integrated assessment. In the SKB 91 analysis, Tullgarn gave the source term to the far-field model.

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Integrated Model of Korean Spent Fuel and High Level Waste Disposal Options

ASME 2009 12th International Conference on Environmental Remediation and Radioactive Waste Management, Volume 1 ◽

10.1115/icem2009-16091 ◽

2009 ◽

Author(s):

Yongsoo Hwang ◽

Ian Miller

Keyword(s):

Nuclear Fuel ◽

Spent Nuclear Fuel ◽

Fuel Cycle ◽

Near Field ◽

Integrated Model ◽

High Level Waste ◽

Spent Fuel ◽

Parameter Uncertainties ◽

Design Concepts ◽

High Level

This paper describes an integrated model developed by the Korean Atomic Energy Research Institute (KAERI) to simulate options for disposal of spent nuclear fuel (SNF) and reprocessing products in South Korea. A companion paper (Hwang and Miller, 2009) describes a systems-level model of Korean options for spent nuclear fuel (SNF) management in the 21’st century. The model addresses alternative design concepts for disposal of SNF of different types (CANDU, PWR), high level waste, and fission products arising from a variety of alternative fuel cycle back ends. It uses the GoldSim software to simulate the engineered system, near-field and far-field geosphere, and biosphere, resulting in long-term dose predictions for a variety of receptor groups. The model’s results allow direct comparison of alternative repository design concepts, and identification of key parameter uncertainties and contributors to receptor doses.

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