Specific features of external heat and mass transfer in the vibration apparatuses used for regenerating spent fuel from nuclear power plants

Centralized Temporary Storage Facility (CTS) is an industrial facility designed to store spent fuel (SF) and high level radioactive waste (HLW) generated at Spanish nuclear power plants (NPP) in a single location. At the end of 2011, the Spanish Government approved the installation of the CTS in the municipality of Villar de Cañas in Cuenca. This approval was the outcome of a long process of technical studies and political decisions that were always surrounded by great social rejection. After years of confrontations between the different political levels, with hardly any progress in its construction, this infrastructure of national importance seems to have been definitively postponed. The present research analyzes the management strategy of SF and HLW in Spain, as well as the alternative strategies proposed, taking into account the current schedule foreseen for the closure of the Spanish NPPs. In view of the results obtained, it is difficult to affirm that the CTS will be available in 2028, with the possibility that its implementation may be delayed to 2032, or even that it may never happen, making it necessary to adopt an alternative strategy for the management of GC and ARAR in Spain. Among the different alternatives, the permanence of the current Individualized Temporary Stores (ITS) as a long-term storage strategy stands out, and even the possibility of building several distributed temporary storage facilities (DTS) in which to store the SF and HLW from several Spanish NPP. Keywords: nuclear waste, storage, nuclear power plants.

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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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Qualification Requirements Design for Neutron Absorber Plate for Spent Fuel Racks in Domestic Nuclear Power Plants

Journal of Nuclear Engineering and Radiation Science ◽

10.1115/1.4043096 ◽

2019 ◽

Vol 5 (3) ◽

Author(s):

You Shi ◽

Dong Ning ◽

Yi-zhong Yang

Keyword(s):

Nuclear Power ◽

Power Plants ◽

Nuclear Power Plants ◽

Aluminum Matrix ◽

Practical Significance ◽

Spent Fuel ◽

Absorber Plate ◽

Neutron Absorber ◽

Fuel Storage ◽

B4c Particle

Boron carbide (B4C) particle-reinforced aluminum matrix composite is the key material for use as neutron absorber plate in fuel storage applications for Generation III advanced passive nuclear power plants in China. This material has once depended upon importing with various restrictions so that it has meaningful practical significance to realize the localized manufacturing for this material in China. More importantly, since it is the first time for this material to be used in domestic plant, particular care should be taken to assure the formal supplied products exhibit high stabilized and reliable service in domestic nuclear engineering. This paper initiates and proposes a principle design framework from technical view in qualification requirements for this material so as to guide the practical engineering application. Aiming at neutron absorber materials supplied under practical manufacturing condition in engineering delivery, the qualification requirements define B4C content, matrix chemistry, 10B isotope, bulk density, 10B areal density, mechanical property, and microstructure as key criteria for material performance. The uniformity assessment as to different locations of this material is also required from at least three lots of material. Only qualified material meeting all of the qualification requirements should proceed to be verified by lifetime testing such as irradiation, corrosion, and thermal aging testing. Systematic and comprehensive performance assessments and verification for process stabilization could be achieved through the above qualification. The long-term service for this neutron absorber material in reliable and safe way could be convincingly expected in spent fuel storage application in China.

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Study on the Impact Limiter Design in Spent Fuel Transfer Cask in Nuclear Power Plants

Volume 1: Beyond Design Basis; Codes and Standards; Computational Fluid Dynamics (CFD); Decontamination and Decommissioning; Nuclear Fuel and Engineering; Nuclear Plant Engineering ◽

10.1115/icone2020-16157 ◽

2020 ◽

Author(s):

Yuchen Hao ◽

Yue Li ◽

Jinhua Wang ◽

Bin Wu ◽

Haitao Wang

Keyword(s):

Nuclear Power ◽

Power Plants ◽

Nuclear Power Plants ◽

Theoretical Method ◽

Structure Design ◽

Design Approach ◽

Spent Fuel ◽

Typical Structure ◽

Explicit Finite Element ◽

The Impact

Abstract In nuclear power plants, the amount of spent fuel stored on-site is limited. Therefore, it is necessary to be shipped to off-site storage or disposal facilities regularly. The key risk in the transfer of spent fuel involves a release of radiation that could cause harmful effects to people and the environment. Transfer casks with impact limiters on both ends are always employed to ensure safe containment of radioactive materials, which should be verified by the 9 meters drop test onto an unyielding surface according to IAEA SSR-6. In this paper, we focus on the influence of the impact-limiter parameters, including geometry dimensions and mechanical properties, on the results of drop events to achieve an optimized approach for design. The typical structure of impact limiter is bulk energy-absorbed material wrapped by thin stainless-steel shells. Compared to traditional wood, foam has advantages of isotropy and steady quality. In this paper, theoretical and numerical methods are both adopted to investigate the influence of impact limiters during hypothetical accidental conditions for optimizing buffer influence and protecting the internal fuel components. First of all, a series of polyurethane foam is selected according to the theoretical method, because its mechanical property is related to density. Therefore, using explicit finite element method to investigate the influence of parameters of foam in impact limiter. These discrete points from the above result can be utilized to establish damage curves by date fitting. Finally, a design approach for spent fuel transfer cask is summarized, to provide a convenient formula to predict the damage and optimize structure design in drop condition. Furthermore, this design approach can be applied in the multi-module shared system of SNF, which can contain different fuel assemblies.

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Twenty Years of Experience in Spent Fuel Shipment from German Nuclear Power Plants—A View of the Competent Authority

International Journal of Radioactive Materials Transport ◽

10.1179/rmt.1994.5.2-4.151 ◽

1994 ◽

Vol 5 (2-4) ◽

pp. 151-153

Author(s):

Ch. Fasten ◽

U. Mtiller ◽

U. Alter

Keyword(s):

Nuclear Power ◽

Power Plants ◽

Nuclear Power Plants ◽

Competent Authority ◽

Years Of Experience ◽

Spent Fuel

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The３rd RRTD International Workshop on Development of Spent Fuel Management for Increasing Nuclear Power Plants Rapidly

Journal of the Atomic Energy Society of Japan ◽

10.3327/jaesjb.49.7_507 ◽

2007 ◽

Vol 49 (7) ◽

pp. 507-508

Keyword(s):

Nuclear Power ◽

Power Plants ◽

Nuclear Power Plants ◽

International Workshop ◽

Spent Fuel ◽

Fuel Management

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Design, Loading, Transport and Storage Experience of CASTOR® Casks for Vitrified High Level Waste

9th ASME International Conference on Radioactive Waste Management and Environmental Remediation: Volumes 1, 2, and 3 ◽

10.1115/icem2003-4724 ◽

2003 ◽

Author(s):

Andre´ Voßnacke ◽

Wilhelm Graf ◽

Roland Hu¨ggenberg ◽

Astrid Gisbertz

Keyword(s):

Nuclear Power ◽

High Performance ◽

Power Plants ◽

Nuclear Power Plants ◽

High Level Waste ◽

Spent Fuel ◽

Highly Active ◽

Dry Conditions ◽

Intermediate Storage ◽

High Level

The revised German Atomic Act together with the Agreement between the German Government and the German Utilities of June 11, 2001 form new boundary conditions that considerably influence spent fuel strategies by stipulation of lifetime limitations to nuclear power plants and termination of reprocessing. The contractually agreed return of reprocessing residues comprises some 156 casks containing vitrified highly active waste, the so-called HAW or glass canisters, coming form irradiated nuclear fuel assemblies to be shipped from COGEMA, France and BNFL, UK to Germany presumably until 2011. Several hundred casks with compacted residues and other waste will follow. The transports are scheduled presumably beyond 2020. The central interim storage facilities in Ahaus and Gorleben, formerly intended to accumulate up to 8,000 t of heavy metal (HM) of spent fuel from German nuclear power plants, offer sufficient capacity to receive the totality of residues to be returned from reprocessing abroad. GNB has developed, tested, licensed, fabricated, loaded, transported and stored a large number of casks for spent fuel and is one of the world leaders for delivering spent fuel and high level waste casks. Long-term intermediate storage of spent fuel is carried out under dry conditions using these casks that are licensed for transport as well as for storage. Standardized high performance casks such as the types CASTOR® HAW 20/28 CG, CASTOR® V/19 and CASTOR® V/52 meet the needs of most nuclear power plants in Germany. Up to now GNS has co-ordinated the loading and transport of 27 casks loaded with 28 canisters each from COGEMA back to Germany for storage in Gorleben for up to 40 years. In all but one case the cask type CASTOR® HAW 20/28 CG has been used.

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