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Author: Publisher: ISBN: Category : Languages : en Pages : 5
Book Description
Research and test reactors around the world are currently returning spent fuel originally enriched in the United States back to the U.S. In May 2006, operators of the reactors will cease to be eligible to return their spent fuel and will have to find national or regional solutions for continued storage, if they want to continue operations of their research reactors. The Savannah River Site (SRS) has looked at a number of options like dry storage, melt-dilute, or continued wet storage for fuel currently stored at SRS. This paper reviews the highlights of the wet basin studies conducted at SRS since 1992. Based on an understanding of the important factors affecting the corrosion of aluminum-clad spent fuel, criteria are presented for the corrosion protection of this fuel in extended water storage. With optimum water quality, aluminum-clad spent fuel can be stored safely and with minimum corrosion for times exceeding 25 years.
Author: Publisher: ISBN: Category : Languages : en Pages : 5
Book Description
Research and test reactors around the world are currently returning spent fuel originally enriched in the United States back to the U.S. In May 2006, operators of the reactors will cease to be eligible to return their spent fuel and will have to find national or regional solutions for continued storage, if they want to continue operations of their research reactors. The Savannah River Site (SRS) has looked at a number of options like dry storage, melt-dilute, or continued wet storage for fuel currently stored at SRS. This paper reviews the highlights of the wet basin studies conducted at SRS since 1992. Based on an understanding of the important factors affecting the corrosion of aluminum-clad spent fuel, criteria are presented for the corrosion protection of this fuel in extended water storage. With optimum water quality, aluminum-clad spent fuel can be stored safely and with minimum corrosion for times exceeding 25 years.
Author: Publisher: ISBN: Category : Languages : en Pages :
Book Description
This paper will examine issues associated with extended storage of a variety of spent nuclear fuels. Recent experiences at the Idaho National Engineering and Environmental Laboratory and Hanford sites will be described. Particular attention will be given to storage of damaged or degraded fuel. The first section will address a survey of corrosion experience regarding wet storage of spent nuclear fuel. The second section will examine issues associated with movement from wet to dry storage. This paper also examines technology development needs to support storage and ultimate disposition.
Author: IAEA Publisher: International Atomic Energy Agency ISBN: 9201233221 Category : Technology & Engineering Languages : en Pages : 139
Book Description
This publication provides an introduction to the management of research reactor spent nuclear fuel (RRSNF). Five key areas are discussed: types of RRSNF, characterization data, wet storage considerations, dry storage considerations, and lessons learned and current practices. Information on internationally accepted standards as well as information on aspects such as drying treatment and surveillance programmes are presented, as well as suggestions for further optimization of effective and safe storage of RRSNF through the application of new approaches. The intended users of this publication include industry professionals at operating research reactors and at RRSNF storage facilities who need to identify the most suitable approach for interim storage of spent fuel.
Author: Publisher: ISBN: Category : Languages : en Pages :
Book Description
Wet storage has been the only licensed option for spent fuel management for US commercial power reactor operators, except for a period of commercial reprocessing at the Nuclear Fuel Services facility, 1965-71. Developments are underway to bring dry storage to licensed status on the US by mid-1986. However, wet storage will remain the predominant storage method, at least beyond the turn of the century. The Nuclear Waste Policy Act of 1982 establishes current US policy regarding responsibilities for spent fuel management. The Nuclear Waste Confidence Rulemaking proceedings address the viability of extended wet storage for US reactors. US utilities have moved aggressively to implement optimized utilization of wet storage technology, assisted in some areas by federal programs. This paper summarizes US policy and regulatory aspects of wet storage and the status of several wet storage technology developments, including: dense racking, double tiering, credit for burnup in rack designs, transshipment, impacts of extended burnup, rod consolidation, and pool decommissioning.
Author: D. Vinson Publisher: ISBN: Category : Languages : en Pages :
Book Description
Aluminum clad research reactor spent nuclear fuel (SNF) is currently being consolidated in wet storage basins (pools). Approximately 20 metric tons (heavy metal) of aluminum-based spent nuclear fuel (Al-SNF) is being consolidated for treatment, packaging, interim storage, and preparation for ultimate disposal in a geologic repository. The storage and disposal of Al-SNF are subject to requirements that provide for safety and acceptable radionuclide release. The options studied for interim storage of SNF include wet storage and dry storage. Two options have also been studied to develop the technical basis for the qualification and repository disposal of aluminum spent fuel. The two options studied include Direct Disposal and Melt-Dilute treatment. The implementation of these options present relative benefits and challenges. Both the Direct Disposal and the Melt-Dilute treatment options have been developed and their technical viability assessed. Adaptation of the melt-dilute technology for the treatment of spent fuel offers the benefits of converting the spent fuel into a proliferation resistant form and/or significantly reducing the volume of the spent fuel. A Mobile Melt-Dilute system concept has emerged to realize these benefits and a prototype system developed. The application of the melt-dilute technology for the treatment of legacy nuclear materials has been evaluated and also offers the promise for the safe disposal of these materials.
Author: Publisher: ISBN: Category : Business & Economics Languages : en Pages : 224
Book Description
This guidebook is a revised version of Technical Reports Series No. 240, published in 1984. It provides a summary of the experience and information in many areas related to spent fuel storage. It will allow a better understanding of the many problems involved and permit countries that are planning for or operating nuclear power reactors to review the issues in a more informative manner. In view of the large quantity of spent fuel discharged from nuclear power plants, long term storage is currently the primary option for the management of spent fuel. The proven wet storage concept is expected to continue to be used in the future. The design and the technological, economic and material problems of safe spent fuel storage will remain a focus of attention, with particular emphasis on dry storage technology, rod consolidation and other advanced concepts.
Author: Publisher: ISBN: Category : Languages : en Pages :
Book Description
Following discharge from research reactors, spent nuclear fuel may be stored 'wet' in water pools or basins, or it may be stored 'dry' in various configurations including non-sealed or sealed containers until retrieved for ultimate disposition. Interim safe storage practices are based on avoiding degradation to the fuel that would impact functions related to safety. Recommended practices including environmental controls with technical bases, are outlined for wet storage and dry storage of aluminum-clad, aluminum-based research reactor fuel. For wet storage, water quality must be maintained to minimize corrosion degradation of aluminum fuel. For dry storage, vented canister storage of aluminum fuel readily provides a safe storage configuration. For sealed dry storage, drying must be performed so as to minimize water that would cause additional corrosion and hydrogen generation. Consideration must also be given to the potential for radiolytically-generated hydrogen from the bound water in the attendant oxyhydroxides on aluminum fuel from reactor operation for dry storage systems.
Author: International Atomic Energy Agency Publisher: ISBN: 9789201061195 Category : Technology & Engineering Languages : en Pages :
Book Description
This publication is a revision by amendment of IAEA Safety Standards Series No. SSG-15 and provides recommendations and guidance on the storage of spent nuclear fuel. It covers all types of storage facility and all types of spent fuel from nuclear power plants and research reactors. It takes into consideration the longer storage periods beyond the original design lifetime of the storage facility that have become necessary owing to delays in the development of disposal facilities and the reduction in reprocessing activities. It also considers developments associated with nuclear fuel, such as higher enrichment, mixed oxide fuels and higher burnup. Guidance is provided on all stages in the lifetime of a spent fuel storage facility, from planning through siting and design to operation and decommissioning. The revision was undertaken by amending, adding and/or deleting specific paragraphs addressing recommendations and findings from studying the accident at the Fukushima Daiichi nuclear power plant in Japan.
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Author: D. Vinson
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Author: James D. Werner
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Author: International Atomic Energy Agency