Conceptual Approach to Handling Irradiated Nuclear Fuel in Storage Systems

Igor Shamanin; Sergei Bedenko; Ildar Gubaydulin; Natalia Novikova; Maria Plevaka

doi:10.4028/www.scientific.net/AMR.1084.285

Paper Titles

High Power Microwave Compressor with Two Output Units for Synchronous Energy Extraction
p.262

Superconducting Cavities in Systems of the Resonant Microwave Pulse Compression
p.266

Advantages of Thorium Nuclear Fuel for Thermal-Neutron Reactors
p.275

Angular Distributions of EUV Generated by Electrons with 5.7 MeV Energy in a Multilayer Mo/Si Structure
p.280

Conceptual Approach to Handling Irradiated Nuclear Fuel in Storage Systems
p.285

Degradation of Beryllium Reflector Properties on the IRT-T Reactor
p.289

Determining Reactor Graphite Lifespan from Thermal Properties Degradation
p.294

Facilities for Neutron Capture Therapy at IRT MEPhI Nuclear Reactor
p.298

Feasibility Study of Using New Fuel Composition in IRT-T Research Reactor
p.306

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 1084Conceptual Approach to Handling Irradiated Nuclear...

Conceptual Approach to Handling Irradiated Nuclear Fuel in Storage Systems

Abstract:

This work considers conceptual approaches to handling fuel irradiated in thermal reactors in technical “dry storage” systems. The experiments carried out in the work allow for improving the ecological, nuclear and radiation safety systems of storage and transportation of irradiated nuclear fuel for new generation reactors.

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Periodical:

Advanced Materials Research (Volume 1084)

Pages:

285-288

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.1084.285

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Online since:

January 2015

Authors:

Igor Shamanin, Sergei Bedenko, Ildar Gubaydulin, Natalia Novikova, Maria Plevaka

Keywords:

Dry Storage, Perspective Ceramic Nuclear Fuel, Threshold Reactions in Nuclear Fuel

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References

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