Thin-walled VVR-M5 fuel elements for research reactors
Journal Article
·
· Sov. At. Energy (Engl. Transl.); (United States)
New VVR-M reactor fuel elements were developed in two stages. In the first stage their geometric parameters were optimized, and the specific heat-transfer surface increased by a factor of 1.8 as a result. Several lots of assemblies of this type (VVR-M3) were in service at the VVR-M reactor of the Institute of Nuclear Physics in Leningrad between 1973 and 1980. In the second stage the design concentration of U 235 in the core was optimized (at 125 g/liter), leading to a large increase in the power production of each assembly and in the reactor reactivity margin. The characteristics of VVR-M assemblies are presented in a table. In particular, the VVR-M5 fuel elements have undergone development and testing, and have been in service for more than 5 years. These elements allow raising the capacity of pool reactors to 30 MW and afford a twofold increase in the core space available for experimental devices. This is achieved with a much lower fuel consumption.
- OSTI ID:
- 7243003
- Journal Information:
- Sov. At. Energy (Engl. Transl.); (United States), Journal Name: Sov. At. Energy (Engl. Transl.); (United States) Vol. 60:2; ISSN SATEA
- Country of Publication:
- United States
- Language:
- English
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Related Subjects
21 SPECIFIC NUCLEAR REACTORS AND ASSOCIATED PLANTS
220700* -- Nuclear Reactor Technology-- Plutonium & Isotope Production Reactors
ACTINIDE ISOTOPES
ACTINIDE NUCLEI
ALPHA DECAY RADIOISOTOPES
BURNUP
DESIGN
DIMENSIONS
EFFICIENCY
ENERGY EFFICIENCY
ENERGY TRANSFER
ENRICHED URANIUM REACTORS
EVEN-ODD NUCLEI
FABRICATION
FUEL ASSEMBLIES
FUEL CANS
FUEL ELEMENTS
HEAT TRANSFER
HEAVY NUCLEI
IRRADIATION REACTORS
ISOMERIC TRANSITION ISOTOPES
ISOTOPE PRODUCTION REACTORS
ISOTOPE SEPARATION
ISOTOPES
MATERIALS TESTING REACTORS
MINUTES LIVING RADIOISOTOPES
NEUTRON FLUX
NUCLEI
OPTIMIZATION
PERFORMANCE
PERFORMANCE TESTING
RADIATION FLUX
RADIOISOTOPES
REACTOR COMPONENTS
REACTORS
RESEARCH AND TEST REACTORS
RESEARCH REACTORS
SEPARATION PROCESSES
TANK TYPE REACTORS
TESTING
THERMAL REACTORS
THICKNESS
URANIUM 235
URANIUM ISOTOPES
WATER COOLED REACTORS
WATER MODERATED REACTORS
WWR TYPE REACTORS
WWR-M-LENINGRAD REACTOR
YEARS LIVING RADIOISOTOPES
220700* -- Nuclear Reactor Technology-- Plutonium & Isotope Production Reactors
ACTINIDE ISOTOPES
ACTINIDE NUCLEI
ALPHA DECAY RADIOISOTOPES
BURNUP
DESIGN
DIMENSIONS
EFFICIENCY
ENERGY EFFICIENCY
ENERGY TRANSFER
ENRICHED URANIUM REACTORS
EVEN-ODD NUCLEI
FABRICATION
FUEL ASSEMBLIES
FUEL CANS
FUEL ELEMENTS
HEAT TRANSFER
HEAVY NUCLEI
IRRADIATION REACTORS
ISOMERIC TRANSITION ISOTOPES
ISOTOPE PRODUCTION REACTORS
ISOTOPE SEPARATION
ISOTOPES
MATERIALS TESTING REACTORS
MINUTES LIVING RADIOISOTOPES
NEUTRON FLUX
NUCLEI
OPTIMIZATION
PERFORMANCE
PERFORMANCE TESTING
RADIATION FLUX
RADIOISOTOPES
REACTOR COMPONENTS
REACTORS
RESEARCH AND TEST REACTORS
RESEARCH REACTORS
SEPARATION PROCESSES
TANK TYPE REACTORS
TESTING
THERMAL REACTORS
THICKNESS
URANIUM 235
URANIUM ISOTOPES
WATER COOLED REACTORS
WATER MODERATED REACTORS
WWR TYPE REACTORS
WWR-M-LENINGRAD REACTOR
YEARS LIVING RADIOISOTOPES