Add to ORKGWith the sustained and rapid development of the nuclear power plants, the spent fuel which is produced by the nuclear power plants will be rapidly rising. Spent fuel is High-level radioactive waste and should be disposed safely, which is important for the environment of land, public safety and health of the nuclear industry, the major issues of sustainable development and it is also necessary part for the nuclear industry activities. It is important to study and resolve the high-level radioactive waste repository problem. Spent nuclear fuel is an important component in the radioactive waste, The KBS-3 canister for geological disposal of spent nuclear fuel in Sweden consists of a ductile cast iron insert and a copper shielding. The ductile c...
U diplomskom radu opisan je koncept odlaganja visoko radioaktivnog otpada i istrošenog nuklearnog go...
The present SF management concept in Lithuania envisages that spent RBMK-1500 fuel will be stored in...
With the reactor operation conditions - 4.3 wt% $^{235}U$ initial enrichment, burn-up 55,000 MWd/MTU...
The spent fuel from the Olkiluoto nuclear power plant (2 x 710 MWe BWR's) is planned to be disposed ...
The report provides a summary of the design of the canister for final disposal of Finnish spent nucl...
Operation of nuclear reactors leads to the production of spent nuclear fuel (SNF). There are two bas...
Korea expects a shortage in storage capacity for spent fuels at reactor sites. Therefore, a need for...
High-level waste storage for spent nuclear fuel is an important part of a system of nuclear waste ma...
Korea expects a shortage in storage capacity for spent fuels at reactor sites. Therefore, a need for...
In this paper, a complementary analysis for the structural safety evaluation of the spent nuclear fu...
The K-Basin Cask and Transportation System will be used for safely packaging and transporting approx...
This report concerns a study which has been conducted for the Swedish Nuclear Power Inspectorate (SK...
PWR spent fuels produced in the Republic of Korea are expected to be recycled by pyroprocess in the ...
This paper describes the implementation of the Bodner–Partom model for the analysis of copper corros...
The ''Department of Energy Spent Nuclear Fuel Canister, Transportation, and Monitored Geologic Repos...
U diplomskom radu opisan je koncept odlaganja visoko radioaktivnog otpada i istrošenog nuklearnog go...
The present SF management concept in Lithuania envisages that spent RBMK-1500 fuel will be stored in...
With the reactor operation conditions - 4.3 wt% $^{235}U$ initial enrichment, burn-up 55,000 MWd/MTU...
The spent fuel from the Olkiluoto nuclear power plant (2 x 710 MWe BWR's) is planned to be disposed ...
The report provides a summary of the design of the canister for final disposal of Finnish spent nucl...
Operation of nuclear reactors leads to the production of spent nuclear fuel (SNF). There are two bas...
Korea expects a shortage in storage capacity for spent fuels at reactor sites. Therefore, a need for...
High-level waste storage for spent nuclear fuel is an important part of a system of nuclear waste ma...
Korea expects a shortage in storage capacity for spent fuels at reactor sites. Therefore, a need for...
In this paper, a complementary analysis for the structural safety evaluation of the spent nuclear fu...
The K-Basin Cask and Transportation System will be used for safely packaging and transporting approx...
This report concerns a study which has been conducted for the Swedish Nuclear Power Inspectorate (SK...
PWR spent fuels produced in the Republic of Korea are expected to be recycled by pyroprocess in the ...
This paper describes the implementation of the Bodner–Partom model for the analysis of copper corros...
The ''Department of Energy Spent Nuclear Fuel Canister, Transportation, and Monitored Geologic Repos...
U diplomskom radu opisan je koncept odlaganja visoko radioaktivnog otpada i istrošenog nuklearnog go...
The present SF management concept in Lithuania envisages that spent RBMK-1500 fuel will be stored in...
With the reactor operation conditions - 4.3 wt% $^{235}U$ initial enrichment, burn-up 55,000 MWd/MTU...