Thermal hydraulic aspects of an unconventional liquid-metal reactor
Thesis/Dissertation
·
OSTI ID:6077048
The Trench Reactor (TR) is a liquid sodium cooled fast power reactor. The reactor core is fueled with U-Pu-Zr metal fuel and generates 800 MW of thermal power. The core is located in a sodium pool which is contained in a thin and deep rectangular vessel. Also located in the pool are the two intermediate heat exchangers (IHX) and the two primary pumps. The liquid sodium exists the core at 485{degree}C and is pumped through the IHXs where it is cooled to 343{degree}C and enters the core through an inlet plenum. The reactor building atmosphere is nitrogen which circulates through the guard tank and reactor vessel. The secondary sodium enters the IHXs at 294{degree}C and exits at 465{degree}C. It then is used to generate steam at 425{degree}C and 15 MPa. The electric power output of the plant is 300 MWe. TR has the advantages of a small plant. The current technology can be applied to build the main components of the reactor system. The initial margins to failure are large and the failure mechanisms are slow. The use of metal fuel and the large sodium pool enhance the safety of the reactor. The major design changes introduced are the elimination of heat capacity effects associated with the core inlet temperature and the rectangular shape of the reactor vessel and the core. The former helped to improve the response of the TR to a wide range of accidents by enabling the effects of core inlet temperature changes to be felt early in the transients. The latter resulted in a simpler core design and control. The TR response to unprotected loss of heat sink, loss of flow, positive reactivity insertion and overcooling accidents is favorable.
- Research Organization:
- Iowa State Univ. of Science and Technology, Ames, IA (USA)
- OSTI ID:
- 6077048
- Country of Publication:
- United States
- Language:
- English
Similar Records
Structural behavior of a pool-type LMFBR reactor-vessel deck to beyond-design-basis loads
An Innovative Hybrid Loop-Pool Design for Sodium Cooled Fast Reactor
Control of reactor coolant flow path during reactor decay heat removal
Conference
·
Fri Dec 31 23:00:00 EST 1982
·
OSTI ID:6174068
An Innovative Hybrid Loop-Pool Design for Sodium Cooled Fast Reactor
Conference
·
Thu Nov 01 00:00:00 EDT 2007
·
OSTI ID:923496
Control of reactor coolant flow path during reactor decay heat removal
Patent
·
Thu Dec 31 23:00:00 EST 1987
·
OSTI ID:866703
Related Subjects
21 SPECIFIC NUCLEAR REACTORS AND ASSOCIATED PLANTS
210500* -- Power Reactors
Breeding
ALKALI METALS
DESIGN
ELEMENTS
ENERGY SOURCES
FAILURES
FLUID MECHANICS
FUELS
HEAT EXCHANGERS
HYDRAULICS
LIQUID METAL COOLED REACTORS
MATERIALS
MECHANICS
MEGAWATT POWER RANGE
METALS
NUCLEAR FACILITIES
NUCLEAR FUELS
NUCLEAR POWER PLANTS
POWER PLANTS
POWER RANGE
POWER RANGE 100-1000 MW
PUMPS
REACTOR COMPONENTS
REACTOR CORES
REACTOR MATERIALS
REACTOR SAFETY
REACTORS
SAFETY
SODIUM
THERMAL POWER PLANTS
210500* -- Power Reactors
Breeding
ALKALI METALS
DESIGN
ELEMENTS
ENERGY SOURCES
FAILURES
FLUID MECHANICS
FUELS
HEAT EXCHANGERS
HYDRAULICS
LIQUID METAL COOLED REACTORS
MATERIALS
MECHANICS
MEGAWATT POWER RANGE
METALS
NUCLEAR FACILITIES
NUCLEAR FUELS
NUCLEAR POWER PLANTS
POWER PLANTS
POWER RANGE
POWER RANGE 100-1000 MW
PUMPS
REACTOR COMPONENTS
REACTOR CORES
REACTOR MATERIALS
REACTOR SAFETY
REACTORS
SAFETY
SODIUM
THERMAL POWER PLANTS