Kinetics of the degradation of type 316 stainless steel by liquid lithium
Thesis/Dissertation
·
OSTI ID:5322310
A forced convection loop is used to study the corrosion of type 316 stainless steel by liquid lithium at temperatures relevant to fusion reactors. Weight loss data are reported for tubular samples located in the hot zone of the loop. Temperatures of 440C and 490C have been used in the hot zone with temperature differences of 100C to 200C between the hot and cold zones. The effect of lithium velocity on local mass transfer rates is examined by simultaneously exposing stainless steel samples to parallel streams of lithium at velocities ranging from 40 to 130 cm/s. The loss rates become essentially steady after one month of exposure. The rates agree substantially with rates reported by previous workers, but are one to two orders of magnitude smaller than the rates predicted by boundary layer theory, using an extrapolation of the available solubility data for iron in lithium. It is presumed that particles of iron circulate in the lithium and by their dissolution and precipitation act as a buffer to reduce the wall fluxes. The loss rate increases with lithium velocity in a manner suggestive of liquid-phase controlled mass transfer. The velocity dependence is weaker than expected for flows in the range of Reynolds numbers studied. This may reflect a significant interfacial resistance to the dissolution. The mass loss rates at 440C are reduced when the temperature difference between the hot and cold zones is reduced. The rates during the first 1000 hours are three to four times higher at 490C than at 440C. The dissolution rate at 490C decreases markedly after 1000 hours. The transformation of the steel surface to a ferritic phase may cause the reduction in the rate.
- Research Organization:
- Wisconsin Univ., Madison (USA)
- OSTI ID:
- 5322310
- Country of Publication:
- United States
- Language:
- English
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Related Subjects
36 MATERIALS SCIENCE
360105* -- Metals & Alloys-- Corrosion & Erosion
70 PLASMA PHYSICS AND FUSION TECHNOLOGY
700209 -- Fusion Power Plant Technology-- Component Development & Materials Testing
ALKALI METALS
ALLOYS
CHEMICAL REACTIONS
CHROMIUM ALLOYS
CHROMIUM STEELS
CHROMIUM-NICKEL STEELS
CORROSION
CORROSION RESISTANT ALLOYS
ELEMENTS
HEAT RESISTANT MATERIALS
HEAT RESISTING ALLOYS
HIGH TEMPERATURE
IRON ALLOYS
IRON BASE ALLOYS
LITHIUM
MATERIALS
MEDIUM TEMPERATURE
METALLURGICAL EFFECTS
METALS
MOLYBDENUM ALLOYS
NICKEL ALLOYS
SIMULATION
STAINLESS STEEL-316
STAINLESS STEELS
STEELS
THERMAL DEGRADATION
THERMONUCLEAR REACTORS
360105* -- Metals & Alloys-- Corrosion & Erosion
70 PLASMA PHYSICS AND FUSION TECHNOLOGY
700209 -- Fusion Power Plant Technology-- Component Development & Materials Testing
ALKALI METALS
ALLOYS
CHEMICAL REACTIONS
CHROMIUM ALLOYS
CHROMIUM STEELS
CHROMIUM-NICKEL STEELS
CORROSION
CORROSION RESISTANT ALLOYS
ELEMENTS
HEAT RESISTANT MATERIALS
HEAT RESISTING ALLOYS
HIGH TEMPERATURE
IRON ALLOYS
IRON BASE ALLOYS
LITHIUM
MATERIALS
MEDIUM TEMPERATURE
METALLURGICAL EFFECTS
METALS
MOLYBDENUM ALLOYS
NICKEL ALLOYS
SIMULATION
STAINLESS STEEL-316
STAINLESS STEELS
STEELS
THERMAL DEGRADATION
THERMONUCLEAR REACTORS