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Effect of Microstructure on Low Temperature Cracking Behavior of EN82H Welds

Conference ·
OSTI ID:799220
 [1]; ;
  1. Bettis Atomic Power Laboratory
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As-fabricated EN82H welds are susceptible to low temperature embrittlements in 54 degree C hydrogenated water. Values of J[sub]IC in water are typically 90% to 98% lower than those in air due to a fracture mechanism transition from microvoid coalescence to hydrogen-included intergranular fracture. Environmental J[sub]IC testing demonstrated that a high temperature (1093 degree C) anneal and furnace-cool alleviates the material's susceptibility to hydrogen-induced intergranular cracking. To identify metallurgical and compositional features that are responsible for the material's environment-sensitive behavior, detailed characterization of the microstructure and grain boundary chemistry for the as-fabricated and as-annealed materials was performed. Results from light optical microscopy, analytical electron microscopy, electron probe microanalysis, Auger electron spectroscopy and mechanical property characterization are used to provide insight into the observed low temperature embrittlement phenomenon. The key microstructural feature responsible for low temperature cracking in as-fabricated welds appears to be fine niobium and titanium-rich carbonitrides that cover most grain boundaries. These precipitates are effective hydrogen traps that promote hydrogen-induced intergranular cracking. Dissolution the fine carbonitrides during the 1093 degree C anneal reduces grain boundary trapping sites, which accounts for the improved fracture resistance displayed by the annealed weld. The role of strength level in promoting low temperature embrittlement is evaluated by cold-rolling the annealed weld to increase its yield strength from 280 to 640 MPa. The annealed and cold-rolled weld exhibits high toughness in 54 degree C water and shows no evidence of hydrogen-induced intergranular cracking, thereby demonstrating that strength is not a primary cause of low temperature embrittlement.
Research Organization:
Bettis Atomic Power Lab., West Mifflin, PA (US)
Sponsoring Organization:
US Department of Energy (US)
DOE Contract Number:
AC11-98PN38206
OSTI ID:
799220
Report Number(s):
B-T-3337
Country of Publication:
United States
Language:
English

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Related Subjects

29 ENERGY PLANNING, POLICY, AND ECONOMY
36 MATERIALS SCIENCE
AUGER ELECTRON SPECTROSCOPY
ELECTRON MICROSCOPY
ELECTRON PROBES
GRAIN BOUNDARIES
MICROSTRUCTURE
NUCLEAR POWER
OPTICAL MICROSCOPY
WATER
YIELD STRENGTH