This paper investigates the use of circumferentially notched bar specimens for the measurement of elastic-plastic fracture toughness JIC of structural alloys and weldments for superconducting magnets in fusion energy systems. Notch tensile tests were performed with small cylindrical notched bar specimens at liquid helium temperature (4 K) using crosshead rates of 0.2 mm/min and 20 mm/s. Test specimens were 5 mm in diameter with a 30-mm reduced section. In the mid-section of the specimen a 1 mm deep electro discharge machined (EDM) notch of 0.2 mm width was machined around the girth, thus maintaining a starting diameter of 3 mm. Correlations between notch tensile strength σNTS, failure energy absorption ENT, and JIC were assessed. The best data fit was found between the ratio σNTS/JIC and JIC. A finite element analysis was also performed to compute directly the J-values. Comparisons of the predicted JIC with results obtained from conventional JIS Z 2284 standard tests were made. Results of structural alloy weldment with a representatively wide range of JIC indicate that fracture toughness prediction accuracy is roughly equal to ±25 percent.

Issue Section:
Technical Papers
Keywords:
austenitic stainless steel, nickel alloys, chromium alloys, molybdenum alloys, fracture toughness testing, notch testing, welding, finite element analysis, tensile strength, plastic deformation, elastoplasticity, cryogenics
Topics:
Alloys, Finite element analysis, Fracture toughness, Tensile strength, Stress, Testing, Fracture (Materials), Displacement, Absorption, Failure
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