Quantification of brittle-ductile failure behavior of ferritic reactor pressure vessel steels using the Small-Punch-Test and micromechanical damage models

Two German ferritic pressure vessel steels are examined in the brittle to ductile transition regime as a function of temperature and irradiation.The experiments are done by a miniaturized Small-Punch-Test in hot cells within the temperature range of -185 °C up to 70 °C. From the load–displacement curve of the SPT,the yield curves and parameters of both a non-local GURSON-TVERGAARD-NEEDLEMAN ductile damage model and a modified BEREMIN model are identified. The influence of temperature and irradiation on the model parameters is analyzed. All parameters are verified by comparison with results from standard test methods. The parameters, identified from SPT, are used to simulate the failure behavior in standard fracture mechanics specimens.In the uppershelf, the non-local GTN-model is applied to simulate crack resistance curves,from where the fracture toughness data could be successfully predicted. In the lower shelf, the WEIBULL-stress of the specimens was computed to find out the statistics of fracture toughness values.Finally, the modified BEREMIN model and the non-local ductile damage model were combined to evaluate the failure of fracture specimens in the brittle-ductile transition region.This way, an acceptable agreement with Master-Curve data for non-irradiated steels could be achieved in the whole temperature range.