Spreadsheet-based method for predicting temperature dependence of fracture toughness in ductile-to-brittle temperature region

Abstract: A spreadsheet-based simplified and direct toughness scaling method to predict the temperature dependence of fracture toughness Jc in the ductile-to-brittle transition temperature region is proposed. This method uses fracture toughness test data and the Ramberg–Osgood exponent and yield stress at the reference temperature, and yield stress at the temperature in interest to predict Jc. The physical basis of the simplified and direct toughness scaling method is the strong correlation between Jc and yield stress. … Show more

“…Note that Kirk et al implicitly assumed that the tensile-to-yield stress ratio does not vary with materials, which is not true, and will be a source of deviation from the MC. For example, the failure of this MC to evaluate increases in K Jc at high temperatures has been reported for non-reactor pressure vessel (RPV) steels [25,26]. Despite the successful application of K Jc MC to RPV steels, a reexamination of the basis of K Jc MC existence and additional application limits must be reexamined for the application of ASTM E1921 MC to ferritic steels in general and not be limited to RPV steels.…”

Application of an Artificial Neural Network to Develop Fracture Toughness Predictor of Ferritic Steels Based on Tensile Test Results

“…Note that Kirk et al implicitly assumed that the tensile-to-yield stress ratio does not vary with materials, which is not true, and will be a source of deviation from the MC. For example, the failure of this MC to evaluate increases in K Jc at high temperatures has been reported for non-reactor pressure vessel (RPV) steels [25,26]. Despite the successful application of K Jc MC to RPV steels, a reexamination of the basis of K Jc MC existence and additional application limits must be reexamined for the application of ASTM E1921 MC to ferritic steels in general and not be limited to RPV steels.…”

Application of an Artificial Neural Network to Develop Fracture Toughness Predictor of Ferritic Steels Based on Tensile Test Results

Quantitative comparison of the predictions of fracture toughness temperature dependence using ASTM E1921 master curve and stress distribution T-scaling methods

Characterization of fracture toughness based on yield stress and successful application to construct a lower-bound fracture toughness master curve