Constraint effects on the ductile-to-brittle transition temperature of ferritic steels: a Weibull stress model

This study examines crack front length and constraint loss effects on cleav age fracture toughness in ferritic steels at temperatures in the ductile-to -brittle transition region. A local approach for fracture at the micro-scal e of the material based on the Weibull stress is coupled with very detailed three-dimensional models of deep-notch bend specimens. A new non-dimension al function g(M) derived from the Weibull stress density describes the over all constraint level in a specimen. This function remains identical for all geometrically similar specimens regardless of their absolute sizes, and th us provides a computationally simple approach to construct (three-dimension al) fracture driving force curves sigma(omega) vs. J, for each absolute siz e of interest. Proposed modifications of the conventional, two-parameter We ibull stress expression for cumulative failure probability introduce a new threshold parameter sigma(omega)-min. This parameter has a simple calibrati on procedure requiring no additional experimental data. The use of a toughn ess scaling model including sigma(omega-min) > 0 increases the deformation level at which the CVN size specimen loses constraint compared to a 1T SE(B ) specimen, which improves the agreement of computational predictions and e xperimental estimations. Finally the effects of specimen size and constrain t loss on the cleavage fracture reference temperature T-0 as determined usi ng the new standard ASTM E1921 are investigated using Monte Carlo simulatio n together with the new toughness scaling model.