Stress intensity factor-based prediction of solidification crack growth during welding of high strength steel

A stress intensity factor (SIF)-based analysis was used to predict solidification crack growth patterns after welding. A coupled thereto-mechanical analysis was conducted to achieve the stresses induced by welding processes, which was used as the initial state in the SIF analysis. The SIF cracked model was established geometrically identical to an uncracked seam element in the thermo-mechanical analysis, based on the Lemaitre strain equivalence principle. Then the prediction of solidification crack growth employed the SIF solutions. The results show that propagation of longitudinal solidification cracks occurs in mode III (at high temperature), as validated by the non-equiaxial and elongated dimple-like crack profile of high-strength steel specimens. Simulations show that the longitudinal cracking switches to mode I as the temperature drops. Transverse orientations are naturally crack-resistant at high-temperature, however, they are prone to the open mode at low temperature. The comparison of SIFs from different welding speeds shows that high-speed welding increases susceptibility to cracking in the open mode regardless of temperature.