Microstructure Evolution in Heat-Affected Zone of Shipbuilding Steel Plates with Mg Deoxidation Containing Different Nb Contents

This study is to comprehensively clarify the effect of Nb addition on the particles, austenite grain growth, microstructure evolution, and toughness in the heat-affected zone after high heat input welding at 400 kJ cm(-1) for shipbuilding steel plates with Mg deoxidation containing 0.002 and 0.016 wt pct Nb. The Nb addition enhances the dissolution of small particles (< 20 nm) and the coarsening of large particles (> 20 nm) during welding period of T > 1300 degrees C, because the stability of (Ti, Nb)(C, N) particles is reduced caused by the weaker bonding of Ti-C, Nb-N, and Nb-C. With the temperature above 1300 degrees C during welding, the austenite grain growth rate increases with Nb addition because the particle pinning force reduces by the small-sized particle dissolution and large-size particle coarsening. Nb addition hinders the ferrite transformation with the transformation temperature decreasing from 700-535 degrees C to 670-520 degrees C, due to the increased PAG size. Thus, with Nb addition, the microstructures change from high-temperature fine polygonal ferrite in small prior austenite grains (PAGs) to low-temperature coarse intragranular bainite ferrite in large PAGs, reducing the high-angled grain boundary density from 1.3 to 0.5 mu m(-1) and increasing the effective grain size from 10.4 to 17.6 mu m. Thus, the toughness at - 40 degrees C decreases from 127 to 58 J.