Currently, research involving metals and their alloys has microstructural control as one of its objectives, to improve the properties of interest, for the desired applications. An important factor that influences the properties of polycrystalline materials are the types and distributions of grain and/or phase boundaries. The application of processes involving high temperatures, such as heat treatments or welding processes, can lead to phase transformations, which modify the crystallography, chemical composition, distribution and size of the grains. Duplex stainless steels are biphasic alloys made up of approximately equal proportions of ferrite and austenite belonging to the Fe-Cr-Ni system. This two-phase structure combines high strength, good toughness and excellent corrosion resistance. Due to these excellent properties, they are used in various industrial sectors such as: chemical, petrochemical, oil and gas, and shipbuilding industries. Increases in the concentration of Cr and Ni in these steels lead to the formation of two new classes, super and hyper duplex steels, whose properties are like duplex steels, but superior. In this case, due to the increase in the content of alloying elements, the welding processes can lead to the formation of intermetallic phases and/or precipitates, which are deleterious to the properties of the steels, facilitating the corrosion process. Many of the solid-state transformations that occur in steels follow certain crystallographic orientation relationships. These relationships describe the lowenergy interfaces that determine the processes of nucleation and growth of new phases. Therefore, the determination of orientation relationships presents in duplex, super-duplex and hyper-duplex steels, from phase transformations obtained under equilibrium and paraequilibrium conditions, were studied with the intention of correlating with the susceptibility to pitting corrosion. The UNS S32205, UNS S32750 and UNS S33207 steels were studied, respectively belonging to the duplex, super and hyperduplex classes. of the phases was obtained by Energy Dispersion Spectroscopy (EDS). These data were correlated with the results obtained after ASTM G-48 corrosion tests. For all steels, there is a trend towards an increase in the KS orientation ratio after submission to thermal cycles, however no clear correlation between the presence of the KS orientation and the formation of pits in the ferrite was found.