This study was conducted to understand the effects of a magnetic field on mean velocity and turbulent characteristics in fully developed turbulent magnetohydrodynamic (MHD) flow through a square duct. Based on the coupled Navier-Stokes MHD equations, an extended Reynolds stress transport model including the Lorentz force effect was applied, and the analysis was performed using an in-house computational fluid dynamics code. In order to directly apply the Lorenz force effect to the turbulent MHD flow, models related to the generation and dissipation rate of the Lorenz force were additionally applied to the Reynolds stress and dissipation rate equations, and the indirect effect was also considered through the modification of the velocity-pressure gradient correlation model of the Reynolds stress equation. In addition, the model coefficients of the models related to the Lorenz force were tuned using the fully developed channel MHD data so that they could be linked to the elliptic-blending Reynolds stress model and then the square duct flow was analyzed. The prediction results were validated through comparison with the direct numerical simulation (DNS) data of Chaudhary et al. (2010), confirming the flattening of the mean velocity distribution and the suppression trends of turbulence intensity and shear stress. The results of the analysis show that the proposed extended model contributes to improving the predictive accuracy of MHD-affected flow fields and suggests its applicability to various engineering applications involving complex boundary conditions.