Using a 3D hydrostatic model developed by a vertical horizontal splitting (VHS) algorithm along with the turbulent model in which the standard k-ε model, a two-equation turbulent model to calculate eddy viscosity, this study discuss the turbulent phenomenon in a sharp bend of an open channel flow. The orthogonal curvilinear and the sigma coordinate systems are used in horizontal and vertical directions, respectively to deal with the irregularity of channel geometry. The water elevation and the depth-averaged velocity are solved by the 2D depth-averaged model; and then the velocity profile along the vertical direction is solved by the velocity defect model. The developed model is appied to simulate the flow pattern in a 193° sharp bend flume (K. Blanckaert, 2009). Three width-depth ratios including 12, 8.2 and 6.3 are considered. The simulated flow patterns are compared with those obtained from experiment, to evaluate the applicability of k-ε model in flow simulation under strong secondary current.