A ground-sill structure on riverbed may fail in a large flood during torrent or typhoon in spite the structure may have a foundation onto the rock bed. Its true failure mechanism deserves attention. The failure of a ground-sill structure is closely related to the forces exerted from the strong water current (water loads). However, the water loads are not easy to know. This thesis made use of the software COMSOL Multiphysics and applied computational fluid mechanics (CFD) to model the open channel problem for river reach with ground-sill works. The simulations utilized turbulent k-ε model and two-phase flow by using level-set method with volume fraction to solve a free surface problem of open channel. The water loads on the boundary of the ground-sill structure were calculated to evaluate the loads acting on the structure. The acquired water loads were then used to evaluate the stability (the factors of safety) for various failure modes including uplift, sliding and overturning of the structure. Also, the flow velocity on the boundary was used to examine the stability of riprap. The study chose a series of similar ground-sill works on the Ba-Chang River as an example to investigate the cause of its failure. The #3 ground-sill structure has already failed, while the #4~6 structures in this series remain intact. The case study aimed to investigate the failire reason of the #3 structure. From the numerical simulation, it appears that the #3 ground-sill works would not fail because of the structure instability solely due to the water loads. Intense scouring under the foundation toe is likely the real cause to result in the failure of the ground-sill structure. Furthermore, the study evaluated the energy dissipation of the ground-sill structures using the results of numerical simulation.