The purpose of this paper was to study the 3D flow field in the mixing of Newtonian or non-Newtonian fluids with high viscosity in laminar flow region for screw impellers and helical ribbon impellers, which is analyzed using a computational fluid dynamics method. The velocity field is assumed to be in a quasi-steady state. The multiple reference frames were employed to model the rotation of impellers. The momentum and continuity equations were solved using finite volume method with unstructured grids. The glucose syrup was used as Newtonian fluid. The rheology of xanthan gum solution, a pseudoplastic fluid with yield stress, was approximated using the Herschel-Bulkley model. After the flow field was calculated, the unsteady-state concentration equation was solved to determined mixing time. The effects of impeller geometry (tank diameter, impeller pitch, impeller clearance, and impeller blade width) and fluid rheology on power consumption, circulation flow rate, mixing efficiency, and mixing time were also investigated. The optimum values of D/d (tank diameter to impeller diameter), S/d (impeller pitch to impeller diameter), C/d (impeller clearance to impeller diameter), W/d (impeller width to impeller diameter) ratios were determined on the minimum mixing time and power consumption can be expressed as functions of these ratios. For the mixing of Newtonian fluids by screw impeller with draght tube, the optimum sizes are D/d=2.0, S/d=1.5, and C/d=0.1. While xanthan gum solution, a pseudoplastic fluid with yield stress, was mixed, the optimum screw impeller pitch is S/d=1.0. Helical ribbon impeller has optimum sizes W/d=0.25, S/d=0.7, and C/d=0.06 when mixing Newtonian fluids, and S/d=1.0 when mixing xanthan gum.