This study mainly used the numerical simulation method as the experiment platform, combining the sliding mesh technology of rotating machinery with the principles of Taguchi experimental method and statistical analysis. The sliding-mesh method was used to calculate the changes in the three-dimensional flow field of the waterjet propulsion system. The Taguchi experimental method was used to effectively and systematically de-sign experimental groups. The ＂larger is better＂ characteristic quality of the thrust of a waterjet propulsion device was configured. The control factors, such as the number of rotor and stator blades, stator placement angle, and the rotor-stator gap were determined; and the orthogonal table planning test was employed to establish a robust design. The thrust value obtained from the numerical simulation calculation was then converted into a signal-to-noise ratio to serve as the parameter design indicator. Thereafter, variance analysis was per-formed to investigate the contribution of the control factors and the effect of their interactions for determining the optimal parameter level combination. The results indicated that the curve trends of the numerical simulation and the experimental data were consistent. In addition, the flow field mechanism around the rotor and stator was also investigated.