Five-axis milling plays an extremely important role in biomedical, aerospace, mold, automobile and other industries. However, the tool path and tool orientation planning of five-axis milling still depend on the experience of the technicians. Although most commercial CAD/CAM software can confirm whether the toolpath is correct or not with residual material through the built-in geometric simulation, but rarely consider the physical quantities in the cutting process, such as cutting force, tool wear, vibration, etc., and in excessive cutting force during machining can cause damage to the tool and spindle, and changes in cutting force may also cause tool deflection problems, thereby deteriorating the final geometric accuracy. Therefore, reducing the variation of cutting force during machining will be an important issue This research will develop a set of software that can automatically generate a five-axis machining tool path on a curved surface. By extracting the Cutter-Workpiece Engagement to calculate the instantaneous cutting force during machining, the physical simulation of cutting processing will be carrying out. By considering the change of the tool orientation during processing, this study proposes adjusting the tool orientation through the curvature of the machining surface to reduce the variation of cutting force, and changing the feed rate to achieve a uniform cutting force. In the verification results of this study, the tool path can be automatically generated on the selected surface and the Cutter-Workpiece Engagement features can be successfully extracted. The variation in the tool orientation movement is reduced, and so do the changes in the cutting force.