: Due to great advancements in various industries and also the need for high precision in the parts manufacturing, moving towards novel technologies in the manufacturing processes is inevitable. Computer Numerical Control (CNC) machines have received increasing attention in the manufacturing industries due to their performance. To produce high-quality components and molds, the accuracy of the desired surface, the need for the rotation at the tool to move in 360 degrees has been proven using the five-axes machines. Reasons for using five-axes device Firstly, startup time reduces since it does not require the displacement of parts as well as making some settings for complex movements. Secondly, the production time and cost of the tools are reduced by the nature of the spindle drive. Reducing the length of the tool will make the quality of the surfaces and the useful life of the tool higher, and will provide significant savings in the long run as well. However, the main advantage of the versatility and flexibility of the five-axes machine is considerable. All parts, all types of designs, which can produce profits, can be produced. This has led to lots of attention being paid to five-axes machines today. Hence, in the present thesis, in addition to understanding more numerical control machines and its advantages, a five-axes machine is designed and manufactured to produce complex woody components. Meanwhile, the effect of the force on the tool and the body of the CNC machine is assessed. Being simple, low cost, and light weight are the major factors in the design phase. By examining the force on the machine body, reducing the amount of displacement in the body, was obtained. Finally, after successful manufacture at the machine, several parts were tested and produced. By using an andicator clock and a dynamometer, the accuracy of axial movement and the force of the tool was investigated. Keywords: Computer Numerical Control, Mach-3, Stepper motor, G-Code, MicroStepping Drive, Ball Screw