The aerospace industry is seeking to reduce the weight of the constructions. This is the reason for the increase in the use of thin-walled elements. One of the main problems in the machining of thin-walled components is the elastic deformation of the wall, which leads to deformations and thus to geometric errors and a deterioration in the quality of the workpiece. In the work, the influence of the adaptive milling and tool type on the surface topography and the dimensional accuracy of thin-walled components was determined. The samples for constant cutting parameters were prepared from titanium alloy Ti6Al4V using conventional, HSM and HPM tools. Based on the experiment results, waviness and roughness and dimensional deviations (using optical scanner GOM) were determined.

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