Study on deformation and compensation for micromilling of thin walls

In order to further reduce the machining errors of microstraight thin walls caused by the elastic deformation in micromilling process, the deformation mechanism has been studied, and a compensation method is proposed to reduce the machining errors. Firstly, conventional micromilling experiments have been conducted. It shows that large dimensional errors exist in finished thin walls. Second, a mathematical model is established to calculate the thin wall deformation based on Rayleigh–Ritz theory. The deformation values are determined by calculating the selected discrete measurement points. Based on the deformation of measurement points, the thin wall deformation of any position can be calculated by numerical method. Finally, the thin wall dimensional errors are reduced by compensating the deformation according to the analysis based on the introduced mathematical model. The high machining quality of the thin wall is realized. The experimental results show that the dimensional errors of the thin wall have been significantly reduced after the deformation compensation. The average relative dimensional errors have been reduced from 6.86 to 1.11 ~ 2.69%. Also, the fabricated thin walls keep good shape accuracy. The experimental results show that the introduced device and the compensation method can effectively improve micromilling quality of thin walls.