Monocrystalline Nickel Nanogrinding Subsurface Deformation-Layer Depth Study Based on Orthogonal Tests

Nanogrinding is one of the main technologies for machining complex surface shapes with nanometer-level precision. The subsurface deformation depth, as an important index of machining quality, directly affects the service life and mechanical properties of machined parts. In order to explore the factors that influence subsurface deformation depth, this work investigated the effects of three factors, namely, grinding speed, grinding depth and crystal orientation, along different crystal planes at the depth of the subsurface deformation layer in a monocrystalline nickel nanofabrication process. By combining molecular dynamics simulation and orthogonal tests, the results showed that, among the three aforementioned factors, the influence of crystal orientation at the depth of the subsurface deformation layer was the greatest, followed by that of grinding depth, while the influence of grinding speed was the weakest. Through the orthogonal tests, the factors affecting the significance of subsurface deformation depth were analyzed, and the results were found to be more meaningful compared with those of current single-factor studies. Meanwhile, in-depth exploration of the nanogrinding mechanism can provide the necessary theoretical basis for the development of nanomachining technology, which is of great significance for the improvement of ultra-precision cutting technology.

Automated summary

This study investigated the effects of three factors, grinding speed, grinding depth, and crystal orientation, on the subsurface deformation depth in a monocrystalline nickel nanofabrication process. The results showed that crystal orientation had the greatest influence on the subsurface deformation depth, followed by grinding depth, while grinding speed had the weakest influence. Orthogonal tests were used to analyze the significance of the factors affecting the subsurface deformation depth, and the results were found to be more meaningful compared to single-factor studies. Moreover, exploring the nanogrinding mechanism can provide a theoretical basis for the development of nanomachining technology, which is vital for improving ultra-precision cutting technology.