Analysis: of a mechanism of bone cutting has an important theoretical and practical significance for orthopaedic
surgeries. In this study, the mechanism of material removal in orthogonal cutting of cortical bone is investigated.
Chip morphology and crack propagation in cortical bone for various cutting directions and depth-of-cut (DOC)
levels are analysed, with consideration of microstructural and sub-microstructural features and material
anisotropy. Effects of different material properties of osteons, interstitial matrix and cement lines on chip
morphology and crack propagation are elucidated for different cutting directions. This study revealed that differences in chip morphology for various DOCs were due to comparable sizes of the osteons, lamellae and DOC.
Acquired force signals and recorded high-speed videos revealed the reasons of fluctuations of dynamic components in tests. Meanwhile, a frequency-domain analysis of force signals showed a frequency difference between
formation of a bulk fractured chip and small debris for different cutting directions. In addition, SEM images of the
top and side surfaces of the machined bone were obtained. Thus, the analysis of the cutting force and surface
damage validated the character of chip formation and explained the material-removal mechanism. This study
reveals the mechanism of chip formation in the orthogonal cutting of the cortical bone, demonstrating importance of the correlation between the chip morphologies, the depth of cut and the microstructure and submicrostructure of the cortical bone. For the first time, it assessed the fluctuations of cutting forces, accompanying chip formation, in time and frequency domains. These findings provide fundamental information important for analysis of cutting-induced damage of the bone tissue, optimization of the cutting process and clinical
applications of orthopaedic instruments.
Funding
China Postdoctoral Science Foundation through grants No. 2019M652629 and No. 2019TQ0107
History
School
Mechanical, Electrical and Manufacturing Engineering
Published in
Journal of the Mechanical Behavior of Biomedical Materials
This paper was accepted for publication in the journal Journal of the Mechanical Behavior of Biomedical Materials and the definitive published version is available at https://doi.org/10.1016/j.jmbbm.2020.103618