Mechanic of Advanced and Smart Materials
Quarterly

Modeling and Global Sensitivity Analysis of Surface Roughness in Cortical Bone Grinding process

Document Type : Original Article

Authors

Ali Akhondi
Vahid Tahmasbi
mahdi qasemi

Department of mechanical engineering of Arak university of technology, Arak, Iran

10.61882/masm.5.1.20.
Abstract
This experimental study investigated the effect of machining parameters on the surface roughness of bone during the grinding process. Bone grinding is commonly used in neurosurgery, spinal operations, and heel spur removal. Despite using CNC machines and robotic systems in this field, selecting optimal process parameters to achieve desirable surface quality remains a significant challenge. In this research, bovine femur bone samples were subjected to experimental trials. Four parameters were examined, including spindle speed, feed rate, depth of cut, and tool diameter. The Sobol sensitivity analysis method was implemented using Python programming to assess surface roughness's sensitivity to these parameters. Subsequently, response surface methodology (RSM) in Minitab software was employed for results analysis and process optimization. The findings revealed that tool diameter, depth of cut, and osteon orientation had the most substantial influence on surface roughness. The optimum roughness value of 1.47 µm was obtained under specific conditions: spindle speed of 3000 rpm, feed rate of 60 mm/min, depth of cut of 0.1 mm, tool diameter of 8 mm, and across osteon orientation. The sensitivity analysis confirmed the dominant role of tool diameter in both longitudinal and across osteon orientations.

Keywords

Grinding
roughness
optimization
Sensitivity analysis
Cortical bone
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Mechanic of Advanced and Smart Materials
Volume 5, Issue 1
Spring 2025
Pages 20-42

  • Receive Date 03 May 2025
  • Revise Date 24 May 2025
  • Accept Date 08 June 2025

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