Processability improvement of laser-assisted micro-machining 95W-3.5Ni-1.5Fe alloy based on surface and subsurface characteristics

Laser-assisted micro-machining proves advantageous in improving the machinability of hard-brittle materials, but its effectiveness is easily weakened due to the uncertainty and complexity of microstructural transformation characteristics. In this research, a comprehensive investigation of the sustainable production mechanisms of tungsten heavy alloys was presented through recognizing the surface morphologies, subsurface microstructures, as well as micro-tool wear features, supported by the critical outcomes from single laser scanning (SLS) and laser-assisted micro-milling (LAMM) experimental tests. A laser thermal affected zone, which is composed mainly of surface oxide layer, near-surface softening layer, and subsurface metamorphic layer, was produced in laser heating. The relationship model between surface energy density and the thickness of laser thermal affected zone was determined. On this basis, a microstructure-based selection approach of the LAMM conditions, such as laser power and the depth of cut, was adopted to achieve a high-performance surface. Results indicated that a nanometer-level roughness surface, Sa = 57.03 nm, with no apparent residual thermal affected layer and newly generated subsurface damage layer were identified while suppressing flank wear. It is confirmed that the adaptability between the thickness of laser thermal affected layer and the depth of cut impacts LAMM sustainable production and justifies its application prospect. (c) 2022 Published by Elsevier Ltd. This is an open access article under the CC BY-NC-ND license (http:// creativecommons.org/licenses/by-nc-nd/4.0/).

Automated summary

In this research, a comprehensive investigation was conducted on the sustainable production mechanisms of tungsten heavy alloys through experimental tests and analysis of surface morphologies, subsurface microstructures, and micro-tool wear features. The study found that high-performance surfaces can be achieved and flank wear can be suppressed by selecting appropriate laser-assisted micro-milling conditions.