A Chip Formation Study of the Micro-Cutting of Commercially Pure Titanium
João Octávio Marçal Assis,
Carlos Henrique Lauro,
Robson Bruno Dutra Pereira,
Lincoln Cardoso Brandão,
Étory Madrilles Arruda,
João Paulo Davim
Affiliations
João Octávio Marçal Assis
Department of Mechanical Engineering, Centre for Innovation in Sustainable Manufacturing, Federal University of São João del Rei, Praça Frei Orlando 170, São João del Rei 36307-352, Brazil
Carlos Henrique Lauro
Department of Mechanical Engineering, Centre for Innovation in Sustainable Manufacturing, Federal University of São João del Rei, Praça Frei Orlando 170, São João del Rei 36307-352, Brazil
Robson Bruno Dutra Pereira
Department of Mechanical Engineering, Centre for Innovation in Sustainable Manufacturing, Federal University of São João del Rei, Praça Frei Orlando 170, São João del Rei 36307-352, Brazil
Lincoln Cardoso Brandão
Department of Mechanical Engineering, Centre for Innovation in Sustainable Manufacturing, Federal University of São João del Rei, Praça Frei Orlando 170, São João del Rei 36307-352, Brazil
Étory Madrilles Arruda
Department of Mechanical Engineering, Centre for Innovation in Sustainable Manufacturing, Federal University of São João del Rei, Praça Frei Orlando 170, São João del Rei 36307-352, Brazil
João Paulo Davim
Department of Mechanical Engineering, University of Aveiro, Campus Santiago, 3810-193 Aveiro, Portugal
In recent years, micro-cutting has been employed to obtain components that are more detailed and/or have great surface quality, regardless of dimensions, like dental implants. In the manufacturing of medical/dental components, titanium and its alloys are biomaterials of great notability. Like in conventional machining, sustainability is a delicate issue because it does not only depend on environmental aspects. One simple solution would be to perform dry machining. However, in the machining of difficult-to-cut materials, like titanium and its alloys, the use of cutting fluids is generally recommended to avoid the high temperature causing damage to the tool and/or machined surface. Concerned with the quality surface that is required for dental components, this work investigates the use of cutting fluid in the micro-cutting of commercially pure titanium. Orthogonal micro-cutting experiments were carried out under dry and wet conditions, using cutting fluid at room and cooled temperatures. To evaluate the lubri-cooling performance, cutting efforts, the friction coefficient, specific cutting energy, and chip formation analysis were compared. The outcomes indicated that, under the test conditions, the use of dry cutting and high feed levels had a positive effect on micro-cutting performance.