Titanium alloy, an ideal aviation and biomedical material, is generally considered as a
typical difficult-to-cut material because of low elastic modulus and poor thermal conductivity …

The metal cutting process is accompanied by complex stress field, strain field, temperature
field. The comprehensive effects of process parameters on chip morphology, cutting force …

Titanium alloy is extremely difficult to machine due to the rapid tool wear. The influence of
tool wear on surface topography and chip formation, during micro-milling of Ti-6Al-4V, using …

Laser-assisted machining (LAM) has demonstrated exceptional performance in terms of
improving the machinability of difficult-to-cut materials like Ti6Al4V. This study reveals a …

The altered microstructure during machining process had an inverse influence on materials
behavior, machining forces and surface integrity. Thus, a constitutive model which builds the …

Although titanium (Ti) alloys possess unique properties that allow them to compete with
many other materials in advanced industries such as aerospace, marine and biomedical …

To meet the growing demands of sophisticated component service life and miniaturization,
the study of surface integrity such as residual stress after the machining becomes more …

A known problem of additive manufactured parts is their poor surface quality, which
influences product performance. There are different surface treatments to improve surface …

The present paper describes and uses a novel bi-spectral imaging apparatus dedicated to
the simultaneaous measurement of kinematic and thermal fields in orthogonal cutting …

The study proposes a coupled thermo-mechanical transient analysis to estimate the cutting
performance during micro-machining of Titanium alloy. A constitutive flow model is used …