Abstract
Titanium alloys are widely used in many areas, such as aerospace, biomedical, and automotive industries, due to their excellent chemical and physical properties. However, its difficult-to-machine characteristic causes various problems in the machining process, such as serious tool wear and elastic deformation of workpieces. To achieve high efficiency and quality of machining titanium alloy materials, this paper conducted an experimental research on the high-speed milling of TC11 titanium alloy with self-propelled rotary milling cutters. In this paper, the wear mechanism of self-propelled rotary milling cutters was explored; the influence of milling velocity was analyzed on cutting process, and the variation laws with the change in milling length were obtained of milling forces, chip morphology, and machined surface quality. The calculation method of self-propelled rotary velocity was proposed, based on the experimental research. The results showed that in the early and middle stages of milling, the insert coating peeled off evenly under the joint action of abrasive and adhesive wear mechanisms. As the milling length increased, the dense notches occurred on the cutting edge of the cutter, the wear mechanism converted gradually into fatigue wear, and furthermore, coating started peeling off the cutting edge with the occurrence of thermal fatigue cracks on the insert. As the milling length was further extended, the milling forces tended to intensify, the chip deformation worsened, and the obvious cracks occurred at the bottom of chips. The increase in milling velocity intensified the friction between chips and self-propelled rotary milling cutters, and decreased the ratio of self-propelled rotary velocity to milling velocity. This caused the drop in cutting performance of cutters and the growth in tool wear rate.
Highlights
With excellent physical and chemical properties, the titanium alloy is widely used in the aerospace, chemical and automobile industries [1,2,3]
The results showed that the self-propelled rotary tools (SPRT) generated lower cutting temperatures
In this paper the corresponding experiment was designed on the high-speed milling of TC11 titanium alloy with the self-propelled rotary milling cutters (SPRMC), for obtaining the variation laws of the tool wear morphology, the tool wear mechanism, the chip morphology, the milling forces and the machined surface quality with the milling length
Summary
With excellent physical and chemical properties, the titanium alloy is widely used in the aerospace, chemical and automobile industries [1,2,3]. The results revealed that the revolving cycloid milling cutter can significantly reduce the axial and tangential forces, and had better wear resistance and surface quality than the ball end milling cutter These studies have provided some good ideas and solutions for the difficulties of machining the titanium alloy, but some problems still occur in the machining process, such as the concentration of tool wear, higher cutting temperature in the local area, etc. In this paper the experimental research was performed on the high-speed milling of TC11 titanium alloy with self-propelled rotary milling cutters (SPRMC), and the cutting performance of cutters was analyzed, based on the milling forces, the tool wear morphology and the wear mechanism This promotes theoretically widespread application of the technique for milling the titanium alloy with the SPRMC
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