Abstract
Tribological phenomena and tool wear mechanisms during machining of hard-to-cut TiAl6V4 aerospace alloy have been investigated in detail. Since cutting tool wear is directly affected by tribological phenomena occurring between the surfaces of the workpiece and the cutting tool, the performance of the cutting tool is strongly associated with the conditions of the machining process. The present work shows the effect of different machining conditions on the tribological and wear performance of TiB2-coated cutting tools compared to uncoated carbide tools. FEM modeling of the temperature profile on the friction surface was performed for wet machining conditions under varying cutting parameters. Comprehensive characterization of the TiB2 coated vs. uncoated cutting tool wear performance was made using optical 3D imaging, SEM/EDX and XPS methods respectively. The results obtained were linked to the FEM modeling. The studies carried out show that during machining of the TiAl6V4 alloy, the efficiency of the TiB2 coating application for carbide cutting tools strongly depends on cutting conditions. The TiB2 coating is very efficient under roughing at low speeds (with strong buildup edge formation). In contrast, it shows similar wear performance to the uncoated tool under finishing operations at higher cutting speeds when cratering wear predominates.
Highlights
IntroductionTitanium alloys are widely used for components in the aerospace industry, due to their good combination of mechanical properties (high temperature strength, high ductility and toughness), and corrosion resistance at elevated temperatures [1]
Titanium alloys are widely used for components in the aerospace industry, due to their good combination of mechanical properties, and corrosion resistance at elevated temperatures [1]
TiB2 coating application for carbide cutting tools strongly depends on the cutting conditions
Summary
Titanium alloys are widely used for components in the aerospace industry, due to their good combination of mechanical properties (high temperature strength, high ductility and toughness), and corrosion resistance at elevated temperatures [1]. Machining these alloys poses a challenge due to the high temperatures generated during cutting as a result of intensive adhesion of the workpiece material to the tool surface. This can be related to the high hardness and residual stress level of this family of coatings [3]. Cutting phenomena vary significantly during machining of Ti alloys under different machining conditions, such as those widely used in industry roughing and finishing operations [7,8]
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