Abstract
To enhance the cutting performance of TiAlSiN coated cemented carbide tools by inserting Ti interlayers and to explore their mechanism, TiAlSiN/Ti multilayer coatings with different Ti thicknesses, including 0 nm, 25 nm, 50 nm, 100 nm, and 150 nm, were deposited onto cemented carbide (WC-10 wt%, Co) substrates by high power impulse magnetron sputtering (HiPIMS). The microstructure, hardness, grain orientation, residual stress, adhesion, and toughness of those coatings were measured, and the cutting performance against Inconel 718 was analyzed. Meanwhile, finite element method (FEM) indentation simulations were performed to gain detailed insight into the effects of Ti interlayer thickness on mechanical properties of TiAlSiN/Ti multilayer coatings. Results demonstrated that mechanical properties of TiAlSiN multilayer coatings were significantly changed after the Ti interlayer was introduced, and the multilayer coating #M2 with 25 nm Ti layer showed the excellent toughness and adhesion without sacrificing hardness too much. As Ti interlayer thickness increased, both toughness and adhesion decrease owing to the plastic mismatch between individual layers, and these changes were discussed detailedly with finite element method. Moreover, the result of the cutting experiment also revealed that the tool flank wear Vb can be reduced by the multilayer structure. This improvement is believed to be due to the increasing toughness, which alleviated the damage caused by the continuous impact load of hard phases generated by Inconel 718 during cutting.
Highlights
Inconel 718, with its capability of maintaining superior, excellent mechanical properties under extreme conditions, is a type of superalloy widely used in the aircraft and nuclear industries
Results demonstrated that mechanical properties of TiAlSiN multilayer coatings were significantly changed after the Ti interlayer was introduced, and the multilayer coating #M2 with 25 nm Ti layer showed the excellent toughness and adhesion without sacrificing hardness too much
As Ti interlayer thickness increased, both toughness and adhesion decrease owing to the plastic mismatch between individual layers, and these changes were discussed detailedly with finite element method
Summary
Inconel 718, with its capability of maintaining superior, excellent mechanical properties under extreme conditions, is a type of superalloy widely used in the aircraft and nuclear industries. Extensive researches have been made on TiAlN hard coatings in cutting Inconel 718, as this material possesses high hardness, high wear resistance, high high-temperature stability, and superior mechanical properties [5,6,7]. Inconel 718 will generate a quantity of hard phases (TiC, NbC, MoC) [19,20], which can produce a continuous and intensive shock load on the coatings of tools Under such conditions, the coatings have to possess higher toughness to resist such shock. This study provides a method to improve the cutting performance of TiAlSiN coated tool in cutting Inconel 718, and can be used as a reference for the application of brittle coatings under high impact load conditions
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