Effect of TiC Content and TaC Addition in Substrates on Properties and Wear Behavior of TiAlN-Coated Tools

Jiao, Yi; Xu, Yinchao; Liu, Zhixiong; Xiao, Lijuan

doi:10.3390/coatings12121911

Cited by 2 publications

(1 citation statement)

References 39 publications

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“…In this direction, the formation of carbides could be a perspective direction as these components are known as hard and wear-resistant [22][23][24]. It is well known that the TiC compound is characterized by very high hardness, and therefore, it is expected that the fabricated composite Ti-C layers result in a significant improvement of the microhardness of the titanium substrates [25]. The TiC compound is known as significantly harder in comparison with a number of transition metal nitride coatings (such as TiN, CrN, ZrN, etc.…”

Section: Introductionmentioning

confidence: 99%

Fabrication and Characterization of Ti/TiC Composite Layers by an Electron-Beam Surface Modification

Valkov,

Nedeva,

Dunchev

et al. 2023

Coatings

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In this study, the possibilities for modification and improvement of the surface structure and properties of titanium substrates by a formation of composite Ti/TiC layers are presented. The layers were fabricated by a two-step electron-beam surface modification technique. The first step consists of injection of C powder within the pure Ti substrates by electron-beam alloying technology. The second step is the refinement and homogenization of the microstructure by the electron-beam remelting procedure. During the remelting, the speed of the motion of the samples was varied, and two (most representative) velocities were chosen: 5 and 15 mm/s. Considering both speeds of the motion of the specimens, a composite structure in the form of fine TiC particles distributed within the base titanium matrix was formed. The remelting speed of 5 mm/s led to the formation of a much thicker composite layer, where the TiC particles were significantly more homogeneously distributed. The results obtained for the Vickers microhardness exhibit a significant increase in the value in the mentioned mechanical characteristic in comparison with the base Ti substrate. In the case of the lower speed of the motion of the specimen during the remelting procedure, the microhardness is 510 HV, or about 2.5 times higher than that of the titanium substrate. The application of a higher speed of the specimen motion leads to a decrease in the microhardness in comparison with the case of lower velocity. However, it is still much higher than that of the base Ti material. The mean microhardness of the sample obtained by the remelting speed of motion of 15 mm/s is 360 HV, or it is 1.8 times higher than that of the base material.

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Section: Introductionmentioning

confidence: 99%

Fabrication and Characterization of Ti/TiC Composite Layers by an Electron-Beam Surface Modification

Valkov,

Nedeva,

Dunchev

et al. 2023

Coatings

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Analysis of Wear Using the Taguchi Method in TiSiNOS-Coated and Uncoated H13 Tool Steel

Alphonse,

Murali,

Salunkhe

et al. 2023

Coatings

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Titanium–silicon oxynitride sulfite (TiSiNOS) is a coating material that is deposited on H13 tool steel using the scalable pulsed power plasma (S3P) technique, where the coating deposition is a hybrid process consisting of a mix of sputtering and arc evaporation. The maximum hardness and coating thickness measured on TiSINOS-coated H13 tool steel are 38 GPa and 3.1 µm, respectively. After implementing the L9 orthogonal array, nine samples were coated with TiSiNOS, which consists of the same properties. The nine coated and uncoated samples were tested separately based on the L9 pattern to achieve accurate results. The experimental results indicate that the wear loss can be reduced by minimizing the load at 25 N even if the temperature rises to 250 °C. SEM analysis reveals that the uncoated sample has higher wear loss when compared with the coated samples, and material pullout is visible from the uncoated sample. Based on these results, it can be concluded that TiSINOS coating in H13 tool steel helps in improving the tool life during the drilling process. Taguchi was used in this research to evaluate the wear behavior. The data observed from the experiment were analyzed using the Minitab tool. The most crucial factor is to determine the effects of process parameters. A higher temperature influenced the wear behavior of the tool.

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Effect of TiC Content and TaC Addition in Substrates on Properties and Wear Behavior of TiAlN-Coated Tools

Cited by 2 publications

References 39 publications

Fabrication and Characterization of Ti/TiC Composite Layers by an Electron-Beam Surface Modification

Fabrication and Characterization of Ti/TiC Composite Layers by an Electron-Beam Surface Modification

Analysis of Wear Using the Taguchi Method in TiSiNOS-Coated and Uncoated H13 Tool Steel

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