Improvement of wear behaviour of titanium by boriding

Kara, Gokhan; Pürçek, G.; Yanar, H.

doi:10.1108/ilt-11-2015-0174

Cited by 14 publications

(9 citation statements)

References 23 publications

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“…It resulted that the surface of the base sample formed a thick and dense layer of TiB 2 . Similar results have been reported in previous studies [14]. TiB 2 was the dominant phase for the samples treated at all boriding temperatures.…”

Section: Composition and Microstructuresupporting

confidence: 92%

“…Kara et al reported that boriding titanium at 950 • C substantially increases its wear resistance. Additionally, at this processing temperature, surface hardness achieved the maximum value [14]. Duan Y. H. et al reported the growth kinetics of Ti-6Al-4V alloy by boriding.…”

Section: Introductionmentioning

confidence: 85%

“…Many preliminary studies of boriding pure Ti have been performed, but few investigated different boriding temperatures [14][15][16][17][18]. Kara et al reported that boriding titanium at 950 • C substantially increases its wear resistance.…”

Section: Introductionmentioning

confidence: 99%

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Improvement of Mechanical, Tribological, and Fricative Reduction Properties of Pure Titanium by Boriding

Chen

Koyama

2021

Applied Sciences

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Surface boriding of pure titanium was performed using dissolved salt impregnation to modify the surface hardness and improve wear performance. The effect of boriding temperature (950–1150 °C) on the microstructure, composition, and room-temperature tribological properties of the borided samples was investigated by X-ray diffraction, scanning electron microscopy, and ball-on-disc tribometry, respectively. Gibbs free energy was also calculated to evaluate the compounds generated during the boriding at different temperatures. After a detailed analysis of the crystal structures and the growth morphologies of TiB, the diffusion mechanisms for B atoms in TiB and TiB2 were discussed in the present report. The boriding temperature had a large effect on the microstructure, mechanical properties, and room-temperature tribological behavior of the borided samples, attributed to the changes in the composition and the increased hardened layer under elevated boriding temperature. The modeling of layer growth kinetics was also discussed in this paper. The actual value of hardened layer thickness was compared to the calculated value, and the difference was analyzed. The fricative value of the borided samples showed a minimum value of 88.9 dB for a boriding temperature of 1050 °C. The depth and width of the wear tracks decreased gradually with increasing boriding temperature. The worn surface of the samples borided at higher temperatures showed very good wear resistance. A boriding condition of 1050 °C was considered optimal, as it provided sufficiently high surface hardness and a low fricative value to reduce vibrations during practical use.

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Section: Composition and Microstructuresupporting

confidence: 92%

Section: Introductionmentioning

confidence: 85%

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Improvement of Mechanical, Tribological, and Fricative Reduction Properties of Pure Titanium by Boriding

Chen

Koyama

2021

Applied Sciences

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“…Increasing surface hardness is one of the effective methods to improve wear resistance (Kara et al , 2017). Tian et al (2021) found that the surface hardness of Ti-6Al-4V alloy increased to 1100 HV 0.1 compared with the matrix after carburizing.…”

Section: Introductionmentioning

confidence: 99%

Tribological investigations of boride layers on Ti6Al4V at room and elevated temperatures

Zhang

Bai

et al. 2023

ILT

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Purpose This paper aims to improve the wear resistance of titanium alloy using a high-hardness boride layer, which was fabricated on Ti6Al4V by a high-temperature boronizing process. Design/methodology/approach The boride layers on Ti6Al4V were obtained at 1000°C for 5–15 h. Scanning electron microscopy, energy dispersive analysis and X-ray diffractometer were used to characterize the properties of the boride layer. The tribological performance of the boride layer at room and elevated temperatures was investigated. Findings The X-ray diffraction analysis showed that the boride layers were a dual-phase structure of TiB and TiB2. When the boronizing time increased from 5 h to 15 h, the microhardness increased from 1192 HV0.5 to 1619.8 HV0.5. At 25°C and elevated temperatures, the friction coefficients of the boride layers were higher than that of Ti6Al4V. The wear track areas of T-5 at 200°C and 400°C were 2.5 × 10–3 and 1.1 × 10–3 mm2, respectively, which were 6.1% and 2.6% of that of Ti6Al4V, indicating boride layer exhibited a significant wear resistance. The wear mechanisms of the boride layer transformed from slight peeling to oxidative wear and abrasive wear as the temperature was raised. Originality/value The findings provide an effective strategy for improving the wear resistance of Ti6Al4V and have important implications for the application of titanium alloy in a high-temperature field.

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“…In another study, Kara, Purcek and Yanar applied a boride layer on pure titanium (grade-2). The COF decreased by about 21% [10]. Furthermore, due to its simplicity and versatility, it can be made in ferrous and non-ferrous high melting point metallic materials, a process that is commonly used today.…”

Section: Introductionmentioning

confidence: 99%

Production and Characterization of Boride and Carbide Layers on AISI 15B30 Steel

Triani

Gomes

Casteletti

et al. 2019

Heat Treat 2019: Proceedings From the 30th Heat Treating Society Conference and Exposition

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In this work, boriding and Thermo-reactive Deposition (TRD) treatments for the production of boride and both vanadium and niobium carbide layers were performed on the substrates of AISI 15B30 steel to evaluate properties such as hardness, adhesive wear resistance, surface adhesion and chemical compounds present in the layers. For this purpose, layers were characterized by optical microscope, Knoop microhardness, microadhesive wear test, Rockwell C indentation adhesion according to VDI 3198 and X-ray diffraction. The results showed layers with high hardness (1400 - 2500 HK), greater microadhesive wear resistance (up to 15 times higher) when compared to the substrate and excellent delamination resistance.

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Improvement of wear behaviour of titanium by boriding

Cited by 14 publications

References 23 publications

Improvement of Mechanical, Tribological, and Fricative Reduction Properties of Pure Titanium by Boriding

Improvement of Mechanical, Tribological, and Fricative Reduction Properties of Pure Titanium by Boriding

Tribological investigations of boride layers on Ti6Al4V at room and elevated temperatures

Production and Characterization of Boride and Carbide Layers on AISI 15B30 Steel

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