Investigation of borided layers contribution on the wear resistance and adhesion of TiN coatings

Almeida, Elisangela Aparecida dos Santos de; Costa, César Edil da; Milan, Júlio César Giubilei; Krelling, Anael Preman; Galiotto, Alexandre

doi:10.1590/s1517-707620170001.0119

Cited by 4 publications

(1 citation statement)

References 15 publications

(16 reference statements)

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“…This could be due to the microstructure heterogeneity of boroniobized samples. While the AISI 52100 steel ball slides over an SiC-coated AISI 1020 surface in the untreated condition leading to an artificial reduction of the wear coefficient for this surface condition [28,[41][42][43], the presence of the porous region in the iron/niobium borides interface in the boroniobized samples may lead to a decrease in the load bearing capacity of the substrate, accelerating the beginning of the wear process through the delamination of the niobium boride layer [44][45][46][47]. Indeed, for a 0.98 N applied load and 0.5 g cm −3 abrasive slurry concentration (lower k according to table 1), the wear crater depth obtained from equation (2) ranged from 22.5 to 87.3 μm for a sliding distance variation of 4-96 m. For the condition that showed the higher wear coefficient, 0.49 N applied load and 0.5 g cm −3 slurry concentration, the wear crater depth ranged from 32.3 to 84.5 μm for the same sliding distance variation.…”

Section: Tribological Behaviormentioning

confidence: 99%

Microstructural and tribological characterization of niobium boride coating produced on AISI 1020 steel via multicomponent boriding

Krelling

Almeida

Costa

et al. 2020

Mater. Res. Express

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Niobium boride coating was produced on AISI 1020 steel by multicomponent boriding process. Boriding treatment at1000°C for 4 h was followed by thermo-reactive diffusion technique at 1000°C for 6 h under argon atmosphere. Microabrasive wear tests were carried out using SiC abrasive particles at slurry concentrations of 0.5 and 1.0 g cm −3 . Normal loads of 0.49 and 0.98 N were used. NbB and Nb 5 B 6 phases were identified by XRD analysis. The niobium boride coating thickness was 2.0±0.5 μm and its hardness was 1360±200 HK 0.01 . Owing to the presence of a porous region on the niobium/iron boride layers the abrasive wear resistance decreased comparing to the borided and untreated AISI 1020 steel. Rolling abrasion was the main wear mechanism observed.

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Section: Tribological Behaviormentioning

confidence: 99%

Microstructural and tribological characterization of niobium boride coating produced on AISI 1020 steel via multicomponent boriding

Krelling

Almeida

Costa

et al. 2020

Mater. Res. Express

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Microstructure and properties of borided Monel 400 alloy

Krelling

Melo

Almeida

et al. 2019

Mater. Res. Express

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Tribological properties and characterization of borided Co–Mg alloys

Yildiz

2022

Open Chemistry

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In this study, tribological properties and characterization of borided Co–Mg alloys were investigated. Cobalt–magnesium (CM) alloys with 97% Co–3% Mg composition were borided at temperatures of 850–900°C and for 1.5–4.5 h with solid boriding. The properties of the resulting boride layers were measured and determined by microhardness, scanning electron microscopy (SEM), X-ray diffraction (XRD), density, and surface roughness testers. XRD analysis results after boriding found CoB, Co2B, and Co phases. Depending on the boriding time and temperature, the thickness of the boride layer for the CM alloy varied from 51 to 138 µm. The boride layer had a hardness varying between 1,674 and 1,956 HV0.05 for the CM alloy, while the Vickers hardness value of untreated Cobalt was 52 HV0.05. The wear tests were carried out in a ball-disc arrangement under a dry friction condition at room temperature with an applied load of 10 N and with a sliding speed of 0.3 m/s at a sliding distance of 250 m. It was observed that the wear rate of borided and unborided CM alloy ranged from 25.89 × 10−5 to 94.95 × 10−5 mm3/N m. As a consequence of the findings, the author reported that boriding CM alloys in the given conditions can make a difference for different application areas.

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Investigation of borided layers contribution on the wear resistance and adhesion of TiN coatings

Cited by 4 publications

References 15 publications

Microstructural and tribological characterization of niobium boride coating produced on AISI 1020 steel via multicomponent boriding

Microstructural and tribological characterization of niobium boride coating produced on AISI 1020 steel via multicomponent boriding

Microstructure and properties of borided Monel 400 alloy

Tribological properties and characterization of borided Co–Mg alloys

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