Characterisation of CoB–Co<sub>2</sub>B coatings by the scratch test

Bravo-Bárcenas, D.; Campos-Silva, I.; Çi̇menoǧlu, Hüseyin; Martínez-Trinidad, J.; Flores-Jiménez, M.; Martínez‐Gutiérrez, Hugo

doi:10.1080/02670844.2015.1121315

Cited by 27 publications

(8 citation statements)

References 19 publications

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“…Also, the difference of Young´s modulus of the cobalt boride layers, the presence of cracks and porosity cause larger gradients along the depth of the CoB-Co 2 B layer. The state of residual stresses estimated on the cobalt boride layers is comparable with those reported in the literature for the CoB and Co 2 B layers obtained by the CPBP [7].…”

Section: Growth Kinetics Of Cob-co 2 B Layers During the Pbcdf Processsupporting

confidence: 85%

“…After the PBDCF process, the samples were subjected to metallographic characterization according to the method proposed by Bravo-Bárcenas et al [7], in order to reveal the microstructure of the cobalt boride layer.…”

Section: Methodsmentioning

confidence: 99%

“…In recent years, research on the boriding of cobalt alloys has advanced, specifically regarding the wear and oxidation properties of the cobalt boride layers [2][3][4]. In addition, the growth kinetics, some indentation properties, micro-abrasive wear resistance of CoB-Co 2 B, and the practical adhesion resistance of the cobalt boride layers formed on the surface of the CoCrMo alloy by means of the conventional powder-pack boriding (CPBP) process have been estimated [5][6][7].…”

Section: Introductionmentioning

confidence: 99%

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Growth Kinetics of CoB–Co₂B Layers Using the Powder-Pack Boriding Process Assisted by a Direct Current Field

Campos-Silva

Franco-Raudales

Meda-Campaña

et al. 2018

High Temperature Materials and Processes

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New results about the growth kinetics of CoB–Co2B layers developed at the surface of CoCrMo alloy using the powder-pack boriding process assisted by a direct current field (PBDCF) were estimated in this work. The PBDCF was conducted at temperatures of 1048 – 1148 K with different exposure times for each temperature, whereas the growth kinetics of the cobalt boride layers was modelled using a system of two differential equations. In addition, indentation properties such as hardness, Young’s modulus and residual stresses were estimated along the depth of the borided CoCrMo surface. The growth kinetics of the cobalt boride layers developed by PBDCF indicated that thicker boride layers were formed on the material’s surface which was in contact to the current field at the anode, in contrast to the surface exposed at the cathode. The kinetics of cobalt boride layers were compared with those obtained by conventional powder-pack boriding process.

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Section: Growth Kinetics Of Cob-co 2 B Layers During the Pbcdf Processsupporting

confidence: 85%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Growth Kinetics of CoB–Co₂B Layers Using the Powder-Pack Boriding Process Assisted by a Direct Current Field

Campos-Silva

Franco-Raudales

Meda-Campaña

et al. 2018

High Temperature Materials and Processes

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“…The normal force (F N ) is constantly increased, generating a worn track with different failure mechanisms over the layer surface. The worn tracks are analysed in terms of the critical scratch load (L CN ) to estimate the characteristic failure mechanisms associated with visual microscopy inspections, CoF, and residual depth [17][18][19].…”

Section: Scratch Adhesion Testmentioning

confidence: 99%

Adhesion behaviour of borided AISI 4140 steel

Márquez-Cortés

Martínez-Trinidad

León

2022

Surface Engineering

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In this study, the adhesion behaviour of the borided AISI 4140 steel was estimated. A di-iron boride layer (Fe 2 B = ∼22 µm) was obtained on the surface of the AISI 4140 steel preheated at 773 K for 30 min to prevent thermal shock; afterwards, the samples were exposed to 1173 K for 30 min. The scratch tests were developed over the surface of the Fe 2 B/substrate system using a Rockwell-C diamond indenter with a normal force increasing from 0.5-80 N. The friction coefficient behaviour and the residual depth values were measured considering the scratch length that was monitored during the test, according to the ASTM C1624 standard procedure. Critical loads were determined through the combination of the normal force and visual inspection over the worn surface with cracks (cohesive failure) or detachment (adhesive failure) and are explained according to the mechanical properties of the Fe 2 B/substrate system.

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“…Also, some researchers studied the in vitro biocompatibility of Co-Cr alloys produced by SLM (Hedberg et al , 2014; Xin et al , 2012; Al Jabbari et al , 2014). Some of the researchers boronized Co-Cr alloys obtained by casting and studied the morphology and properties of the samples (Mu and Shen, 2010; Alvarez et al , 2013; Barcenas, et al , 2016). However, no study has yet been conducted on the mechanical and tribological effects of boronizing on CoCrW alloy produced by SLM.…”

Section: Introductionmentioning

confidence: 99%

Effect of boronizing on the structural, mechanical and tribological properties of CoCrW dental alloy produced by selective laser melting

Uzun

Kovacı

Yetim

et al. 2019

ILT

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Purpose This paper aims to investigate the effects of boriding on the structural, mechanical and tribological properties of CoCrW dental alloy manufactured by the method of selective laser melting. Design/methodology/approach In this study, CoCrW alloy samples that are used in dentistry were manufactured by the method of laser melting, and boriding treatment was made on the samples at 900°C and 1,000°C for 1, 4 and 8 h. The structural, mechanical and tribological effects of boriding on the samples were analyzed using X-ray diffraction, scanning electron microscopy, energy dispersive X-ray spectroscopy, microhardness and an abrasion test device. Findings According to the results, the best outcomes in terms of abrasion strength and hardness were obtained in the sample that was subjected to boriding at 1,000°C for 4 h. Originality/value This study produced CoCrW alloys, which are fundamental biomaterials that are used in dentistry, by a different production method called selective laser melting and improved their surface characteristics by boriding.

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Characterisation of CoB–Co₂B coatings by the scratch test

Cited by 27 publications

References 19 publications

Growth Kinetics of CoB–Co₂B Layers Using the Powder-Pack Boriding Process Assisted by a Direct Current Field

Growth Kinetics of CoB–Co₂B Layers Using the Powder-Pack Boriding Process Assisted by a Direct Current Field

Adhesion behaviour of borided AISI 4140 steel

Effect of boronizing on the structural, mechanical and tribological properties of CoCrW dental alloy produced by selective laser melting

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Characterisation of CoB–Co2B coatings by the scratch test

Cited by 27 publications

References 19 publications

Growth Kinetics of CoB–Co2B Layers Using the Powder-Pack Boriding Process Assisted by a Direct Current Field

Growth Kinetics of CoB–Co2B Layers Using the Powder-Pack Boriding Process Assisted by a Direct Current Field

Adhesion behaviour of borided AISI 4140 steel

Effect of boronizing on the structural, mechanical and tribological properties of CoCrW dental alloy produced by selective laser melting

Contact Info

Product

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Characterisation of CoB–Co₂B coatings by the scratch test

Growth Kinetics of CoB–Co₂B Layers Using the Powder-Pack Boriding Process Assisted by a Direct Current Field

Growth Kinetics of CoB–Co₂B Layers Using the Powder-Pack Boriding Process Assisted by a Direct Current Field