Effect of friction modifiers compositions on tribological properties of Cu-Sn alloy/Al<sub>2</sub>O<sub>3</sub> brake composite material

Singh, Vaibhav; Raja, P. Sriram Karthick; Katiyar, Jitendra Kumar; Ramkumar, P.

doi:10.1177/1350650120974132

Cited by 10 publications

(10 citation statements)

References 22 publications

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“…Further, the abrasive wear and formation of oxide layer are possible wear mechanism at higher applied loads while adhesive wear is possible wear mechanisms at lower loads. A similar observation is reported by Sing et al 42 in their research work that is carried out on sintered composite of Cu-Sn alloy/Al 2 O 3 /graphite/talc.…”

Section: Resultssupporting

confidence: 88%

Optimization of tribological process parameters of titanium carbide reinforced copper matrix composites

Ravichandran¹,

Alagarsamy²,

Dinakaran³

et al. 2022

Proceedings of the Institution of Mechanical Engineers, Part J:

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Copper (Cu) matrix composites are developed by reinforcing Cu with Titanium Carbide (TiC) powder using the powder metallurgy (PM) method. Pin-on-disc tribo analysis is conducted to evaluate the tribological performance of the developed composites. Moreover, the influence of different parameters such as, concentration (wt.%) of TiC, applied load, sliding velocity and sliding distance on the wear rate and friction coefficient are studied using Taguchi L16 orthogonal array. The main effect plot reveals that the lowest wear rate is obtained at 12 wt.% of TiC, 10 N applied load, 4 m/s sliding velocity and 1750 m sliding distance. Similarly, the lowest friction coefficient is attained at 12 wt.% of TiC, 10 N applied load, 4 m/s sliding velocity and 750 m sliding distance. Analysis of variance (ANOVA) results shows that the wt.% of TiC powder is a more noteworthy parameter for obtaining the lowest wear rate and friction coefficient with a contribution of 94.54% and 94.17%, respectively. A regression model is also developed to predict the friction coefficient and wear rate for the developed composites.

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Section: Resultssupporting

confidence: 88%

Optimization of tribological process parameters of titanium carbide reinforced copper matrix composites

Ravichandran¹,

Alagarsamy²,

Dinakaran³

et al. 2022

Proceedings of the Institution of Mechanical Engineers, Part J:

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“…With the activation and deactivation of braking, the surface of brake components or materials deteriorates after a while. For such reasons, it is important to develop brake material components that provide the optimum friction coefficient with the increased wear resistance occurring in the materials (Singh et al , 2021).…”

Section: Introductionmentioning

confidence: 99%

Friction and wear characteristics of brake friction materials obtained from fiber and huntite blends

Yavuz

Bayrakçeken

2022

ILT

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Purpose The purpose of this paper, brake friction material samples with six different contents were produced using three different fiber types consisting of variable proportions of huntite mineral and basalt, glass and steel fibers. The friction properties and formation of the transfer film in these friction materials were investigated. Design/methodology/approach Friction materials were produced using a hot molding method from materials containing 10%–15% huntite in varying proportions, consisting of basalt, glass and steel fibers. The densities and hardness values of the samples were measured. Friction tests were performed using a brake pad friction material tester to determine tribological properties. After the friction tests, microscopic examination of the sample surfaces was performed using scanning electron microscope (SEM) and three-dimensional (3D) surface profilometer devices. Findings Huntite mineral content and fiber type affected the friction coefficient. With an increase in the amount of huntite, the friction coefficient increased in the friction material samples formed with glass and steel fibers. The fiber type and amount of huntite also affected the transfer film formation. The surface roughness values of all the friction materials decreased with an increase in the amount of huntite. The surface roughness values of the samples with glass fibers were higher than those of other samples. Originality/value The importance of using huntite minerals and different fiber types in automotive brake friction materials is emphasized. This will help industrial companies and academics study the tribological properties of friction materials.

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“…Finally, it has been concluded that the adhesive, abrasive, and plow wear are possible to wear mechanisms at the counterface. Singh et al 30 investigated the tribological performance of Cu–Sn alloy/Al 2 O 3 /graphite/talc composite, fabricated by the powder metallurgy technique and observed a similar phenomenon.…”

Section: Resultsmentioning

confidence: 84%

Optimization of tribo-mechanical properties of boron carbide reinforced magnesium metal matrix composite

Ravichandran¹,

Veerappan²,

Dhinakaran³

et al. 2021

Proceedings of the Institution of Mechanical Engineers, Part J:

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In this study, magnesium–boron carbide composites are developed through the powder metallurgy technique and investigated for their tribological properties using a pin-on-disc tribometer. The process parameters such as load, sliding distance, sliding velocity, and concentration (wt%) of boron carbide are optimized using Taguchi's L16 array. A lower wear rate of magnesium–boron carbide composite is obtained at optimized process parameters. Further, the analysis of variance result shows that the most dominating factor that affects the wear loss is load followed by concentration of boron carbide reinforcement. Moreover, the optimum parameters for the low wear rate of magnesium–boron carbide composites are obtained as 5 N, 6 wt% of boron carbide, 1200 m, and 3 m/s through signal-to-noise ratio analysis. Further, the mechanical properties of magnesium–boron carbide composites such as hardness and compressive strength are also analyzed. The result shows that the hardness and compressive strength of magnesium–boron carbide composites are improved with the inclusion of boron carbide reinforcement.

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Effect of friction modifiers compositions on tribological properties of Cu-Sn alloy/Al₂O₃ brake composite material

Cited by 10 publications

References 22 publications

Optimization of tribological process parameters of titanium carbide reinforced copper matrix composites

Optimization of tribological process parameters of titanium carbide reinforced copper matrix composites

Friction and wear characteristics of brake friction materials obtained from fiber and huntite blends

Optimization of tribo-mechanical properties of boron carbide reinforced magnesium metal matrix composite

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Effect of friction modifiers compositions on tribological properties of Cu-Sn alloy/Al2O3 brake composite material

Cited by 10 publications

References 22 publications

Optimization of tribological process parameters of titanium carbide reinforced copper matrix composites

Optimization of tribological process parameters of titanium carbide reinforced copper matrix composites

Friction and wear characteristics of brake friction materials obtained from fiber and huntite blends

Optimization of tribo-mechanical properties of boron carbide reinforced magnesium metal matrix composite

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Effect of friction modifiers compositions on tribological properties of Cu-Sn alloy/Al₂O₃ brake composite material