Investigation of tribological and mechanical properties of aluminium boron carbide composites using response surface methodology and desirability analysis

Canute, X.; Majumder, M. C.

doi:10.1108/ilt-01-2017-0010

Cited by 16 publications

(9 citation statements)

References 55 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…7). The AlB 2 and Al 3 BC phases formed at the interface between the main matrix aluminum and the reinforcement B 4 C. The presence of the AlB 2 phase was relatively low [21]. The XRD results showed a more homogenous mixture with the 15% Al/B 4 C composite in comparison to the other reinforcement rates.…”

Section: Research Discussionmentioning

confidence: 89%

Investigation of Wear Behavior of Particle Reinforced AL/B4C Composites under Different Sintering Conditions

Topçu

2020

Teh. glas. (Online)

View full text Add to dashboard Cite

In this study, the effects of different sintering conditions of boron carbide reinforced to aluminum matrix powder on microstructure, density and wear resistance by a mechanical alloying method were researched. Powders produced by mechanical alloying for eight hours at the atrial shaft were compressed with a cold isostatic press die under 350 MPa to obtain cylindrical composite specimens. The raw samples were sintered in high purity argon at 600, 625, 650 °C for 90 minutes. The wear behavior of the Al/B4C metal matrix composite was studied using a pin-on-disk wear tester. Under favorable conditions, it has been observed that reinforced boron carbide wear can be reduced by more than two decades. Various investigations have been made to relate this improved wear performance to reinforcement ratios. Aluminum abrasion test results showed that different types of abrasion occurred and that the abrasion resistance was increased by the change of the bubble rate. In the experimental studies that were carried out, it was observed that wear resistance increased with the proportion of boron carbide reinforced directly by the weight, and especially with a 15% B4C ratio depending on the increased reinforcement ratio.

show abstract

Section: Research Discussionmentioning

confidence: 89%

Investigation of Wear Behavior of Particle Reinforced AL/B4C Composites under Different Sintering Conditions

Topçu

2020

Teh. glas. (Online)

View full text Add to dashboard Cite

show abstract

“…Therefore, the effect of wear restricted with micro plowing marks and minimal delamination [Figure 7 Figure 7(c) shows that the minor portion of the waviness textures was covered with the layer of deformed material which was deformed due to adhesive wear mechanism. Jiang et al (1994), Canute and Majumder (2017) and Mishra et al (2013) described that heat produced due to wear deforms the wear debris and deposited over the pin surface and subsequently form the deformed layer. Figure 7(d) shows worn-out surface of 14th experimental run covered with layer of deformed material and minimum plowing marks.…”

Section: Wear Mechanismmentioning

confidence: 99%

Effect of laser surface texturing on wear resistance of nickel based superalloy

Prakash

Duraiselvam

Natarajan

et al. 2019

ILT

View full text Add to dashboard Cite

Purpose This paper aims to investigate the effect of laser surface texturing (LST) on the wear behavior of C-263 nickel-based superalloy and to identify the optimum wear operating condition. Design/methodology/approach C-263 nickel-based superalloy was selected as substrate material and pico-second Nd-YAG laser was used to fabricate the waviness groove texture on their surface. Wear experiments were designed based on Box-Bhenken design with three factors of sliding velocity, sliding distance and applied load. Wear experiments were performed using pin on disc tribometer. Morphologies of textures and worn-out surfaces were evaluated by scanning electron microscopy and energy dispersive spectroscopy. Surface topographies and surface roughness of the textures were evaluated by weight light interferometry. The response surface methodology was adopted to identify the optimum wear operating condition and ANOVA to identify the significant factors. Findings LST improves the wear resistance of C-263 nickel-based superalloy by appeoximately 82 per cent. Higher wear rate occurs at maximum values of all operating conditions, and applied load affects the coefficient of friction. Applied load significantly affects the wear rate of un-textured specimen. The interaction of sliding velocity and applied load also affects the wear rate of textured specimens. The optimum parameters to get minimum wear rate for un-textured specimens are 1.5 m/s sliding velocity, 725 m sliding distance and 31 N of applied load. For textured specimens, the optimum values are 1.5 m/s sliding distance, 500 m sliding distance and 40 N of the applied load. Originality/value Literature on laser texturing on nickel-based superalloy is very scarce. Specifically, the effect of laser texturing on wear behavior of the nickel-based superalloy C-263 alloy is not yet reported.

show abstract

“…6,12,13 Producing aluminium matrix composites via stir casting is also in great demand lately. 12,14 A method which is a combination of these two methods mentioned above can be very useful and controllable way to produce particle reinforced composite foams.…”

Section: Introductionmentioning

confidence: 99%

Manufacturing of B₄C particle reinforced A360 aluminium cellular composite materials by the integration of stir casting and space holder methods

Sunar

Çetin

2021

Journal of Composite Materials

View full text Add to dashboard Cite

Stir casting method has become prominent for fabrication of metal matrix composites in recent years. This method can be adjusted for casting around space holding particles to obtain cellular composite materials. In this study, a specific method which is a combination of stir casting and space holder techniques were used to produce open-celled A360 aluminium-B4C composite foams with regular sized and distributed pores. Weight ratios of reinforcement particles determined as 0.5, 1, 1.5 and 2%. The influences of particle reinforcement on the microstructure and the mechanical behaviour of composite foams were investigated. Microstructures were analysed with optical microscope (OM), scanning electron microscope (SEM). Compression and hardness tests were carried out to observe the effects of reinforcement on mechanical properties. Compression strength properties and hardness of composites increased with the ceramic reinforcement, however the plastic strength of the composite foams showed worsening trend after a certain reinforcement ratio (0.5 wt.%). Energy absorption properties of the composite foams showed parallel trends with compressive strength properties.

show abstract

Investigation of tribological and mechanical properties of aluminium boron carbide composites using response surface methodology and desirability analysis

Cited by 16 publications

References 55 publications

Investigation of Wear Behavior of Particle Reinforced AL/B4C Composites under Different Sintering Conditions

Investigation of Wear Behavior of Particle Reinforced AL/B4C Composites under Different Sintering Conditions

Effect of laser surface texturing on wear resistance of nickel based superalloy

Manufacturing of B₄C particle reinforced A360 aluminium cellular composite materials by the integration of stir casting and space holder methods

Contact Info

Product

Resources

About

Investigation of tribological and mechanical properties of aluminium boron carbide composites using response surface methodology and desirability analysis

Cited by 16 publications

References 55 publications

Investigation of Wear Behavior of Particle Reinforced AL/B4C Composites under Different Sintering Conditions

Investigation of Wear Behavior of Particle Reinforced AL/B4C Composites under Different Sintering Conditions

Effect of laser surface texturing on wear resistance of nickel based superalloy

Manufacturing of B4C particle reinforced A360 aluminium cellular composite materials by the integration of stir casting and space holder methods

Contact Info

Product

Resources

About

Manufacturing of B₄C particle reinforced A360 aluminium cellular composite materials by the integration of stir casting and space holder methods