Microstructure, hardness, and wear properties of AA6061/WC nanocomposite fabricated by friction stir processing

Megahed, A. A.; Mohamed, Mostafa A.; Hamid, M. Abdel; Zoalfakar, Said H.

doi:10.1177/09544062221091904

Cited by 4 publications

(1 citation statement)

References 55 publications

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“…Карбид вольфрама выделяется за счет высоких механических свойств, износостойкости, термической стабильности, низкого коэффициента теплового расширения, что позволяет применять его, прежде всего, в абразивных материалах и буровых инструментах [32,33], а совместимость с алюминиевой матрицей позволяет его использовать в соответствующих композитных материалах [34]. Добавление частиц WC в алюминиевую матрицу существенно улучшает износостойкость и трибологические характеристики композита, а также его механические и коррозионные свойства при высокой температуре [35,36]. Это дает основание утверждать возможность применения разрабатываемых материалов, прежде всего, в автомобильной, транспортной и оборонной промышленности при изготовлении тормозных дисков, роторов, пар трения, баллистических компонентов и др.…”

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Formation of composites with an aluminum matrix reinforced with tungsten carbide nanoparticles

Nikitin,

Nassyrbayev,

Tsimmerman

et al. 2024

IZVESTIYA

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Relevance. The fact that composites with a metal matrix and structural products based on them are in great demand in various industries, including the automotive industry, aerospace industry, and shipbuilding. Aluminum matrix composites are the most popular since they combine the excellent ductility, low density, good corrosion resistance of aluminum and the high strength, hardness and wear resistance of a ceramic reinforcing component. Aim. To obtain bulk Al-WC metal matrix composites with different contents of the reinforcing phase and with increased physical and mechanical characteristics using spark plasma sintering. Objects. Sintered bulk products made of pure aluminum and obtained at 400, 450, 500, 550, 600°C and bulk metal matrix composites Al-1%WC, Al-5%WC, Al-10%WC, Al-15%WC obtained at 600°C. Methods. Spark plasma sintering; X-ray diffractometry (XRD phase analysis); scanning electron microscopy; indentation (microhardness measurement). Results. The authors have obtained bulk composite metal matrix products with an aluminum matrix and tungsten carbide as a reinforcing component. Compacting mixtures of nanosized initial powders of aluminum and tungsten carbide using spark plasma sintering made it possible to obtain products with a WC content of 1 to 15 wt %. Taking into account the results of a preliminary series of experiments, when pure aluminum samples were sintered to determine the optimal sintering temperature, bulk composite materials were obtained. A distinctive feature of the obtained samples is their high degree of compaction, which is due to the simultaneous application of a heating current and external pressure, coupled with the relative preservation of the fine-grained structure of the material due to the short process time. The analysis of various sintering modes revealed the need to carry out sintering of composites at 600°C. The research has shown that, although adding a reinforcing phase to a metal matrix significantly reduces the degree of compaction of the material from 97.45% in the absence of an additive to 62.32% with the addition of 15%WC, an increase in the microhardness of products is observed when the concentration of the reinforcing component increases from 3.95 to 5.75 HV. This proves the possibility of reinforcing a metal material using ceramic WC particles. The results can be used in a variety of structural applications, including automotive and aerospace.

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Formation of composites with an aluminum matrix reinforced with tungsten carbide nanoparticles

Nikitin,

Nassyrbayev,

Tsimmerman

et al. 2024

IZVESTIYA

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Metal matrix composite fabricated from electrospun PAN, EGNS/PAN nanofibers and AL 5049 alloy by using friction stir processing

Abdelhady

Elbadawi²,

Zoalfakar

2023

Int J Adv Manuf Technol

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This work is an attempt to fabricate aluminum (AA 5049) matrix composites (AMCs) reinforced with electrospun polyacrylonitrile (PAN) nanofibers and consisting of exfoliated graphite nanosheets (EGNS/PAN) by utilizing friction stir processing (FSP) to improve the mechanical characteristics of AA 5049. The electrospinning method was used for fabricating PAN and EGNS/PAN nanofibers. The average diameter of the electrospun PAN nanofibers is 195 ± 57 nm, and after EGNS incorporation is 180 ± 68 nm. Dynamic recrystallization was the main process in the microstructure evolution of the stir zone during the FSP with PAN and EGNS/PAN nanofibers. According to PAN and EGNS/PAN nanofibers were used in the FSP procedure, the grain size reduced as a result of the pinning effects. PAN and EGNS/PAN nanofiber reinforcement enhanced the hardness to 89 and 98 Hv, respectively. Also, the ultimate tensile strength was raised to 291 MPa and 344 MPa, respectively. Tensile strength and hardness of the stir zone increased during the FSP with PAN and EGNS/PAN nanofibers due to the higher density of the strengthening mechanisms of grain boundaries and dislocations. The mechanical characteristics of AA5049 can be enhanced by the procedure of incorporating nanofibers, making them an ideal choice for applications in the automotive and aerospace industries.

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Investigation on microstructure, mechanical properties and tribological behavior of AlZnMgCu1.5-T6/zirconia surface nanocomposites developed by FSP

Yaghoubi¹,

Mirsalehi²,

Jamali³

2022

Journal of Materials Research and Technology

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Microstructure, hardness, and wear properties of AA6061/WC nanocomposite fabricated by friction stir processing

Cited by 4 publications

References 55 publications

Formation of composites with an aluminum matrix reinforced with tungsten carbide nanoparticles

Formation of composites with an aluminum matrix reinforced with tungsten carbide nanoparticles

Metal matrix composite fabricated from electrospun PAN, EGNS/PAN nanofibers and AL 5049 alloy by using friction stir processing

Investigation on microstructure, mechanical properties and tribological behavior of AlZnMgCu1.5-T6/zirconia surface nanocomposites developed by FSP

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