Manufacture of Nano-Sized Particle-Reinforced Metal Matrix Composites: A Review

doi:10.1007/s40195-014-0154-z

摘要/Abstract

Abstract:

Compared to the micro-sized particle-reinforced metal matrix composites, the nano-sized particle-reinforced metal matrix composites possess superior strength, ductility, and wear resistance, and they also exhibit good elevated temperature properties. Therefore, the nano-sized particle-reinforced metal matrix composites are the new potential material which could be applied in many industry fields. At present, the nano-sized particle-reinforced metal matrix composites could be manufactured by many methods. Different kinds of metals, predominantly Al, Mg, and Cu, have been employed for the production of composites reinforced by nano-sized ceramic particles such as carbides, nitrides, and oxides. The main drawbacks of these synthesis methods are the agglomeration of the nano-sized particles and the poor interface between the particles and the metal matrix. This work is aimed at reviewing the ex situ and in situ manufacturing techniques. Moreover, the distinction between the two methods is discussed in some detail. It was agreed that the in situ manufacturing technique is a promising method to fabricate the nano-sized particle-reinforced metal matrix composites.

Key words: Fabrication, Metal matrix composites, Nanocomposite

. [J]. 金属学报英文版, 2014, 27(5): 798-805.

Zhou Dongshuai, Qiu Feng, Wang Huiyuan, Jiang Qichuan. Manufacture of Nano-Sized Particle-Reinforced Metal Matrix Composites: A Review[J]. Acta Metallurgica Sinica (English Letters), 2014, 27(5): 798-805.

图/表 10

Fig. 1 Possible distribution of the matrix and nano-sized reinforcement particles in the composite, where the reinforcements are distributed along the grain boundaries of the matrix phase a and the reinforcements are inside the matrix grains b (the open hexagons represent the matrix grains and the open and filled circles represent the reinforcements) [19]

Fig. 2 Schematic of typical powder metallurgy processing scheme [25]

Fig. 3 The variation of the B4C particle size as a function of milling time [29]

Fig. 4 Schematic of ultrasonic solidification processing [32]

Fig. 5 Schematic of the cavitation and steaming effects for nanoparitcle dispersion and wetting in the metal melts: a formation and growth of bubbles; b collapsing of bubbles; c break-up and re-dispersion of nanoparticle clusters [34]

Fig. 6 SEM images showing SiC clusters in AZ91D alloys which were produced by traditional mechanical stirring a and ultrasonic stirring method b [34]

Fig. 7 Morphologies of the TiC particles formed in the Me-Ti-CNT systems: a Me = 50 wt% Cu; b, c Me = 60 wt% Cu; d, e Me = 70 wt% Cu; f Me = 80 wt% Cu; g Me = 50 wt% Al; h, i Me = 60 wt% Al; j Me = 70 wt% Al; k Me = 80 wt% Al; l, m Me = 50 wt% Fe; n Me = 60 wt% Fe; o, p Me = 70 wt% Fe; q, r Me = 80 wt% Fe [56] (The scale bars in the inset images represent 100 nm)

Fig. 8 Schematic diagram of in situ direct reaction synthesis apparatus [58]

Fig. 9 Evolution of Mg-Ti-C mixtures during milling [61]

Fig. 10 Schematic of gas-liquid reaction process [67]

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