Fabrication and properties of Fe matrix composites reinforced by macro-particles

QIU Bo; XING Shu-ming; DONG Qi

doi:10.13374/j.issn2095-9389.2018.08.011

Volume 40 Issue 8

Aug. 2018

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QIU Bo, XING Shu-ming, DONG Qi. Fabrication and properties of Fe matrix composites reinforced by macro-particles[J]. Chinese Journal of Engineering, 2018, 40(8): 969-978. doi: 10.13374/j.issn2095-9389.2018.08.011

Citation:

QIU Bo, XING Shu-ming, DONG Qi. Fabrication and properties of Fe matrix composites reinforced by macro-particles[J]. Chinese Journal of Engineering, 2018, 40(8): 969-978. doi: 10.13374/j.issn2095-9389.2018.08.011

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Fabrication and properties of Fe matrix composites reinforced by macro-particles

doi: 10.13374/j.issn2095-9389.2018.08.011

School of Mechanical, Electronic and Control Engineering, Beijing Jiaotong University, Beijing 100044, China

Received Date: 2017-09-23

Abstract

Abstract

The basic challenges in the preparation and application of particle-reinforced metal matrix composites are the difficulty in achieving a uniform and stable mixing and the weak bonds between the particles and matrix. At present, these challenges are mainly tackled by making the particles into precursor beforehand and adopting the wetting treatment technologies, respectively. However, these measures can result in lower production efficiency and higher preparation costs. Based on the molten metal die forging process, an innovation technology termed "mixing by the molten metal and cohering by high pressures" was proposed to prepare the metal matrix composites reinforced with ceramic particles without a precursor or wetting them beforehand. Using this technique, a kind of ZTA particles-reinforced KmTBCr26 cast iron wear resistant composite with a good compound effect had been prepared, and the microstructure, hardness, and impact property of the ZTA/KmTBCr26 composite was studied. The study reveals that the particle distribution in the ZTA/KmTBCr26 composite is generally uniform, and the interfacial bonding between ceramic particle and KmTBCr26 matrix is of micromechanical interlocking. The results of impact tests show that the impact toughness of the composites is significantly lower than that of the single metal, and the fracture morphology indicates that the fracture of the composites extends through the ceramic particle instead of the matrix. No particle detachment is observed, which indicates a high bonding strength between the particles and matrix. Furthermore, the dry friction and wear properties of the ZTA/KmTBCr26 composite and KmTBCr26 cast iron were investigated. The results show that the wear resistance of the composite is 1.82 times that of the KmTBCr26 cast iron when the load is lower, while the wear resistance of the composite increased by 3.3 times under the higher load.
- composite,
- wear white cast iron,
- molten metal die forge,
- impact toughness,
- wear resistance

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References(13)

References

[1]	Wiengmoon A, Chairuangsri T, Brown A, et al. Microstructural and crystallographical study of carbides in 30wt.%Cr cast irons. Acta Mater, 2005, 53(15):4143
[2]	Miracle D B. Metal matrix composites——from science to technological significance. Compos Sci Technol, 2005, 65(15-16):2526
[3]	Akhtar F. Microstructure evolution and wear properties of in situ synthesized TiB₂ and TiC reinforced steel matrix composites. J Alloys Compd, 2008, 459(1-2):491
[6]	Francois H. Composite Wear Component: USA Patent, 6399176B1. 2002-06-04
[8]	Kish O, Froumin N, Aizenshtein M, et al. Interfacial interaction and wetting in the Ta₂O₅/Cu-Al system. J Mater Eng Perform, 2014, 23(5):1551
[10]	Liu A G, Guo M H, Zhao M H, et al. Microstructure and wear resistance of large WC particles reinforced surface metal matrix composites produced by plasma melt injection. Surf Coat Technol, 2007, 201(18):7978
[12]	Edelbauer J, Schuller D, Lott O, et al. High temperature squeeze casting of nickel based metal matrix composites with interpenetrating microstructure. Mater Sci Forum, 2015, 825-826:93
[15]	Malomo B O, Fadodun O O, Oluwasegun K M, et al. The effect of controlled melt-solidification on the strain rate sensitivity of a squeeze-cast hybrid-reinforced aluminum AA 6061 matrix composite. Int J Eng Res Afr, 2015, 16:1
[16]	Gurusamy P, Balasivanandha P S. Effect of the squeeze pressure on the mechanical properties of the squeeze cast Al/SiCp metal matrix composite. Int J Microstruct Mater Prop, 2013, 8(4-5):299
[17]	Llorca J, Martin A, Ruiz J, et al. Particulate fracture during deformation of a spray formed metal-matrix composite. Metall Trans A, 1993, 24(7):1575
[18]	Turnbull A, De Los Rios E R. The effect of grain size on fatigue crack growth in an aluminum magnesium alloy. Fatigue Fract Eng Mater Struct, 1995, 18(11):1355
[20]	Kamat S V, Hirth J P, Mehrabian R. Mechanical properties of particulate-reinforced aluminum-matrix composites. Acta Mater, 1989, 37(9):2395
[22]	Ashby M F, Abulawi J, Kong H S. Temperature maps for frictional heating in dry sliding. Tribol Trans, 1991, 34(4):577