Abstract
To obtain the compatible material of high hardness and high toughness, Hadfield steel matrix composites, reinforced by high-Cr cast iron bars made of flux-cored welding wires, which were inserted into the Hadfield steel melt, were investigated. The mechanical properties of three materials, i e, composites for as-cast and quenching-water condition, as well as Hadfield steel, were compared. The results show that the alloy powder inside flux-cored welding wires can be melted by the heat capacity of Hadfield steel melt and solidify into high-Cr cast iron bars. The impact toughness of the composite for quenching-water condition is higher than that of the composite for as-cast condition and is lower than that of the Hadfield steel, but it can still meet the requirements of hardness and toughness in industrial application. Regardless of load variation, composite for quenching-water condition shows better wear resistance than those of the composite for as-cast condition and Hadfield steel. The modified fracture toughness and wear resistance of composites are attributed to not only the combining actions of Hadfield steel matrix and high-Cr cast iron bars, but also the effect of heat treatment.
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Funded by the Research Center for lnnovation Engineering in Science and Technology, Shaan Xi Province, China (No.2007ZDGC-17)
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Niu, L., Xu, Y. & Wu, H. Microstructure and mechanical properties of high-Cr cast iron bars reinforced Hadfield steel matrix composites. J. Wuhan Univ. Technol.-Mat. Sci. Edit. 25, 464–468 (2010). https://doi.org/10.1007/s11595-010-0024-0
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DOI: https://doi.org/10.1007/s11595-010-0024-0