Quantitative characterization of the wear interactions between the boride and metallic matrix in Fe-3.0 wt % B duplex alloy

The purpose of this research was to clarify wear-related interactions between the M2B phase and the metallic matrix in an Fe-3.0 wt % B duplex alloy, and to characterize those effects on two-body abrasive wear by establishing a mathematical model. Furthermore, the effects of 1.0–2.5 wt % Cr addition...

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Bibliographic Details
Published in:Wear 2019-10, Vol.436-437, p.203021, Article 203021
Main Authors: Jian, Yongxin, Xing, Jiandong, Huang, Zhifu, Wu, Tonghai
Format: Article
Language:English
Subjects:
Abrasive wear
Chromium
Chromium additions
Fe-3.0 wt % B duplex alloy
Ferrous alloys
Fracture toughness
Iron
Mathematical analysis
Matrix methods
Sandpaper
Silicon dioxide
Wear interaction
Wear resistance
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Summary:The purpose of this research was to clarify wear-related interactions between the M2B phase and the metallic matrix in an Fe-3.0 wt % B duplex alloy, and to characterize those effects on two-body abrasive wear by establishing a mathematical model. Furthermore, the effects of 1.0–2.5 wt % Cr additions on the two-body abrasive wear of the alloy against silica sand paper are discussed in detail. Results of this investigation show that matrix/second phase microstructural interactions significantly decrease the wear of Fe-3.0 wt % B alloy. By comparison, M2B plays a predominant role in improving the alloy's wear interaction, while the metallic matrix is detrimental to it. The trend resulting from chromium additions is analogous to the effects of the fracture toughness of M2B, and chromium additions also contribute to wear resistance. Improving the fracture toughness of M2B not only decreases the wear directly but it also enhances the matrix/second phase wear interactions, which in turn improve the wear resistance of Fe-3.0 wt % B duplex alloy. •For the first time, the metallic matrix/Fe2B interaction during abrasive wear is quantitatively characterized.•Wear interaction benefits to decreasing the wear weight loss of Fe-3.0 wt% B duplex alloy.•Improving the fracture toughness of Fe2B can enhance the wear interaction.
ISSN:0043-1648
1873-2577
DOI:10.1016/j.wear.2019.203021