Microstructure and mechanical properties of Cu-12 Al-6 Ni with Ti addition prepared by powder metallurgy

Owing to its excellent wear resistance and good mechanical properties, the sintered Cu–Al–Ni alloy is an ideal material for preparing sliding bearings and self-lubricating sleeves. Adding trace elements into the Cu–Al–Ni alloy is expected to further enhance these properties. Hence, in this work, the...

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Published inMaterials science & engineering. A, Structural materials : properties, microstructure and processing Vol. 803; p. 140472
Main Authors Deng, Zhenghua, Yin, Haiqing, Zhang, Cong, Li, Wanquan
Format Journal Article
LanguageEnglish
Published Lausanne Elsevier B.V 28.01.2021
Elsevier BV
Subjects
Alloy powders
Alloys
Aluminum base alloys
Coefficient of friction
Copper
Cu–Al–Ni alloy
Hardness
Mechanical properties
Microstructure
Nickel aluminides
Nickel compounds
Powder metallurgy
Self lubricating bearings
Self lubrication
Sintering (powder metallurgy)
Sleeves
Tensile strength
Titanium
Trace elements
Tribological properties
Wear resistance
Mechanical properties
Cu–Al–Ni alloy
Tribological properties
Powder metallurgy
Ti
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Summary:Owing to its excellent wear resistance and good mechanical properties, the sintered Cu–Al–Ni alloy is an ideal material for preparing sliding bearings and self-lubricating sleeves. Adding trace elements into the Cu–Al–Ni alloy is expected to further enhance these properties. Hence, in this work, the microstructure and properties of sintered Cu-12 Al-6 Ni alloys with varying contents of added Ti are studied. Results indicated that the NiAl, γ2, and α phases were distinctly refined when the Ti addition was 0.2 wt%, and a small amount of the granular X phase ((Cu, Ni)2AlTi) appeared in the alloy. The X phase increased and coarsened with increasing Ti addition. When the Ti addition was 0.7 wt%, pores appeared in the center of the large granular X phase. With increasing Ti addition, the sintered density of the alloys gradually decreased, while the hardness and tensile strength increased first and then decreased. When the Ti addition was 0.7 wt%, the hardness reached the maximum (160 HB), while when the Ti addition was 0.2 wt%, the tensile strength reached the maximum (412.2 MPa). Moreover, the friction coefficient and wear loss of the alloy were the lowest when the Ti addition was 0.2 wt%. These findings can provide some theoretical guidance for fabricating high-performance Cu–Al–Ni powder alloys.
ISSN:0921-5093
1873-4936
DOI:10.1016/j.msea.2020.140472