Journal
MATERIALS SCIENCE AND ENGINEERING A-STRUCTURAL MATERIALS PROPERTIES MICROSTRUCTURE AND PROCESSING
Volume 835, Issue -, Pages -Publisher
ELSEVIER SCIENCE SA
DOI: 10.1016/j.msea.2022.142672
Keywords
Cu-Ti alloys; Heterogeneous structure; Thermo-mechanical treatment; Semi in-situ EBSD; Hetero-deformation induced hardening
Categories
Funding
- Science and Technology Research Project of Jiangxi Education Department [GJJ190477]
- Special Program for Key Innovative of Science and Technology from Ningbo science and technology bureau [2018B10053]
- Program of Qingjiang Excellent Young Talents (JXUST)
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By using thermo-mechanical treatment, a heterogeneous structure was obtained in Cu-3.2Ti0.2Fe-0.2V alloy, which synergistically improved the strength and ductility of the copper alloy. Aging at different temperatures resulted in higher tensile strength and elongation in the heterogeneous-structured alloy compared to the coarse-grained alloy, with even better strengthening effect after cold rolling.
To synergistically improve the strength-ductility of copper alloys used in the miniaturized component, Cu-3.2Ti0.2Fe-0.2V alloy with heterogeneous structure was obtained by thermo-mechanical treatment (namely, short time annealing). The heterogeneous structure was composed of the non-uniform grains formed due to Laves phase inhibiting grain growth and FCC structured Cu4Ti phase with good coherent interface precipitated on the grain boundaries in sub-micro size. After aging at 400 degrees C for 2 h and then 450 degrees C for 4 h, the ultimate tensile strength and elongation of the heterogeneous-structured alloy were 976.8 MPa and 18.8% respectively, which was approximately 120 MPa more than that of the coarse-grained alloy after complete annealing, but both alloys had comparable ductility. When cold-rolling with 5% reduction was carried out before the aging of 450 degrees C, the strength increased to 1057 MPa and corresponding elongation was still over 10%. The strengthening mechanism of alloy with heterogeneous structure was analyzed and the hetero-deformation induced hardening of 284.5 MPa was the other significant reinforcement. The semi in-situ observation of tensile deformation behavior shown that the superior ductility in coarse-grained alloy was mainly attributed to the slipping and twinning. While grain rotation and grain boundary sliding were additional deformation mechanism in heterogeneous-structured alloy during tensile deformation, meanwhile, the texture of S, {110}<1 <(1)over bar> 1> and {331}<1<(2)over bar> 3> components converted to the texture of {441}<<(11)over bar> 8>, Goss, Copper and {012}<8<(2)over bar>1> components. The deteriorative ductility after rolling with the reduction of 5% was owing to the S and Cube components converted to the strong texture of {032}<22<(3)over bar>> components.
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