METALS AND METAL MATRIX COMPOSITES |
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Effect of Aging Processes on the Anisotropic Mechanical Property of 6061 Aluminum Alloy and the Related Microstructure Evolution |
LIU Wei1,2, WU Yuanzhi1,2, DENG Bin1,2, LIU Anmin1,2, LIU Wei2, SUN Qian2, YE Tuo1,2
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1 Research Institute of Automobile Parts Technology, Hunan Institute of Technology, Hengyang 421002, China 2 School of Mechanical and Engineering, Hunan Institute of Technology, Hengyang 421002, China |
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Abstract The effect of aging on the anisotropic mechanical properties of a commercial 6061 rolling sheet has been investigated by 0°, 45° and 90° uniaxial tensile tests. The mechanical properties of the studied alloy are strongly related to the applied heat treatment state and loading direction, exhibiting visible anisotropy. The T6 treated alloy exhibits the lowest anisotropy as compared with the other treated alloys. In addition,the studied alloys has a strong cube {001} 〈100〉 and a much weaker {001} 〈100〉 components. The artificial aging utilized in present work has little influence on the grain microstructure and texture evolution. The dislocation distributions of T6 and HTA 240 ℃ alloys are denser and more homogeneous as compared with those in other treated alloys, and the visibly higher density of β″ precipitates in T6 alloy is the main reason for the highest strength and the lowest anisotropy.
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Published: 23 February 2021
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Fund:This work was financially supported by the National Natural Science Foundation of China (51501061), the National Students' Platform for Innovation and Entrepreneurship Training Program (S202011528013) and the Natural Science Foundations of Hunan Province (2019JJ30009, 2019JJ50110), the Scientific Research Projects of Hunan Education Department (20B116), Hengyang Science and Technology Project Program (2020jh012668, 2019yj011174). |
Corresponding Authors:
hnuyetuo@163.com
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About author:: Wei Liu, lecturer, Hunan Institute of Technology. He received his master's degree in materials science and engineering from Xiangtan University in June 2013. Since joining Hunan Institute of Technology in October 2015, he has been mainly engaged in the research of deformation behavior of light metals such as aluminum and magnesium at high and low temperatures, the evolution of microstructure and the analysis of the mechanism. He has published 7 scientific research papers, including 4 in SCI and 1 in EI, such as Int. J. Solids Struct., Comput. Mater. Sci., Journal of Mater. Sci. Eng. A and other academic journals. He has applied for se-ven patents, four of which were authorized. Tuo Ye, lecturer, Hunan Institute of Technology. He graduated from Hunan University in October 2016 with a doctorate in mechanical engineering. He joined Hunan Institute of Technology in January 2017, he has been engaged in the research of high temperature deformation mechanism, plastic forming and microstructure characterization of metal materials. More than 10 papers have been published in Materials Science and Engineering A, International Journal of Impact Engineering, Vacuum, Metals, China Journal of Nonferrous Metals, Chinese Journal of Materials Research, China Mechanical Engineering and other well-known academic journals, including 4 in SCI and 6 in EI. |
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