Transactions of Materials and Heat Treatment

Title：Effect of high-efficiency forging and rolling process on microstructure and properties of C192 special-shaped copper strip

Authors： Han Zhenbin1 Zhao Zhao2 Yu Guojun1 Liu Dong1 Liu Jianbin1 Qi Xiaotian1 Yang Shutian1

Unit： (1.Jinchang Nidu Mining Industry Co. Ltd. Jinchang 737100 China 2.Jinchuan Group Copper Co. Ltd. Jinchang 737100 China)

KeyWords： forging and rolling C192 special-shaped copper strip microstructure mechanical properties grain orientation

ClassificationCode：TG113.26+2

year,vol(issue):pagenumber：2024,49(9):43-49

Abstract：

To investigate the microstructure evolution laws and properties of special-shaped copper strip materials, C192 irregular section copper strip was prepared by the self-developed high-frequency forging and rolling automated production line, and the microstructure evolution during the die forging process for forging and rolling was analyzed by metallographic (OM), electron backscatter diffraction (EBSD) and universal tensile testing methods. The test results show that during the die forging process, the grain size is refined and the preferred grain orientation is <101 >, and the grains in the thin material area show obvious deformation direction. Through the mechanical properties test, it is found that the tensile strength, yield strength and Vickers hardness of thin material are better than those of thick material, while the plasticity of thick material is slightly better than that of thin material. The conductivity was tested, and it is found that the thin material is subjected to solution annealing treatment after die forging, and its grain size gradually recoveres to the initial state of die forging, reducing the difference in conductivity between thick and thin materials. Thus, the die forging process has a significant impact on the microstructure and performance of irregular section copper strip, and optimizing the process parameters can improve the comprehensive performance of irregular section copper strip.

Funds：

基金项目:甘肃省联合科研基金项目（23JRRC0017）；甘肃省企业技术创新项目（GXH20230817-7）

作者简介：韩振斌（1992-），男，硕士，工程师 E-mail：1987196202@qq.com

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