Effects of microrolling parameters on the microstructure and deformation behavior of pure copper

被引：0

作者：

Yi Jing ^{[1
]}

Hongmei Zhang ^{[1
,2
]}

Hao Wu ^{[1
]}

Lianjie Li ^{[1
]}

Hongbin Jia ^{[3
]}

Zhengyi Jiang ^{[1
,2
]}

机构：

[1] School of Material and Metallurgy,University of Science and Technology Liaoning

[2] School of Mechanical,Materials and Mechatronic Engineering,University of Wollongong

[3] An-steel Group,Da-Xing Plant

来源：

InternationalJournalofMineralsMetallurgyandMaterials | 2018年 / 25卷 / 01期

关键词：

micro-rolling; grain size effect; reduction; deformation behavior; microstructure; pure copper;

D O I：

暂无

中图分类号：

TG146.11 [];

学科分类号：

080502 ;

摘要：

Microrolling experiments and uniaxial tensile tests of pure copper under different annealing conditions were carried out in this paper. The effects of grain size and reduction on non-uniform deformation, edge cracking, and microstructure were studied. The experimental results showed that the side deformation became more non-uniform, resulting in substantial edge bulge, and the uneven spread increased with increasing grain size and reduction level. When the reduction level reached 80% and the grain size was 65 μm, slight edge cracks occurred. When the grain size was 200 μm, the edge cracks became wider and deeper. No edge cracks occurred when the grain size was 200 μm and the reduction level was less than 60%; edge cracks occurred when the reduction level was increased to 80%. As the reduction level increased, the grains were gradually elongated and appeared as a sheet-like structure along the rolling direction; a fine lamellar structure was obtained when the grain size was 20 μm and the reduction level was less than 60%.

引用

页码：45 / 52

页数：8

共 17 条

[1]

Effect of continuous induction annealing on the microstructure and mechanical properties of copper-clad aluminum flat bars[J]. Xin-hua Liu,Yan-bin Jiang,Hong-jie Zhang,Jian-xin Xie.International Journal of Minerals Metallurgy and Materials. 2016(12)

[2]

Microstructure and texture evolution in commercial-purity Zr 702 during cold rolling and annealing[J]. Min Ma,Ming-he Li,Yuan-biao Tan,Hui Yuan,Wen-chang Liu.International Journal of Minerals Metallurgy and Materials. 2014(08)

[3]

Hybrid Micro-forming Processes and Quality Evaluation of Micro-double Gear[J]. 徐杰.Journal of Wuhan University of Technology（Materials Science Edition）. 2009(S1)

[4]

Microstructural Evolution and Micro‐Compression in High‐Purity Copper Processed by High‐Pressure Torsion＜link href="#adem201500488-note-0001"/＞[J] . Jianwei Li,Jie Xu,Chuan Ting Wang,Debin Shan,Bin Guo,Terence G. Langdon.Adv. Eng. Mater. . 2016 (2)

[5]

Analysis of micro flexible rolling with consideration of material heterogeneity[J] . Feijun Qu,Zhengyi Jiang,Haina Lu.International Journal of Mechanical Sciences . 2016

[6]

Ductile fracture and deformation behavior in progressive microforming[J] . B. Meng,M.W. Fu,C.M. Fu,K.S. Chen.Materials ＆ Design . 2015

[7]

Size effect on deformation behavior and ductile fracture in microforming of pure copper sheets considering free surface roughening[J] . B. Meng,M.W. Fu.Materials ＆ Design . 2015

[8]

Grain and geometry size effects on plastic deformation in roll-to-plate micro/meso-imprinting process[J] . Zhaoyang Gao,Linfa Peng,Peiyun Yi,Xinmin Lai.Journal of Materials Processing Tech. . 2015

[9]

Surface Morphology of Micro Stepped Components in Micro Cross Wedge Rolling[J] . Dongbin Wei,Haina Lu,Zhengyi Jiang,Ken-ichi Manabe.Procedia Engineering . 2014

[10]

Modelling of size effects in microforming process with consideration of grained heterogeneity[J] . H.N. Lu,D.B. Wei,Z.Y. Jiang,X.H. Liu,K. Manabe.Computational Materials Science . 2013

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