Progresses in Fabrication of High-performance Metals by Using Cryorolling

被引：0

作者：

Yu H. ^{[1
,2
,3
]}

机构：

[1] State Key Laboratory of High Performance Complex Manufacturing, Central South University, Changsha

[2] College of Mechanical and Electrical Engineering, Central South University, Changsha

[3] Light Alloys Research Institute, Central South University, Changsha

来源：

Zhongguo Jixie Gongcheng/China Mechanical Engineering | 2020年 / 31卷 / 01期

关键词：

Cryorolling; High strength and toughness; Mechanical property; Metal and alloy; Ultrafine-grained material;

D O I：

10.3969/j.issn.1004-132X.2020.01.010

中图分类号：

学科分类号：

摘要：

Compared with conventional hot rolling, warm rolling and cold rolling, cryorolling was an innovative technique. During cryorolling, the ultralow temperature suppressed the dislocation movement and dynamic recovery during deformation, thereby enhancing the grain-refinement, and enhancing both strength and ductility of metals and alloys. The progresses in development of high-performance metals and alloys by using cryorolling were introduced, including aluminium, copper, titanium, as well as metal laminated composites. Finally, prospects for the preparation of high-performance metal materials by using cryrolling in the future were also presented. © 2020, China Mechanical Engineering Magazine Office. All right reserved.

引用

页码：89 / 99

页数：10

共 67 条

[1] Valiev R.Z., Langdon T.G., Principles of Equal-channel Angular Pressing as a Processing Tool for Grain Refinement, Progress in Materials Science, 51, 7, pp. 881-981, (2006)
[2] Zhilyaev A.P., Langdon T.G., Using High-pressure Torsion for Metal Processing: Fundamentals and Applications, Progress in Materials Science, 53, 6, pp. 893-979, (2008)
[3] Tsuji N., Saito Y., Lee S.H., Et al., ARB (Accumulative Roll-bonding) and Other New Techniques to Produce Bulk Ultrafine Grained Materials, Advanced Engineering Materials, 5, 5, pp. 338-344, (2003)
[4] Yu H.L., Lu C., Tieu K., Et al., Special Rolling Techniques for Improvement of Mechanical Properties of Ultrafine-grained Metal Sheets: a Review, Advanced Engineering Materials, 18, 5, pp. 754-769, (2016)
[5] Zherebtsov S.V., Dyakonov G.S., Salem A.A., Et al., Formation of Nanostructures in Commercial-purity Titanium via Cryorolling, Acta Materialia, 61, pp. 1167-1178, (2013)
[6] Sagaradze V.V., Shabashov V.A., Kataeva N.V., Et al., Deformation-induced Dissolution of the Intermetallics Ni3Ti and Ni3Al in Austenitic Steels at Cryogenic Temperatures, Philosophical Magazine, 96, pp. 1724-1742, (2016)
[7] Ma Y., Yuan F., Yang M., Et al., Dynamic Shear Deformation of a CrCoNi Medium-entropy Alloy with Heterogeneous Grain Structures, Acta Materialia, 148, pp. 407-418, (2018)
[8] Korznikova G., Mironov S., Konkova T., Et al., EBSD Characterization of Cryogenically Rolled Type 321 Austenitic Stainless Steel, Metallurgical and Materials Transactions A, 49, pp. 6325-6336, (2018)
[9] Fu B., Fu L.M., Liu S.C., Et al., High Strength-ductility Nano-structured High Manganese Steel Produced by Cryogenic Asymmetric-rolling, Journal of Materials Science and Technology, 34, pp. 695-699, (2018)
[10] Yan Y., Luo J., Zhang J., Et al., Study on the Microstructure Evolution and Mechanical Properties Control of a Strong Textured AZ31 Magnesium Alloy Sheet during Cryorolling, Acta Metallurgica Sinica, 53, 1, pp. 107-113, (2017)

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