Hot deformation in dispersion strengthened aluminum alloys and composites

被引:0
作者
Bieler, TR
机构
来源
CIM BULLETIN | 1997年 / 90卷 / 1007期
关键词
metallurgy; aluminum alloys; powder metallurgy; metal matrix composites; hot working; superplasticity; post-forming properties;
D O I
暂无
中图分类号
TF [冶金工业];
学科分类号
0806 ;
摘要
Hot forming and superplasticity in powder metallurgy aluminum alloys and composites is reviewed. The effects of alloy composition, particulate composition, size, and size distribution is summarized. The role of climb distance for recovery is described in connection with the size of strengthening phases. In materials with fine strengthening phases on the order of one micron or less, high strain rate superplastic deformation processes are likely. However, the quality of superplastic deformation depends on the prior processing history, and these effects are reviewed. Very few data describing the effects of hot forming history on post-forming properties exist, but some results emerging in the literature are compared.
引用
收藏
页码:55 / 63
页数:9
相关论文
共 50 条
[41]   Hot plane strain compression testing of aluminum alloys [J].
Shi, H ;
McLaren, AJ ;
Sellars, CM ;
Shahani, R ;
Bolingbroke, R .
JOURNAL OF TESTING AND EVALUATION, 1997, 25 (01) :61-73
[42]   HOT TEARING OF ALUMINUM ALLOYS A CRITICAL LITERATURE REVIEW [J].
Li, S. ;
Apelian, D. .
INTERNATIONAL JOURNAL OF METALCASTING, 2011, 5 (01) :23-40
[43]   Deformation behavior of aluminum alloys and driving for their high performances [J].
Kanetake N. .
Keikinzoku/Journal of Japan Institute of Light Metals, 2017, 67 (08) :369-376
[44]   Texture, grain boundaries and deformation of superplastic aluminum alloys [J].
Pérez-Prado, MT ;
McNelley, TR ;
González-Doncel, G ;
Ruano, OA .
SUPERPLASTICITY IN ADVANCED MATERIALS, ICSAM-2000, 2001, 357-3 :255-260
[45]   FORMING THE STRUCTURE AND PROPERTIES OF SINTERED COPPER MATRIX COMPOSITES DISPERSION-STRENGTHENED [J].
Juszczyk, Barbara ;
Ciura, Ludwik ;
Malec, Witold ;
Czepelak, Marian ;
Cwolek, Beata ;
Marchewka, Lukasz .
COMPOSITES THEORY AND PRACTICE, 2008, 8 (02) :141-146
[46]   Temperature–strain rate deformation conditions of aluminum alloys [J].
D. A. Kitaeva ;
Sh. T. Pazylov ;
Ya. I. Rudaev .
Journal of Applied Mechanics and Technical Physics, 2016, 57 :352-358
[47]   Hybrid particles dispersion strengthened aluminum metal matrix composite processed by stir casting [J].
Negi, Ankit Singh ;
Shanmugasundaram, T. .
MATERIALS TODAY-PROCEEDINGS, 2021, 39 :1210-1214
[48]   Electrochemical Dispersion of Aluminum Alloys in an Aqueous Sodium Hydroxide Solution [J].
Badaev F.Z. ;
Khairi A.K. ;
Reznichenko A.V. ;
Novoselov R.A. ;
Rybal’chenko V.V. ;
Kozlyakov V.V. ;
Khovanskii V.N. .
Chemical and Petroleum Engineering, 2017, 52 (11-12) :834-837
[49]   Comparison of Hot Deformation Behavior Characteristics Between As-Cast and Extruded Al-Zn-Mg-Cu (7075) Aluminum Alloys with a Similar Grain Size [J].
Jeong, H. T. ;
Kim, W. J. .
MATERIALS, 2019, 12 (23)
[50]   Intragranular Dispersion of Carbon Nanotubes Comprehensively Improves Aluminum Alloys [J].
So, Kang Pyo ;
Kushima, Akihiro ;
Park, Jong Gil ;
Liu, Xiaohui ;
Keum, Dong Hoon ;
Jeong, Hye Yun ;
Yao, Fei ;
Joo, Soo Hyun ;
Kim, Hyoung Seop ;
Kim, Hwanuk ;
Li, Ju ;
Lee, Young Hee .
ADVANCED SCIENCE, 2018, 5 (07)