Mechanical properties of particle stabilized aluminum foam

被引:70
作者
Kenny, LD
机构
来源
ALUMINIUM ALLOYS: THEIR PHYSICAL AND MECHANICAL PROPERTIES, PTS 1-3 | 1996年 / 217卷
关键词
aluminum foam; cellular material; energy absorption; mechanical properties;
D O I
10.4028/www.scientific.net/MSF.217-222.1883
中图分类号
T [工业技术];
学科分类号
08 ;
摘要
A cellular product, aluminum foam, can be manufactured by introduction of air or other gas into molten aluminum composites. Cell structure-cell size and cell wall thickness-is controlled by the process variables during manufacture. Both physical and mechanical properties are dependent on the cell structure with cell size being the dominant variable. In this paper, mechanical properties of aluminum foam in compression, tension and shear modes are described. The effect of material variables-composite alloy and volume fraction of particles-and strain rate regime are examined under compressive loading. The mode of deformation and failure is described and together with mechanical property data is briefly compared to the Ashby-Gibson theoretical models((1)).
引用
收藏
页码:1883 / 1889
页数:7
相关论文
共 50 条
[31]   Evolution of mechanical properties of a residue from the secondary aluminum remelting industry stabilized with gypsum [J].
Tayibi, H ;
Pérez, C ;
López, FA ;
López-Delgado, A .
REVISTA DE METALURGIA, 2005, 41 (04) :280-285
[32]   Compressive deformation and energy absorption characteristics of closed cell aluminum-fly ash particle composite foam [J].
Mondal, D. P. ;
Goel, M. D. ;
Das, S. .
MATERIALS SCIENCE AND ENGINEERING A-STRUCTURAL MATERIALS PROPERTIES MICROSTRUCTURE AND PROCESSING, 2009, 507 (1-2) :102-109
[33]   Preparation and properties of controllable aluminum foam [J].
Sun, Leilei ;
Wang, Yanli ;
Wang, Lucai ;
Wang, Fang ;
Xu, Hong ;
Huang, Wenzhan ;
You, Xiaohong .
MATERIALS RESEARCH EXPRESS, 2021, 8 (02)
[34]   Influence of mechanical alloying on the mechanical and tribological properties of SiC particle reinforced aluminum matrix composites [J].
Deng, Xiaoyan ;
Zhang, Guoheng ;
Qiang, Chengwen ;
Xu, Jincheng .
OPTOELECTRONICS AND ADVANCED MATERIALS-RAPID COMMUNICATIONS, 2015, 9 (11-12) :1535-1543
[35]   The Influence of Titanium Hydride Pretreatment on the Compressive Properties of Aluminum Foam [J].
Zhang, Zan ;
Xia, Xingchuan ;
Zhao, Weimin ;
Chen, Xiaowei ;
Chen, Xu .
MATERIALS SCIENCE-MEDZIAGOTYRA, 2014, 20 (04) :424-428
[36]   Fabrication of aluminum foam stabilized by copper-coated carbon fibers [J].
Cao, Zhuo-Kun ;
Li, Bing ;
Yao, Guang-Chun ;
Wang, Yong .
MATERIALS SCIENCE AND ENGINEERING A-STRUCTURAL MATERIALS PROPERTIES MICROSTRUCTURE AND PROCESSING, 2008, 486 (1-2) :350-356
[37]   Mechanical Properties of Advanced Pore Morphology Foam Elements [J].
Vesenjak, Matej ;
Gacnik, Franci ;
Krstulovic-Opara, Lovre ;
Ren, Zoran .
MECHANICS OF ADVANCED MATERIALS AND STRUCTURES, 2015, 22 (05) :359-366
[38]   Sample size effect on the mechanical behavior of aluminum foam [J].
Zhang, Yue ;
Jin, Tao ;
Li, Shiqiang ;
Ruan, Dong ;
Wang, Zhihua ;
Lu, Guoxing .
INTERNATIONAL JOURNAL OF MECHANICAL SCIENCES, 2019, 151 :622-638
[39]   Filling of surface pores of aluminum foam with polyamide by selective laser melting for improvement in mechanical properties [J].
Matsumoto, Ryo ;
Kanatani, Shigehiro ;
Utsunomiya, Hiroshi .
JOURNAL OF MATERIALS PROCESSING TECHNOLOGY, 2016, 237 :402-408
[40]   The effect of cell-size dispersity on the mechanical properties of closed-cell aluminum foam [J].
Su, Bo-Yuan ;
Huang, Chun-Min ;
Sheng, Hao ;
Jang, Wen-Yea .
MATERIALS CHARACTERIZATION, 2018, 135 :203-213
12345