泡沫金属具有优良的物理性能和综合力学性能,在很多场合都可用作轻质结构材料.在简要介绍该类材料用途的基础上,指出了多向载荷研究对于泡沫金属应用的实际意义,分析了以往工作在该类材料力学性能研究方面的不足,以期推进相关领域的研究者在该方面的突破.在此基础上,提出了一条研究该类材料在多向载荷作用下有关数理关系的思路.
参考文献
| [1] | Banhart J .Manufacture,characterisation and application of cellular metals and metal foams[J].Progress in Materials Science,2001,46:559. |
| [2] | Gibson L J;Ashby M F.Cellular solids:Structure and properties-Second edition[M].Cambridge:Cambridge University Press,1997 |
| [3] | Liu PS.;Liang KM. .Functional materials of porous metals made by P/M, electroplating and some other techniques [Review][J].Journal of Materials Science,2001(21):5059-5072. |
| [4] | 刘培生.多孔材料引论[M].北京:清华大学出版社,2004 |
| [5] | 刘培生;马晓明.多孔材料检测方法[M].北京:冶金工业出版社,2006 |
| [6] | LIU Pei-sheng,SANG Hai-bo.Mechanical Property of Foamed Metal[J].钢铁研究学报(英文版),2004(03):53-58. |
| [7] | Seeliger H W.Metal foams and porous metal structures[A].Bremen:MIT Press-Ver-lag,1999:29. |
| [8] | Hanusa H G .Reticular Structures and methods of producing same[P].US,3549505,1970-12-22. |
| [9] | Andrews E W;Gibson L J;Ashby M F .The creep of cellu-lar solids[J].Acta Materials,1999,47(10):2853. |
| [10] | 肖华星,陈光,崔鹏.定向凝固多孔金属制造人工骨的前景展望[J].特种铸造及有色合金,2001(02):88-89. |
| [11] | 张景怀,惠志林,方政秋.泡沫镍的制备工艺与性能[J].稀有金属,2001(03):230-234. |
| [12] | 刘培生,梁开明,顾守仁,于青,付超,李铁藩,李美栓.多孔金属电极基体材料[J].稀有金属,2000(06):440-444,422. |
| [13] | Sugimura Y;Meyer J;He M Y .On the mechanical per-formance of closed cellar alloy foams[J].Acta Materials,1997,45(12):5245. |
| [14] | 朱震刚.金属泡沫材料研究[J].物理,1999(02):84. |
| [15] | Guest S D .On the determinacy of repetitive structures[J].J Mechanics Phys Solids,2003,51:383. |
| [16] | Mohr D .Mechanism-based multi-surface plasticity model for ideal truss lattice materials[J].International Journal of Solids and Structures,2005(11/12):3235-3260. |
| [17] | 刘培生.多孔金属格子材料(点阵材料)的制造方法[J].稀有金属材料与工程,2007(z3):535-538. |
| [18] | 何宜柱;张吉人;雷廷权 .透气性莫来石基陶瓷-金属复合材料[J].功能材料,1997,28(02):196. |
| [19] | 黄培云.粉末冶金原理[M].北京:冶金工业出版社,1997 |
| [20] | 刘培生.泡沫金属双向拉伸破坏时名义应力与孔率的关系[J].中国科学E辑,2003(09):774-777. |
| [21] | 丁华东;浩宏奇;李雅文 等.复压对铜石墨含油材料强度的影响[J].兵器材料科学与工程,1997,20(05):17. |
| [22] | Liu P S.Chapter 3 porous materials:The mathematical-physical expressions for some properties of three-dimensio-nal reticulated porous metallic materials in the same analyti-cal model system[J].Mater Sci Res Horizon,2007 |
| [23] | 刘培生.泡沫金属的经典性模型--Gibson-Ashby模型浅析[J].有色金属,2005(02):55-57. |
| [24] | 刘培生.关于多孔材料的新模型[J].材料研究学报,2006(01):64-68. |
| [25] | Zhu HX.;Mills NJ.;Knott JF. .ANALYSIS OF THE ELASTIC PROPERTIES OF OPEN-CELL FOAMS WITH TETRAKAIDECAHEDRAL CELLS[J].Journal of the Mechanics and Physics of Solids,1997(3):319 ff.-0. |
| [26] | Chen C.;Lu TJ. .A phenomenological framework of constitutive modelling for incompressible and compressible elasto-plastic solids[J].International Journal of Solids and Structures,2000(52):7769-7786. |
| [27] | Gioux G.;Gibson LJ.;McCormack TM. .Failure of aluminum foams under multiaxial loads[J].International Journal of Mechanical Sciences,2000(6):1097-1117. |
| [28] | Kim H S;Al-Hassani S T s .Effective elastic constants of two-dimensional cellular materials with deep and thick cell walls[J].International Journal of Mechanical Sciences,2002,44(08):1559. |
| [29] | W. M. Huang .A simple approach to estimate failure surface of polymer and aluminum foams under multiaxial loads[J].International Journal of Mechanical Sciences,2003(9):1531-1540. |
| [30] | Doyoyo M.;Wierzbicki T. .Experimental studies on the yield behavior of ductile and brittle aluminum foams[J].International Journal of Plasticity,2003(8):1195-1214. |
| [31] | Kesler O.;Crews LK.;Gibson LJ. .Creep of sandwich beams with metallic foam cores[J].Materials Science & Engineering, A. Structural Materials: Properties, Misrostructure and Processing,2003(1/2):264-272. |
| [32] | Wicklein M;Thoma K .Numerical investigations of the elastic and plastic behaviour of an open-cell aluminium foam[J].Materials Science & Engineering, A. Structural Materials: Properties, Misrostructure and Processing,2005(1/2):391-399. |
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