采用拉伸测试、维氏硬度测试和透射电镜分析等方法研究实验应力和时效时间对2524铝合金蠕变时效行为的影响.结果表明:时效时间和试验应力对材料的成形与微观组织均有较大的影响,应力越大、时间越长,蠕变行为越明显;在190℃温度下,试验应力为180 MPa,时效时间约为12 h时,材料的硬度和强度趋近于峰值;TEM 分析表明,合金板材强度和伸长率的差别主要由时效后强化相 S′相和 S″相的尺寸和分布密度决定;采用线性回归方法获得合金在190℃下稳态蠕变速率与实验应力的本构关系.
@@@@The creep age forming effects of 2524 aluminum alloy at different stresses and aging times were investigated through tensile performance, Vickers hardness and TEM. The results show that the aging time and stress have great effect on not only creep behavior but also microstructure of 2524 aluminum alloy. And the creep behavior will become stronger with heavier stress and longer time. The hardness and strength of material will tend to be peak at 190 ℃ when the test-stress reaches 180 MPa and ageing time is 12 h. It can be concluded that the differences of strength and elongation of the alloy plate are determined by the size and distribution of S″and S′phase. Finally, the constitutive relationship between the steady creep rate and stress of 2524 aluminum alloy at 190℃is obtained by linear regression.
参考文献
| [1] | SALLAH M;PEDDIESON J;FOROUDASTAN S .A mathematical model of autoclave age forming[J].Journal of Materials Processing Technology,1991,28(09):211-219. |
| [2] | MITCH ELL C H .Au to clave age forming large aluminum aircraft panels[J].JOURNAL OF MECHANICAL WORKING TECHNOLOGY,1989,20:477-488. |
| [3] | 曾元松,黄遐.大型整体壁板成形技术[J].航空学报,2008(03):721-727. |
| [4] | 李劲风,郑子樵,李世晨,任文达,陈文敬.铝合金时效成形及时效成形铝合金[J].材料导报,2006(05):101-103,119. |
| [5] | Manabu Nakai;Takehiko Eto .New aspects of development of high strength aluminum alloys for aerospace applications[J].Materials Science & Engineering, A. Structural Materials: Properties, Misrostructure and Processing,2000(1/2):62-68. |
| [6] | STARKE E A;STALEY J T Jr .Application of modern aluminum alloys to aircraft[J].PROGRESS IN AEROSPACE SCIENCES,1996,32(2/3):131-172. |
| [7] | T. Warner .Recently-Developed Aluminum Solutions for Aerospace Applications[J].Materials Science Forum,2006(Pt.2):1271-1278. |
| [8] | 刘兵,彭超群,王日初,王小锋,李婷婷.大飞机用铝合金的研究现状及展望[J].中国有色金属学报,2010(09):1705-1715. |
| [9] | GB/T 2039-1997.金属拉伸蠕变及持久试验方法[S]. |
| [10] | 张俊善.材料的高温变形与断裂[M].北京:科学出版社,2007:3-4. |
| [11] | 邓运来,周亮,晋坤,张新明.2124铝合金蠕变时效的微结构与性能[J].中国有色金属学报,2010(11):2106-2111. |
| [12] | 杨松涛,李继文,魏世忠,徐流杰,张国赏,张二召.纯钼板坯高温塑性变形行为及本构方程[J].中国有色金属学报,2011(09):2126-2131. |
| [13] | 李炎光,湛利华,谭斯格.工艺参数对2124合金蠕变时效成形的影响[J].特种铸造及有色合金,2011(06):580-582. |
| [14] | 周亮,邓运来,晋坤,张新明.预处理对2124铝合金板材蠕变时效微结构与力学性能的影响[J].材料工程,2010(02):81-85,96. |
| [15] | 刘禹门.Al-Cu-Mg合金中位错与S相的相互作用[J].兵器材料科学与工程,2005(05):1-4. |
| [16] | 杨胜,易丹青,杨守杰,钟利.温度对2E12铝合金疲劳性能与断裂机制的影响[J].航空材料学报,2007(06):1-5. |
| [17] | 马建丽.无机材料科学基础[M].重庆:重庆大学出版社,2008:165-173. |
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