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5083H111轧制铝合金的低周疲劳行为 被引量:4

Low-Cycle Fatigue Behavior of 5083H111 Rolled Aluminum Alloy
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摘要 在室温下对5083H111轧制铝合金板三个典型方向——轧制方向(RD方向)、与轧制方向成45°角方向(MD方向)、垂直于轧制方向(TD方向)的试样进行了单轴对称应变控制的低调疲劳试验,研究了不同方向试样的循环变形行为和疲劳寿命差异。结果表明:铝合金板在三个方向上都表现出了明显的循环硬化特性,即在恒定的应变幅下,三个方向的响应应力幅均随着循环次数的增加而增大,并且外加应变幅越大,响应应力幅也越大;三个方向的低周疲劳ε-Nf曲线差别不明显;三参数幂函数寿命模型可以很好地预测5083H111铝合金的低周疲劳寿命。 Uniaxial symmetrical strain-controlled fatigue tests were conducted at room temperature for rolled aluminum alloy plates along three typical directions,the rolling direction(RD),the direction at 45°angle with the rolling direction(MD),and the transverse direction(TD),to study the differences of cyclic deformation and fatigue lives of the 5083H111 alloy plates.The results show that the rolled alloy plates were characterized by obvious cyclic hardening in three directions-that was to say the responded stress amplitude increased progressively with the increase of the cycles number.The larger the applied strain amplitudes,the larger the responded stress amplitudes.However,the differences among theε-Nfcurves in three directions were not obvious.The fatigue lives of the alloy plates were predicted by a three-parameter power function failure model,and the predicted lives were in good agreement with the experimental ones.
作者 彭金波 康国政 刘宇杰 卢福聪 陈辉
机构地区 西南交通大学力学与工程学院 西南交通大学材料科学与工程学院
出处 《机械工程材料》 CAS CSCD 北大核心 2015年第1期39-41,45,共4页 Materials For Mechanical Engineering
基金 四川省青年科技创新团队支持项目(2013TD0004)
关键词 5083铝合金 低周疲劳行为 三参数幂函数寿命模型 疲劳寿命 5083Al alloy low-cycle fatigue behavior three-parameter power function failure model failure life
分类号 TG111.91 [金属学及工艺—物理冶金]
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  • 1钟群鹏,赵子华,张峥.断口学的发展及微观断裂机理研究[J].机械强度,2005,27(3):358-370. 被引量:192
  • 2张君尧.美国铝业公司6013铝合金简介[J].轻合金加工技术,1995,23(3):24-26. 被引量:21
  • 3王涛,尹志民.高强变形铝合金的研究现状和发展趋势[J].稀有金属,2006,30(2):197-202. 被引量:103
  • 4DUBEY S, SOBOYEJO A B O, SOBOYEJO W O. An investigation of the effects of stress ratio and crack clouse on micromechanisms of fatigue crack growth in Ti-6Al-4V[J].Acta mater, 1997,45 (7) : 2777-2787.
  • 5MORGENEYER T F, STARINK M J, SINCLAIR I. Experimental analysis of toughness in 6156 Al-Alloy sheet for aerospace applications [J]. Materials Science Forum, 2006, 519/ 521:934-942.
  • 6EDWARDS G A, STILLER K, DUNLOP G L, et al. The precipitation sequence in AI-Mg Si alloys[J]. Acta Mater, 1998,46(11) :3893-3904.
  • 7BRAY G H, GLAZOV M, RIOJA R J. Effect of artificial aging on the fatigue crack propagation resistance of 2000 series aluminum alloys[J].International Journal of Fatigue, 2001,23 : 265-276.
  • 8CHEN D L, CHATURVEDI M C, GOEL N. Fatigue crack growth behavior of X2095 A1-Li alloy[J].International Journal of Fatigue, 1999,21 : 1079-1086.
  • 9ZABETT A, PLUMTREE A. Microstructural effects of the small fatigue crack behavior of an aluminum alloy plate[J]. Fatigue & Fracture of Engineering Materials & Stuctures, 1995,18:801-809.
  • 10VENKATESWARA Rao K T, YU W, RITCHIE R O. Fa- tigue crack propagation in aluminum-lithium alloy 2090: partl-Long crack behavior[J]. Metallurgical Transaction A, 1988,19(3):549 -561.

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