7A52铝合金Johnson-Cook本构模型的有限元模拟
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摘要
为探究7A52铝合金的流动应力变化规律,在材料拉伸试验数据基础上,建立Johnson-Cook本构模型。利用有限元软件AQAQUS,模拟7A52铝合金在温度为25~400℃、应变率为0.1~10 000 s~(-1)的准静态和动态拉伸试验。结果表明:温度和应变率都会影响7A52铝合金的流动应力,但对温度的敏感性较大,对应变率敏感性较小;流动应力随着温度的升高而减小;流动应力随着应变率的增加而增大,尤其在应变率高于1 000 s~(-1)时影响更加明显。所建有限元模型结果与试验结果吻合较好,证明该Johnson-Cook本构模型能够在一定温度和应变率范围内预测7A52铝合金的流动应力。
To investigate the flow stress characteristics of 7A52 aluminum alloy,Johnson-Cook constitutive model was established on the basis of data from tensile tests.Quasi-static and dynamic tensile of 7A52 aluminum alloy during the temperature range of 25-400 ℃ and strain rate range of 0.1-10 000 s~(-1) were simulated based on finite element software AQAQUS.The results indicate that the flow stress of 7A52 aluminum alloy is strongly sensitive to temperature compared with strain rate,the flow stress reduces with the increase of temperature and increases with the increase of strain rate,especially for the strain rate higher than 1 000 s~(-1).Good agreement between the finite element model predictions and experimental results is obtained.The Johnson-Cook constitutive model can predict the flow stress of 7A52 aluminum alloy in a certain range of temperatures and strain rate.
To investigate the flow stress characteristics of 7A52 aluminum alloy,Johnson-Cook constitutive model was established on the basis of data from tensile tests.Quasi-static and dynamic tensile of 7A52 aluminum alloy during the temperature range of 25-400 ℃ and strain rate range of 0.1-10 000 s~(-1) were simulated based on finite element software AQAQUS.The results indicate that the flow stress of 7A52 aluminum alloy is strongly sensitive to temperature compared with strain rate,the flow stress reduces with the increase of temperature and increases with the increase of strain rate,especially for the strain rate higher than 1 000 s~(-1).Good agreement between the finite element model predictions and experimental results is obtained.The Johnson-Cook constitutive model can predict the flow stress of 7A52 aluminum alloy in a certain range of temperatures and strain rate.
引文
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[13]方家芳,尹志民,黄继武,等.7A52铝合金热加工过程中高温压缩变形行为[J].轻合金加工技术,2006,34(5):48-52.
[2]ABOTUL S,CHALIVENDRA V B.An experimental and numerical investigation of the static and dynamic constitutive behaviour of aluminium alloys[J].The Journal of Strain Analysis for Engineering Design,2010,45(8):555-565.
[3]李娜,李玉龙,郭伟国.3种铝合金材料动态性能及其温度相关性对比研究[J].航空学报,2008,29(4):903-908.
[4]LINDHOLM U S,BESSEY R L.A survey of rate dependent strength properties of metals,AD854012[R].Ohio:Air Force Material Lab,1969.
[5]LEE W S,SU W C,LI C F.The strain rate and temperature dependence of the dynamic impact properties of 7075 aluminium alloy[J].Journal of Materials Processing Technology,2000,100(1):116-122.
[6]朱耀,庞宝君,邹东利,等.7055铝合金动态压缩下的剪切局部化[J].稀有金属材料与工程,2010,39(Z1):159-161.
[7]滑勇之,关立文,刘辛军,等.铝合金7050-T7451高温高应变率本构方程及修正[J].材料工程,2012(12):7-13.
[8]俞秋景,刘军和,张伟红,等.Inconel 625合金Johnson-Cook本构模型的一种改进[J].稀有金属材料与工程,2013,42(8):1679-1684.
[9]董菲,GUEN?EL Germain,JEAN Lou Lebrun,等.有限元分析法确定Johson-Cook本构方程材料参数[J].上海交通大学学报,2011,45(11):1657-1660+1667.
[10]严宏志,龚黎军.20Cr Mo材料本构模型及其有限元模拟[J].中南大学学报(自然科学版),2012,43(11):4268-4273.
[11]戚运连,曾卫东,赵永庆,等.Ti-Al-Zr-Sn-Mo-Si-Y合金高温塑性变形行为及加工图[J].稀有金属材料与工程,2007,36(11):1891-1895.
[12]李忠盛,潘复生,吴护林,等.新型含Zr超高强Al-Zn-MgCu-Zr合金的高温压缩流变行为[J].稀有金属材料与工程,2010,39(Z1):413-417.
[13]方家芳,尹志民,黄继武,等.7A52铝合金热加工过程中高温压缩变形行为[J].轻合金加工技术,2006,34(5):48-52.
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