Crystal plasticity finite element simulation of slip system evolution in pure copper foil rolling

被引：0

作者：

Chen S.-D. ^{[1
]}

Liu X.-H. ^{[1
]}

Liu L.-Z. ^{[2
]}

Sun X.-K. ^{[1
]}

机构：

[1] State Key Laboratory of Rolling and Automation, Northeastern University, Shenyang

[2] School of Materials Science & Engineering, Northeastern University, Shenyang

来源：

Dongbei Daxue Xuebao/Journal of Northeastern University | 2016年 / 37卷 / 05期

关键词：

Crystal plasticity finite element; Foil rolling; Inhomogeneous deformation; Slip system activity;

D O I：

10.3969/j.issn.1005-3026.2016.05.009

中图分类号：

学科分类号：

摘要：

The distributions of the stress, strain and slip systems in pure copper foil rolling with the same reduction were simulated by the rate-dependent crystal plasticity theory and Voronoi polycrystalline model with respect to specimen dimension, grain orientation and its distribution to quantitatively evaluate the influence of thickness on inhomogeneous deformation behavior of foil rolling at mesoscale. The simulated stress-strain curves agree well with the experimental results. The simulation results reveal that the deformation behavior in the polycrystalline aggregate is inhomogeneous not only in intracrystalline but also in intergranule with a 20% reduction in foil rolling. The foils are composed of only a single layer grain across thickness, the grains with different sizes, shapes and orientations are unevenly distributed in the foil, the misorientation of neighboring grains and the property of active slip systems. © 2016, Editorial Department of Journal of Northeastern University. All right reserved.

引用

页码：647 / 652

页数：5

共 12 条

[1] Klusemann B., Svendsen B., Vehoff H., Investigation of the deformation behavior of Fe-3%Si sheet metal with large grains via crystal plasticity and finite-element modeling, Computational Materials Science, 52, 1, pp. 25-32, (2012)
[2] Fan H.D., Li Z.H., Huang M.S., Size effect on the compressive strength of hollow micropillars governed by wall thickness, Scripta Materialia, 67, 3, pp. 225-228, (2012)
[3] Hill R., Rice J.R., Constitutive analysis of elastic-plastic crystals at arbitrary strain, Journal of the Mechanics and Physics of Solids, 20, 6, pp. 401-413, (1972)
[4] Zhang P., Karimpour M., Balint D., Et al., A controlled Poisson Voronoi tessellation for grain and cohesive boundary generation applied to crystal plasticity analysis, Computational Materials Science, 64, pp. 84-89, (2012)
[5] Kim H.K., Oh S.K., An interfacial energy incorporated couple stress crystal plasticity and the finite element simulation of grain subdivision, Journal of the Mechanics and Physics of Solids, 60, 11, pp. 1815-1841, (2012)
[6] Rawat S., Chandra S., Chavan V.M., Et al., Integrated experimental and computational studies of deformation of single crystal copper at high strain rates, Journal of Applied Physics, 116, 21, (2014)
[7] Parasiz S.A., Kinsey B., Krishnan N., Et al., Investigation of deformation size effects during microextrusion, Journal of Manufacturing Science and Engineering, 129, 4, pp. 690-697, (2007)
[8] Kim G.Y., Ni J., Koc M., Modeling of the size effects on the behavior of metals in microscale deformation processes, Journal of Manufacturing Science and Engineering, 129, 3, pp. 470-477, (2007)
[9] Wang Y., Dong P.L., Xu Z.Y., Et al., A constitutive model for thin sheet metal in micro-forming considering first order size effects, Materials & Design, 31, 2, pp. 1010-1014, (2010)
[10] Lu H.N., Wei D.B., Jiang Z.Y., Et al., Modelling of size effects in microforming process with consideration of grained heterogeneity, Computational Materials Science, 77, pp. 44-52, (2013)

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