Simulations of deformation and damage processes of SiCp/Al composites during tension
来源期刊:JOURNAL OF MATERIALS SCIENCE TECHNOLOG2018年第4期
论文作者:J.F.Zhang X.X.Zhang Q.Z.Wang B.L.Xiao Z.Y.Ma
文章页码:627 - 634
摘 要:The deformation, damage and failure behaviors of 17 vol.% SiCp/2009Al composite were studied by microscopic finite element(FE) models based on a representative volume element(RVE) and a unit cell. The RVE having a 3D realistic microstructure was constructed via computational modeling technique, in which an interface phase with an average thickness of 50 nm was generated for assessing the effects of interfacial properties. Modeling results showed that the RVE based FE model was more accurate than the unit cell based one. Based on the RVE, the predicted stress-strain curve and the fracture morphology agreed well with the experimental results. Furthermore, lower interface strength resulted in lower flow stress and ductile damage of interface phase, thereby leading to decreased elongation. It was revealed that the stress concentration factor of SiC was 2.0: the average stress in SiC particles reached 1200 MPa, while that of the composite reached 600 MPa.
J.F.Zhang1,2,X.X.Zhang1,Q.Z.Wang1,B.L.Xiao1,Z.Y.Ma1
1. Shenyang National Laboratory for Materials Science, Institute of Metal Research, Chinese Academy of Sciences2. University of Chinese Academy of Sciences
摘 要:The deformation, damage and failure behaviors of 17 vol.% SiCp/2009Al composite were studied by microscopic finite element(FE) models based on a representative volume element(RVE) and a unit cell. The RVE having a 3D realistic microstructure was constructed via computational modeling technique, in which an interface phase with an average thickness of 50 nm was generated for assessing the effects of interfacial properties. Modeling results showed that the RVE based FE model was more accurate than the unit cell based one. Based on the RVE, the predicted stress-strain curve and the fracture morphology agreed well with the experimental results. Furthermore, lower interface strength resulted in lower flow stress and ductile damage of interface phase, thereby leading to decreased elongation. It was revealed that the stress concentration factor of SiC was 2.0: the average stress in SiC particles reached 1200 MPa, while that of the composite reached 600 MPa.
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