Quasi-Flow Corner Theory on Large Plastic Deformation of Ductile Metals and its Applications

Hu Ping; Liu Yuqi; Guo Wei; Tai Feng

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Article Navigation > Applied Mathematics and Mechanics > 1996 > 17(11): 1005-1011

Hu Ping, Liu Yuqi, Guo Wei, Tai Feng. Quasi-Flow Corner Theory on Large Plastic Deformation of Ductile Metals and its Applications[J]. Applied Mathematics and Mechanics, 1996, 17(11): 1005-1011.

Citation:

Hu Ping, Liu Yuqi, Guo Wei, Tai Feng. Quasi-Flow Corner Theory on Large Plastic Deformation of Ductile Metals and its Applications[J]. Applied Mathematics and Mechanics, 1996, 17(11): 1005-1011.

Citation:

Hu Ping, Liu Yuqi, Guo Wei, Tai Feng. Quasi-Flow Corner Theory on Large Plastic Deformation of Ductile Metals and its Applications[J]. Applied Mathematics and Mechanics, 1996, 17(11): 1005-1011.

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Quasi-Flow Corner Theory on Large Plastic Deformation of Ductile Metals and its Applications

Jilin University of Technology, Changchun 130025, P. R. China

Received Date: 1995-07-24
Publish Date: 1996-11-15

Abstract

Abstract

A quasi-flow corner theory on lalge plastic deformation if ductile metals is proposed in this paper. From orthogonal rule of plastic flow, the theory introduces a "modulus rethtced function" and a corner effect of yield surface into the constilulive model of elastic-plastic large deformation. Thereby, the smooth and continuous transitions from orthogonal constitutive model to non-orthogonal one, and from plastic loading to elastic unloading are realized. In addition, the theory makes it possible to connect general anisotropic yield functions with corner hardening effect. The comparison between numerical simulation and experimental observation for the uniaxial tensile instability and shear band deformation of anisotropic sheet metals shows the validity of the present quasi-flow corner theory.
- quasi-flow corner theory,
- modulus reduced function,
- shear band,
- Anisotropy

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References(9)

References

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