Development of a unified viscoplasticity constitutive model based on classical plasticity theory

Abstract: The traditional unified viscoplasticity constitutive model can be only applied to metal materials. The study of the unified constitutive theory for metal materials has discovered the correlation between the classical plasticity theory and the unified viscoplasticity constitutive model, thus leading to the concepts of the classic plastic potential and yield surface in the unified constitutive model. Moreover, this research has given the continuous expression of the classical plastic multiplier and presented the… Show more

“…To obtain the properties of these materials under the conditions of service, experimental investigations has been previously carried out and complex deformation behaviors have been exhibited [2][3][4][5][6]. For adequately capturing the material's deformation behavior at elevated temperature, a variety of constitutive models have been proposed utilizing either crystal plasticity-based or phenomenological-based considerations [7][8][9][10][11][12][13], in which the unified Chaboche model has attracted much attention due to its capacity in modeling a wide range of inelastic material behavior such as cyclic hardening/softening, Bauschinger effect, stress relaxation, stress ratcheting and creep for a range of materials [14]. However, although many important conclusions have been reached in the above-mentioned work, limited attention has been previously paid on developing unified models for simultaneously simulating the complex deformation behaviors under tension-compression, cyclic, creep and creep-fatigue loadings.…”

Unified modeling of high temperature deformations of a Ni-based polycrystalline wrought superalloy under tension-compression, cyclic, creep and creep-fatigue loadings

“…To obtain the properties of these materials under the conditions of service, experimental investigations has been previously carried out and complex deformation behaviors have been exhibited [2][3][4][5][6]. For adequately capturing the material's deformation behavior at elevated temperature, a variety of constitutive models have been proposed utilizing either crystal plasticity-based or phenomenological-based considerations [7][8][9][10][11][12][13], in which the unified Chaboche model has attracted much attention due to its capacity in modeling a wide range of inelastic material behavior such as cyclic hardening/softening, Bauschinger effect, stress relaxation, stress ratcheting and creep for a range of materials [14]. However, although many important conclusions have been reached in the above-mentioned work, limited attention has been previously paid on developing unified models for simultaneously simulating the complex deformation behaviors under tension-compression, cyclic, creep and creep-fatigue loadings.…”

Unified modeling of high temperature deformations of a Ni-based polycrystalline wrought superalloy under tension-compression, cyclic, creep and creep-fatigue loadings

An improved viscoplastic constitutive model and its application to creep behavior of turbine blade