Your search keyword '"Johnson–Cook laws"' showing total 4 results

1. Accuracy of Variational Formulation to Model the Thermomechanical Problem and to Predict Failure in Metallic Materials.

Author

Ben Said, Lotfi and Wali, Mondher

Subjects

*FRACTURE mechanics, *DUCTILE fractures, *STRAIN rate, *MATERIAL plasticity, *FINITE element method, *MANUFACTURING processes

Abstract

The main purpose of this study is to develop a variational formulation for predicting structure behavior and accounting for damage mechanics in metallic materials. Mechanical and coupled thermomechanical models are used to predict failure in manufacturing processes. Ductile failure is accompanied by a significant amount of plastic deformation in metallic structural components. Finite element simulation of damage evolution in ductile solids is presented in this paper. Uncoupled models are implemented in a finite element model simulating deep drawing as well as cutting processes. Based on the Johnson–Cook model, the effect of deformation on the evolution of flow stress is described. The combined effect of strain, strain rate, and temperature on plasticity and damage behavior in cutting processes is considered. The accuracy of these models is verified when predicting ductile damage in forming and cutting processes. [ABSTRACT FROM AUTHOR]

Published

2022

2. Elastic–plastic deformation and residual stresses in helical springs

Author

Kobelev, Vladimir

Published

2020

3. Accuracy of Variational Formulation to Model the Thermomechanical Problem and to Predict Failure in Metallic Materials

Author

Lotfi Ben Said and Mondher Wali

Subjects

variational approach, coupled thermomechanical models, Johnson–Cook laws, ductile fracture, Mathematics, QA1-939

Abstract

The main purpose of this study is to develop a variational formulation for predicting structure behavior and accounting for damage mechanics in metallic materials. Mechanical and coupled thermomechanical models are used to predict failure in manufacturing processes. Ductile failure is accompanied by a significant amount of plastic deformation in metallic structural components. Finite element simulation of damage evolution in ductile solids is presented in this paper. Uncoupled models are implemented in a finite element model simulating deep drawing as well as cutting processes. Based on the Johnson–Cook model, the effect of deformation on the evolution of flow stress is described. The combined effect of strain, strain rate, and temperature on plasticity and damage behavior in cutting processes is considered. The accuracy of these models is verified when predicting ductile damage in forming and cutting processes.

Published

2022

4. Accuracy of Variational Formulation to Model the Thermomechanical Problem and to Predict Failure in Metallic Materials

Author

Mondher WALI and Lotfi Ben Said

Subjects

General Mathematics, Computer Science (miscellaneous), variational approach, coupled thermomechanical models, Johnson–Cook laws, ductile fracture, Engineering (miscellaneous)

Abstract

The main purpose of this study is to develop a variational formulation for predicting structure behavior and accounting for damage mechanics in metallic materials. Mechanical and coupled thermomechanical models are used to predict failure in manufacturing processes. Ductile failure is accompanied by a significant amount of plastic deformation in metallic structural components. Finite element simulation of damage evolution in ductile solids is presented in this paper. Uncoupled models are implemented in a finite element model simulating deep drawing as well as cutting processes. Based on the Johnson–Cook model, the effect of deformation on the evolution of flow stress is described. The combined effect of strain, strain rate, and temperature on plasticity and damage behavior in cutting processes is considered. The accuracy of these models is verified when predicting ductile damage in forming and cutting processes.

Published

2022