Constitutive Modeling of Annealed OFHC with Wide Strain-Rate and Temperature Effects: Incorporating Dislocation Dynamics and Normalized Microstructural Size Evolution

Author:

Xu Mengwen1,Xiao Qiangqiang1,Zu Xudong1ORCID,Tan Yaping2ORCID,Huang Zhengxiang1ORCID

Affiliation:

1. School of Mechanical Engineering, Nanjing University of Science and Technology, Nanjing 210094, China

2. School of Information Technology, Jiangsu Open University, Nanjing 210094, China

Abstract

The flow stress of face-centered cubic (FCC) metals exhibits a rapid increase near a strain rate of 104 s−1 under fixed-strain conditions. However, many existing constitutive models either fail to capture the mechanical characteristics of this plastic deformation or use piecewise strain-rate hardening models to describe this phenomenon. Unfortunately, these piecewise models may suffer from issues such as discontinuity of physical quantities and difficulties in determining segment markers, and struggle to reflect the underlying physical mechanisms that give rise to this mutation phenomenon. In light of this, this paper proposes that the abrupt change in flow stress sensitivity to strain rate in FCC metals can be attributed to microstructural evolution characteristics. To address this, a continuous semiempirical physical constitutive model for FCC metals is established based on the microstructural size evolution proposed by Molinari and Ravichandran and the dislocation motion slip mechanism. This model effectively describes the mutation behavior of strain-rate sensitivity under fixed strain, particularly evident in an annealed OFHC. The predicted results of the model across a wide range of strain rates (10−4–106 s−1) and temperatures (77–1096 K) demonstrate relative errors generally within ±10% of the experimental values. Furthermore, the model is compared with five other models, including the mechanical threshold stress (MTS), Nemat-Nasser–Li (NNL), Preston–Tonks–Wallace (PTW), Johnson–Cook (JC), and Molinari–Ravichandran (MR) models. A comprehensive illustration of errors reveals that the proposed model outperforms the other five models in describing the plastic deformation behavior of OFHC. The error results offer valuable insights for selecting appropriate models for engineering applications and provide significant contributions to the field.

Funder

China Scholarship Council, China

National Natural Science Foundation of China

Publisher

MDPI AG

Subject

General Materials Science

Reference53 articles.

1. A Review on the Strain Rate Dependency of the Dynamic Viscoplastic Response of FCC Metals;Salvado;Prog. Mater. Sci.,2017

2. High Strain Rate Properties of Metals and Alloys;Armstrong;Int. Mater. Rev.,2008

3. Constitutive Modelling of Plasticity of Fcc Metals under Extremely High Strain Rates;Gao;Int. J. Plast.,2012

4. Jia, X., Hao, K., Luo, Z., and Fan, Z. (2022). Plastic Deformation Behavior of Metal Materials: A Review of Constitutive Models. Metals, 12.

5. Johnson, G.R., and Cook, W.H. (1983, January 19–21). A Constitutive Model and Data for Materials Subjected to Large Strains. Proceedings of the 7th International Symposium on Ballistics, The Hague, The Netherlands.

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