Hostname: page-component-cd9895bd7-p9bg8 Total loading time: 0 Render date: 2024-12-27T09:28:41.741Z Has data issue: false hasContentIssue false

A Constitutive Model Research Based on Dislocation Mechanism of 5083 Aluminum Alloy

Published online by Cambridge University Press:  27 November 2017

N. Gao
Affiliation:
State Key Laboratory of Traction Power Southwest Jiaotong University Chengdu, China
Z. Zhu*
Affiliation:
State Key Laboratory of Traction Power Southwest Jiaotong University Chengdu, China
S. Xiao
Affiliation:
State Key Laboratory of Traction Power Southwest Jiaotong University Chengdu, China
Q. Xie
Affiliation:
State Key Laboratory of Traction Power Southwest Jiaotong University Chengdu, China
*
*Corresponding author ([email protected])
Get access

Abstract

The study of the mechanical properties of polycrystalline alloy materials under dynamic impact, namely, the prediction of mechanical behavior after yield stress and the establishment of a constitutive model, has attracted much attention in the field of engineering. The stress-strain curves of 5083 aluminum alloy were obtained under strain rates varying from 0.0002 s-1 to 7130 s-1 through uniaxial compression experiments. The equipment used included a CRIMS RPL100 tester, Instron tester, and split Hopkinson test system. In addition, based on dislocation dynamics and the strengthening mechanism of metals, the plastic flow of the 5083 aluminum alloy was systematically analyzed under a wide range of strain rates. It was found that the abnormal yield behavior of the 5083 aluminum alloy under a wide range of strain rates increased, and the experimental phenomenon of hardening rate decreased with an increase in strain rate. This study also revealed that the abnormal yield behavior is caused by the different dislocation mechanisms of two-phase alloy elements under different strain rates. Based on the thermal activation theory and the experimental data, a constitutive model was developed. A comparison showed good agreement between the experimental and model curves. This indicates that this model has good plastic flow stress prediction ability for such types of materials.

Type
Research Article
Copyright
© The Society of Theoretical and Applied Mechanics 2017 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

Popović, M. and Romhanji, E., “Stress Corrosion Cracking Susceptibility of Al-Mg Alloy Sheet with High Mg Content,” Journal of Materials Processing Technology, 125, pp. 275280 (2002).Google Scholar
Yang, L., “The Effect of Zn on the Properties of 5083 Aluminum Alloy Corrosion and the Second Phase Simulation Study on Al-Mg-(Zn) Alloy,” M. D. Thesis, School of Materials Science and Engineering, Central South University, Changsha, China (2012).Google Scholar
Pope, D. P. and Ezz, S. S., “Mechanical Properties of Ni3Al and Nickel-Base Alloys with High Volume Fraction of Gamma',” International Metals Reviews, 29, pp. 136167 (1984).Google Scholar
Hammond, C. M., Flinn, R. A. and Thomassen, L., “Phase Equilibria and Elevated-Temperature Properties of Some Alloys in the System Ni3Cr-Ni3Al,” Transactions of the Metallurgical Society of AIME, 221, pp. 400405 (1961).Google Scholar
Lin, Y., Zhu, F. W., Liang, C. and Xiao, J., “The FIM-AP Research on Ni3Fe Ordering and Antiphase Boundary,” Science in China (Series A), 10, pp. 10841091 (1994).Google Scholar
Kear, B. H. and Wilsdorf, H. G., “Dislocation Configurations in Plastically Deformed Polycrystalline Cu3Au Alloys,” Transactions of the Metallurgical Society of AIME, 224, pp. 382 (1962).Google Scholar
Jockweg, J. and Nembach, E., “Anisotropy of the Critical Resolved Shear-Stress of a Superalloy Containing 6 Vol-Percent Ll(2)-Ordered Gamma'-Precipitates,” Acta Metallurgica Sinica, 43, pp. 32953300 (1995).Google Scholar
Heredia, F. E. and Pope, D. P., “The Tension/ Compression Flow Asymmetry in a High Gamma' Volume Fraction Nickel Base Alloy,” Acta Metallurgica Sinica, 34, pp. 279285 (1986).Google Scholar
Liu, X., Huang, X., Chen, Y., Su, X. and Zhu, J., “A Review on Constitutive Models for Plastic Deformation of Metal Materials under Dynamic Loading,” Advances in Mechanics, 37, pp. 362363 (2007).Google Scholar
Li, Y., “Definition and Mechanical Characteristics of True Stress-Strain,” Journal of Chongqing University, 24, pp. 5860 (2001).Google Scholar
Orowan, E., “Discussion in Symposium on Internal Stresses in Metals and Alloys,” Institute of Metals, 22, pp. 451 (1948).Google Scholar
Johnston, W. G. and Gilman, J. J., “Dislocation Velocities, Dislocation Densities and Plastic Flow in Lithium Floride Crystals,” Journal of Applied Physics, 30, pp. 129144 (1959).Google Scholar
Zerilli, F. J. and Armstrong, R. W., “Dislocation-Mechanics-Based Constitutive Relations for Material Dynamics Calculations,” Journal of Applied Physics, 61, pp. 18161825 (1987).Google Scholar
Kocks, U. E., Argon, A. S. and Ashby, M. F., “Thermodynamics and Kinetics of Slip,” Materials Science, 19, pp. 127 (1975).Google Scholar
Nemat-Nasser, S. and Li, Y., “Flow Stress of FCC Polycrystals with Application to OFHC Copper,” Acta Materialia, 46, pp. 565577 (1998).Google Scholar
Li, Y., “Investigation on Alloying and Application Characteristics of Magnesium-Aluminum Intermetallics,” School of Materials Science and Engineering, Taiyuan University of Technology, China (2015).Google Scholar
Sha, Y., Zhang, J., Jin, T., Xu, Y. and Hu, Z., “Dependence of Compression Yield Behavior on Temperature, Orientation and Strain Rate in a Ni-Base Superalloy Single Crystal,” Acta Metallurgica Sinica, 35, pp. 495498 (1999).Google Scholar
Li, W. and Kong, X., “Electron Theory of Anomalous Yield Behavior in TiAl,” Nonferrous Metals, 51, pp. 6367 (1999).Google Scholar
Chen, G., Huang, Y., Zhang, L., Sun, Z. and Yang, W., “Strain-Induced Micro structural Changes and Effects of Alloying Elements for Fe3Al-Based Alloys,” Journal of University of Science and Technology Beijing, 24, pp. 10841091 (1994).Google Scholar
Copley, S. M., Kear, B. H. and ROWE, G. M., “The Temperature and Orientation Dependence of Yielding in Mar-M200 Single Crystals Materials,” Science and Engineering, 10, pp. 8792 (1972).Google Scholar
Basinski, Z. S., “Thermally Activated Glide in Face-Centred Cubic Metals and Its Application to the Theory of Strain Hardening,” Philosophical Magazine, 4, pp. 393432 (1959).Google Scholar
Conrad, H., “On the Mechanism of Yielding and Flow in Iron,” Journal of Iron and Steel Research International, 198, pp. 364 (1961).Google Scholar
Basinski, S. J., Basinski, Z. S. and Howie, A., “Early Stages of Fatigue in Copper Single Crystals,” Philosophical Magazine, 19, pp. 899924 (1969).Google Scholar
Campbell, J. D. and Ferguson, W. G., “The Temperature and Strain-Rate Dependence of the Shear Strength of Mild Steel,” Philosophical Magazine, 81, pp. 6382 (1970).Google Scholar
Dolinski, M., Rittel, D. and Dorogoy, A., “Modeling Adiabatic Shear Failure from Energy Considerations,” Journal of the Mechanics and Physics of Solids, 58, pp. 17591775 (2010).Google Scholar
Rodríguez-Martínez, J. A., Rodríguez-Millán, M., Rusinek, A. and Arias, A., “A Dislocation-Based Constitutive Description for Modeling the Behavior of FCC Metals within Wide Ranges of Strain Rate and Temperature,” Mechanics of Materials, 43, pp. 901912 (2011).Google Scholar
Tang, C., Zhu, J. and Zhou, H., “Correlation between Yield Stress and Strain Rate for Metallic Materials and Thermal Activation Approach,” Acta Metallurgica Sinica, 31, pp. A248A253 (1995).Google Scholar
Wang, Z. and Duan, Z., “Plastic Mesoscopic Mechanics,” Science Press, Beijing (1995).Google Scholar
Guo, W., “Plastic Flow Behavior and Constitutive Relation of BCC Metals,” M. D. Thesis, School of Aeronautics, Northwestern Polytechnical University, Xi’an, China (2007).Google Scholar