Predication of Hot Flow Behavior of Micro-Alloy Steel Using Modified Johnson-Cook Model

Document Type : Original Articles

Authors

1 Department of Mechanical Engineering, Aligudarz Branch, Islamic Azad University, Aligudarz, Iran.

2 School of Mechanical Engineering, Arak University of Technology, Arak, Iran.

Abstract

Constitutive models can be used as a powerful tool to predict the complex behavior of materials under different deformation conditions. These equations can model and control the flow behavior of materials with appropriate accuracy by considering the parameters affecting the behavior of the material. In this study, a modified Johnson-Cook model has been developed to predict the hot working behavior of L80 micro alloy steel at various deformation parameters such as temperature, strain rate, and strain. In order to develop this model, experimental data related to hot compression tests at a temperature range of 1173-1373 K and strain rates of 0.001-1 s-1 have been used. The results of the microstructure correctly describe the flow behavior of the material. The results show that the developed model, taking into account the softening effects of temperature as well as strain and strain rate hardening, provides a good prediction of the hot working behavior of micro-alloy steel and this developed model can be used to simulate the production processes of this steel at high temperatures.

Keywords

References

  1. Faria, G.L., Paula, J.M.A. and Lima, M.S.F., "Characterization of phase transformations and microstructural changes in an API 5CT L80 steel grade during Ni alloy laser cladding", Materials Research, Vol. 21, NO. 5, pp. 1-9, (2018).
  2. Kennedy, J.R., Wiskel, J.B., Ivey, D.G. and  Henein, H., "L80 pipe steel microstructure assessment using ultrasonic testing",  Materials Science and Technology, Vol. 35, NO. 16, pp. 1942–1949, (2019).
  3. Rezaei Ashtiani, H.R., Parsa, M.H. and Bisadi, H., "Constitutive equations for elevated temperature flow behavior of commercial purity aluminum", Materials Science and Engineering A, Vol. 545, pp. 61-67, (2012).
  4. Lin, Y.C. and Chen, X.M., "A review of experimental results and constitutive description for metals in hot working", Materials and Design, Vol. 32, NO. 4, pp.1733-1759, (2011).
  5. Mandal, S., Rakesh, V., Sivaprasad, P.V., Venugopal, S. and Kasiviswanathan, K.V., "Constitutive equations to predict high temperature flow stress in a Ti-modified austenitic stainless steel", Materials Science and Engineering A, Vol. 500, NO. 1, pp. 114-121, (2009).
  6. Rezaei Ashtiani, H.R. and Shahsavari, P., "Strain-dependent constitutive equations to predict high temperature flow behavior of AA2030 aluminum alloy", Mechanics of Materials, Vol. 100, pp. 209-218, (2016).
  7. Lin, Y.C., Li, Q.F, Xia. Y.C. and Li, L.T., "A phenomenological constitutive model for high temperature flow stress prediction of Al-Cu-Mg alloy", Materials Science and Engineering A, Vol. 534, pp. 654–62, (2012).
  8. Mohanraj, M. and Dong, W.D., "Johnson Cook material and failure model parameter estimation of AISI-1045 medium carbon steel for metal forming application", Materials, Vol. 12, No. 4, pp. 1-18, (2019).
  9. Rezaei Ashtiani, H.R. and Shahsavari, P., "A comparative study on the phenomenological and artificial neural network models to predict hot deformation behavior of AlCuMgPb alloy", Journal of Alloys and Compounds, Vol. 687, pp. 263–273, (2016).
  10. Wang, Y.P., Han, C.J., Wang, C. and Li, S.K., "A modified Johnson-Cook model for 30Cr2Ni4MoV rotor steel over a wide range of temperature and strain rate", Journal of Materials Science, Vol. 46, pp. 2922–2927, (2011).
  11. Xu, L., Chen, L., Chen, G. and Wang, M., "Hot deformation behavior and microstructure analysis of 25Cr3Mo3NiNb steel during hot compression tests", Vacuum, Vol. 147, pp. 8–17, (2018).
  12. He, A., Xie, G., Zhang, H. and Wang, X., "A comparative study on Johnson-Cook, modified Johnson-Cook and Arrhenius-type constitutive models to predict the high temperature flow stress in 20CrMo alloy steel", Materials and Design, Vol. 52, pp. 677–685, (2013).
  13. He, J., Chen, F., Wang, B. and Zhu, L.B., "A modified Johnson-Cook model for 10%Cr steel at elevated temperatures and a wide range of strain rates", Materials Science and Engineering A, Vol. 715, pp. 1–9, (2018).
  14. Bobbili, R. and Madhu, V., "Constitutive modeling of hot deformation behavior of high-strength armor steel", Journal of Materials Engineering and Performance, Vol. 25, pp.1829–1838, (2013).
  15. Li, H.Y., Wang, X.F., Duan, J.Y. and Liu, J.J., "A modified Johnson Cook model for elevated temperature flow behavior of T24 steel", Materials Science and Engineering A, Vol. 577, pp. 138–146, (2013).
  16. Ahmadi, H., Rezaei Ashtiani, H.R. and Heidari, M., "A comparative study of phenomenological, physically-based, and artificial neural network models to predict the Hot flow behavior of API 5CT-L80 steel", Materials Today Communications, Vol. 25, pp. 101528, (2020).
  17. Verlinden, B., Driver, J., Samajdar, I. and Doherty, D., "Thermo-mechanical processing of metallic materials”, Elsevier Science publication, Amsterdam, pp. 57-105, (2007).
  18. Lin, Y.C., Wu, X.Y., Chen, X.M., Chen, J., Wen, D.X., Zhang, J.L. and Li, L.T., "EBSD study of a hot deformed nickel-based superalloy", Journal of Alloys and Compounds, Vol. 640, pp. 101–113, (2015).
  19. Saadatkia, S., Mirzadeh, H. and Cabrera, J.M., "Hot deformation behavior, dynamic recrystallization, and physically-based constitutive modeling of plain carbon steels", Materials Science and Engineering A, Vol. 636, pp.196–202, (2015).
  20. Zhao, L., Park, N., Tian, Y., Shibata. A. and Tsuji, N., "Combination of dynamic transformation and dynamic recrystallization for realizing ultrafine-grained steels with superior mechanical properties", Scientific Reports, Vol. 6, pp. 1-11, (2016).
  21. Lin, Y.C., Chen, X.M. and Liu, G., "A modified Johnson-Cook model for tensile behaviors of typical high-strength alloy steel", Materials Science and Engineering A, Vol. 527, pp. 6980–6986, (2010).

 

 

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Journal Of Metallurgical and Materials Engineering
Volume 32, Issue 2 - Serial Number 24
ُSpring & Summer
June 2021
Pages 125-136

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