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Constitutive modeling for high temperature compressive deformation of non-oriented electrical steel

  • Qiang Dong und Jianshui Zhang
Veröffentlicht/Copyright: 21. Februar 2019
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Materials Testing
Aus der Zeitschrift Materials Testing Band 61 Heft 3

Abstract

A material mechanical model provides basic data for numerical simulation and technological optimization during the forming process. In this paper, the flow behavior of the hot compressive deformation 0.3 wt.-% Si non-orientation electrical steel were investigated by thermal simulation tests, and a constitutive model was built based on a new modeling method. The thermal simulation tests conducted on a Gleeble 1500 thermo-mechanical simulator over a range of temperatures from 750 to 1050 °C and strain rates from 0.1 to 10 s−1. To predict the hot deformation process of the silicon steel, a constitutive model based on the multiple regression method was developed. Prediction results showed that the proposed model can track deformational behavior accurately. The model was applied to finite element (FE) simulation, and the FE calculation results matched the industry production data satisfactorily.

*Correspondence Address, Dr. Qiang Dong, School of Mechanical Engineering, Shandong Jiaotong University, Jinan 250357, P. R. China, E-mail:

Dr. Qiang Dong, born in 1986, studied Mechanical Engineering at University of Science and Technology Beijing, China. After receiving his doctoral degree in 2016, he was hired as a Research Fellow and Lecturer at the School of Mechanical Engineering, Shandong Jiaotong University, Jinan, China. His active research interests include steel rolling technology, modeling and simulation of metal forming process, material fatigue and fracture.

Dipl.-Ing. Jianshui Zhang, born in 1986, studied Mechanical Engineering at Taiyuan University of Science and Technology, Shanxi, China. After receiving his Master of engineering in 2013, he joined the China New Metallurgy Hi-Tech Group Corporation, Beijing, as a manager. He has been working in the field of steel forming technology and the mechanical behavior analysis of steel rolling mill.

References

1 T.Ros-Yañez, Y.Houbaert, O.Fischer, J.Schneider: Production of high silicon steel for electrical applications by thermomechanical processing, Journal of Materials Processing Technology143–144 (2003), pp. 91692110.1016/j.jmatprotec.2003.10.002Suche in Google Scholar

2 F. J. G.Landgraf, M.Emura, K.Ito, P. S. G.Carvalho: Effect of plastic deformation on the magnetic properties of non-oriented electrical steels, Journal of Magnetism and Magnetic Materials215–216 (2000), pp. 949610.1016/S0304-8853(00)00075-5Suche in Google Scholar

3 F.Schausberger, A.Steinboeck, A.Kugi: Mathematical modeling of the contour evolution of heavy plates in hot rolling, Applied Mathematical Modelling39(2015), No. 15, pp. 4534454710.1016/j.apm.2015.01.017Suche in Google Scholar

4 E. S.Puchi-Cabrera, J.Guérin, M.Dubar, M. H.Staia, J.Lesage, D.Chicot: Constitutive description for the design of hot-working operations of a 20MnCr5 steel grade, Materials & Design62 (2014), pp. 25526410.1016/j.matdes.2014.05.011Suche in Google Scholar

5 F. H.Abed, S. I.Ranganathan, M. A.Serry: Constitutive modeling of nitrogen-alloyed austenitic stainless steel at low and high strain rates and temperatures, Mechanics of Materials77 (2014), pp. 14215710.1016/j.mechmat.2014.07.007Suche in Google Scholar

6 J.Zhou, B.Wang, M.Huang: Two constitutive descriptions of boron steel 22MnB5 at high temperature, Materials & Design63(2014), pp. 73874810.1016/j.matdes.2014.07.008Suche in Google Scholar

7 Q.Dong, J.Cao, H.Li, Y.Zhou, T.Yan, W.Wang: Analysis of spalling in roughing mill backup rolls of wide and thin strip hot rolling process, steel research international86 (2015), No. 2, pp. 12913610.1002/srin.201300476Suche in Google Scholar

8 G. R.Johnson, W. H.Cook: A constitutive model and data for metals subjected to large strains, high strain rates and high temperatures, Proc. of the Seventh International Symposium on Ballistics, Hague, Netherlands (1983), pp. 541547Suche in Google Scholar

9 F. J.Zerilli, R. W.Armstrong: Dislocation-mechanics-based constitutive relations for material dynamics calculations, Journal of Applied Physics61 (1987), No. 5, pp. 1816182510.1063/1.338024Suche in Google Scholar

10 C.Zener, J. H.Hollomon: Effect of strain rate upon plastic flow of steel, Journal of Applied Physics15 (1944), No. 1, pp. 223210.1063/1.1707363Suche in Google Scholar

11 C.Sellars, W.McTegart: On the mechanism of hot deformation, Acta Metallurgica14 (1966), pp. 1136113810.1016/0001-6160(66)90207-0Suche in Google Scholar

12 J.Sheikh-Ahmad, J.Twomey: ANN constitutive model for high strain-rate deformation of Al 7075-T6, Journal of Materials Processing Technology186(2007), No. 1–3, pp. 33934510.1016/j.jmatprotec.2006.11.228Suche in Google Scholar

13 X.Xiao, G. Q.Liu, B. F.Hu, X.Zheng, L. N.Wang, S. J.Chen, A.Ullah: A comparative study on Arrhenius-type constitutive equations and artificial neural network model to predict high-temperature deformation behaviour in 12Cr3WV steel, Computational Materials Science62 (2012), pp. 22723410.1016/j.commatsci.2012.05.053Suche in Google Scholar

14 P.Rodriguez-Calvillo, A.Boulaajaj, M.Perez-Sine, J.Schneider, J. M.Cabrera: On the hot working of FeSi ferritic steels, Materials Science and Engineering A606 (2014), pp. 12713810.1016/j.msea.2014.03.073Suche in Google Scholar

15 K. S.Han, T. J.Song, B. C.De Cooman: Hot Deformation Behavior of Fe-2 %Si, ISIJ International53 (2013), No. 2, pp. 294303, 10.2355/isijinternational.53.294Suche in Google Scholar

16 J.Cao, T.Wang, H.Li: High-temperature constitutive relationship of a non-oriented electrical steel based on modified Arrhenius model, Journal of Mechanical Engineering52 (2016), No. 4, pp. 908610.3901/JME.2016.04.090Suche in Google Scholar

17 D.Trimble, G. E. ODonnell: Constitutive Modelling for elevated temperature flow behaviour of AA7075, Materials & Design76 (2015), pp. 15016810.1016/j.matdes.2015.03.062Suche in Google Scholar

18 J.Cai, J.Shi, K.Wang, F.Li, W.Wang, Q.Wang, Y.Liu: A modified parallel constitutive model for elevated temperature flow behavior of Ti-6Al-4 V alloy based on multiple regression, International Journal of Material Research108 (2017), No. 7, pp. 52754110.3139/146.111514Suche in Google Scholar

19 D.Samantaray, S.Mandal, A. K.Bhaduri: A comparative study on Johnson Cook, modified Zerilli–Armstrong and Arrhenius-type constitutive models to predict elevated temperature flow behaviour in modified 9Cr–1Mo steel, Computational Materials Science47 (2009), No. 2, pp. 56857610.1016/j.commatsci.2009.09.025Suche in Google Scholar

Published Online: 2019-02-21
Published in Print: 2019-03-01

© 2019, Carl Hanser Verlag, München

Artikel in diesem Heft

  1. Inhalt/Contents
  2. Contents
  3. Fachbeiträge/Technical Contributions
  4. Improved stress concentration factors for circular shafts for uniaxial and combined loading
  5. Constitutive modeling for high temperature compressive deformation of non-oriented electrical steel
  6. Microstructure and mechanical properties of a rotary friction welded tungsten heavy alloy
  7. Laser speckle photometry – Optical sensor systems for condition and process monitoring
  8. Bending behavior of sandwich structures with different fiber facing types and extremely low-density foam cores
  9. Effects of specimen dimensions and impact energy on energy absorption and damage of glass/epoxy composite plates
  10. Wear behavior of sansevieria cylindrica and E-glass reinforced polyester composites
  11. Synergistic effects of chemical finishing processes on comfort characteristics of micro-modal and lyocell knitted fabrics
  12. Inspection of defects in CFRP by improved magnetic induction tomography
  13. Effects of the drill flute number on drilling of a casted AZ91 magnesium alloy
  14. Limit load evaluation of inlet pigtail pipe bends with ovality under in-plane bending
  15. Synthesis of graphene oxide with superhydrophilicity and well-defined sheet size distribution
  16. Effects of induction hardened surface depth on the dynamic behavior of rotating shaft systems
  17. Tool condition monitoring in the milling process with vegetable based cutting fluids using vibration signatures
https://doi.org/10.3139/120.111306

Artikel in diesem Heft

  1. Inhalt/Contents
  2. Contents
  3. Fachbeiträge/Technical Contributions
  4. Improved stress concentration factors for circular shafts for uniaxial and combined loading
  5. Constitutive modeling for high temperature compressive deformation of non-oriented electrical steel
  6. Microstructure and mechanical properties of a rotary friction welded tungsten heavy alloy
  7. Laser speckle photometry – Optical sensor systems for condition and process monitoring
  8. Bending behavior of sandwich structures with different fiber facing types and extremely low-density foam cores
  9. Effects of specimen dimensions and impact energy on energy absorption and damage of glass/epoxy composite plates
  10. Wear behavior of sansevieria cylindrica and E-glass reinforced polyester composites
  11. Synergistic effects of chemical finishing processes on comfort characteristics of micro-modal and lyocell knitted fabrics
  12. Inspection of defects in CFRP by improved magnetic induction tomography
  13. Effects of the drill flute number on drilling of a casted AZ91 magnesium alloy
  14. Limit load evaluation of inlet pigtail pipe bends with ovality under in-plane bending
  15. Synthesis of graphene oxide with superhydrophilicity and well-defined sheet size distribution
  16. Effects of induction hardened surface depth on the dynamic behavior of rotating shaft systems
  17. Tool condition monitoring in the milling process with vegetable based cutting fluids using vibration signatures
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