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Research on parameters of MMC fracture criterion for advanced high strength dual-phase steel sheets

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
To predict the shear fracture, tests of advanced high-strength DP steels have been carried out, and fracture models of DP steels have been established using the MMC fracture model. The MMC fracture parameters were obtained through multiple sets of experiments and stress triaxiality solved by simulation. The result was verified by stretch-bending, Nakazima tests and simulations. It shows that the MMC criterion is suitable for predicting ductile fracture of DP980, 1180. The correlation between the parameters of the MMC criterion and DP steel material properties can reduce the amount of tests data required.
Rocznik
Strony
253--265
Opis fizyczny
Bibliogr. 24 poz., rys., tab.
Twórcy
autor
  • School of Traffic and Vehicle Engineering, Shandong University of Technology, Zibo, China
autor
  • School of Transportation and Vehicle Engineering, Shandong University of Technology, Zibo, China
autor
  • School of Traffic and Vehicle Engineering, Shandong University of Technology, Zibo, China
autor
  • School of Traffic and Vehicle Engineering, Shandong University of Technology, Zibo, China
autor
  • School of Traffic and Vehicle Engineering, Shandong University of Technology, Zibo, China
autor
  • School of Traffic and Vehicle Engineering, Shandong University of Technology, Zibo, China
Bibliografia
  • 1. Bai Y., Wierzbicki T., 2010, Application of extended Mohr-Coulomb criterion to ductile fracture, International Journal of Fracture, 161, 1, 1-20.
  • 2. Barlat F., Brem J.C., Yoon J.W., Chung K., Dick R.E., Lege D.J., Pourboghrat F., Choi S.-H., Chu E., 2003, Plane stress yield function for aluminum alloy sheets, Part I: Theory, International Journal of Plasticity, 19, 9, 1297-1319.
  • 3. Durrenberger L., Molinari A., Rusinek A., 2008, Internal variable modeling of the high strain-rate behavior of metals with applications to multiphase steels, Materials Science and Engineering A, 478, 1-2, 297-304.
  • 4. Gotoh M., Katoh M., Yamashita M., 1997, Studies of stretch-drawing process of sheet metals, Journal of Materials Processing Technology, 63, 123-128.
  • 5. Granum H., Morin D., Børvik T., Hopperstad O.S., 2021, Calibration of the modified Mohr-Coulomb fracture model by use of localization analyses for three tempers of an AA6016 aluminium alloy, International Journal of Mechanical Sciences, 192, 15, 106122.
  • 6. Hill R.A., 1948, A theory of the yielding and plastic flow of anisotropic metals, Proceedings of the Royal Society of London, 193, 1033, 281-297.
  • 7. Ji C., Li Z., Liu J., 2020, Development of an improved MMC-based fracture criterion characterizing the anisotropic and strain rate-dependent behavior of 6061-T5 aluminum alloy, Mechanics of Materials, 150, 11, 103598.
  • 8. Lee M.G., Kim D., Kim C.M., Wenner M.L., Wagoner R.B., Chung K., 2005, Spring-back evaluation of automotive sheets based on isotropic-kinematic hardening laws and non-quadratic anisotropic yield functions, Part II: characterization of material properties, International Journal of Plasticity, 21, 883-914.
  • 9. Levy B.S., van Tyne C.J., 2009, Predicting breakage on a die radius with a straight bend axis during sheet forming, Journal of Materials Processing Technology, 209, 2038-2046.
  • 10. Li Y., Luo M., Gerlach J., Wierzbicki T., 2010, Prediction of shear-induced fracture in sheet metal forming, Journal of Materials Processing Technology, 210, 14, 1858-1869.
  • 11. Lian J., Sharaf M., Archie F., Münstermann S., 2013, A hybrid approach for modelling of plasticity and failure behaviour of advanced high-strength steel sheets, International Journal of Damage Mechanics, 22, 2, 188-218.
  • 12. Lian J., Wu J., Münstermann S., 2015, Evaluation of the cold formability of high-strength low-alloy steel sheets with the modified Bai-Wierzbicki damage model, International Journal of Damage Mechanics, 24, 3, 383-417.
  • 13. Lou Y., Huh H., 2013, Prediction of ductile fracture for advanced high strength steel with a new criterion: Experiments and simulation, Journal of Materials Processing Technology, 213, 8, 1284-1302.
  • 14. Meng L., Chen X., Shi M.F., Shih H.C., 2010, Numerical analysis of AHSS fracture in a stretch-bending test, American Institute of Physics Conference Series, American Institute of Physics.
  • 15. Qian L., Ji W., Wang X., Sun C., Ma T., 2020, Research on fracture mechanism and prediction of high-strength steel sheet under different stress states (in Chinese), Chinese Journal of Mechanical Engineering, 56, 24, 72-80.
  • 16. Shih H., 2009. An experimental study on shear fracture of advanced high strength steels, Presentations of Great Design in Steel 2009, Detroit, MI.
  • 17. Shih H.C., Shi M.F., 2008, Experimental study on shear fracture of advanced high strength steels, Proceedings of International Conference on Manufacturing Science and Engineering, MSEC 2008-72046.
  • 18. Sriram S., Wong C., Huang M., Yan B., 2003, Stretch-bendability of advanced high strength steels, Proceedings of SAE 2003 Word Congress, Detroit, MI, SAE 2003-01-1151.
  • 19. Walp M.S., Wurm A., Siekirk J.F., Desai A.K., 2006, Shear fracture in advanced high strength steels, Proceedings of SAE 2006 Word Congress, Detroit, MI, SAE 2006-01-1433.
  • 20. Wierzbicki T., Bao Y., Lee Y.-W., Bai Y., 2005, Calibration and evaluation of seven fracture models, International Journal of Mechanical Sciences, 47, 4-5, 719-743.
  • 21. Wierzbicki T., Xue L., 2005, On the effect of the third invariant of the stress deviator on ductile fracture, Technical Report, Impact and Crashworthiness Lab., Massachusetts Institute of Technology.
  • 22. Xue L., 2007, Damage accumulation and fracture initiation in uncracked ductile solids subject to triaxial loading, International Journal of Solids and Structures, 44, 16, 5163-5181.
  • 23. Xue L., Wierzbicki T., 2009, Numerical simulation of fracture mode transition in ductile plates, International Journal of Solids and Structures, 46, 6, 1423-1435.
  • 24. Yoshida F., Uemori T., Fujiwara K., 2008, Elastic-plastic behavior of steel sheets under in-plane cyclic tension-compression at large strain, Proceedings of Symposium on Constitutive Equations and their Role in Applied Deformation Behavior, 18, 633-659.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-c4c8266d-7f18-49fb-ba76-c92dd179c5c1
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