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Acta Mechanica Slovaca 2016, 20(1):14-21 | DOI: 10.21496/ams.2016.003

Verification the Numerical Simulation of the Strip Drawing Test by its Physical Model

Emil Evin1,*, Miroslav Tomáš2, Marek Výrostek3
1 Department of Automotive Production, Technical University in Košice, Mäsiarska 74, 040 01 Košice, Slovakia
2 Department of Computer Support of Technology, Technical University in Košice, Mäsiarska 74, 040 01 Košice, Slovakia
3 Production Director, Zastrova a.s., SNP 86, 061 01 Spišská Stará Ves

When numerically simulate the stamping processes, it is important to define the friction coefficients in different regions. These depend on the deformation processes due to various stress-strain states in each area. In the deep drawing process, the friction conditions in the blankholder-blank-die area and blank-die radius area differ. The analytical models for the friction coefficients determination by strip drawing test are presented in the paper. The equations have been used to calculate the friction coefficients based on a physical model of the strip drawing test and its numerical simulation. The physical and numerical experiments have been performed on Zn coated IF steel DX54D with thickness 0.78 mm. Hill48 yield law and Hollomon's hardening curve have been used as material characteristics when numerically simulated. The blank-holding forces 4 and 9 kN have been set during the experiment and numerical simulation. Good conformity of numerical simulation and the physical model have been found when friction coefficients were calculated from analytical models including the ratio of drawing forces measured with fixed and rotated cylinder. Additionally, the normal contact pressure under the blankholder and on the die radius was evaluated from the numerical simulations. The highest value has been found at the die radius start.

Keywords: deep drawing, numerical simulation, strip drawing test, friction coefficient, physical model

Published: March 31, 2016  Show citation

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Evin, E., Tomáš, M., & Výrostek, M. (2016). Verification the Numerical Simulation of the Strip Drawing Test by its Physical Model. Acta Mechanica Slovaca20(1), 14-21. doi: 10.21496/ams.2016.003
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    References

    1. Doege E., Droder B., Greisbach B. (1997). On development of new characteristic value for the evaluation of sheet metal formability. Journal of Materials Processing Technology, Vol. 71, p. 152-159. Go to original source...
    2. Lange K. (1990). Umformtechnik - Blechbearbeitung. Springer/Verlag, Berlin. Go to original source...
    3. Mahrenholtz O., Bontcheva N. (2005). Influence of surface roughness on friction during metal forming processes. Journal of Materials Processing Technology, Vol. 159, p. 9-16. Go to original source...
    4. Kim Y.S., Jain M.K., Metzger D.R. (2012). Determination of pressure-dependent friction coefficient from draw-bend test and its application to cup drawing. International Journal of Machine Tools & Manufacture, Vol. 56, p. 69-78. Go to original source...
    5. Schrek A., Gajdošová V., Švec P. (2016). Deformation Properties of Tailor Welded Blank Made of Dual Phase Steels. Acta Mechanica et Automatica, Vol. 10, p. 38-42. Go to original source...
    6. Ma G., Huang B. (2014). Optimization of Process Parameters of Stamping Forming of the Automotive Lower Floor Board. Journal of Applied Mathematics, Vol. 2014, doi:10.1155/2014/470320. Go to original source...
    7. Wen Y., Zhong W., Liu Y. (2013). Optimization design of process parameters in sheet metal drawing. Journal of Plasticity Engineering, Vol. 20, No. 3, p. 31-36.
    8. Volk M., Nardin B., Dolšak B. (2011). Application of numerical simulations in deep-drawing process and holding system with segments' inserts. Strojniški vestnik - Journal of Mechanical Engineering, Vol. 57, No. 9, p. 697-703. Go to original source...
    9. Trzepieciński T., Hirpa G. (2015). Proposal for an Experimental-Numerical Method for Friction Description in Sheet Metal Forming. Journal of Mechanical Engineering. Vol. 61, p. 383-391. Go to original source...
    10. Zhenyu H., Vollertsen F. (2004). A new friction test method. Journal for Technology of Plasticity, Vol. 29, p.1-9
    11. Vollertsen F., Zhenyu H. (2008). Determination of size dependent friction functions in sheet metal forming with respect to the distribution of contact pressure. Production Engineering - Research and Development, Vol. 2, p. 345-350. Go to original source...
    12. Evin E., Németh S., Vyrostek M. (2014). Evaluation of Friction Coefficient of Stamping. Acta Mechanica Slovaca, Vol. 18, p. 20-27. ISSN 1335-2393. Go to original source...

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