Theoretical and Experimental Analysis of Formability of Explosive Welded Mg/Al Bimetallic Bars

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Abstract

The paper has presented the results of theoretical studies and experimental tests of the plastic deformation of Mg/Al bimetallic specimens. Theoretical studies were carried out using the Forge2011® computer program. Physical modeling, on the other hand, was performed using the Gleeble3800 simulator. Bimetallic bars of an outer diameter of 22.5 mm and a cladding layer thickness of 1.7 mm were obtained by the explosive welding method. Samples for formability tests, characterized by a diameter-to-length ratio of 1, were taken from the bars. The theoretical studies and experimental tests were carried out for the temperature range from 300 to 400°C and for different strain rates. Based on the obtained investigation results it has been found that the main parameters influencing the formability of Mg/Al bimetallic bars are strain rate than the process temperature.

[1] D. Kuc, E. Hadasik, I. Bednarczyk, Solid State Phenomena 191, 101 (2012).

[2] D. Kuc, E. Hadasik, I. Schindler, P. Kawulok, R. Sliwa, Arch. of Met. and Mat. 58 (1), 151 (2013).

[3] S.M Hirth, G.J Marshall, S.A Court, D.J Lloyd, Mat. Sci. and Eng. A 319-321, 452 (2001).

[4] M. Keigler, H. Bauer, D. Harrison, Anjali K.M. De Silva, J. of Mat. Proc. Techn. 167, 363 (2005).

[5] N. Zhang, W. Wang, X. Cao, J. Wu, Materials & Design 65, 1100 (2015)

[6] I.A. Bataev, A.A. Bataev, V.I. Mali, D.V. Pavliukova, Materials & Design 35, 225 (2012)

[7] A. Tajyar, A. Masoumi, J. of Mech. Sc. and Techn. 30 (9), 4299 (2016).

[8] S. Mróz, G. Stradomski, H. Dyja, A. Galka, Arch. Civil Mech. Eng. 15 (2), 317 (2015).

[9] A.G. Mamalis, A. Szalay, N.M. Vaxevanidis, D.E. Manolakos, J. of Mat. Proc. Techn. 83 (1), 48 (1998).

[10] M. Asemabadi, M. Sedighi, M. Honarpisheh, Mat.s Sc. and Eng. A 558, 144 (2012).

[11] N. Kahraman, B. Gülenç, F. Findik, J. of Mat. Proc. Techn. 169 (2), 127 (2005).

[12] A. Durgutlu, B. Gülenç, F. Findik, Materials & Design 26 (6), 497 (2005).

[13] S.A. Mousavi, P. F. Sartangi, Materials & Design 30 (3), 459 (2009).

[14] T.Z. Blazynski, Explosive Welding, Forming and Compaction, Springer, (1983)

[15] H. Dyja, S. Mroz, Z. Stradomski, Metalurgija 42 (3), 185 (2003).

[16] C. Binotsch, A. Feuerhack, B. Awiszus, M. Handel, D. Nickel, D. Dietrich, Forming of Co-Extruded Al-Mg Hybrid Compounds, Conf. Meform 2014, Altenberg, Saxony, Conference Procedings, 94 (2014).

[17] S. Mróz, P. Szota, T. Bajor, A. Stefanik, Key Engineering Materials 716, 114 (2016).

[18] F.H. Norton, Creep of Steel at High Temperature, New York 1929.

[19] N.J. Hoff, Appl. Mech. 2 (1954).

[20] A. Hensel, T. Spittel, Kraft – und Arbeitsbedarf bildsamer Formgebungsverfahren, Deutscher Verlag für Grundstoffindustrie, Leipzig 1978.

Archives of Metallurgy and Materials

The Journal of Institute of Metallurgy and Materials Science and Commitee on Metallurgy of Polish Academy of Sciences

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