Results are provided for a study of diffusion redistribution of chromium and nickel in multilayer metallic materials prepared by hot pack rolling. The choice of steels for forming the original binary composite multilayer materials is based on the assumption of the mutual effect of the main alloying elements and carbon. Multilayer materials are studied based on steels 08kp + 08Kh18, 08kp + 08Kh18N10, U8 + 08Kh18, and U8 + 08Kh18N10, having 100 layers after the first and 1500 layers after the second production cycles. It is shown that the diffusion mobility of chromium between layers is the main reason for a slowdown in nickel diffusion. Results of mathematical modeling compare well with the experimental data obtained.
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V. V. Rybin, V, A. Malyshevskii, and E. I. Khlusova, “Technology for creating structural nanostructured steels,” MiTOM, No. 6, 3–7 (2009).
I. V. Gorynin, V. V. Rybin, V. A. Malyshevskii, and E. I. Khlusova, “Principles of alloying, phase transformation, structure and properties of cold-resistant weldable shipbuilding steels,” MiTOM, No. 1, 9–15 (2007).
Y. Kimura, T. Inoue, F. Yin, and K. Tsuzaki, “Inverse temperature dependence of toughness in an ultrafine grain-structure steel,” Science, 320, 1057–1060 (2008).
Y. Saito, Utsunomiya, N. Tsuji, and T. Sakai, “Novel ultra-high straining process for bulk materials-development of the accumulative roll bonding (ARB) process,” Acta Materialia, No. 47, 579–583 (1999).
A. I. Rudskoi, G. E. Kodzhaspirov, and S. V. Dobatkin, “Promising technology for preparing rolled sheet with an ultrafine grained structure,” Metally, No. 1, 88–92 (2012).
A. G. Kolesnikov, A. I. Plokhikh, Yu. S. Kamissarchuk, and I. Yu. Mikhal’tsevich, “Study of features of sub-micro- and nanosize structure formation in multilayer materials by hot rolling,” MiTOM, No. 6, 44-49 (2010).
M. I. Karpov, V. I Vnukov, et al., “Possibilities of vacuum rolling method as a procedure for preparing multilayer composites with nanometer layer thicknesses,” Materialovedenie, No. 1, 48–53 (2004).
S. V. Gladovskii, S. V. Kuteneva, I. S. Kamantsev, et al., “Effect of plastic deformation on the structure and mechanical properties of medium-carbon IF-steel in monolithic material and within the composition of a layered composite,” FMM, 117, No. 10, 1105–1112 (2016).
T. I. Tabachikova, A. I. Plokhikh, I. L. Yakovlev, and S. Yu. Klyuchev, “Structure and properties of multilayer material based on steels prepared by hot pack rolling,” FMM, 114, No. 7, 633 (2013).
T. I. Tabachikova, I. L. Yakovleva, A. I. Plokhikh, and S. Yu. Del’gado Reina, “Study of multilayer material based on stainless steel prepared by hot pack rolling,” FMM, 115, No. 4, 441-442 (2014).
D. R. Lesuer, C. K. Syn, O. D. Sherby, et al., “Mechanical behaviour of laminated metal composites,” Int. Mater. Rev., 41, No. 5, 169–197 (1996).
M. Pozuelo, F. Carreno, C. M. Cepeda-Jimenez, and O. A. Ruano, “Effect of hot rolling on bonding characteristics and impact behavior of a laminated composite material based on UHCS-1.35% C,” Metallurgical and Materials Trans. A, 39, No. 3, 666–671 (2008).
A. Schmiedt, L. Luecker, A. Kolesnikov, et al., “Production-and microstructure-based fatigue assessment of metallic AISI 304/430 multilayer materials produced by hot pack rolling,” Materialpruefung, 59, No. 2, 123–129 (2017).
M. Yu. Semenov, and L. P. Fomina, “Mathematical modeling of vacuum carburization of carbon- and low-alloy steels,” Dvigatel’, No. 1(73), 18–20 (2011).
M. A. Duyananda, “Diffusion in ternary alloys,” in H. Mehrer (editor), Diffusion in Solid Metals and Alloys, (Landolt-Bornstein new series). Springer-Verlag, III (26) (1990), pp. 372–436.
A. D. Le Claire and G. Neumann, “Diffusion of impurities in solid metallic elements,” in H. Mehrer (editor), Diffusion in Solid Metals and Alloys, (Landolt-Bornstein New Series). Springer-Verlag, III (26) (1990), pp. 85–212.
A. I. Plokhikh, Yue Chan, and S. D. Karpukhin, “Study of the effect interlayer diffusion redistribution of carbon on impact strength of multilayer materials,” Izv. Volgograd. Gos. Tekh. Univ., No. 8, 86–91 (2015).
A. Bondar, V. Ivanchenko, A. Kozlov, and J. C. Tedenac, Carbon–Chromium–Iron, Iron Systems, Part 2, Springer Berlin Heidelberg (2008).
D. Bouchet and L. Priester, “Indirect detection of grain boundary segregation of carbon in iron-chromium alloys (Cr 10%) by electrochemical study,” J. Mater. Sci., 14, No. 9, 2205–2214 (1979).
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Translated from Metallurg, Vol. 62, No. 5, pp. 33–38, May 2018.
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Vlasova, D.V., Plokhikh, A.I., Semenov, M.Y. et al. Effect of Diffusion Processes During Pack Rolling on Multilayer Material Stability. Metallurgist 62, 432–439 (2018). https://doi.org/10.1007/s11015-018-0678-y
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DOI: https://doi.org/10.1007/s11015-018-0678-y