Abstract
In the present study, values of yield strength of individual layers of layered composites based on different strength mild steels obtained by explosion welding followed by cold rolling and heat treatment were determined. The effect of cold rolling with a total reduction of 50% and heat treatment at a temperature of 500 °C on the change of the deformational resistance of Fe-2Mn-Si and Fe-11Cr-9Ni-2Mo-1Ti steels’ layers in the composite was established. It was shown that additional cold deformation of the layered composite leads to an increase in yield strength of Fe-2Mn-Si and Fe-11Cr-9Ni-2Mo-1Ti steels’ layers by 20% and 24%, respectively, and additional heat treatment of the cold-deformed composite contributes to strengthening of the Fe-11Cr-9Ni-2Mo-1Ti steel layers by 17% and softening of the Fe-2Mn-Si steel layers by 6%. It was shown that the level of strengthening of the Fe-11Cr-9Ni-2Mo-1Ti steel layers after cold rolling corresponds to the level of strengthening of this steel after heat treatment. It was determined that the maraging steel layers with initial ultrafine-grained microstructure are intensely strengthened (35%) by conducting combined heat-deformational processing of a layered composite, including cold rolling with a total reduction of 50% and subsequent heat treatment at a temperature of 500 °C.
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References
D.D.L. Chung, Composite Materials: Science and Application, 2nd ed., B. Derby, Ed., Springer, Berlin, 2010, p 5–27
K.N. Chawla, Composite Materials Science and Engineering, The University of Alabama at Birmingham, 2019, p 557
S.V. Gladkovsky, S.V. Kuteneva, I.S. Kamantsev, S.N. Sergeev, and I.M. Safarov, Effect of Plastic Deformation on the Structure and Mechanical Properties of an Ultra-Low Carbon Interstitial-Free Steel in the Monolithic State and in the Composition of a Sandwich Composite, Phys. Met. Metallogr., 2016, 117, p 1070–1077 (in English)
M. Randall, Particulate Composites: Fundamentals and Applications, Springer, Berlin, 2016, p 98
T.A. Venkatesh, K.J. Van Vliet, A.E. Giannakopoulos, and S. Suresh, Determination of Elasto-Plastic Properties by Instrumented Sharp Indentation: Guidelines for Property Extraction, Scr. Mater., 2000, 42, p 833–839 (in English)
J.L. Bucaille, S. Stauss, E. Felder, and J. Michler, Determination of Plastic Properties of Metals by Instrumented Indentation Using Different Sharp Indenters, Acta Mater., 2003, 51, p 1663–1678 (in English)
D.A. Konovalov, S.V. Smirnov, and A.V. Konovalov, Determination of Metal Strain-Hardening Curves from Conical-Indenter Impression Results, Russ. J. Nondestruct., 2008, 44, p 847–853 (in English)
D.A. Konovalov, I.A. Golubkova, and S.V. Smirnov, Determining the Strength Properties of Individual Layers of Strained Laminated Composites by Kinetic Indentation, Russ. J. Nondestruct., 2011, 47, p 852–857 (in English)
Y.P. Trykov, L.M. Gurevich, V.G. Shmorgunov, Sloistyye kompozity na osnove alyuminiya i yego splavov (Layered composites based on aluminum and its alloys), Metallurgiya, 2004, p 230 (in Russia)
V.S. Lozhkin, E.A. Lozhkina, V.I. Mali, and M.A. Esikov, Structure and Mechanical Properties of Multilayered Composite Material, Formed by Explosive Welding of Steel 12X18H10T and Steel H18К9M5T Thin Plates, Obrabotka Metallov, 2014, 3(64), p 28–36 (in Russia)
V.S. Lozhkin, Structure and Mechanical Properties of Multilayered Composite Material, Formed by Explosive Welding of Steel 12X18H10T and Steel H18К9M5T Thin Plates, Obrabotka Metallov, 2013, 3(60), p 110–114 (in Russia)
I.M. Safarov, A.V. Korznikov, R.M. Galeyev, S.N. Sergeev, S.V. Gladkovsky, D.I. Dvoynikov, and IYu Litovchenko, The Ultrafine-Grained Structure, Texture and Mechanical Properties of Low Carbon Steel Obtained by Various Methods of Plastic Deformation, Lett. Mater., 2016, 6(2), p 126–131 (in English)
V.I. Mali, I.A. Bataev, A.A. Bataev, D.V. Pavlyukova, E.A. Prikhodko, and M.A. Esikov, Geometric Transformations of Sheet Steel Billets in Explosion Welding of Multiple Sandwiches, Phys. Mesomech., 2011, 14, p 117–124 (in English)
E.W. Andrews, A.E. Giannakopoulos, E. Plisson, and S. Suresh, Analysis of the Impact of a Sharp Indenter, Int. J. Solids Struct., 2002, 39, p 281–295 (in English)
N. Chollacoop, M. Dao, and S. Suresh, Depth-Sensing Instrumented Indentation with Dual Sharp Indenters, Acta Mater., 2003, 51, p 3713–3729 (in English)
M. Dao, N. Chollacoop, K.J. Van Vliet, T.A. Venkatesh, and S. Suresh, Computational Modeling of the Forward and Reverse Problems in Instrumented Sharp Indentation, Acta Mater., 2001, 49, p 3899–3918 (in English)
G. Care and A.C. Fisher-Cripps, Elastic-Plastic Indentation Stress Fields Using the Finite-Element Method, J. Mater. Sci., 1997, 32, p 5653–5659 (in English)
R. Vaidyanathan, M. Dao, G. Ravichandran, and S. Suresh, Study of Mechanical Deformation in Bulk Metallic Glass Through Instrumented Indentation, Acta Mater., 2001, 49, p 3781–3789 (in English)
S.V. Smirnov and V.P. Shvejkin, Method of Determination of Diagrams of Strengthening for Individual Structural Constituents in Multicomponent Systems, Phys. Met. Metallogr., 1995, 80, p 145–151 (in English)
M.B. Bakirov, M.A. Zaitsev, and I.V. Frolov, Mathematical Simulation of the Indentation Process of a Sphere into an Elastoplastic Half-Space, Diagnost. Mater., 2001, 67, p 37–47 (in English)
A.N. Tikhonov, V.Ya. Arsenin, Metody resheniya nekorrektnykh zadach (Solution of Ill-Posed Problems), 3rd ed., Nauka, 1986, p 76–102 (in Russia)
T.I. Tabatchikova, I.L. Yakovleva, S.Y. Delgado Reina, and A.I. Plokhikh, Effect of Cyclic Treatment on the Formation of a Fragmented Structure in a Sparingly Alloyed Martensitic Steel, Phys. Met. Metallogr., 2016, 117, p 1123–1228 (in English)
M.D. Perkas and V.M. Kardonskii, Vysokoprochnye martensitno-stareyushchie stali (High-Strength Maraging Steels), Metallurgiya, 1970, p 224 (in Russia)
S.V. Gladkovsky, S.V. Kuteneva, I.S. Kamantsev, R.M. Galeev, and D.A. Dvoynikov, Formation of the Mechanical Properties and Fracture Resistance Characteristics of Sandwich Composites Based on the 09G2S Steel and the EP678 High-Strength Steel of Various Dispersion, DREAM, 2017, 6, p 71–90 (in Russia)
Acknowledgments
The authors are grateful to V.I. Mali, PhD, for producing layered composites by explosion welding, R.M. Galeev, PhD, for deformational and heat processing of Fe-11Cr-9Ni-2Mo-1Ti steel sheet and I.S. Kamantsev for experimental assistance. The study was funded by the state assignment to the Institute of Engineering Science, Ural Branch of the Russian Academy of Sciences, No. AAAA-A18-118020790147-4, and the project of Ural Branch of the Russian Academy of Sciences, No. 18-9-1-20.
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Gladkovsky, S.V., Konovalov, D.A. & Kuteneva, S.V. Yield Strength Evaluation of Dissimilar Components of Layered Steel/Steel Composite by Kinetic Indentation. J. of Materi Eng and Perform 29, 5757–5763 (2020). https://doi.org/10.1007/s11665-020-05083-3
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DOI: https://doi.org/10.1007/s11665-020-05083-3