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Metallurgist

Erschienen in:

01.01.2022

Effect of Nanosized Phase Precipitates on the Corrosion Resistance of Cold-Rolled High-Strength Low-Carbon Niobium Microalloyed Steels

verfasst von: I. G. Rodionova, A. V. Amezhnov, N. A. Arutyunyan, Yu. S. Gladchenkova, I. A. Vasechkina, A. A. Papshev

Erschienen in: Metallurgist | Ausgabe 9-10/2022

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Abstract

The effect on corrosion resistance of the structural state of cold-rolled low-carbon microalloyed steels treated in continuous annealing units was studied. The bulk density and size of niobium carbonitride nanosized precipitates were established as the main structural factors determining the corrosion resistance of rolled products. The formation of these precipitates is shown to be affected by hot rolling temperature parameters. An increase in the temperature following rolling in roughing stands, as well as at the conclusion of final rolling and coiling, contributes to a decrease in the quantity of nanosized particles and an increase in their average size in the rolled products following annealing, which increases the corrosion resistance of the steels under consideration.

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C. Lesch, N. Kwiaton, and F.B. Klose, “Advanced high strength steels (AHSS) for automotive applications - tailored properties by smart microstructural adjustments,” Steel Research Int., 88, No. 1700210 (2017).

Z. B. Jiao, J. H. Luan, M. K. Miller, Y. W. Chung, and C. T. Liuet, “Co-precipitation of nanoscale particles in steels with ultra-high strength for a new era,” Mater. Today, 20, 142 (2017).CrossRef

A. J. DeArdo, “Niobium in modern steels,” Int. Mater. Rev., 48, 371–402 (2003).CrossRef

C. I. Garcia, M. Hua, K. Cho, and A. J. DeArdo, “On the strength of microalloyed steels. An interpretive review,” La Metallurgia Italiana, No. 11-12, 25–42 (2009).

G. Larzabal, N. Isasti, J. M. Rodriguez-Ibabe, and P. Uranga, “Evaluating strengthening and impact toughness mechanisms for ferritic and bainitic microstructures in Nb, Nb-Mo and Ti-Mo microalloyed steels,” Metals, 7, 65 (2017).CrossRef

W. Chen, P. Gao, S. Wang, H. Lu, and Z. Zhao, “Effect of vanadium on hydrogen embrittlement susceptibility of high-strength hotstamped steel,” J. Iron Steel Res. Int., 28, 211–222 (2020).CrossRef

S. Zhang, J. Wan, Q. Zhao, J. Liu, F. Huang, Y. Huang, and X. Li, “Dual role of nanosized NbC precipitates in hydrogen embrittlement susceptibility of lath martensitic steel,” Corrosion Sci., 164, 108345 (2020).CrossRef

W. Huang, “Suppression of hydrogen-induced damage in 22MnB5 hot stamping steel by microalloying,” Mater. Chem. Phys., 256, 123–129 (2020).CrossRef

H. J. Kim, S. H. Jeon, W. S. Yang, B. G. Yoo, Y. D. Chung, H. Y. Ha, and H. Y. Chung, “Effects of titanium content on hydrogen embrittlement susceptibility of hot-stamped boron steels,” J. Alloys Compd., 735, 2067–2080 (2018).CrossRef

10.

L. Lin, B. S. Li, G. M. Zhu, Y. L. Kang, and R. D. Liu, “Effect of niobium precipitation on microstructure and hydrogen induced cracking of press hardening steel 22MnB5,” Mater. Sci. Eng. A., 721, 25–46 (2018).CrossRef

11.

I. G. Rodionova, A. V. Amezhnov, D. L. D’yakonov, N. G. Shaposhnikov, O. N. Baklanova, and Y. S. Gladchenkova, “Study of the effect of microstructure characteristics on corrosion resistance of cold-rolled micro-alloyed sheet steels (HSLA) of strength classes 340-420 for Automobile Building,” Metallurgist, 63, No. 11-12, 1165–1177 (2020).

12.

I. Rodionova, A. Amezhnov, E. Alekseeva, Y. Gladchenkova, and I. Vasechkina, “Effect of carbonitride precipitates on the corrosion resistance of low-alloy steels under operating conditions of oil-field pipelines,” Metals, 11, 766 (2021).CrossRef

13.

I. G. Rodionova, E. T. Shapovalov, M. E. Kovalevskaya, O. N. Baklanova, D. A. Burko, N. I. Endel’, Yu. B. Gusev, R. E. Gliner, A. M. Lamukhin, V. V. Kuznetsov, V. L. Chernousov, S. D. Zinchenko, S. V. Efimov, M. V. Shurygina, and A. D. Gorin, “Increasing the resistance of automobile sheet to atmospheric corrosion by optimizing its chemical composition and the parameters of the manufacturing process,” Metallurgist, 49, 314–323 (2005).CrossRef

14.

I. G. Rodionova, O. N. Baklanova, A. I. Zaitsev, M. E. Marzoeva, et al., “Investigation of the factors controlling the corrosion resistance of microalloyed automobile steels,” Problemy Chernoi Metallurgii i Materialovedeniy, No. 2, 45–55 (2010).

15.

A. V. Amezhnov, I. G. Rodionova, A. I. Zaitsev, E. I. Zarkova, and M. E. Marzoeva, “Influence patterns of the characteristics of non-metallic inclusions and phase precipitates on the corrosion resistance of low-carbon and ultra-low-carbon steels,” Problemy Chernoi Metallurgii i Materialovedeniya, No. 1, 58–69 (2019).

16.

E. T. Shapovalov, I. G. Rodionova, A. I. Zaitsev, M. E. Kovalevskaya, O. N. Baklanova, et al., “Factors determining corrosion resistance and other consumer properties of cold-rolled steel,” Problemy Chernoi Metallurgii i Materialovedeniya, No. 3, 68–76 (2009).

17.

I.G. Rodionova, A. V. Amezhnov, N. G. Shaposhnikov, Y. S. Gladchenkova, and D. L. D’yakonov, “Features of the effect of microstructure characteristics on corrosion resistance of cold-rolled high-strength low-alloy steels (HSLA) grade 260-300 for automobile building,” Metallurgist, 63, No. 9-10, 920–932 (2020).CrossRef

18.

K. D. Ralston and N. Birbilis, “Effect of grain size on corrosion: a review,” Corrosion, 66, No. 7, 075005–075005-13 (2010).CrossRef

19.

S. Ghosh, A.K. Singh, S. Mula, P. Chanda, V. Vinay, V. V. Mahashabde, and T. K. Roy, “Mechanical properties, formability and corrosion resistance of the mechanically controlled processed Ti-Nb stabilized IF steel,” Mater. Sci. Eng., 684A, 22–36 (2017).CrossRef

20.

B. Hadzima, M. Janecek, Y. Estrin, and H. S. Kim, “Microstructure and corrosion properties of ultrafine grained interstitial free steel,” Mater. Sci. Eng., 462A, 243–247 (2007).CrossRef

21.

K. G. Krishna, K. Sivaprasad, T. S. N. Sankaro Narayanan, and K. C. Hari Kumar, “Localized corrosion of an ultrafine grained Al-4Zn-2Mg alloy produced by cryorolling,” Corrosion Sci., 60, 82–89 (2012).CrossRef

22.

H. Zhang, P. Xue, L. H. Wu, Q. N. Song, D. Wang, B. L. Xiao, and Z. Y. Ma, “Effect of grain ultrarefinement on corrosion behavior of ultra-high strength high nitrogen stainless steel,” Corrosion Sci., 174, 108847 (2020).CrossRef

23.

A. I. Zaitsev, I. G. Rodionova, N. A. Arutyunyan, and S. F. Dunaev, “Study of features of phase precipitation formation, structural state, and properties of ferritic class microalloyed low-carbon steels,” Metallurgist, 64, No. 7-8, 750–758 (2020).

Titel: Effect of Nanosized Phase Precipitates on the Corrosion Resistance of Cold-Rolled High-Strength Low-Carbon Niobium Microalloyed Steels
verfasst von: I. G. Rodionova
A. V. Amezhnov
N. A. Arutyunyan
Yu. S. Gladchenkova
I. A. Vasechkina
A. A. Papshev
Publikationsdatum: 01.01.2022
Verlag: Springer US
Erschienen in: Metallurgist / Ausgabe 9-10/2022
Print ISSN: 0026-0894
Elektronische ISSN: 1573-8892
DOI: https://doi.org/10.1007/s11015-022-01237-x

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