Microstructure and Properties of 20Cr23Ni18 (AISI 304L) Thin Steel Tapes Obtained by Melt Spinning

T.I. Bobkova; Pavel A. Kuznetsov; M.V. Khromenkov; Mikhail V. Staritsyn; M.V. Balashov

doi:10.4028/p-b420s5

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HomeKey Engineering MaterialsKey Engineering Materials Vol. 910Microstructure and Properties of 20Cr23Ni18 (AISI...

Microstructure and Properties of 20Cr23Ni18 (AISI 304L) Thin Steel Tapes Obtained by Melt Spinning

Abstract:

The paper presents the results of a study of morphology, chemical composition, microcrystalline structure and properties of thin tapes of alloy grade 20KH23N18S2, obtained by melt spinning. The influence of process parameters on the properties and microstructure of the tapes is established.

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Periodical:

Key Engineering Materials (Volume 910)

Pages:

579-585

DOI:

https://doi.org/10.4028/p-b420s5

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Online since:

February 2022

Authors:

T.I. Bobkova*, Pavel A. Kuznetsov, M.V. Khromenkov, Mikhail V. Staritsyn, M.V. Balashov

Keywords:

High Temperature Superconductors, Melt Spinning, Microcrystalline Belts, Microstructure, Superconductivity, Thin Tapes

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References

[1] Kablov E.N. Science as a driver of economic development, Industry, No. 1 (167), 2017, pp.1-2.

Google Scholar

[2] Guseva L. High-temperature superconductors. Prospects for use in microwave components. Electronics NTB, issue No. 2/1999, electronic version of the journal, access mode https://www.electronics.ru/journal/article/1649, access date 05/14/(2021).

Google Scholar

[3] Zakharova E. I. Application of high-temperature superconductivity in metallurgical industry. E. I. Zakharova, M. M. Suyundikov. - Technical sciences in Russia and abroad: materials of the V Intern. Scientific. Conf. (Moscow, January 2016). -Moscow: Buki-Vedi, 2016. - pp.23-29.- URL: https://moluch.ru/conf/tech/archive/164/9257/ (access date: 14.05.2021).

Google Scholar

[4] Fossheim K., Sudbo A. Superconductivity, Physics and Applications // John Wiley & Sons. Ltd., 2004, 333 pp.

Google Scholar

[5] Molozemov A.P., Mannhart J., Scalapino D. High-Temperature Cuprate Superconductors Get to Work //Physics Today, 2005, 58 (4), 41-47. http://physics03.narod.ru/Interes/Doclad/poezd1.htm.

DOI: 10.1063/1.1955478

Google Scholar

[6] Feldmann D. M., Reeves J. L., Polyanskii A. A., et al. // Appl. Phys. Lett. - 2000. -Vol. 77. - P. 2906-2908.

Google Scholar

[7] Molotilov B. V. Study of structure formation in the two-roll method of rapid quenching. B. V. Molotilov, N. M. Zakazalov. Steel. - 1992. - No. 3. - p.75–78.

Google Scholar

[8] Vereshchagin M.N. Formation of contact surface of frozen metal in the two-roll fast quenching method. M.N. Vereshchagin, N.M. Zapazalov, I.V. Agunovich. Vestn. of Gomel. State Tech. University named after P.O. Sukhoi. - 2007. - No. 3. - p.3–10.

Google Scholar

[9] Vereshchagin M.N. Analysis of solidification process of metal during two-roll quenching of the melt. Vesti AN Resp. Belarus. - 1994. - No. 2. - p.47–52.

Google Scholar

[10] Microstructure & properties of Fe-36% Ni invar alloy produced by twin-roll strip casting process at POSCO / J. T. Choi [et al.] // 83rd Steelmaking Conference, USA, 2000. – Р. 29–40.

Google Scholar

[11] F. Shahri and А. Beitollahi, Effect of super-heat treatment and quenching wheel speed on the structure and magnetic properties of Fe–Si–Nb–Cu–B–Al–Ge melt spun ribbons, J. Non. Cryst. Solids, vol. 354, no. 14, p.1487–1493, Mar. (2008).

DOI: 10.1016/j.jnoncrysol.2007.08.036

Google Scholar

[12] F. Shahri, a. Beitollahi, S. G. Shabestari, M. Ghanaatshoar, M. M. Tehranchi, S. M. Mohseni, S. E. Roozmeh, N. Wanderka, and F. Fiorillo, «Structural characterization and magnetoimpedance effect in amorphous and nanocrystalline AlGesubstituted FeSiBNbCu ribbons», J. Magn. Magn.

DOI: 10.1016/j.jmmm.2006.09.014

Google Scholar

[13] Sultan Öztürk, Kürşat İcin, Bülent Öztürk «Investigation of Production of Rapidly Solidified 304 Stainless Steel Ribbons by Melt Spinning Method» Conference Paper June (2014).

Google Scholar

[14] Rudnev I.A. Effects of the influence of nanoadditives and radiation effects on the transport and magnetic characteristics of promising superconducting materials. Dissertation for the degree of Doctor of Physics and Mathematics, Moscow - 2013, 258 p.

Google Scholar

[15] Lappo I.S. et al. Technology and properties of magnetic HTSC screens. Obtaining, properties and analysis of high-temperature superconducting materials and products. - Yekaterinburg: Ural Branch of the Academy of Sciences of the USSR, 1991, pp.94-97.

Google Scholar