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Erschienen in:

01.04.2023

Improvement of Hot Rolling Technology to Reduce the “Rolled-in Scale” Defect

verfasst von: S. I. Platov, R. R. Dyoma, O. R. Latypov, V. S. Banshchikov, V. A. Mustafin, M. V. Kharchenko, N. Sh. Tyuteryakov

Erschienen in: Steel in Translation | Ausgabe 4/2023

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Abstract

Based on the results of the published literature and production experience, technical and technological measures were developed and implemented to reduce the «rolled-in scale» defect: collectors with water descaling nozzles for removing furnace scale were replaced with new ones manufactured by Spraing Systems; the scheme of operation of hydraulic descalings has been changed; the specific impact force of jets was increased and the distance from the nozzles to the slab surface was reduced. These measures gave significant reduction of defective goods by a total of 55%.

Vorheriger Artikel Electrochemical Protection of Cross Country Pipelines

Nächster Artikel Application of Diffusive Saturation with Boron Together with Aluminum for Hardening of Die Tooling Made of 5KhNM Steel

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Taits, N.Yu., Tekhnologiya nagreva stali (Technology of Steel Heating), Moscow: Metallurgizdat, 1962.

Severdenko, V.P., Makushok, E.M., and Ravin, A.N., Okalina pri goryachei obrabotke metallov davleniem (Oxide Scale at Hot Treatment of Metal Forming), Moscow: Metallurgiya, 1977.

Chmelev, A.A., Mazur, V.L., Timoshenko, L.V., Ben-der, E.A., Sosulin, V.P., and Zhalgasova, L.T., Effect of the oxide scale formation on the profile of cross section of strips, Metall. Gornorudn. Prom-st., 1988, no. 1, pp. 24–25.

Smirnov, A.V., Goryachee tsinkovanie (Hot Zinc Galvanizing), Moscow: Metallurgiya, 1953.

Arkharov, V.I., Okislenie metallov (Oxidation of Metals), Sverdlovsk: Moskva.

Okislenie metallov. Teoreticheskie osnovy (Oxidation of Metals: Theoretical Foundations), Benar, Zh., Ed., Moscow: Metallurgiya, 1968.

Arkharov, V.I. and Blankova, E.B., On the structural characteristics of oxide scale used in studying the mechanism of reaction diffusion, Fiz. Met. Metalloved., 1960, vol. 9, no. 6, pp. 878–887.

Krzyzanowski, M. and Beynon, J.H., Modelling the behaviour of oxide scale in hot rolling, ISIJ Int., 2006, vol. 46, no. 11, pp. 1533–1547. https://doi.org/10.2355/isijinternational.46.1533CrossRef

Sun, W., Tieu, A.K., Jiang, Z., Lu, C., and Zhu, H., Surface characteristics of oxide scale in hot strip rolling, J. Mater. Process. Technol., 2003, vol. 140, nos. 1–3, pp. 76–83. https://doi.org/10.1016/S0924-0136(03)00823-9CrossRef

10.

Zhang, M. and Shao, G., Characterization and properties of oxide scales on hot-rolled strips, Mater. Sci. Eng., A, 2007, vols. 452–453, pp. 189–193. https://doi.org/10.1016/j.msea.2006.10.151CrossRef

11.

Chernov, P.P., Larin, Yu.I., and Polyakov, V.N., Effect of the conditions of coiling and accelerated cooling on the phase composition and properties of rolling oxide scale, Proizvod. Prokata, 2001, no. 12, pp. 35–38.

12.

Leutina, L.E. and Stepanov, G.V., Improvement of the efficiency of water descaler, Metallurgiya, 1984, no. 10, p. 39.

13.

Byukhele, V., Descaling after hot rolling, Chern. Met., 1996, no. 3, pp. 38–40.

14.

Bekker, E.-A., Birkemaier, G., Byukhele, V., Degner, M., Devrient, L., Novak, G., and Timan, M., Application of optimized nozzles for water descaling on a wide-strip mill of hot rolling of Thyssen Krupp Stahl AG, Chern. Metall., 2000, no. 7, pp. 42–46.

15.

Berdichevskii, Yu.E., et al., Choice of rational parameters of water descaling systems taking into account the oxide scale properties on the surface of rolled products, Trudy Shkoly-seminara Fazovye i strukturnye prevrashcheniya v stalyakh (Proc. Workshop on Phase and Structural Transformations in Steels, Magnitogorsk, 2002), Magnitogorsk: Magnitogorsk. Dom Pechati, vol. 3, pp. 536–545.

16.

Dema, R.R., Kuvshinov, D.A., Amirov, R.N., and Stepanishchev, A.E., Development and implementation of hydraulic removal (hydraulic suppression) of secondary scale on finishing hot-rolling mill stands. Part 1. Theoretical substantiation of the problem of scale formation at the section of finishing hot-rolling mill stands, Proizvod. Prokata, 2015, no. 8, pp. 7–11.

17.

Dema, R.R., Kuvshinov, D.A., Amirov, R.N., and Gataulina, Yu.Kh., Development and implementation of hydraulic removal (hydraulic suppression) of secondary scale on finishing hot-rolling mill stands. Part 2. Mathematical modeling of the temperature mode of rolling for determining the operation conditions of water descaling system, Proizvod. Prokata, 2015, no. 9, pp. 3–9.

18.

Dema, R.R., Kuvshinov, D.A., Amirov, R.N., Nefed’ev, S.P., and Tyuteryakov, N.Sh., Development and implementation of hydraulic removal (hydraulic suppression) of secondary scale on finishing hot-rolling mill stands. Part 3. Development and design of the water descaling system in finishing hot-rolling mill stands of sheet metal, Proizvod. Prokata, 2015, no. 10, pp. 27–33.

19.

Dema, R.R., Kuvshinov, D.A., Amirov, R.N., Kharchenko, M.V., Nefed’ev, S.P., Tyuteryakov, N.Sh., and Nefedova, E.V., Development and implementation of hydraulic removal (hydraulic suppression) of secondary scale on finishing hot-rolling mill stands. Part 4. Experimental and theoretical study of the problem of oxide scale formation at the finishing hot-rolling mill stands to reduce the environmental impact and impact on the staff, Proizvod. Prokata, 2016, no. 2, pp. 3–9.

20.

Dubina, O.V., Lebedev, A.N., and Manshilin, A.G., On the choice of rational heating mode of ingots for rolling, Nauka Proizvodstvu. Sbornik statei (Science for Insdustry: Collection of Papers), 2003, p. 120.

21.

Platov, S.I., Kandaurov, L.E., Zhelezkov, O.S., Terent’ev, D.V., and Mironenkov, E.I., Improvement of reliability and longevity of elements and units of metallurgical equipment, Vestn. Magnitogorskogo Gos. Tekh. Univ. G.I. Nosova, 2009, no. 2.

22.

Platov, S.I., Ogarkov, N.N., Terent’ev, D.V., Zhelezkov, O.S., Rubanik, V.V., and Vassal, Zh.P., Development of the theory and technology of designing machinery, aggregates, and tools in metal forming and cutting, Vestn. Magnitogorskogo Gos. Tekh. Univ. G.I. Nosova, 2014, no. 1.

23.

Berdichevskii, Yu.E. et al., Choice of rational parameters of descaling systems taking into account the properties of scale on the surface of rolled products, Trudy shkoly-seminara “Fazovye i strukturnye prevrashcheniya v stalyakh” (Proceedings of the School-Seminar “Phase and Structural Transformations in Steels) (Magnitogorsk, 2002), Magnitogorsk: Magnitogorskii Dom Pechati, 2003, no. 3, pp. 536–545.

24.

Chernov, P.P., Larin, Yu.I., and Polyakov, V.N., Influence of winding conditions and accelerated cooling on the phase composition and properties of mill scale, Proizvodstvo Prokata, 2001, no. 12, pp. 35–38.

25.

Dobronravov, A.I. and Karpov, E.V., Klassifikator defektov poverkhnosti goryachekatannogo ploskogo stal’nogo prokata (Glossary of Surface Defects of Hot-Rolled Sheet Steel Products), Magnitogorsk: TsPK Personal, Magnitogorsk. Metall. Kombinat, 2002.

Titel: Improvement of Hot Rolling Technology to Reduce the “Rolled-in Scale” Defect
verfasst von: S. I. Platov
R. R. Dyoma
O. R. Latypov
V. S. Banshchikov
V. A. Mustafin
M. V. Kharchenko
N. Sh. Tyuteryakov
Publikationsdatum: 01.04.2023
Verlag: Pleiades Publishing
Erschienen in: Steel in Translation / Ausgabe 4/2023
Print ISSN: 0967-0912
Elektronische ISSN: 1935-0988
DOI: https://doi.org/10.3103/S0967091223040150

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