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Metal Science and Metal Physics
Название Methodology for assessing the susceptibility of metal to cracking under various rolling conditions
DOI 10.17580/chm.2023.10.13
Автор A. V. Danilenko, A. V. Muntin, A. A. Khlybov
Информация об авторе

Vyksa Steel Works, Vyksa, Russia

A. V. Danilenko, Сontrol Room Operator, e-mail: zz-top_@mail.ru
A. V. Muntin, Cand. Eng., Dep. Director for Research Activities, e-mail: muntin_av@omk.ru

 

Nizhny Novgorod State Technical University, Nizhny Novgorod, Russia
A. A. Khlybov, Dr. Eng., Prof., Head of the Dept. of Materials Science, Materials Technologies and Heat Treatment of Metals, e-mail: hlybov_52@mail.ru

Реферат

Methods for studying the susceptibility of a metal to fracture by testing tensile samples are considered. The method is proposed for assessing the tendency of metal to open defects during rolling, which allows to estimate the probability of metal destruction in the edge zone. The defects under consideration include “overlap” and “longitudinal crack” (formed as a result of distortion of a narrow face), “dents” (formed during compression in the edger stand in the presence of a coarse mesh of fire) and “coarse oscillation marks” (formed during casting). These defects can lead to both longitudinal and transverse cracks in the finished rolled steel. The developed method makes it possible to estimate the probability of metal destruction in each rolling pass, taking into account temperature-strain conditions and the shape of defects. The application of the method is shown using the example of the presence of defects on a narrow face in the form of dents. The critical parameters of rolling and temperature-strain conditions under which metal destruction can occur have been determined. Using the method of mathematical modeling, the possibility of using the tensile method to assess destruction in the near-edge zone of the strip was analyzed.
The research was carried out under financial support of the grant of Russian Scientific Fund No. 19-19-00332-П "Development of the scientifically substantiated approaches as well as hardware and software for monitoring of damages in structural materials using artificial intellect to provide safe operation of technical objects in Arctic regions".

Ключевые слова Defect shape, cracking tendency, limiting deformation, reduction value, rolling start temperature, near-edge zone
Библиографический список

1. Bondarenko A. S. Study of the process of bulging of a narrow face when forming a slab billet on a continuous casting machine. All-Russian Scientific and Practical Conference “Cherepovets Scientific Readings – 2017”. Cherepovets, 2018. pp. 29–30.
2. Nastyushkina A. V., Shevchenko A. A. Review of approaches to eliminating profile distortion on continuously cast slab billets. Nauka i proizvodstvo Urala. 2018. No. 14. pp. 33–35.
3. Naumenko V. V., Muntin A. V., Danilenko A. V., Baranova O. A. Study of the nature of surface defects formation in hot-rolled steel in the near-edge zone. Stal. 2020. No. 1. pp. 40–45.
4. Rudskoy A. I., Kolbasnikov N. G., Toropov S. S. Structure. Plasticity and fracture of steels. Saint Petersburg : SPbPU, 2016. 328 p.
5. Chervonyi A. V., Ringinen D. A., Astafiev D. S., Efron L. I. Study of hot plasticity of pipe microalloyed steels produced in conditions of casting and rolling plant. Problemy chernoy metallurgii i materialovedeniya. 2015. No. 2. pp. 45–47.
6. Matveev M. A., Kolbasnikov N. G., Mishin V. V. et al. Metal failure probability assessment during hot rolling by physical and numerical simulation. Chernye Metally. 2014. No. 4. pp. 55–60.
7. Matveev M. A. Physico-mechanical analysis of reasons for formation of near-edge cracks in hot-rolled sheets of pipe steel: Dissertation ... of Candidate of Engineering Sciences. Saint Petersburg : Peter the Great Saint Petersburg Polytechnic University, 2014. pp. 94–98.
8. Pavlov I. M. Theory of rolling and fundamentals of plastic deformation. Moscow : GONTI, 1938. pp. 46–54.
9. Neuber H. Kerbspannungslehre. Translated from Germany. Moscow : OGIZ, 1947. pp. 185–188.
10. Takashi I., Nobuki Y., Yoshinori Y. Deformation analysis of surface defect on plate rolling. Tetsu-to-Hagane. 2003. Vol. 89. pp. 1142–1149.
11. Ervasti E., Ståhlberg U. Transversal cracks and their behaviour in the hot rolling of steel slabs. Journal of Materials Processing Technology. 2000. Vol. 101. pp. 312–321.
12. Danilenko A.V., Naumenko V.V., Muntin A.V. Study of features of the surface defects transformation in the near-edge zone of hot-rolled coils. Issues of metallurgy and heat treatment in mechanical engineering: collection of abstracts of the All-Russian scientific and technical conference, dedicated to 85th anniversary of the birth of Doctor of Engineering Sciences, professor Arkady Konstantinovich Tikhonov. Moscow, 2021. pp. 44–47.
13. Grudev A. P. Theory of rolling: textbook for universities. Moscow : Metallurgiya, 1988. pp. 82–84.
14. Skudnov V. A., Kochetkov Yu. S., Vorobyov I. A. On the issue of uneven deformation during upsetting (heading). Proizvodstvenno-tekhnicheskiy byulleten "Tekhnologiya aviatsionnogo priboro- i agregatostroeniya". 1972. No. 2. pp. 40–44.
15. Pavlov I. M., Fedosov N. M., Severdenko V. P. et al. Metal Forming. Moscow: Metallurgizdat, 1955. pp. 97–105.
16. Okhrimenko Ya. M., Tyurin V. A. Theory of forging processes: textbook for universities. Moscow : Vysshaya shkola, 1977. pp. 49–52.
17. Tselikov A. I., Tomlenov A. D., Zyuzin V. I., Tretyakov A. V., Nikitin G. S. Theory of rolling: handbook. Moscow : Metallurgiya, 1982. pp. 196–200.
18. Maksimov E. A., Shatalov R. L., Boshamdzhiev N. Sh. Production of flatness strips during rolling. Moscow : Teplotekhnika, 2008. 336 p.
19. Smolentsev A. A., Chikishev D. N. Contact friction in rolling production and determination of the friction coefficient. Modelirovanie i razvitie protsessov OMD. 2019. No. 2 (29). pp. 16–21.
20. Danilenko A. V., Muntin A. V., Naumenko V. V., Makimov V. M. Improvement of the shape of the edger roll groove of the broadband mill roughing group of a casting and rolling plant. Stal. 2021. No. 4. pp. 18–23.

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