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Evaluation of the Effect of Holding the Mandrel in the Extreme Position of the FQM Mill on the Formation of Surface Defects

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Abstract:

Modern continuous mills FQM are high-performance technological units that allow you to get products of a wide range. The paper presents the results of the study of the effect of the time of holding the mandrel in the extreme position of the continuous mill FQM (Fine Quality Mill) on the probability of defect formation of surface defects. The problems of сcomputational simulation of the process of continuous rolling of pipes were set and solved. It is established that the increase in the holding time of the mandrel allows to reduce the sliding of the metal on the surface of the tool, and contributes to a stable process of removing the mandrel without the formation of defects on the inner surface of the draft pipe. The results of solving the problems of сcomputational modeling allowed to formulate technical recommendations aimed at reducing the probability of surface defects in the production of pipes at the FQM mill.

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Periodical:

Solid State Phenomena (Volume 316)

Pages:

375-379

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.316.375

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Online since:

April 2021

Authors:

Vladimir Toporov, Alexander Khalezov, Danis Sh. Nukhov

Keywords:

Cockcroft-Latham Fracture Criterion, Computational Experiment, Computer Modeling, FQM Continuous Mill, Probability of Failure, Production of Seamless Pipes, Shaping, Surface Defects

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References

[1] V.A. Toporov, V.L. Pyatkov, B.G. Pyankov Development of PRU with a continuous FQM mill at the Seversk pipe plant / in the collection: Innovations and import substitution in the pipe industry (Pipes-2016), Proceedings of the XXII International scientific and practical conference. Edited by I. Y. Pyshmintsev. (2016) 16-19.

Google Scholar

[2] S.S. Singh, B.M. Ghodki, T.K. Goswami, Effect of grinding methods on powder quality of king chilli, Journal of Food Measurement and Characterization, 12(3) (2018) 1686-1694.

DOI: 10.1007/s11694-018-9784-6

Google Scholar

[3] V.A. Chanturia, Innovation-based processes of integrated and high-level processing of natural and technogenic minerals, Gornyi Zhurnal, (7) (2015) 29-37.

DOI: 10.17580/gzh.2015.07.05

Google Scholar

[4] N. Teelen, P. Rinaldi, D. Milanese, and others. PQF Technology for the production of seamless steel pipes. Ferrous metals. 4 (2005) 47-52.

Google Scholar

[5] E.A. Shkuratov, A.V. Vydrin, Inprovement of the technology for hollow shell longitudinal rolling in continuous rolling mills. Chernye Metally. (3) (2017) 42-46.

Google Scholar

[6] M.D. Alyutin, V.V. Shirokov, Push Benches and Prospects of Their Application. Metallurgist.62(9-10) (2019) 1062-1067.

DOI: 10.1007/s11015-019-00754-6

Google Scholar

[7] N.A. Glazunova, O.V. Rozhkova, I.A. Kovaleva, Classification by type of prodir, defect on the inner surface of hot-rolled pipes, Casting and metallurgy. 1 (74) (2014) 28-32.

Google Scholar

[8] V.V. Pravosudovich, V.P. Sokurenko, V.N. Danchenko, Defects of steel ingots and rolled products: secondary edition, M.: Intermet Engineering, (2006).

Google Scholar

[9] N.N. Vavilkin, A.V. Krasikov, Investigation of deformation and kinematic parameters of pipe rolling on a continuous mill. Proceedings of higher educational institutions. Ferrous metallurgy. 11 (2009) 22-25.

Google Scholar

[10] O.A. Panasenko, E.A. Shkuratov, O.I. Belov, Improving the axial configuration of the FQM mill equipment based on contactless 3D measurement systems. Metallurgist. 7 (2019) 26-29.

Google Scholar

[11] Technological instruction STZ 004-024-2019.Rolling of seamless pipes in the FQM continuous mill line,. Technological information of polevskaya, (2016).

Google Scholar

[12] Screw rolling of continuously cast billets from structural steel grades: a textbook / A. A. Bogatov, D. A. Pavlov, D. sh. Nukhov; scientific editor G. A. Orlov; Ministry of education and science of the Russian Federation, Ural Federal University named after the first President of Russia B. N. Yeltsin. Yekaterinburg: Ural University Press, (2017).

DOI: 10.15826/umpa.2020.04.035

Google Scholar

[13] Shi, J., Yu, W., Dong, E., Wang, J. Finite element simulation for hot continuous-rolled TC4 alloy seamless pipe, Lecture Notes in Mechanical Engineering. (2018) 705-716.

DOI: 10.1007/978-981-13-0107-0_67

Google Scholar

[14] V.Ya. Osadchy A. P. Golikov; edited by V. Ya. Osadchy, Production and quality of steel pipes: a textbook for universities, Moscow: mgupi publishing House, (2012).

Google Scholar

[15] A.P. Kolikov, B.A, Romantsev, The theory of metal processing by pressure. M.: Ed. Mrs.'s House, (2015).

Google Scholar

[16] N.G. Kolbasnikov, V.V. Mishin, I.A. Shishov, M.A. Matveev, A.M. Korchagin, Surface-crack formation in the manufacture of microalloyed steel pipe, Steel in Translation. 46(9) (2016) 665-670.

DOI: 10.3103/s0967091216090035

Google Scholar

[17] S. Alexandrov, E. Lyamina, P. Date, Design of streamline dies for drawing driven by fracture, Solid State Phenomena. 295 (2019) 85-89.

DOI: 10.4028/www.scientific.net/ssp.295.85

Google Scholar

[18] S.M. Mirghasemi, A.R. Eivani, S.H. Seyedein, H.R. Jafarian, A comparison between routine vs. normalized Cockroft-Latham fracture criteria for prediction of fracture during equal channel angular pressing, Engineering Fracture Mechanics. 199 (2018) 721-279.

DOI: 10.1016/j.engfracmech.2018.07.016

Google Scholar

[19] S. Alexandrov, E. Lyamina, P. Date, Numerical modeling as the method to determine the parameters of tube bending with local induction heating, Solid State Phenomena. 246 (2016) 213-216.

DOI: 10.4028/www.scientific.net/ssp.246.213

Google Scholar

[20] A. Stefanik, P. Szota, S. Mróz, H. Dyja, Slitting criterion for various slitting roll geometry in MSR rolling process, Solid State Phenomena. 165 (2010) 365-370.

DOI: 10.4028/www.scientific.net/ssp.165.365

Google Scholar

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