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Tytuł artykułu

Preventing the development of emergency modes of interlocked electric drives of a rolling mill under the impact loads

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Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
In recent years, due to the tightening of competition in the global market of steel producers, the requirements for the quality of hot-rolled steel have increased. The finishing group of the rolling mill is characterized by a complex structure of mechanical and electrical parts. The operation of electric drive systems of such units is characterized by the interrelation of electromagnetic processes, mechanical phenomena and technological factors. As experimental studies have shown, the quality of the supply voltage is inextricably linked with the impact nature of the loads in the rolling stands of the roughing and finishing groups of the hot rolling mill. A decrease in the supply voltage may be accompanied by the development of emergency modes of synchronous electric drives, leading to a decrease in the quality of the finished product.The paper developed a mathematical model of the power supply system of the rolling mill JSC "ArcelorMittal Temirtau". It is shown that this can lead to loss of synchronism of the synchronous motor. Such a voltage drop has a significant impact on the operation of DC electric drives of the finishing group. Various strategies are proposed to counter the development of emergency situations.
Czasopismo
Rocznik
Strony
art. no. 2023105
Opis fizyczny
Bibliogr. 35 poz., rys., tab.
Twórcy
  • Non-commercial Joint-Stock Company «Karaganda Industrial University», Republic Ave., 30, Karagandy Province, Karaganda region, Temirtau, Kazakhstan
  • Non-commercial Joint-Stock Company «Karaganda Industrial University», Republic Ave., 30, Karagandy Province, Karaganda region, Temirtau, Kazakhstan
  • Non-commercial Joint-Stock Company «Abylkas Saginov Karaganda Technical University», Nursultan Nazarbayev Ave., 56, Karaganda, Kazakhstan
  • Kryvyi Rih National University, Vitaly Matusevich, str, 11, Kryvyi Rih, 50027, Ukraine
  • Ukrainian State University of Science and Technologies, Lazaryan str., 2, Dnipro, 49010, Ukraine
  • Ukrainian State University of Science and Technologies, Lazaryan str., 2, Dnipro, 49010, Ukraine
  • Ukrainian State University of Science and Technologies, Lazaryan str., 2, Dnipro, 49010, Ukraine
Bibliografia
  • 1. Voskaniants AA. Automated control of rolling processes. Moscow State Technical University named after N.E. Bauman. Moscow. MSTU im. N.E. Bauman. 2010.
  • 2. Kornilov GP, Abdulveleev IR, Gazizova OV, Koptsev LA. Power supply at metallurgical iron-and-steel works: features and development Prospects. Metallurgist. 2021;65:783-793. https://doi.org/10.1007/s11015-021-01216-8.
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  • 4. Shpiganovich AA, Fedorov OV, Pushnitsa KA, Churkina EV. Operating features of electric power supply systems at the iron and steel works. Chernye Metally. 2017;5:56-61.
  • 5. Grewal GS, Rajpurohit B.S. Energy management by role of energy-efficient machines and rescheduling of transformer load in steel rolling mill: A case study. Journal of The Institution of Engineers. 2019;3:277-284. https://doi.org/10.1007/s40031-019-00371-6.
  • 6. Yakimov IA, Voronin SS, Maklakova EA, Maklakov AS. Analysis of the impact load causes. Procedia Engineering. International Conference on Industrial Engineering, ICIE Saint-Petersburg; 2017:1839-1842. https://doi.org/10.1016/j.proeng.2017.10.722.
  • 7. Maklakova EA, Gasiyarov VR. Impact load researches for different settings of current regulation loop of electric drive control system of rolling stand. Dynamics of Systems, Mechanisms and Machines. 2016:16602423. https://doi.org/10.1109/Dynamics.2016.7819043.
  • 8. Maklakova EA, Voronin SS, Gasiyarov VR, Maklakov AS. The dynamic torque decrease of the rolling stand electric drive for metal biting. Proceedings of the Researchers in Electrical and Electronic Engineering Conference, 2017:939-942. https://doi.org/10.1109/EIConRus.2017.7910711.
  • 9. Matveev BN. Investigation of the possibility and feasibility of using lubricant during hot rolling of steel strips (According to foreign sources). Chernye Metally. 2018;10:43-47.
  • 10. Gartlib EA, Alimova TO, Gasiyarova OA. Intelligent rolling stand control system using neural network. International Russian Automation Conference. Sochi. 2018. https://doi.org/10.1109/RUSAUTOCON.2018.8501817.
  • 11. Gasiyarov VR, Radionov AA, Karandaev AS, Khramshin VR. Method of limiting the dynamic loads on hot plate mill's mechatronics system. IEEE 10th International Conference on Mechanical and Intelligent Manufacturing Technologies, ICMIMT. 2019;43-47. https://doi.org/10.1109/ICMIMT.2019.8712076.
  • 12. Radionov AA, Loginov BM, Odintsov KE, Gasiyarova OA. limitation of dynamic loads of the mechatronic system of the rolling stand. proceedings - 2022. International Conference on Industrial Engineering, Applications and Manufacturing, ICIEAM. 2022:1157-1162. https://doi.org/10.1109/ICIEAM54945.2022.9787233.
  • 13. Formánek I, Farana R. Load torque impact on interstand section control of continual rolling mills. Proceedings of the 2016 17th International Carpathian Control Conference, ICCC. 2016:206–209. https://doi.org/10.1109/CarpathianCC.2016.7501094.
  • 14. Wang Ji-Zhonga, Tong CN, Li Q. Harmonic analyses of power grid in a kind of multi-group AC-DC-AC variable frequency speed-regulating drive system. Journal of University of Science and Technology Beijing. 2014;36(10):1394-1399. https://doi.org/10.13374/j.issn1001-053x.2014.10.017.
  • 15. Kuznetsov V, Nikolenko A. Models of operating asynchronous engines at poor-quality electricity. Eastern-European Journal of Enterprise Technologies. 2015;1(8):37-42. https://doi.org/10.15587/1729-4061.2015.36755.
  • 16. Kuznetsov V, Tryputen N, Kuznetsova Y. Evaluating the effect of electric power quality upon the efficiency of electric power consumption. IEEE 2nd Ukraine Conference on Electrical and Computer Engineering, UKRCON. 2019:556-561. https://doi.org/10.1109/UKRCON.2019.8879841.
  • 17. Kuznetsova Y, Kuznetsov V, Tryputen M, Kuznetsova A, Tryputen M, Babyak M. Development and Verification of Dynamic Electromagnetic Model of Asynchronous Motor Operating in Terms of PoorQuality Electric Power. IEEE International Conference on Modern Electrical and Energy Systems (MEES), 2019:350-353. http://doi.org/10.1109/mees.2019.8896598.
  • 18. Tytiuk VK, Baranovskaya ML, Chornyi OP, Burdilnaya EV, Kuznetsov VV, Bogatyriov KN. Online-identification of electromagnetic parameters of an induction motor (2020) Energetika. Proceedings of CIS Higher Education Institutions and Power Engineering Associations, 63 (5), pp. 423-440. https://doi.org/10.21122/1029-7448-2020-63-5-423- 440.
  • 19. Yuan Y, Wang K, Feng Sh. Traceability of power quality pollution in smelting industry event traceability based on steady state characteristic index. International Conference on Electronic Engineering and Informatics, EEI. 2019:356-360. https://doi.org/10.1109/EEI48997.2019.00084.
  • 20. Siergiejczyk M, Rosinski A, Pas J. Analysis of unintended electromagnetic fields generated by safety system control panels. Diagnostyka. 2016; 17(3):35-40.
  • 21. Sebok M, Kucera M, Korenciak D, Gutten M. Thermal diagnostic systems and their application for analysis of transformer winding. Diagnostyka. 2019;20(2):49-55. https://doi.org/10.29354/diag/105933.
  • 22. Liu Yu-Jen, Hung, Jen-Pan. On real-time simulation for power quality assessment of a power system with multi steel plants. EEEIC 2016 - International Conference on Environment and Electrical Engineering. 2016. https://doi.org/10.1109/EEEIC.2016.7555404.
  • 23. Bednarz SA, Dybkowski M. Induction motor windings faults detection using flux-error based MRAS estimators. Diagnostyka. 2019;20(2):87-96. http://dx.doi.org/10.29354/diag/109092.
  • 24. Zholmagambetova B, Mazakov T, Jomartova S, Izat A, Bibalayev O. Methods of extracting electrocardiograms from electronic signals and images in the Python environment. Diagnostyka. 2020;21(3):95-101. http://dx.doi.org/10.29354/diag/126398.
  • 25. Benguesmia H, M’ziou N, Boubakeur A. Simulation of the potential and electric field distribution on high voltage insulator using the finite element method. Diagnostyka. 2018;19(2):41-52, http://dx.doi.org/10.29354/diag/86414.
  • 26. Theory and technology of rolling production. [Electronic resource] https://ozlib.com/854693/tehnika/teoriya_i_tehnologi ya_prokatnogo_proizvodstva (date of access 13.07.2022).
  • 27. Haifang Wang, Yu Rong, Shengtao Liu and Jinhua Cui. Fieldbus technology and rolling process automation. International Conference On Computer Design and Applications. 2010:V4-73-V4-76, https://doi.org/10.1109/ICCDA.2010.5541484.
  • 28. Khramshin VR, Karandayev AS, Radionov AA, Andryushin IY, Gostev AN. Reducing the dynamic loads of mechanical and electrical equipment of the roughing subgroup of hot rolling mill stands. Engineering: online electronic scientific journal. 2013; 2:69-77. (in Russ.).
  • 29. Gasiyarov VR, Zalogin ОА, Radionov AA. Investigation of energy-power parameters of sheet rolling on a thick-plate mill 5000 of PJRC «MMK». Actual problems of modern science, technology and education. Magnitogorsk: MSTU. 2010;2:73-77. (in Russ.).
  • 30. Radionov AA, Gasiyarov VR, Usatiy DY. Experimental determination of the position of the resultant pressure of the metal on the rolls on the plate mill 5000. Electrical systems and complexes. - Magnitogorsk: MSTU 2010;2:3-6. (in Russ.).
  • 31. Active, reactive and apparent power in the AC circuit. [Electronic resource] https://samelectrik.ru/chtotakoe-aktivnaya-reaktivnaya-i-polnayamoshhnost.html (date of access 13.07.2022).
  • 32. Zagirnyak M, Rod'kin D, Romashykhin I, Romashykhina Z, Nikolenko A, Kuznetsov V. Refined calculation of induction motor equivalent circuit nonlinear parameters by an energy method. EasternEuropean Journal of Enterprise Technologies. 2017;3(5-87):4-10. https://doi.org/10.15587/1729-4061.2017.104146.
  • 33. Romashykhin I, Rudenko N, Kuznetsov V. The possibilities of the energy method for identifying the parameters of induction motor. Proceedings of the International Conference on Modern Electrical and Energy Systems, MEES. 2017:128-131. https://doi.org/10.1109/MEES.2017.8248869.
  • 34. Druzhinin VM. Development of a simulation model for a section of the power supply network of the HPC1 JSC "Arcelor Mittal Temirtau". Proceedings of the International scientific and practical conference "Actual problems of the mining and metallurgical complex of Kazakhstan. "Karaganda: Publishing House of Karaganda State Technical University; 2007: 534.
  • 35. Breido IV, Druzhinin VM. Analysis of the influence of the parameters of the power supply network on the operating modes of the electric drives of the stands of the hot rolling mill 1700 of ArcelorMittal Temirtau JSC. IOP Conference Series: Materials Science and Engineering. 2020: 966. https://doi.org/10.1088/1757- 899X/966/1/012056.
Uwagi
Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-4de178f5-5dce-465d-b4fd-3669ae1d789e
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