Selection of parameters of high-speed thermodeformation of Cr–Ni–Mo steel processing on the basis of imitation modeling

The temperature of the end of finishing stage, cooling rate and coil winding temperature are structure-sensitive parameters for bainite-grade steels in the production of plate less than 10 mm thick. Simulation modeling of high-speed thermo-deformation processing of Cr–Ni–Mo bainitic steel samples has been carried out in order to select the most rational technological modes in continuous hot rolling mills. The influence of strain rate and temperature as well as niobium and vanadium microalloying additives on phase transformations has been investigated.

1. Kong, J., Xie, C., Effect of molybdenum on continuous cooling bainite transformation of low-carbon microalloyed steel, Materials and Design, 2006, V. 27, Is. 10, pp. 1169–1173.

2. Suzuki, T., Ono, Y., Miyamoto, G., Furuhara, T., Effects of Si and Cr on bainite microstructure of medium carbon steels, ISIJ International, 2010, V. 50, Is. 10, pp. 1476–1482.

3. Kim, S.J., Lee, C.G., Lee, T.H., Lee, S., Effects of coiling temperature on microstructure and mechanical properties of high-strength hot-rolled steel plates containing Cu, Cr and Ni, ISIJ International, 2000, V. 40, pp. 692–698.

4. Challa, V.S.A., Zhou, W.H., Misra, R.D.K., O’Malley, R., Jansto, S.G., The effect of Coiling Temperature on the Microstructure and Mechanical Properties of a Niobium-Titanium Microalloyed Steel Processed via Thin Slab Casting, Materials Science and Engineering: A, 2014, No 595, pp. 143– 153.

5. Challa, V.S.A., Misra, R.D.K., O’Malley, R., Jansto, S.G., The Effect of Coiling Temperature on the Mechanical Properties of Ultrahigh-Strength 700 MPa Grade Processed via Thin-Slab Casting, AISTech 2014 Proceedings, pp. 2987–2997.

6. Bernier, N., Bracke, L., Malet, L., Godet, S., Crystallographic reconstruction study of the effects of finish rolling temperature on the variant selection during bainite transformation in C–Mn high-strength steels, Metallurgical and Materials Transactions: A, 2014, No 45, pp. 5937–5955.

7. Jun, H.J., Kang, J.S., Seo, D.H., Kang, K.B., Park, C.G., Effects of deformation and boron on microstructure and continuous cooling transformation in low carbon HSLA steels, Materials Science and Engineering: A, V. 422, 2006, pp. 157–162.

8. Isasti, N., Jorge-Badiola, D., Taheri, M.L., Uranga, P., Phase Transformation Study in Nb–Mo Microalloyed Steels Using Dilatometry and EBSD Quantification, Metallurgical and Materials Transactions, 2013, V. 44А, pp. 3552–3563.

9. Korotovskaya, S.V., Nesterova, E.V., Orlov, V.V., Khlusova, E.I., Vliyanie parametrov plasticheskoi deformatsii na formirovanie ultramelkozernistoi struktury v nizkolegirovannykh beinitnykh stalyakh [The influence of plastic deformation parameters on the formation of an ultrafine-grained structure in low-alloy bainite steels], Voprosy materialovedeniya, 2011, No 1 (56), pp. 100–109.

10. Misra, R.D.K., Nathani, H., Hartmann, J.E., Siciliano, F., Microstructural evolution in a new 770 MPa hot rolled Nb–Ti microalloyed steel, Materials Science and Engineering: A, 2005, No 394, pp. 339–352.

11. Petrov, S.N., Ptashnik, A.V., Ekspress-metod opredeleniya granits byvshego austenitnogo zerna v stalyah beinitno-martensitnogo klassa na osnove kartirovaniya kristallograficheskikh orientirovok prevrashchennoi struktury [Express method for determining the boundaries of the former austenitic grain in steels of the bainite-martensitic class based on mapping the crystallographic orientations of the transformed structure], Metallovedenie i termicheskaya obrabotka metallov, 2019, No 5.

12. Sun, G., Ding, Z., Effects of heating rate and strain rate on phase transformation in micro-grinding, EPJ Web of Conferences, 2019, No 224, pp. 1–5.

13. Dey, I., Ghosh, S.K., Saha, R., Effects of cooling rate and strain rate on phase transformation, microstructure and mechanical behaviour of thermomechanically processed pearlitic steel, Materials research and technology, 2019, No 8 (3), pp. 2685–2698.

14. Urtsev, V.N., Okishev, K.Yu., Mirzaev, D.A., Degtyarev, V.N., Yakovleva, I.L., Kineticheskie zakonomernosti obrazovaniya perlita iz austenita, podvergnutogo deformatsii [Kinetic patterns of formation of perlite from austenite subjected to deformation], Vestnik YuUrGu, 2006, No 10, pp. 90–95.

15. Kaletin, A.Yu., Ryzhkov, A.G., Kaletina, Yu.V., Povyshenie udarnoi vyazkosti kon-struktsionnykh stalei pri obrazovanii beskarbidnogo beinita [Increasing the impact strength of structural steels during the formation of carbide-free bainite], Fizika metallov i metallovedenie, 2015, V. 116, No 1, pp. 114–120.

16. Kaputkina, L.M., Marmulev, A.V., Polyak, E.I, Erman, G., Vliyanie uslovii okhlazhdeniya rulonov na neravnomernost struktury i mekhanicheskikh svoistv goryachekatanykh vysokoprochnykh avtolistovykh stalei [The influence of roll cooling conditions on the unevenness of the structure and mechanical properties of hot-rolled high-strength sheet steels], Metallovedenie i termicheskaya obrabotka metallov, No 12 (690), 2012, pp. 14–18.

17. Kaputkina, L.M., Marmulev, A.V., Shchetinin, I.V., Erman, G., Polyak, E.I., Issledovanie formirovaniya neravnomernosti struktury i svoistv v goryachekatanoi rulonnoi vysokoprochnoi nizkouglerodistoi stali [Investigation of the formation of unevenness of structure and properties in hot-rolled highstrength low-carbon steel], Izvestiya vysshykh uchebnykh zavedenii. Chernaya metallurgiya, 2013, No 9, pp. 4–47.

18. Chashchin, V.V., Kuklev, A.V., Popov. E.S., Slavov, E.S., Reguliruemoe okhlazhdenie polosy v rulone – otvetstvenny etap formirovaniya tonkoi struktury stali [Adjustable cooling of the strip in the roll, a crucial stage in the formation of a thin steel structure], Stal, 2007, No 3, pp. 79–82.

19. Chashchin, V.V., Tekhnologiya reguliruemogo okhlazhdeniya rulonov na transportnom konveyere polosovogo stana goryachei prokatki [Technology of controlled cooling of rolls on the transport conveyor of a strip hot rolling mill], Stal, 2018, No 6, pp. 27–31.

20. Lipukhin, Yu.V., Chashchin, V.V., Pimenov, A.F., et al., Stabilizatsiya mekhanicheskikh svoistv goryachekatanykh polos po dline putem sovershenstvovaniya uslovii ikh okhlazhdeniya v rulonakh [Stabilization of the mechanical properties of hot-rolled strips along the length by improving their cooling conditions in rolls], Bul. NTI: Chernaya metallurgiya, 1983, No 5, pp. 44–45.

21. Chashchin, V.V., Khloponin, V.N., Peshkov, V.A., et al., Uluchshenie kachestva goryachekatanykh polos reguliruemym okhlazhdeniem rulonov [Improving the quality of hot-rolled strips by controlled cooling of rolls], Stal, 1990, No 3, pp. 77–81.

22. Orlov, M.R., Terekhin, A.M., Morozova, L.V., Zhuravleva, P.L., Naprienko, S.A., Issledovanie vliyaniya plasticheskoi deformatsii stali 20Kh3MVF so strukturoi ferrita na mekhanicheskie svoistva i kharakter razrusheniya [Investigation of the effect of plastic deformation of 20Kh3MVF steel with ferrite structure on mechanical properties and fracture pattern], Aviatsionnye materialy i tekhnologii, 2014, No S4, pp. 118–124.

23. Khlusova, E.I., Sych, O.V., Orlov, V.V., Khladostoikie stali. Struktura, svoistva, tekhnologii [Cold-resistant steels. Structure, properties, technologies], Fizika metallov i metallovedenie, 2021, V. 122, No 6, pp. 621–657.