Microalloying effects on structure-forming processes during hot plastic deformation

The kinetics of austenite grains' growth upon heating has been investigated, and the processes of dynamic and static recrystallization occurring under different modes of plastic deformation (reduction pattern, deformation temperature) of high-strength steels with various microalloying complexes have been studied. The research made it possible to reveal the thermal deformation conditions for the formation of a finely dispersed homogeneous structure of steel. Technological recommendations have been developed for the production of high-strength steels depending on their microalloying (vanadium, niobium).

1. Lavrentiev, A.A., Golosienko, S.A., Ilyin, A.V., Mikhailov, M.S., Motovilina, G.D., Petrov, S.N., Sadkin, K.E., Soprotivlenie khrupkomu razrusheniyu vysokoprochnoy srednelegirovannoy stali i ego svyaz s parametrami strukturnogo sostoyaniya [Resistance to brittle fracture of high-strength medium-alloy steel and its relationship with the parameters of the structural state], Voprosy Materialovedeniya, 2019, No 3 (99), pp. 128-147.

2. Nasibov, A.G., Matrosov, Yu.I., Rudchenko, A.V., Vliyanie vanadiya, niobiya, ugleroda i kremniya na svoystva maloperlitnoy stali [Effect of Vanadium, Niobium, Carbon and Silicon on the Properties of Low-Pearl Steel], Materialovedenie i termicheskaya obrabotka metallov, 1973, No 4, pp. 19-24.

3. Odessky, P.D., Smirnov, L.A. O primenenii vanadiya i niobiya v mikrolegirovannykh stalyakh dlya metallicheskikh konstruktsiy [On the use of vanadium and niobium in microalloyed steels for metal structures], Stal, 2005, No 6, pp. 116-123.

4. Opiela, M., Ozgowicz, W., Effects of Nb, Ti and V on recrystallization kinetics of austenite in microalloyed steels, Journal of Achievements in Materials and Manufacturing Engineering, 2012, No 55/2, pp. 759-771.

5. Glodowski, R.J., Effect of V and N on processing and Properties of HSLA strip steels produced by thin slab casting, 42nd MWSP Conf. Proc. 2000, V. 38, pp. 441-451.

6. Siwecki, T., Sandberg, A., Roberts, W., Lagneborg, R., The influence of processing route and nitrogen content on microstructure development and precipitation hardening in V-microalloyed HSLA steels, Thermomechanical processing of microalloyed austenite, TMS-AIME, Warren-dale, USE, 1982, pp. 163-192.

7. Garcia de Andres, C., Bartolome, M.J., Capdevila, C., San Martin, D., Caballero, F.G., Lopez, V., Metallographic techniques for the determination of the austenite grain size in medium-carbon microalloyed steels, Materials Characterization, 2001, No 46, pp. 389-398.

8. Fernandez, A.I., Uranga, P., Lopez, B., Rodrigues-Ibabe, J.M., Dynamic recrystallization behavior covering a wide austenite grain size range in Nb and Nb-Ti microalloyed steels, Materials Science and Engineering, 2003, No 361, pp. 367-376.

9. Medina, S.F., Hernandez, C.A., General expression of the Zener-Holloman parameter as a function of the chemical composition of low alloy and microalloyed steels, Acta Materialia, 1996, V. 44, No 1, pp. 137-148.

10. Zisman, A.A., Soshina, T.V., Khlusova, E.I., Postroenie i ispolzovanie kart strukturnykh izmeneniy pri goryachey deformatsii austenita nizkouglerodistoy stali 09KhN2MDF dlya optimizatsii promyshlennykh tekhnologiy [Construction and use of maps of structural changes during hot deformation of austenite of low-carbon steel 09KhN2MDF for optimization of industrial technologies], Voprosy Materialovedeniya, 2013, No 1 (73), pp. 37-48.