Effect of direct microalloying of boron-containing structural steels on their structure and mechanical properties

In conditions of converter shop of JSC “ArcelorMittal T tau” the authors have developed and implemented the technology of direct microalloying of structural steels with boron. Microalloying was carried out due to 2 boron recovery from the slags of the CaO – SiO₂ – B₂O₃ – MgO – Al₂O₃ system formed in ladle furnaces. The use of the developed technology provided in steels 08KP, 3SP, 3PS and 09G2S boron content of 0.0016 – 0.0050 %, a sufficiently high degree of metal desulfurization 36.8 – 51.7 %, reduction in manganese ferroalloys consumption by 0.3 – 0.6 kg/t of steel, improving the environmental situation by eliminating the use of fluorspar. For 09G2S steel the yield σ_y and tensile σ_t strengths are higher for the experimental metal then for the steel without boron by an average 27 and 24 MPa, respectively. Percentage of elongation of the metal with boron increased by an average 0.2 %. Grain-size index of rolled metal of 08KP steel with a thickness of 2.0 – 2.5 mm, containing 0.001 % of boron and a manganese concentration lowered to 0.18 %, reaches 10.0 in contrast to 9.0 for the heats of the current production. The yield σ_y and tensile σt strengths are on average by 6.0 and 5.0 MPa higher for an experimental metal than for a comparative one. Percentage of elongation δ reaches 36.3 % for the experimental metal unlike 33.3 % for the heats of the current production. Experimental rolled metal of 3PС steel with lower concentration of manganese lowered by 0.02 % and with an average boron content of 0.001 % is characterized by an increased yield strength σ_y , tensile strength σ_t (on average by 2.0 and 9.0 MPa) and percentage of elongation δ reaching in average 21.0 %, and fine-grained structure. Rolled metal of 3SP steel, microalloyed with boron, with a thickness of 4 mm that contains manganese content reduced to 0.43 % is characterized by improved strength properties with preservation of plastic characteristics. The absolute value of the yield σ_y and tensile σ_t strengths of steel are by 4.0 and 2.0 MPa higher than the strength characteristics of steel without boron.

red mud, sintering, residues, sinter pot, sinter burden, microstructural examination, low-alkali red mud, impact resistance, abrasion strength, ferrite bond, silicate bond

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