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Abstract

The industrial trials of N₂ injection and nitrogen-containing alloy addition for increasing the nitrogen content in molten steel were carried out on a 300 t ladle Ruhrstahl–Heraeus (RH) treatment. The effects of the order of N₂ injection and alloy addition, as well as vacuum chamber pressure on the nitrogen dissolution rate of the molten steel were investigated. A nitrogen dissolution model for N₂ injection of RH was established and the predicted result was in good agreement with the measured. The equilibrium [N] contents corresponding to pressure of 7.5–8.5 kPa, 3.0–4.0 kPa and <0.1 kPa were 160–170 ppm, 110–130 ppm and 90–100 ppm, respectively. The [N] content increase rate was slow with only N₂ injection, and the [N] content was not further increased after reaching the equilibrium. The [N] content increase rate was fast with nitrogen-containing alloy addition, while the [N] content rapidly rised to a supersaturation state if the amount of nitrogen brought in by the alloy exceeded the nitrogen equilibrium. Thereafter, the [N] content decreased to near the equilibrium value. The nitrogen-containing alloy addition led to a deterioration of the cleanliness of molten steel, and the earlier addition of alloys had more time to remove the inclusions and to reduce the T.O content.

Keywords

Steel containing nitrogen RH refining nitrogen-containing alloy cleanliness

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References

Zhao

Yang

Barati

, et al. Strategies for nitrogen control during the production of interstitial-free steel. Ironmak Steelmak 2018; 45: 485.

Wang

, et al. Vacuum denitrification and nitrogen absorption of molten steel under ultra-low nitrogen conditions. Mater Sci Technol 2019; 35: 240.

Zhou

Qin

Zhang

, et al. Behaviors of denitrogenation in RH-MFB. J Iron Steel Res Int 2013; 20: 40.

Mukherjee

Shukla

Senk

. Prediction of decarburisation process along with hydrogen and nitrogen removal by mathematical modelling of RH degassing process. Ironmak Steelmak 2018; 45: 412.

Zhan

Wang

Huang

, et al. Effect of slag compositions on change behavior of nitrogen in molten steel. Metals 2022; 12: 846.

Shchennikova

Zalazinskii

Gel’chinskii

. Thermodynamic simulation of nitrogen dispersion of alloyed iron-carbon melts. Russ Metall 2014; 8: 618. doi:https://doi.org/10.1134/S0036029514080126

Feng

, et al. Formation mechanism of AlN inclusion in high-nitrogen stainless bearing steels. Metall Mater Trans B 2021; 52: 2210.

Zheng

, et al. Effects of nitrogen content on pitting corrosion resistance of non‑magnetic drill collar steel. J Iron Steel Res Int 2020; 27: 1466. doi:https://doi.org/10.1007/s42243-020-00428-7

Dai

Feng

Jiang

, et al. Nitrogen significantly enhances corrosion resistance of 316L stainless steel in thiosulfate-chloride solution. Corros Sci 2020; 174: 108792.

10.

Shen

Chen

Umeda

, et al. Advanced mechanical properties of a powder metallurgy Ti-Al-N alloy doped with ultrahigh nitrogen concentration. JOM 2018; 70: 626.

11.

Berns

. High nitrogen steels. Manufacture and application of high nitrogen steels. ISIJ Int 1996; 36: 909.

12.

Yamasaki

Mitsuhara

Nakashima

. Development of high-chromium ferritic heat-resistant steels with high nitrogen content. ISIJ Int 2018, 58, 1146.

13.

Feng

Xia

, et al. A Promising pressurized duplex manufacturing route of high nitrogen stainless steel. Steel Res Int 2023; 94: 2200321.

14.

Tong

Liu

Jie

. Preparation of high-nitrogen ductile iron by injecting nitrogen gas in molten iron. Materials 2020; 13: 2508.

15.

Riipi

Fabritius

Heikkinen

. Behavior of nitrogen during AOD process. ISIJ Int 2009; 49: 1468.

16.

Zhao

Wang

, et al. Investigation of V–N micro-alloying using nitrogen bottom blowing. Trans Indian Inst Met 2020; 73: 2693.

17.

Zhu

, et al. Quality and complex performance of deformed steel bars by the whole process bottom blowing nitrogen of BOF. Iron and Steel 2012; 47: 39. doi:https://doi.org/10.1016/S1006-706X(12)60085-5

18.

Wang

. Study on nitrogen increasing by mixed blowing process of nitrogen and oxygen. Tianjin Metallurgy 2018; 3: 14.

19.

Cao

Zhang

Zhou

, et al. Analysis on nitrogen absorption of new nickel-free high nitrogen stainless steel. J Iron Steel Res 2013; 25: 16.

20.

Zhao

. Adding nitrogen process by alloy for melting nitrogenous stainless steels in vacuum induction furnace. Special Steel 2008; 29: 43.

21.

Chen

Qiao

Jiang

, et al. Application study to increase nitrogen in steel by Si-Mn-N alloy. Ferro-alloys 2009; 40: 43.

22.

Dong

Liu

, et al. Mechanism and model of nitrogen absorption of molten steel during N2 injection process in RH vacuum. Metall Mater Trans B 2024; 55: 72.

23.

Hideki

Hirokazu

Kazuki

, et al. Effects of O, Se, and Te on the rate of nitrogen dissolution in molten iron. Metall Mater Trans B 1996; 27: 848. doi:https://doi.org/10.1007/BF02915614

24.

Lee

Morita

. Interfacial kinetics of nitrogen with molten iron containing sulfur. ISIJ Int 2003; 43: 14.

25.

Saito

Yoshizawa

Soma

. Gas-phase mass transfer by impinging jet on liquid surface in crucible. Tetsu-to-Hagane 1984; 70: 58.

26.

Tang

Pistorius

. Kinetics of nitrogen removal from liquid third generation advanced high-strength steel by tank degassing. Metall Mater Trans B 2022; 53: 1383.

27.

Yin

Souronis

Roy

, et al. The 6th international congress on the science and technology of steelmaking, 2015, 1016.

28.

Chu

Fang

, et al. Effect of nitrogen on the microstructure and strengthening mechanism of high performance tinplate. JMR&T 2024; 33: 4685.

Effect of nitrogen-containing alloy and N 2 injection on nitrogen absorption and cleanliness of molten steel in RH vacuum

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