DOI: 10.52150/2522-9117-2026-40-003

T. М. Golubenko^1,*, Ph. D. (Tech.), ORCID 0000-0002-3583-211X
V. A. Lutsenko¹, D. Sc. (Tech.), Senior Researcher, ORCID 0000-0002-4604-5592
О. V. Lutsenko¹, Ph. D. (Tech.), ORCID 0000-0001-8298-5306
G. I. Sivak¹, Researcher, ORCID 0000-0001-6948-7732

¹ Iron and steel institute of Z.I. Nekrasov of National academy of science of Ukraine
^* Corresponding author: sumer@i.ua

ABOUT INFLUENCE OF THE CLEANLINESS OF THE LOW-CARBON STEEL G3Si1 DURING PRODUCTION OF THE THIN WIRE

Abstract. Non-metallic inclusions play a key role in many important properties of steel, affecting the processing and application of steel products. The production of steel wire requires high purity of steel, since non-metallic inclusions can negatively affect its quality: cause defects, reduce plasticity and reduce the durability of the product. Control of non-metallic inclusions is an important stage in the production of high-quality steel wire. For rod made of alloyed, in particular silicon-manganese steels of the G3Si1 type, the regulatory documentation does not specify the maximum number of non-metallic inclusions that can be in the steel without affecting the technical characteristics. Therefore, the purpose of the study was to determine the number of non-metallic inclusions for steel for welding purposes and their effect on the technical characteristics of the wire. A comparative study of the quality of two batches of silicon-manganese steel G3Si1, which is processed into wire by cold drawing from a diameter of 5.5 mm to 2.0 mm and 0.8 mm, was carried out. The main difficulties in the production of small-diameter wire are associated with increasing the strength and brittleness of the metal during the drawing process in production. The structure of the studied G3Si1 wire rod with a diameter of 5.5 mm consisted of ferrite, pearlite and bainite-martensitic areas. Before drawing to a small (1.2…0.8 mm) diameter, the silicon-manganese steel is subjected to heat treatment – annealing, which reduces the strength due to the passage of spheroidization processes. As a result, the structure of the experimental steel consists of ferrite and granular pearlite. Both batches of wire from G3Si1 steel, produced without breaks and with breaks, have the same granular ferrite-pearlite structure and similar properties. A slight increase in the strength of the wire may be due to a higher manganese content within the regulatory values. Studies have shown that for G3Si1 steel, the presence of an excess of non-metallic inclusions by 0.5…0.8 index units in the initial rod with a diameter of 5.5 mm leads to breaks during further drawing into wire. As a result of deformation, the number of linear non-metallic inclusions in small-diameter wire increases significantly. Therefore, control of inclusions in low-carbon G3Si1 steel is necessary to ensure continuous production.

Keywords: low-carbon steel, non-metallic inclusions, breakability, mechanical properties, structure.

For citation: Golubenko, T. М., Lutsenko, V. A., Lutsenko, О. V., & Sivak, G. I.(2026). About influence of the cleanliness of the low-carbon steel G3Si1 during production of the thin wire. Fundamental and applied problems of ferrous metallurgy, 40, 44-55. https://doi.org/10.52150/2522-9117-2026-40-003

References

1. Parusov, E. V., Sychkov, O. B., Chuyko, I. M., Sahura, L. V., Syvak, A. I., & Holubenko, T. M. (2017). Vplyv khimichnoho skladu stali na utvorennya beynito-martensytnykh dilyanok v strukturi buntovoho prokatu zvaryuvalʹnoho pryznachennya [The influence of the chemical composition of steel on the formation of bainite-martensitic areas in the structure of rolled steel for welding purposes]. Bulletin of the ukrainian material science society of i.m. frantsevich, 10, 60-66.

2. Asati, B., Shajan, N., & Arora, K. S. (2023). Development of high strength welding consumable for arc welding carbon steels. Materials Today: Proceedings. http://doi.org/10.1016/j.matpr.2023.07.007

3. Das, S., Talukdar, S., Kumar, A., & Mukhopadhyay, G. (2020). Metallurgical investigation of welding wire rod grade during processing. Engineering Failure Analysis, 118, 104884. http://doi.org/10.1016/j.engfailanal.2020.104884

4. Wang, Y., Karasev, A., Park, J. H., & Jönsson, P. G. (2021). Non-metallic Inclusions in Different Ferroalloys and Their Effect on the Steel Quality: A Review. Metallurgical and Materials Transactions B, 52, 2892–2925 https://doi.org/10.1007/s11663-021-02259-7

5. Lipiński, T. (2024). Analysis of the Distribution of Non-Metallic Inclusions and Its Impact on the Fatigue Strength Parameters of Carbon Steel Melted in an Electric Furnace. Materials. 17(24), 6151 https://doi.org/10.3390/ma17246151

6. Vasconcellos A. L. da Costa e Silva. (2019). The effects of non-metallic inclusions on properties relevant to the performance of steel in structural and mechanical applications. Journal of Materials Research and Technology. 8(2), 2408-2422 https://doi.org/10.1016/j.jmrt.2019.01.009

7. Vasconcellos A. L. da Costa e Silva. (2018). Non-metallic inclusions in steels – origin and control. Journal of Materials Research and Technology. 7 (3), 283-299 https://doi.org/10.1016/j.jmrt.2018.04.003

8. ISO 16120-4:2017. Non-alloy steel wire rod for conversion to wire – Part 4: Specific requirements for wire rod for special applications. International standard, Switzerland, 11.

Рукопис надійшов до редакції / Received  06.11.2025
Рекомендовано до друку / Accepted  28.05.2026
Опубліковано / Published  30.05.2026