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Thermodynamic study of non-metallic inclusion formation in SAE 1141 steel

Abstract

The main purpose of this paper is the thermodynamic study of non-metallic inclusion formation in the CC tundish for SAE 1141 steel. The specific purposes are: 1) obtaining inclusions as function of steel composition and casting temperature. 2) establishing steel chemical composition to form less harmful inclusions to the SAE 1141 steel castability. Simulations using the commercial software FactSage and databases were carried out. Results showed both different solid oxides and liquid phase formation in inclusions by varying calcium content in the steel. Thus, it was possible: 1) to determine both the inclusion composition as a function of aluminum and calcium content of SAE 1141 steel. 2) to establish a range of calcium content in which inclusions are formed predominantly by liquid phase. 3) to calculate percentage of liquid and solid phases in inclusions, and oxides composition as well.

SAE 1141 steel; inclusions; calcium treatment; FactSage


Thermodynamic study of non-metallic inclusion formation in SAE 1141 steel

Wagner Viana BielefeldtI; Antônio Cezar Faria VilelaII

IPPGEM - Federal University of Rio Grande do Sul/UFRGS. e-mail: wagner@ct.ufrgs.br

IIDEMET and PPGEM - Federal University of Rio Grande do Sul/UFRGS. e-mail: vilela@ufrgs.br

ABSTRACT

The main purpose of this paper is the thermodynamic study of non-metallic inclusion formation in the CC tundish for SAE 1141 steel. The specific purposes are: 1) obtaining inclusions as function of steel composition and casting temperature. 2) establishing steel chemical composition to form less harmful inclusions to the SAE 1141 steel castability. Simulations using the commercial software FactSage and databases were carried out. Results showed both different solid oxides and liquid phase formation in inclusions by varying calcium content in the steel. Thus, it was possible: 1) to determine both the inclusion composition as a function of aluminum and calcium content of SAE 1141 steel. 2) to establish a range of calcium content in which inclusions are formed predominantly by liquid phase. 3) to calculate percentage of liquid and solid phases in inclusions, and oxides composition as well.

Keywords: SAE 1141 steel, inclusions, calcium treatment, FactSage.

1 INTRODUCTION

Additions of calcium-based alloys are largely employed to control composition, distribution and morphology of remaining non-metallic inclusions in the steel. The greatest benefit of that practice is to minimize clogging occurrence during the continuous casting (CC), that is, to increase heats castability in the steel mill.

Another advantage of inclusions treatment with calcium is to have influence on the control of sulfides morphology. Sims' classification provides three specific types of sulfides which can be found in steels. Among them, type II MnS inclusions are found in steels with both low oxygen and Al content. Such type of inclusion precipitates along primary grain-boundaries during steel solidification. Thus, the primary goal of controlling the morphology of sulfides is to eliminate type II sulfide inclusions by forming (Ca, Mn)S, according to Kiessling [1].

Firstly, addition of Ca modifies oxide inclusions and later, it either forms CaS or converts MnS to (Ca, Mn)S. Inclusions of (Ca, Mn)S precipitate at higher temperatures than those of type II MnS (elongated MnS sulfides), according to Faulring [2].

Inclusions of high melting point, such as Al2O3 and CaS, can work as nucleation sites for MnS making sulfides thinly dispersed in the steel matrix. Yaguchi [3] describes a study performed with a base steel (SAE 1030 - 0.06%S) with large sulfides inclusions concentrated on the as cast product. Formation of sulfide lines in the matrix can be observed in the forged product. In the steel with addition of Ca and Mg, sulfide inclusions became both thin and globular, and thinly dispersed in the forged product, as well.

For the production of special steels (as those intended for automotive industry) quality requirements are above average, whether compared to the most part of commercial steels. According to Kirsch-Racine et al. [4], the present tendency is the production of both aluminum killed and resulfurized steels. The former, to answer clients demand, regarding both grain size and fatigue resistance, and the latter to improve machinability for the production of mechanical components. In this way, such steels are considered critical in relation to their production in steel mill, since contents of some of their elements (Al, S, O, Ca) must be controlled.

Thus, the general purpose of this work is the thermodynamic study of non-metallic inclusions formation in the CC tundish for SAE 1141 steel. Specific purposes are: 1) obtaining phases and compounds formed in inclusions due to chemical composition and CC temperature employed for SAE 1141 steel. 2) establishing conditions of steel chemical composition for producing less harmful inclusions to the SAE 1141 steel castability.

2 MATERIALS AND METHODOLOGY

2.1 Materials

SAE 1141 quality combines both good conformability and machinability in the same steel grade. It is widely employed in forging segments to produce components with both relative complexity and mechanical demand, such as forks and shaft ends for automotive industry, according to Capellari [5] SAE 1141 steel is classified by SAE-AISI as resulfurized carbon steel. The chemical composition used was obtained from a series of industrial heats, as it is showed in Table 1.

2.2 Methodology

Based on previous studies by Bielefeldt et al. [6], thermodynamic simulations were performed with the commercial software FactSage and databases. Simulations were carried out by using both global chemical composition and average temperature of SAE 1141 steel in the CC tundish. The result obtained is the steel composition and non-metallic inclusions (oxides and sulfides) at the temperature of 1,520 ºC, during CC.

Thermodynamic study was performed with the commercial software FactSage 5.5. A general description of the software and databases was carried out by Bale et al [7, 8], as well as current modifications.

The following databases were used, described according to FactSage Database Documentation [9]:

  • Ftoxid - FS50 database was extended and optimized from 2000 to 2003 and divided into FToxid, FTsalt, FThall, FTmisc and Fthelg. Ftoxid database contains data for both stoichiometric solids and liquids, and oxide solutions of 20 elements (as well as for diluted solutions of S, SO

    4, PO

    4, H

    2O/OH, CO

    3, F, Cl, I, in melting slag phase). Among several sub-systems of solutions in Ftoxid, FToxid-SLAGA was used. It contains oxides of Al, As, B, Ca, Co, Cr(II), Cr(III), Cu(I), Fe(II), Fe(III), Ge, K, Mg, Mn, Na, Ni, Pb, Si, Sn, Ti(III), Ti(IV), Zn, Zr + F, Cl, S in diluted solution (<10%). For calculations, the following compounds were taken into consideration: FeO, MnO, SiO

    2, CaO, Al

    2O

    3, NiO, CaS, FeS, MnS, Fe

    2O

    3, CrO, Cr

    2O

    3, NiS.

  • FSStel - Database primarily directed for iron-rich compounds. Among several sub-systems in FSStel, FSstel-FE-L was used. Liquid-iron phase which includes the elements: Al, B, Bi, C, Ca, Ce, Co, Cr, Fe, Mg, Mn, Mo, N, Nb, Ni, O, P, Pb, S, Sb, Si, Te, Ti, V, W, Zn, Zr. For calculations, the following compounds were taken into consideration: Fe, C, Cr, Al, Mn, Ni, P, S, Si, O, AlO, Al2O, CrO, Cr2O, MnO, SiO, FeS, MnS, Ca, CaO, CrS, NiS, CaS.

For calculating liquid windows, both FToxid-SLAGA (for oxides and CaS) and FSstel-FE-L (for steel) solution databases were employed in the FactSage Equilib module.

Before calculating, liquid window boundaries (or area) were determined as follows:

1) By calculating calcium-aluminates saturation line (CaOAl2O3, CaO2Al2O3), considering a minimum of 30 and 35% of CaO in inclusions.

2) By calculating CaS saturation lines: maximum of 5 and 10% of CaS.

Furthermore, a more detailed analysis of liquid window was carried out, taking into account the following reasons:

1) There are few studies on oxide inclusions in resulfurized steels treated with calcium;

2) It could be interesting to establish percentages of both inclusions liquid and solid phases in liquid windows, what could increase knowledge not only on casting, but also on a wider control of phase formation in inclusions;

3) A major fraction of solids in oxide inclusions can help controlling the morphology of manganese sulfides (MnS), mainly to avoid forming elongated sulfides (type II), according to Wakoh [10];

4) As stated by Fuhr et al. [11], according to industrial results, castability problems more evidently occur when solid inclusions proportion is higher than 60-70%.

Considering reasons presented above, a different approach was adopted in order to make possible calculating either the formation or not of solid phases. In this case, besides employing solutions databases, stoichiometric pure solids (FactSage FS50 databases) were used as well, what was not possible with only solutions databases.

3 RESULTS AND DISCUSSION

Figure 1 shows the junction of two approaches described on the methodology:


1) Liquid window calculated for SAE 1141 steel;

2) Curve points from the beginning of liquid phase formation, 40% of liquid phase and 100% of liquid phase.

One can observe in Figure 1 that, from 10 ppm to around 45 ppm of Al, there is a great difference between both formation curves of 35% of CaO and liquid fraction points. From 45 ppm of Al, formation curves of 35 % of CaO and liquid fraction points coincide. Determination of liquid fraction points was obtained from graphics of oxides mass fractions in inclusions x steel Ca content. See Figures 2, 3 and 7 to 9 .







Figures 2, 3 and 7 to 9 show the mass percentage of varied oxides and CaS in inclusions, depending on total calcium content. Each figure takes into consideration a fixed Al content. It is possible to analyze curves of both solid oxides and liquid phase - for selected points - as showed in Figure 1.

In order to understand better how points from Figure 1 were obtained, Table 2 shows a cut from Figure 1, highlighting curve points in 15 ppm of Al, as an example. Values of each selected point were obtained from Figure 2.

Among 10 ppm and little above 20 ppm Al, there are two peaks forming 100% of liquid phase, according to Figures 2 and 3.

Figure 3 regards Al = 21.23 ppm, which is heats average collected in the plant. There are two zones of liquid phase, however, the first one (between 4 and 8 ppm of calcium) is smaller than the second one (initiating in 13 ppm of calcium). In the first zone, heats sampled in the plant are located, and the liquid phase coexists with inclusions of CaO.2Al2O3.

Figure 4 shows a liquid phase composition in mass percentage %. Considering both content of Al = 21.23 ppm and Ototal = 24.5 ppm, and other conditions for SAE 1141 steel. If the first zone is compared to the second one, both an increase of CaO content and a decrease of Al2O3 occur, with increasing of calcium content (from 17.7 ppm of Ca). SiO2 content remains practically constant.

Figure 5 shows both Ca and O contents dissolved in steel as function of total calcium content. Moreover, dissolved Ca contents are multiplied by 100, while oxygen ones, by 10. Figure 6 shows dissolved Al in steel as function of total calcium content. In figures 5 and 6 both Al = 21.23 ppm and Ototal = 24.5 ppm contents and other conditions for SAE 1141 steel were taken into consideration. In these figures - for average total calcium content of 5.7 ppm - values obtained were: O = 11.5 ppm, Ca = 0.085 ppm and Al = 10.6 ppm.

Figure 7 (Al = 30 ppm) shows the only formation of a liquid phase zone (from 14.1 ppm of Ca), coexisting with calcium-silicate inclusions 2CaOAl2O3SiO2 (Gehlenite).

In Figure 8, there is not Gehlenite formation. Liquid phase starts with lower calcium contents. In Figure 9, for Al = 80 ppm, CaOAl2O3 formation occurs; with a new increase of calcium content necessary to form liquid phase.

4 CONCLUSIONS

For SAE 1141 steel conditions, ranging from 10 ppm to around 45 ppm of Al, there is a great difference between formation curves of 35% of CaO, and the points of liquid fraction. However, from 45 ppm of Al, they coincide.

There are two peaks of 100% liquid phase formation, from 10 ppm and little above 20 ppm of Al.

Considering Al = 21.23 ppm, Ototal = 24.5 ppm and average total calcium content of 5.7 ppm, the following values obtained from dissolved elements in steels were: O = 11.5 ppm, Ca = 0.085 ppm and Al = 10.6 ppm.

For Al = 50 ppm, there is not Gehlenite formation, and the liquid phase starts with lower calcium content.

However, for Al = 80 ppm, formation of CaO.Al2O3 occurs, backing to increase the calcium content necessary to form the liquid phase.

Both conditions of chemical composition for obtaining window of liquid inclusions and the influence of aluminum content on forming inclusions for SAE 1141 steel were satisfactorily evaluated.

5 REFERENCES

Data de envio: 30/04/2010

Data de aceite: 25/06/2010

Autor Responsável: Wagner Bielefeldt

  • [1] KIESSLING, R., "Non metallic inclusions in steels: Parts I-IV", London: The Institute of Materials, 1978.
  • [2] FAULRING, G., "Sulphide shape control", Conferência Internacional de Dessulfuração e Controle de Inclusões, Volta Redonda, RJ; Associação Brasileira de Metalurgia e Materiais; pp. 103-109, 28 e 29 de outubro de 1997.
  • [3] YAGUCHI, H., "Technical trend of japanese steel industry - especially the status of free-machining steels", http://akseli.tekes.fi/opencms/opencms/OhjelmaPortaali/ohjelmat/ NewPro/fi/Dokumenttiarkisto/ Viestinta_ja_aktivointi/Seminaarit/Vuosiseminaari_06 /Vuosiseminaari2006_05.Yaguchi.pdf, acessado em 05/01/2009.
  • [4] KIRSCH-RACINE, A., BORNONT-ARZUN, M., CONTENTE, M., "Calcium treatment of medium carbon steel grades for machinability enhancement: from the theory to industrial practice", Revue de Métallurgie-CIT, n. 12, pp. 591-597, 2007.
  • [5] CAPPELLARI, A., "Estudo da formação de trincas internas centrais em barras laminadas em aço SAE 1141", Dissertação de MSc., Engenharia de Minas, Metalurgia e de Materiais - Universidade Federal do Rio Grande do Sul, 137 f., 2006.
  • [6] BIELEFELDT, W.V., VILELA, A.C.F., MORAES, C.A.M., FERNÁNDEZ, P.C., "Computational thermodynamics application on the calcium inclusion treatment of the SAE 8620 steel", Steel Research International, v. 78, n. 12, pp. 857-862, 2007.
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  • [9] FactSage Database Documentation. Parte integrante do programa FactSage versão 5.5 e revisado em 2007.
  • [10] WAKOH, M., SAWAI, T., MIZOGUCHI, S., "Effect of S content on the MnS precipitation in steel with oxide nuclei", ISIJ International, v. 36, n. 8, pp. 1014-1021, 1996.
  • [11] FUHR, F., CICUTTI, C., "Relationship between nozzle deposits and inclusion composition in the continuous casting of steels", Iron and Steelmaker, pp. 53-58, 2003.
  • Publication Dates

    • Publication in this collection
      27 Aug 2010
    • Date of issue
      2010

    History

    • Accepted
      25 June 2010
    • Received
      30 Apr 2010
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