WO2008034502A1 - Method for producing a steel strip - Google Patents

Abstract

The invention relates to a method for producing a strip-cast, low-carbon, partly Mn/Si killed steel strip that is largely free of cracks and surface defects from a steel melt with a sulphur content of between 20 and 300 ppm and an Mn/Si ratio = 3.5, using a strip forming force of between 2 and 50 kN/m.

Description

 Process for producing a steel strip

The invention relates to a method for the continuous production of a steel strip having at least two casting rolls and optionally laterally arranged side plates, wherein in operation between the casting rolls and the side plates, a pouring reservoir can be formed, from which molten steel melt can be applied to the casting rolls.

Background of the Invention In the production of a steel strip from low carbon, Mn / partially killed molten steel, the steel strip produced often has cracks and surface defects using the prior art two-roll casting process, thereby significantly reducing the quality of the steel strip produced.

From WO03024644 and US2005145304 it is known to avoid or at least reduce cracks and surface defects in that the composition of a molten steel is selected such that liquid non-metallic inclusions are formed in the molten steel which remain liquid during the solidification of the steel shell and through the formation of a liquid Films on the surface of the casting rolls allow a homogeneous heat flow and thus a homogeneous cooling effect.

In industrial smelting operation, the MnO / SiO ₂ ratios actually present in a Mn / Si partially stabilized molten steel are often much lower than theoretically calculated for operational reasons. The melting temperature of the non-metallic inclusions of Mn / Si partially annealed steel melts is very sensitive to changes in the steel composition and associated changes in the MnO / SiO ₂ ratio of its own composition. In view of the metallurgical rules for producing the liquid nonmetallic inclusions specified in the prior art, it can therefore not be assumed in the industrial melting operation that each treated ladle has a composition which comprises the Ensures the presence of liquid non-metallic inclusions during the casting process. This can lead to cracks and surface defects.

OBJECT OF THE INVENTION It is the object of the present invention to avoid these known disadvantages of the prior art, and to provide a method for the production of a homogeneous surface of a low-carbon, Mn / Si partially annealed molten steel substantially free of cracks and surface defects. In this process, the tolerance of non-metallic inclusion melting temperature to deviations from a setpoint of the steel composition should be sufficient to ensure the presence of liquid non-metallic inclusions in the casting process in each melted melt in the industrial smelting operation.

Detailed description of the invention

The object of the invention is achieved by a method in which a molten steel with a Mn and Si content in a certain ratio and with a certain sulfur content in normal operation using a certain band forming force (roll separating force, RSF) is processed.

The invention therefore relates to a method for producing a strip-cast low carbon, Mn / Si partially annealed steel strip, wherein a molten steel is fed from a melt reservoir between at least two, with a steel belt moving and cooled casting rolls and solidifies at the casting rolls at least partially to the steel strip, characterized in that the molten steel has a sulfur content between 20 and 300 ppm and a ratio Mn / Si ≥ 3.5 and in normal operation, the band forming force between 2 and 50 kN / m.

Unexpectedly, a steel strip made in this way is largely free of cracks and surface defects and has a homogeneous surface. By low-carbon steel strip is meant a steel strip in which the carbon content is less than 0.1% by weight.

The inventive composition of the molten steel ensures a low melting temperature of the non-metallic inclusions. The low melting temperature causes the non-metallic inclusions in the casting process during the solidification of the steel shell on the casting rolls in the liquid state. By broadening the compositional range in which liquid non-metallic inclusions are present in the multiphase system, the tolerance of the melting temperature of non-metallic inclusions to deviations from a target value of the steel composition increases. This broadened composition range ensures that the molten steel has a composition that guarantees liquid non-metallic inclusions in the casting process, even if the setpoint for a particular steel composition is not exactly met in industrial smelting operations.

In the course of steel preparation, nonmetallic inclusions of an oxidic or sulfidic nature are formed in a molten steel. The main components of non-metallic inclusions in Mn / Si partially annealed steel melts are MnO and SiO ₂ .

By adjusting the sulfur content according to the invention to values between 20 and 300 ppm and the Mn / Si ratio to values ≥ 3.5, it is achieved that the non-metallic inclusions consist mainly of a

Multiphase system with the main components MnO-SiO ₂ -MnS exist. If the proportion of MnS in this multi-phase system is less than 37% by weight MnS, the melting temperature of the multiphase system is lower than the melting temperature of a multiphase system composed of the main components MnO and SiO ₂ . The 3-phase system MnO-SiO ₂ -MnS has a ternary eutectic at approximately 1130 ⁰ C. The modeling of the 3-phase system MnO-Si (VMnS in Figure 1 shows that the liquidus touches the binary edge system MnO-SiO ₂ at its eutectic temperature of 1251 ⁰ C in the elektischer point and in the transition to a 3-phase system with increasing MnS At lower temperatures, the liquidus area has lifted off the edge system and exists only at minimum levels of MnS.

Typical operating points with a simultaneously low melting temperature of the non-metallic inclusions and, in the industrial melting operation, sufficient tolerance of the melting temperature to fluctuations in the MnS content in the inventive composition of the molten steel amount to about 15% by weight MnS.

Simulation of solidification ratios in a strip caster using inert gas, contact time, and superheat immersion tests with molten metal contents of between 150 and 500 ppm resulted in average MnS contents in the liquid nonmetallic inclusions of between 7 and 40 wt%. Higher sulfur contents of Mn / Si partially killed steel melts lead to higher MnS contents of the non-metallic inclusions.

2 shows the influence of the sulfur content of a low-carbon, Mn / semi-stabilized molten steel (0.05 wt% C, 0.7 wt% Mn, 0.2 wt% Si) with a Mn / Si ratio of ≥ 3.5 on the tendency to crack, expressed by the frequency of cracks or by the width of the melting interval of the molten steel, on the composition of non-metallic inclusions, and on the melting temperatures (liquidus temperatures) of the non-metallic inclusions. The measurement data in FIG. 2 were obtained from the immersion experiments mentioned above.

Below a sulfur content of the melt, the corresponding to the ternary eutectic at about 1130 ⁰ C MnS content of non-metallic Inclusions leads, the melting temperature of non-metallic inclusions decreases with increasing sulfur content.

Above a sulfur content of the melt, which leads to a MnS content of the non-metallic inclusions corresponding to the ternary eutectic at about 113O ⁰ C, the melting temperatures of the non-metallic inclusions and the crack frequency increase steeply.

The width of the melting interval increases up to a sulfur content of about 300 ppm and then remains approximately constant.

FIG. 2 shows the opposite behavior of increasing hot cracking tendency and decreasing melting temperature of the nonmetallic inclusions. From FIG. 2, the sulfur content recommended according to the invention, in which sufficiently low melting temperatures of the non-metallic inclusions and at the same time tolerable hot cracking tendency can be achieved, can be deduced. The presence of sulfur in a steel alloy results in the expansion of the 2-phase area solid / liquid, i. the melting interval, the steel alloy while lowering its solidus temperature, whereby the temperature range of the hot cracking formation between Liquid Impenetration Temperature LIT and zero ductility temperature ZDT is extended.

Up to a sulfur content of 300 ppm in the molten steel, the width of the 2-phase region increases approximately linearly up to about 45 ° C. From this sulfur content, the width of the 2-phase region remains approximately constant as a result of MnS precipitation in the course of solidification with increasing sulfur content. These MnS precipitates deposit in solid form on the casting roll surfaces and thereby hinder a homogeneous heat flow or a homogeneous cooling effect, which favors the formation of surface defects and cracks. Rising sulfur content of the molten steel leads to increasing amounts of MnS precipitates and thus to the increase of surface defects and cracks.

Therefore, the maximum sulfur content according to the invention is limited to 300 ppm. At a sulfur content of the molten steel below 20 ppm, lowering the melting temperature of the liquid non-metallic inclusions to multiphase systems of the major components MnO and SiO _{2 is} not large enough to ensure the presence of liquid nonmetallic inclusions in the casting process during the solidification of the steel shell on the casting rolls.

In addition, when the sulfur content is below 20 ppm, the width of the compositional range in which liquid nonmetallic inclusions are present in the multiphase system is not large enough to ensure sufficient tolerance to deviations from a setpoint of the steel composition in industrial smelting operation.

Preferably, the sulfur content is at least 50 ppm, more preferably at least 70 ppm. The upper limit of the sulfur content is preferably 250 ppm, particularly preferably 200 ppm.

The sulfur content of the molten steel can be brought to the desired level by desulphurisation or controlled addition of sulfur or sulfur compounds.

With a Mn / Si ratio of less than 3.5 in the molten steel, no multiphase system of the main components MnO-SiO ₂ -MnS forms with a sufficiently large lowering of the melting temperature of the liquid compared to a multiphase system of the main components MnO and SiO ₂ non-metallic inclusions to values below the melting temperature of the steel mixture. Therefore, the Mn / Si ratio according to the invention must be greater than or equal to 3.5.

The strip forming force is the force with which the casting rolls are pressed against one another during the casting process, normalized to the width of the steel strip. The band forming force has an influence on the presence of cracks and surface defects of a band-cast steel strip. The higher the band forming force, the more temperature inhomogeneities occur in the "kissing point" of the steel shells Such temperature inhomogeneities lead to uneven cooling of the steel strip, which can result in surface cracks In addition, due to high band forming forces, stresses build up in the band-cast steel strip, which also leads to cracks and may cause deteriorated mechanical properties.

The use of a low band forming force avoids such problems and additionally offers the advantage that the mechanical stress of the casting apparatus is lower. However, the choice may be a low one

Bandformkraft adversely affect the stability of the casting process, because at a low band forming force there is a risk that the metal shells solidified on the casting rolls are insufficiently pressed together due to inhomogeneities during solidification and the steel strip tears under its own weight that the steel shells partially or over the entire Stick to the width of the casting roll and that it comes to tears of the steel shell.

In prior art methods, the size of the roller separation force during normal operation is between 5 and 250 kN / m.

According to the invention, the strip forming force is less than 50 kN / m. Since the inventive composition of the molten steel due to ensuring the occurrence of liquid non-metallic inclusions minimizes the formation of inhomogeneities during the solidification of the steel shells, such a low strip forming force can be used without risk to the stability of the casting process.

The crack frequency increases with increasing band forming force. When using strip forming forces above 50 kN / m, the production of a homogeneous, free of cracks and surface defects free surface of the steel strip can not be ensured. According to the invention, the lower limit for the strip forming force is 2 kN / m. Below this value, sufficient stability of the casting process is not guaranteed.

Preferably, the band forming force is at least 5 kN / m. Its upper limit is preferably 30 kN / m.

The given values for the strip forming force refer to the steady-state normal operation of a casting plant, but not to the conditions when starting up the plant or for temporary extraordinary load effects.

According to a further preferred embodiment of the method according to the invention, the non-metallic inclusions of the molten steel have a mass fraction of Al ₂ O ₃ which is less than 45% by weight. The forming multiphase system with the main components MnO-SiO ₂ -MnS-Al ₂ θ ₃ has a melting temperature which is lower than the melting temperature of a multiphase system of the main components MnO and SiO ₂ . Moreover, in the polyphase system having the main components MnO-SiO ₂ -MnS-Al ₂ θ ₃ , the composition range in which liquid non-metallic inclusions exist is wider than that in the multiphase system of the main components MnO and SiO ₂ . The Al ₂ O ₃ content is adjusted by the choice of the starting materials for the preparation of the molten steel or, if appropriate, by the specific addition of Al or Al compounds.

Claims

claims 1) A method for producing a strip-cast low-carbon, Mn / Si- hallowed steel strip, wherein a molten steel from a melt reservoir between at least two, moving with a steel belt and cooled casting rolls is applied and solidifies at the casting rolls at least partially to the steel strip, characterized in that the molten steel has a sulfur content between 20 and 300 ppm and a ratio Mn / Si ≥ 3.5 and in normal operation the band forming force is between 2 and 50 kN / m. 2) Method according to claim 1, characterized in that the molten steel has a sulfur content between 50 and 250 ppm, preferably between 70 and 200 ppm. 3) Method according to one of claims 1 or 2, characterized in that the strip forming force is between 5 and 30 kN / m. 4) Method according to one of claims 1-3, characterized in that the molten steel contains non-metallic inclusions with a mass fraction of Al2O3 of less than 45% by weight.