This invention relates to the casting of steel strip. It has particular application to continuous casting of thin steel strip in a twin roll caster.
In twin roll casting, molten metal is introduced between a pair of counter-rotated horizontal casting rolls, which are cooled so that metal shells solidify on the moving roll surfaces, and are brought together at the nip between them to produce a solidified strip product delivered downwardly from the nip. The term “nip” is used herein to refer to the general region at which the rolls are closest together. The molten metal may be poured from a ladle into a smaller vessel from which it flows through a metal delivery nozzle located above the nip forming a casting pool of molten metal supported on the casting surfaces of the rolls immediately above the nip and extending along the length of the nip. This casting pool is usually confined between side plates or dams held in sliding engagement with end surfaces of the rolls so as to dam the two ends of the casting pool against outflow.
When casting thin steel strip in a twin roll caster, the molten steel in the casting pool will generally be at a temperature of the order of 1500° C. and above, and therefore high cooling rates are needed over the casting roll surfaces. It is important to achieve a high heat flux and extensive nucleation on initial solidification of the steel on the casting surfaces to form the metal shells. U.S. Pat. No. 5,720,336 describes how the heat flux on initial solidification can be increased by adjusting the steel melt chemistry so that a substantial proportion of the metal oxides formed as deoxidation products are liquid at the initial solidification temperature so as to form a substantially liquid layer at the interface between the molten metal and the casting surface. As disclosed in U.S. Pat. Nos. 5,934,359 and 6,059,014 and International Application PCT/AU99/00641, nucleation of the steel on initial solidification can be influenced by the texture of the casting surface. In particular International Application PCT/AU99/00641 discloses that a random texture of peaks and troughs can enhance initial solidification by providing potential nucleation sites distributed throughout the casting surfaces. We have now determined that nucleation is also dependent on the presence of oxide inclusions in the steel melt and that, surprisingly, it is not advantageous in twin roll strip casting to cast with “clean” steel in which the number of inclusions formed during deoxidation has been minimized in the molten steel prior to casting.
Steel for continuous casting is subjected to deoxidation treatment in the ladle prior to pouring. In twin roll casting, the steel is generally subjected to silicon manganese ladle deoxidation. However, it is possible to use aluminum deoxidation with calcium addition to control the formation of solid Al2O3 inclusions that can clog the fine metal flow passages in the metal delivery system through which molten metal is delivered to the casting pool. It has hitherto been thought desirable to aim for optimum steel cleanliness by ladle treatment and minimize the total oxygen level in the molten steel. However we have now determined that lowering the steel oxygen level reduces the volume of inclusions, and if the total oxygen content and free oxygen content of the steel are reduced below certain levels the nature of the intimate contact between the steel and roll surfaces can be adversely effected to the extent that there is insufficient nucleation to generate rapid initial solidification and high heat flux. Molten steel is trimmed by deoxidation in the ladle such that the total oxygen and free oxygen contents fall within ranges which ensure satisfactory solidification on the casting rolls and production of a satisfactory strip product. The molten steel contains a distribution of oxide inclusions (typically MnO, CaO, SiO2 and/or Al2O3) sufficient to provide an adequate density of nucleation sites on the roll surfaces for initial and continued solidification and the resulting strip product exhibits a characteristic distribution of solidified inclusions and surface characteristics.
There is provided a method of casting steel strip comprising:
assembling a pair of cooled casting rolls having a nip between them and confining closures adjacent the ends of the nip;
introducing molten low carbon steel between said pair of casting rolls to form a casting pool between the casting rolls with said closures confining the pool adjacent the ends of the nip, with the molten steel having a total oxygen content in the casting pool of at least 70 ppm, usually less than 250 ppm, and a free-oxygen content of between 20 and 60 ppm;
counter rotating the casting rolls and solidifying the molten steel to form metal shells on the casting rolls with levels of oxide inclusions reflected by the total oxygen content of the molten steel to promote the formation of thin steel strip; and forming solidified thin steel strip through the nip between the casting rolls to produce a solidified steel strip delivered downwardly from the nip.
There is also provided a method of casting steel strip comprising:
assembling a pair of cooled casting rolls having a nip between them and confining closures adjacent the ends of the nip;
introducing molten low carbon steel between said pair of casting rolls to form a casting pool between the casting rolls with said closures confining the pool adjacent the ends of the nip, with the molten steel having a total oxygen content in the casting pool of at least 100 ppm, usually less than 250 ppm, and a free-oxygen content between 30 and 50 ppm;
counter rotating the casting rolls and solidifying the molten steel to form metal shells on the casting rolls with levels of oxide inclusions reflected by the total oxygen content of the molten steel to promote the formation of thin steel strip; and
forming solidified thin steel strip through the nip between the casting rolls to produce a solidified steel strip delivered downwardly from the nip.
The total oxygen content of the molten steel in the casting pool may be about 200 ppm or about 80-150 ppm. The total oxygen content includes free oxygen content between 20 and 60 ppm or between 30 and 50 ppm. The total oxygen content includes, in addition to the free oxygen, the deoxidation inclusions present in the molten steel at the introduction of the molten steel into the casting pool. The free oxygen is formed into solidification inclusions adjacent the surface of the casting rolls during formation of the metal shells and cast strip. These solidification inclusions are liquid inclusions that improve the heat transfer rate between the molten metal and the casting rolls, and in turn promote the formation of the metal shells. The deoxidation inclusions also promote the presence of free oxygen and in turn solidification inclusions, so that the free oxygen content is related to the deoxidation inclusion content.
The low carbon steel may have a carbon content in the range 0.001% to 0.1% by weight, a manganese content in the range 0.01% to 2.0% by weight and a silicon content in the range 0.01% to 10% by weight. The steel may have an aluminum content of the order of 0.01% or less by weight. The aluminum may for example be as little as 0.008% or less by weight. The molten steel may be a silicon/manganese killed steel.
The oxide inclusions are solidification inclusions and deoxidation inclusions. The solidification inclusions are formed during cooling and solidification of the steel in casting, and the deoxidation inclusions are formed during deoxidation of the molten steel before casting. The solidified steel may contain oxide inclusions usually comprised of any one or more of MnO, SiO2 and Al2O3 distributed through the steel at an inclusion density in the range 2 gm/cm3 and 4 gm/cm3.
The molten steel may be refined in a ladle prior to introduction between the casting rolls to form the casting pool by heating a steel charge and slag forming material in the ladle to form molten steel covered by a slag containing silicon, manganese and calcium oxides. The molten steel may be stirred by injecting an inert gas into it to cause desulphurization, and then injecting oxygen, to produce molten steel having the desired total oxygen content of at least 70 ppm, usually less than 250 ppm, and a free oxygen content between 20 and 60 ppm in the casting pool. As described above, the total oxygen content of the molten steel in the casting pool may be at least 100 ppm and the free oxygen content between 30 and 50 ppm. In this regard, we note that the total oxygen and free oxygen contents in the ladle are generally higher than in the casting pool, since both the total oxygen and free oxygen contents of the molten steel are directly related to its temperature, with these oxygen levels reduced with the lowering of the temperature in going from the ladle to the casting pool. The desulphurization may reduce the sulphur content of the molten steel to less than 0.01% by weight.
The thin steel strip produced by continuous twin roll casting as described above has a thickness of less than 5 mm and is formed of a cast steel containing solidified oxide inclusions. The distribution of the inclusions in the cast strip may be such that the surface regions of the strip to a depth of 2 microns from the outer faces contain solidified inclusions to a per unit area density of at least 120 inclusions/mm2.
The solidified steel may be a silicon/manganese killed steel and the oxide inclusions may comprise any one or more of MnO, SiO2 and Al2O3 inclusions. The inclusions typically may range in size between 2 and 12 microns, so that at least a majority of the inclusions are in that size range.
The method described above produces a unique steel high in oxygen content distributed in oxide inclusions. Specifically, the combination of the high oxygen content in the molten steel and the short residence time of the molten steel in the casting pool results in a thin steel strip with improved ductility properties.
In order that the invention may be described in more detail, some illustrative examples will be given with reference to the accompanying drawings in which:
While the invention will be illustrated and described in detail in the drawings and following description, the same is to be considered as illustrative and not restrictive in character, it being understood that one skilled in the art will recognize, and that it is desired to protect, all aspects, changes and modifications that come within the concept of the invention.
We have conducted extensive casting trials on a twin roll caster of the kind fully described in U.S. Pat. Nos. 5,184,668 and 5,277,243 to produce steel strip of the order of 1 mm thick and less. Such casting trials using silicon manganese killed steel have demonstrated that the melting point of oxide inclusions in the molten steel have an effect on the heat fluxes obtained during steel solidification as illustrated in
Liquid inclusions are not produced when their melting points are higher than the steel temperature in the casting pool. Therefore, there is a dramatic reduction in heat transfer rate when the inclusion melting point is greater than approximately 1600° C. With casting trials, we found that with aluminum killed steels, the formation of high melting point alumina inclusions (melting point 2050° C.) could be limited if not avoided by, calcium additions to the composition to provide liquid CaO.Al2O3 inclusions.
The solidification oxide inclusions formed in the solidified metal shells. Therefore, the thin steel strip comprises inclusions formed during cooling and solidification of the steel, as well as deoxidation inclusions formed during refining in the ladle.
The free oxygen level in the steel is reduced dramatically during cooling at the meniscus, resulting in the generation of solidification inclusions near the surface of the strip. These solidification inclusions are formed predominantly of MnO.SiO2 by the following reaction:
Mn+Si+3O=MnO SiO2
The appearance of the solidification inclusions on the strip surface, obtained from an Energy Dispersive Spectroscopy (EDS) map, is shown in
In manganese silicon killed steel, the comparative levels of the solidification inclusions are primarily determined by the Mn and Si levels in the steel.
Deoxidation inclusions are generally generated during deoxidation of the molten steel in the ladle with Al, Si and Mn. Thus, the composition of the oxide inclusions formed during deoxidation is mainly MnO.SiO2.Al2O3 based. These deoxidation inclusions are randomly located in the strip and are coarser than the solidification inclusions near the strip surface formed by reaction of the free oxygen during casting.
The alumina content of the inclusions has a strong effect on the free oxygen level in the steel and can be used to control the free oxygen levels in the melt.
With the introduction of alumina, MnO/SiO2 inclusions are diluted with a subsequent reduction in their activity, which in turn reduces the free oxygen level, as seen from the following reaction:
Mn+Si+3O+Al2O3(Al2O3).MnO.SiO2.
For MnO.SiO2.Al2O3 based inclusions, the effect of inclusion composition on liquidus temperature can be obtained from the ternary phase diagram shown in
Analysis of the oxide inclusions in the thin steel strip has shown that the MnO/SiO2 ratio is typically within 0.6 to 0.8 and for this regime, it was found that alumina content of the oxide inclusions had the strongest effect on the melting point (liquidus temperature) of the inclusions, as shown in
With initial trial work, we determined that it is important for casting in accordance with the present invention to have the solidification and deoxidation inclusions such that they are liquid at the initial solidification temperature of the steel and that the molten steel in the casting pool have an oxygen content of at least 100 ppm and free oxygen levels between 30 and 50 ppm to produce metal shells. The levels of oxide inclusions produced by the total oxygen and free oxygen contents of the molten steel promote nucleation and high heat flux during the initial and continued solidification of the steel on the casting roll surfaces. Both solidification and deoxidation inclusions are oxide inclusions and provide nucleation sites and contribute significantly to nucleation during the metal solidification process, but the deoxidation inclusions may be rate controlling in that their concentration can be varied and their concentration affects the concentration of free oxygen present. The deoxidation inclusions are much bigger, typically greater than 4 microns, whereas the solidification inclusions are generally less than 2 microns and are MnO.SiO2 based, and have no Al2O3 whereas the deoxidation inclusions also have Al2O3 present as part of the inclusions.
It was found in casting trials using the above M06 grade of silicon/manganese killed steel that if the total oxygen content of the steel was reduced in the ladle refining process to low levels of less than 100 ppm, heat fluxes are reduced and casting is impaired whereas good casting results can be achieved if the total oxygen content is at least above 100 ppm and typically on the order of 200 ppm. As described in more detail below, these oxygen levels in the ladle result in total oxygen levels of at least 70 ppm and free oxygen levels between 20 and 60 ppm in the tundish, and in turn the same or slightly lower oxygen levels in the casting pool. The total oxygen content may be measured by a “Leco” instrument and is controlled by the degree of “rinsing” during ladle treatment, i.e., the amount of argon bubbled through the ladle via a porous plug or top lance, and the duration of the treatment. The total oxygen content was measured by conventional procedures using the LECO TC-436 Nitrogen/Oxygen Determinator described in the TC 436 Nitrogen/Oxygen Determinator Instructional Manual available from LECO (Form No. 200-403, Rev. April 96, Section 7 at pp. 7-1 to 7-4.)
In order to determine whether the enhanced heat fluxes obtained with higher total oxygen contents was due to the availability of oxide inclusions as nucleation sites during casting, casting trials were carried out with steels in which deoxidation in the ladle was carried out with calcium silicide (Ca—Si) and the results compared with casting with the low carbon Si-killed steel known as M06 grades of steel.
The results are set out in the following tables:
Although Mn and Si levels were similar to normal Si-killed grades, the free oxygen level in Ca—Si heats was lower and the oxide inclusions contained more CaO. Heat fluxes in Ca—Si heats were therefore lower despite a lower inclusion melting point (See Table 2).
The free oxygen levels in Ca—Si grades were lower, typically 20 to 30 ppm compared to 40 to 50 ppm with M06 grades. Oxygen is a surface active element and thus reduction in free oxygen level is expected to reduce the wetting between molten steel and the casting rolls and cause a reduction in the heat transfer rate between the metal and the casting rolls. However, from
It can be concluded that lowering the free and total oxygen levels in the steel reduces the volume of inclusions and thus reduces the number of oxide inclusions for initial nucleation and continued formation of solidification inclusions during casting. This has the potential to adversely impact the nature of the initial and continued intimate contact between steel shells and the roll surface. Dip testing work has shown that a nucleation per unit area density of about 120/mm2 is required to generate sufficient heat flux on initial solidification in the upper meniscus region of the casting pool. Dip testing involves advancing a chilled block into a bath of molten steel at such a speed as to closely simulate the conditions of contact at the casting surfaces of a twin roll caster. Steel solidifies onto the chilled block as it moves through the molten bath to produce a layer of solidified steel on the surface of the block. The thickness of this layer can be measured at points throughout its area to map variations in the solidification rate and in turn the effective rate of heat transfer at the various locations. It is thus possible to produce an overall solidification rate as well as total heat flux measurements. It is also possible to examine the microstructure of the strip surface to correlate changes in the solidification microstructure with the changes in observed solidification rates and heat transfer values, and to examine the structures associated with nucleation on initial solidification at the chilled surface. A dip testing apparatus is more fully described in U.S. Pat. No. 5,720,336.
The relationship of the oxygen content of the liquid steel on initial nucleation and heat transfer has been examined using a model described in Appendix 1. This model assumes that all the oxide inclusions are spherical and are uniformly distributed throughout the steel. A surface layer was assumed to be 2 μm and it was assumed that only inclusions present in that surface layer could participate in the nucleation process on initial solidification of the steel. The input to the model was total oxygen content in the steel, inclusion diameter, strip thickness, casting speed, and surface layer thickness. The output was the percentage of inclusions of the total oxygen in the steel required to meet a targeted nucleation per unit area density of 120/mm2.
Following the casting trials, more extensive production has commenced of which the total oxygen and free oxygen levels are reported in
The measurements reported in
These free oxygen and total oxygen levels were measured in the tundish immediately above the casting pool, and although the temperature of the steel in the tundish is higher than in the casting pool, these levels are indicative of the slightly lower total oxygen and free oxygen levels of the molten steel in the casting pool. The measured values of total oxygen and free oxygen from the first samples are reported in
Also, these data show the practice of the invention with high blow (120-180 ppm), low blow (70-90 ppm) and ultra low blow (60-70 ppm) with the oxygen lance in the LMF. Sequence nos. from 1090 to 1130 were done with high blow practice, sequences nos. from 1130 to 1160 were done with low blow practice, and sequence nos. from 1160 to 1220 were done with ultra low blow practice. These data show that total oxygen levels reduced with the lower the blow practices, but that free oxygen levels did not reduce as much. These data show that the best procedure is to blow with ultra low blow practice to conserve oxygen used while providing adequate total oxygen and free oxygen levels to practice the present invention.
As can be seen from these data, the total oxygen is at least about 70 ppm (except for one outlier) and typically below 200 ppm, with the total oxygen level generally between about 80 ppm and 150 ppm. The free oxygen levels were above 25 ppm and generally clustered between about 30 and about 50 ppm, which means the free oxygen content should be between 20 and 60 ppm. Higher levels of free oxygen will cause the oxygen to combine in formation of unwanted slag, and lower levels of free oxygen will result in insufficient formation of solidification inclusions for efficient shell formation and strip casting.
While the invention has been illustrated and described in detail in the drawings and foregoing description, the same is to be considered as illustrative and not restrictive in character, it being understood that only the preferred embodiments have been shown and described and that all changes and modifications that come within the spirit of the invention are desired to be protected.
a. List of symbols
b. Equations
mi=(Ot×ms×0.001)/0.42 (1)
This application is a divisional application of Ser. No. 10/761,953 filed Jan. 21, 2004, now U.S. Pat. No. 7,048,033, which is a continuation-in-part application of application Ser. No. 10/243,699, filed Sep. 13, 2002, now abandoned, which claims priority to and the benefit of U.S. Provisional Patent Application No. 60/322,261, filed Sep. 14, 2001, the disclosures of which are expressly incorporated herein by reference.
Number | Date | Country | |
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60322261 | Sep 2001 | US |
Number | Date | Country | |
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Parent | 10761953 | Jan 2004 | US |
Child | 11419684 | May 2006 | US |
Number | Date | Country | |
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Parent | 10243699 | Sep 2002 | US |
Child | 10761953 | Jan 2004 | US |