EP0166718A2 - Method of and installation for continuous casting of metallic melts - Google Patents

Abstract

1. A method for extruding molten metals, in particular alloys with a relatively high melting point, e.g. steel, wherein the molten metal is conveyed via at least one melt feed line (2), e.g. a duct, from a melt container (1), a pan or the like, to a substantially horizontally arranged chill (4) connected with the container in a fluid-tight manner and preferably fluid-cooled, through an outlet opening of a nozzle block (3), which opening has a smaller cross-sectional area than the chill (4), and the billet is drawn backwards out of the chill (4), preferably stepwise, possibly with a partial step, characterised in that the melt is conveyed substantially tangentially into a substantially horizontal part (8, 10) of the melt feed line (2), thus effecting rotation of the melt around the longitudinal axis (12) of the part (8), and thereafter the rotating melt is conveyed into the chill (4).

Description

The invention relates to a method and an apparatus for the continuous casting of metallic melts, in particular of higher melting alloys, e.g. Stole.

When metal melts, especially alloys, solidify, so-called segregations occur, i.e. different chemical or physical compositions based on the cross-section and, where appropriate, longitudinal section of the solidifying block or strand. In order to prevent such segregations or to keep them lower, it is known both in block and continuous casting to keep the melt in motion in the mold during solidification. Here, the melt can be caused to rotate, for example, by electromagnetic stirring devices around the casting direction or around the longitudinal direction of the mold, or it can cause flows from the outer edge of the mold to the inner edge of the mold. Such flows can be achieved by suitably arranged electromagnetic stirring devices and corresponding controls.

Melt flows beginning in front of the crystallization front can also lead to inhomogeneities or Seiger stripes. These known negative segregations (white bands) greatly affect the quality of the product.

From DE-OS 29 03 234 a method for vertical continuous casting is known, the melt reaching the mold from a melt container via a pouring tube. Around the pouring tube is an electromagnetic stirring device, with which the molten metal can be stirred, so that it already provides a movement which is superimposed on the direction of flow and into which the mold enters.

In the case of horizontal continuous casting, it has already become known to provide an electromagnetic valve in front of the mold in the melt feed line in order to prevent the melt flow.

The present invention aims to provide a method and an apparatus for the horizontal continuous casting of metallic melts, in particular of higher melting alloys, e.g. To create steel in which a particularly high surface quality is achieved, which has the least possible outlay on equipment, and which permits energy-saving operation, and the. Internal quality of the strand increased significantly.

The process according to the invention for the continuous casting of metallic melts, in particular of higher melting alloys, e.g. steel, the metallic melt via at least one melt feed line, e.g. channel, from a melt container, pan, or the like into a substantially horizontally arranged and liquid-tight with it Connected, preferably liquid-cooled mold is fed, and the partially solidified strand from the mold, preferably step by step, optionally with a partial step backwards, consists essentially in that the melt is stirred in the melt feed line, causing the melt to rotate about its direction of flow will, and that already rotating melt is introduced into the mold via a preferably smaller cross-sectional area than the die having the mold. In such a process, the melt already rotates into the mold, so that the boundary layers, i.e. surface layers, which may have notches when the strand is gradually withdrawn, also have a particularly high degree of homogeneity, while at the same time an additional acceleration in the Metal melt flow direction is applied. Another advantage is that there is already a rotational flow of the molten metal at the start of the formation of the strand shell.

If the melt feed line has at least two different cross-sections, the corresponding sections of the melt feed line opening tangentially into one another, then a stirring movement in the melt can be achieved without further energy expenditure and expensive devices.

If the melt feed line has at least two different, adjoining cross-sectional areas, the melt being introduced approximately tangentially, preferably from that section with the smaller cross-sectional area into the one with the larger cross-sectional area, then rotation of the melt about its direction of flow can also be carried out without additional energy, e.g. can be achieved by electromagnets or the like, with the entire metal current being set in motion at the same time.

A particularly homogeneous strand can be obtained if the melt flow rate at each Point of melt feed is kept constant over time.

A particularly low overheating of the melt in the melt container can be maintained if the melt is discharged from an essentially vertically arranged melt feed line from the melt container into an inclined, preferably essentially horizontally arranged, short melt feed line.

A short melt feed line can also be achieved in that the melt flows faster in the substantially vertically arranged melt feed line than in the melt feed line inclined to it and is introduced therein essentially tangentially to the cross section thereof.

A device for the continuous casting of metallic melts, in particular higher melting metals and alloys, e.g. Steel, with a melt container, essentially horizontally arranged, preferably liquid-cooled mold and at least one melt feed line and a strand draw-off device arranged between them, essentially consists in the melt feed line having at least two adjoining sections with different cross sections, viewed in the flow direction of the melt, one section, preferably with the smaller cross-sectional area, opens into the following essentially tangentially.

With such a device, a particularly simple device for horizontal continuous casting is created, at the same time a rotation of the melt entering the mold is achieved, so that surface damage to the strand and also segregation can be kept particularly low.

According to a further feature of the invention, the axes of the melt feed in the area of the diversion are skewed and preferably have a normal distance of 1/2 to 1/6 of the inner diameter of the melt feed with the larger cross-sectional area from one another. According to a further advantageous embodiment of the present invention, the melt feed line in the melt container can be closed with a stopper.

The invention is explained in more detail below with reference to the drawings and examples.

1 shows the schematic representation of a horizontal continuous casting installation in section and FIG. 2 shows the section through a melt feed line.

The melt container 1 according to FIG. 1 has a melt feed line 2 which opens into the liquid-cooled mold 4 via an outlet opening of the nozzle block 3. The smallest free cross-sectional area of the nozzle stone is smaller than that of the mold. The melt feed line protruding from the melt container is fastened to the melt container 1 by means of a clamp 5. The melt supply to the mold can be prevented by lowering the stopper 6. As can be seen from FIG. 1 a, the melt feed line has different cross sections, the section 7 lying first in the direction of flow opening tangentially into the following section 8. In the mouth area, the cross section 7 is essentially slit-shaped.

2 shows a further section through a melt feed line, the section 9 with axis 11 of the melt feed line, which has an essentially circular cross section, opening tangentially into section 10 with axis 12 of the melt feed line, which likewise has a circular cross section. The cross-sectional area of section 9 is approximately 15 cm ² , whereas that of section 10 is 43 cm ² . The normal distance a is approx. 1/4 of the inner diameter d of the melt feed line with the larger cross-sectional area.

For a horizontal continuous casting installation, it is also necessary to provide a continuous take-off, which is not part of the present invention, so that the description thereof can be dispensed with here.

In a pilot plant, iron-based alloys and carbon steels with different compositions were initially cast using the horizontal continuous casting process. The casting cross sections were 0 96 mm and qu. 100 mm. The melt weights were 2.5 and 14 t. The strand material was subjected to extensive quality testing. For this, the examination was carried out in the transverse and longitudinal directions of the strand.

• Rundstränge wiesen ein unterschiedliches Schalenwachstum auf, welches letztlich zu einer polygonalen Querschnittsform führte. weiters waren Kühlspannungsrisse festgestellt worden, wobei sich die Strangfehler mit größer werdender Überhitzung des Stahles häuften. Der Lunker und die Erstarrungsstruktur waren im Strang exzentrisch angeordnet.

The testing of the strands cast according to the prior art yielded the following results:

• Circular strands showed different shell growth, which ultimately led to a polygonal cross-sectional shape. Furthermore, cooling voltage cracks were found, whereby the strand defects increased with increasing overheating of the steel. The blowhole and the solidification structure were arranged eccentrically in the strand.

Through the use of an electromagnetic field, it was possible to find the inside of the strand from approx To crystallize the form and to convert the eccentric blowhole into a core porosity, however, concentrically arranged stripes, negative segregation, the so-called "white bands" emerged.

After installation of the device according to the invention according to FIG. 1 and the possibility of using the method according to the invention, the tests were repeated with the same alloys. Testing the strands cast by the process according to the invention gave the following results:

Example 1:

• C 0,38, Si 0,25, _Mn 0,7, P 0,021, S 0,012, Rest Eisen und Verunreinigungen.

Cast 2.5 t of an alloy with the following composition in% by weight:

• C 0.38, Si 0.25, _M n 0.7, P 0.021, S 0.012, balance iron and impurities.

• Die Querschnittsform der Stränge war kreisrund, die Strangschalenbildung schon in der..Kokille war gleichmäßig. Die Rotation der Schmelze bewirkte, daß auch bei der hohen Stahlüberhitzung keine Kühlspannungsrisse in der oberflächennahen Strangzone auftraten. Die Kristallisationsform war weitgehend globulitisch, die Exzentrizität des Lunkers konnte wesentlich gemindert werden.

The casting speed or average strand withdrawal speed from the mold was 1.4 m / min. The mold had a cross section of 96 mm round. The overheating of the steel at the beginning of the casting was 75 ° C, accordingly the steel temperature in the melt container was 1570 ^o C. The melt feed line had a first section with an inner diameter of 40 mm, which ended tangentially in the second section with an inner diameter of 75 mm. The two cross sections were circular. The normal distance between the axially skewed axes was 17.5 mm. The examination in the transverse and longitudinal directions of the strand gave the following results:

• The cross-sectional shape of the strands was circular, the strand shell formation in the mold was even. The rotation of the melt had the effect that no cooling stress cracks occurred in the strand zone near the surface, even when the steel overheated. The crystallization form was largely globulitic, the eccentricity of the blow hole could be significantly reduced.

Example 2:

In a further experiment, which was carried out with the same steel brand as in Example 1, electromagnetic stirring fields were used after the mold. The examinations of these strands showed that the quality of the strands was significantly increased. Contrary to expectations and previous experience, when using the electromagnetic traveling field after the mold, no Seiger stripes appeared in the strand material. The electromagnetic field brought about a further decisive improvement in the internal strand quality.

An outstanding feature of the strands cast by the process according to the invention was the decisive improvement in the crystallization of the strand zone near the surface and the surface quality. With the same withdrawal parameters, the notches were reduced in such a way that no fragility occurred in the subsequent rolling, even with high degrees of deformation of the strand in the first pass.

Example 3:

• C 0,03, Si 0,65, Mn 1,12, Cr 17,90, Ni 9,02, P 0,022 und S 0,012 Rest Eisen gegossen.

An alloy with the following composition in% by weight was:

• C 0.03, Si 0.65, Mn 1.12, Cr 17.90, Ni 9.02, P 0.022 and S 0.012 balance cast iron.

The casting speed was 1.6 m / min. The casting cross section was qu. 100 mm. The overheating of the alloy at the beginning of the casting was 80 ° C. The steel temperature in the melt container was accordingly 1540 ° C.

The cross-sectional shape of the strands was square, the rotation of the melt causing no cooling stress cracks in the strand, even with high steel overheating occurred. The crystallization form was largely globulitic. The eccentricity of the blow hole could be reduced considerably, while at the same time a significant reduction in the notches on the strand surface could be achieved. Subsequent hot deformations showed no cracks after the first deformation stitch.

Claims (11)

1. Process for the continuous casting of metallic melts, in particular of higher melting alloys, e.g. Steel, wherein the metallic melt via at least one melt feed line (2), e.g. Channel, from a melt container (1), pan or the like. into a, essentially horizontally arranged and liquid-tightly connected, preferably liquid-cooled, mold (4), and the strand is withdrawn from the mold (4), preferably step by step, optionally with a partial step, characterized in that the melt is stirred in the melt feed line (2), causing the melt to rotate about its direction of flow, and the already rotating melt into the mold (4) over a preferably smaller cross-sectional area than the mold (4) having an outlet opening of a nozzle block (3) is initiated. 2. The method according to claim 1, characterized in that the melt feed line (2) has at least two different cross sections, the corresponding sections (7, 8, 9, 10) of the melt feed line (2) opening into one another tangentially. 3. The method according to claim 1 or 2, characterized in that the melt feed line (2) has at least two different, adjacent cross-sectional areas, the melt, preferably from that portion with the smaller cross-sectional area into the tangentially introduced with the larger cross-sectional area. 4. The method according to claim 1, 2 or 3, characterized in that the flow rate of the melt at each point of the melt feed line is kept substantially constant over time. 5. The method according to any one of claims 1 to 4, characterized in that the melt is derived from an essentially vertically arranged melt feed line from the melt container into an inclined, preferably substantially horizontally arranged melt feed line. 6. The method according to any one of claims 1 to 5, characterized in that the melt flows in the, substantially vertically arranged melt feed line faster than in the melt feed line inclined to this and is introduced into this substantially tangential to the cross section of the same. 7. Device for the continuous casting of metallic melts, in particular higher-melting alloys, for example steel, with a melt container (1), essentially horizontally arranged, preferably liquid-cooled, mold (4) and at least one melt feed line arranged between them and a strand withdrawal device, characterized in that that the melt feed line (2) has at least two adjoining sections (7, 8, 9, 10) with different cross sections, the first section (7, 9) in the following (8, 10) essentially seen in the flow direction of the melt opens tangentially. 8. The device according to claim 6, characterized in that the cross-sectional area of the first section (9) is smaller than that of the subsequent section (10). 9. Apparatus according to claim 7 or 8, characterized in that the axes of the melt feed in the region of the deflection of the direction of the melt flow are skewed, and preferably from each other a normal distance (a) of 1/2 to 1/6 of the inner diameter (d) Have melt feed with the larger cross-sectional area. 10. The device according to claim 6, 7 or 8, characterized in that the melt feed line (7) in the melt container (1) with a plug (6) on the inlet opening can be closed. 11. Device according to one of claims 7 to 10, characterized in that the melt feed line (7) has two substantially perpendicular sections, one being connected to the mold and the other to the melt container.

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