EP1960136A1

EP1960136A1 - Method for the continuous casting of thin metal strip and continuous casting installation

Info

Publication number: EP1960136A1
Application number: EP06829136A
Authority: EP
Inventors: Wolfgang Hennig; Holger Beyer-Steinhauer; Chirstian Bilgen
Original assignee: SMS Demag AG
Current assignee: SMS Siemag AG
Priority date: 2005-12-14
Filing date: 2006-11-27
Publication date: 2008-08-27
Also published as: AU2006326711A1; CN101330996A; JP2009519134A; BRPI0619864A2; ZA200804269B; RU2383411C2; RU2008122474A; US20090199391A1; TW200732061A; AR057241A1; CA2631800A1; AU2006326711B2; WO2007068338A1; DE102005059692A1; US8186422B2; EG25046A; KR20080078650A; UA92049C2; AU2006326711A2

Abstract

The invention relates to a method for the continuous casting of thin metal strip (1) in a continuous casting installation (2), in which method metal leaves a die (3) vertically downwards, wherein the metal strip (1) is bent out from the vertical direction (V) into the horizontal direction (H) and wherein the metal strip (1) is supported and/or conveyed and/or plastically deformed by means of a number of pairs of driving rollers (4, 5, 6, 7, 8, 9, 10). In order to avoid a drop in quality, in particular when changing the casting parameters, it is provided according to the invention that at least one pair of driving rollers (8, 9, 10) plastically deforms the metal strip (1) without significantly changing the average thickness (d) of the metal strip (1). Furthermore, the invention relates to a continuous casting installation, in particular for carrying out this method.

Description

Process for continuous casting of thin metal strips and continuous casting plant

The invention relates to a method for continuously casting thin metal strips in a continuous casting plant, in which metal emerges from a mold vertically downwards, wherein the metal strip is bent from the vertical direction in the horizontal direction and wherein the metal strip is supported and / or conveyed by means of a number of drive roller pairs and / or plastically deformed. Furthermore, the invention relates to a continuous casting plant, in particular for carrying out this method.

A generic method is known from EP 1 071 529 B1 and from WO 2004/065030 A1. In the continuous casting of thin metal strips, liquid metal is supplied from above to a mold, from which the preformed metal strip with a still liquid core emerges vertically downwards. The tape cools in the direction of promotion and solidifies; it is gradually bent from the vertical direction to the horizontal direction. For this purpose, a number of pairs of driver rollers are available to support and promote the metal strip. It can also be provided that the driver roller pairs make a pre-deformation of the metal strip, d. H. the metal band is reduced in thickness. Subsequently, d. H. After passing the pairs of driver rollers, the belt passes into a downstream rolling mill, where the belt is further rolled out.

The term "CSP" refers to a combined casting and rolling process for thin slabs, the thickness of which is usually between 45 and 70 mm, sometimes up to 90 mm, and the requirements for the dimensional accuracy of the geometry and the mechanical properties of the finished hot strip are constantly increasing At the same time, the market demands for hot strip with the lowest possible final thickness increase as well.The thinner the hot strip is to be rolled in the finishing mill, the more difficult it is to control the rolling process Demands on the control and positioning systems in the finishing train increase significantly at final thicknesses below 1.5 mm.

A significant influence on the stability of the rolling process has the incoming in the finishing mill slab geometry, in particular the profile and the wedging of the thin slab over the width of the metal strip and their uniformity over the slab length arrives. Sudden changes in the profile or the wedge over the length lead to sudden changes in the flatness state within the finishing train and thus to instabilities in rolling, which in unfavorable case can result in a so-called "high-altitude" with loss of production (casting demolition) immediate quality-determining result of the casting process. According to the prior art, it is only possible to achieve a certain thickness reduction in the area of the pairs of driver rolls by the rolling process between the driver rolls.

According to the state of the art, CSP casting machines are equipped with a "Liquid Core Reduction" (LCD) and offer the possibility of changing the wedging of the metal strip or the thin slab via position-controlled hydraulic cylinders The profile of the thin slab results from the rigidity of the segments and The deeper the sump tip is in the caster, the greater the ferrostatic pressure and thus, given a constant segment stiffness, the sag of the segments and the resulting thin slab profile In addition, the slab profile can be negatively influenced by the wear profile of the segmented rollers, which effect can lead to considerable difficulties in the subsequent rolling process ,

In any case, previously used CSP casting machines usually did not have a "Liqud Core Reduction", which means that neither the profile nor the profile can be seen there Tilting of the thin slab could be influenced. The slab geometry in this case depends both on the orientation of the segments to each other as of the segment stiffness and finally on the position of the sump tip. Therefore, the problems to be expected in the rolling mill in casting machines without "Liquid Core Reduction" are correspondingly greater.

In order to achieve reproducible conditions for rolling the metal strip in the rolling mill, so far lacking in the CSP process has an influence, with which the geometry of the thin slab can be improved and kept constant.

The invention is therefore based on the object to provide a method and an associated continuous casting machine, with which or with which it is possible to overcome the disadvantages mentioned. It is therefore to be ensured that optimum conditions for achieving a high-quality metal band are present in the rolling process following the continuous casting apparatus.

The solution of this problem by the invention according to the method is characterized in that at least one driver roller pair plastically transforms the metal strip without significant change in the average thickness of the metal strip.

Preference is given to proceeding so that the at least one driver roller pair at least largely eliminates any existing wedging of the metal strip over its width direction. Alternatively or additionally, it can be provided that the at least one pair of driver rollers generates a desired cross-sectional profile of the metal strip. Furthermore, it is desirable that exclusively or at least substantially a material flow takes place transversely to the conveying direction of the metal band due to the deformation in the pairs of driver rollers. The transformation without significant change in the average thickness takes place with advantage in the conveying direction of the metal strip seen in the last, in the last two or in the last three pairs of driver rollers. Furthermore, this transformation takes place immediately before or after the bending of the metal strip in the horizontal direction. Specifically, it is provided that the deformation takes place without significant change in the average thickness in the pairs of driver rollers immediately prior to forming in a downstream rolling mill in the conveying direction of the metal strip.

By the mentioned transformation of the metal strip without a substantial change in its average thickness, it is to be understood that the average thickness of the metal strip by means of the last, the last two or the last three pairs of drive rolls at the end of the continuous casting plant is less than 5%, preferably less than 3 % is.

The proposed continuous casting plant for the continuous casting of thin metal bands, with a mold from which can emerge vertically down metal, with means for bending the metal strip from the vertical direction in the horizontal direction and with a number of pairs of drive rollers for supporting, conveying and / or plastic deformation of the Metal strip is inventively characterized by at least one pair of drive rollers for plastic deformation of the metal strip without significant change in the average thickness - as explained above.

With the proposed invention, a targeted adjustment of the geometry of a thin slab is possible, which in particular the profile and the Keilig- speed are to be understood.

Changes in the casting parameters, in particular the casting speed, therefore result in no changes in the slab contour as a result. The pair of driver rollers used for this purpose or the last pair of driver rollers seen in the conveying direction can be made stronger in order to provide the explained plastic see transformation without substantial reduction of the thickness of the tape to accomplish.

Thus, constant run-in conditions are achieved in the finishing train, which leads to more stable rolling conditions, especially at critical, d. H. thin ribbons, comes.

In particular, it is possible to improve both the profile and the wedging of a thin slab without permanently changing the thickness and without the surface-near microstructure of the metal strip. The material flow should only take place in the transverse direction, not in the longitudinal direction. Since no reduction in thickness is required and desired, the design of the straightening drivers, for example, in comparison with the known from WO 2004/065030 A1 solution can be done less expensive. Whereas in the cited document a reduction stitch takes place (with a significant decrease in the average thickness of the band), according to the invention only a smoothing pass is carried out which leaves the average thickness of the band largely unchanged but alters the profile of the metal band. The conditions for the subsequent thin strip rolling are thus improved.

In the drawing, an embodiment of the invention is shown. Show it:

Fig. 1 is a schematic representation of a continuous casting in the side view and

Fig. 2 shows schematically the view of a pair of driver rollers, seen in the conveying direction of the metal strip.

FIG. 1 shows a continuous casting plant 2 in which a metal strip 1 is produced. For this purpose, liquid metal is supplied to an oscillating mold 3 from above. The vertically downwards from the mold 3 exiting metal strip. 1 has inside a still liquid core 11, which, viewed in the conveying direction F gradually hardens until the metal strip is completely solid. The Durcherstarrungspunkt 14 is indicated in Fig. 1.

Below the mold 3, the metal strip 1 is first led vertically downwards by means of a vertical strand guide 12, but then gradually deflected into the horizontal H by a number of rollers, of which only a part is shown. As a result, a pouring arc 13 forms.

Although there are still very high temperatures in the metal strip 1 at the solidification point 14, the strip is still so soft that a controlled rolling of the metal strip 1 with pairs of driver rolls 4, 5, 6, 7, 8, 9, 10 is possible. Driver roller pairs are well known as such in the prior art and serve for supporting, conveying and rolling the metal strip 1 until it is transferred to the horizontal H and fed to a rolling mill, not shown, located behind the last pair of drive rollers 10 in the conveying direction F followed.

The proposed idea is basically to provide an actuator after the casting and solidification process of the thin slab, ie the metal strip 1, with which the slab geometry can be influenced. This task is to be taken over by the last driver roller pairs 8, 9, 10 of the continuous casting machine, which are located at the delivery end of the continuous casting machine. These are mostly driver roller pairs that act as straighteners, so align the metal band in a flat state. In the straightener in front of the (not shown) shear of the casting machine rule in the normal case constant and low throughput speeds, and set in the last driver roller pair geometry in terms of profile and wedging is not changed until the entry into the finishing mill. It is provided that the last pair of driver rollers or the last pairs of driver rollers 8, 9, 10 - as viewed in the conveying direction F - is or are designed with respect to the pressures and forces such that only a minimal amount of torque is transmitted Thickness reduction of the slab takes place. This minimum reduction in thickness results in a corresponding material crossflow (material flow transversely to the direction of conveyance F), as a result of which the slab profile and the slab wedging can be set in a targeted manner.

This is illustrated in FIG. There is shown in solid lines - exaggerated and viewed in the direction of the conveying direction F - the cross section of the metal strip 1 outlined. The two rollers 10a and 10b of the last pair of drive rollers 10 acting in the conveying direction F act on the two surfaces of the metal strip 1, which is indicated by the arrows (for reasons of clarity, the rollers 10a, 10b are shown at a distance from the metal strip 1).

The thickness d of the metal strip 1 is not constant over the width, but it is high profile of the metal strip to recognize that is undesirable and adversely affected the subsequent rolling process in the finishing mill. Therefore, the rollers 10a, 10b are adjusted so that, although no appreciable change in the average thickness d of the metal strip 1 results, but an elimination of the excessive profile overshoot, which is shown by the dashed lines. The mean thickness is to be understood as the mean value of all values of the thickness d across the width of the metal strip 1.

It is known in the operation of CSP continuous casting that an ideal in the strand guide segments thin slab profile in the subsequent bending and / or straightening can be changed unfavorably. The most common cause is excessive driver roll wear. Due to the high temperatures on the cast strand, even low driving forces are sufficient to sustainably change the slab geometry. For this reason, the last straightener roller pair 10 is provided as the preferred location for the proposed concept, whereby the last two or the last three pairs of driver rollers 8, 9, 10 can also be provided. In the prior art, however, it is already known, influencing the slab geometry still before the straighteners 8, 9, 10 make. This leads to the disadvantages explained above. The previously known measures provide anyway to achieve an improvement of the surface quality of the thin slab by a deformation of the slab, wherein not the improvement of the dimensional stability is in the foreground.

In order to be able to set a constant profile even with changed input conditions, such as at different slab temperatures, the last driver roller pair 10 (or again the last three pairs of driver roller 8, 9, 10) can be equipped with a roller bending system. Such a bending system can keep constant the deflection of the driver rollers depending on the applied rolling force. Another possibility of deliberate influence is the provision of a hydraulically employed counter-roller, which presses with different forces against the center of the driver roller depending on the deflection. This ensures that the deflection of the driver rollers can be kept constant.

Alternatively or additively, the driver rollers can also have a special profiling (CVC contour), and a sliding system would thus also make it possible to keep the profile of the slab constant and, in particular, to eliminate any possibility of slippage.

In any case, it is advantageous to provide the last driver roller pair 10 or the two or three last pairs of driver rollers 8, 9, 10 with a hydraulic adjustment. This makes it easy to correct an existing wedge. With position-controlled adjustment, a higher force results on the side with the larger thickness due to the higher decrease. The latter may cause some slab saberiness over the length. Here it is to be estimated to what extent such a saberiness can or should subsequently be corrected. Earlier investigations on this subject have shown that a saberiness after the casting machine in the tunnel kiln largely or at least partially equalized. Regarding a possible residual sulliness Where appropriate, it should be examined to what extent this can lead to problems in the rolling mill.

It is advantageous to achieve the largest possible transverse material flow (material flow transversely to the conveying direction F) during the forming in the straightening driver. It is true that the larger the transverse flow, the less the change in length and thus the subsequent saberiness of the slab. With a larger roller diameter of the rollers of the driver roller pair and with higher friction between the slab and roller, the cross flow can be favorably influenced.

Since higher loads, in particular in the last driver roller pair, occur in the proposed directional and shaping unit, increased roller wear is the result. One way to limit this wear is to influence the slab geometry only in critical sequences (thin strip rolling). For all noncritical sequences, the mode of operation would not change in comparison to the prior art.

An additional improvement of the roll wear problem can be achieved by using an online polisher (analogous to the reel driver rolls). By individually engageable segments (for example via a rotary or spiral spring or a pneumatic), the original role contour can be reground steadily. In this way wear edges in the roll contour can be avoided.

As part of a sample calculation for the roll deflection with a "Waikz force" of 1,000 kN, there was a deflection per roll in the middle of the roll of 564 microns. Based on the strip edge of a strand with a casting width of 1,400 mm, the deflection in the middle is about 270 μm. For the entire roller gap, this resulted in a profile of approx. 540 μm. LIST OF REFERENCE NUMBERS

1 metal band

2 continuous casting plant

3 mold

4 driver roller pair

5 driver roller pair

6 driver roller pair

7 driver roller pair

8 driver roller pair

9 driver roller pair

10 driver roller pair

10a roller of the driver roller pair

10b roller of the driver roller pair

11 liquid core

12 vertical strand guide

13 pouring arc

14 solidification point

V vertical direction

H horizontal direction d thickness of the metal strip

F conveying direction

Claims

claims:

1. A method for continuously casting thin metal strips (1) in a continuous casting plant (2), wherein the metal from a mold (3) emerges vertically downwards, wherein the metal strip (1) from the vertical direction (V) in the horizontal direction (H ) and wherein the metal strip (1) by means of a number of pairs of drive rollers (4, 5, 6, 7, 8, 9, 10) is supported and / or conveyed and / or plastically deformed, characterized in that at least one pair of drive rollers (8 , 9, 10) plastically deforms the metal strip (1) without substantially changing the average thickness (d) of the metal strip (1).

2. The method according to claim 1, characterized in that the at least one pair of drive rollers (8, 9, 10) at least substantially eliminates any existing wedging of the metal strip (1) over its width direction.

3. The method according to claim 1 or 2, characterized in that the at least one driver roller pair (8, 9, 10) generates a desired cross-sectional profile of the metal strip (1).

4. The method according to any one of claims 1 to 3, characterized in that by the deformation in the driver roller pairs (8, 9, 10) exclusively a material flow transversely to the conveying direction (F) of the metal strip

(1).

5. The method according to any one of claims 1 to 4, characterized in that the deformation without substantial change in the average thickness (d), in the conveying direction (F) of the metal strip (1) seen in the last (10), in the last two ( 9, 10) or in the last three driver roller pairs (8,

9, 10) takes place.

6. The method according to claim 4 or 5, characterized in that the deformation without substantial change in the average thickness

(D) takes place immediately before or after the bending of the metal strip (1) in the horizontal direction (H).

7. The method according to claim 5 or 6, characterized in that the deformation without substantial change in the average thickness (d) in the pairs of driver rollers (8, 9, 10) immediately before forming in a conveying direction (F) of the metal strip (1) Downstream rolling mill is done.

8. The method according to any one of claims 1 to 7, characterized in that the change in the average thickness (d) of the metal strip (1) by means of the at least one pair of drive rollers (8, 9, 10) less than 5%, preferably less than 3%.

9. Continuous casting plant (2) for the continuous casting of thin metal strips (1), with a mold (3) from the perpendicular down metal can escape, with means (4, 5, 6, 7, 8, 9, 10) for bending the Metal strip (1) from the vertical direction (V) in the horizontal direction (H) and with a number of pairs of drive rollers (4, 5, 6, 7, 8, 9, 10) for supporting, conveying and / or plastic deformation of the metal strip (1), in particular for

Implementation of the method according to one of claims 1 to 8, characterized by at least one driver roller pair (8, 9, 10) for the plastic deformation of the metal strip (1) without substantial change in the mean thickness (d) thereof.