WO2013000841A1 - Method for strand casting a cast strand, and strand casting system - Google Patents

Abstract

The invention relates to a method for strand casting a cast strand (3) from metal, in particular steel. A mold (2) is used in a strand casting system (1), and molten metal can flow out downwards through said mold in a vertical manner in order to be shaped into the cast metal strand (3). The aim of the invention is to be able to cast strands without oscillating means and without casting powder while still being able to produce high-quality cast strands of any dimension. According to the invention, this is achieved in that the molten metal in the mold (2) is guided through two opposing boundaries for the metal, said boundaries being formed by two cooled continuous casting belts (5, 6). The lateral connecting regions between the casting belts (5, 6) are formed by lateral boundaries (12) that move with the casting belts. The cast strand (3) which is shaped by the casting belts (5, 6) and the lateral boundaries (12) and which still has a molten core (14) is conveyed directly below the mold (2) into a strand guide (4) comprising a plurality of strand guide segments. The cast strand (3) is supported by the rollers of the strand guide segments (7, 8) at least until the strand is completely solidified and is preferably deflected from the vertical (V) into the horizontal (H) in the strand guide. The invention further relates to a strand casting system for carrying out the method.

Description

 Method for continuous casting of a cast strand and continuous casting plant

The invention relates to a method for the continuous casting of a cast strand of metal, in particular of steel, in which a mold is used in a continuous casting, is discharged through the molten metal vertically down to be formed into the metallic casting strand. Furthermore, the invention relates to a continuous casting plant.

In a conventional continuous casting usually a mold is used, which is provided with an oscillation device to assist the casting process. Furthermore, casting powder is used to prevent adhesion of the casting strand to the mold. The mold usually has copper plates.

This prior art approach to making a cast strand has certain disadvantages:

The oscillation leaves on the cast strand oscillation marks on the strand surface, which are disturbing.

Furthermore, the use of the casting powder leads to contamination of the cooling water. Furthermore, the casting powder is relatively expensive, which entails corresponding costs. As an alternative to an oscillating mold DE 27 09 540 A1 discloses a mold which has two cooperating chain-like bands which form the wall of the mold. The bands are dimensioned in the direction of the vertical extent of the mold so that after about half the contact length to the bands, the liquid metal is completely solidified. Accordingly, an already completely solidified strand leaves the bands, which indeed offers advantages for the further handling of the strand, which it does however does not allow larger dimensions of the cast strand to be realized since the device disclosed herein does not suggest any possibility of handling a cast strand which is still partially liquid inside. In DE 100 57 876 C1 a mold with circumferential bands is provided in a similar manner, although in the same way already a completely solidified cast strand leaves the bands down. Here, a transition zone is provided, which is designed as a rolling element, in which the cast strand is subjected to a substantial reduction in thickness. Subsequently, the reduced thickness, completely solidified strand is deflected via a Ausförderteil into the horizontal. A similar solution is shown in EP 0 329 639 A1, in which only the completely solidified and reduced-thickness cast strand is bent over by deflection and support rollers in the horizontal. Similar solutions with bands forming the mold walls are shown in WO 96/09130 A1, US 5 964 276 and US 5 967 220.

EP 0 974 413 B1 shows a continuous casting machine which operates with moving belts and has an upper and a lower continuous casting belt. The cast strand is thus deployed in a horizontal direction. A deflection of the casting strand is therefore not necessary and therefore no means provided for this purpose.

Similar solutions are described in EP 0 237 478 A1, in DE-AS 1 253 417, in DE 1 558 259 A1, in DE 1 558 260 A1, in DE 1 758 957 A1 and in FR 1 498 360 A1 disclosed.

Not prepublished prior art forms the German patent application with the application number DE 10 2010 046 292.6. For a better understanding of the invention, some basic concepts from the field of continuous casting are explained in more detail below:

mold

The mold gives the strand the outer shape. It is usually included

Slabs and thin slabs from each of 2 opposite, water-cooled copper plates, the 2 broad sides and the 2 between the broad sides

movable narrow sides.

 In the mold is created by the heat extraction of the copper plates on each

Copper plate a solid strand shell, which together at the exit of the mold a z. B. 1 cm thick shell box form.

Liquid steel is passed through a submerged nozzle (the distributor trough) in the mold, wherein the liquid steel is supplied below the free liquid surface of the mold. This is necessary because the free surface in the mold is covered with casting powder. This casting powder fulfills several functions:

- Forming a lubricating film between solidifying strand shell and the

 copper plates

 - Insulator, which ensures that the copper plates are not overheated

 - Shielding the melt against oxygen and nitrogen in the air

strand guide

Immediately below the mold of a continuous casting plant, the strand for further solidification is supported by pairs of rolls and cooled further until the strand is solidified. These opposing pairs of rollers are referred to as strand guide. segment

 To make the mechanical engineering modular and to make the strand guide for maintenance manageable, the roller pairs of the strand guide are combined to form individual segments. For example, each 7 pairs of rollers in the upper and lower frame of a segment installed and

be clamped together mechanically or by hydraulic cylinders. These segments are then incorporated as a unit in the strand guide or removed from the strand guide. The maintenance of the segments takes place in special

Workshops.

segment carrier

 Segment carriers are often used for receiving and accurately positioning a segment within a strand guide. Segment carriers have bearing surfaces for the individual segments. In addition, to the

 Segment carriers typically have water trays attached (see below) that provide the water and air supplies to the segments.

Primary and secondary cooling

 In continuous casting, a distinction is made between primary and secondary cooling. The primary cooling takes place in the mold, in the copper plates or revolving

Casting strips are cooled with water and thereby heat the steel

withdraw, so that at the output of the mold, a strand shell surrounding the liquid steel has formed inside.

In the strand guide following the mold, the strand shell is supported by the parallel pairs of rolls and cooled further by spraying water from outside under pressure onto the strand shell. This (and by roller contact and radiation) heat is further withdrawn from the strand and the strand shell continues to grow until the strand is completely solidified. Einstoffkühlung / dual fuel cooling

 In the secondary control in continuous casting plants, a distinction is made between single-material cooling and dual-substance cooling. The one-substance cooling is a pure water cooling. In the two-fluid cooling a water-air mixture is swirled by means of a special mixing body and then sprayed by means of nozzles on the slab. The two-fluid cooling produces a finer water mist and with correct metering a higher cooling impulse of the water droplets impinging on the strand.

Soft reduction

 The term soft reduction means compression / welding of upper and lower strand shell in the region of the sump tip, with the result that even liquid material is pressed back against the casting direction in the interior of the strand. A soft reduction is made with the aim of improving the internal quality of the strand, e.g. Segregations are prevented; it is not a reduction in thickness in the true sense.

The present invention has for its object to provide a method for continuous casting and a continuous casting, with which or with which it is possible to dispense both on oscillating means for the mold and on the use of casting powder, wherein it is simultaneously possible in to produce the dimensions largely any casting strands in high quality. Thus, high-quality casting strands of any dimensions can be produced at a favorable cost. The solution of this problem by the invention according to the method is characterized in that the molten metal and / or the solidifying metal is guided in the region of the vertical extent of the mold by two opposing boundaries for the metal, wherein the boundaries are formed by two circumferential, cooled casting belts and wherein the lateral connection areas between the casting belts are formed by running side boundaries, and that of the casting belts and the Side boundaries shaped casting strand is conveyed with still molten core immediately below the mold in a strand guide with a plurality of immediately adjacent strand guide segments in the casting direction, where the casting strand further cooled and supported by the rollers of the strand guide segments at least until its solidification and preferably from the vertical in the horizontal is deflected.

Accordingly, the cast strand with still molten core from the mold enters the segmented strand guide, in which only the actual solidification of the strand takes place.

The inventive method advantageously allows high casting speeds of, for example, equal to 10 m / min and thus correspondingly high casting capacities (t / min). That The circulation speed of the belt mold is greater for casting formats (preferably casting thickness smaller than or equal to 100 mm) than at

conventional molds. This is advantageously only possible by the claimed combination of the band mold with the segmented strand guide. To explain the above: In conventional molds in the o. G. Speed both the heat load of Kokillenplatten and the turbulence of the liquid steel in the mold too large.

Other advantages:

It is a very good surface quality of the cast product achieved (due to lack of oscillation and lack of relative movement between the strand shell and circumferential chill strips). It continues to be a very good internal quality of the cast product (due to the cooling condition in the mold in combination with the Resterstarrung within the segmented strand guide).

 The o. G. high casting performance preferably requires the tracking of the material-specific shrinkage dimension. The segmented strand guide allows this.

 The claimed combination allows a soft reduction within the segmented strand guide, as the residual solidification in the

high casting performance takes place below the mold.

In short: The claimed combination of belt mold and segmented strand guide enables the realization of high casting performance combined with very high quality of the cast product. The claimed plurality of segments in the strand guide allows greater flexibility in terms of casting performance, casting of different grades of steel and casting at different casting speeds, as opposed to just one segment. This is especially true because different casting speeds and casting rates require a different location of the sump tip within the strand guide. Specifically, high pouring rates and casting speeds require greater removal of the sump tip from the exit of the mold than lower casting rates and lower casting speeds. For the deflection into the horizontal of the cast strand in the strand guide is typically performed in an arc. The position of the sump tip of the casting strand, that is the place of complete solidification, can - as seen in the casting direction, before, lie in or behind the bow. The cast strand preferably has a cross-section at its entry into the uppermost segment of the strand guide, which is at least 50%, preferably at least 75%, still made of molten material. This can be controlled by appropriate primary cooling of the strand in the mold and secondary cooling of the strand along / in the segmented strand guide as a function of the casting speed.

By the mold with the circulating, cooled casting belts a conventional oscillating mold is preferably replaced.

In terms of apparatus, the above-mentioned object is achieved by a claimed continuous casting plant, which has a mold through which molten metal, in particular steel, can flow down vertically in order to be formed into a metallic cast strand. This continuous casting plant is characterized according to the invention by the fact that the mold has two opposing boundaries for the molten metal, which are separated by two

circulating, cooled casting tapes are formed, with the lateral

Connecting areas between the casting belts by running

Page boundaries are formed. It is one of the mold associated

Primary cooling device (20) provided for cooling the casting belts only so strong that, although the cast strand is formed with a strand shell in the mold, but the cast strand is not yet solidified down from the mold escapes. Immediately below the mold (2) is adjacent a strand guide with a plurality of immediately following in the casting direction

Strand guide segments is arranged, wherein the strand guide segments have rollers which are designed to support the first not yet solidified Gießstrangs and preferably for deflecting the casting strand from the vertical to the horizontal. Finally, a secondary cooling device associated with the strand guide is provided for controlled further cooling of the casting strand in the strand guide at least up to its

complete solidification. Each segment of the strand guide consists of two mutually opposite roller carriers, on which - in each case - the casting strand facing - preferably a plurality of rollers is rotatably mounted. The cast strand is passed between the opposed rollers and supported and guided by them.

The lateral connection areas between the casting belts are preferably formed by dam block chains, each dam block chain being formed from a number of cuboid sealing elements. The sealing elements can be provided with positive connection means, in particular in the form of a tongue-and-groove connection, in order to be prevented from moving relative to one another in a horizontal direction of movement.

The dam block chains thus act as a lateral boundary element, which consists of individual interconnected metallic cuboids. The dam block chains run, as well as the preferably metallic casting tapes, at times each with a portion of the strand.

The cuboid sealing elements preferably have a width which corresponds to the clear distance between the two casting belts, which they have when facing each other.

The mold is preferably free of oscillating agents. The mold may further be equipped with inertizing agents. These means may be designed, in particular, to give off an inert gas in the region of the mold.

It is very advantageous if, for optimum guidance of the still substantially molten strand at the lower outlet from the mold, a number of foot or transition rolls are integrated into it. It is advantageous if it is further provided that the coming into contact with the molten metal surfaces of the mold, d. h the circulating belts are coated.

The basic concept of the invention therefore aims to design a mold so that the transport of the cast strand is carried out by metal strips on the broad sides, in combination with a segmented below the mold strand guide is arranged and this receives the still largely molten cast strand harden leaves and diverts into the horizontal. The invention thus includes a vertically oriented mold consisting of typically four revolving side boundaries in combination with immediately adjacent to the mold segments for guiding the casting strand.

It is preferably provided that the hitherto customary and common casting powder is eliminated. In order not to allow the molten material to adhere to the mold walls, a coating of the accompanying narrow and broad sides is preferably provided. Freezing of the steel on the mold walls is thus prevented. An oscillating device for the mold is not used; Accordingly, no disturbing oscillation marks are generated, which adversely affect the quality of the cast strand and can be dispensed with a scouring or grinding of the slabs before hot rolling. Thus, a larger output is given at the same time greater proportion of material for hot application.

Can also be omitted copper plates in the mold and previous exchange Ausbusausgusssysteme. The substitution of the casting powder also has the advantage that the environmental impact of cooling water and atmosphere is reduced by fluorine and chlorine. Furthermore, in the absence of casting powder turbulence in the mold, which arise during pouring of the liquid metal into the mold and otherwise lead to deficient lubrication and inclusion of casting powder, do not adversely affect the quality of the cast strand.

Since there is no relative movement between the moving mold and strand shell, there is an advantageous manufacturing condition for the casting of crack and surface critical grades.

Through a longer design of the molds in the vertical direction longer support lengths can be achieved in the mold at low pull-out forces. This also favors the casting of grades with large solidification ranges and casting at high casting speeds.

The dam block chain or the size of the blocks of the chain is adapted to the required width of the strand to be cast. Also possible are springs in the dam block chain, which allows a slight compression. With regard to the transition of the mold or dam block chains and the uppermost segment of the strand guide, it is provided that the formation of the segment allows the dam block chain to be brought out laterally in the upper region since the dam block chain requires a deflection radius. In this area, a cooling and support of the narrow sides is provided. Accordingly, it may be useful that the mold and the first segment are interlocked and integrated at the end of the mold foot or transition roles in the mold.

The opposing roller carriers of the strand guide segments are employed with their roles, at least in the region of not yet solidified Gießstrangs against each other so that no reduction in thickness, but preferably a compensation of the ferrostatic pressure in not yet solidified Gießstrang done. The invention does not provide for thickness reduction in the strand guide with a view to rapidly achieving a desired target thickness. However, this does not preclude that in the strand guide in addition to the compensation of the ferrostatic pressure quite a necessary compensation of the shrinkage of the cast strand and / or a soft reduction can be done. All three mentioned measures, the compensation of the ferrostatic pressure, the compensation of the shrinkage and the soft reduction serve to improve the inner quality of the strand and are only possible with a segmented strand guide, but not with single rolls as a strand guide.

The invention provides that the strand guide is formed by the mold at least up to the point of solidification of the casting strand, that is segmented to the sump tip. Behind it, the strand guide in the casting direction can optionally be segmented or formed in the form of individual roles.

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

1 shows schematically a part of a continuous casting plant according to the invention with a mold and directly below arranged strand guide,

Fig. 2 shows the section A-C of FIG. 1, wherein the mold is shown only partially, and

Fig. 3 is an enlarged part of Fig. 1, wherein for the casting strand

Solidification ratios are shown. Fig. 1 and Fig. 2 show a continuous casting plant 1, which has a mold 2, with which a cast strand 3 can be cast. The mold 2 is divided by two opposite casting belts 5 and 6 are formed, which form two opposite side boundaries of the mold 2. For this purpose, the two casting belts 5, 6 run around rollers 9 and 10. The casting mirror 1 1 is located in the region of the upper end of the casting belts 5 and 6. In the area of the casting belts, a primary cooling 20 is provided for cooling the casting belts for the purpose of forming the casting strand with its strand shell.

The lateral end portions, which lie between the casting belts 5 and 6 are formed by two revolving side boundaries in the form of dam block chains 12, which are well known as such.

In this regard, reference is made to EP 0 974 413 B1 and expressly incorporated by reference, which discloses a suitable dam block chain. Here also various details of a dam block chain are shown, which advantageously result in the present case. The individual blocks of the dam block chain made of metal are provided with corresponding, complementary configurations (eg in the form of a tongue-and-groove joint) in order to prevent a relative displacement of the blocks in one direction. The cuboid sealing elements of the dam block chain have a width which corresponds to the distance a of the two casting belts 5, 6 in the region in which the casting belts 5, 6 lie opposite one another (see Fig. 1).

The cast Gießstrang 3 is immediately below the existing of the follower bands and chains mold 2 preferably with integrated Fußbzw. Transition rollers 13 passed in the strand guide 4. The preferred provision of the rollers 13 is not contrary to the claimed arrangement of the strand guide immediately behind the exit of the mold. The strand guide consists of a number of segments 17, with which the casting strand 3 is diverted from the vertical V in the horizontal H or bent. The Strand guide 4 has per se known pairs of rollers 7, 8, with which the cast strand 3 is guided on opposite surfaces and acted upon by a force. In the strand guide, the cast strand is at least until its solidification further cooled by means of a secondary cooling device 30th

In Fig. 3, the essential aspect of the present invention is illustrated. Immediately below the mold 2 with said casting belts 5, 6, 12 of the casting strand 3 enters the segmented strand guide 4, namely in the top / first strand guide segment 16. The top roller pairs of this strand guide segment 16 are in the immediate vicinity of the foot or Transition rollers 13 placed, which are integrated into the mold 2. This is therefore useful and necessary because the casting strand 3 at the point where it leaves the mold 2 and enters the strand guide 4, is still molten to substantial parts in the interior. He has here only a relatively thin shell that forms him so far that he can be promoted down. However, the actual curing of the cast strand takes place only in the segmented strand guide 4.

FIG. 3 illustrates for this purpose that the still molten core 14 of the casting strand 3 extends far into the course of the strand guide 4. The cast strand 3 has at the point of entry into the segmented strand guide 4 a cross-section, which still consists essentially of molten material, preferably at least 50%, more preferably even at least 75%.

LIST OF REFERENCES:

 1 continuous casting plant

 2 mold

 5 3 cast strand

 4 strand guide

 5 casting belt

 6 casting belt

 7 pairs of rollers

10 8 pairs of rollers

 9 roll

 10 roll

 1 1 pouring mirror

 12 revolving side boundary

 15 13 integrated foot or transfer roller

 14 molten core

 5 sump tip (end of the molten core)

16 top strand guide segment

 17 strand guide segment

20 20 primary cooling device

 30 secondary cooling device

V vertical

 H horizontal

 25 D Thickness direction of the cast strand

 B width direction of the cast strand

 L longitudinal direction of the cast strand

 a distance

Claims

claims:

1 . Process for the continuous casting of a cast strand (3) of metal, in particular of steel, in which a mold (2) is used in a continuous casting plant (1), through which molten metal can flow vertically downwards, in order to be formed into the metallic cast strand (3) become,

 characterized,

 that the molten metal and / or the solidifying metal in the region of the vertical extent of the mold (2) is guided by two opposing boundaries for the metal, wherein the boundaries by two circumferential, cooled casting strips (5, 6) are formed and wherein the lateral Connecting areas between the casting belts (5, 6) by running side boundaries (12) are formed, and that of the casting belts (5, 6) and the side boundaries (12) molded casting strand (3) with still molten core (14) immediately below the Mold (2) is conveyed into a strand guide (4) with a plurality of directly adjacent strand guide segments (17) in the casting direction, where the casting strand (3) further cooled and by the rollers of the strand guide segments (7, 8) at least up to its

 Through solidification is supported.

2. The method according to claim 1, characterized in that the cast strand is deflected within the strand guide from the vertical (V) in the horizontal (H).

3. The method according to claim 1 or 2, characterized in that the casting strand (3) upon entry into the uppermost or first segment (16) of the strand guide (4) has a cross-section which is at least 50th %, preferably at least 75%, still made of molten material.

4. The method according to any one of claims 1 to 3, characterized in that a conventional oscillating mold is replaced by the mold (2) with the circulating, cooled casting belts (5, 6).

5. Method according to one of the preceding claims,

 characterized,

 that the strand guide segments of the caused by the cooling

Shrinkage of the casting strand can be traced to compensate for the shrinkage.

6. The method according to any one of the preceding claims

 characterized,

 that the strand guide segments are controlled in such a way that the casting strand undergoes a soft reduction in the area of the sump tip.

7. continuous casting plant (1) having a mold (2) through which

 molten metal, in particular steel, vertically downwards

 can be discharged to be formed into a metallic cast strand (3), for carrying out the method according to one of claims 1 to 4,

 characterized,

 that the mold (2) has two opposite boundaries for the molten metal passing through two circulating, cooled

Casting belts (5, 6) are formed, wherein the lateral connection areas between the casting belts (5, 6) are formed by running side boundaries (12) that a mold associated with the primary cooling device (20) is provided for cooling the casting belts only so strong that although the cast strand is formed with a strand shell in the mold, but the cast strand is not yet solidified down from the mold escapes;

5 that immediately adjacent to the mold (2) a strand guide (4) is arranged with a plurality of directly adjacent in the casting direction strand guide segments (17), wherein the

 Strand guide segments (17) have rollers (7, 8) which are designed to support the cast strand (3), which has not yet solidified at first; and

10

 a secondary cooling device (30) assigned to the strand guide is provided for the controlled cooling of the cast strand in the strand guide at least until its complete solidification.

15 8. Continuous casting plant according to claim 7, characterized in that the

 Continuous casting is designed to divert the casting strand from the vertical (V) in the horizontal (H).

9. Continuous casting plant according to claim 7 or 8, characterized in that 20 each segment of the strand guide (4) two opposite each other

 Roller carrier, wherein at each of the roller carrier - on the cast strand facing the inside - a plurality of rollers is rotatably mounted.

25 10. Continuous casting plant according to one of claims 7 to 9, characterized

 characterized in that the lateral connection areas between the casting belts (5, 6) are formed by dam block chains, each dam block chain being formed from a number of parallelepiped sealing elements, the sealing elements preferably with positive locking

30 connecting means, in particular in the form of a tongue and groove joint, are provided to relatively to each other in a horizontal direction of movement to be prevented from shifting.

1 1. Continuous casting plant according to one of claims 7 to 10,

 characterized,

 that the mold (2) is free of oscillating agents.

12. Continuous casting plant according to one of claims 7 to 1 1, characterized in that the mold (2) is equipped with means for inerting, wherein the means for inerting are preferably formed to give up an inert gas in the region of the mold (2).

13. Continuous casting plant according to one of claims 7 to 12, characterized in that at the output of the mold, a number of foot or transition rollers (13) in the mold (2) are integrated.

14. Continuous casting plant according to one of claims 7 to 13, characterized

 characterized in that the opposing roller carriers of the strand guide segments are employed with their roles, at least in the region of not yet solidified Gießstrangs against each other, that no reduction in thickness, but preferably a compensation of the ferrostatic pressure in the cast strand.

15. Continuous casting plant according to one of claims 7 to 14, characterized in that the strand guide is formed to follow the strand guide segments caused by the cooling shrinkage of the casting strand.

16. Continuous casting plant according to one of claims 7 to 15, characterized in that the strand guide is designed to control the strand guide segments such that the casting strand undergoes a soft reduction in the region of the sump tip.