EP2183065A1

EP2183065A1 - Method and device for the production of a metal strip by roll casting

Info

Publication number: EP2183065A1
Application number: EP08801645A
Authority: EP
Inventors: Dieter Rosenthal; Stephan Krämer; Christoph Klein; Jürgen Seidel; Wolfgang-Dietmar Hackenberg
Original assignee: SMS Siemag AG
Current assignee: SMS Siemag AG
Priority date: 2007-08-24
Filing date: 2008-08-21
Publication date: 2010-05-12
Also published as: MX2010002048A; US20100147484A1; TW200916217A; CA2693205A1; CN101848780A; US8011418B2; KR20100057073A; AU2008291362A1; JP2010536577A; RU2429923C1; DE102008020412A1; WO2009027045A1; AR068018A1; AU2008291362B2

Abstract

The invention relates to a method for the production of a metal strip (1) by roll casting, wherein initially a thin slab (3) is cast in a casting machine (2), wherein said slab is subsequently rolled in at least one rolling train (4, 5) while utilizing the primary heat of the casting process, wherein in a first operating mode a continuous production of the metal strip (1) may occur by directly coupling the casting machine (2) to the at least one rolling train (4, 5) (continuous rolling), and wherein in a second operating mode a discontinuous production of the metal strip (1) may occur by decoupling the casting machine (2) from the at least one rolling train (4, 5) (batch operation). In order to increase the flexibility of the system, the invention provides according to the method that slabs (3) or pre-strips (3') cast in the belt conveying direction (F) behind the casting machine (2) are removed from the main transport line (6) during the operation of the discontinuous production of the metal strip (1), stored, and later re-transported into the main transport line (6), wherein the slabs (3) or pre-strips (3') removed are brought to a desired temperature or are maintained at a desired temperature before the same are re-transported into the main transport line (6). The invention further relates to a device for the production of a metal strip (1) by roll casting.

Description

Method and device for producing a metal strip by casting rolls

The invention relates to a method for producing a metal strip by casting rolls, in which a thin slab is first cast in a casting machine, which is then rolled in at least one rolling mill using the primary heat of the casting, wherein in a first mode by direct coupling of the casting machine with the continuous rolling of the metal strip can take place at least one rolling train (endless rolling) and in a second operating mode a discontinuous production of the metal strip can take place by decoupling the casting machine from the at least one rolling train (batch operation). Furthermore, the invention relates to an apparatus for producing a metal strip by casting rolls.

Plants of this type are known as thin-slab thin-strip caster under the name CSP plants. Endless rolling out of the casting heat has been known for a long time, but it has not yet reached the market. The rigid connection of continuous casting plant and rolling mill and the temperature control through the entire system have proven to be difficult to control.

EP 0 286 862 A1 and EP 0 771 596 B1 disclose endless rolling out of the casting heat. Here, the casting and rolling processes are directly coupled. A separation of the endless belt with a pair of scissors is done just before the reel.

Similar processes for the continuous production of strip steel in the coupling of casting and rolling plant are disclosed in EP 0 415 987 B2 and EP 0 889 762 B1. To overcome the temperature problems in the relative low transport speed inductive heaters are provided there before and inside the rolling train.

An alternative technology for this is the rolling of single slabs or single bands. In the discontinuous rolling of belts, the casting and rolling are decoupled. The casting speed is usually very low and the rolling speed is independent of a high level in such a way that the temperature for the last transformation is above the minimum temperature. Such systems, which are also referred to as CSP plants, are described for example in EP 0 266 564 B1, where a high deformation in the thin slab plant is performed.

A similar thin slab plant is also shown in EP 0 666 122 A1, where strips are discontinuously rolled using induction heating between the first finishing stands.

The advantages of batch rolling are that the casting and rolling speeds can be adjusted independently. In Dünnbandwalzung can be z. B. flexibly set higher rolling speeds, even if the casting machine operates at low speed or the speed is being changed there.

Both methods - ie on the one hand the continuous casting rolls and on the other hand the discontinuous casting rolls - are difficult to combine due to the circumstances explained above.

The invention has for its object to provide a method of the type mentioned so or to create a corresponding device with which or with which it is possible to increase the flexibility of the method and the device. It is no longer necessary, especially in the event of malfunctions or required short-term maintenance or other interruptions in rolling be to interrupt the casting process, which has significant economic and procedural advantages.

The solution of this object by the invention according to the method is characterized in that in the belt conveying direction behind the casting machine gegne- ne slabs or Vorbänder taken out of the main transport line while driving the discontinuous production (ie rolling) of the metal strip, stored and later transported back to the main transport line, wherein the removed slabs or pre-belts are brought to a desired temperature or maintained at a desired temperature prior to being transported back into the main transport line.

In this case, a special ferry system consisting of two or more subsystems is preferably used in succession.

It is particularly preferably provided that during a roll change in the rolling mill with continuous operation of the casting machine cast slabs taken out of the main transport line and transported at a later date back into the main transport line. This makes it possible to perform a roll change without having to forego the continuous operation of the casting machine.

A proposed apparatus for producing a metal strip by casting rolls comprises a casting machine, in which a thin slab is first cast, and at least one downstream of the casting machine, in which the thin slab is rolled using the primary heat of the casting process. The invention is characterized in that in the belt conveying direction behind the casting machine, a ferry system is arranged, which is suitable for moving out and in-drive cast slabs from or into the main transport line. On or in the ferry system, heating means are preferably arranged with which slabs can be brought to a desired temperature. These heating means are advantageously designed as inductive heating and / or as furnaces with combustion means (eg gas, oil). The ferry system may comprise conveying elements with which slabs can be moved transversely to the belt conveying direction. These conveying elements may comprise movable carriages. Alternatively, it is also possible that the conveying elements are lifting bar conveying elements.

According to one development of the invention, the ferry system consists of two or more subsystems (eg 3 or 4) arranged in succession in the belt conveying direction. These subsystems can be moved together or independently of each other transversely to the belt conveying direction. Within the subsystems of the ferry system, longitudinal transport in the belt conveying direction or counter to it (i.e., forward or backward) from one to the other subsystem is possible.

The ferry system is preferably arranged between the casting machine and the rolling train. However, it can also be advantageous that the ferry system is arranged between a roughing mill or a roughing stand and a finishing train.

The ferry system may also be associated with a roller table for storing slabs. The roller table can be provided with a thermal insulation. Heating means can be arranged between the roller table and the ferry system.

In addition to the roller table, at least one additional memory, z. B. in the form of a Warmhaltegrube or a similar device for storing slabs or Vorbändern be arranged. This expands the storage capacity or allows a longer storage time for microstructure control. This can therefore be advantageous for metallurgical reasons, namely, if longer should be realized in the acting as a memory Warmhaltegrube.

In belt conveying direction in front of the ferry system, a slab or Vorbandschere may be arranged.

The advantages of the endless technology, d. H. The continuous operation of the proposed casting and rolling plant, in connection with the CSP technology, has the following features: The result is a short overall length of the plant and thus lower investment costs. Energy savings are possible as a result of consistent direct deployment. Furthermore, a lower deformation resistance results due to the lower rolling speed. The possibility is created difficult to roll products and z. B. very thin (ultra thin) bands (strip thickness of about 0.8 mm) to produce in high production volumes. Special materials (high-strength materials) can be processed. A combination of wide and thin ribbons can be processed. Bandendenverwalzungen and thus roller damage can be avoided or reduced. The disturbance rate of the system can be reduced and high speeds can be avoided.

In the drawings, embodiments of the invention are shown. Show it:

1 is a schematic side view of a casting and rolling plant according to a first embodiment of the invention,

2 is the associated with FIG. 1 top view,

3 is a view of the casting machine according to an alternative embodiment of the invention,

4 the plan view associated with FIG. 3, 5 in the representation according to FIG. 1 a cast roll plant according to a further alternative embodiment of the invention, FIG.

6 the plan view associated with FIG. 5,

7 in the representation according to FIG. 1 a cast roll plant according to a further alternative embodiment of the invention, FIG.

FIG. 8 shows the plan view associated with FIG. 7,

9 the region of a ferry system as a detail from the top view of a casting rolling mill,

Fig. 10 in the illustration of FIG. 9 shows an alternative embodiment of the ferry system and

Fig. 11 in the illustration of FIG. 9 shows a further alternative embodiment of the ferry system.

In Fig. 1 and Fig. 2 is a cast roll plant to see in which a metal strip 1 is produced. For this purpose, a thin slab 3 is first cast in a casting machine 2 known per se, which is then fed to a rolling train 4, 5 which in the present case consists of a roughing train 4 (consisting of one or more scaffolds) and a finishing train 5. The casting machine 2 has a strand cooling, which is provided with a narrow cooling zone division for a temperature zone control over the width in order to set a homogeneous outlet temperature from the continuous casting plant can.

The cast rolling mill still has various other elements that are known per se in such systems. In the belt conveying direction F behind the casting machine Machine 2 is arranged a scale scrubber 12 for slab cleaning. Behind the roughing 4 follows a band shears 11. The scissors is used to separate the cold strand during casting, for separating the slabs (usually single slabs or half slabs) and for shredding the band in case of disturbances.

This is followed by a ferry system 7, which will be described in more detail below.

Behind the ferry system 7, a furnace 13 is arranged, which is preferably designed as an induction furnace; but it can also be a roller hearth furnace here. There is still the possibility to divide the illustrated induction heating. An arrangement of an induction heater in front of and behind the ferry system would therefore also be conceivable. Behind this, another band shears 14 and another scale washer 15 are arranged. The scissors 14 serves as an emergency scissors or for profiling the slab end shape.

Behind the finishing train 5, a cooling section 16 is arranged. Behind it are the reel 17. The finishing train 5 often has three to eight scaffolding, preferably six scaffolding. The pre-strip is here rolled down to a final thickness of, for example, about 0.8 to 16 mm.

For the ferry system 7, the following should be noted: The solution according to FIGS. 1 and 2 - as can be seen in FIG. 2 - is heatable ferries or furnace parts which serve as additional short slab storage, for example for the time of the roll change in the finishing train in which

Slabs 3 or split slabs or pre-strips 3 'from the main transport line 6 taken out for storage and later can be introduced into this again. The ferry elements are indicated here as carriages, which are arranged movably transversely to the belt conveying direction F, in order to be able to carry out or inward transport of slabs out of or into the main transport line 6. Alternatively, it is also possible to replace a ferry Insert a walking beam conveyor next to the main transport line 6. When transporting through the ferry or the furnace, the slab temperature is generally maintained. Slab heating is also provided at low casting speeds in order to be able to set flexibly almost constant inlet temperatures for the subsequent processes.

As can further be seen, there are two consecutive ferry subsystems T and 7 "in the belt conveying direction F. These may advantageously have in sum the length of a maximum ring weight slab plus some travel for commuting executed relatively short.

In FIGS. 3 and 4, 5 and 6 or 7 and 8, variations of the solution according to FIGS. 1 and 2 can be seen. In the solution according to FIGS. 3 and 4 further ferries 7 are provided, wherein a slab transport within the ferries and outside the main transport line 6 can take place in or against the belt conveying direction F (see double arrows in belt conveying direction F in FIG.

In the embodiment according to Figures 5 and 6, the ferry system is directly behind the caster - d. H. in front of the rolling mill - arranged. Furthermore, further induction heaters 19 are arranged between the rolling stands of the finishing train 5 for continuous operation.

In Fig. 7, a cold strand disposal 20 is indicated, with which the cut cold strand can be removed. It can be taken up or laterally out of the transport line by means of a "gallows" or a chain by means of a sliding unit at the sprue, after which a roller table cover 21 can be swung down to reduce the temperature loss.

FIG. 9 shows a further embodiment of the oven / ferrule arrangement 7/8. Here there is the possibility of a longer fault slabs 3 or half slabs to a secondary roller table 9 deport. Also for metallurgical reasons (structural training) a longer slab or pre-strip storage time is necessary.

As can be seen in FIG. 11, these can then optionally be stored in holding pits 10 and later reinserted and rolled out, as indicated in FIG. 11. In FIG. 11, the parking positions of the ferries shown at the bottom with dashed lines and also between the main transport line 6 and the ferries at the very top are shown with dashed lines. In the uppermost position of the ferries 7, the pushing off of the slabs 3 or pre-bands 3 'takes place.

Depending on the system variant, it is possible to work in front of the ferry 7 with or without a fixed furnace section. This also applies to the behind the ferry arranged induction heating or roller hearth 13. Between the roller table 9 and the right next to this located ferries 7 can commute the slab 3 done to heat the slab 3 by means of the induction heater 8. The roller table 9 may be encapsulated for thermal insulation.

The subsequent reheating can optionally inductive with a heating means 8, z. B. a gas or oil-heated roller hearth furnace, done.

In Fig. 10 it can be seen that there is also a short embodiment of the fen fen ferry arrangement when z. B. three or more ferries 7 are provided side by side.

With the heating means 19 (in FIG. 9) or heating means 13 (in FIG. 2 or 6), which is preferably designed as induction heating, the preliminary strip can be brought individually to the desired finishing line inlet temperature. This is, for example, therefore, desirable to be able to set a higher temperature (eg. B. 1350 ⁰ C) at the rolling of grain-oriented silicon steel (GO-Si-Steel) or other materials to higher temperatures in the small intestine or to increase the temperatures, if the thin slab temperature is too low. Of course, it can also be provided, in the case of low temperatures, to work without or with low energy input, for example, if energy is to be saved in normal bands.

Furthermore, with the heating means 8, 13 and 19, homogeneous temperatures above the thin slab length can be generated and possible temperature irregularities can be compensated by different energy input over the length.

If the system is operated in continuous mode with a relatively low casting speed and thus rolling speed in the rolling train, then the induction heating is necessary to set a sufficiently high rolling temperature. The induction heating in front of the finishing train is optionally also supported by induction heaters within the finishing train. The induction heating in front of the finishing train is optionally transversely displaceable or swiveling, so that the induction heating can be replaced by a roller table cover (passive or heated) or a conventional oven part as required.

The band shears 18 in Fig. 5 is used to cut the bands just before the reel 17, when the system is operated in endless mode.

The arrangement of the ferry system 7 can take place (as shown in FIGS. 5 to 8) directly behind the casting machine 2. However, it is also possible (as shown in FIGS. 1 to 4) to first carry out a reduction in thickness of one or more stands (see roughing street 4) behind the casting machine 2 and then to install the ferry system 7.

The holding furnace 13 arranged behind the casting plant 2 can also be a conventionally gas-fired furnace. According to the embodiment according to FIG. 1, the roughing train 4 has a rolling stand, while the finishing train 5 has six rolling stands. Between the roughing train 4 and the finishing train 5, the furnace 13 is arranged as an induction furnace in order to heat the strip after the rough rolling in the roughing train 4 to the optimum strip temperature before finish rolling in the finishing train 5.

The band shearing machine 11 is used for separating the thin slabs 3 in the batch mode and the band shears 14 for separating the bands in endless rolling. The scissors 11 is used in particular for scooping the tape head or tape end when starting or discharging in continuous operation or in discontinuous operation.

By using the proposed plant types, a coupled fully continuous casting-rolling process (continuous rolling) and optionally a decoupled discontinuous use of individual slabs (batch rolling) is possible.

In continuous rolling, the level of casting speed determines the temperature profile throughout the plant. Depending on the casting speed, a calculation model dynamically controls the heating performance of the furnaces before and inside the rolling train in such a way that the rolling-line outlet temperature reaches the target temperature.

If the casting speed falls below a certain predetermined threshold value (in the case of problems in the casting plant, in the case of difficult-to-cast materials, during the start-up process, etc.), the system switches automatically from endless mode to discontinuous rolling. Ie. the thin slab 3 is separated with the scissors 11 and 14 and the rolling speed is increased so that the desired final rolling temperature is reached. Here are the slab or. Tracked segments within the road 4, 5 and dynamically adjusted depending on the temperature distribution, the transport or rolling speed and inductive heating power over the tape length. Has the casting process stabilized again and the casting speed exceeds the predetermined minimum value, then analogous to discontinuous operation is switched back to the endless mode.

By any switching or setting of continuous operation or discontinuous operation is given a high degree of flexibility, which represents an increase in process reliability. This is especially true when commissioning a production plant.

The endless mode during processing will not be generally used; Batch operation will be used primarily for casting speed problems or during startup.

For energy optimization, it may be provided to roll primarily thin or difficult to produce belts in continuous mode and belts having thicknesses greater than a critical thickness in batch operation at high speed and low heating energy requirements. The right combination of generation method optimizes the energy balance of the CSP continuous batch system for the entire product mix.

Through the use of the proposed system, a coupled fully continuous casting-rolling process (continuous rolling) and optionally a decoupled discontinuous use of individual slabs in batch mode is possible. The system is very space-saving. Compared with a conventional CSP system, this results in only about half the system length (about 250 m). Nevertheless, the proposed system allows a work roll change without aborting the casting process.

As regards the possible modes of operation of the proposed annex, the following should be noted: 1. Batch operation in the rolling mill:

At the beginning of the casting process, during commissioning of the plant, in general casting problems or difficult to cast steels, the casting speed is set relatively low. At low casting speeds, continuous rolling with this low mass flow from the caster to the finishing mill is not possible or uneconomical for reasons of temperature. To reduce the energy losses, the batch mode is preferably used. In batch mode, the casting process and the finish rolling are each decoupled and thus take place at different speeds (ie mass flow). After sprueing, the cold strand is first disposed of and the thin slab is scooped up in the slab head area. After reaching the desired coil weight, the repeated scooping takes place on the scissors behind the continuous casting plant or roughing line for each slab. It follows the rolling in the finishing train with an individually adjustable rolling speed and the further transport through the cooling section and ultimately the winding.

2. Endless operation (i.e., caster and rolling mill are coupled)

With increasing casting speed and depending on the end thicknesses to be rolled, the system switches to endless mode. In this mode of operation, the scissors in front of the reel are used to separate the bands. Before the thin slab enters the finishing train, it is inductively heated so that a sufficiently high rolling temperature is established and the rolling takes place in the austenitic region. In the subsequent endless rolling usually the inductive heaters are used within the finishing mill and support the inductive heaters in front of the finishing train. In the case of discontinuous operation or when starting up on the tape head, on the other hand, they stand in a safe standby position far above or next to the tape. 3. roll change in the finishing train with active casting

When changing the work rolls or in case of disturbances in the rolling mills, preferably the casting process should not be interrupted or disturbed.

Therefore, it makes sense to install a buffer for the slabs. For this purpose, a short roller hearth furnace is provided behind the casting plant in a compact CSP plant in which four (or six) slabs can be accommodated due to the process. The furnace is embodied in its embodiment in the form of the proposed ferries, as can be seen in particular from FIGS. 9 to 11.

As can be seen from the figures, two ferry groups T, 7 "are arranged one after the other in the transport direction, both of which can travel transversely independently of one another Alternatively, the front ferry group T is also permanently installed behind the casting machine 2 or roughing 4 as the furnace part In these two groups of ferries, for example, four whole or half thin slabs can be accommodated in total Optionally, storage possibilities are provided in short oven parts The dashed fields in Figures 2, 4, 6 and 8 to 11 are alternative parking positions for the ferries 7, 7 ', 7 ". It is also a transport of slabs from ferry to ferry next to the rolling line possible, so that individually from one or the other ferry backhaul of slabs in the rolling line can be performed. This arrangement facilitates the flexible return transport of slabs after a roll interruption (i.e., in particular when changing rolls or in the event of a malfunction). As a further alternative embodiment, as a second ferry group, more than two ferry parts or lifting beam furnace parts (for example, three or four) are conceivable side by side, in order to increase the storage capacity with the same overall system length.

In Fig. 4, a constellation of ovens and ferries is selected in a short Gießwalzanlage, wherein three furnaces 8 are arranged side by side, which are fed by a ferry 7. Are the ferries (stoves) full, z. B. because the roll interruption takes longer, the slabs on a roller table 9 (see Figures 10 and 11) can be deported, stored, reheated and later reinserted in the main transport line 6 and rolled.

Saving half slabs (ie a compromise during roll changeover) makes it easier to draw between two slivers in a short design so that slabs can be easily driven out of or into transport line 6 with a ferry. The total length of the two ferries allows in normal operation, however, to keep an entire slab length warm.

During the roll change time, the casting speed is optionally reduced to increase the buffering time.

A 1-strand caster with pendulum or transverse ferries is preferably provided in order to store a thin slab or deformed thin slab z. B. during a roll change in a ferry and / or parallel stoves to allow.

For the roller change is previously switched from continuous operation to batch mode.

Within the ferries, which are adjacent to the main transport line 6, a longitudinal transport of slabs from one to the other ferry is also possible (see double arrow in the direction of the belt conveying direction F in FIG.

Accordingly, the invention proposal suggests that both the benefits of the continuous casting rolling process and those of the single belt rolling process can be utilized. In particular, a very advantageous solution for the roll change results. The conversion costs (rolling energy, heating energy) can be reduced, and it is possible to reduce the length of the system by approx. 40% to 50% compared with the CSP technology. Accordingly, the investment costs and the operating costs are lowered.

The endless rolling reduces the number of punctures in the finishing train, which is particularly advantageous in the rolling of thin end thicknesses. The cast slab, for example, passes through two in-line rolling stands, in which it is reduced to a pre-strip thickness which is suitable for producing the final product with the smallest possible number of finishing stands.

The pre-strip temperature can be maintained in a roller hearth furnace at the level of the temperature exiting the inline stands. An inductive heating before and optionally also within the finishing train increases this to the required rolling temperature.

The advantage of providing inductive heating systems before and in the finishing train results from the fact that in the continuous process only relatively low rolling speeds are possible. Here, the temperature loss without inductive heating system would be greater than allowed to the end of the finishing mill to maintain the final rolling temperature.

The proposed method also allows the single strip rolling known from the CSP process. For this purpose, the Vorband is divided with a pendulum scissors after the inline scaffolding in the desired length. This allows the production of a variety of steel grades, which must be cast out of metallurgical requirements with lower casting speeds. At these low casting speeds, an endless rolling process is not economical. The required reheating to maintain the final rolling temperature is too high. In addition, the steel grades produced by this process eliminate the advantages of continuous rolling, since these products are produced in the usual final strip thicknesses. Preferably, the continuous casting operation should not be disturbed when changing the roll in the finishing train. For this reason, it is necessary to incorporate the proposed system for buffering the pre-bands, which on the one hand can produce the required buffer time, but on the other hand, does not affect the quality of the Vorbandes. The uniformity of the pre-strip temperature along the length and width is a striking feature of CSP technology and a prerequisite for a multitude of advantages in the downstream finish rolling process. The roller hearth furnace is a suitable solution for this. In the present case, the roller hearth furnace is essentially designed to accommodate approximately four half the pretreatment lengths, which provides a buffer in the length of the required roll changeover time by transverse processing and storage of the pre-belts.

The concept described is a single-line concept. An extension to two casting strands is possible. Designed as a single-line system, the capacity of the system components is utilized. This generally leads to favorable investment and operating costs.

Typical data in the proposed concept are casting thicknesses between 60 and 100 mm, casting speeds between 4 m / min and 8 m / min, pre-strip thicknesses between 25 mm and 60 mm and final strip thicknesses between 1, 0 and 16 mm.

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LIST OF REFERENCE NUMBERS

1 metal band

2 casting machine

3 thin slab

3 'opening band

4, 5 rolling mill

4 rough road

5 finishing line

6 main transport line

7 ferry system

T subsystem

7 "subsystem

8 heating means (induction heating or roller hearth furnace)

9 roller table

10 warm water pit / additional storage

11 band scissors

12 tinder scrubber

13 Oven (induction or roller hearth furnace)

14 band scissors

15 tinder scrubber

16 cooling section

17 reel

18 band scissors

19 heating means (induction heating) 20 cold-string disposal

21 roller table cover

F belt conveying direction

Claims

claims:

1. A method for producing a metal strip (1) by casting, in which first in a casting machine (2) a thin slab (3) is cast, which is then rolled in at least one rolling train (4, 5) using the primary heat of the casting process in which in a first operating mode by direct coupling of the casting machine (2) with the at least one rolling train (4, 5) a continuous production of the metal strip (1) can take place (endless rolling) and wherein in a second mode by decoupling the casting machine (2) from the at least one rolling train (4, 5) a discontinuous production of the metal strip (1) can take place (batch operation),

characterized,

that in the belt conveying direction (F) behind the casting machine (2) cast slabs (3) or Vorbänder (3 ¹ ) from the main transport line (6) when driving the discontinuous production of the metal strip (1) taken, stored and later back into the main transport line (6 ), wherein the removed slabs (3) or pre-strips (3 ') are brought to a desired temperature or kept at a desired temperature prior to being transported back into the main transport line (6).

2. The method according to claim 1, characterized in that during a roll change in the rolling train (4, 5) at steady

Operation of the casting machine (2) cast slabs (3) or pre-bands (3 ') taken out of the main transport line (6) and transported back to the main transport line (6) at a later date.

3. Apparatus for producing a metal strip (1) by casting, with a casting machine (2), in which initially a thin slab (3) is cast, and at least one of the casting machine (2) downstream rolling train (4, 5), in which Thin slab (3) is rolled using the primary heat of the casting process, in particular for carrying out the method according to claim 1 or 2, characterized in that in the belt conveying direction (F) behind the casting machine (2) or roughing (4) a ferry system (7 ), which is suitable for driving out and inward driving of cast slabs (3) from or into the main transport line (6).

4. Apparatus according to claim 3, characterized in that on the or in the ferry system (7) heating means (8) are arranged, with which slabs (3) can be brought to a desired temperature or maintained at a desired temperature.

5. Apparatus according to claim 4, characterized in that the heating means (8) are designed as inductive heating and / or as a heated roller hearth furnace.

6. Device according to one of claims 3 to 5, characterized in that the ferry system (7) comprises conveying elements with which slabs can be moved transversely to the belt conveying direction (F).

7. Apparatus according to claim 6, characterized in that the conveying elements comprises movable carriage.

8. Apparatus according to claim 6, characterized in that the conveying elements Hubbalkenförderelemente.

9. Device according to one of claims 3 to 8, characterized in that the ferry system (7) consists of two or more in the belt conveying direction (F) successively arranged subsystems (7 ', 7 ").

10. The device according to claim 9, characterized in that the two or more subsystems (7 ', 7 ") of the ferry system (7) can be moved together transversely to the belt conveying direction (F).

11. The device according to claim 9, characterized in that the two or more subsystems (7 ', 7 ") of the ferry system (7) can be moved independently of one another transversely to the belt conveying direction (F).

12. Device according to one of claims 3 to 11, characterized in that the ferry system (7) between the casting machine (2) and the WaIz- road (4, 5) is arranged.

13. Device according to one of claims 3 to 11, characterized in that the ferry system (7) between a roughing mill or a

Pre-rolling stand (4) and a finishing train (5) is arranged.

14. Device according to one of claims 9 to 13, characterized in that means are provided, with which within the ferry system (7) a longitudinal transport of the slabs (3) or Vorbänder (3 ') in Bandforderrichtung (F) or against the same of a Subsystem (7 ', 7 ") can be done to another.

15. Device according to one of claims 3 to 14, characterized in that the ferry system (7) with a roller table (9, 21) for storing slabs (3) or Vorbändern (3 ') can be associated.

16. The apparatus according to claim 15, characterized in that the roller table (9, 21) is provided with a thermal insulation.

17. The apparatus of claim 15 or 16, characterized in that between the roller table (9) and the ferry system (7) heating means (8) are arranged.

18. Device according to one of claims 15 to 17, characterized in that next to the roller table (9) at least one additional memory for Spe- ehern of slabs (3) or Vorbändern (3 ') is arranged.

19. The apparatus according to claim 18, characterized in that the at least one additional storage is formed as a warming pit (10).

20. Device according to one of claims 3 to 19, characterized in that in the belt conveying direction (F) in front of the ferry system (7) a belt scissors (11) is arranged.

21. Device according to one of claims 3 to 20, characterized in that induction heaters and / or roller hearth furnaces (13) are arranged in front of and behind the ferry system (7).