EP2418031A1 - Method for producing a metal strip using a casting rolling assembly and control and/or regulating device for a compound casting rolling assembly - Google Patents

Abstract

Producing a metal band using a casting roller composite plant, comprises casting a metal by a casting device (1, 1'), and hot forming the metal bands by at least one rolling mill (2). The casting roller composite plant is operated so that the metal band extends continuously between the casting device and the rolling mill. The metal band is continuously supplied to the rolling mill. The rolling mill has a desired thickness profile, according to which the rolling mill rolls the metal band. The thickness profile exhibits at least two different target thicknesses for different band sections. Producing a metal band using a casting roller composite plant, comprises casting a metal by a casting device (1, 1') and hot forming the metal bands by at least one rolling mill (2). The casting roller composite plant is operated so that the metal band extends continuously between the casting device and the rolling mill. The metal band is continuously supplied to the rolling mill. The rolling mill has a desired thickness profile, according to which the rolling mill rolls the metal band. The thickness profile exhibits at least two different target thicknesses for different band sections in the longitudinal direction of the metal band. The thickness profile is designed so that the first and/or the second target thickness are adjusted at least twice. Independent claims are also included for: (1) a control and/or regulating device (10) for a casting roller composite plant to produce longitudinally thick profiled metal strip, comprising a machine readable program code, which includes control commands and causes the control and/or regulating device to perform the method mentioned above; and (2) the casting roller composite plant to manufacture metal strip thick profiled in its longitudinal direction, comprising the casting device and the rolling mill, where the control and regulating device is operatively connected with the rolling mill.

Description

Method for producing metal strip by means of a Gießwalzverbundanlage, control and / or regulating device for a Gießwalzverbundanlage and Gießwalzverbundanlage

The invention relates to a method for producing metal strip by means of a Gießwalzverbundanlage, comprising a casting device for casting metal and at least one roll stand comprising rolling train for hot working of the metal, wherein the Gießnalzverbundanlage is operated such that the metal strip between the casting device and the rolling mill continuously wherein the rolling train is fed continuously metal strip, wherein the rolling train is given a desired thickness profile, according to which the rolling mill rolls the metal strip. Furthermore, the invention relates to a control and / or regulating device for a Gießwalzverbundanlage and a Gießwalzverbundanlage for producing in its longitudinal direction thick profiled metal strip.

The invention relates to the technical field of rolling metal strip, in particular so-called "tailored blanks", i. Metal strip with desired thickness profile in the longitudinal direction of the metal strip. Such metal strip is also referred to as longitudinally profiled metal strip. The associated process is also known as flexible rolling. Flexible rolling is now used only in the cold rolling area for various reasons explained below. The products produced by these methods are used, for example, in the automotive industry to increase the safety of the vehicle occupants while minimizing the weight of the automobile.

From the publication DE10041280A1 a method for flexible cold rolling of metal strip is known.

From the WO 00/13820 is a method for producing metal strips by means of a hot rolling known, whose Thickness is constantly changing in the longitudinal direction. This variable thickness is adjusted by means of a variable casting roll gap and the cooling of the casting rolls. Disadvantage of this solution is that thickness settings by means of casting rollers are inaccurate and difficult to control. Furthermore, only certain thickness profiles can be produced. This limits the flexibility of the system.

Conventional hot rolling mills today do not produce tailored blanks. Because the achievable minimum hot strip thicknesses are usually in the range of 1.2 to 1.5 millimeters, which is not sufficient for tailored blanks, which often require minimum thicknesses of 0.6 mm. Therefore, the required thickness range can be covered only insufficiently by conventional hot rolling mills for tailored blanks.

The object of the present invention is to provide a method and a device by means of which longitudinally profiled metal strip can be produced significantly more favorably than with conventional processes.

The procedural part is achieved by a method for producing metal strip by means of a Gießfalzverbundanlage comprising a casting device for casting metal and at least one roll stand comprising rolling train for hot working of the metal strip, wherein the Gießnalzverbundanlage is operated such that the metal strip between the casting device and the rolling train extends continuously, wherein the rolling train is fed continuously metal strip, wherein the rolling mill a desired thickness profile is predetermined, according to which the rolling mill rolls the metal strip, the thickness has at least two different target thicknesses for different band sections in the longitudinal direction of the metal strip, and in that the course of the thickness is designed such that the first and / or the second setpoint thickness is set at least twice.

The use of a Gießwalzverbundanlage whose aggregates are coupled by the one-piece rolling, allows the production of longitudinally profiled hot strip already during hot rolling. Because of the Gießwalzverbunds usually the speed of the belt at the output of the hot rolling mill is determined essentially by the casting speed and the reduction made by means of the plant thickness reduction. Due to this coupling maximum strip speeds are achieved in the rolling mill, which are significantly below the usual belt speeds of 10 to 20 meters / second in conventional, non-coupled hot rolling mills.

In addition, the thickness range required for "tailored blanks" can be easily covered, in particular in thin strip casting or thin slab casting.

Casting devices which can be used are any casting installations which are suitable for casting roll composite systems.

Thus, it becomes possible to introduce a longitudinal profile into the hot strip in an economical manner by means of a roll stand.

As a result, a flexible cold rolling step can be completely eliminated. Thus, an entire plant part, namely the cold rolling mill for the production of longitudinally profiled rolling, eliminated. This leads to significant savings in investment costs and operating costs.

As a course of thickness in the longitudinal direction, any thickness profiles can be specified, depending on what is desired by the customers of the product produced. In particular, periodic thickness profiles in the longitudinal direction can be produced very efficiently in this way.

In an advantageous embodiment of the method, in addition to the at least two different nominal thicknesses associated desired rolling forces and / or set roll gap openings. As a result, the accuracy for the production of a longitudinally profiled hot strip is further increased.

In a preferred embodiment, the course of the thickness comprises repetitive, in particular periodically repeated, thickness changes in the longitudinal direction of the metal strip. As a result, effectively large numbers of metal sheets profiled in the longitudinal direction can be produced, which, for example, are cut directly out of the metal strip after rolling.

In a preferred embodiment of the method according to the invention, a strip store, in particular a belt loop, is present between the casting device and the rolling train, with which mass flow fluctuations caused by the predetermined course of thickness are compensated in the cast roll composite system. This is particularly easy and effective in Dünnbandgießwalzverbundanlagen possible. Because due to the small diameter of the cast metal strip during thin strip casting, the cast strip already has sufficient deformability, which allows, for example, between the rolling stand and casting device formed by a gravity belt loop. This can be used as a strip storage between casting and rolling mill. A strip accumulator is therefore very advantageous since the mass flow fluctuations in the casting rolling mill, in particular in the rolling mill, can be compensated for as a result of the changes in thickness in the longitudinal direction of the metal strip. This in turn makes it possible, for example, to avoid ligament tears.

For the strip accumulator can be designed in particular as a band storage device, which is operated in such a way that caused by the predetermined thickness profile mass flow fluctuations in the Gießwalzverbundanlage be compensated.

In a further advantageous variant of the invention, the casting device is operated in such a way that by means of the casting device a predetermined, with the desired thickness course tuned actual thickness profile of the metal strip is produced, which has the metal strip before entering the rolling train. As a result, the at least one rolling stand is supported in the longitudinal profiling of the metal strip by the casting device. In particular, high rolling forces can thereby be avoided and unwanted processing speed deviations between casting device and rolling train can be reduced. As a result, the corresponding division of the setting of the thickness profile of the casting device and rolling train, it is possible that the rolling stand is always operated so that it does not encounter plant technical limits or technological limits in the setting of the desired thickness course. Technical limits are, for example, the setting position and / or positioning speed of the work rolls, technological limits are, for example, thickness decreases, which would be required to set the desired thickness course, but lead to no longer tolerable deviations eg in the flatness of the metal strip. This can be avoided if the longitudinal profiling of the metal strip is divided between the casting device and the rolling train.

In a further advantageous embodiment of the invention, the rolling mill in the mass flow direction is followed by a thickness measuring device, by means of which the rolled thickness of the metal strip is detected, wherein at least one actuator for the rolling train is adjusted depending on the detected thickness and the predetermined thickness profile. This makes it possible to make a comparison between the desired nominal thickness for a strip section behind the rolling mill stand and the actually present actual thickness for this strip section. Based on this, an improved adjustment of the actuators and / or a model adaptation can be made which, for future band sections to be rolled, further approximates the actual actual thickness behind the rolling stand to the desired target thickness behind the rolling stand.

Further, it is advantageous that the rolling mill in the mass flow direction is followed by a flatness measuring device, by means of which the flatness of the metal strip is detected, wherein at least one actuator, in particular a bending cylinder is set for the rolling train in dependence on the detected flatness and a predetermined thickness profile. In this way it can be ensured that, on the one hand, the desired thickness profile is set and, on the other hand, the requirements for the metal strip with regard to flatness are met.

In a preferred embodiment of the method according to the invention, the thickness profile is set with a rolling train which comprises a rolling stand which has a set of work rolls having a diameter of less than 800 millimeters, in particular 200 millimeters to 600 millimeters, wherein the Gießwalzverbundanlage is operated such that a Speed of the metal strip immediately in the mass flow direction in front of the rolling mill is less than 7 meters / second, in particular less than 5 meters / second, is set.

In particular, it is advantageous that the inlet belt speed is set in such a way and the rolling stand is designed such that a ratio of an inlet belt speed of the metal strip in the roll stand to a maximum Anstellgeschwindigkeit the work rolls of the rolling mill for thickness control of the metal strip is less than 3500, in particular less than 2000, in particular between 200 and 1500, is. Preferably, the above ratio is maintained for all operated rolling mills of a rolling train, as long as the rolling train comprises more than a single stand. As a rule, the entry speed can be influenced or controlled by means of the casting speed. By using the work rolls with a diameter of less than 800mm in combination with the above-mentioned ratio of inlet belt speed to maximum setting speed of the rolling stand thickness gradients can be adjusted, which allow substantially all required Dickengradienten for the production of longitudinally profiled rolling stock. This makes it possible to realize almost all thickness profiles desired by the customer during hot rolling. In particular, while maintaining the above ratio of inlet belt speed to maximum Anstellgeschwindigkeit sufficient dynamics for the rolling mill for processing the metal strip in the desired manner available. Under Dickengradient the change in the thickness per unit length of the metal strip, ie in the longitudinal direction of the metal strip, understood. Anstellgeschwindigkeit is understood to mean the hydraulic setting speed for setting the work rolls under load.

The inventive method can be used particularly advantageously for cast roll mills in which a two-roll caster or a belt caster, also referred to as direct strip casting, is used. Because these casting facilities are Dünnbandgießeinrichtungen. The metal strip produced by the casting device is usually already relatively thin, in particular, this has a thickness of less than 3 mm. On the one hand, this allows final thicknesses in the range of 0.7 mm and below to be produced in the rolling train at comparatively low infeed belt speeds. In particular, two casting rollers may be considered as casting machines in which the two rolls are arranged in a vertical plane, i. the metal is shed horizontally. These systems can be used, for example, for aluminum, magnesium, zinc, etc., i. E. for "soft" metals. Furthermore, two-roll casters may also be used in which the rolls are arranged in a horizontal plane, i. the metal is shed vertically. This is e.g. common for carbon steels and other steels.

The device-related part of the object is achieved by a control and / or regulating device for a Gießwalzverbundanlage for producing longitudinally profiled profiled Metallbande, with a machine-readable program code, which control commands, which cause the control and / or regulating device for performing the method according to one of claims 1 to 10. In particular, the control and / or regulating device may comprise a plurality of modules, which are designed to implement the individual method steps of the embodiments of the method according to the invention in a machine-readable manner for the control and / or regulating device, so that these are controlled by the control and / or Control device can be arranged.

Further, the device-related part of the object is achieved by a Gießwalzverbundlage for producing thick-profiled in its longitudinal direction metal strip, wherein the metal strip in the stationary operation of the Gießwalzverbundanlage continuously from the caster to a rolling mill comprising at least one rolling mill, with a control device according to claim 11, wherein the control device according to claim 11 is operatively connected to the at least one rolling stand. As a result, a device is provided with which longitudinally profiled metal strip can be produced during hot rolling.

In a preferred embodiment of the device according to the invention, the rolling train comprises a roll stand which has a set of work rolls having a diameter of less than 800 millimeters, in particular 200 millimeters to 600 millimeters, wherein the rolling stand is designed and operated such that a ratio of an inlet velocity of the Metal bands in rolling mill to a maximum Anstellgeschwindigkeit the work rolls of the rolling stand for thickness control of the metal strip is less than 3500, in particular less than 2000, in particular between 200 and 1500, is. If the Gießwalzverbundanlage has a rolling train with more than one rolling mill, then the above ratio is preferably maintained for each rolling mill. As a result, a device is provided by means of which almost all of the customer desired thickness profiles during hot rolling realized are because appropriate Dickengradienten are rollable.

Another advantage is that in addition the casting device with the control and / or regulating device according to claim 11 is operatively connected. This makes it possible to divide the thickness profile and thus the load of the individual units for producing the desired target thickness for a band section in expediently between the casting device and rolling train. By means of a tape tracking, the belt section cast in accordance with the specifications of the control and / or regulating device is then processed in a time- and location-correct manner through the rolling train in such a way that the belt section after the rolling train has as large a desired desired thickness as possible. This avoids that, for example, individual actuators of the rolling train for producing the desired thickness curve run to their limits or technological problems, such as flatness errors, due to, for example. To high thickness decreases in the rolling stand, occur.

It is also advantageous that the casting device is designed as Zweirollengießeinrichtung or as Umlaufbandgießeinrichtung. The advantages arise according to the above statements on the corresponding method claim.

FIG 1

eine schematische Darstellung einer Gießwalzverbundanlage mit einer Umlaufbandgießeinrichtung,

FIG 2

eine schematische Darstellung einer Gießwalzverbundanlage mit einer vertikal gießenden Zweirollengießeinrichtung,

FIG 3

eine schematische Darstellung einer Gießwalzverbundanlage mit einer horizontal gießenden Zweirollengießeinrichtung,

FIG 4

ein Ablaufdiagramm zur schematischen Darstellung einer Ausführungsform des Verfahrens.

Further advantages of the invention will become apparent from the embodiments, which are explained in more detail with reference to the following schematic drawings. Show it:

FIG. 1

a schematic representation of a Gießwalzverbundanlage with a Umlaufbandgießeinrichtung,

FIG. 2

a schematic representation of a Gießwalzverbundanlage with a vertically cast Zweirollengießeinrichtung,

FIG. 3

a schematic representation of a Gießwalzverbundanlage with a horizontally cast Zweirollengießeinrichtung,

FIG. 4

a flowchart for schematically illustrating an embodiment of the method.

FIG. 1 shows a Gießwalzverbundanlage comprising a Umlaufbandgießeinrichtung 1 'and a "direct strip casting" device, with which liquid metal M is cast on a revolving cast strip. Here, the metal solidifies and there is a thin metal strip B, which is weiterverarbeitbar in the Gießwalzverbundanlage.

The continuous rolling system further comprises a rolling mill 2. The rolling mill 2 may have a rolling stand or even several rolling stands. The rolling train 2 is used for hot forming of the metal strip B. In particular, by means of this, the metal strip B is rolled to its final thickness.

The metal strip B extends continuously from the circulating belt caster 1 'to the rolling line 2. The metal strip generally has, i. in stationary operation of the Gießwalzverbundanlage, all units of the Gießwalzverbundanlage coupled to each other via the metal strip B.

Between the rolling train 2 and the Umlaufbandgießeinrichtung 1 ', a tape storage S' is arranged. The tape storage S 'is formed as a pair of S-rollers. The rotation of the pair of rollers about a pivot point located between the rollers, the tape length, which is guided over the rollers change. This can provide a tape storage volume.

Downstream of the rolling train 2 in the mass flow direction, a thickness measuring device 3 and a flatness measuring device 4 are provided. These can be configured as desired. Corresponding devices are sufficiently known to the person skilled in the art. Possibly. These may also be arranged in the direction of mass flow in front of the rolling train 2, so that the at least one rolling stand of the rolling train 2 can be operated in a pilot-controlled manner, that is, the measured belt section passes through still the rolling mill. As a result, this band section can still be influenced in the desired manner.

The flatness measuring device 4 and the thickness measuring device 3 are operatively connected to a control and / or regulating device 10 which controls or regulates the rolling train 2 such that the desired thickness profile is generated in the longitudinal direction of the metal strip B.

The recorded data for flatness and thickness are fed to the control and / or regulating device 10. Based on these data and on the basis of the predetermined desired thickness profile, the rolling train 2 is operated.

The control and / or regulating device 10 is upgraded by means of machine-readable program codes 12 to operate the rolling train 2 according to an embodiment of the method according to the invention. The machine-readable program code 12 is stored, for example, by means of a storage medium 11 on the control and / or regulating device 10. Furthermore, by means of the control and / or regulating device 10 to be rolled target thickness profiles for the metal strip can be specified.

In operation, the entry speed V of the metal strip into the rolling mill is set such that the entry speed of the metal strip B of 5 meters / second is not exceeded for any of the rolling mill 2 covered by the rolling mill. This can be achieved by a corresponding adjustment of the casting speed.

Furthermore, work rolls are used for producing the thickness profiles in the longitudinal direction of the metal strip, which have a diameter D of 500 millimeters. Due to the reduced diameter D of the work rolls compared to the commonly used work rolls during hot rolling - these often have a diameter of about 1000mm -, the rolling forces can be increased to the metal strip B, whereby higher thickness decreases can be achieved. At the same time be rolled higher density gradients. Furthermore, the work rolls can be set to influence the thickness at a setting speed of at most 4 millimeters / second.

This achieves an exemplary maximum ratio of inlet velocity V to setting speed of 1250, which is very well suited for thickness profiling of the metal strip in the longitudinal direction.

As a result of the thickness profiling in the longitudinal direction of the metal strip, fluctuations in the entry speed V of the metal strip into the rolling train or in a rolling stand usually occur. These fluctuations are compensated by means of the band memory S ', so that as far as possible a constant tension for the metal strip during the flexible hot rolling is realized.

FIG. 2 shows a Gießnalzverbundanlage comprising a Zweiroll Casting 1 for the vertical casting of liquid metal M. Further, the casting and rolling mill comprises a rolling mill 2, in which the cast metal is rolled to its final thickness. Analogous to FIG. 1 For example, the rolling train may comprise a rolling stand or a plurality of rolling stands.

The metal strip B cast by the twin roll caster 1 forms a loop S due to gravity and then enters a rolling train 2 comprising at least one rolling stand.

In mass flow direction behind the rolling train 2 and the roll stand is analogous to the under FIG. 1 described Gießwalzverbundanlage arranged a thickness measuring device for measuring the thickness of the emerging from the rolling train 2 metal strip B.

Furthermore, a flatness measuring device 4 is also arranged downstream of the rolling train 2 in the direction of mass flow. The thickness measuring device 3 and the flatness measuring device 4 are with a control and / or regulating device 10 operatively connected to which the detected data are supplied.

The control and / or regulating device 10 is in accordance with the in FIG. 1 made statements to induce an embodiment of the method according to the invention. In the present case, the control and / or regulating device 10 is operatively connected to the rolling train 2 on the one hand and to the casting device 1 on the other hand.

The control and / or regulating device 10 controls the setting of the desired thickness profile in the longitudinal direction for the metal strip B across, that is. the control and / or regulating device 10 already causes a casting of the liquid metal M with a corresponding thickness profile in the longitudinal direction based on the desired desired thickness profile, so that the metal strip B already has varying thicknesses in the longitudinal direction when entering the rolling train 2. This thickness pre-profile produced by the casting device 1 is subsequently rolled by the at least one rolling stand of the rolling train 2 such that the desired nominal thickness profile is obtained in the longitudinal direction. In this way, the required load for the desired thickness profiling can be divided between the units, so that the rolling train 2 does not approach system limits when rolling the longitudinal profile of the metal strip.

Further, in addition to the thickness pre-profile, the casting speed of the two-roll caster 1 is controlled such that the ratio of the lead-in speed V of the metal strip B to the rolling stand and the setting speed of the work rolls to influence the thickness of the rolling stand is less than 2,000. For this purpose, a rolling mill is used, which has a pitch of 3 millimeters / second and a casting speed of 2 meters / second set. This results in a ratio of about 670, with which it is possible, without reaching plant engineering limits, desired thickness profiles in the longitudinal direction in the desired Way to produce. Particularly advantageous this can be combined with work rolls with diameters smaller than 800 millimeters.

FIG. 3 shows a Gießnalzverbundanlage comprising a Zweiroll Casting 1 for horizontal casting of liquid metal M. In contrast to FIG. 2 the casting rolls are arranged here so that the metal can be cast horizontally and not vertically. Furthermore, forms in the system according to FIG. 3 , usually no belt loop of the potted metal, so that - as in FIG. 1 - Preferably, a strip storage device between the casting device 1 and rolling mill 2 is provided.

One reason why horizontal and not vertical shedding is due to the tensile strength of the metal to be cast. While in a plant according to FIG. 2 it comes to a design of a sling whose own weight must be borne by the band, this load of the band in a system according to FIG. 3 be avoided. This is therefore usually to be used for the casting of such metal and alloys whose tensile strength is too low to the weight of a sling, as in FIG. 2 shown to wear. Examples of such metals include magnesium, zinc or aluminum.

In addition, the apply for FIG. 2 made statements essentially analogous to FIG. 3 , In particular, there are no substantial differences from the embodiment for the rolling train, the flatness measuring device or the thickness measuring device FIG. 2 in front. The statements too FIG. 2 can easily go up for these parts FIG. 3 be transmitted.

In particular, the rolling operation is usually independent of whether the metal is cast horizontally or vertically. It is only on the possibly present changed casting speeds, material strengths, etc. take into account and adjust the rolling operation accordingly.

FIG. 4 shows an exemplary flowchart for an embodiment of the method according to the invention. In the flowchart, it is assumed that the Gießwalzverbundanlage is in a steady state operation, wherein as casting a Zweirollengießeinrichtung according to FIG. 2 is used.

In a method step 101, a desired thickness profile in the longitudinal direction of the metal strip is specified for the hot strip to be rolled. This gives, for example, a repetitive periodic thickness profile for the metal strip.

In a method step 102, a manipulated variable for the caster and the rolling train is determined based on the predetermined thickness profile from method step 101. In particular, a thickness profile to be provided by the casting device is determined. As a rule, this deviates from the thickness progression to be provided by the rolling train in the longitudinal direction, since the casting rolls can only deliver a comparatively inaccurate thickness profile. However, this thickness curve significantly simplifies the machining of the metal strip with regard to the provision of the desired thickness profile. Furthermore, a thickness profile is determined for the rolling train, which results in that the metal strip emerges with an actual thickness profile in the longitudinal direction of the rolling train, which substantially corresponds to the desired desired thickness profile in the longitudinal direction of the metal strip.

The casting rolls of the casting device are controlled or regulated in such a way by means of the control and / or regulating device that the predetermined course of thickness is present before entry into the rolling train. In addition, the casting device is controlled by means of the control and / or regulating device in dependence on the maximum setting speed of the roll stand such that the entry speed is in the rolling mill below a corresponding threshold, for example. 3 meters / second. This will ensure that the ratio of belt entry speed into the rolling stand and setting speed of the work rolls for influencing the metal strip thickness is such that the desired thickness profile can also be produced. This is usually possible if the ratio of belt entry speed and setting speed for each rolling stand of the rolling train is less than 3500, in particular between 200 and 1500.

For the desired thickness profile, a plurality of operating points are provided, which are to be traversed by the rolling stand for a particular band section. These operating points give, for example, in addition to the desired thickness, a desired rolling force and a desired rolling gap for the rolling stand. These operating points are preferably determined by means of a process model.

In a method step 103, the corresponding strip section is cast in accordance with the thickness profile predetermined for the casting device.

Subsequently, the corresponding strip section enters the rolling train and is rolled according to the predetermined course of thickness in a method step 104 in such a way that the strip section has an actual thickness profile which substantially corresponds to the intended target thickness profile for this strip section.

The thickness of the metal strip is preferably controlled, in particular with the aid of detected setting positions for the work rolls, detected rolling forces, detected thicknesses and / or detected profiles of the metal strip.

In particular, in a method step 105, a thickness measurement and a flatness measurement are carried out. The data obtained from the measurement are supplied to the control and / or regulating device, which influences the actuators of the roll stand based on this data such that the subsequently rolled strip sections the actual thickness of the desired thickness and the actual flatness of the desired flatness is further approximated.

In a method step 106, a query is made as to whether the method should be aborted. If not, the procedure is executed until terminated.

Such a procedure is according to all types of equipment 1 to FIG. 3 feasible, but neither on the process as such nor on the types of equipment according to 1 to FIG. 3 limited.

The method can also be used for cast roll composite systems at correspondingly low rolling speeds, which, for example, uses a mold as a casting device.

Claims (15)

Method for producing metal strip (B) by means of a cast roll composite installation, comprising a casting device (1, 1 ') for casting metal and a rolling train (2) comprising at least one rolling stand for hot working the metal strip (B), wherein the cast roll composite plant is operated in such a way in that the metal strip (B) extends continuously between the casting device (1, 1 ') and the rolling train (2), wherein the rolling train (2) is fed continuously with metal strip, wherein the rolling train (2) is given a desired thickness profile according to in which the rolling train (2) rolls the metal strip (B), characterized in that the course of thickness has at least two different nominal thicknesses for different strip sections in the longitudinal direction of the metal strip (B), and that the course of thickness is formed such that the first and / or or the second target thickness is set at least twice. Method according to claim 1,
characterized in that in addition to the at least two different desired thicknesses associated desired rolling forces and / or setpoint roll gap openings are specified. Method according to claim 1 or 2,
characterized in that the thickness course comprises repetitive, in particular periodically repeating, changes in thickness in the longitudinal direction of the metal strip (B). Method according to one of the preceding claims,
characterized in that between the pouring device (1, 1 ') and the rolling train (2) a strip accumulator (S, S'), in particular a belt loop (S), is present, with which caused by the predetermined thickness profile mass flow fluctuations are compensated. Method according to one of the preceding claims,
characterized in that the casting device (1, 1 ') is operated such that by means of the casting device (1, 1') a predetermined, with the desired thickness course tuned actual thickness profile of the metal strip (B) is produced, which the metal strip ( B) before entering the rolling train (2). Method according to one of the preceding claims,
characterized in that the rolling train (2) in the mass flow direction, a thickness measuring device (3) is arranged by means of which the rolled thickness of the metal strip (B) is detected, wherein at least one actuator for the rolling train (2), in particular at least one rolling mill, in dependence is adjusted by the detected thickness and the predetermined thickness profile. Method according to one of the preceding claims,
characterized in that the rolling train (2) in the mass flow direction is a flatness measuring device (4) is arranged, by means of which the flatness of the metal strip (B) is detected, wherein at least one actuator, in particular a bending cylinder, for the rolling train (2) in dependence on recorded flatness and a predetermined thickness profile is set. Method according to one of the preceding claims,
characterized in that the course of the thickness is adjusted with a rolling train (2) which comprises a rolling mill comprising a set of work rolls having a diameter (D) of less than 800 millimeters, in particular 200 millimeters to 600 millimeters, wherein the cast roll composite plant operates in this way is that an inlet speed (V) of the metal strip (B) is set in the rolling stand smaller than 7 meters / second, especially less than 5 meters / second, in particular between 1 meter / second and 4 meters / second. Method according to claim 8,
characterized in that the lead-in speed is set and the millstand is designed such that a ratio of a lead-in belt speed (V) of the metal strip (B) to the mill stand to a maximum stop speed of the work rolls of the mill stand for thickness-influencing the metal strip (B) is less than 3500, especially less than 2000, in particular between 200 and 1500, is. Method according to one of the preceding claims,
characterized in that as a casting device (1, 1 ') a Zweirollengießeinrichtung (1) or a Umlaufbandgießeinrichtung (1') is used. Control and / or regulating device (10) for a cast roll composite system for producing longitudinally profiled metal strip (B), with a machine-readable program code (12) which contains control commands which the control and / or regulating device (10) for carrying out the method according to any one of the preceding claims. Cast roll composite layer for producing thickness-profiled metal strip (B) in its longitudinal direction, wherein the metal strip (B) in stationary operation extends continuously from the casting device (1, 1 ') to a rolling mill (2) comprising at least one rolling stand, with a control and / or control device (10) according to claim 11, wherein the control and / or regulating device (10) with the rolling train (2) is operatively connected. Cast roll composite layer according to claim 12,
characterized in that the rolling train (2) comprises a rolling mill comprising a set of work rolls having a diameter (D) of less than 800 millimeters, in particular 200 millimeters to 600 millimeters, the mill stand being designed and so is operated such that a ratio of an infeed speed (V) of the metal strip (B) in the roll stand to a maximum setting speed of the work rolls of the rolling mill for influencing the thickness of the metal strip (B) is less than 3500, in particular less than 2000, in particular between 200 to 1500 Cast roll composite layer according to claim 12 or 13,
characterized in that additionally the casting device (1, 1 ') is operatively connected to the control and / or regulating device (10) according to claim 11. Cast roll composite layer according to one of claims 12 to 14,
characterized in that the casting device (1, 1 ') as Zweirollengießeinrichtung (1) or as Umlaufbandgießeinrichtung (1') is formed.

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