EP2691188B1 - Operating method for a rolling train - Google Patents

Description

• wobei einem Steuerrechner für die Walzstraße Gerüstparameter des Walzgerüsts beschreibende Gerüstdaten vorgegeben werden,
• wobei der Steuerrechner im Rahmen einer Stichplanberechnung das Walzen des flachen Walzgutes im Walzgerüst beschreibende Größen ansetzt,
• wobei die angesetzten Größen in Verbindung mit das flache Walzgut vor dem Walzen in dem Walzgerüst beschreibenden Anfangsdaten und den Gerüstdaten des Walzgerüsts den sich beim Walzen des flachen Walzgutes im Walzgerüst ergebenden Walzspalt und dessen Asymmetrie beschreiben,
• wobei die das Walzen des flachen Walzgutes im Walzgerüst beschreibenden Größen für die Gesamtwalzkraft, die Walzkraftdifferenz zwischen Antriebs- und Bedienseite und die Anstellungsdifferenz zwischen Antriebs- und Bedienseite charakteristisch sind,
• wobei die Anfangsdaten zumindest für die Breite, die mittlere Dicke und die mittlere Festigkeit des flachen Walzgutes charakteristische Größen umfassen,
• wobei der Steuerrechner im Rahmen der Stichplanberechnung anhand der Anfangsdaten, der Gerüstdaten und der angesetzten Größen mittels eines Keilmodells einen Auslaufkeil und/ oder einen Säbel ermittelt, die für das flache Walzgut erwartet werden, wenn das flache Walzgut im Walzgerüst mit den angesetzten Größen gewalzt wird.

The present invention relates to an operating method for a rolling train for rolling a flat rolling stock in at least one rolling stand of the rolling train,

• wherein a control computer for the rolling mill framework parameters of the mill stand descriptive framework data are given,
• wherein the control computer, as part of a pass-plan calculation, sets the variables describing the rolling of the flat rolling stock in the mill stand,
• wherein the estimated sizes in connection with the starting data describing the flat rolling stock before rolling in the rolling stand and the rolling mill stand data describe the rolling gap resulting from rolling of the flat rolling stock in the roll stand and its asymmetry,
• wherein the variables describing the rolling of the flat rolling stock in the roll stand for the total rolling force, the rolling force difference between the drive and operating side and the difference in employment between drive and operating side are characteristic,
• wherein the initial data comprise characteristic quantities at least for the width, the average thickness and the average strength of the flat rolling stock,
• wherein the control computer in the context of Stichplanberechnung based on the initial data, the framework data and the applied sizes by means of a wedge model determines a discharge wedge and / or a saber, which are expected for the flat rolling, when the flat rolling is rolled in the rolling stand with the set sizes.

The present invention further relates to a computer program comprising machine code, which can be processed directly by a control computer for a rolling train for rolling a flat rolling stock and its execution by the control computer causes the control computer to operate the mill train according to such an operating method.

The present invention further relates to a control computer for a rolling mill for rolling a flat rolling stock, wherein the control computer is designed such that it operates the mill train according to such an operating method.

The present invention further relates to a rolling mill for rolling a flat rolled stock, which is equipped with such a control computer.

Such objects are for example from the WO 2006/063 948 A1 known.

In the known operating method, the estimated sizes, in conjunction with the initial rolling data describing the flat rolling stock before rolling in the rolling stand, and the stand data of the rolling stand, describe the rolling gap resulting from rolling the flat rolled stock in the rolling stand. As part of the stitch plan calculation on the basis of the initial data, the scaffolding data and the set sizes, the control computer determines, using a model, expected sizes expected for the flat rolled stock when the flat rolled stock is rolled in the rolling stand with the set sizes. The control computer varies in the context of Stichplanberechnung according to a strategy at least one of the scheduled sizes, so that the determined expected sizes are at least approximated the end sizes. The control computer transfers the variables determined within the stitch plan to a basic automation of the rolling stand, so that the flat rolling stock is rolled in the roll stand according to the varied sizes.

From the DE 10 2009 043 400 A1 is a concept for model-based determination of actuator setpoints for a hot strip mill with multiple rolling stands known. With this concept, a desired target contour of the rolling column of the stands can be set when the actuator setpoint values are executed. In a first method step of this concept, a desired speed wedging of the hot strip is specified after each stand. In the second step, values for strip thickness contours at the outlets of the frameworks are determined with the aid of flatness models. In the third step will be determined by means of material flow models for each frame applied rolling force distributions. In the fourth step, the target contour for the tape drive members is determined. In the fifth step, the actuator setpoint values are calculated from the target contour for each scaffold with the aid of an optimization method.

That in the DE 10 2009 043 400 A1 described method is applied while the flat rolling passes through a multi-stand rolling mill. For the implementation of the method both inlet side and outlet side measured variables of all involved rolling stands are required.

Of the DE 10 2009 043 401 A1 an equivalent stored disclosure is to be taken.

When rolling metal, the shape of the rolling stock is an important factor from the beginning of the process on all intermediate steps. Besides thickness, width, profile and flatness, the wedges (i.e., the asymmetric portion of the thickness across the width of the flat rolled stock) and the saberiness (i.e., the curvature of the flat rolled stock in the rolling plane) are also important parameters. Both a wedge and a saber are undesirable because these sizes (if different from 0) make the further process steps more difficult and even impossible or even result in rejects.

Due to the conservation of material, the wedging and the saberiness are still closely linked. Runs, for example, a one-sided cold slab in the rolling stand, so due to the unilaterally higher rolling force and the associated unilaterally higher springing of the rolling stand, the colder side is less severely rolled than the warmer side, unless otherwise controlled. As a result, a thickness wedge and a saber corresponding thereto are formed. If, by contrast, an already wedged flat rolling stock runs into the rolling stand and becomes the thickness wedge When rolling the flat rolled material eliminated, so a saber is generated by the rolling.

If the flat rolling stock already has a thickness wedge, in the prior art often the upper set of rolls and the lower set of rolls are pivoted against each other, so that during the rolling pass the relative wedge is retained and consequently no curvature (= saber) is generated. The pivoting is performed manually by an operator due to the observation of the rolling stock. There are also known methods for automatically assisting the operator to anticipate or at least reduce these manual interventions. These methods are based on measurements of differential rolling forces and regulations, ie they are carried out within the framework of basic automation.

For wedge slabs, i. Slabs which have a thickness wedge, methods are still known which eliminate the wedge by imposing asymmetric Zugverteilungen, but at the same time prevent the formation of a saber. This is achieved by causing a cross flow in the material.

It is difficult or even impossible to determine only from the rolling load signal a setpoint for a correction member, by means of which the Auslaufkeilkorrekt is affected.

The object of the present invention is to provide possibilities by means of which an outlet wedge and / or an expiring saber can be specifically predicted and adjusted in a flexible manner.

The object is achieved by an operating method for a rolling train with the features of claim 1. Advantageous embodiments of the method of operation are the subject of the dependent claims 2 to 9.

• dass dem Steuerrechner von außen eine Keilstrategie vorgegeben wird,
• dass die das Walzen des flachen Walzgutes im Walzgerüst beschreibenden Größen zusätzlich für mindestens eine weitere die Walzenkontur beeinflussende Walzgerüstgröße sowie den Versatz des flachen Walzgutes relativ zur Walzgerüstmitte charakteristisch sind,
• dass der Steuerrechner
  • -- anhand der Gesamtwalzkraft, der Walzkraftdifferenz zwischen Antriebs- und Bedienseite, der weiteren Walzgerüstgrößen, der Breite des flachen Walzgutes und des Versatzes des flachen Walzgutes relativ zur Walzgerüstmitte einen Walzenkonturanteil,
  • -- anhand der Anstellungsdifferenz zwischen Antriebs- und Bedienseite und einer Gerüstauffederungsdifferenz zwischen Antriebs- und Bedienseite einen Verkippungsanteil und
  • -- anhand des Walzenkonturanteils und des Verkippungsanteils den Auslaufkeil und/oder den Säbel ermittelt,
• dass der Steuerrechner im Rahmen der Stichplanberechnung gemäß der vorgegebenen Keilstrategie mindestens eine der angesetzten Größen variiert, so dass der ermittelte Auslaufkeil einem Sollauslaufkeil und/oder der Säbel einem Sollsäbel zumindest angenähert werden, und
• dass der Steuerrechner die im Rahmen der Stichplanberechnung ermittelten variierten Größen an eine Basisautomatisierung des Walzgerüsts übergibt, so dass das flache Walzgut im Walzgerüst gemäß den variierten Größen gewalzt wird.

According to the invention, it is provided to design an operating method of the type mentioned at the outset,

• that the control computer is given a wedge strategy from the outside,
• that the variables describing the rolling of the flat rolling stock in the roll stand are additionally characteristic of at least one further roll stand size influencing the roll contour and the offset of the flat rolled stock relative to the rolling stand center,
• that the control computer
  • - Based on the total rolling force, the rolling force difference between the drive and operating side, the other roll stand sizes, the width of the flat rolled material and the offset of the flat rolled material relative to the rolling mill center a roll contour fraction,
  • - Based on the difference in employment between the drive and operating side and a Gerüstfederfederungsifferenz between the drive and operating side a Verkippungsanteil and
  • determined on the basis of the roller contour portion and the Verkippungsanteils the discharge wedge and / or the saber,
• in that the control computer varies at least one of the set variables in the stitch plan calculation in accordance with the predetermined wedge strategy, so that the determined wedge is at least approximated to a desired outlet wedge and / or the saber is at least approximated to a desired saber, and
• in that the control computer transfers the varied variables determined in the context of the passplan calculation to a basic automation of the rolling stand, so that the flat rolling stock is rolled in the rolling stand according to the varied sizes.

The wedge strategy may, for example, be directed as needed to maintain the relative wedge, wedge = 0, on the bounding of a saber.

The other roll stand sizes can also be determined as needed. In particular, they may comprise a roll-back force and / or a crown of rolls of the roll stand and / or an entanglement and / or a displacement of the rolls of the roll stand against each other.

The sizes describing the rolling of the flat rolling stock in the roll stand can be supplemented by further sizes. The further variables may include, for example, the on and / or the outgoing side train in the flat rolling stock and / or the corresponding differences between the drive and operating side and / or the corresponding distributions over the width of the flat rolling stock.

• anhand der Gesamtwalzkraft, der Walzkraftdifferenz zwischen Antriebs- und Bedienseite, der weiteren Walzengerüstgrößen, der Breite des flachen Walzgutes und des Versatzes des flachen Walzgutes relativ zur Walzgerüstmitte einen Biegelinienanteil,
• anhand der Gesamtwalzkraft, der Walzkraftdifferenz zwischen Antriebs- und Bedienseite und der Breite des flachen Walzgutes einen Abplattungsanteil und
• anhand des Biegelinienanteils und des Abplattungsanteils den Walzenkonturanteil ermittelt.

It is preferably provided that the control computer

• based on the total rolling force, the rolling force difference between drive and operating side, the other roll stand sizes, the width of the flat rolled material and the offset of the flat rolled relative to the mill center a Biegelinienanteil,
• Based on the total rolling force, the rolling force difference between the drive and operating side and the width of the flat rolling a flaking share and
• determined by the Biegelinienanteils and Abplattungsanteils the roll contour portion.

By doing so, the roll contour fraction can be particularly efficiently, i. with relatively little computational effort to be determined.

In a preferred embodiment of the present invention, it is provided that the framework parameters of the rolling stand for the drive and the operating side each comprise their own springing characteristic. With this configuration, a particularly flexible modeling of the discharge wedge and / or the saber is possible.

The initial data may be purely symmetrical data, for example characterizing the average thickness and the average strength of the flat rolled stock. However, it is also possible that the initial data additionally comprise variables which are characteristic of a strength wedge-for example a temperature wedge-and / or for a thickness wedge and / or for a (inlet-side) saber of the flat rolling stock.

It is possible that the target discharge wedge and / or the target saber are fixedly assigned to the control computer. For example, the target discharge wedge and / or the target saber can be set to 0. Alternatively, it is possible that the target discharge wedge and / or the target saber be explicitly specified to the control computer. Again, alternatively, it is possible that the control computer determines the target discharge wedge using the initial data of the flat rolling stock. In this case, the control computer may in particular determine the relative wedge, i. the ratio of thickness wedge to medium thickness of the flat rolled material, maintained.

It is possible to carry out the operating method according to the invention - based on the respective rolling process - only once for each flat rolling stock. Preferably, however, the control computer determined over the length of the flat rolled material for several positions respectively the discharge wedge and varies according to the wedge strategy at least one of the scheduled sizes. This procedure is particularly advantageous when the flat rolling stock is a band. However, it is equally applicable if the flat rolling stock is a heavy plate.

• für die Ermittlung eines Teils oder direkt als Teil der Anfangsdaten des flachen Walzgutes für mindestens einen späteren Walzvorgang desselben flachen Walzgutes in demselben oder einem anderen Walzgerüst,
• für die Adaption des Keilmodells und/oder
• für die Visualisierung des tatsächlichen Auslaufkeils und/ oder des tatsächlichen Säbels des flachen Walzgutes verwenden.

In a preferred embodiment of the present invention, the control computer takes during the rolling of the flat rolled material in the rolling stand occurring rolling stand conditions and / or during and / or after rolling the flat rolled material in the rolling stand for the actual outlet wedge and / or the actual saber of the flat rolling characteristic sizes opposite. The control computer can in particular the sizes received in this case

• for the determination of a part or directly as part of the initial data of the flat rolled stock for at least one subsequent rolling operation of the same flat rolled stock in the same or another rolling stand,
• for the adaptation of the wedge model and / or
• for the visualization of the actual discharge wedge and / or the actual saber of the flat rolled stock.

The object of the invention is further achieved by a computer program of the type mentioned. The computer program is designed in this case such that the control computer executes an operating method with all steps of an operating method according to the invention.

The object is further achieved by a control computer for a rolling train for rolling a flat rolling stock, which is designed such that it carries out such an operating method during operation.

The object is further achieved by a rolling mill for rolling a flat rolling stock, which is equipped with such a control computer.

FIG 1

schematisch eine Walzstraße,

FIG 2 bis 5

Ablaufdiagramme,

FIG 6

einen Abschnitt eines flachen Walzgutes und

FIG 7

schematisch eine weitere Walzstraße.

Further advantages and details will become apparent from the following description of exemplary embodiments in conjunction with the drawings. In a schematic representation:

FIG. 1

schematically a rolling mill,

FIGS. 2 to 5

Flowcharts,

FIG. 6

a section of flat rolled stock and

FIG. 7

schematically another rolling mill.

FIG. 1 shows a rolling mill for rolling a flat rolling stock 1. The rolling mill is according to FIG. 1 designed as multi-stand rolling train, which has several - usually four to eight - rolling stands 2. In the rolling stands 2 of the rolling mill, the flat rolling stock 1 is rolled.

The rolling train is equipped with a control computer 3. The control computer 3 is designed such that it operates the rolling train according to an operating method with all the steps of an operating method according to the invention. The operating method according to the invention will be explained in more detail below. The corresponding design of the control computer 3 is effected by a computer program 4, with which the control computer 3 is programmed. The computer program 4 can for this purpose on a suitable disk 5 - purely exemplary is the disk in FIG. 1 as a USB memory stick - be saved. The storage on the data carrier 5 is in machine-readable form, as a rule in an exclusively machine-readable form, for example in electronic form. The computer program 4 comprises machine code 6. The machine code 6 can be processed directly by the control computer 3. The processing of the machine code 6 by the control computer 3 causes the control computer 3 to operate the rolling train according to the operating method according to the invention.

According to FIG. 2 - is always complementary FIG. 1 with - are the control computer 3 in a step S1 set framework data. The framework data describe framework parameters of a rolling mill 2 executing a specific rolling process, in particular its spring-back characteristic.

In a step S2, the control computer 3 for the specific rolling process in the specific rolling mill 2 initial data are known, which describe the flat rolling stock 1 before rolling in the respective rolling stand 2. The initial data include at least the width b, the average thickness d and a characteristic of the average strength of the flat rolled material 1 size, for example, the temperature T. It is possible that the initial data to the control computer 3 are specified from the outside. Alternatively, it is possible for the control computer 3 to determine the initial data itself. For example, the initial data may result, in whole or in part, from a previous rolling operation that is performed prior to the rolling process now under consideration. This will be explained later become. It is possible for the control computer 3 to carry out the step S2 as part of a passplan calculation.

In a step S3, the control computer 3 sets in the context of Stichplanberechnung sizes that describe the rolling of the flat rolled stock 1 in the respective rolling stand 2. Due to the fact that the control computer 3 executes the step S3 in the stitch plan calculation, the control computer 3 executes the step S3 before starting rolling of the rolling stock 1 in the corresponding rolling mill 2.

The stated sizes describe, in conjunction with the initial data d, b, T of the flat rolling stock 1 and the framework data of the respective rolling stand 2, the roll gap, which results in the respective rolling stand 2 during rolling of the flat rolling stock 1. They further describe the asymmetry of the roll gap seen in the direction of the roll axes. The control computer 3 is therefore able to determine in a step S4 within the stitch plan calculation on the basis of the initial data b, d, T, the framework data and the applied variables by means of a wedge model 7 an outlet wedge K, which is expected for the flat rolling stock 1 when the flat rolling stock 1 is rolled in the respective stand 2 with the sizes set. Alternatively or additionally, a saber K 'can be determined by means of the wedge model 7, which is expected for the flat rolling stock 1 when the flat rolled stock 1 is rolled in the rolling stand 2 with the sizes set.

The wedge model 7 comprises mathematical-physical equations by means of which the behavior of the rolling stand 2 and of the flat rolling stock 1 is described. It is also realized by the computer program 4 or the machine code 6.

The term "outlet wedge" has the following meaning: An outlet wedge is the asymmetrical portion of the thickness function seen over the bandwidth b. The term "saber" means the curvature of the flat rolled stock 1 to the side.

In a step S5, the control computer 3 varies as part of the stitch plan calculation according to a wedge strategy at least one of the set sizes. The variation takes place in such a way that the determined discharge wedge K is at least approximated to a desired discharge wedge. Alternatively or additionally, the determination can be made such that the saber K 'is approximated to a target saber.

In a step S6, the control computer 3 transfers the variables determined in the stitch plan calculation to a basic automation 8 of the respective rolling stand 2. In addition, the functional dependencies of the outlet wedge K and / or the saber K 'are additionally transferred from the set sizes. The basic automation 8 is thereby able to roll the respective rolling stand 2 in accordance with the varied sizes, while the flat rolling stock 1 passes through the respective rolling stand 2. The step S6 is also executed by the control computer 3 before the flat rolling stock 1 is rolled in the respective rolling stand 2.

The operating method according to the invention will be described below in connection with FIG. 3 explained again. FIG. 3 includes steps S11 to S16. The steps S11 to S16 are similar to the steps S1 to S6 of FIG FIG. 2 , However, the steps S11 to S16 show more detailed configurations than the steps S1 to S6.

The embodiment of steps S11 to S16 can be implemented independently of one another. It is not necessary, for example, to combine the more concrete embodiment of step S11 with the more concrete embodiment of step S13. For example, the sequence of steps S11 and S2 to S6 could be combined or the sequence of steps S1, S2, S13 and S4 to S6 and the like more.

In step S11-analogous to step S1-the framework data are specified. According to step S11, the framework parameters include of the rolling stand 2 - separately for the drive and the operating side - each have their own Auffederungscharakteristik.

In step S12, the control computer 3 becomes aware of the quantities b, d, T already mentioned in connection with step S2. In addition, the initial data may include, for example, a strength wedge-in particular a temperature wedge ΔT-and / or a thickness wedge Δd. Likewise, in addition, a variable characteristic of an incoming saber of the flat rolling stock 1 can be known, for example a corresponding curvature k.

Furthermore, the control computer 3 may be aware of further data in step S12, for example the desired wedge and / or the nominal saber or maximum permissible values for the discharge wedge and / or the outgoing saber.

Step S13 shows some of the set sizes. According to the step S3, the set sizes are characteristic at least for the total rolling force F. Preferably, the set sizes are still characteristic of the rolling force difference δF between the drive and operating side. Other sizes that may be used are further roll stand sizes B, C, δB that influence the roll contour and the difference in setting δs between the drive side and the operating side. Optionally, an offset V can be used with. The offset V indicates how far the flat rolling stock 1, offset relative to the rolling mill center, enters the relevant rolling stand 2.

According to the step S14, the control computer 3 determines a bending line part K1 from the total rolling force F, the rolling force difference δF, the other rolling stand sizes B, C, δB, the width b of the flat rolled material 1, and the offset V. Furthermore, in step S14, the control computer 3 determines a flattening portion K2 on the basis of the total rolling force F, the rolling force difference δF and the width b of the flat rolling stock 1. Furthermore, the control computer 3 determines in the context of step S14 based on the employment difference δs and a Gerüstfederfederungsifferenz δg between the drive and operator side a Verkippungsanteil K3. Based on the bending line portion K1, Abplattungsanteil K2 and the Verkippungsanteil K3 then determines the control computer 3 the Auslaufkeil K. If the initial data also includes values for the inlet side wedge and the inlet side saber and continue the incoming and outgoing trains and their differences or distributions are known or a material transverse flow is excluded, in addition, the outlet-side saber K 'can be determined.

Steps S15 and S16 are of steps S5 and S6 of FIG FIG. 2 identical.

• Die Walzen 9 des betrachteten Walzgerüsts 2 werden in finite Elemente aufgeteilt. Es wird eine Matrix ermittelt, welche eine gegebene Verschiebung der finiten Elemente aus einer jeweiligen Ruhelage mit der sich ergebenden Druckverteilung im Walzspalt in Beziehung setzt (sogenannte elastische Gleichungen). Diese Matrix wird invertiert, so dass anhand einer gegebenen Walzkraftverteilung der zugehörige Konturverlauf des Walzspalts ermittelbar ist. Die entsprechende Vorgehensweise zum Ermitteln der Matrix und deren Invertierung sind Fachleuten bekannt. Eine analoge Vorgehensweise ist möglich, wenn alternativ oder zusätzlich zum Übergang vom Walzgut 1 zur Arbeitswalze 9 ein Übergang zwischen zwei Walzen 9 des Walzgerüsts 2 betrachtet wird. Eine analoge Vorgehensweise ist weiterhin auch möglich, wenn die Verschiebungen als kontinuierliche Funktionen angesetzt werden (sogenannte Greensche Funktion).

As an alternative to the procedure of step S14, in which separately the bending line component K1 and the flattening component K2 are determined, it is possible to directly determine a roller contour component which corresponds to the sum of the bending line component K1 and the flattening component K2. If this procedure is to be implemented, it is possible, for example, to proceed as follows:

• The rollers 9 of the rolling mill 2 considered are divided into finite elements. A matrix is determined which relates a given displacement of the finite elements from a respective rest position with the resulting pressure distribution in the roll nip (so-called elastic equations). This matrix is inverted, so that based on a given rolling force distribution of the associated contour of the roll gap can be determined. The corresponding procedure for determining the matrix and its inversion are known to those skilled in the art. An analogous procedure is possible if, alternatively or in addition to the transition from the rolling stock 1 to the work roll 9, a transition between two rolls 9 of the rolling stand 2 is considered. An analogous procedure is also possible if the shifts are applied as continuous functions (so-called Green function).

FIG. 4 shows further possible embodiments of the step S13 of FIG. 3 , Analogous to the ratio of FIG. 2 and 3 Steps S21 and S22 are alternatively realizable.

• Eine Walzenrückbiegekraft B,
• gegebenenfalls deren Differenz δB zwischen Antriebs- und Bedienseite,
• eine (temperatur- und verschleißabhängige) Balligkeit C von Walzen 9 des betreffenden Walzgerüsts 2,
• eine Verschiebung der Walzen 9 des betreffenden Walzgerüsts 2 in Richtung der Walzenachsen und
• eine Verschränkung der Walzen 9 des Walzgerüsts 2 gegeneinander, d.h. eine gegensinnige Verschwenkung der Walzen 9 des Walzgerüsts 2 in und entgegen einer Walzgutlaufrichtung x.

In step S21 possible further rolling stand sizes are explained. According to step S21, the further roll stand sizes may comprise at least one of the following sizes:

• A roll bending force B,
• if necessary, their difference δB between drive and operating side,
• a (temperature and wear-dependent) crown C of rollers 9 of the respective rolling stand 2,
• a displacement of the rollers 9 of the respective rolling stand 2 in the direction of the roll axes and
• an entanglement of the rollers 9 of the roll stand 2 against each other, ie an opposite pivoting of the rollers 9 of the roll stand 2 in and against a Walzgutlaufrichtung x.

The crown C can optionally be actively influenced by local cooling of the rollers 9.

• Der einlaufseitige Zug Z im flachen Walzgut 1,
• der auslaufseitige Zug Z' im flachen Walzgut 1,
• die entsprechenden Differenzen δZ, δZ' zwischen Antriebsund Bedienseite und
• die entsprechenden Verteilungen über die Breite b des flachen Walzgutes 1.

According to step S22, the control computer 3 can continue to be given additional variables which describe the rolling of the flat rolling stock 1 in the respective rolling stand 2. In particular, the control computer 3 can additionally be preset with at least one of the following variables:

• The inlet-side train Z in the flat rolling stock 1,
• the outlet-side train Z 'in the flat rolling stock 1,
• the corresponding differences ΔZ, ΔZ 'between drive and operating side and
• the corresponding distributions over the width b of the flat rolled material. 1

The operating method according to the invention can be configured in various ways. Examples of such embodiments are in FIG. 5 shown.

FIG. 5 shows various possible embodiments. The embodiments can be implemented independently of each other. Furthermore, the possible embodiments in the context of FIG. 5 explained in connection with steps S1 to S6 already in FIG. 2 were explained. Alternatively, together or individually, steps S11 through S16 of FIG FIG. 3 be used, if necessary in the embodiments according to FIG. 4 ,

According to FIG. 5 In addition, a step S31 is present. In step S31, the control computer 3 is given the wedge strategy. For example, the control computer can be specified whether it should set the discharge wedge K and / or the saber K 'to 0, whether it should retain an already existing relative asymmetry (possibly in which distribution on discharge wedge K and saber K').

Furthermore, there is a step S32. In step S32, the control computer 3 determines the target discharge wedge and / or the target saber using the initial data of the flat rolling stock 1. In particular, the control computer 3, for example, in the case that the flat rolling stock 1 before rolling in the respective rolling stand 2 already has a wedge and / or a saber and further due to the thickness d of the rolling stock 1, a material flow is no longer or only in limited Scope is possible to specify the desired wedge and the target saber such that the target saber is still within tolerable range and the target wedge describes the remaining asymmetry of the flat rolled material 1. The determination of the desired wedge and / or the Sollsäbels in the context of step S32, of course, only if the desired wedge and / or the target saber are not already specified and determined by the wedge strategy as such.

Furthermore, steps S36 to S38 (or at least one of the steps S36 to S38) may be present.

In step S36, the control computer 3 receives rolling stand conditions which occur during the rolling of the flat rolling stock 1 in the respective rolling stand 2. For example, the control computer 3 can receive the actual rolling forces and / or the actual rolling force differences or the corresponding values of the bending-back force.

In step S37, the control computer 3 during the rolling of the flat rolling stock 1 in the respective rolling stand 2 can take sizes that are characteristic of the actual discharge wedge and / or the actual saber of the flat rolled material 1. For example, the actual exit-side train or its difference or distribution can be detected and fed to the control computer 3.

In step S38 corresponding sizes can be accepted after rolling the flat rolled stock 1. For example, the flat rolling stock 1 may be measured after complete rolling in the respective rolling stand 2 under certain circumstances. It is also possible for suitable sizes to be detected at one point or at several locations behind the rolling stand 2 and closed based on the variables on the actual outlet-side curvature of the flat rolling stock 1. Corresponding procedures are known to the person skilled in the art.

The control computer 3 can use the quantities taken in the course of the steps S36, S37 and / or S38 for different purposes. For example, it is possible for the control computer 3 to output a visualization of the actual discharge wedge and / or the actual saber of the flat rolling stock 1-for example via a display device or a printer-to an operator 10 in a step S41. Alternatively or additionally, it is possible that the control computer 3 in a step S42, the actual, accepted sizes compares with corresponding expected sizes and adapted the wedge model 7 based on the comparison.

Furthermore, it is possible for the control computer 3 to use the quantities received to determine actual states of the flat rolling stock 1 and to take them into account during subsequent processing steps. For example, the control computer 3 can check in a step S43 whether the processing of the flat rolling stock 1 has ended. If this is not the case, the control computer 3 can proceed to a step S44 in which the control computer 3 uses the initial data of the flat rolling stock 1 for a later treatment step - in particular a subsequent rolling process - of the same flat rolling stock 1 or at least using this data determined a part of the initial data of the flat rolling stock 1. The subsequent rolling process can, depending on the type of rolling train, be carried out in the same or in another rolling stand 2.

In the case that the rolling of the flat rolling stock 1 has not yet ended, that is to say still further rolling operations take place, a step S46 can additionally be present in addition. In step S46, the control computer 3 may change the wedge strategy under certain circumstances. For example, the control computer 3 can determine the wedge strategy such that the discharge wedge K and the saber K 'are corrected if and as long as the incoming thickness d of the flat rolling stock 1 is greater than a critical thickness. However, if the thickness d of the flat rolled stock 1 before rolling is (are) smaller than the critical thickness, the control computer 3 may change the wedge strategy so that from this point on, the run-out wedge K existing at that time is maintained. Other possibilities of change are also given.

It is possible that the operating method according to the invention per flat rolled product 1 is executed only once. Preferably, however, it is carried out several times. In particular, the control computer 3 according to FIG. 6 over the length of the flat rolling stock Determine a plurality of positions (sections 11) and determine for each section 11 respectively the outlet wedge K and / or the saber K 'and according to the respective given wedge strategy at least one of the set sizes - for example, the rolling force difference δF or the offset V - in the sense of Approximation to a respective setpoint vary. It is possible for the control computer 3 to carry out the determination of the discharge wedge K and / or the saber K 'for all considered sections 11 before the first section 11 of the rolling stock 1 enters the rolling stand 2 under consideration. However, at least the control computer 3 executes the process for each section 11 at a time before the respective section 11 enters the rolling mill 2 executing the respective rolling process.

In conjunction with the 1 to 6 has been described above, that a flat rolled stock 1 is rolled in a multi-stand rolling mill, wherein the Walzgutlaufrichtung x is always the same. With such an embodiment of the rolling train, each rolling pass is made in another rolling stand 2 of the rolling train. This embodiment of the rolling train is particularly suitable when the flat rolling stock 1 is a band. In principle, however, this procedure is equally applicable if the flat rolled stock 1 is a heavy plate (a plate).

In principle, it is also possible that according to the representation of FIG. 7 the rolling train reversing works, that is designed as a reversing mill. In this case, the individual rolling operations (rolling passes) take place in the same rolling stand 2, wherein the rolling stock running direction x changes from rolling pass to rolling pass. This embodiment is particularly suitable when the flat rolling stock 1 is a heavy plate. In principle, however, it is equally applicable when the flat rolled stock 1 is a strip. In this case, the reversing mill is preferably designed as a Steckel mill.

The present invention has many advantages. In particular, a targeted determination of the outlet wedge K and / or the saber K 'and an integration of this determination in the stitch plan calculation is possible.

The above description is only for explanation of the present invention. The scope of the present invention, however, is intended to be determined solely by the appended claims.

Claims (12)

1. Operating method for a rolling train for rolling a flat workpiece (1) in at least one rolling stand (2) of the rolling train,

   - wherein stand data describing stand parameters of the rolling stand (2) is prescribed to a control computer (3) for the rolling train,

   - wherein as part of a rolling schedule calculation, the control computer (3) sets variables (F, δF, G, δs, V) which describe the rolling of the flat workpiece (1) in the rolling stand (2),

   - wherein the set variables (F, δF, G, δs, V), the initial data (b, d, T) which describes the flat workpiece (1) before rolling in the rolling stand (2), and the stand data of the rolling stand (2) together describe the resultant roll nip and the asymmetry thereof during the rolling of the flat workpiece (1) in the rolling stand (2),

   - wherein the variables (F, δF, G, δs, V) describing the rolling of the flat workpiece (1) in the rolling stand (2) are characteristic of the total rolling force (F), the rolling force difference (δF) between drive side and operator side, and the screw-down difference (δs) between drive side and operator side,

   - wherein the initial data (b, d, T) comprises characteristic variables at least for the width (b), the average thickness (d) and the average strength of the flat workpiece (1),

   - wherein as part of the rolling schedule calculation, on the basis of the initial data (b, d, T), the stand data and the set variables (F, δF, G, δs, V), by means of a taper model (7), the control computer (3) determines an expected delivery taper (K) and/or an expected camber (K') for the flat workpiece (1) when the flat workpiece (1) is rolled in the rolling stand (2) using the set variables (F, δF, G, δs, V),

   wherein

   - a taper strategy is externally prescribed to the control computer (3),

   - the variables (F, δF, G, δs, V) describing the rolling of the flat workpiece (1) in the rolling stand (2) are additionally characteristic of at least one further rolling stand variable (B, C, δB) which influences the rolling contour, and the offset (V) of the flat workpiece (1) relative to the rolling stand centre,

   - the control computer (3) determines

   -- a rolling contour portion on the basis of the total rolling force (F), the rolling force difference (δF) between drive side and operator side, the further rolling stand variables (B, C, δB), the width (b) of the flat workpiece (1) and the offset (V) of the flat workpiece (1) relative to the rolling stand centre,

   -- a tilt portion (K3) on the basis of the screw-down difference (δs) between drive side and operator side and a stand frame stretch difference (δg) between drive side and operator side, and

   -- the delivery taper (K) and/or the camber (K') on the basis of the rolling contour portion and the tilt portion (K3).

   - as part of the rolling schedule calculation, the control computer (3) varies at least one of the set variables (F, δF, G, δs, V) in accordance with the prescribed taper strategy, such that the determined delivery taper (K) is brought at least close to a desired delivery taper and/or the camber (K') is brought at least close to a desired camber, and

   - the control computer (3) transfers the varied variables (F, δF, G, δs, V) that are determined by the rolling schedule calculation to a basic automation system (8) of the rolling stand (2), such that the flat workpiece (1) is rolled in the rolling stand (2) in accordance with the varied variables (F, δF, G, δs, V).
2. Operating method according to claim 1,
   characterised in that
   the further rolling stand variables (B, C, δB) comprise a rolling reverse bending force (B) and/or a convexity (C) of rollers (9) of the rolling stand (2) and/or a transposition and/or a displacement of the rollers (9) of the rolling stand (2) relative to each other.
3. Operating method according to claim 1 or 2,
   characterised in that
   the variables (F, δF, G, δs, V) describing the rolling of the flat workpiece (1) in the rolling stand (2) may additionally comprise the feed-side tension and/or the delivery-side tension (Z, Z') in the flat workpiece (1) and/or the corresponding differences (δZ, δZ') between drive side and operator side and/or the corresponding distributions over the width (b) of the flat workpiece (1).
4. Operating method according to claim 1, 2 or 3,
   characterised in that
   the control computer (3) determines

   - a deflection curve portion (K1) on the basis of the total rolling force (F), the rolling force difference (δF) between drive side and operator side, the further rolling stand variables (B, C, δB), the width (b) of the flat workpiece (1) and the offset (V) of the flat workpiece (1) relative to the rolling stand centre,

   - a flattening portion (K2) on the basis of the total rolling force (F), the rolling force difference (δF) between drive side and operator side, and the width (b) of the flat workpiece (1), and

   - the rolling contour portion on the basis of the deflection curve portion (K1) and the flattening portion (K2).
5. Operating method according to one of the preceding claims,
   characterised in that
   the stand parameters of the rolling stand (2) comprise an individual frame stretch characteristic for the drive side and operator side in each case.
6. Operating method according to one of the preceding claims,
   characterised in that
   the initial data (b, d, T) additionally comprises characteristic variables for a strength taper - e.g. a temperature taper (δT) - and/or for a thickness taper (δd) and/or for a camber of the flat workpiece (1).
7. Operating method according to one of the preceding claims,
   characterised in that
   the control computer (3) determines the desired delivery taper and/or the desired camber using the initial data (b, d, T) of the flat workpiece (1).
8. Operating method according to one of the preceding claims,
   characterised in that
   the control computer (3) determines the respective delivery taper (K) and/or the camber (K') for a plurality of positions (11) over the length of the flat workpiece (1) and varies at least one of the set variables (F, δF, G, δs, V) according to the taper strategy.
9. Operating method according to one of the preceding claims,
   characterised in that
   the control computer (3) receives rolling stand states that occur during the rolling of the flat workpiece (1) in the rolling stand (2), and/or characteristic variables for the actual delivery taper and/or the actual camber of the flat workpiece (1) during and/or after the rolling of the flat workpiece (1) in the rolling stand (2), and that the control computer (3) uses the received variables for the purpose of

   - determining part, or directly as part, of the initial data (b, d, T) of the flat workpiece (1) for at least one subsequent rolling operation of the same flat workpiece (1) in the same or a different rolling stand (2),

   - adapting the taper model (7), and/or

   - visually depicting the actual delivery taper and/or the actual camber of the flat workpiece (1).
10. Computer program comprising machine code (6) which can be directly executed by a control computer (3) for a rolling train for rolling a flat workpiece (1) and whose execution by the control computer (3) results in the control computer (3) operating the rolling train in accordance with an operating method having all the steps of an operating method according to one of the preceding claims.
11. Control computer for a rolling train for rolling a flat workpiece (1),
    characterised in that
    the control computer is so designed as to operate the rolling train according to an operating method having all the steps of an operating method according to one of claims 1 to 9.
12. Rolling train for rolling a flat workpiece (1),
    characterised in that
    the rolling train is equipped with a control computer (3) according to claim 11.

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