EP3107666A1 - Simple pre-control of a wedge-type roll-gap adjustment of a roughing stand - Google Patents

Abstract

A number of flat metal items to be rolled (3) are fed to a number of rolling stands (1, 2) of a rolling installation one after the other over a feed path (4). The flat items to be rolled (3) are rolled by means of the number of rolling stands (1, 2). In the number of rolling stands (1, 2), the respective flat item to be rolled (3) is first rough-rolled in at least one roughing pass with a wedge-type roll gap adjustment (ds) and then finish-rolled in finishing passes. After the finish-rolling of the respective flat item to be rolled (3), a thickness taper (dd) that is present in the respective finish-rolled flat item to be rolled (3) is recorded by measuring instruments. The thickness taper (dd) is compared with a target taper (dZ). On the basis of a deviation of the thickness taper (dd) present in the respective finish-rolled flat item to be rolled (3) from the target taper (dZ) and the wedge-type roll gap adjustment (ds), a new wedge-type roll gap adjustment (ds) is determined for the at least one roughing pass. The wedge-type roll gap adjustment (ds) in the case of the at least one roughing pass for the flat item to be rolled (3) that is to be rolled next is set in a way corresponding to the newly determined value of the wedge-type roll gap adjustment (ds), so that the flat item to be rolled (3) that is to be rolled next is rough-rolled in the at least one roughing pass with the newly determined value of the wedge-type roll gap adjustment (ds).

Description

description

Simple pre-control of a wedge setting of a roughing stand The present invention relates to an operating method for a rolling mill,

 wherein a number of rolling stands of the rolling mill are fed successively a plurality of first flat rolled metal goods via a first feed path,

- wherein the first flat rolled goods are rolled by means of the number of rolling stands,

 wherein the respective first flat rolling stock in the number of rolling stands is initially rough-rolled in at least one roughing pass with a first wedge setting and then finish-rolled into finishing passes,

 wherein, after the finish rolling of the respective first flat rolling stock, a first thickness wedge present in the finish-rolled respective first flat rolling stock is measured,

- Wherein in the finish-rolled respective first flat

 Walzgut existing first thickness wedge with a first

 Target wedge is compared,

 - Based on a deviation of the existing first thickness wedge of the first target wedge and the first wedge position a new first wedge position for the at least one roughing pass is determined and

 - wherein the first wedge adjustment in the at least one

Pre-roll pass for the next to be rolled first flat rolling stock is set according to the newly determined value of the first wedge adjustment, so that the first flat rolling to be rolled next in the at least one roughing pass is pre-rolled with the newly determined value of the first wedge adjustment. The present invention further relates to a Steuerpro ^¬ program for control means of a rolling mill, wherein the control program comprises machine code that is processable by the control device, wherein execution of the machine NENCODES caused by the control device that the STEU ^¬ ereinrichtung operates the rolling mill according to such an operating method. The present invention further relates to a control device of a rolling mill, wherein the control device is programmed with such a control program.

The present invention further relates to a rolling mill, wherein the rolling mill has a first feed path via which a plurality of rolling stands of the rolling mill are successively supplied with a plurality of first flat rolled metal goods,

 - wherein the rolling mill comprises a number of rolling stands, by means of which the first flat rolled goods are rolled,

wherein the respective first flat rolling stock in the number of rolling stands is initially rough-rolled in at least one roughing pass with a first wedge setting and then finish-rolled into finishing passes,

- wherein the rolling mill has a thickness measuring device, by means of which, after the finish rolling of the respective first flat rolling stock, a first thickness wedge present in the finish-rolled respective first flat rolling stock is detected metrologically.

A quality feature in the rolling of flat rolling is the size of a wedge, ie, see an asymmetric thickness distribution of the flat rolled product across the width of the flat rolled product ge ^¬. As a rule, a thickness wedge is undesirable.

To avoid or eliminate a thickness wedge, various approaches are known.

For example, JP Hll-010 215 A discloses the abovementioned objects.

From WO 2006/063 948 AI is an operating method for a rolling mill with at least one rolling stand for rolling a Bandes in several rolling operations known. In the context of this method of operation, a computer determines rolling stand settings for each rolling operation on the basis of a rolling mill model for each rolling operation and transmits these settings to the rolling mill carrying out this rolling operation. The rolling stand adjusts according to the transmitted settings and rolls the belt accordingly. As part of the rolling mill model, the calculator also determines an expectorant thickness wedge expected during this rolling process. By means of a measuring device dependent on the actual leak-proof thickness wedge of the tape measured variable is detected and transmitted to the computer. On the basis of the measured variable and the expected leak-proof thickness wedge, the computer adapts the model of the rolling train. As a rule, is one of the Eingangsparame ^¬ ter one in which each rolling process expected einlaufsei- term thick wedge.

From WO 2012/159 849 AI a Betriebsverfah- ren for a rolling mill with at least one rolling stand for rolling a strip is also known. In this operating method, a control computer for the rolling mill is given framework parameters which describe the rolling stand. As part of a pass schedule calculation, the control computer sets of sizes, which write the rolling of flat material to be rolled in the roll stand be ^¬. The sizes used, in conjunction with the framework parameters and sizes describing the flat stock prior to rolling in the mill stand, describe the nip and its asymmetry that results from rolling the stock in the mill. As part of the stitch plan calculation, the control computer determines, by means of a model of the rolling train, an outlet-seeping thickness wedge and / or a siphon that is ready for siphoning and which is expected for the flat rolling stock during rolling in the rolling mill stand. The control computer is given a wedge strategy from the outside, ie criteria by means of which the control computer can determine what the leak-proof thickness wedge should be. In accordance with the wedge strategy The control computer calculates optimized control variables for the rolling stand.

From WO 2006/119 984 AI a method for hot rolling of slabs is known, wherein the slabs in at least one

Pre-scaffolding be rolled out to Vorbändern. In this method, the Vorbandgeometrie is specifically influenced to reshape a saber or wedge slab in a straight and wedge-free Vorband. Under this procedure, are disposed before and behind the rough rolling mill side guides, which can be placed against the rolling stock and are applied to the rolling stock by means of which cross ^¬ forces, to prevent the formation ei ^¬ nes saber in the rolling stock. In particular, WO 2006/119 984 AI represents an advance, since according to the teaching of WO 2006/119 984 AI at least a straight and wedge-free opening band can be generated. However, the teaching of WO 2006/119 984 AI only leads to a significant success, if not for other reasons in the finishing line the straight and wedge-free Vorband again a wedge and / or a saber are imprinted.

From WO 2013/174 602 AI a further embodiment of the teaching of WO 2006/119 984 AI is known, in which the side guides additionally have a roller which can be made in the transverse direction of the rolling stock, so that by means of the roller a transverse force can be practiced on the rolling stock ^¬ . From WO 2009/016086 AI is known, the wedging of a

Vorbandes while maintaining the saber clearance during roughing by using compressors in conjunction with the rough rolling to influence. The object of the present invention is to provide opportunities by means of which avoided in a simple manner, a thickness wedge in finish-rolled flat rolling or can at least be reduced, at the same time a saber formation should be avoided.

The object is achieved by an operating method with the features of claim 1. Advantageous embodiments of the operating ^method according to the invention are the subject of dependent claims 2 to 4.

According to the invention, an operating method of the type mentioned at the outset is configured by

 that during the pre-rolling of the respective first flat rolling stock in the rolling mill which carries out the at least one roughing pass before and / or behind this rolling stand, side guides and / or stufferers are set against the rolling stock,

- That the side guides and / or upsets exert lateral forces on the respective first flat rolling, which prevent Sä ^¬ belbildung during rough rolling, and

- That a change in the first wedge adjustment is at least up to a certain limit of the change of the first wedge position proportional to the deviation of the present in the finish-rolled respective first flat rolling first thickness wedge of the first target wedge. Thus, the present invention is based firstly on the ^¬ He knowledgeable that it is irrelevant whether in intermediate stages - at ^¬ play, in the opening act - a deviating from the target wedge Di ^¬ ckenkeil exists. It is only decisive that the target wedge is achieved in the final product, that is to say in the flat rolling stock after the finish rolling. Secondly, the present ^¬ de invention is based on the realization that in the event that nevertheless deviates the thick wedge from the target wedge, can be counteracted this deviation for the next, not yet rolled flat rolled by ent ^¬ speaking setting the roll stand in rough rolling , Here, no complicated model ^{¬-regulation} of the rolling process is required. It is sufficient if the deviation of the thickness wedge from the target wedge tends to be counteracted. This is ensured by the procedure according to the invention.

Although the procedure according to the invention presupposes that the results, in particular the resulting thickness wedge, can be reproduced from rolling stock to rolling stock. However, this is the case in practice, at least within uniform flat rolled goods. This often applies even if wedge positions are used during finish rolling during the respective finishing passes. Such Keilanstellungen can be taken for example manually by an operator of the rolling mill before ^¬ to make the tape run low. Because crucial is only the reproducibility of the thickness ^¬ wedge, which is still given in this case.

The first target wedge may be determined as needed. Often, the first target wedge will be zero. It is also possible, depending ^¬ but that the first target wedge has a value different from zero.

It is preferably provided that the change in the first wedge setting increases monotonically with the ratio of a mean rolling stock thickness of the respective first flat rolled stock after roughing and after finish rolling. This makes it possible to track the first wedge adjustment even if different Endwalzdicken to be rolled.

Preferably, it is provided that during the rolling of each ^¬ weiligen first flat rolled stock a RAC is performed. The term "RAC" stands for "roll alignment control". Roll ^¬ align ment control means that is responsive to a lateral migration of the rolling stock during the rolling on ^¬ occurring defects tend differential rolling force between the operator side and drive side ^¬ and / or. As part of the roll alignment control, additional wedge adjustment of the corresponding rolling stand is determined in order to counteract the differential rolling forces and / or the migration of the rolling stock. The roll alignment Control is still effective during the rolling process ^¬ sam.

In rolling flat stock, in some cases, the number of stands becomes in addition to the first flat

Rolled goods via a second feed path successively fed to a second second flat rolling stock. For example, egg ^¬ ner multi-stand finishing train with roughing mill arranged upstream of slabs can on the one hand directly from a continuous casting and on the other hand be supplied from a continuous casting facility and / or a slab storage area. In such a case, the second flat rolled goods are also rolled by the number of rolling stands. Here, analogously to the first flat rolled goods, the respective second flat rolled stock in the number of rolling stands is first pre-rolled in at least one roughing pass with a second wedge setting and then finish-rolled into finishing passes. Here too, after the finish rolling of the respective second flat rolling stock, a second thickness wedge present in the finish-rolled respective second flat rolling stock is measured. Furthermore, here too the second thickness wedge is compared with a second target wedge and, based on a deviation of the second thickness wedge present in the finish-rolled second flat rolling stock from the second target wedge and the second wedge position, a new second wedge position is determined for the at least one roughing pass. Finally, here too, the second wedge adjustment is set in the at least one roughing pass for the second flat rolling stock to be rolled next according to the newly determined value of the second wedge setting, so that the second flat roll to be rolled next

Walzgut in which at least one roughing pass is pre-rolled with the newly determined value of the second wedge adjustment. As a result of the separate treatment of the first rolled goods and the respective change in the wedge setting on the one hand and the second rolled goods and of the respective change in wedge setting determined for these rolling goods, the optimum wedge adjustments can be achieved be determined separately for the first and second rolled goods.

The second target wedge may be determined as needed. Often the second target wedge will have the value zero, analogous to the first target wedge. However, again analogous to the first target wedge, it is also possible for the second target wedge to have a value other than zero. With regard to the second rolling goods, of course, the advantageous embodiments are possible, which are possible with respect to the first rolling stock.

The procedure can also be extended to other feed routes.

The object is further achieved by a control program having the features of claim 5. According to the invention, a control program of the aforementioned kind is characterized tet ausgestal- that the execution of the machine code caused by the STEU ^¬ ereinrichtung that the control means operates the rolling mill according to an inventive method of operation. The object is further achieved by a control device with the features of claim 6. According to the invention egg ^¬ ne control device of the type mentioned is programmed with a control program according to the invention. The object is further achieved by a rolling mill with the features of claim 7. According to the invention, a rolling mill of the type mentioned in the introduction is configured in that the rolling mill has side guides and / or upsweeters in front of and / or behind the rolling mill which carries out the at least one roughing pass, which are set against this rolling stand during roughing of the respective first flat rolled stock and transverse forces to the respective first bottle che rolling, which prevent saber formation during Vorwal ^¬ zen, and

- That the rolling mill has a control device according to the invention, which operates the rolling mill according to an inventive operating method.

The above-described characteristics, features and advantages of this invention, as well as the manner in which they are achieved, will become clearer and more clearly understood in connection with the following description of the embodiments, which will be described in detail in conjunction with the drawings. Here are shown in a schematic representation:

1 shows a rolling mill,

2 a nip of a roughing stand,

 3 shows a cross section through a flat rolling stock,

 4 shows a section of the rolling mill from above and

5 shows another rolling mill. 1 shows an embodiment of a rolling mill, in which a single roughing stand 1 and several finishing stands 2 - usually between four and seven finishing stands 2 - are present. At least the finished scaffolds 2 are traversed by flat rolling ^¬ goods 3 successively. The flat rolled goods 3 are in the finishing stands 2 each in a single

Walzstich (finish stitch) rolled. The flat rolled goods 3 are made of metal, for example steel or aluminum. However, other metals are possible, such as copper.

In the embodiment according to FIG 1, each Fertigge ^¬ Rüst 2 thus performs a single rolling pass. It is also possible for the roughing stand 1 to carry out reversing several rolling passes (pre-roll stitches). Are present so that a single roughing stand 1 and a plurality of finishing stands 2, the roughing reversing 1 performs multiple rolling passes and each Fertigge ^¬ Rüst each 2 executes a single rolling pass - - In connection with this often be applied for striking embodiment, the pre- underlying invention explained below. However, the present invention ^¬ is not limited to this configuration.

Thus, for example, several roughing scaffolds 1 may be present, which are passed through in succession by the flat rolled goods 3. In this case, it is possible for each roughing stand 1 to execute one roughing pass each. Alternatively, in this case, too, the roughing stands 1 can be reversed several times by the flat rolled goods 3. Also, in individual cases, a single roughing stand 1 could be present, which is passed through by the flat rolled goods 3 in a single roll pass. In both cases, the finished scaffolds 2 would continue to be passed successively by the flat rolled goods 3, with each finishing scaffold 2 each executing a single rolling pass. Furthermore, it is possible that in the case of several roughing passes per respective flat rolled stock 3, the respective flat rolled stock 3 is not rolled in individual one of the roughing passes, that is, it is not reduced in thickness. But it is also possible that a total of only one rolling mill is present, which is repeatedly reversed by the flat rolling stock 3. In this case, all rolling passes - ie both the Vorstiche and the Fer ^¬ tigstiche - advertising from the same mill run the.

The rolling stands 1, 2, the flat rolled goods 3 are successively fed via a Zuführweg 4. The feed path 4 can be designed, for example, as a continuous casting plant with a downstream equalizing furnace. Alternatively, the Zuführweg 4 may be designed as a ferry with downstream furnace (for example, a tunnel furnace). Also, the Zuführweg 4 may be formed as a slab store with downstream furnace. Other embodiments are possible.

After feeding one of the flat rolled goods 3 to the first rolling mill 1 of the rolling mill - according to the embodiment of FIG 1 thus after feeding to the roughing stand 1 - the je- stays awhile flat rolled metal 3 in the rolling stands 1, 2 in ^¬ jeweili gen rolling passes (in reversing multiple Vorwalzstichen in the finishing stands 2 in a respective final pass in the roughing stand 1) is first rough rolled, and then finish-rolled. In particular, the rough rolling in the roughing stand 1 takes place with a wedge adjustment ds of the roughing stand 1. The rolling mill 1 is currency ^¬ rend of the respective Vorwalzstichs therefore set such that the roll gap s of the roughing stand 1 according to the Dar ^¬ position in FIG 2 over the width b of the roughing stand 1 seen wedge-shaped runs. Thus, the roll gap s of the rough stand 1 has a wedge engagement ds, wherein the wedge engagement ds is given by the relationship ds sDS - sOS (1). SDS and SOS are in Equation 1, the nip SDS at the driving side and the roll gap on the operator SOS ^¬ side of the roughing stand 1. The wedge adjustment ds is clearly shown exaggerated ben in FIG 2 for reasons of better illustration.

The wedge adjustment ds can be the same for all roughing passes. Alternatively, the wedge setting ds can be determined individually from roughing pass to roughing pass. For example, the wedge setting ds of the respective roughing pass can be correlated with the outlet-side desired thickness of the respective roughing pass, in particular be proportional to the outlet-side desired thickness of the respective roughing pass. Other approaches are possible.

After performing the roughing passes, the finished stitches are executed. The respective flat rolling stock 3 is therefore finish-rolled in the finishing stands 2 in the finishing passes. Where necessary, the finishing stands 2 during the execution tion of each finished stitch - be subjected to a respective Keilanstel ^¬ lung - for example, as part of the roll alignment control. The finishing stands 2 - to be more precise: the final finishing stand 2 - is a thickness measuring device

5 downstream. By means of the thickness measuring device 5, after the finish rolling of the respective flat rolling stock 3, a thickness wedge dd, which is present in the finish-rolled respective flat rolling stock 3, is detected metrologically. The thickness wedge dd is according to FIG 3 - analogous to the wedge ds - example, ^{¬ given} by the relationship dd = dDS - dOS (2). DDS and DOS are in Equation 2, the rolling-stock thickness DDS at the driving side and the rolling stock thickness SOS on the control ^¬ side of the flat material to be rolled 3 on the outlet side of the last finishing pass exporting finishing stand 2. The thickness wedge dd is shown in FIG 3 - analogous to the wedge adjustment ds - for reasons the better illustration clearly exaggerated. It is also possible to determine the thickness wedge dd basis of other large ^¬ SEN. For example, it is common to measure the rolling stock thickness dDS and dOS not directly on the side edges of the flat rolled stock 3, but at a distance from the side edges. The distance may be 25 mm or 40 mm, for example. Another meaningful value can be used as a distance from the page margins. It is also possible to detect the Walzgutdicke at several points on the Walzgutbreite and to optimize based on the recorded Walzgutdicken example, a parameterized description of Walzgut ^¬ thickness as a function of location in the width direction. In this case, one of the parameters of the parameterized description, which is characteristic for the asymmetry of the rolling stock thickness, can be used to determine the thickness wedge dd. Other approaches are possible. The thickness measuring device 5 is connected according to FIG 1 data processing with a control device 6. The control device

6 is programmed with a control program 7. The Steuerpro ^¬ program 7 includes machine code 8, which from the Steuereinrich- 6 can be processed. The processing of the machine code 8 by the control device 6 causes the control device 6 to operate the rolling mill according to the operating method described above and also explained below. In particular, the control device 6 controls the rolling stands 1, 2 and the transport of the flat rolled goods 3 through the rolling mill. Preferably, the control ^device 6 continues to perform a RAC during the rolling of the respective flat rolling stock 3.

As part of the processing of the machine code 8, the control device 6 receives its measured values from the thickness measuring device 5, in particular the thickness wedge dd or the rolling stock thickness dDS, dWS on the drive side and the operating side. Based on the deviation of the thickness wedge dd of a target wedge dZ, optionally with additional utilization of other variables such as the wedge ds and / or a Walzgutbreite, determines the controller 6 a change dds of the wedge engagement ds. Then, the controller 6 changes the wedge position ds by the change dds of the wedge engagement ds. The control device 6 thus determines a (new) wedge engagement ds. For example, a determination can be made according to the relationship ds = ds + dds (3). The newly determined wedge setting ds applies to the flat rolling stock 3 to be rolled next. The flat rolling stock 3 to be rolled next is thus pre-rolled in the roughing pass - generally: in the at least one roughing pass - with the new wedge setting ds, for example according to Equation 3 currently

The purpose of the explained procedure is that for the next rolled flat rolling stock 3, the deviation of the thickness wedge dd from the target wedge dZ has at least a smaller value than for the last already rolled flat rolled stock 3. In the optimal case, the thickness wedge dd is the next rolled flat rolled stock 3 even equal to the target wedge dZ. The control device 6 therefore determines the change dds of the wedge engagement ds such that the change dds of the wedge engagement ds counteracts the deviation.

In the simplest case, the control device 6 determines the change dds of the wedge engagement ds according to the relationship dds = k (dd-dZ) (4)

In the simplest case, the change dds the Keilanstel ^¬ lung ds is proportional to the deviation of the present in the finish-rolled respective flat rolling thickness wedge 3 from the target dd wedge dZ. k is a proportionality factor chosen according to magnitude and sign.

The change of the respective flat rolled material 3 dds the Keilan ^¬ position ds monotonously with the ratio of an average rolling gutdicke D, d after preliminary rolling, and after the finish rolling - preferably further increases - with the same deviation of the thickness wedge dd from objective wedge dZ. D is here the average rolling stock thickness of the respective flat rolling stock 3 after the rough rolling, d the average rolling stock thickness after the finish rolling. In the simplest case, there is a simple proportionality ratio. In this case, the proportionality factor k results in k = k 'D / d. (5) k' in Equation 5 is another proportionality factor independent of the two rolling stock thicknesses D, d.

A combination of Equations 4 and 5 thus yields - see also FIG. 1 - the relationship dds = k 'D (dd - dZ) / d (6) To implement the procedure last described, that is, the monotonic increase in the change dds the Keilanstel ^¬ lung ds with the ratio of the mean rolling-stock thickness D, d of the respective flat rolled product 3 after rough rolling, and after the finish rolling, it is necessary that the two Walzgutdicken D , d of the control device 6 are known. With regard to the average rolling stock thickness D of the respective flat rolling stock 3 after rough rolling, the control device 6 may be aware of this rolling stock thickness D, for example due to the setting of the roughing stand 1 during the execution of the last roughing pass of the respective flat rolled stock. With respect to the average rolling stock thickness d of the respective flat rolling stock 3 after the finish rolling, detection is preferably carried out by the thickness measuring device 5 or another further thickness measuring device not shown in FIG.

According to the invention, the procedure explained above in connection with FIGS. 1 to 3 is modified further in accordance with FIG. 4.

According to FIG 4, the rolling mill additionally on side guides 9. The side guides 9 are arranged in front of and behind the roughing stand 1 according to FIG. The side guides 9 are made during the pre-rolling of the flat rolled material 3 to the sides of the flat rolled material 3. The side guides 9 exert on the input side and on the output side transverse forces FE, FA on the flat rolling stock 3. The transverse forces FE, FA prevent both the inlet side and outlet side saber formation of the flat rolled stock 3 during roughing. The lateral guides 9 can be elongated as shown in FIG. Alternatively or additionally, the lateral guides 9-analogously to the procedure described in WO 2013/174 602 A1-can have a roller or a similar element which can be set transversely to the respective flat rolling stock 3, thus by means of the roller a lateral force can be exerted on the respective flat rolling stock 3. In the embodiment according to FIG. 4, lateral guides 9 are arranged both in front of and behind the roughing stand 1. In individual cases it may be sufficient to arrange a side guide 9 only in front of or behind the roughing stand 1. The respective other side guide 9 is not present in this case. Furthermore, it is possible, the front and / or the rear Be ^¬ tenführung 9 - regardless of whether the other side guide 9 is present or not - to replace it with a stuffer.

The design of the rolling mill according to FIG 5 corresponds over long distances with the design of the rolling mill according to FIG 1. According to FIG 5, however, the rolling mill not only the Zuführweg 4, but additionally another Zuführweg 10. The two Zuführwege 4, 10 are below is referred to as first feed path 4 and second feed path 10. Also via the second Zuführweg 10, the number of rolling stands 1, 2 successively a plurality of flat rolling stock 11 is supplied. The flat rolling stock 3, 11 supplied to the rolling stands 1, 2 via the respective feed path 4, 10 are referred to below as first flat rolled goods 3 and second flat rolled goods 11.

The second flat rolled goods 11 are rolled in the rolling mill in a completely analogous manner as the first rolled goods 3. Ins ^¬ particular, the second flat rolled goods 11 are rolled by means of the number of rolling stands 1, 2, wherein the respective second flat rolling stock 11 by means of the number of rolling ^¬ scaffolds 1, 2 is first pre-rolled in at least one roughing pass with a respective second wedge setting ds and then finished in finishing passes.

Furthermore, after the finish rolling of the respective second flat rolling stock 11, a second thickness wedge dd present in the finish-rolled respective second flat rolling stock 11 is also metrologically detected for the second flat rolled goods 11 and supplied to the control device 6. The control device 6 compares the second thickness wedge dd with a second one Target wedge dZ and determined for the respective second flat rolling stock 11 based on the deviation of the second thickness wedge dd from the second target wedge dZ and the second wedge ds a new second wedge ds for the at least one roughing pass. The determination can be made in a completely analogous manner as for the first flat rolled goods 3. In this way, as for the first flat rolled products 3 also, the second wedge adjustment ds is changed in the at least one roughing pass for the second flat rolling stock 11 to be rolled next. The next to be rolled second fla ^¬ che rolling 11 is thus ^¬ engraving rough rolled in said at least one rough rolling with the new value of the second wedge adjustment ds.

The decisive fact is therefore that the determination of the new wedge adjustment ds and, associated therewith, the tracking of the wedge adjustment ds for the first and second flat rolled products 3, 11 takes place independently of one another. Even if the first and second flat roll goods 3, 11 completely different properties (at ^¬ play different chemical compositions, un ^¬ terschiedliche temperatures, different widths, under ^¬ schiedliche Walzgutdicken before the rough rolling, etc.), therefore, a reliable tracking of the respective wedge adjustment ds for the next rolling to be rolled respective flat rolling 3, 10 done.

The distinction between the first supply path 4 and the second supply path 10 may be made as needed. In individual cases, it is even possible that the flat rolling stock 3, 11 although originate from the same source - for example, from a common slab stock - but different ways before feeding to the rolling mill, beispielswei ^¬ se different ovens.

The present invention stands out due to its A ^¬ simplicity. Because there is no complex modeling of Walzan ^¬ location required. Furthermore, there is no detection of a Any thickness wedge in the rolling stock 3, 11 before the rough rolling or between the rough rolling and the finish rolling required. It is only necessary to detect the then existing in the rolling stock 3, 11 thickness wedge dd after the finish rolling and subsequently this thickness wedge dd hand the wedge adjustment ds of the Minim ^¬ least to track a Vorwalzstichs.

Although the invention in detail by the preferred embodiment has been illustrated and described in detail, the invention is not limited ^¬ by the disclosed examples and other variations can be derived therefrom by the skilled artisan without departing from the scope of the invention.

Claims

claims

1. Operating method for a rolling mill,

 - wherein a number of rolling stands (1, 2) of the rolling mill are supplied via a first feed path (4) successively a plurality of first flat rolled goods (3) made of metal,

 - wherein the first flat rolled goods (3) are rolled by means of the number of rolling stands (1, 2),

 wherein the respective first flat rolling stock (3) in the number of rolling stands (1, 2) is initially rough-rolled in at least one roughing pass with a first wedge setting (ds) and then finish-rolled into finishing passes,

- wherein a finish-rolled in the respective first flat rolled stock (3) existing first thickness wedge (dd) is detected by measurement ^¬ technically after the finish rolling of the respective first flat rolled stock (3),

 - Wherein in the finish-rolled respective first flat

Rolled stock (3) existing first thickness wedge (dd) with a ers ^¬ th target wedge (dZ) is compared,

- Based on a deviation of the existing first thickness wedge (dd) of the first target wedge (dZ) and the first wedge adjustment (ds) a new first wedge position (ds) for the at least one roughing pass is determined and

 wherein the first wedge adjustment (ds) in the at least one roughing pass is set for the next flat first rolled stock (3) corresponding to the newly determined value of the first wedge adjustment (ds), so that the first flat roll to be rolled next Rolling stock (3) is pre-rolled in the at least one roughing pass with the newly determined value of the first wedge adjustment (ds), characterized

- that during the pre-rolling of the respective first flat rolling stock (3) in the at least one roughing pass from ^¬ leading rolling mill (1) in front of and / or behind this rolling stand (1) side guides (9) and / or upsetting to the rolling stock ( 3) are hired,

- That the side guides (9) and / or upsetting shear forces (FE, FA) on the respective first flat rolling stock (3) practice, which prevent saber formation during roughing, and

- that a change (dds) of the wedge adjustment (ds) proportio nal ^¬ available to the respective first flat in the finish-rolled rolling stock (3) thickness wedge (dd) is.

2. Operating method according to claim 1,

characterized ,

that the change (dds) of the wedge adjustment (ds) monotonously with the ratio of a mean rolling-stock thickness (D, d) increasing the time jewei ^¬ first flat rolled stock (3) after the rough rolling and after the finish rolling.

3. Operating method according to one of the above claims, d a d u c h e c e n e c e n e,

in that during the rolling of the respective first flat rolling stock (3) a RAC takes place.

4. Operating method according to one of the above claims, d a c o v e c e s e c e n e,

 - that the number of rolling stands (1, 2) via a second feed path (10) successively a plurality of second flat rolled goods (11) are supplied,

 that the second flat rolled goods (11) are rolled by means of the number of rolling stands (1, 2),

 - That the respective second flat rolling stock (11) by means of the number of rolling stands (1, 2) is first pre-rolled in at least one roughing pass with a second wedge adjustment (ds) and then finished in finishing passes, - that after the finish rolling of the respective second flat Walzguts (11) in the finish-rolled respective second flat rolling stock (10) existing second thickness wedge (dd) is detected metrologically,

 - That in the finish-rolled respective second flat

 Walzgut (10) existing thickness wedge (dd) with a second

Target wedge (dZ) is compared,

that by means of a deviation of the existing second thickness wedge (dd) from the second target wedge (dz) and the two wedge adjustment (ds) a new second wedge position (ds) for the at least one roughing pass is determined and

 in that the second wedge adjustment (ds) in the at least one roughing pass is set for the second flat rolled stock (11) to be rolled next according to the newly determined value of the second wedge setting (ds), so that the second flat roll to be rolled next Walzgut (11) in the at least one roughing pass with the newly determined value of the second wedge adjustment (ds) is pre-rolled.

5. Control program for a control device (6) of a rolling mill, wherein the control program machine code (8), which is executable by the control device (6), wherein the execution of the machine code (8) by the control device (6) causes the control device (6) operates the rolling mill according to an operating method according to any one of the above claims.

6. Control device of a rolling mill, wherein the control device is programmed with a control program (7) according to claim 5.

7. rolling plant,

- wherein the rolling mill has a first feed path (4) via which a number of rolling stands (1, 2) of the rolling mill successively a plurality of first flat rolled goods (3) are supplied from Me ^¬ tall,

 - wherein the rolling mill comprises a number of rolling stands (1, 2), by means of which the first flat rolled goods (3) are rolled,

 - wherein the respective first flat rolling stock (3) in the number of rolling stands (1, 2) is first pre-rolled in at least one roughing pass with a first wedge setting (ds) and then finish-rolled into finishing passes,

- wherein the rolling mill has a thickness measuring device (5) on ^¬ , by means of which after the finish rolling of the respective first flat rolled stock (3) in a finish-rolled respective is detected metrologically by the first flat rolling stock (3) existing first thickness wedge (dd),

- wherein the rolling plant before and / or behind the at least one Vorwalzstich exporting roll stand (1) Seitenfüh- extensions (9) and / or edger having during the pre ^¬ rolling of the respective first flat rolled stock (3) to the ^¬ ses roll stand (1) are employed and transverse forces (FE, FA) on the respective first flat rolling stock (3) exercise, which prevent saber formation during roughing, and - wherein the rolling mill has a control device (6) according to claim ^¬ 6, which the rolling mill operates according to one Be ^¬ drive method according to one of claims 1 to 5.