EP2283942A1 - Method for influencing a position of a milled item that passes through a multiple scaffold mill train, control and/or regulating device for a mill train and mill train - Google Patents

Abstract

The method involves passing a milled item (G) into roll stands (2, 3) comprising roll gaps (WS1, WS2), where the milled item extends between the roll stands. Adjusting units e.g. loop lifters (5), roller (5') and hydraulic cylinders (6, 7), are provided between the roll stands for adjusting different tensile stress distribution in width direction of the milled item, where the stress distribution is effected in a region of the roll gaps. Position of the milled item is influenced by adjusting the tensile stress distribution and detected relative to a transport route. An independent claim is also included for a multi-stand rolling mill for rolling a milled item.

Description

The invention relates to a method for influencing a layer of a multi-stand rolling train, in particular hot rolling mill, continuous rolling stock, in particular metal strip, wherein the rolling stock at least a first rolling stand, comprising a first nip, and a second rolling stand, having a second nip passes, wherein the rolling stock extends between the first rolling stand and the second rolling stand. Furthermore, the invention relates to a control and / or regulating device for a rolling mill, as well as a rolling mill for rolling of rolling stock, with a first rolling stand, comprising a first roll gap, and a second rolling stand, having a second roll gap.

The invention is in the technical field of rolling mill technology. During the production of rolling stock by means of a rolling process, the position of a strip to be rolled within the rolling train plays a not insignificant role for the quality of the ultimately producible rolled end product. If the course of the rolling stock from the desired position of the rolling stock in the rolling train is too large, it may even be necessary to interrupt the rolling process. It can also cause damage to the system.

For this reason, it is desirable that a rolling stock passes through a rolling mill as centrally as possible. Since this is usually not the case for a long time, however, attempts are made by appropriate influence on the rolling stock, in particular by means of the work rolls of the rolling stands to set the barrel of the rolling stock or the position of the rolling targeted.

Such a method is known, for example, from the published patent application DE 198 43 039 A1 which is a procedure and shows an apparatus for correcting a tape when rolling tapes having at least one stand. Here it is disclosed that the position of the band is determined by means of measured values related to the tensile stress values of the rolling stock. If the actual values of the determined measured variables deviate from the desired nominal values, this is interpreted as an error of a band position in the rolling train and the roller adjustment is changed, whereby the band position is to be corrected.

Disadvantage of this approach is that the band position of the rolling stock is determined only indirectly via measured characteristic of the tensile stress. Because their deviation from a setpoint is not necessarily based on a faulty band position. Moreover, by changing the setting of the work rolls of the rolling stands, the rolling process may be undesirably affected, i. Due to the correction of the strip course due to the change in the roll positions, undesired deviations from other parameters of the rolling stock can occur.

The object of the present invention is to further improve the strip running of rolling stock in a rolling mill.

A procedural part of the object is achieved by a method of the aforementioned type, wherein between the first rolling stand and the second rolling stand means for setting a variable tensile stress distribution in the width direction of the rolling stock are provided, wherein the tensile stress distribution in the region of the first roll gap and / or the second Rolling gap is effective, and the position of the rolling stock is controlled by adjusting the tensile stress distribution targeted. By such means, the mill operator receives an additional actuator for influencing the band position, without necessarily having to influence the employment of the rolls of the rolling mills of the rolling mill. As a result, on the one hand, a very high-quality roller product is made possible, and, on the other hand, a desired band position can be achieved of the rolling stock during the rolling process in the rolling mill can be adjusted by the means mentioned above. As a means, in particular means can be used, which are already present in the rolling mill. However, these are then to be modified or prepared in such a way that with these a variable tensile stress distribution in the width direction of the rolling stock in the region of the first roll gap and / or second roll gap can be adjusted. As a result, a particularly cost-effective provision of funds can be realized. Also, for example, side guides can be used as a potentially suitable means.

In an advantageous embodiment of the method according to the invention, a position of the rolling stock is detected relative to a transport path provided for the rolling stock, preferably between the two rolling stands, and the position of the rolling stock is controlled and / or regulated by adjusting the tension distribution on the basis of the detected position of the rolling stock. The transport path is the desired path that a rolling stock should take through the rolling mill. As a measure of the transport path, for example, the center axis of the rolling train can be used at the height of the transport level of the rolling stock. Since in the detection of the situation usually any reference points of the rolling mill are also included, in this case always takes place a detection of the situation relative to a designated transport path. Any measurement which allows an assessment of the position or the run of the rolling stock in the rolling mill fulfills the characteristic of "detection relative to a planned transport path". As a result of this procedure, it is possible to realize particularly precisely a desired strip course or a desired strip position of the strip in the rolling train. In particular, an automated solution can be provided here, which is preferably based on an optical detection of the band layer. As a result, the band position is detected directly and it can be done on the basis of this directly detected band position, a particularly accurate control or regulation of the position of the rolling stock in the rolling train by a means corresponding tensile stress distribution in the region of the first roll gap and / or second roll gap is set.

In a preferred embodiment of the method according to the invention, the means comprise a loop lifter over which the rolling stock is guided. By using a loop lifter as means for setting a variable tensile stress distribution in the width direction of the rolling stock, a band layer can be influenced in a particularly simple manner by means of an already required device.

It is particularly advantageous that the loop lifter has a first actuator for the drive side of the rolling train and a second actuator for the operating side of the rolling train, wherein the first actuator and / or the second actuator are used to adjust the variable tensile stress distribution. By using different actuators for the drive side and operator side, the loop lifter or its roller can be moved independently on the drive side and operator side. That It can be realized different positions for the drive side and operator side and thus in particular almost arbitrary inclinations of the looper roll between the drive and operating side. This allows a variable adjustment of the tensile stress distribution in the region of the first roll gap and / or second roll gap.

In a particularly advantageous embodiment of the method according to the invention, the first actuator and the second actuator are each formed as a hydraulic cylinder, by means of which a position and / or orientation of a roller of the loop lifter for adjusting the variable tension is set. By using two independently operable hydraulic cylinder as large variability in the positioning and alignability of the role is realized. The use of two independent linear actuators is particularly useful suitable for the invention. Here, with the greatest possible flexibility, a variable tensile stress distribution in the first nip and / or second nip can be adjusted in order to influence the band position of the rolling stock in the rolling train in a targeted manner.

In a further advantageous variant of the method according to the invention, a tensile stress distribution for the rolling stock in the region of the loop lifter is determined by means of a measuring device, in particular by means of a measuring roller encompassed by the loop lifter for detecting a tensile stress which has been resolved in the width direction. As a result, a tensile stress distribution in the width direction for the rolling stock can be determined. From this tensile stress distribution conclusions can be drawn on the tensile stress distribution in the first and / or second nip, whereby the tape run or the band position can be influenced. The measuring device can be configured, for example, as a segmented measuring roller. Here, the conventional looper roller is replaced by a corresponding measuring roller. Alternatively or additionally, for example, a force measurement for the drive side and operating side for the role of the loop lifter for determining a tensile stress distribution in the region of the loop lifter can be used.

In a further variant of the method according to the invention is carried out for influencing the position of the rolling stock, in particular on the basis of the detected rolling stock, additionally a control engagement on at least one of the two rolling stands, in particular at the work rolls, for adjusting the position of the rolling stock. In this respect, the known pivoting of the work rolls for adjusting the rolling stock in the rolling train is combined by means of the method according to the invention. However, since a tensile stress distribution in the width direction in the region of the first roll gap and / or second roll gap is adjusted by means of appropriate means, there is an interaction in a change in the employment of the work rolls of the rolling stands. In particular, this changes the effective tensile stress in the width direction of the rolling stock in the area the nip, when the nip forming work rolls are employed in a modified manner. As a result, further variations of the tensile stress distribution in the width direction are made possible. This further increases the variability of the method for influencing the band position by increasing the variability of the adjustable tensile stress distribution in the nip.

An apparatus part of the object is achieved by a control and / or regulating device for a rolling mill, with a machine-readable program code which has control commands which, when executed, the control and / or regulating device for carrying out the method according to one of claims 1 to 6 cause.

The device-related part of the object is also achieved by means of a rolling mill for rolling rolling, having a first rolling stand, comprising a first nip, and a second rolling mill, comprising a second nip, with means for adjusting a variable tensile stress distribution in the width direction of the rolling stock, the Means are arranged between the first rolling stand and the second rolling stand, wherein the tensile stress distribution in the region of the first roll gap and / or the second roll gap is effective, with a control and / or regulating device according to claim 7, wherein the means for adjusting a variable tensile stress distribution the control and / or regulating device are operatively connected. In this way, a device is provided by means of which the method according to the invention can be carried out. The advantages for this result analogously from the above statements on the corresponding method claim.

In a particularly advantageous embodiment of the device according to the invention, there is a device for detecting a position of a rolling stock passing through the rolling train, in particular relative to a designated transport path, which is operatively connected to the control and / or regulating device is. This makes it possible to control the strip position of the rolling stock on the basis of the detected strip position of the rolling stock in the rolling train by providing the means for setting a variable tensile stress distribution in the width direction of the rolling stock in the region of the first and / or second roll gap.

In a particularly advantageous embodiment of the device according to the invention, the means comprise a loop lifter. The loop lifter is adapted to generate a variable tensile stress distribution in the width direction of the rolling stock in the region of the first roll gap and / or the second roll gap. In addition, the loop lifter additionally has the function of detecting the tensile stress of the rolling stock between the first rolling stand and the second rolling stand. As a result, various functionalities are thus combined in a device which is generally present anyway.

In an advantageous embodiment of the device according to the invention, the loop lifter has a first actuator for the drive side of the rolling train, and a second actuator for the operating side of the rolling train, wherein the first actuator and the second actuator are independently operable. By using a plurality of actuators, which allow a different employment of the drive side and operating side looper, the above-mentioned variable widthwise tension distribution in the region of the first roll gap and / or second roll gap can be generated.

In particular, it is advantageous that the first actuator and the second actuator is each formed as a hydraulic cylinder, by means of which a position and / or orientation of a roller of the loop lifter for adjusting the variable tension is adjustable. In particular, these are means for linear adjustment of the height of the role of the loop lifter, the position of the role on the drive side and operating side set almost arbitrary can be. This achieves a high variability in the setting of the variable tensile stress distribution.

In a further advantageous embodiment of the rolling mill according to the invention, the loop lifter comprises a measuring device, wherein the measuring device is designed to detect a tensile stress distribution in the width direction of a rolling stock guided over the loop lifter. Preferably, the measuring device is designed as a measuring roller for detecting a tensile stress distribution in the width direction of the rolling stock. This measuring roller can replace the traditional role of looper. In particular, this measuring roller may, for example, be designed as a segmented measuring roller, which is available on the market, for example, under the name Planicim measuring roller. As a result, not only the tension can be adjusted by means of the loop lifter, but at the same time a tension in the width direction of the metal goods in the region of the role of the loop lifter can be determined. This makes it particularly easy to implement a closed control. Alternatively, the measuring device can also be realized via a force measuring device. Thus, for example, by means of a drive-side and operator-side measurement of the force on the role of looper a force distribution to the role of the loop lifter, especially in the longitudinal direction of the roller, and determined this force distribution or force difference between the drive side and operating side for controlling and / or regulating the Tensile tension in the width direction can be used in the region of the first and / or second roll gap. The drive-side and / or operator-side measurement of the force can take place, for example, via load cells. The measurement of the force in the longitudinal direction of the roller can also be used to determine a tensile stress distribution which can be used to control and / or regulate the band position.

In a further advantageous embodiment of the device according to the invention is additionally at least one of two rolling stands operatively connected to the control and / or regulating device and it is based on the detected position of the rolling stock additionally a control engagement for at least one of the two rolling stands, in particular for the work rolls, for adjusting the position of the rolling stock. It is a combination of the conventional means for adjusting the position of a rolling stock in the rolling mill by changing the setting of work rolls. Due to the effective tension in the nip split generated by the appropriate means between the first stand and second rolling stand, the influenceability of the position of the rolling stock is further improved.

Furthermore, the invention extends to a machine-readable program code for a control and / or regulating device according to claim 7, which comprises control commands which cause the control and / or regulating device to carry out the method according to one of claims 1 to 6.

Moreover, the invention extends to a storage medium, e.g. a flash memory medium or a CD or DVD, with machine-readable program code.

FIG 1

eine Seitenansicht eines Ausschnitts einer Walzstraße,

FIG 2

einen Querschnitt des Ausschnitts der Walzstraße aus FIG 1 mit einer ersten Anstellung des Schlingenhebers,

FIG 3

einen Querschnitt des Ausschnitts der Walzstraße aus FIG 1 mit einer zweiten Anstellung des Schlingenhebers,

FIG 4

einen Querschnitt des Ausschnitts der Walzstraße aus FIG 1 mit einer dritten Anstellung des Schlingenhe- bers.

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

FIG. 1

a side view of a section of a rolling mill,

FIG. 2

a cross-section of the section of the rolling train FIG. 1 with a first employment of the looper,

FIG. 3

a cross-section of the section of the rolling train FIG. 1 with a second employment of the looper,

FIG. 4

a cross-section of the section of the rolling train FIG. 1 with a third employment of the loop lifter.

FIG. 1 shows a section of a rolling train 1. The present rolling train 1 may be zweigerüstig, dreigerüstig, four-stand, five-stand or have more than five stands. That is, the rolling train 1 has at least two rolling stands 2 and 3, respectively.

The statements apply to any adjacent rolling stands of a multi-stand rolling train.

FIG. 1 shows a rolling mill 1 in operation. In this case, rolling stock G, ie hot strip in the context of this exemplary embodiment, passes through the rolling train 1 and is located in particular both in the roll gap WS 1 of the first rolling stand 2 and in the rolling gap WS 2 of the second rolling stand 3. The rolling stock G extends from rolling stand 2 to rolling stand 3, that is formed integrally at least in this area.

Between the rolling stands 2 and 3 is a detection device 4 for detecting a band position of the rolling stock G in the rolling mill 1, in particular relative to the transport center axis. Thus, the position of the rolling stock G in the rolling mill 1, in particular between the rolling stands 2 and 3 can be determined.

Furthermore, a loop lifter 5 is arranged between the first rolling stand 2 and the second rolling stand 3. The loop lifter 5 is in the state shown in contact with the rolling stock G and is used to detect the belt tension.

In addition, the loop lifter 5 serves to adjust a tensile stress distribution in the width direction of the rolling stock G, which acts both in the nip WS 1 of the first rolling stand 2 and in the nip WS 2 of the second rolling stand 3.

This tensile stress distribution in the roll nips WS 1 or WS 2 leads to the formation of a transverse force acting on the rolling stock G in the respective roll gap WS 1 or WS 2 by means of this transverse tension, which can be adjusted via the tensile stress distribution, a course of a strip in the rolling train 1 can be set.

To set this tension distribution, the loop lifter 5 has two hydraulic cylinders 6 and 7 which can be operated independently of one another. These serve to adjust the position of a roller 5 'of the loop lifter for drive side A or operating side B. By the independently operable hydraulic cylinders 6 and 7, the roller 5' of the loop lifter 5 realize pivotal movements about a plurality of pivot points. As a result, the tensile stress in the roll gap WS 1 of the first roll stand and in the roll gap WS 2 of the second roll stand can be set almost arbitrarily. Accordingly versatile is the influenceability of the band position of the rolling stock G in the rolling mill. 1

If such a method for influencing the band position or the tape run is designed as a control or regulating method, then a particularly stable band run can be set.

Specifically, for this purpose, the detection device 4 is operatively connected to a control and / or regulating device 8. The detected band position by means of the camera, preferably a 3D camera, is supplied via signals to a control and / or regulating device 8.

Furthermore, the loop lifter 5, in particular its actuators, ie in the present case, the hydraulic cylinders 6 and 7 for drive side A and operating side B, with the control and / or regulating device 8 operatively connected.

In addition, the positioning systems of the first rolling stand 2 and of the second rolling stand 3 are also operatively connected to the control and / or regulating device 8.

The control and / or regulating device 8 is prepared for carrying out a variant of the method according to the invention. For this purpose, a machine-readable program code 9, which comprises control commands which cause the method to be carried out, is transmitted via a network or via a storage medium 10, e.g. a USB stick or a CD. The machine-readable program code 9 is preferably stored in memory on the control and / or regulating device 8.

When the program code 9 is executed, the control and / or regulating device 8 initiates a detection of the strip position of the rolling stock G in the rolling train 1. On the basis of this detected strip position, the control and / or regulating device 8 determines a deviation of the current and / or future actual strip position from a target band position in the rolling mill 1.

Because of this deviation, the control and / or regulating device 8 determines a tensile stress distribution which changes the band position from the actual band position in the direction of the nominal band position.

This is done with a model describing the conditions in the respective first and / or second nip.

Subsequently, control signals for the hydraulic cylinders 6 or 7 and / or for the positioning systems of the work rolls 11 of the first and / or second roll stand 2 or 3 are determined on this basis, so that the determined tensile stress distribution in the first and / or second roll gap WS 1 or WS 2 is set.

Alternatively, the adjustment of the band position can be done without the intermediate step of a tension distribution calculation. In this case, based on historical data, a movement of Roller 5 'of the loop lifter 5 carried out such that a desired band position is set. In this case, the control or regulation of the band position is based on a learning process of the control and / or regulating device, for example by means of a neural network.

By using such methods, a strip running of a rolling stock G can be stably adjusted by a rolling mill 1, which has a positive effect on the quality of the products produced with the rolling mill 1.

In particular, a simple control of the belt layer is possible by the roller 5 'of the loop lifter is designed as a segmented measuring roller for detecting a tensile stress of the rolling stock in the width direction. The tensile stress values present on the roller as a result of the tensile stress measurement can advantageously be combined with the optical detection of the belt layer and used for controlling and / or regulating the belt layer.

In FIG. 1 is below the first rolling mill 2 is a plan view of the rolling mill G passing through the first rolling mill 2 dargstellt. The arrows shown here represent an exemplary tensile stress distribution over the width of the rolling stock G.

2, FIG. 3 and FIG. 4 show different positions and orientations of the roller 5 'of the loop lifter 5.

FIG. 2 shows a parallel employment for the role 5 'on the drive side A and operating side B of the loop lifter 5. In this case, no additional tensile stress distribution is applied to the roll nip WS 1 and WS 2. This position substantially corresponds to the operating state of a loop lifter 5 used today in the rolling train 1, which is used only for detecting the tension.

FIG. 3 By lifting the operator-side roller end relative to the drive-side roller end, an additional asymmetrical tensile stress distribution in the first and / or second roller gap WS 1 or WS 2 is achieved. In this case, the tension in the nip WS 1 and WS 2 on the operating side B is higher than on the drive side A. The tape thus runs when rolling in the direction of the drive side A.

FIG. 4 shows a substantially reverse employment of the hydraulic cylinders 6 and 7 of the loop lifter 5 compared with FIG. 3 , Here, the user-side end of the roller 5 'is lowered relative to the drive-side end of the roller 5'. In this case, a reinforced train on the drive side A in the nip WS 1 and WS 2 is generated, which leads to the running of the belt G at the exit from the roll gap WS 1 in the direction of the operator side B.

In addition, the work rolls 11 of the first and / or second roll stand 2 or 3 can be tuned to the position and / or position of the roll 5 'of the loop lifter 5, in particular pivoted. It should be noted here that the tension in the respective roll gap WS 1 or WS 2 is additionally influenced by pivoting the work rolls 11. By pivoting the work rolls can thus be made in addition a fine adjustment of the tape run.

Claims (14)

Method for influencing a layer of rolling stock (G), in particular metal strips, running on a multi-stand rolling train (1), in particular hot rolling mill, wherein the rolling stock has at least a first rolling stand (2) comprising a first roll gap (WS 1) and a second rolling stand (3) passing through a second roll gap (WS 2), wherein the rolling stock (G) extends between the first rolling stand (2) and the second rolling stand (3),
characterized in that between the first rolling stand (2) and the second rolling stand (3) there are provided means (5, 5 ', 6, 7) for setting a variable tensile stress distribution in the widthwise direction of the rolling stock (G), the tensile stress distribution being in the range of first roll gap (WS 1) and / or the second roll gap (WS 2) is effective, and the position of the rolling stock (G) is influenced by selective adjustment of the tensile stress distribution. Method according to claim 1,
characterized in that a position of the rolling stock (G) relative to a for the rolling stock (G) provided transport path, preferably between the two rolling stands (2, 3), is detected, and that the position of the rolling stock (G) by adjusting the tensile stress distribution controlled and / or regulated on the basis of the detected position of the rolling stock (G). Method according to claim 1 or 2,
characterized in that the means (5, 5 ', 6, 7) comprise a loop lifter (5), over which the rolling stock (G) is guided. Method according to claim 3,
characterized in that the loop lifter (5) comprises a first actuator (6) for the drive side (A) of the mill train (1), and a second actuator (7) for the operator side (B) of the mill train (1) first actuator (6) and / or the second actuator (7) are used to set the variable tensile stress distribution. Method according to claim 4,
characterized in that the first actuator (6) and the second actuator (7) are each formed as hydraulic cylinders (6, 7), by means of which a position and / or orientation of a roller (5 ') of the loop lifter (5) for adjusting variable tension is adjusted. Method according to one of the preceding claims,
characterized in that for influencing the position of the rolling stock (G), in particular based on the detected rolling stock, additionally a control engagement on at least one of the two rolling stands (2, 3), in particular their work rolls (11), for adjusting the position of the rolling stock (G ) he follows. Control and / or regulating device (8) for a rolling mill (1), with a machine-readable program code (9) which has control commands which, when executed, the control and / or regulating device (8) for carrying out the method according to one of the preceding Induce claims. Rolling train (1) for rolling rolling (G), comprising a first roll stand (2), comprising a first roll gap (WS 1), and a second roll stand (3), having a second roll gap (WS 2), by means (5 , 5 ', 6, 7) for adjusting a variable tensile stress distribution in the width direction of the rolling stock (G), wherein the means (5, 5', 6, 7) between the first rolling stand (2) and the second rolling stand (3) are arranged and in that the tensile stress distribution in the region of the first roll gap (WS 1) and / or the second roll gap (WS 2) is effective, with a control and / or regulating device (8) according to claim 7, wherein the means (5 , 5 ', 6, 7) for setting a variable Zugspannungsverteilung with the control and / or regulating device (8) are operatively connected. Rolling train according to claim 8,
characterized by a device (4) for detecting a position of a rolling stock (G) passing through the rolling train (2), in particular relative to a designated transport path (T), which is operatively connected to the control and / or regulating device (8). Rolling train according to claim 8 or 9,
characterized in that the means (5, 5 ', 6, 7) comprise a loop lifter (5). Rolling train according to claim 10,
characterized in that the loop lifter (5) comprises a first actuator (6) for the drive side (A) of the mill train (1), and a second actuator (7) for the operator side (B) of the mill train (1), the first one Actuator (6) and the second actuator (7) are operable independently of each other. Rolling train according to claim 11,
characterized in that the first actuator (6) and the second actuator (7) are each formed as hydraulic cylinders (6, 7), by means of which a position and / or orientation of a roller (5 ') of the loop lifter (5) for adjusting variable tension is adjustable. Rolling train according to one of claims 10 to 12,
characterized in that the loop lifter (5) comprises a measuring device, in particular a measuring roller (5 '), wherein the measuring device (5') is designed to detect a tensile stress distribution in the width direction of a rolling stock (G) guided over the loop lifter (5). Rolling train according to one of claims 8 to 13,
characterized in that in addition at least one of the two rolling stands (2, 3) is operatively connected to the control and / or regulating device (8) and based on the detected position of the rolling stock (G) additionally a control engagement for at least one of the two rolling stands (2, 3), in particular for the work rolls (11), for adjusting the position of the rolling stock (G).

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