WO2021180719A1

WO2021180719A1 - Method for reducing process disruptions in the production of a rolled product

Info

Publication number: WO2021180719A1
Application number: PCT/EP2021/055912
Authority: WO
Inventors: Christoph Hassel; August Sprock; Kai GRYBEL; Guido BUSCHHOFF
Original assignee: Sms Group Gmbh
Priority date: 2020-03-09
Filing date: 2021-03-09
Publication date: 2021-09-16
Also published as: EP4117836A1

Abstract

The invention relates to a method for reducing process disruptions in the production of a rolled product. By taking complex interactions into account in the controlling of a roll train, in the form of a disruption index, process disruptions leading to a reduction in yield of the roll train can be better compensated.

Description

Title:

Method for reducing process disruptions in the manufacture of a rolled product Area:

The invention relates to a method for reducing process disturbances in the manufacture of a rolled product.

State of the art: Process disruptions in the manufacture of a rolled product can have a number of causes. A process disruption is initially any deviation of an actual value from a target value. Not every process disturbance that occurs has a negative effect on the output of the rolling train. Yield is understood here in the sense of the invention as the quotient of the amount of rolling stock produced in a time interval corresponding to the specifications and the maximum amount to be produced in the rolling train in this time interval

Requirements corresponding amount of the rolled material, a =

That

Output according to the invention can therefore be reduced by qualitative deviations in the rolling stock or deviations in relation to the production output or throughput of the rolling train, with qualitative deviations likewise being described by deviations in the actual values from the target values for the rolled product.

Rolling trains usually consist of a number of units, for example furnaces, roll stands or cooling sections, through which the rolled product passes during manufacture without interrupting the manufacturing process. For this purpose, a large number of target specifications for a control and regulation of the overall process must be given to a rolling train or the units. These target specifications of the units for the manufacturing process are based on the target specifications for the rolled product and the empirical knowledge of the Plant operator or process models for individual units with which the target specifications of the rolled product can be adhered to.

Not every target specification of a unit has a direct influence on the output of the rolling train. Not every deviation of an actual value from a target specification in an aggregate therefore also leads directly to a reduction in output. Within certain limits, the control or regulation of each individual unit of the rolling train can initially correct a deviation of an actual value from its target value. However, a possible consequence can be that this deviation from the target value or a fluctuation due to the control process in a downstream unit of the rolling train then also leads to a deviation from a target value and thus to a process disruption relevant to output. Previous control and regulation concepts in rolling mills therefore set very narrow ranges for the tolerances in relation to deviations from target specifications, which can be corrected by the individual unit.

In the event of process disruptions in the rolling train that clearly lead to a reduction in output, the setpoints and / or the permissible control range of the unit must then be adapted on the basis of empirical values and / or process models. In this case, however, the adjustments are usually only related to the unit if thickness deviations are adjusted or optimized by adjusting the pass schedules or piercing temperatures. Interactions going beyond this are mostly not considered. In some cases, process models are known which describe and predict relationships between target specifications or actual values and the effects on the rolled product for individual process variables and / or individual units. Process models are, for example, temperature models, microstructure models or also deformation models in the roll gap. These are known from the prior art. Some of these are able to determine target specifications across all units, independently of a system control, or even Calculate actual values in advance. However, the previous models only take into account a small number of input variables and (only) track a relevant actual value of the rolled product. With these process models, the specialist is able to plan target specifications for the units in advance, analyze process errors afterwards and adapt individual target specifications. In some cases, these models can also influence the process within a control or regulation system across all units. The more target specifications and process parameters a previously known process model takes into account, the less it can be integrated into a known control or regulation concept of a rolling mill, since previously known linear process models with increasing complexity require disproportionately high computing capacity. Process disruptions that arise from a complex interaction of deviations from target specifications in individual units of the rolling train can therefore only be analyzed and remedied by a specialist using the known models or based on experience after the production of the rolled product has been completed. This creates a certain time delay between the error detection and the adjustment of the target specifications. This can significantly reduce the output of a rolling train.

Object of the invention:

The object of the invention is therefore to improve the control or regulation of a rolling train in such a way that these aggregate interactions between the setpoints, actual values and deviations between the values are taken into account in the control or regulation of the rolling train and thereby process disruptions are reduced. Invention:

The invention is achieved with a method having the features according to claim 1. In the production of a rolled product, in particular a hot strip, by means of a rolling train, a process disruption affecting the output of the rolling train is caused by at least a deviation of an actual value from a target specification of the rolled product itself and / or a target specification of an aggregate of the rolling train during the manufacture of the Rolled product justified, whereby these deviating actual values are associated with more than 4 actual values or target values. Connected in the sense of the invention means that a fluctuation, in particular a deviation from a target specification, of this value leads directly or indirectly to a fluctuation of at least 4 further actual values and / or is caused. The rolled product is manufactured with the rolling train by at least one heating device, at least one rolling stand, at least one cooling section, with a higher-level control of the rolling train controlling or regulating the production on the basis of setpoints.

The output, the actual values and the associated target specifications for the manufacture and the rolled product, in particular the dimensions of the units and / or process measurement values, are recorded at different points in the rolling train and the output, the actual values and the target specifications are stored for further use. The output, the actual values and the target specifications are available on a data memory for further evaluation and retrieval by the higher-level control or an external evaluation system.

A single process disruption of one or more units, in particular if a deviation arises from it in relation to the rolled product, is recorded as a data record with the associated setpoints and actual values. From this, a model, in particular a model connected to the control of the rolling train, determines a relationship for determining a malfunction indicator. The malfunction index is a in the sense of the invention Key figure for a combination of related setpoints, actual values and output that lead to a process disruption. A model in the sense of the invention is any mathematical relationship or algorithm with which such a characteristic number can be determined from this data. From the prior art, for example, statistical evaluation methods, in particular regression analyzes, are known as a mathematical method for this.

When determining the relationship for the malfunction indicator, the model takes into account the interactions between the target specifications and actual values over the entire production of the rolled product in the rolling train by creating relationships between stored target specifications and / or actual values with the individual process disruption and / or the setpoints and / or actual values without process disruption.

For a rolling mill, different relationships can be drawn up for the malfunction indicator. Correlations can be established for different dimensions of materials or processes, for example.

With the help of the relationship found, the higher-level control continuously determines the malfunction indicator during the manufacture of the rolled product, in particular online, on the basis of actual values during the manufacture of a rolled product. The ongoing production of the rolled product is interrupted or the production of a subsequent rolled product is not started if the malfunction indicator reaches a previously determined critical value range. Any range of values of the malfunction index that leads to a deviation of an actual value of the rolled product from its target value can initially be viewed as critical. In order to leave or not reach the critical value range, the higher-level control can, as an alternative to interrupting production, specify changed target specifications for the units of the rolling train for further production, the changed target specifications using further process models connected to the higher-level control of the rolling train, in particular temperature - and / or structural models, can be determined and / or optimized.

Further advantageous features of the method emerge from claims 2 to 11 which are dependent on claim 1.

The output of the rolling train is reduced, for example, by cobble formation of the rolled product. A cobble is understood to mean any incorrect rolling which leads to an interruption in the rolling process of a single rolled product or a series of identical rolled products. This can be, for example, the rise of a rolled product in the cooling section or between two roll stands.

Cobble arise in particular from deviations in the process variables of rolling force, rolling temperature, degrees of deformation and / or the course of recrystallization of the rolled product in the course of the process. In order to avoid the output reduction through Cobble, target specifications and / or actual values are preferably taken into account when determining the malfunction index, which influence the Cobble formation of a metallic strip. As a result, the number of target specifications and / or actual values to be taken into account can be reduced.

The output of the rolling train is reduced, for example, by a geometric deviation of the rolled product. Geometry deviations arise, for example, from roll wear, uneven rolling forces and / or an uneven temperature distribution on the surface of the rolled product. Preference is given to avoiding the reduction in output Target specifications and / or actual values are taken into account when determining the malfunction index, which influence the geometric deviation of a metallic strip. As a result, the number of target specifications and / or actual values to be taken into account can be reduced.

The output of the rolling train is reduced, for example, by a deviation in the product quality, preferably mechanical properties, surface quality and / or dimensions. To avoid the reduction in output, target specifications and / or actual values are preferably taken into account when determining the malfunction index, which influence a deviation in product quality, preferably mechanical properties, surface quality and / or dimensions. The roll age, the temperature control in the rolling train and / or the actual chemical analysis of the rolled product in relation to the material can have an influence on the product quality. As a result, the number of target specifications and / or actual values to be taken into account can be reduced.

The output of the rolling train is reduced, for example, through a reduction in production output, in particular through unplanned machine downtimes. The occurrence of unplanned downtimes can, for example, be influenced by the process parameters of cooling water quality, backup roll age, maintenance intervals of the units or parts of units, and / or the power consumption of drives. In order to avoid the reduction in output, target specifications and / or actual values are preferably taken into account when determining the malfunction index, which influence a reduction in production output, in particular due to equipment downtimes. As a result, the number of target specifications and / or actual values to be taken into account can be reduced. Preference is given to more than 5, preferably more than 25, even more preferably more than 100 actual values in the entire rolling train when determining the Incident code used. The more actual values and target values are linked, the more interactions can be taken into account. This also reduces the risk of receiving different key figures due to target specifications and / or actual values that are not taken into account with the same input variables.

The malfunction index is preferably determined in the form of a probability index. The same actual values of the production can lead to a reduction of the output if there are not recorded disturbance-relevant influencing parameters. This is preferably represented by a malfunction indicator in the form of a probability.

The model preferably uses a self-learning algorithm, particularly preferably a KI algorithm, to determine the malfunction index. Such algorithms, especially neural networks, can do it quickly

Establish relationships between a large number of different process data with an accuracy sufficient for control. With neural networks, it is not necessary to map the physical relationships between the individual processes; instead, a weighting and learning process takes place. This means that process parameters can also be linked to one another that initially have no direct physical relationship. This considerably simplifies the creation of a model for determining the malfunction indicator.

The model for determining the relationship recalculates, preferably cyclically, more preferably once per rolling campaign, the relationship on the basis of the actual values, target specifications and / or the output and uses the new relationship to calculate new malfunction indicators. A rolling campaign can be a series of different rolled products or a defined number of similar rolled products. The number should be chosen so that there are enough data records. In the event of a deviation between the mean value and / or spread of the old and new malfunction indicators of more than 10%, preferably more than 5%, even more preferably more than 2.5%, at least one warning message is generated and sent to an operator by means of the control of the rolling train transmitted. This allows the quality of the relationship to be determined and monitored on a regular basis. Ideally, this is done by executing the model for determining the relationship on the process computer of the higher-level controller. As a result, such a value can be output and displayed quickly and easily within the control system of the rolling train.

The self-learning behavior of the algorithm increases the accuracy of the determination of the malfunction indicator with each rolled product manufactured. With a corresponding configuration of the algorithm in connection with the control of the rolling train and the data memory, intervention by a person skilled in the art to rectify a process disturbance is not necessary or is significantly less

The self-learning algorithm for determining the characteristic number is preferably trained with existing data records from a rolling mill. This means that a functioning model can be set up before the rolling mill is put into operation. For this purpose, for example, data from units that are not currently producing in the network can be combined with one another.

The determination of changed target process parameters for avoiding or leaving the critical value range of the malfunction indicator is preferably carried out by a self-learning algorithm, preferably a KI algorithm. Here, too, a connection between process parameters and target specifications can be established with simple means without taking physical connections into account. The self-learning part then increases the accuracy of the target specification. The self-learning algorithm for determining the changed target specifications is preferably trained with existing data records from a rolling mill. This means that a functioning model can be set up before the rolling mill is put into operation. For this purpose, for example, data from aggregates can be combined that are not currently producing in a network.

Furthermore, the invention is achieved by a method having the features of claim 12. Process disruptions in the rolling train of a casting and rolling plant with a superordinate control are reduced by a method according to one of claims 1 to 11 and the actual values and the target values of the units before the first tapping of the rolled product in a rolling stand are taken into account in the method. The casting and solidification process has a significant influence on the quality of the rolled product. A large number of process parameters are also available here in addition to those of the rolling train that were previously not taken into account, or only in a simplified manner, in the control or regulation of a rolling train. In particular, since direct physical modeling of individual processes, such as solidification with simultaneous structure formation, has not yet been possible. Here, the effect-based modeling according to the invention without a mandatory physical connection is a possibility of avoiding process disturbances.

The changed target specifications are preferably specified by the control for the units before the first piercing in a roll stand. In the event of process deviations, the ongoing casting process can usually only be interrupted for ongoing production with difficulty. It is mostly possible to discharge a cast product with these deviations from a casting and rolling plant. This ejected cast products can, for example, be re-introduced after a review and approval. This will make that Bringing out the casting and rolling plant versus a failure of the finished one

Rolled product also improved.

Furthermore, the object of the invention is achieved by a method having the features of claim 12. Before starting to manufacture the

Rolled product, preferably a series of different rolled products, the malfunction indicator is determined by the model for each rolled product on the basis of planned actual values. In the case of a critical malfunction index, the influence of the respective individual actual value is weighted in relation to the malfunction index and a necessary changed target specification. The changes to the

Target specifications through maintenance and / or replacement of whole or parts of the units involved in the production then take place before the start of the production of the rolled product. In this way, before the start of production, the risk of reducing the output due to the standstill of a unit can be determined and technical measures can be taken to react. This includes the replacement of parts of the units or even entire units of the rolling train that unexpectedly fail with the previous control method. Alternatively, rolled products can also be removed from the production sequence and replaced by others with non-critical malfunction indicators.

Furthermore, the object of the invention is achieved by a method with the features of claim 13. Before the start of the production of the rolled product, preferably a series of different rolled products, the malfunction indicator determined by the model is determined for each rolled product on the basis of planned actual values and In the case of a critical malfunction index, the influence of the respective individual actual value is weighted in relation to the malfunction index and a necessary changed target specification. An optimization algorithm minimizes the malfunction indicator in the area of the system-technical possible target specifications by adapting the Target specifications. A minimization routine before the start of production can reduce the risk of a reduction in output, especially when assuming the probability of malfunctions as a malfunction indicator. The description of the invention is accompanied by three figures.

Figure 1: Rolling train with higher-level control

Figure 2: Neural network

Figure 3: Program structure

The invention is described in detail below with reference to the figures in the form of exemplary embodiments. In all figures, the same technical features are denoted by the same reference symbols

Starting from a casting and rolling plant (casting plant 1, rolling train 2 to 11), as shown in FIG. 1, the sequence of the method according to the invention is to be explained. The casting and rolling plant consists of n = 1 to 11 units 1 to 11. Each unit is assigned m measured values MW with corresponding n setpoints SV, which arise and / or are recorded during the operation and control of the rolling train. It is not absolutely necessary that all actual values and setpoints are recorded in the same time intervals t, but an appropriate value must be able to be assigned to a time interval t at any time. Furthermore, the output a of the casting and rolling plant at each of these time intervals t is described by a code number.

For example, wear data from rolls, which are recorded cyclically, can be assigned to a series of rolled products in the same way. With corresponding trustworthy models, it is also possible to simulate measured values at points (soft sensors) that are not accessible to conventional measurement. It is essential that all recorded actual values, target values and the application can be assigned to a point in time or interval t. The key figure output a is initially defined as described above and, if necessary, can be weighted, _{for example, by quality factors f q} and / or monetary value factors f _m. As a result, the economic success of the overall production can be better compared and evaluated with different materials of the rolled product. This results in the double assignment of the output a to the measured values MW and the target values SV (formula 1.1).

If measured values MW and target values SV do not necessarily always achieve the same output a, an output probability a ^w or, reciprocally to a or a ^w, a malfunction indicator s and malfunction probability s ^w can be formed from the fixed output a.

Measured values are, for example, rolling forces in the finishing train 8, a temperature profile of the strip / rolls across the width, a center line deviation, roll bending, roll age, furnace dwell times / temperatures and / or a material of the rolled product. Target specifications also include, for example, the target dimensions of the rolled product, the coil weight, the surface quality, the material properties and / or a structural composition of the rolled product. Measured values from a soft sensor can be, for example, the core temperature of a slab calculated on the basis of the surface temperature.

This data so present is stored with the above-described assignment in a database with which, for example, a neural network 13 is trained. Training means that the existing data is shared and the neural network 13 with one half in a first step Establishes connection 15 and the prediction quality of the connection for the malfunction indicator is checked on the basis of the second half of the data. The more input variables 14 are taken into account, the more data sets must be available for training and control. At least one data set for training and one data set for

Control of the relationship 15 must be present (FIG. 2).

The relationship determined in this way between the malfunction indicator or malfunction probability and the actual values and target specifications is then used to generate a current production based on the actual values and target specifications measured during the manufacture of the rolled product

Determine the fault number or probability.

If this malfunction indicator then leaves a previously defined range, the higher-level control 12 of the rolling train (2-11) begins to vary the setpoint values SV during ongoing production using process models, taking into account the technical possibilities of the units. The procedure takes place here in iteration steps. First, in a first step, new target specifications are determined on the basis of a predetermined variance v and within the possibilities of the units and the target specifications for the rolled product in relation to the existing ones. In a second step, these are used to calculate new actual values for the rolling train using process models. In a third step, this actual data record is then evaluated with the aid of the relationship 15 with regard to its probability of malfunction. If the failure probability is within the desired range, production is continued with these target specifications. If the malfunction code does not reach the desired range, you can start again with step 1. To avoid an endless iteration, a termination criterion, for example a number of iteration steps, should interrupt the iteration and then interrupt the ongoing production. The model 13 for determining the relationship 15 for the malfunction indicator also checks the quality of the relationship 15 cyclically. For this purpose, analogous to the training of the neural network, the data records stored during the production of a series of rolled products are combined in groups. With this new group of data sets, the model establishes a new relationship for the malfunction indicator. This relationship and the values determined for the malfunction index are compared with the previous relationship and the previous values for the malfunction index and evaluated. If a defined deviation is exceeded, a message is output to the operator. Furthermore, the previous connection can also be automatically replaced by the new connection.

List of reference symbols:

1 casting plant

2 scissors

3 oven

4 roughing stand (s)

5 transferable cooling

6 oven

7 Inductive heating

8 finishing stand (s)

9 cooling section

10 scissors

11 reel

12 Higher-level control

13 Model for determining the relationship

14 input variables for the model

15 Correlation for fault code

51 Change process conditions that directly affect probability

52 Check with 12 whether these new process conditions are compatible with the overall process

53 Start of production with the proposed process conditions

54 Checking the model calculation accuracy

55 Retraining the neural network

SV target specifications

MW measured values a Spreading s Fault index

Claims

Patent claims:

1 . Method for reducing process disruptions in the production of a rolled product, in particular hot strip, by means of a rolling train (2-11), wherein

- a process disruption affecting the output of the rolling train (2-11) is caused by at least a deviation of an actual value from a target specification of the rolled product itself and / or a target specification of an assembly of the rolling train (2-11) during the manufacture of the rolled product , whereby this deviating actual value is linked to more than 4 further actual values or target values; and

- The rolling product is produced with the rolling train (2-11) by at least one heating device (3,6,7), a rolling stand (4,8), a cooling section (9), with a higher-level control (12) of the rolling train ( 2-11) controls or regulates production based on target specifications; and

- the output, actual values and associated target specifications of the production and the rolled product, in particular dimensions of the units and / or process measured values, recorded at different points in the rolling train (2-11) and the output, the actual values and the target specifications for a further use are stored, the output, the actual values and the target specifications being available on a data memory for further evaluation and retrieval by the higher-level controller (12) or an external evaluation system; and a single process disruption of one or more units, in particular if this results in a deviation in relation to the The rolled product is created, recorded as a data record with the associated setpoints and actual values, and a model, in particular a model connected to the higher-level controller (12) of the rolling train (2-11), determines a relationship for determining a malfunction indicator therefrom; and

- When determining the relationship for the malfunction indicator, the model takes into account the interactions between the target specifications and actual values over the entire production of the rolled product in the rolling train (2-11) by establishing relationships between the stored target specifications and / or actual values the individual process disruption and / or between the target specifications and / or the actual values without process disruption; and

- the higher-level control (12) with the help of the found relationship continuously during the manufacture of the rolled product, in particular online, determines the malfunction indicator on the basis of actual values in the manufacture of a rolled product; and

- the higher-level control interrupts the ongoing production of the rolled product or the production of a subsequent rolled product does not start if the malfunction indicator reaches a previously determined critical value range or in order to leave the critical value range or not to reach the higher-level control changed setpoints for the units of the rolling mill ( 2-11) for the further production, whereby the changed target specifications by means of further process models connected to the higher-level control of the rolling train (2-11), in particular temperature and / or structure models, can be determined and / or optimized.

2. The method according to claim 1, characterized in that the output of the rolling train (2-11) is reduced by cobble formation of the rolled product.

3. The method according to claim 1, characterized in that the output of the rolling train (2-11) is reduced by a geometric deviation of the rolled product.

4. The method according to claim 1, characterized in that the output of the rolling train (2-11) is reduced by a deviation in the product quality, preferably mechanical properties, surface quality and / or dimensions.

5. The method according to claim 1, characterized in that the output of the rolling train (2-11) is reduced by a reduction in production output, in particular by stoppages of units.

6. The method according to any one of the preceding claims, characterized in that more than 5, preferably more than 25, even more preferably more than 100 actual values with the actual values of the process disturbance are used when determining the disturbance index.

7. The method according to any one of the preceding claims, characterized in that the malfunction index is determined in the form of a probability index.

8. The method according to any one of the preceding claims, characterized in that the model uses a self-learning algorithm, preferably a KI algorithm, to determine the relationship for the malfunction indicator.

9. The method according to claim 8, characterized in that the self-learning algorithm is trained with existing data sets of a rolling mill (2-11).

10. The method according to any one of the preceding claims, characterized in that

the model for determining the relationship cyclically, preferably once per rolling campaign, redetermines the relationship on the basis of the actual values, target values and / or the output; and

- Calculates a new malfunction indicator with the new context; and

- in the event of a deviation between the mean value and / or spread of the old and new malfunction indicators of more than 10%, preferably more than 5%, even more preferably more than 2.5%, at least one warning message is generated and controlled by the rolling train (2nd -11) transmitted to an operator.

11. The method according to any one of the preceding claims, characterized in that the determination of changed target values for avoiding or leaving the critical value range of the malfunction indicator is carried out by a self-learning algorithm, preferably a KI algorithm.

12. The method according to claim 11, characterized in that the self-learning algorithm for determining the target specifications is trained with existing data sets of a rolling mill (2-11).

13. A method for producing a rolled product by means of a casting and rolling plant (1-11) with a superordinate control (12), characterized in that

- The process disturbances in the rolling train (2-11) are reduced by a method according to one of Claims 1 to 12, and

- Actual values and target values of the units are taken into account in the process before the first tap in a rolling stand (4, 8) of the rolling train (2-11), and

- Changed target specifications are specified by the control for units before the first piercing in a rolling stand (4, 8) of the rolling train (2-11).

14. A method for avoiding production interruptions in the manufacture of a rolled product by a method according to any one of claims 1 to 12 or claim 13, characterized in that - Before the start of the production of the rolled product, preferably a series of different rolled products, the relationship for the malfunction indicator is determined by the model for each rolled product on the basis of planned actual data and / or target specifications, and

- in the case of a critical malfunction index, the influence of the respective individual actual value is weighted in relation to the malfunction index and a necessary changed target specification, and

- the changes to the target specifications are made by maintenance and / or replacement of whole or parts of the units involved in the production before the start of production of the rolled product.

15. A method for avoiding production interruptions in the manufacture of a rolled product by a method according to any one of claims 1 to 12, characterized in that

- Before the start of the production of the rolled product, preferably a series of different rolled products, the malfunction indicator is determined by the model for each rolled product on the basis of planned actual data, and

- In the case of a critical malfunction index, the influence of the respective individual actual value is weighted in relation to the malfunction index and a necessary changed target specification, and an optimization algorithm minimizes the malfunction index in the area of the system-related target process parameters by adapting the target process parameters.