EP2121209A1

EP2121209A1 - Method for assisting at least partially manual control of a metal processing line

Info

Publication number: EP2121209A1
Application number: EP08708742A
Authority: EP
Inventors: Stefan Schmors; Klaus Weinzierl
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2007-02-15
Filing date: 2008-02-06
Publication date: 2009-11-25
Anticipated expiration: 2028-02-06
Also published as: US8359119B2; PL2121209T5; CN101610856B; DE102007007560A1; CA2678062A1; EP2121209B1; RU2009134330A; PL2121209T3; KR20090122948A; ATE528081T1; CN101610856A; RU2457054C2; UA95129C2; US20100131092A1; WO2008098863A1; EP2121209B2; BRPI0807810A2; MX2009008349A

Abstract

In a method for assisting at least partially manual control of a metal processing line (1), in which metal (4) in strip or slab form or a pre-profiled state is worked, the proportion of at least one metallurgical phase of the metal is continuously determined with respect to at least one specific location of the metal processing line while taking into account operating parameters of the metal processing line (1) that influence the phase state and/or state parameters of the metal, and the proportion of the least one phase with respect to the specific location of the metal processing line is indicated to an operator.

Description

description

Method for supporting at least partially manual control of a metalworking line

The invention relates to a method for supporting an at least partially manual control of a metal processing line in which strip-shaped or slab-shaped or pre-profiled metal is processed, as well as a metal processing line.

Such metalworking lines - for example, production lines for rolling the metal, cooling lines for cooling the metal, or a combination of both - are well known. Frequently, certain phase states of the metal are required in the final product or for certain processing steps as precisely as possible, which means that certain phase portions of different phases of the metal, in particular of the steel, are predetermined as target values. Compliance with these targets is an essential criterion for the quality of the metal.

In order to achieve ex possible ^¬ acts maintain the desired phase state of the metal in an automatically controlled system, 2005/099923 Al was proposed, for example in WO to use a phase transformation model taking into account a displacement monitoring, the Betriebsparame ^¬ ter of the metal processing line, the Primary data describing the metal entering the metalworking line and its state, and to determine at least one phase component of tracked metal points from measured values and correspondingly controlling a cooling path based on the result.

However, automatic control can not actually achieve the desired target parameters (for example, phase components, temperature, thickness, and the like) of the processed metal in each process, so that systems with a At least partially manual control are known. In the ^¬ sen systems, an operator various components, drive at ^¬ play as actuators for cooling, roller swing or rolling by hand, so as to achieve a setting on the gewunsch- th target parameters. At the end of the processing line, for example, the temperature is then measured and the operator brought to the display, for example at the end of a Kuhlstrecke. Various settings of operating parameters can lead to the same temperature, but at different phase states of the metal, so that - not recognizable to the operator - a reject production can occur. Also, a poorer quality of the machined metal is thus obtained. It can also happen that because of the wrong phase state, a processing fails and it comes to so-called cobbles in the system, so the metal is tilted or hooked in the system, which can lead to at least a shutdown of the system. With such a Cobble also the safety of any persons present is endangered.

The invention is therefore based on the object of specifying a method for supporting an at least partially manual control of a metalworking line, which allows a Be ^¬ servant better setting in terms of Zielpara- meter and therefore increases the quality of the processed metal, reduces the production of waste and cobbles prevented.

To solve this object is inventively provided in a method of the type mentioned that continuously based on at least one specific location of the Me ^¬ tallbearbeitungsstraße the proportion of at least one metallurgical phase of the metal in consideration of the phase state influencing operating parameters of the Metallbear- beitungsstraße and / or determined by state parameters of the metal and the proportion of the at least one phase with respect to the specific location of the metalworking line is displayed to an operator. According to the invention therefore, the proportion at least ei ^¬ ner phase at a certain, in particular for the machining process relevant location of the metal processing line is first determined. The determination result can furthermore be used for the partial automatic control of the metalworking line, but in the method according to the invention advantageously also displayed to a user in real time, for example at a control device. The operator thus obtained promptly for the quality of the machined metal talls relevant information reflecting the Emfluss by him immediately before ^¬ Taken manual controls, so that if the manual settings can be further optimized by further changes. The display is thus quality assurance, but also prevents cobbles and the production of rejects and increases the safety of the metalworking line. In particular, the display can be used even if the metalworking line is operated in an automatic mode, so that it is recognized early that a quality problem occurs and can be switched to manual control to make appropriate corrections. In general, however, the term "manual control" should also be understood as a minimal intervention - in short, any kind of user information that has an influence on the operating procedure, albeit one that is so small Manual control is the selection of a suitable cooling plan or cooling parameters.

In particular, a model for determining the phase state of the metal at different metal points (defined locations on the metal) can be used to determine the proportion, wherein a tracking of the metal points and / or parameters describing the metal entering the metalworking line and its state , be taken into account. Such models provide reliable information about the phase state of the metal at various metal points. The model is introduced to everyone in the metalworking line. metal point, possibly due to a measurement, initialized. All metal points in the road are tracked. Since, due to the tracking and operating parameters, the influences at all metal points are known, the phase state at each of the metal points under consideration can be continuously updated. For the display then only the corresponding information must be queried at the specific point of the metalworking line. This information may, for example, be taken from the metal point closest to the particular location. The model can also be integrated into a superordinate model, for example with a temperature model. Of course, other methods may be used to determine the phase component (s), for example, measurement procedures.

As already mentioned, measuring variables can also be included in the determination of the phase state of the metal. For this purpose, it may be provided that at least one measuring device is used for recording state parameters, in particular a pyrometer. By means of a pyrometer, the temperature at a certain point metal let measure, so that the pitch made, particularly in connection with the Pπmardaten, at such a point at ^¬ initialization of the model advertising the can. Of course, state parameters can also be used for adapting the model by a measured value specifies, for example, a correction of the model determined by the phase state ^¬ close.

The metalworking line may be any type of metalworking line in which the phase state of the metal plays an important role. For example, the metalworking line may be a production line in which ferritic rolling is provided. Ferritic metal can be rolled with a lower rolling force than, for example, austenitic metal. It is important here that the transformation point of ferrite to austenite is known as precisely as possible and lies between two specific rolling mills. Then can be provided in the inventive method, for example, that the display of the phase fraction of feathers Walzgerust done. In this way, ferritic rolling could be realized, since the operator at any time has an overview of the phase states of the metal and can optionally intervene by a manual control in the rolling process.

However, the method can be used particularly advantageously if the metal is processed in a metal processing line designed as a cooling path for cooling the metal. Cooling lines are often connected to a production line and serve to prepare the metal for removal. For example, therefore, a reel may be provided at the end of the cooling section, onto which the processed metal is unwound. Of course, it is equally possible that further processing takes place at the end of the cooling section or another removal or storage device is provided. An example of this is the heavy plate mill. Since there can not be reeled, the sheets are straightened straight instead in a stretcher and stored as plates. In such Kuhlstrecke actuators are provided which serve to influence the temperature of the metal and therefore have on the phase components Emfluss. A Kuhlstrecke can, for example, above and below a roller table arranged valves, via the Kuhlmittel, in particular water, is applied to the metal. What the ^¬ sermenge and the water pressure can for example be controlled manually or automatically. Frequently, the temperature of the metal is measured at the beginning and at the end of the cooling section. Therefore, it can be provided that measured values of a first pyrometer connected upstream of the cooling path and one downstream of the cooling path are used as the state parameter. Of course, other temperature measurements can be made. The measured values of the first pyrometer can be combined with parameter data and a general

Information about the incoming metal, for example, that this is made of 100% austenite, serve to initialize the phase components at a metal point. The two te pyrometer ultimately serves to control and adapt the model.

Of course, a total production can be considered, that means, for example, a combination of production line and Kuhlstrecke.

In order to be able to judge the quality of the processed metal ideally at the relevant location, the proportion is expediently referred to a point at the end of the processing line ^¬ shows, ie, for example, at the end of the Kuhlstrecke, before rolling on a possibly provided reel. It is then possible to assess directly whether the desired target parameters are reached with the current operating parameters.

For example, considering a Kuhlstrecke having a length of about 70 meters, as needed, a faster be ^¬ wegtes band, for example at a speed of 10 meters / second, 7 seconds to passing the Kuhlstrecke. Often, however, slower speeds, for example, 2 meters / second are common, so that the metal takes half a minute to go through the Kuhlstrecke. If a modified activation is now carried out at the beginning of the cooling section, the real-time display, for example at a point at the end of the metalworking line, causes an operator to observe the effects on the display only after a few seconds or even half a minute.

Therefore, it can be provided in an advantageous development of the method, that in addition to determining the current share with modified control of at least one component of the processing line and a forecast for the future share, taking into account the change in control at the point determined and displayed. The ^¬ be indicated with knowledge of the current operating parameters and the current phase proportions at the position of the altered control is carried out, can from this position a pre-calculation up to hm to the point, with respect to the display, be made so that the Auswir ^¬ effect of the change for an operator is immediately apparent - especially if the comparative value with the previous settings there is still displayed. However, such a prognosis - which, of course, can not yet take into account subsequent changes of the machining process which are not controlled by the operator, for example an unplanned increase in the transport speed - gives the operator earlier indications of the type of change in the control. With particular advantage may additionally be provided that a test mode can be selected. In this test mode, changes to the control can be defined on the user interface, but these can not be taken over immediately. Nevertheless, it is possible, based on the determination of the phase components and the known changed and unaltered operating parameters, to make a prognosis which indicates what effects the intended change will have. If the operator is satisfied, he can take over the changes, for example, by pressing another control element in the controller.

For metals, especially for carbonaceous steels, complex phase diagrams exist in which a variety of different phases are included. A determination and display of the proportions of all these phases is not appropriate. Therefore, mainly relevant phases are preferably displayed. In particular, it can be provided that the proportion of austenitic and / or ferritic and / or pearlitic and / or cementitious and / or further phases is determined and displayed.

The share can be displayed in any form that is easy to grasp and clearly arranged. Thus, it is expedient to display the proportion in the form of a curve and / or as a pie chart and / or in numerical form and / or as a bar chart and / or as a color graphic. With special derem advantage can also be provided that when falling below or exceeding at least one predetermined value for at least a portion of the site a warning message is issued. For example, tolerance values may be specified that represent a quality tolerance that should be adhered to. The warning message, which can take place op ^¬ table and / or acoustically, the attention of the operator is directed to the problem encountered and the display of the phase or shares and it can be taken appropriate countermeasures.

In addition, the invention also relates to a metalworking line for the treatment of strip-shaped or slab-form or pre-profiled metal with a control device, comprising one for continuously determining the proportion of at least one metallurgical phase of the metal relative to at least one specific location of the metalworking line, taking into account the phase state influencing operating parameters and / or state parameters of the metal talls formed arithmetic unit, an input device for at least partially selectively possible manual control of the operation of the metal processing line, as well as to at ^¬ show the proportion of the at least one phase based on the specific location of the metal processing line embodied display device. In particular, such a metal processing line for carrying out the erfmdungsgemaßen method is formed, and the statements with respect to the procedural ^¬ rens can be transferred to the metalworking line. The arithmetic unit thus receives signals indicating the state of the metal or the metalworking line, in the form of operating parameters and / or state parameters. After determining the at least one phase, corresponding signals are sent to the display device so that the display can take place.

Thus, it can be provided that in the arithmetic unit for determining the proportion, a model for determining the phase state of the metal at different metal points is provided. rucksichtigung a displacement monitoring the metal points and / or raw data that describe the in the metal processing line ^¬ a metal and its current state is stored. For example, such a model may also be part of a more comprehensive model of the metalworking line, which may additionally include, for example, a temperature model.

Expediently, the metalworking line may comprise a measuring device for recording state parameters, in particular a pyrometer.

The metalworking line can be any type of processing line, for example a production line or a complete line. The embodiment is particularly advantageous if the metalworking line is designed as a cooling section that comprises actuators for influencing the temperature of the metal. Pyrometers may be provided at the beginning and at the end of such a cooling path, wherein the arithmetic unit is designed as a state parameter to take into account the measured values of the pyrometers. Of course, other pyrometers or other measuring devices may be provided.

The display device may be designed to display the portion in the form of a curve and / or as a pie chart and / or in numerical form and / or as a bar chart and / or as a color graphic.

Finally, it should be noted that the invention can be used advantageously not only in the processing of strip-shaped and metal-shaped metal. In particular, in the treatment of pre-profiled metal, for example the production of pipes or profiles, manual control possibilities are often given, so that use here is also profitably possible. Further advantages and details of the present invention will become apparent from the Ausfuhrungsbeispiel described below and with reference to the drawings. Showing:

1 shows a erfmdungsgemaße metal processing line,

2 shows a possible user interface for displaying information or for at least partially manual activation of the metalworking line, FIGS. 3A-D possible representations of phase portions, and FIG. 4 shows a possible warning message.

1 shows a metalworking line 1, which is designed here as Kuhlstraße 2. The Kuhlstraße 2 is connected downstream of a production line, the last Walzgerust is indicated at 3. Em to be processed metal 4, here in strip form, first passes through the production line and then the Kuhlstrecke 2, whereupon it is unwound for removal or for intermediate storage for further processing on a reel 5, which is downstream of the Kuhlstrecke 2.

The Kuhlstrecke 2 comprises actuators 6 which serve to Beeinflus ^¬ solution the temperature of the metal. 4 In this case, in order ^¬ the actuators take 6 valves and valves with which water ser can be applied to the band-shaped metal 4 to cool it. Although only a few actuators 6 are shown in the drawing, however, the cooling path may comprise a large number of such actuators 6.

The cooling section 2 further comprises a control device 7, which is indicated schematically in FIG. The control ^¬ device 7 comprises a processing unit 8, an input device 9 for the partial manual control of the actuators and a display device 10. Further, the Kuhlstraße a respective pyrometer 11 for measuring the temperature of the metal structure ^¬ 4 upstream or downstream. The arithmetic unit 8 controls the actuators 6 (eg valves, nozzles or flaps etc.) according to operating parameters S, which can be changed in a manual operating mode at least partially by the operator via the input device 9, so that the actuators 6 in groups or can be controlled separately. The manual controllability does not have to be permanently provided, it is just as conceivable that it is possible to switch between an automatic operating mode and a manual operating mode. Furthermore, it is conceivable that parts of the actuators 6 can be formed separately for manual ^¬ len control. Furthermore, it is conceivable that the operator varies input magnitudes of an automatic operation, eg an amplification factor with which the amount of water is increased as the belt speed is increased (semi-automatically). Other manual intervention, a manual

Control are, for example, the change of planing data (e.g., reel target temperature), the change in cooling strategy (e.g., cooling gradient), the change in the length of un-chilled band sections, or even a quality assessment that does not represent a change in the automatic itself.

Furthermore, maintaining the computing unit 8 further information about the state of Kuhlstrecke 2 or of the Me ^¬ talls 4. In addition to the measured values T of the pyrometers 11, the computing unit 8 Pπmardaten P of the metal 4, the metal 4 and the state arriving m Kuhlstrecke 2 describe, and as a further operating parameter, the metal velocity v supplied.

Further, a tracking 28 is provided, which tracks the position of a metal point of the metal 4 during the passage of the cooling line 2 constantly. The path tracking 28 can also be integrated into the arithmetic unit 8; in any case, the arithmetic unit 8 also has the data of the path tracing 28 at its disposal.

In the arithmetic unit 8, a model 12 of the cooling section 2 is now stored, which is a model 13 for determining the phase sequence. Stands of the metal 4 at different metal points and a temperature model 14 for determining the temperature relationship ^¬ the temperature distribution of the metal 4 at different metal points includes. The models 13 and 14 can also be implemented as a common model. The model 13 is adapted to determine the proportion of at least one phase of the metal to a plurality of metal dots in consideration of the phase state be ^¬ influential end operating parameters S, the state parameters of the metal 4, here the temperature measurements T, the Pπmardaten P and the Wegverfolgungsdaten x. Similarly, the temperature model 14 is designed to perform such a determination with respect to the temperature or the temperature profile. The determination of the component or the temperature or temperature takes place continuously. The models 13 and 14, for example, work as follows.

First, the temperature at a certain metal point is measured on the cooling section 2 upstream pyrometer 11. Together with the parameters P, one or more initial phase components can thereby be determined. From there, the metal point is traced, wherein, for example, by the Be ^¬ operating parameters S and the speed v, the tempera ^¬ ture or the phase state of the metal 4 influence influential and whose size is known, a continuous

Nachfuhrung the at least one phase component or the temperature is realized in real time. In front of the reel 5 ends the tracking 28 of the metal points. This means that at all tracked metal points of the metal 4 the at least one phase component from the model 13 is known at all times.

The second temperature measurement at the downstream pyrometer 11 serves to consistency check and adaptation of the model.

In the metalworking line 1 according to the invention, the information about the phase state of the metal 4 obtained by the model 13 is not or Control of Kuhlstrecke 2 used, but the proportion of at least one phase with respect to a specific point 15 of the Kuhlstrecke 2, here at the end of the Kuhlstrecke 2, at or shortly after the pyrometer 11, brought by the display device 10 to an operator for display. This allows on the one hand a continuous quality assurance monitoring, on the other hand an operator can observe the effect of a change of the operating parameters S in the context of a manual activation. Therefore, additional information is available which leads to an improvement in the quality of the processed metal 4 and to an increase in the safety of the cooling section 2.

In the context of the method according to the invention carried out in the cooling section, not only the determination of the phase component (s) taking into account operating parameters and state parameters of the metal 4 and the display of the component on the display device 10 is provided, but also the possibility of a prognosis. The model 13 is designed to predict in advance what effects an altered control of actuators 6 of the cooling line 2 has on the phase state of the metal 4 at the point 15. For this purpose, the current phase components of a metal point are used directly in front of the relevant actuator or the first actuator 6 concerned, in order to start from this

Perform prediction, which determines the expected proportion of at least one phase at the point 15 taking into account the current and changed operating parameters S and the other operating parameters, such as the speed v. This information is also the

Operator after the detection advantageously displayed so that it does not have to wait to observe the influence on the phase distribution until a processed with the new operating parameters metal point actually reaches the point 15. Expediently is also a

Provided test mode, in which the control device 7, for example, by selecting a corresponding switch panel shown on the display device 10 is switchable, wherein changed Operating parameters S not immediately, but, for example, only after pressing a control element, be accepted. However, a prognosis for the position 15 is already created and displayed during the changed control that has not yet been applied, so that an operator can adjust his setting accordingly without producing rejects. This forecast is also based on the current phase proportions or temperatures contained in models 13 and 14.

FIG. 2 shows a possible user interface 29 to be displayed on the display device 10 (a monitor). In a first area 16, general information about the metalworking line 1 is displayed, a second area 17 serves to display and set operating parameters S of the actuators 6 Design of such areas is well known and will not be more detailed here. In addition, however, an area 18 for displaying information about the metal 4 is provided. In a generally known manner, information 19 about the

Temperature of the metal 4 displayed at the point 15. In addition, however, there is provided a display 20 of the present current at the point 15 of the metal phase portions 4, as determined by the Mo ^¬ dell. 13 In addition, a prognosis 21 with modified activation in the area 18 can also be represented. If the original value before changed control is additionally displayed in 21, a direct comparison is possible. Furthermore, the user interface 16 may include an operating element 22 for activating the above-described test mode, as well as a further operating element 23 for accepting the changed operating parameters entered in a test mode. Of course, as known, further selectable for example by means of a mouse control 24 controls can be provided.

FIGS. 3A-3D show various possibilities of designing the display 20 of the proportion of the at least one Phase. FIG 3A shows a display 20a in the form of a Tortengra ^¬ PhiK. Shown are the proportions of the phases ferrite, austenite and the proportion of other phases.

FIG. 3B shows a display 20b in the form of a bar chart. The proportions of the phases ferrite, austenite, perlite and cementite are shown.

FIG. 3C shows a numerical display 20c of the proportions of the phases ferrite and austenite as well as other phases.

FIG. 3D shows a possible display 2Od in the form of a color graphic. Along a single bar, the proportions of the phases austenite, perlite, cementite and ferrite are shown in different colors and scaled in the same length. The boundaries 25 between the colors shift according to the changes as indicated by the arrows 26. In addition, a scale of 0% to 100% can be provided so that the shares can also be read. This provides a particularly intuitive embodiment of the display 2Od. Of course, color coding is also possible with the other displays 20a, 20b and 20c.

When the phase components change, the respective representations change in accordance with the real-time determination of the

Shares, so that the user can instantly know ^¬ the actual phase distribution - either in the working mode or in test mode.

The controller 7 is further configured to issue a warning message when at least a portion below Wenig ^¬ least exceeds a predetermined value at the point 15 or. Such a warning message 27 is shown by way of example in FIG. The display device 10 may also include an acoustic component that may generate an audible warning signal. The alert directs the operator's attention to the display 20 of the phase state 4. It is pointed out that there is a problem with quality or even a dangerous situation.

Claims

claims

A method of supporting at least partially manual control of a metalworking line in which strip or slab or pre-profiled metal is processed, wherein continuously the proportion of at least one metallurgical phase of the metal relative to at least one particular location of the metalworking line takes into account the phase condition influencing Betπebs- parametern the metalworking line and / or conditional parameters of the metal determined and the proportion of at least one phase based on the specific point of the metalworking line is brought to an operator for display.

2. The method according to claim 1, characterized in that for determining the proportion of a model for determining the phase state of Me ^¬ talls at different metal points is used, wherein a tracking of the metal points and / or Pπmardaten, which enters the metal processing line metal and its state be considered.

3. The method according to claim 1 or 2, characterized in that at least one measuring device is used for recording state parameters, in particular a pyrometer.

4. The method according to any one of the preceding claims, characterized in that the metal is processed in a cooling path for cooling the metal from ^¬ formed metal processing line.

5. The method according to claim 4, characterized in that measured values of one of the Kuhlstrecke upstream first and one of the Kuhlstrecke downstream second pyrometer are used as the state parameter.

6. Method according to one of the preceding claims, characterized in that the proportion is displayed relative to a point at the end of the processing line.

7. Method according to claim 1, wherein in addition to the determination of the current component with changed control of at least one component of the processing line, a prognosis for the future component is also determined and displayed taking into account the changed control at the location.

8. The method according to claim 7, wherein a test mode is selected in which the changed control is not immediately adopted.

9. Method according to one of the preceding claims, characterized in that the proportion of austenitic and / or ferritic and / or political and / or cementitic and / or further phases is determined and displayed.

10. The method according to any one of the preceding claims, characterized in that the display of the proportion in the form of a curve and / or as pie ^¬ graphic and / or in numerical form and / or as a bar chart and / or as a color graphic.

11. The method according to any one of the preceding claims, characterized in that when falling short of or exceeding at least one predetermined value for at least a portion of the site a warning message is issued.

12. Metal processing line for the treatment of band- o- the brammenformigem or pre-profiled metal (4) comprising a control device (7) comprising a continuous determination of the proportion of at least one metallurgical phase of the metal (4) with respect to at least one specific point (15) Metal processing line (1) taking into account the phase parameters influencing operating parameters (S) and / or state parameters of the metal (4) formed computing unit (8), an input device (9) for at least partially selectively possible manual control of the operation of the metalworking line and a display (20) the proportion of the at least one phase relative to the specific point (15) of the metalworking line (1) formed display device (10).

13. Metalworking line according to claim 12, characterized in that in the arithmetic unit (8) for determining the proportion of a model (13) for determining the phase state of the metal (4) at various metal points taking into account a tracking (28) of the metal points and / or from Pπmardaten (P), which describe the in the metalworking line (1) incoming Me ^¬ tall (4) and its state, is stored.

14. Metal working line according to claim 12 or 13, characterized in that it rametern at least one measuring device for recording Zustandspa ^¬, in particular a pyrometer (11) comprises.

15. Metal working line according to one of claims 12 to 14, d a d u c h e c e n e c e in that it is an actuator (6) for influencing the temperature of the metal (4) comprising Kuhlstrecke (2).

16. Metal processing line according to claim 15, characterized in ^{¬ ¬ characterized in} that in each case at the beginning and at the end of the Kuhlstrecke (2) a pyrometer (11) are provided, wherein the arithmetic unit (8) for Berucksich- tion of the measured values (T) of the pyrometer (11) is designed as a state parameter.

17. The metalworking line according to claim 12, characterized in that the display device (10) displays the proportion in the form of a curve and / or as a pie chart (20a) and / or in numerical form (20c) and / or as a bar chart ( 20b) and / or as a color graphic (20d) is formed.

18. Metal processing line according to one of claims 12 to 17, adapted for carrying out the method according to one of claims 1 to 11.