EP2428288B1 - Method for producing steel bands using continuous casting or semi-continuous casting - Google Patents

Description

FIELD OF THE INVENTION

The invention relates to a method for producing steel strips by endless rolls or semi-endless rolls, wherein first in a casting plant, a slab is poured, the slab is rolled in a roughing mill to a pre-strip, the pre-strip is heated in an oven and the heated pre-strip in one Finishing mill is rolled to a predetermined final thickness and a predetermined Endwalztemperatur finish.

One speaks of "endless rolls", when a casting plant is connected to a rolling mill, that the cast in the casting slab directly - without separation from the just cast slab part and without intermediate storage - fed into a rolling mill and rolled there to the final thickness. The beginning of the slab can therefore already be finished rolled to a steel strip to the final thickness, while the casting plant continues to pour on the same slab, so there is no end of the slab. One speaks also of directly coupled operation or endless operation of the casting and rolling plant.

In the so-called "semi-continuous rolling" the cast slabs are divided after casting and fed the separated slabs without intermediate storage and cooling to ambient temperature of the rolling mill.

The emerging from the casting slab is usually descaled, pre-rolled, the resulting pre-strip is heated in an oven and rolled finished in the finishing train. In the finishing train usually hot rolled, that is, the rolling stock during rolling a Temperature above its recrystallization temperature. For steel, this is the range above about 720 ° C, usually is rolled at temperatures up to 1200 ° C warm.

During hot rolling of steel, the metal is usually in the austenitic state, where the iron atoms are arranged cubic face centered. One then speaks of rolls in the austenitic state, when both the initial and the final rolling temperature are in the austenitic region of the respective steel. The austenite area of a steel depends on the steel composition, but is usually above 800 ° C. In order to safely roll in the austenitic state during the entire process of finish rolling, a correspondingly high final rolling temperature is usually specified in the pass plans.

STATE OF THE ART

The continuous rolling or semi-continuous rolling of steel strips is well known from the prior art, as are the disadvantages that result from it: in particular in continuous rolling transmits each fluctuation in the casting process to the rolling process by the direct coupling of casting and rolling. During casting, with fluctuating casting speed and with disturbances of the casting plant, fluctuations in the speed and the temperature of the preliminary strip can occur, which in turn has an effect on the finish rolling of the steel strip and can lead to quality fluctuations. In particular, the mass or volume flow of the Vorbands may change and / or the temperature of the Vorbands. The mass or volume flow changes z. B. if, with the same thickness and width of the Vorbandes the speed of the Vorbandes changes or if the thickness changes with the same width and speed of the Vorbandes. Instead of the volume flow, the width-specific volume flow is often used in the rolling technique, ie as a volume flow per unit width (1 m), which can be represented as a product of the thickness of a belt and belt speed, in particular if the width of the belt plays no special role for the process in question. This often applies when the width is at least seven to ten times the thickness. The (broad specific) mass flow is known to be obtained by multiplying the (specific volume) volume flow by the density of the belt.

Fluctuations in the temperature and / or the width-specific mass or flow rate can lead to the actual final rolling temperature, ie the temperature of the steel strip after the last mill stand of the finishing train, deviating from the desired final rolling temperature, which can be associated with quality losses. Thus, as an essential product property, the microstructure of the steel strip may deviate from the desired microstructure, such as an austenitic microstructure. But it can also come to deviations from the desired thickness or the desired profile of the steel strip. But the quality of the finished steel strip can also be so bad that it has to be treated as scrap.

In the conventional hot rolling of slabs or slivers, which are separated from the cast strand, usually a change in the final thickness of the steel strip is only allowed from one slab or a preliminary sliver to the next slab or to the next slate. Likewise, the temporal inlet temperature profile of the pre-strip in the finishing train and the flow rate profile (thickness change, width change) and in particular a fixed finish rolling temperature (on the last rolling stand) for a slab or a subband are always set in advance. During rolling of the same slab or apron, deviations from these intended or expected gradients are generally not permitted. Slowly decreasing inlet temperatures of the pre-strip when entering the finishing train are increased by an increase in the Speed of the pre-strip (speed-up) compensated, so that the Stichabnahmeperteilung on the individual stands and the final rolling temperature can still be approximated. Changes to the pass plan, ie a distribution of the sampling on the individual rolling stands, are carried out in the idle time between leakage of a finished steel strip and the arrival of the next Vorbandes. There are no critical operating conditions in the finishing mill because the basic rolling mill control has already been determined in advance for each pre-strip. Sudden changes in the inlet temperature of the pre-strip in the finishing train lead to increased rejects, sudden changes in the flow rate at the inlet of the pre-strip in the finishing train are excluded.

In semi-endless rolling the usually overlong slab is separated from the strand of the casting plant, a newly incoming slab can be braked to the pass schedule of the finishing train due to changes in properties (temperature, width, thickness, speed of the slab or Vorbands) or because of Recalculation of a new final thickness.

When fully continuous endless rolling accounts for the idle times between the individual metal bands or slabs and all changes in the operating condition of the composite system must be done during load operation, ie while a steel strip is rolled in the finishing train.

In order to ensure a sufficiently high final rolling temperature for relevant processes, the DE 10 2007 058 709 A1 on the other hand, to determine a functional relationship between casting speed or mass flow on the one hand and final rolling temperature on the other hand for a certain number of active rolling stands and different final thicknesses, to determine the optimum number of active rolling stands on specification of a certain casting speed or mass flow, with which a desired final rolling temperature is achieved and optionally a number of rolling stands drive so that only the optimum number of rolling stands is active.

But only by reaching a desired final rolling temperature can not be ensured that a certain final thickness of the steel strip is achieved. According to DE 10 2007 058 709 A1 Paragraph 20, this is not intended.

PRESENTATION OF THE INVENTION

It is therefore an object of the invention to provide a method which ensures - if technically possible - the achievement of the desired final thickness and - in any case - reaching the desired final rolling temperature of the steel strip in case of fluctuations in the mass or volume flow and / or speed That is, the achievement of that final thickness or that final rolling temperature, which is desired and achievable without the aforementioned fluctuations in undisturbed operation of the endless compound system. Such a method is also applicable in the case of start-up of the endless compound system, when the broadly specific mass flow or volume flow of the pre-strip increases slowly.

• bei Änderung der Einlauftemperatur des Vorbandes beim Einlaufen in die Fertigwalzstraße um mehr als 1 K/Sekunde, insbesondere um mehr als 5 K/Sekunde, und/oder
• bei Änderung des Einlaufmassenstroms des Vorbandes beim Einlaufen in die Fertigwalzstraße um mehr als 0,2 %/Sekunde, insbesondere um mehr als 1,5 %/Sekunde,

ein neuer Stichplan ausgewählt wird, mit dem die gewünschte Enddicke und die gewünschte Endwalztemperatur erzielt wird, wobei das letzte in Eingriff befindliche Walzgerüst der Fertigwalzstraße aus dem Walzeingriff gebracht wird oder ein Walzgerüst der Fertigwalzstraße in Walzeingriff gebracht wird, das dem letzten in Eingriff befindlichen Walzgerüst nachgeschaltet ist, unter der - wesentlichen - Nebenbedingung, dass eine Minimierung der Energie, die dem Ofen und/oder der Fertigwalzstraße zugeführt wird, erreicht wird,
und dass die Einlauftemperatur des Vorbandes durch Regelung des Ofens und die Walzgerüste entsprechend dem neuen Stichplan eingestellt werden.The problem is solved by that

• when changing the inlet temperature of the pre-strip when entering the finishing train by more than 1 K / second, in particular by more than 5 K / second, and / or
• when changing the inlet mass flow of the pre-strip when entering the finishing train by more than 0.2% / second, in particular by more than 1.5% / second,

selecting a new pass schedule to achieve the desired final thickness and finish roll temperature, wherein the last intermeshing stand of the finishing train is brought out of rolling engagement or a rolling stand of the finishing train is in rolling engagement which is connected downstream of the last rolling mill engaged, under the essential condition that a minimization of the energy supplied to the furnace and / or the finishing train is achieved;
and that the inlet temperature of the Vorbandes be adjusted by controlling the furnace and the rolling stands according to the new stitch plan.

Changes in the inlet temperature or the inlet mass flow are detected by measuring devices, whereby the usual measures are taken to ensure the validity and accuracy of the signals, which are sometimes already integrated in the measuring instruments, or carried out on the statistical basis in the measurement processing. In particular, so-called filtering methods are used so that only statistically significant and freed of the usual signal noise measured values are used to assess the current constancy or variability of inlet mass flow or inlet temperature.

Thus, if there is a significant change in the mass flow and / or temperature of the pre-strip as it enters the finishing train, then a new pass schedule must be used to continue to achieve the desired final thickness and finish rolling temperature of the steel strip. A change in the inlet temperature of the pre-strip when entering the finishing train by more than 1 K / second or the inlet mass flow of more than 0.2% / second corresponds to the conditions when starting the Gießwalz composite system and provides a constant or slow change of inlet temperature and Inlet mass flow. The values of more than 5 K / second or more than 1.5% / second correspond to the values of a disturbance of the cast roll compound system and represent a significant and mostly also suddenly occurring change of inlet temperature and inlet mass flow. In determining the new stitching plan, an attempt is made to achieve the desired final thickness and finish rolling temperature of the steel strip while minimizing the energy consumed in the furnace and / or in the finishing train.

Energy can be saved when a not necessarily required rolling stand is driven up, which is then no longer in engagement with the steel strip and where the steel strip passes through this mill without changing the thickness. In this case, however, only a rolling stand is ever driven up and also only that which was previously in the past in engagement with the steel strip. Thus, if only the first five were in engagement with the steel strip, ie "active", of six rolling mills of the finishing train, then according to the invention only the fifth mill stand could possibly be driven up, and not the fourth.

But it may also be necessary to switch on a rolling stand, because otherwise the desired final thickness and final rolling temperature can not be achieved, even if this leads to an increase in the required energy. In this case, only one rolling stand is switched on per change of the stitch plan and always only that which is directly downstream of the rolling mill last engaged. Thus, of the six rolling mills of the finishing train last - before the stitch plan change - only the first four in engagement with the steel strip ("active"), so only the fifth mill stand can be switched, and not the sixth, which in this case the Last mill stand of the finishing train is. When minimizing the energy, therefore, care must always be taken, for example by formulating a corresponding boundary condition in a mathematical process model, that the desired final rolling thickness is achieved unchanged.

Energy can also be saved if the inlet temperature is lowered, ie the temperature with which exits the subband from the oven and enters the finishing train. This will be possible in particular if the number of active rolling stands of the finishing train is reduced by one and in the remaining active rolling stands thickness reductions of the steel strip close to the maximum possible reduction degrees (relative change in thickness of the steel strip after and in front of the rolling stand), because thereby per rolling stand more dissipative forming heat is generated, which additionally heats the steel strip. The maximum possible reduction rates are determined on the one hand by the material properties of the steel strip itself, on the other hand by the roll stand, which can muster only a finite rolling force.

Needless to say, in the method according to the invention, only adjustments of the rolling stands within predefined limit values are meaningful in order not to damage the composite installation and in particular the finishing train. Thus, for rolling stands, for example, maximum permissible rolling and bending forces are predetermined, the exceeding of which may lead to damage to the rolling stands or to roll breakage. Furthermore, there are limits for the maximum possible speed of the steel strip, which can be determined both by the drive of the rolling stands and / or the reels and by the properties of the steel strip, for example, to prevent damage thereof.

However, if the individual active rolling mills of the finishing train have not yet reached the limit values, it is provided according to the invention to open the last active mullion with increasing mass flow of the pre-strip and to distribute the pass decreases to the then remaining active mills. As a result, energy can be saved for the furnace, because the now higher changes in thickness per rolling stand more energy is introduced in the form of heat of transformation in the steel strip and thereby heats the steel strip.

The term "if possible within plant-technical limit values" therefore means that the originally desired final thickness may be sought only if this is possible within the limit values applicable to the finishing train, in particular the maximum permissible rolling and bending forces. This will usually be possible if the inlet temperature or the inlet mass flow increase and an additional rolling mill is switched on. The originally desired final thickness can, however, possibly not be maintained if the inlet temperature or the inlet mass flow sink and a rolling stand is driven up because in some cases the rolling and bending forces of the finishing train needed to maintain the final thickness would exceed the corresponding limit values. It must therefore be allowed a greater final thickness, which must not be a disadvantage if later in the rolling program anyway a larger final thickness is to be rolled.

In any case, when a rolling stand is fed in or driven up, the stitch decreases, ie the changes in thickness per rolling stand, must be redistributed to the individual then active rolling stands. The distribution of the pass decreases on the individual rolling stands is what the expert calls "pass schedule". However, a stitch plan also contains further information about the rolling process, as is well known to those skilled in the art.

The rolling stock, ie the steel strip, is described at any time during the rolling process and thus also in the stitch plan at least by the following variables: speed, thickness, temperature and relative profile (thickness of the strip in the middle relative to the edge). Each roll stand is characterized - also in the pass chart - at least by the following variables, which simultaneously represent the manipulated variables of the roll stand: peripheral speed of the work rolls, rolling force and bending force.

It can be provided that the new stitch plan is determined during the ongoing rolling process. In doing so, the new pass schedule can be recalculated with the aid of the current measurement data of the rolling process and therefore particularly accurate. Of course, it would also be possible to predict different stitch plans with different data of the rolling process before the rolling process and store them in a database, so that then with a significant change in the inlet temperature and / or the inlet mass flow a suitable new stitch plan can be selected from the saved stitch plans. However, since only a finite number of pass schedules can be predicted and stored in a database, and these will then not be entirely suitable for the given rolling process, this procedure will lead to comparatively worse results than the calculation of the new pass schedule during the rolling process ( online calculation).

The new stitch plan according to the invention is best created by means of a mathematical process model that simulates the rolling process of at least all rolling mills of the finishing train. During the rolling process, the rolling process in the finishing train can be recalculated several times per minute due to the process model.

In this case, in each calculation step, for example, the final rolling temperature, the final thickness, the rolling and bending forces required per framework and the energy requirements of the finishing wharf and the furnace can be calculated. Then the distribution of the rolling force on the individual rolling stands and also the number of active rolling stands is varied and thereby determined whether an active rolling mill would be less energetically advantageous in compliance with plant limits and operational limits.

Those skilled in the art are familiar with such mathematical process models, some examples of which are in the publication, for example EP 1 014 239 A1 called, where usually several Partial models are used: rolling force models, speed models, temperature models and profile models.

In order to achieve a minimization of the energy that is supplied to the furnace and / or the finishing train, a so-called objective function can be formed, which is a mathematical optimization, such. B. an extreme value formation, is subjected, and the determined in this way function values of the objective function are used to create a stitch plan.

For example, the function values of the objective function determined by the optimization can be used directly as parameters of the stitch plan. One possible embodiment is that the objective function is a function of state variables of the rolling stock, such as speed, thickness, temperature, relative profile, and / or control variables, such as peripheral speed, rolling force, bending force.

In the subject invention, the objective function will be the energy supplied to the furnace and / or the finishing train so that, for example, a very low energy pass schedule is calculated. Because at least one condition imposed on the pass schedule in the form of a limit value is taken into account as a secondary condition during the optimization, plant technology or technological limit values are included in the optimization in a simple manner. Furthermore, at least one condition that specifies a fixed value for a control or state variable is considered as a constraint in the optimization. As a result, defined values, just the desired final thickness and the final rolling temperature, can be incorporated into the optimization.

Which mathematical methods are now used concretely for optimization, is left to the expert and will not be described here. Some applicable methods are in the already mentioned EP 1 014 239 A1 cited.

If it is not possible to find a new stitch plan with the desired final thickness and finish rolling temperature, then the stitch plan may be used for which, under given constraints, the solution with the smallest violation of the constraints occurs. For example, a deviation from the desired final thickness may be allowed if such a product had to be manufactured anyway at a later date according to the production plan. But at least a final rolling temperature can be achieved, where the metal is in the austenitic state.

Specifically, it can be provided that the process model of the stitch plan at least the final rolling temperature of the steel strip, the final thickness of the steel strip, and the combined energy demand of the finishing train and the furnace is calculated, the number of rolling stands varies and the associated energy for the rolling stands and the Furnace is determined, and if, in accordance with predetermined limits for the settings of the rolling stands and the furnace, a variation in a reduction of the common energy requirement results, this is based on the new pass schedule.

But it can also be sought only a minimization of the furnace energy, it is then provided that at least the final rolling temperature of the steel strip, the final thickness of the steel strip, and the energy consumption of the furnace is calculated with the process model of the stitch plan, the number of rolling stands varies and the associated energy for the furnace is determined, and if, in accordance with preset limits for the settings of the rolling mills and of the furnace, a variation results in a reduction of the energy for the furnace, this is based on the new pass schedule.

Another way to minimize the energy required for the furnace is to increase the thickness of the pre-strip is changed. In this case, the rolling stands of the rough rolling mill must also be included in the new pass schedule to be recalculated. Although the thinner the pre-band is, the lower the energy required to heat the pre-band in the oven. However, the aim here is to select the pre-strip thickness at given values for intake mass flow, end strip thickness and final rolling temperature so high that the active rolling stands of the finishing train are as close as possible to the maximum possible reduction levels to replace the energy saved at the furnace by the dissipative forming heat. The temperature of the steel strip as it exits the furnace, which is proportional to the energy supplied to the furnace, should generally not exceed 1250 ° C, more preferably be less than 1220 ° C. However, if the reduction levels in the rolling mills of the finishing train are increased, the temperature of the steel strip as it exits the furnace may be lowered to, for example, about 1090 ° C.

The method according to the invention can be used both for endless rolling or semi-endless rolling. In particular, it can be used for startup and startup of a cast roll compound plant after a casting-rolling break, ie the daily restart of the plant and not only after a plant shutdown due to an error. If it is used for semi-endless rolling, then there are basically two possibilities when the stitch plan change takes place and thus, when a rolling stand for the implementation of the new stitch plan is switched on or driven.

The pre-strip to be rolled may already be in the finishing train when a rolling stand is brought into rolling engagement or out of rolling engagement. This corresponds to the continuous rolling process, where the endless steel strip runs through all the rolling stands. Semi-continuous rolling produces several pre-bands from the split slabs, which run into the finishing train relatively just one behind the other, usually only with a time interval of less than 20 seconds, preferably less than 10 Seconds, especially less than five seconds. In this first variant, the connection or driving of a rolling mill is carried out regardless of whether a steel strip is in the finishing train or not. Therefore, it is likely to take place when there is just a steel strip in the relevant rolling stand.

In the second variant, it is provided that the pre-strip to be rolled during semi-endless rolling only enters the finishing train when a rolling stand has been opened or closed in accordance with the new pass schedule. That is, it must be arranged in front of the finishing train a pair of scissors, which cuts through the opening band, so that that part which is already in the finishing train, can be accelerated out of the finishing train, while not yet in the finishing train part enters the finishing train (or at least not in the rolling mill to be adjusted) until the corresponding rolling mill has been adjusted according to the new stitch plan. The cutting of the pre-strip is not a disadvantage, because a finished strip is usually too long for a bunch and therefore anyway must be cut after the finishing train at least once to wind it up to at least two coils. So you can perform the cut of the steel strip instead of after the finishing mill before the finishing mill and thus simultaneously create a break for the necessary conversion to the new stitch plan.

When driving on or connecting a roll stand, the roll gap per second can be increased or reduced by about 5 mm.

The method according to the invention can be carried out with the aid of a computer program product which, when loaded and executed on a computer, determines a pass schedule according to one of the method claims.

With the method according to the invention it can be ensured that the finish rolling can be carried out with the highest possible operational reliability despite considerable or sudden reduction of inlet temperature and / or wide-range inlet mass flow, for example due to faults in the furnace, descaling or the casting plant.

Either the total energy consumption of the furnace plus the finishing train or only the energy consumption of the furnace can be minimized, in particular with a constant or slowly changing input state (inlet temperature and mass flow).

The inventive method requires only a small control effort in the actuators for the strip temperature (oven, cooling).

The inventive method allows a very early start of finish rolling after casting start, even if the inlet mass flow is still relatively low. By connecting one rolling mill after the other in the finishing train, the strip thickness can be gradually reduced as the inlet mass flow and / or the heating power of the furnace are gradually increased.

BRIEF DESCRIPTION OF THE FIGURES

The invention will be explained by way of example with reference to a schematic figure. The figure shows the side view of a cast roll compound system.

WAYS FOR CARRYING OUT THE INVENTION

In the figure, an embodiment of a cast-roll composite plant is sketched on which the inventive method for producing steel strips 1 can be performed. There is a vertical caster 2 available in the slabs 3 are cast, for example, 70 mm thickness. On a pair of scissors 12, cutting could be carried out to a desired slab length during semi-endless rolling. It is followed by a first oven 6, in which the slab 3 is brought to about 1000 to 1200 ° C rough rolling temperature T1 and in which there is a certain temperature compensation in the width direction. The oven 6 can also be omitted.

Then the rough rolling takes place in a rough rolling 4, which may consist of a - as here - or of several stands and in which the slab 3 is rolled to an intermediate thickness or Vorbanddicke. During roughing, the transformation of cast structure into the fine-grained rolling structure takes place. It is also possible to dispense with the use of a scale washer 13 or another system for descaling upstream of the rough rolling mill 4.

Behind the framework of Vorwalzstrasse 4, another furnace 7 for the pre-band 3 'is arranged. The furnace 7 may preferably be designed as an induction furnace, but also as a conventional furnace or as a high-temperature furnace with flame treatment. Therein, the pre-strip 3 'is brought relatively uniformly over the cross section to the desired inlet temperature T2 for the inlet to the finishing train 5, wherein the inlet temperature T2 usually depending on the steel grade and subsequent rolling in the finishing train 5 between 1090 ° C and 1250 ° C. lies.

After the heating in the oven 7, the finish rolling in the multi-stand finishing train 5 to the desired final thickness and final rolling temperature and then the belt cooling in a cooling section 14 and ultimately the winding by means of reel 15. On the scale scrubber 13 before and / or between the rolling stands 51-56 can also be dispensed with.

If now when starting up the Gießwalz compound system, such as after a break in operation, the inlet mass flow of the Vorbandes 3 'in the finishing train 5 is still relatively low (<70% of the intake mass flow during normal operation), is rolled only with the first three rolling stands 51-53. If now the inlet mass flow increases continuously, in order to achieve the desired final thickness and final rolling temperature, first the fourth rolling stand 54, then in a further step, the fifth rolling stand 55 and possibly also the sixth rolling stand 56 closed, so active. Before connecting a further roll stand, the temperature in the furnace 7 and thus the inlet temperature T2 of the pre-strip 3 'would decrease with increasing inlet mass flow. As soon as another scaffold is switched on or closed, the inlet temperature must be raised significantly, typically between 35 and 55 K, for reasons of economy or product quality 1250 ° C, more preferably 1220 ° C surface temperature should not be exceeded.

Likewise, care should be taken that in the event of a sudden, unpredictable change in the inlet mass flow or inlet temperature (e.g., partial failure of the oven 7), one additional rolling stand 51-56 is opened or closed to achieve the desired final thickness and finish rolling temperature.

However, it is according to the invention - both in continuous changes as well as sudden changes in the inlet sizes (temperature, mass flow) - to make sure to use only the actually necessary number of rolling stands 51-56. In particular, the pre-strip thickness is to be selected so high that at the lowest possible inlet temperature, eg 1090 ° C, the three, four or five currently still active rolling stands with maximum reduction ratios, ie at the technical limits of the rolling stands, the desired steel strip just can still produce ,

The following is an example of a 1570 mm wide strip product with a finishing line inlet thickness of 15 mm and a broad specific inlet mass flow of 440 mm m / min specify. It shows the reduction in total energy demand, as well as the changes in roll mill rolling capacity, the number of passes and the furnace energy required, if only four stands are used instead of five:
Scaffolding 51-55 Scaffolding 51-active 54 active Inlet temperature 1069 ° C 992 ° C Preload inlet Thickness 15 mm 15 mm Inlet mass flow 440 mm m / min 440 mm m / min Substrate Total energy requirement 125 102 (furnace + finishing mill) [kWh / t] Energy requirement Kiln 91.5 61.5 [kWh / t] Scaffolds 51-55 active Scaffolds 51-54 active Stich- Rolls- Total- Stitch- Rolling Total Decay Energy Decrease force Energy Demand [MN] Demand [%] [MN] Demand [%] [kWh / t] [kWh / t] Rolling stand 43 22.5 33.5 53 33 40.5 51 Rolling stand 41 25 49 33 52 Rolling stand 36 22.5 37 23 53 Rolling stand 30 21 20 14 54 Rolling stand 20 14 0 0 0 55

LIST OF REFERENCE NUMBERS

1

steel strip

2

casting plant

3

slab

3 '

opening act

4

roughing

5

Finish rolling mill

51

first rolling stand of the finishing train

52

second rolling stand of the finishing train

53

third rolling stand of the finishing train

54

fourth rolling stand of the finishing train

55

fifth rolling stand of the finishing train

56

sixth rolling stand of the finishing train

6

Oven for slab

7

Oven for support band

12

scissors

13

descaling

14

cooling section

15

reel

F

conveying direction

T1

Vorwalztemperatur

T2

Inlet temperature of the steel strip when entering the finishing train

Claims (10)

1. Method for producing steel strips (1) by continuous rolling or semi-continuous rolling, wherein firstly a slab (3) is cast in a casting plant (2), the slab (3) is rolled in a roughing train (4) to produce a transfer bar (3'), the transfer bar (3') is heated in a furnace (7) and the heated transfer bar (3') is finished by rolling in a finishing train (5) to a predefined final thickness and a predefined final rolling temperature, characterised in that

   - if there is a change in the feed temperature (T2) of the transfer bar (3') by more than 1 K/second, in particular by more than 5 K/second, when it is being fed into the finishing train (5), and/or

   - if there is a change in the feed mass flow of the transfer bar by more than 0.2%/second, in particular by more than 1.5%/second, when it is being fed into the finishing train,
   a new pass schedule is selected in order to achieve the desired final thickness and the desired final rolling temperature, wherein the last rolling stand of the finishing train (5) that is in engagement is brought out of rolling engagement or a rolling stand of the finishing train which is arranged downstream of the last rolling stand in engagement is brought into rolling engagement, subject to the subsidiary condition that the energy supplied to the furnace (7) and/or to the finishing train (5) is minimised,
   and that the feed temperature (T2) of the transfer bar (3') is set by regulating the furnace (7) and the rolling stands (5) are set in accordance with the new pass schedule.
2. Method according to claim 1, characterised in that the new pass schedule is determined during the ongoing rolling process.
3. Method according to claim 1 or 2, characterised in that the new pass schedule is produced on the basis of a mathematical process model which simulates the rolling process of at least all of the rolling stands (51-56) of the finishing train (5).
4. Method according to claim 3, characterised in that the process model of the pass schedule is used to calculate at least also the final rolling temperature of the steel strip, the final thickness of the steel strip, as well as the joint energy requirements of the finishing train (5) and the furnace (7), wherein the number of rolling stands (51-56) is varied and the associated energy for the rolling stands and the furnace is determined, and if a reduction in the joint energy requirements results in the event of a variation while maintaining predefined limit values for the settings of the rolling stands and the furnace, this is used as a basis for the new pass schedule.
5. Method according to claim 4, characterised in that the process model of the pass schedule is used to calculate at least also the final rolling temperature of the steel strip, the final thickness of the steel strip and the energy requirements of the furnace (7), wherein the number of rolling stands (51-56) is varied and the associated energy for the furnace is determined, and if a reduction in the energy for the furnace results in the event of a variation while maintaining predefined limit values for the settings of the rolling stands and the furnace, this is used as a basis for the new pass schedule.
6. Method according to one of claims 1 to 5, characterised in that the thickness of the transfer bar (3') is varied in order to minimise the energy required for the furnace (7).
7. Method according to one of claims 1 to 6, characterised in that continuous or semi-continuous rolling comes into application during the starting up and ramping up of a combined casting and rolling plant after a casting/rolling interval.
8. Method according to one of claims 1 to 7, characterised in that during semi-continuous rolling the transfer bar (3') is already located in the finishing train (5) when a rolling stand (51-56) is brought into rolling engagement or out of rolling engagement.
9. Method according to one of claims 1 to 7, characterised in that during semi-continuous rolling the transfer bar (3') to be rolled is not fed into the finishing train (5) until a rolling stand (51-56) has been activated or raised in accordance with the new pass schedule.
10. Computer program product, characterised in that when it is loaded and executed on a computer it determines a pass schedule according to one of the preceding claims.

Images