WO1999031949A2 - Method and device for coating a metal strip - Google Patents

Abstract

The invention relates to a method and a device for coating a metal strip (5). The metal strip passes through a bath (11) of coating metal, especially zinc. After the metal strip has left the bath (11), part of the coating metal is blasted away with air from at least one nozzle (6, 10). The thickness of the metal coating on the metal strip (5) is regulated according to the distance (a, ao, au) between the metal strip (5) and the nozzle (6, 10), using a coating model (30). This distance is determined using an inverse coating model (31).

Description

description

Method and device for coating a metal strip

The invention relates to a method and a device for coating a metal strip which runs through a bath with coating metal, in particular zinc, a part of the coating metal being blown away after leaving the bath with air which emerges from at least one nozzle.

Such a device is known from EP 0 663 632 AI. Furthermore, EP 0 663 632 A1 discloses a regulation in which the layer thickness of the coating metal on the metal strip is dependent on the speed of the metal strip, the distance between the nozzle and the bath through which the metal strip runs, and the distance between the nozzle and the metal band and depending on the angle of attack of the nozzle with respect to the metal band. A model of the coating process is used, which is adapted to the actual conditions in the coating process. A particularly precise coating can be achieved in this way.

It is an object of the invention to provide a method and a device for the particularly precise coating of a metal strip. It is particularly desirable to further improve the control according to EP 0 663 632 AI.

The object is achieved according to the invention by a method according to claim 1 or a device according to claim 14. The metal strip, which runs through a bath with coating metal, is exposed to an air stream that emerges from a nozzle. Part of the coating metal that has deposited on the metal strip is removed by the air stream after leaving the bath with coating metal. blow. The layer thickness of the coating metal on the metal strip is regulated by means of a coating model as a function of the distance between the metal strip and the nozzle, the distance between the metal strip and the nozzle being determined by means of an inverse coating model. In this way, more precise layer thicknesses can be achieved. The method according to the invention and the device according to the invention are used particularly advantageously in connection with the formation of the coating model and the inverse coating model based on a neural network according to EP 0 663 632 AI.

In an advantageous embodiment of the invention, the layer thickness of the coating metal on the metal strip is regulated as a function of target values for the layer thickness of the coating metal on the metal strip.

In a further advantageous embodiment of the invention, the layer thickness of the coating metal on the metal strip is regulated as a function of target values for the layer thickness of the coating metal on the metal strip, the target values of the layer thickness of the coating metal on the metal strip being based on actual values of the layer thickness of the coating metal measured by a so-called cold measurement the metal band are corrected.

In a further advantageous embodiment of the invention, the distance between the metal strip and the nozzle is determined by means of the inverse coating model depending on a measured value of the pressure at which the air exits the nozzle or an equivalent pressure measured value.

In a further advantageous embodiment of the invention, the distance between the metal strip and the nozzle is made dependent on a measured value by means of the inverse coating model the layer thickness of the coating metal determined on the metal strip.

In a further advantageous embodiment of the invention, the layer thickness of the coating metal on the metal strip is measured shortly behind the nozzle in the direction of movement of the metal strip or in the region of the nozzle.

In a further advantageous embodiment of the invention, the measurement of the layer thickness of the coating metal on the metal strip is carried out as a so-called hot measurement.

In a further advantageous embodiment of the invention, when measuring the layer thickness of the coating metal on the metal strip, the layer thickness of the coating metal on the metal strip is measured on both sides of the metal strip.

In a further advantageous embodiment of the invention, a setpoint value of the pressure at which the air exits the nozzle or an equivalent pressure value is determined by means of the coating model.

In a further advantageous embodiment of the invention, the coating model and / or the inverse coating model are adapted on-line.

In a further advantageous embodiment of the invention, the coating model and the inverse coating model are adapted on-line with actual values of the layer thickness of the coating metal measured by means of a cold measurement on the metal strip.

In a further advantageous embodiment of the invention, part of the coating metal becomes after leaving the bath blown away from both sides of the metal strip with air that emerges from at least two opposite nozzles, and the distance between the metal strip and the nozzle determined by means of the inverse coating model is corrected by means of the distance between the opposite nozzles.

Further advantages and details emerge from the following description of ^exemplary embodiments. In detail show:

1 shows a schematic illustration of part of a coating system, FIG. 2 shows the interaction of the coating model and the inverse coating model in an exemplary embodiment, FIG. 3 shows an exemplary embodiment of a coating system using the method according to the invention.

1 shows a schematic illustration of a coating system, for example a hot-dip galvanizing system. Such a coating system is partly described in EP 0 663 632 AI. The metal strip 5 to be coated emerges from a trunk 22 and passes through a bath 11 with liquid coating metal at the speed v. A steel strip is particularly suitable as a steel strip and zinc as a coating metal. After exiting the bath 11 with coating metal, a still liquid layer of coating metal adheres to the metal strip 5. At a distance a ₀ and a _u from the metal strip 5, nozzles 6 and 10 are arranged, from which air flows against the metal strip 5. Excess coating metal is removed from the metal strip 5 due to the air flow that emerges from the nozzles 6 and 10 and strikes the metal strip 5. The airflow is more advantageous wise laminar. The air pressure of the air emerging from the nozzles 6 and 10 is adjusted via an actuator 13, here a valve, as a function of an actuating variable for the pressure, which is determined in a computing device 23. The actuator 13 is arranged in an air line 7, into which air is blown by means of a blower 9. The nozzle 6 is arranged at the other end of the air line 7. A corresponding air supply is assigned to the nozzle 10, but is not shown. The coating system also has deflection rollers 12, 24, 25, 26 and a stabilizing roller 14. Furthermore, a hot measuring device 1 for measuring the layer thickness c _H , o of the coating metal on the top of the metal strip 5, a hot measuring device 2 for measuring the layer thickness c _H , _{u of} the coating metal on the underside of the metal strip 5, a cold measuring device 3 for measuring the layer thickness c _κ , o of the coating metal on the metal strip 5 and a cold measuring device 4 for measuring the layer thickness Ck.u of the coating metal on the metal strip 5 are provided. The hot measuring device 1 and 2 and the cold measuring device 3 and 4 are connected in terms of data technology to the computing device 23.

On the compressed air line 7, a compressed air measuring device 28 is provided, by means of which the pressure p _u in the compressed air line 7 is measured. In terms of data technology, the compressed air measuring device 28 is connected to the computing device 23. Alternatively or in addition, a pressure measuring device can also be provided in the nozzles 6 and 10.

The measured values of the layer thicknesses CH.L, C _H .O, C _K , U CK.O pressure measured values p _u and information about the belt speed v are fed to the computing device. Optionally, the computing device 23 can additionally provide the height h of the nozzles 6 and 10 above the bath 11 with coating metal and to supply an angle of attack α of the nozzles 6 and 10. However, these values can also be stored in the computing device 23. The angle of attack α is not shown for reasons of simplicity m FIG 1. The nozzles 6 and 10 are outlined with an angle of attack α = 0 for the sake of simplifying the illustration. The definition of the angle of attack α can be found in FIG. 1 of EP 0 663 632 AI.

2 shows an exemplary embodiment for the functional interaction of a coating system according to the invention. Reference numeral 32 denotes the coating process, which includes the metal strip 5, the bath 11 with coating metal, the nozzles 6 and 10, the hot measuring devices 1 and 2, the pressure measuring device 28, the actuator 13, the compressed air line 7, the blower 9 and one on the computing device 23 n FIG 1 implemented pressure controller, which controls the actuator 13 depending on a predetermined target pressure p * and the measured pressure p _u , and optionally includes the cold measuring devices 3 and 4 of FIG 1. Numeral 30 denotes a coating model and numeral 31 denotes a reverse coating model. The coating models 30 and 31 are implemented on the computing device 23 in FIG. 1.

2 shows the interaction of the coating model 31 and the coating process 32 for a strip side. Accordingly, the indices "o" and "u" are omitted. The coating model 30 determines a target pressure p * for the pressure in the compressed air line 7 m FIG. 1 m as a function of a target value c * for the layer thickness of the coating metal on the metal strip, as a function of the strip speed v, and of the distance a between the nozzle and the strip. The distance a between the nozzle and the belt is determined by the inverse coating model 31 as a function of the belt speed v, m as a function of the pressure p in the pressure air line 7 or ner equivalent size (such as the air pressure in the nozzle 6 in FIG 1) and the layer thickness c _H , which is measured with the hot measuring device 2 in FIG 1, determined. If, at the start of the coating process 32, there is still no distance a between the nozzle and the metal strip determined by the inverse coating model 31, half of the distance between two nozzles is initially used instead. The inverse coating model 31 is a partially inverse model of the coating model 30.

In a particularly advantageous embodiment, the coating model and / or the inverse coating model are retrained online. It is particularly advantageous to retrain both models, the coating model 30 and the inverse coating model 31. This training of the coating model 30 and the inverse coating model 31 is carried out in more detail in FIG. 4 using an example.

The interaction of the individual measuring devices and actuators of a coating system, as shown in FIG. 1, and the coating model 30 described in FIG. 2 and the inverse coating model 31 are illustrated in FIG. 3 with reference to the top of the metal strip 5. The individual sizes are correspondingly indicated by the Index "o" marked. Further additional advantageous embodiments of the invention are explained.

In FIG. 3, reference numeral 40 denotes a monitor, 41 a switch, 44 a normalization, 45 and 46 multipliers, 47 and 49 adders, 48 a divider and 51 a pressure regulator, dbar.d denotes the thickness of the metal strip 5 and a _D o the distance between the nozzles 6 and 10. This distance is advantageously set and output by a nozzle precontrol 50. The distance a _c between the nozzle 6 and the metal strip 5, which is from the inverse Coating model 31 is determined, to the distance a _D D between the nozzle 6 of the nozzle 10 reduced by the band thickness d _B nd. By means of this standardization, it is possible by means of the method according to the invention to set an even more precise layer thickness of coating metal on the metal strip 5, so that the invention is developed in a particularly suitable manner.

By means of the monitor 40 and the switch 41, the set layer thickness value c * is corrected in relation to the layer thickness c, o / as a function of the measured values supplied by the cold measuring device 4. Such a corrected layer thickness setpoint for the exemplary embodiment 1 according to FIG. 3 is the input variable in the coating model 30.

4 shows an example for training a coating model. The starting point is a basic model 52, which has a layer thickness c _θ deiι as a function of the speed v of the metal strip, as a function of the pressure p at which the air emerges from the nozzles 6 and 10 in FIGS. 1 and 3, or an equivalent size and as a function of it of the distance between nozzle 6 or 10 and metal strip 5. The distance a between nozzle 6 or 10 and metal strip 5 is advantageously an average value of the distance or half the distance between the two nozzles 10 and 6. The parameters kl, k2, k3, k4, k5, k6 and k7 of the basic model 52 designed as a structured neural network are determined by means of a learning algorithm 53 as a function of the difference between a measured value of the layer thickness c _κ and the value for determined by the basic model 52 the layer thickness c _Mθ deiι of the coating metal on the metal strip 5 is determined. The measured value of the layer thickness c _κ of coating metal 5 is the output variable of one of the two cold measuring devices 3 and 4 in FIG. 1. The learning algorithm 53 changes or determines the parameters k4 and k5 as a function of the distance a between nozzle 6 and 10 and metal strip 5. The learning algorithm determines or changes the parameters kl and k3 as a function of the pressure p in the nozzle 6 or 10. The learning algorithm determines or changes the parameters kl and k7 depending on the speed v of the metal strip and the measured layer thickness c _{κ of} the coating metal on the metal strip 5. The base model 52 is partially inverted for use as the coating model 30 or inverse coating model 31. The use of a structured neural network is particularly advantageous.

Claims

claims 1. A method for coating a metal strip (5) which runs through a bath (11) with coating metal, in particular zinc, wherein part of the coating metal after leaving the bath (11) with air, which comes from at least one nozzle (6, 10 ) emerges, is blown away, and the layer thickness of the coating metal on the metal strip (5) is regulated by means of a coating model (30), characterized in that the layer thickness of the coating metal on the metal strip (5) is dependent on the distance (a, a ₀ , a _u ) between the metal strip (5) and the nozzle (6, 10) is regulated, the distance (a) between the metal strip (5) and the nozzle (6, 10) being determined by means of an inverse coating model (31). 2. The method according to claim 1, so that the layer thickness of the coating metal on the metal strip (5) is regulated as a function of target values (c *) of the layer thickness of the coating metal on the metal strip (5). 3. The method according to claim 1, characterized in that the layer thickness of the coating metal on the metal strip (5) is controlled as a function of setpoints (c *) of the layer thickness of the coating metal on the metal strip (5), the setpoints (c *) of the layer thickness of the coating metal on the metal strip (5) can be corrected with actual values (c _κ , c, _u , c _κ .o) of the layer thickness of the coating metal on the metal strip (5) measured by a cold measurement. 4. The method according to claim 1, 2 or 3, characterized in that the distance (a, a _Q , a _u ) between the metal strip (5) and the nozzle (6, 10) by means of the inverse coating model (11) as a function of a measured value the pressure at which the air exits the nozzle (6, 10), or an equivalent pressure measurement (p, p _u , p ₀ ) is determined. 5. The method according to claim 1, 2, 3 or 4, characterized in that the distance (a, a ₀ , a _u ) between the metal strip (5) and the nozzle (6, 10) by means of the inverse coating model (31) in dependence a measured value (c _H , c _l0 > c _H , _u ) of the layer thickness of the coating metal on the metal _strip (5) is determined. 6. The method according to claim 5, characterized in that the measurement of the layer thickness of the coating metal on the metal strip (5) just behind the nozzle (6, 10) in the direction of movement (20) of the metal strip (5) or in the region of the nozzle (6, 10th ) he follows. 7. The method of claim 6, d a d u r c h g e k e n n z e i c h n e t that the measurement of the layer thickness of the coating metal on the metal strip (5) is carried out as a hot measurement. 8. The method according to any one of the preceding claims, characterized in that when measuring the layer thickness of the coating metal on the metal strip (5), the layer thickness of the coating metal on the metal strip (5) is measured on both sides of the metal strip (5). 9. The method according to any one of the preceding claims, characterized in that by means of the coating model (30) a setpoint (p *, p * _u , P * _o ) of the pressure at which the air exits the nozzle (6, 10), or an equivalent pressure value is determined. 10. The method as claimed in one of the preceding claims, that the coating model (30) and the inverse coating model (31) are neural networks, in particular structured neural networks. 11. The method according to any one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that the coating model (30) and the inverse coating model (31) are adapted on-line. 12. The method according to claim 11, characterized in that the coating model (30) and the inverse coating model (31) on-line with actual values measured by a cold measurement (ck, C _k , _u , C, o) of the layer thickness of the coating metal on the metal strip (5) be adapted. 13. The method according to any one of claims 1 to 12, characterized in that a part of the coating metal after leaving the bath (11) from both sides of the metal strip (5) with air that exits from at least two opposite nozzles () is blown away and that the distance (a, a _c , a _u ) between the metal strip (5) and the nozzle (6, 10) determined by means of the inverse coating model (31) by means of the distance (a _DD ) between the opposing nozzles (6, 10 ) is corrected. 14. Coating system for coating a metal strip (5) which runs through a bath (11) with coating metal, in particular zinc, for carrying out the method according to one of the preceding claims, wherein the coating system has at least one nozzle (6, 10) , by means of which a part of the coating metal is blown away after leaving the bath (11) with air which emerges from the nozzle (6, 10), and wherein the coating system has at least one coating model for regulating the layer thickness of the coating metal on the metal strip ( 5), characterized in that the coating system for coating a metal strip (5) has an inverse coating model (31) for determining the distance (a, a ₀ , a _u ) between the metal strip (5) and the nozzle (6, 10) and that the coating model (30) the layer thickness of the coating metal on the metal strip (5) depending on the distance (a, a _σ , a _u ) between the metal strip (5) and the Nozzle (6, 10) is designed to regulate.