WO2011054902A1

WO2011054902A1 - Device for coating a metal strip and method therefor

Info

Publication number: WO2011054902A1
Application number: PCT/EP2010/066810
Authority: WO
Inventors: Christos Karinos; Joachim Kuhlmann; Holger Behrens; Pascal Fontaine
Original assignee: Sms Siemag Ag
Priority date: 2009-11-04
Filing date: 2010-11-04
Publication date: 2011-05-12
Also published as: EP2496728A1; JP2013510236A; KR20120063550A; DE102009051932A1; HUE038462T2; CA2794925C; CN102597295B; JP5663763B2; PL2496728T3; KR101421981B1; CN102597295A; TR201802499T4; ES2660746T3; CA2794925A1; EP2496728B1

Abstract

The invention relates to a device for coating a metal strip (1) with a coating material, comprising a coating container (2) filled with a liquid coating material, through which or out of which the coated strip (1) is guided vertically (V) upward, wherein a stripping nozzle (3) for stripping still liquid coating material from the strip surface is arranged above the coating container (2), wherein an electromagnetic apparatus (4) for stabilizing the position of the strip (1) in a central position (5) is arranged above the stripping nozzle (3), wherein the apparatus (4) comprises two magnets (6) arranged on both sides of the metal strip (1) at the same height. In order to be able to respond in an improved and simplified manner to different requirements with respect to the strip guidance, the invention is characterized by means (7) for adjusting the vertical distance (H) of the magnets (6) from the stripping nozzle (3). The invention further relates to a method for coating a metal strip.

Description

Apparatus for coating a metallic strip

and method for this

The invention relates to a device for coating a metallic strip with a Beschichtungsmatenal having a filled with a liquid Beschichtungsmatenal coating container through which or from which the coated strip is discharged vertically upwards, wherein o- beyond the coating container, a stripping nozzle for stripping yet liquid Beschichtungsmatenal of the strip surface is arranged, wherein above the Abstreifdüse an electromagnetic means for stabilizing the position of the tape is arranged in a central position, wherein the device comprises at least two on both sides of the metal strip arranged at the same height magnets. Furthermore, the invention relates to a method for coating a metallic strip with a Beschichtungsmatenal.

A device of this type and a corresponding method are known. DE 10 2008 039 244 A1 shows a device for hot-dip coating in which the metal strip is passed through the coating bath and discharged from the latter vertically upwards. Above the coating container, a wiping nozzle is arranged, with the excess Beschichtungsmatenal is blown off the belt surface. Above the wiping nozzle, a band stabilization is arranged at a defined distance, with which the band is to be held centrally in the center plane of the plant.

A similar solution is known from WO 02/14574 A1. Details of hot-dip coating processes are also shown in WO 01/1 1 101 A1, EP 0 659 897 B1, EP 0 854 940 B1 and JP 1 100 6046. In hot-dip coating plants, in particular in hot-dip galvanizing plants, different requirements are imposed on the strip layer and the band run. Particularly in the area of wiping nozzles, non-contact systems, the so-called electromagnetic band stabilization systems, are intended to reduce band vibrations and influence the band shape.

In systems with an inductive heating system (galvannealer) connected downstream of the wiper nozzle, guide rollers are additionally inserted above the wiper nozzle in front of the heating device to ensure smooth belt running between the heating coils and defects on the system as well as on the belt through contact of the belt with these should avoid.

Likewise, a stable central belt run in systems with and without downstream heating inductors is of great importance for the strip cooling devices following the wiping nozzle, in order to achieve a uniform cooling effect. Again, it is important to avoid damage to the system and the belt surface.

Various systems have become known which exert additional forces on the steel strip without contact, namely electromagnetically, in order to minimize band movements in the form of vibrations. Furthermore, with these systems, the band shape can be influenced transversely to the transport direction.

The belt position normal to the belt surface is measured in the belt stabilization system by means of displacement sensors and regulated in a closed loop. In this case, further measuring devices within the downstream devices can be used as additional signals for the belt position control.

As a disadvantage, the following has been found: The position of the belt stabilization is defined by design and concentrated in the previously known solutions mostly on a spatial proximity to the scraper. Thus arises dependent from design a distance of the belt stabilization magnets from the nozzle lip of the wiper (air outlet from the nozzle).

As a result, the distance to the downstream facilities, such. B. to the heating inductors or to the downstream strip cooling, very large. This results in no or only a minimal effect of the belt stabilization magnets on the local belt movement and consequently no possibility of influencing the belt stability in the region spaced from the wiper. However, if the belt stabilization magnets are installed directly in front of the heating inductor or the belt cooling, a significantly reduced effect on the belt centering in the area of the scraping nozzle results accordingly.

In the case of the previously known systems, therefore, there is always only one selected position, which is usually matched to the effect in the area of the wiping nozzle, ie. H. The band-stabilizing magnets are usually arranged in the region of the wiping nozzle.

However, this means that the requirements for a modern strip-type coating plant can not be met, or can only be met to a limited extent.

In the light of these disadvantages, the invention is based on the object of further developing a device for coating a metallic strip with a coating material and a corresponding method such that the different requirements for strip guidance can be reacted in an improved and simpler manner. Accordingly, the quality of the hot dip coating, in particular the hot dip galvanizing, should be increased. The solution of this object by the invention is device-technically characterized by means for adjusting the vertical distance of the magnets of the wiper.

These means for adjusting the vertical distance may comprise at least one lifting element which is directly or indirectly connected to the wiper. The wiping nozzle can have a frame structure or be connected to such, on which the at least one lifting element is arranged. A heating element for heating the strip can be arranged above the wiping nozzle in order to be able to carry out a so-called galvannealing process. The heating element is preferably formed as an inductive element. The means for adjusting the vertical position are preferably formed for adjusting the vertical distance of the magnets in the entire region of the height extension between the wiper and the heating element.

Above the heating element may further be arranged a cooling section. Between heating element and cooling section, a holding furnace may be arranged. The means for adjusting the vertical distance may include at least one hydraulic or pneumatic actuator; they may also comprise at least one mechanical actuator, in particular a spindle-nut system. The method for coating a metallic strip with a coating material, in which the strip is passed through liquid coating material, which is located in a coating container, and then discharged vertically upwards from the coating container, wherein liquid coating material is still passing above the coating container a stripper nozzle is stripped from the strip surface and wherein, above the stripper nozzle, the strip is removed by means of an electromagnetic device. stabilized for stabilization of the position of the tape in a central position, wherein the device comprises two on both sides of the belt arranged at the same height magnets, according to the invention is characterized in that the vertical distance of the magnets is set by the wiper according to a predetermined value, wherein To set the distance, means for adjusting the vertical distance are operated by a controller.

The magnets are preferably kept centered in the center position when setting the vertical distance. The essence of the invention thus depends on the fact that the position of the belt stabilization magnets is not stationary, but can be adapted to the respective requirements by means of a suitable lifting device. In this case, the aligned (centered) and optimized position of the belt stabilizing magnets to the continuous steel belt - in the direction normal to the belt - by a mechanical coupling of the belt stabilization magnets with the wiper remains always exist.

From physical considerations it follows that the belt stabilization system must be positioned as close as possible to the respective device or effective point for optimal function and thus for the purpose of reducing the belt movements (principle of St. Vernant). This is, for example, for optimizing the coating with liquid metal a position as close as possible to the wiping, wherein for a central and quiet tape within the Nacherwärmungseinrichtung the position of the non-contact tape stabilization should be selected as close to this device. Thus, it makes sense to be able to approach by means of a suitable auxiliary device both positions (once close to the scraper and once near the heating device) without loss of stabilization function. Furthermore, other positions can be approached, which allow influencing both plant parts (wiper and heating device) with the belt stabilization. By means of a lifting device according to the invention, therefore, the vertical position of the belt stabilizing magnets, which are part of a belt stabilizing unit, can be flexibly adjusted to a desired value. This takes place depending on the operating state or the desired non-contact band position influencing. The positioning preferably takes place between the wiping nozzle and the downstream in the conveying direction of the belt heating inductors for galvannealing operation or a downstream strip cooling. The actuating means for the height adjustment of the magnets always remain centered to the scraper, since they are mechanically coupled thereto.

Thus, the invention enables a variable, selectively adjustable position of the belt stabilizing magnets above the scraper nozzle in a Feuerverzinkungsanlage.

Accordingly, the vertical adjustment capability of the belt stabilizing magnets relative to the scraper nozzle allows any position to achieve optimum operation between the extreme locations directly on the scraper nozzle and directly in front of the downstream heating elements or before the belt cooling.

In combined applications where both tape position control in the wiper nozzle and in the downstream equipment is important, the effects on the equipment are determined by a mathematical model taking into account the stress distribution in the tape; Accordingly, a vertical position of the belt stabilization magnets is set, which is optimized for the application.

In the drawings, embodiments of the invention are shown. Show it: 1 shows an alternative embodiment of the invention, in perspective view a holding frame for the wiping nozzle of the hot-dip coating installation, on which magnets for strip stabilization are arranged vertically variable, and in perspective the magnets for belt stabilization, arranged on a height adjustment device.

In Fig. 1 a hot dip coating plant is sketched, which serves to coat a strip 1 with a coating metal. In the exemplary embodiment, the strip 1 is introduced in a known manner into a coating container 2 in which liquid coating material is contained. In the present case, a deflection of the belt 1 in the vertical direction V by means of a deflection roller 14 is made. Of course, the CVGL method can likewise be used in the same way, in which the band 1 enters the coating container 2 vertically from below and the bottom opening is sealed by means of an electromagnetic shutter.

After the coated tape 1 has emerged vertically upward from the coating container 2, excess coating metal is blown off by a wiping nozzle 3. Above the wiping nozzle 3 there is a device 4 for stabilizing the band 1. This device 4 has as its core two electro-magnets 6 arranged on both sides of the belt 1. With these devices it is achieved that the belt is deliberately subjected to magnetic forces such that it is held in a symmetrical center position 5 of the device. It is essential that means 7 are provided with which the vertical distance H of the magnets 6 can be set by the wiper 3 targeted. This is indicated in Fig. 1 with the double arrows next to the magnets 6 and in that the magnets 6 are sketched once (in a middle position) with solid lines and in two further alternative positions with dashed lines, namely in a lower position near the Wiper 3 and in an upper position at the top of the movement, which can be accomplished with the means 7. The distance of the magnets 6 from the upper end of the wiper 3 is indicated by H and indicates how far the magnets 6 are lifted by the means 7.

Above the device 4 for stabilizing a cooling section 1 1 is provided for the band 1 in Fig. 1. Above the cooling section 1 1, the band 1 is deflected by a deflection roller 13 in the horizontal.

2, an alternative solution is outlined, in which case in comparison with FIG. 1 an inductive heating device 10 is provided above the strip stabilizer 4, with which a galvannealing process can be carried out in a manner known per se. Between the heating element 10 and the cooling section 1 1 is still a holding furnace 12th

An idea of the structural design of the proposed device is shown in FIG. 3. Here it can be seen that the wiping nozzle 3 is arranged on a frame structure 9, on which four lifting elements 8 are fastened, with which the magnets 6 can be raised or lowered relative to the wiping nozzle 3.

Further details of the constructive structure are shown in FIG. 4. Here it can be seen how four lifting elements 8 - in the present case designed as mechanical actuators in the form of spindle-nut systems - are used to provide the Move magnets 6 in the vertical direction V or adjust. The wiping nozzles 3 are not shown here; they are in the lower part of the illustration according to FIG. 4.

If strip layer changes occur which lead to a readjustment of the stripper nozzle, the position of the strip stabilization is also tracked by the mechanical coupling of the strip stabilization magnets.

The continuous height adjustment of the magnets 6 of the belt stabilization allows the following procedure:

For optimum galvannealing operation (GA operation), the belt stabilizer 4 and, in particular, the magnets 6 are positioned directly below the inductive heating elements 10 by means 7 (lifting device). Since the coating thickness for GA products is very thin (maximum 90 g / m ² ) and therefore only slight improvements in the layer structure can be achieved by the strip stabilization effect, the focus of the stabilization effect is on the strip run in the heating element 10 (GA inductor). and thus on the quality of the GA coating. Due to the mechanical coupling to the wiping nozzle 3, the wiping nozzle 3 and the magnets 6 of the belt stabilization are always centered to the belt 1.

The effect of band stabilization in the region of the wiper nozzle 3 is reduced in this case, but it does not go away because of the optimal position calculation by a mathematical model used here. The magnets 6 are positioned closer to the heating elements 10 (GA inductors) than to the wiping nozzle 3, but taking into account the physical action in both directions.

For other coating products, the focus of the stabilizing effect is on minimizing tape movement within the stripper nozzle. 3. For this purpose, the position of the magnets 6 of the belt stabilization in the region of the wiping nozzle 3 is selected.

The guide rollers in front of the heating element, which are used in previously known systems to stabilize the belt, are no longer necessary, since now the stabilizing effect can be influenced in a targeted manner in the entire height range between the wiper and the heating element.

The means 7 (lifting device) also advantageously allow a manual cleaning of the wiper 3 during operation. The belt stabilization or the magnets 6 are moved to an elevated position, but without losing the stabilizing effect. This is not possible with previously known systems. Thus, the maintenance personnel obtains free access to the scraper nozzle 3 and therefore can clean the nozzle lips manually. This requirement is met with every hot dip galvanizing line.

The positioning of the belt stabilizing magnets 6 is as explained with a device which may have two guides, holders and corresponding clamping devices which cause the tensioning of the system and thus the parallel alignment of the belt stabilization (the magnets 6) to the belt or wiper support system. This band-stabilizing position changing device is fixedly mounted on the scraping nozzle 3, which includes a frame structure with alignment members.

The principle is thus a frame construction, which in turn is firmly connected to the basic frame construction of the wiping nozzle 3. This is done with the alignment of the wiper 3 to the band 1 also always a synchronous alignment of the magnets 6 of the band stabilization to the band. 1 LIST OF REFERENCE NUMBERS

1 band

2 coating containers

3 wiper nozzle

4 stabilization device

5 middle position

6 magnet

7 means for adjusting the vertical position

8 lifting element

9 frame structure

10 heating element

1 1 cooling section

12 holding furnace

13 pulley

14 pulley

V vertical direction

H distance

Claims

Patent claims

Device for coating a metallic strip (1) with a coating material, which has a coating container (2) filled with a liquid coating material, through or from which the coated strip (1) is discharged vertically (V) upwards, above of the coating container

(2) a stripping nozzle (3) is arranged for stripping still liquid coating material from the strip surface, an electromagnetic device (4) for stabilizing the position of the strip (1) in a central position (5) being arranged above the stripping nozzle (3). and wherein the device (4) comprises at least two magnets (6) arranged at the same height on both sides of the metal strip (1), characterized by

Means (7) for adjusting the vertical distance (H) of the magnets (6) from the wiper nozzle (3).

Device according to claim 1,

characterized,

that the means (7) for adjusting the vertical distance (H) comprise at least one lifting element (8) which is connected directly or indirectly to the wiper nozzle (3).

Device according to claim 2, characterized,

that the wiper nozzle

(3) has a frame structure (9) on which the at least one lifting element (8) is arranged.

4. Device according to one of claims 1 to 3,

characterized,

that a heating element (10) for heating the strip (1) is arranged above the stripping nozzle (3).

5. Device according to claim 4,

characterized,

that the heating element (10) is designed as an inductive element.

6. Device according to claim 4 or 5,

characterized,

that the means (7) are designed to adjust the vertical distance (H) of the magnets (6) in the entire area of the height extension between the wiper nozzle (3) and the heating element (10).

7. Device according to one of claims 4 to 6,

characterized,

that a cooling section (1 1) is arranged above the heating element (10).

8. Device according to claim 7,

characterized, that between heating element

(10) and cooling section

(1 1) a holding furnace (12) is arranged.

Device according to one of claims 1 to 8,

characterized,

that the means (7) for adjusting the vertical distance (H) comprise at least one hydraulic or pneumatic actuator.

Device according to one of claims 1 to 8,

characterized,

that the means (7) for adjusting the vertical distance (H) comprise at least one mechanical actuator, in particular a spindle-nut system.

Method for coating a metallic strip (1) with a coating material, in which the strip (1) is passed through liquid coating material located in a coating container (2) and then vertically (V) upwards is discharged from the coating container (2), with liquid coating material above the coating container (2) being stripped from the strip surface by a stripping nozzle (3), and above the stripping nozzle (3) the strip (1) is removed by means of an electromagnetic device (4). Stabilization of the position of the band (1) is stabilized in a central position (5), the device comprising at least two magnets (6) arranged on both sides of the band (1) at the same height, characterized in that that the vertical distance (H) of the magnets (6) from the stripping nozzle (3) is adjusted according to a predetermined value, with means (7) for adjusting the vertical distance (H) being actuated by a controller to adjust the distance (H). .

12. The method according to claim 1 1,

characterized,

that the magnets (6) are always kept centered in the middle position (5) when adjusting the vertical distance (H).