EP1646734A1

EP1646734A1 - Device for hot dip coating a metal strip

Info

Publication number: EP1646734A1
Application number: EP04739945A
Authority: EP
Inventors: Holger Behrens; Rolf Brisbeger; Hans Georg Hartung; Bernhard Tenckhoff; Walter Trakowski; Michael Zielenbach
Original assignee: SMS Demag AG
Current assignee: SMS Siemag AG
Priority date: 2003-07-08
Filing date: 2004-06-16
Publication date: 2006-04-19
Anticipated expiration: 2024-06-16
Also published as: US20060243203A1; AU2004256166A1; CA2531638A1; JP2007533840A; CN100529152C; US7476276B2; RU2335573C2; AU2004256166B2; EP1646734B1; JP4486085B2; ATE372398T1; MXPA06000151A; CN1849405A; DE502004004891D1; RU2006103627A; KR20060033783A; BRPI0412393A; KR101182152B1; DE10330656A1; WO2005005681A1

Abstract

The invention relates to a device for hot dip coating a metal bar (1), especially a steel strip, in which the metal bar (1) is directed vertically through a container (3) accommodating the molten coating metal (2) and through a guide channel (4) mounted upstream thereof. The inventive device comprises at least two inductors (5) which are arranged on both sides of the metal bar (1) in the area of the guide channel (4) and generate an electromagnetic field for retaining the coating metal (2) inside the container (3). In order to relax the coating bath, the distance (d) between the walls (6) that delimit the guide channel (4) is not kept constant in a direction (N) extending perpendicular to the surface of the metal strip (1) in the zone (H) of the vertical extension of the guide channel (4), which is located between the bottom side (7) thereof and the bottom area (8) of the container (3).

Description

Device for hot dip coating a metal strand

The invention relates to a device for hot-dip coating a metal strand, in particular a steel strip, in which the metal strand is passed vertically through a container holding the molten coating metal and through an upstream guide channel, with at least two inductors arranged on both sides of the metal strand in the region of the guide channel to generate an electromagnetic Field to retain the coating metal in the container.

Classic metal dip coating systems for metal strips have a maintenance-intensive part, namely the coating vessel with the equipment contained therein. The surfaces of the metal strips to be coated must be cleaned of oxide residues before coating and activated for connection to the coating metal. For this reason, the strip surfaces are treated in a reducing atmosphere in heat processes before coating. Since the oxide layers are removed chemically or abrasively beforehand, the reducing heat process activates the surfaces so that they are metallically pure after the heat process.

With the activation of the band surface, however, the affinity of these band surfaces for the surrounding atmospheric oxygen increases. In order to prevent atmospheric oxygen from reaching the strip surfaces again before the coating process, the strips are introduced into the dip coating bath from above in a dip nozzle. Since the coating metal is in liquid form and you want to use gravitation together with blow-off devices ("air knife") to adjust the coating thickness, the subsequent processes, however, touch the strip until it is completely Forbidding the coating metal from being rigid, the strip must be deflected in the vertical direction in the coating vessel. This happens with a roller that runs in the liquid metal. Due to the liquid coating metal, this role is subject to heavy wear and is the cause of downtimes and thus failures in production.

Due to the desired low contact thickness of the coating metal, which can be in the micrometer range, high demands are placed on the quality of the strip surface. This means that the surfaces of the tape-guiding rolls must also be of high quality. Faults on these surfaces generally lead to damage to the belt surface. This is another reason for frequent plant downtimes.

In order to avoid the problems associated with the rollers running in the liquid coating metal, solutions are known which use a coating vessel which is open at the bottom and has a guide channel of a defined height in its lower region for vertical tape passage upwards and an electromagnetic one for sealing Insert closure. These are electromagnetic inductors that work with pushing back, pumping or constricting electromagnetic alternating or traveling fields that seal the coating vessel downwards.

Such a solution is known for example from EP 0 673 444 B1. The solution according to WO 96/03533 or that according to JP 5086446 also uses an electromagnetic closure to seal the coating vessel downward.

DE 195 35 854 A1 and DE 100 14 867 A1 provide special solutions for precise regulation of the position of the metal strand in the guide channel. According to the concepts disclosed there, it is provided that in addition to the coils for generating the electromagnetic traveling field, additional correction door coils are provided, which are connected to a control system and ensure that the metal strip is returned to the middle position when it deviates from it.

To this extent, the electromagnetic closure used to seal the guide channel, which is used in the solutions discussed above, represents a magnetic pump which retains the coating metal in the coating container.

The industrial testing of such systems has shown that the flow pattern on the surface of the metal bath, ie. H. the bath surface, is relatively restless, which can be attributed to the electromagnetic forces caused by the magnetic lock. The restlessness in the bathroom means that the quality of the hot-dip coating is negatively affected. By the “air knife” located above the coating container, excess liquid metal is, as already mentioned, blown off the coated strand. A smooth metal bath surface is essential for precise adjustment of the coating thickness.

However, to calm the bathroom, there is no possibility of significantly reducing the intensity of the magnetic field without endangering the tightness of the magnetic lock. It is known from DE 102 54 307 A1 that a certain minimum strength of the magnetic field is required to ensure the tightness of the closure depending on the level in the coating bath. It is provided there that the level of the magnetic field strength generated by the inductors is determined as a function of the level of the molten coating metal in the container.

The invention is therefore based on the object of providing a device for hot-dip coating a metal strand of the type mentioned at the outset, with which it is possible to overcome the disadvantage mentioned. It should This ensures that the immersion bath remains calm when using an electromagnetic lock, which is intended to increase the quality of the coating.

The solution to this problem by the invention is characterized in that the distance between the walls delimiting the guide channel in the direction normal to the surface of the metal strand is not constant in the area of the vertical extent of the guide channel between its underside and the bottom area of the container.

According to this, it is provided that the effective width of the guide channel changes over its height extension, the height of the channel to be considered between the channel underside and the container bottom being relevant. The proposed change in cross-section of the guide channel is intended to create a zone within the vertical extent of the channel in which the flow in the coating metal can be calmed down, with the aim that the bath surface is also calmed thereby.

According to a first embodiment it is provided that the course of the walls delimiting the guide channel is funnel-shaped at least in sections. The funnel-shaped section can directly adjoin the bottom region of the container and can be arranged with its wider side upwards. In particular, it can be provided that the height of the funnel-shaped section is at most 30% of the height of the guide channel.

An alternative or additive embodiment provides that the walls delimiting the guide channel have a constriction. Again, alternatively or in addition to this, it can be provided that the walls delimiting the guide channel have an extension. The constriction or the enlargement can essentially have the shape of a circular section in cross section. A further flow stabilization can be achieved if, according to a further development, it is provided that at least one flow guiding element is arranged in the container and / or in the guide channel. The flow guiding element is advantageously designed as a flat, narrow sheet metal, the longitudinal axis of which extends in the direction perpendicular to the conveying direction of the metal strand and perpendicularly in the direction normal to the surface of the metal strand. Furthermore, the at least one flow guide element can be arranged in the guide channel in the region of the extension.

A further calming of the bath surface can be achieved if, according to a further development, it is provided that at least one bath calming plate is arranged in the area of the surface of the coating metal in the container. This lies on the bathroom surface or is located at a low height above the bathroom. The position of the bath calming plate can be adjusted in height by means of an actuator. The bath calming plate is preferably made of ceramic material.

The proposed measures ensure that the surface of the metal bath remains relatively calm despite the use of the electromagnetic closure, so that it is ensured that a high quality of the dip coating can be achieved.

Exemplary embodiments of the invention are shown in the drawing. Show it:

1 schematically shows a hot-dip coating device with a metal strand passed through it in a side view in section, FIG. 2 shows an alternative embodiment to FIG. 1, only the area of the bottom of the container for the coating metal and the guide channel adjoining at the bottom being shown, and

3 shows a further alternative embodiment analogous to FIG. 2.

The device shown in the figures has a container 3 which is filled with molten coating metal 2. This can be zinc or aluminum, for example. The metal strand 1 to be coated in the form of a steel strip passes the container 3 vertically upwards in the conveying direction R. It should be noted at this point that it is fundamentally also possible for the metal strand 1 to pass the container 3 from top to bottom.

To allow the metal strand 1 to pass through the container 3, it is open in the bottom area; here is an exaggeratedly large or wide guide channel 4. This has an area H of the vertical extent. It should be noted that this area H is calculated from the bottom area 8 of the container 3 to the underside 7 of the guide channel 4 and represents the area that provides an opening gap for the passage of the metal strand 1.

So that the molten coating metal 2 cannot flow down through the guide channel 4, there are two electromagnetic inductors 5 on both sides of the metal strand 1, which generate a magnetic field which counteracts the gravity of the coating metal 2 and thus seals the guide channel 4 downward.

The inductors 5 are two alternating field or traveling field inductors arranged opposite one another, which are operated in the frequency range from 2 Hz to 10 kHz and build up an electromagnetic transverse field perpendicular to the conveying direction R. The preferred frequency range for single phase Systems (alternating field inductors) lies between 2 kHz and 10 kHz, those for multiphase systems (e.g. traveling field inductors) between 2 Hz and 2 kHz.

To stabilize the metal strand 1 in the center plane of the guide channel 4, correction coils (not shown) can be arranged on both sides of the guide channel 4 or the metal strand 1. These are controlled by control means such that the superimposition of the magnetic fields of the inductors 5 and the correction coils always keeps the metal strand 1 in the center of the guide channel 4.

By means of the correction coils, the magnetic field of the inductors 5 can be strengthened or weakened depending on the control (superposition principle of the magnetic fields). In this way, the position of the metal strand 1 in the guide channel 4 can be influenced.

In order to calm the bath surface in the container 3, it is provided that the distance d between the walls 6 delimiting the guide channel 4 in the direction N is normal to the surface of the metal strand 1 in the area H of the vertical extent of the guide channel 4 between its underside 7 and the bottom area 8 of the container 3 is not constant.

As can be seen from FIG. 1, this is accomplished in this exemplary embodiment by connecting a funnel-shaped section 9 directly below the bottom region 8 of the container 3, the broad side of the funnel 9 adjoining the bottom region 8 of the container 3. The height d of the funnel-shaped section 9 reduces the distance d between the walls 6 delimiting the guide channel 4 to the value which is reached below the funnel-shaped section 9 and is then kept constant downwards.

The choice of this design has resulted from the following knowledge: During industrial testing of the hot-dip coating in question Conditioners occurred that created a calm bath surface. However, the evaluation of the data showed that an interplay between the level in the coating bath and the set sealing performance of the inductors 5 was the cause. A control operation for the position of the metal strand 1 in the guide channel 4 by means of the correction coils mentioned further showed that the control interventions locally increase the unrest on the bath surface. So this is a combination of several competing effects. It is not possible to only reduce the power of the inductors 5, since this would result in leakages. However, as explained above, the inductor output depends on the level in the coating bath, which should be as large as possible. However, it is also necessary to regulate the position of the metal strand 1 in the guide channel 4, which creates local unrest. The proposed change in the geometry of the guide channel 4 or the additional measures for calming the bath surface, which are explained in more detail below, are therefore proposed.

The embodiment of the guide channel 4 with funnel-shaped section 9 illustrated in FIG. 1 represents a measure which is based on the fact that the flow coming from the guide channel 4 is directed in the coating metal 2 in such a way that there are no swellings on the bath surface. It is also possible, by means of a suitable measure, to limit the turbulence in the flow, which is caused by the inductors 5 in the coating metal, locally to the region of the guide channel 4.

The provision of the funnel-shaped section 9 represents a first essential effect with which the flow in the coating metal 2 can be directed in the region of the guide channel 4. The funnel-shaped section 9 reduces the swelling of the bath on the surface of the metal bath, because the proposed geometry of the upward flow in the guide channel 4 gives space for evasion into the volume of the container 3. As a result, the local turbulence is reduced or absorbed. Swelling of the bath on the surface of the coating metal 2 is prevented or reduced as a result, which would otherwise result in the “air knife” not being able to be set to a distance from the bath surface that is suitable for the quality of the coating.

Another measure for flow control is the placement of bath calming plates 16, for example made of ceramic material, on the surface 15 of the coating bath. The bath calming plates 16 are held on the surface 15 of the coating metal 2 or positioned near the surface. Actuators 17 are used for this purpose, with which the suitable height of the horizontally arranged bath calming plates 16 can be set. As a result, the turbulence, which may have penetrated to the surface of the bath, is deflected in the horizontal direction, so that swelling of the bath can be prevented.

A further possibility of flow control is by inserting flow guide elements 12, 12 ', 12 ", 13, 13' - designed as guide plates or guide vanes - into the liquid coating metal 2. As can be seen in FIG. 1, these flow guide elements 12 are 12 ', 12 "are designed as narrow plates, the longitudinal axis 14 of which is perpendicular to the plane of the drawing. They are arranged at a desired angle and ensure that the flow in the coating metal is deflected in the horizontal direction, so that bath build-up is minimized. The flow guide elements 12, 12 ', 12 "are arranged relatively close to the metal strand 1.

Further configurations, which are illustrated in FIGS. 2 and 3, are possible as measures for local limitation of the flow to the region of the guide channel 4.

In general, it can be said that the inductors 5 generate a turbulent flow especially in the guide channel 4 due to their pumping action. As a measure If swelling was suppressed on the surface of the bath, there is the possibility, by changing the geometry of the guide channel 4, to create space for evading the turbulence in the area of the guide channel 4, or to prevent the spreading of this turbulence into the container 3 by weirs, thus reducing the turbulence to limit the area of the guide channel 4.

This is already done to a considerable extent by the funnel-shaped section 9, which is illustrated in FIG. 1. As an alternative or in addition to this, FIG. 2 provides that a constriction 10 is provided in the region of the vertical extent H of the guide channel 4, which represents a type of web or weir and is preferably arranged directly below the base region 8 of the container 3 (particularly proven) the area between the - not shown - channel flange and the tank bottom).

As can be seen in FIG. 2, the limiting walls 6 in the region of the constriction 10 have the shape of the section of a circle in cross section. This achieves a certain flow calming.

The constriction 10 initially prevents or prevents the turbulence from spreading into the container 3. The aluminum depletion to be feared in such a measure in the guide channel 4 does not occur since the volume of coating metal 2 in the guide channel 4 is only small and the tracking of fresh coating metal from the coating container above the channel is ensured by the normal discharge of coating metal. Furthermore, the higher likelihood of tape contact (between metal strand 1 and constriction 10) to be feared with such a measure is only slight, since there are no more ferromagnetic attraction forces as in the channel area and the self-centering of the metal strand 1 between the two sides of the constriction 10 occurs the effect of two flow baffles is known. The design and shape of such a weir in the form of the constriction 10 and its clear width for the metal strand 1 corresponds to the fluidic requirements in the intermediate area between the guide channel 4 and the container 3.

A further alternative embodiment is illustrated in FIG. 3. It is provided here that an extension 11 is arranged in the area of the height H of the guide channel 4, in this case above the height area over which the inductors 5 extend (which is also advantageous in the case of the embodiment according to FIG. 2).

The extension 11 represents in a certain way a compensation volume between the guide channel 4 and the bottom region 8 of the container 3. This ensures that the turbulence in the guide channel can expand and calm before the container 3 is reached, and thus no longer the flow conditions in the container 3 affects. It is thus achieved that the flow in the guide channel 4 no longer continues into the container 3 lying above, but the coating metal 2 again reaches the lower region of the guide channel 4, in which the turbulence prevails.

The same applies to this embodiment with regard to possible aluminum depletion or self-centering of the strand 1, which was already explained above in connection with FIG. 2.

It is not shown that a constriction 10 according to FIG. 2 can follow the extension 11 in the upward continuation.

As explained above in connection with FIG. 2, the geometric configuration of the extension 11 corresponds to the fluidic requirements in the area between the guide channel 4 and the container 3.

Another measure for locally limiting the flows to the area of the guide channel 4 is likewise illustrated in FIG. 3. Here are in Area of the extension 11 arranged flow guide elements 13 and 13 ', which functionally correspond to the flow guide elements 12, 12', 12 ", which were described above. By using the flow guide elements 13, 13 '(in the form of guide webs or guide vanes) Turbulence can be deflected downwards again between the underside 7 of the guide channel 4 and the bottom region 8 of the container 3. The flow guide elements 13, 13 'support the desired formation of the flow conditions in the region of the enlargement 11 and result in the reduction of turbulence.

The implementation of the measures mentioned is very easy to implement, since in addition to metal, ceramic materials can also be machined and assembled very well. They are also sufficiently resistant to use in the aggressive environment of the coating metal 2.

The combination of the measures described in FIGS. 1, 2 and 3 is particularly preferably used, which, in the superposition, produce an overall low-turbulence flow in the guide channel 4 and in the container 3 and thus provide a good calming of the surface of the coating metal 2 in the container 3 lead.

LIST OF REFERENCE NUMBERS

1 metal strand (steel band)

2 coating metal

3 containers

4 guide channel

5 inductor

6 delimiting wall

7 Bottom of the guide channel

8 bottom area of the container

9 funnel-shaped section

10 constriction

11 extension

12, 12 ', 12 flow guiding element

13, 13 'flow guiding element

14 longitudinal axis of the flow guiding element

15 Surface of the coating metal

16 bath calming plate

17 actuator

d Distance between the walls delimiting the guide channel

N normal direction to the surface of the metal strand *

H area of the vertical extent of the guide channel h vertical extent of the funnel-shaped section

R direction of conveyance

Claims

claims:

1. Device for hot-dip coating a metal strand (1), in particular a steel strip, in which the metal strand (1) is passed vertically through a container (3) holding the molten coating metal (2) and through an upstream guide channel (4), with at least two Inductors (5) arranged on both sides of the metal strand (1) in the region of the guide channel (4) for generating an electromagnetic field for retaining the coating metal (2) in the container (3), characterized in that the distance (d) between the guide channel ( 4) bounding walls (6) in direction (N) normal to the surface of the metal strand (1) in the area (H) of the vertical extent of the guide channel (4) between its underside (7) and the bottom area (8) of the container (3) is not constant.

Device according to claim 1, cüadyrch characterized in that the course of the walls (6) delimiting the guide channel (4) is funnel-shaped (9) at least in sections.

3. Device according to claim 2, characterized in that the funnel-shaped section (9) directly adjoins the bottom region (8) of the container (3) and is arranged with its wider side upwards.

4. The device according to claim 2 or 3, characterized in that the height extension (h) of the funnel-shaped section (9) is at most 30% of the height extension (H) of the guide channel (4).

5. The device according to claim 1, characterized in that the guide channel (4) delimiting walls (6) have a constriction (10).

6. The device according to claim 1, characterized in that the guide channel (4) delimiting walls (6) have an extension (11).

7. The device according to claim 5 or 6, characterized gekennzeichn t that the constriction (10) or the extension (11) has in cross section essentially the shape of a circular section.

8. Device according to one of claims 1 to 7, characterized in that in the container (3) and / or in the guide channel (4) at least one flow guide element (12, 12 ', 12 ", 13, 13') is arranged.

9. The device according to claim 8, characterized in that the flow guide element (12, 12 ', 12 ", 13, 13') is designed as a flat, narrow plate, the longitudinal axis (14) of which is in the direction perpendicular to the conveying direction (R) of the metal strand (1) and perpendicular to the direction (N) normal to the surface of the metal strand (1).

10. The device according to claim 8 or 9, characterized in that the at least one flow guide element (13, 13 ') in the guide channel (4) is arranged in the region of the extension (11).

11. The device according to one of claims 1 to 10, characterized in that in the region (15) of the coating metal (2) in the container (3) at least one bath calming plate (16) is arranged.

12. The apparatus according to claim 11, characterized in that the position of the bath calming plate (16) is adjustable in height by means of an actuator (17).

13. The apparatus of claim 11 or 12, characterized in that the bath calming plate (16) consists of ceramic material.