WO2018019670A1 - Device and method for forming a transverse curvature on a metal strip leaving an annealing furnace - Google Patents

Abstract

The invention relates to a device (1) for forming a transverse curvature on a metal strip (3) leaving an annealing furnace (2). In order to permit the formation of a transverse curvature on a metal strip (3) leaving an annealing furnace (2), without impairing the surface quality of the metal strip (3), the invention proposes that the device (1) has at least one support nozzle arrangement (6) mounted under a length of metal strip (3), which arrangement is designed to generate, between the metal strip (3) and the support nozzle arrangement (6), a gas cushion (7) that supports the metal strip (3) from below such that the transverse curvature on the metal strip (3) can be formed in a contact-free manner by means of the gas cushion (7).

Description

 Device and method for forming a transverse curvature on a metal strip emerging from an annealing furnace

The invention relates to a device for forming a transverse curvature on a metal strip emerging from an annealing furnace.

The invention further relates to a method for forming a transverse curvature on a metal strip emerging from an annealing furnace. A metal strip is usually made using a continuous casting process. The metal strip can be heated to create a desired microstructure in an annealing furnace. Subsequently, the created microstructure can be "frozen" by rapid or gentle cooling (hard or soft quenching), also known as rough cooling, whereby the metal strip is first passed through the annealing furnace and then through a cooling line.

In order to increase dimensional stability and flatness of a metal strip and thus facilitate its promotion, for example, by a cooling section, the metal strip can be provided with a transverse arc, for example, circular arc-shaped. For example, it is known from DE 100 46 273 A1 to impose such a transverse curvature with mechanical guide means, in particular rollers or shafts, on a flat metal strip. The mechanical guide means may be arranged in a heating area and in a cold area. Through the use of mechanical guide means for forming the transverse curvature on the metal strip, physical contact between the mechanical guide means and the metal strip may cause damage, in particular scratches and the like, on the surface of the metal strip. In addition, a fixation or guidance of the metal strip with mechanical guide means within a

page 1 Cooling road adversely affect a stripline control and a strip tension control.

An object of the invention is to allow formation of a transverse curvature on a metal strip emerging from an annealing furnace without adversely affecting the surface finish of the metal strip.

This object is solved by the independent claims. Advantageous embodiments are specified in particular in the dependent claims, each of which, taken alone or in various combinations with each other, can represent an aspect of the invention.

A device according to the invention for forming a transverse curvature on a metal strip emerging from an annealing furnace comprises at least one support nozzle arrangement arranged below a strip run of the metal strip, which is arranged to generate a gas cushion supporting the metal strip from below between the metal strip and the support nozzle arrangement such that the gas cushion on the metal band, the transverse curvature can be formed without contact. In accordance with the invention, the transverse curvature is imposed contactlessly by means of the gas cushion on, for example, the metal strip, which is initially planar. There are no mechanical means used to form the transverse curvature of the metal strip, which are in physical contact with the metal strip. As a result of the non-contact embodiment of the transverse curvature on the metal strip according to the invention, it is therefore not possible for any mechanical damage to the surface of the metal strip to occur. Thus, with the device according to the invention, the formation of the transverse curvature on the exiting from the annealing metal strip is possible without affecting the surface finish of the metal strip.

Page 2 The device may also comprise two or more support jet arrangements arranged in the strip running direction offset from one another and below the strip run of the metal strip, each being adapted to produce a gas cushion supporting the metal strip from below between the metal strip and the support nozzle arrangement such that through the gas cushion on the metal strip the transverse curvature can be formed without contact. Here, the mutually offset in the strip running direction gas cushion can be designed differently in order to force the transverse curvature step by step to the metal strip. The support nozzle assembly may be disposed outside of the annealing furnace or formed as an output side unit of the annealing furnace.

The device may additionally comprise at least one nozzle arrangement arranged above the strip run of the metal strip, which is arranged to generate a gas cushion between the metal strip and the nozzle arrangement which acts on the metal strip from above such that the transverse curvature can be formed by the gas cushion on the metal strip. As a result, the formation of the transverse curvature can be supported on the metal strip. The nozzle assembly may be vertically disposed above a support nozzle assembly.

The gas cushion may be, for example, an air cushion. Alternatively, the gas cushion may be formed by a gas having a composition other than air. A metal strip, in particular aluminum strip, can first be subjected to solution annealing in a floating strip annealing furnace, wherein the metal strip in the floating strip annealing furnace is guided without contact by means of floating nozzles. The metal strip can be guided in the floating strip furnace with a characteristic of the strip guide in the SINUS. Subsequently, the metal strip, in particular at the exit from the Schwebiegeglühen and in the transition to a water cooler, with the Schwebiegeglühofen in

Page 3 Tape running direction downstream device according to the invention the transverse curvature are imposed contactless. The metal strip can then be fed with the transverse curvature of a rough cooling and a downstream high-performance air cooling, whereby the transverse curvature of the metal strip is "frozen." Preferably, the metal strip is guided by means of floating nozzles also during the rough cooling and during the high-performance air cooling Thus, the metal strip can be guided completely contact-free, so that the surface quality of the metal strip is not impaired by physical contact with mechanical guiding means and a higher quality metal strip can be produced The transverse curvature of the metal strip is preferably given in the form of an upwardly curved, positive or concave transverse curvature s metal bands, which in particular allows a contactless guidance of the metal strip without mechanical guide means in a cooling area or a cooling line. The transverse curvature also has the advantage that a cooling water sprayed from above onto the metal strip flows off uniformly and under the action of gravity automatically over the strip edges from the surface of the metal strip.

As a result of the contactless design of the transverse curvature on the metal strip according to the invention, the metal strip has a higher flatness and a lower internal mechanical stress in a downstream cooling region, so that a stretch-bending straightener must be used less intensively in the further production process in order to achieve a desired flatness To reach metal bands. This leads to better mechanical material properties of the metal strip, since a greater use of the stretch-bending straightener would degrade the material properties of the metal strip.

page 4 According to an advantageous embodiment, the support nozzle arrangement comprises at least one gas nozzle extending essentially across the width of the metal strip, transversely to a strip running direction of the metal strip. The gas for forming the gas cushion emerges from the gas nozzle. Preferably, the gas nozzle extends exactly over the width of the metal strip. The apparatus may include a blower or the like for generating a pressurized gas, with which the gas nozzle is supplied via at least one fluid line. The support nozzle arrangement may alternatively have at least two gas nozzles arranged offset to one another in the width direction of the metal strip or in the strip running direction.

Advantageously, the gas nozzle comprises at least one outlet opening with a continuous or graduated transverse curvature corresponding to the transverse curvature to be formed on the metal strip. The outlet opening preferably extends substantially over the entire width of the metal strip. The transverse curvature of the outlet opening can be achieved in that the center of the gas nozzle is arranged higher than the sides of the gas nozzle. The gas cushion has by the transverse curvature of the outlet opening a corresponding transverse curvature, which serves to form the transverse curvature of the metal strip. Preferably, the gas exits the length of the, for example, slot-shaped, outlet opening to produce a uniform air cushion. According to a further advantageous embodiment, a width of the support nozzle arrangement which is transverse to the strip running direction of the metal strip can be varied. As a result, the width of the support nozzle arrangement or the gas nozzle can be varied to adapt to the respective width of the metal strip. The variation of the width of the support nozzle arrangement or the gas nozzle can be automated by means of a controllable actuator or manually. In the first case, the device can be a signal with the actuator

page 5 connected control and / or regulating electronics, the data supplied to the respective width of the metal strip and with which these data are processed to generate actuating signals for the actuator. A further advantageous embodiment provides that the support nozzle arrangement is arranged vertically adjustable. As a result, the positioning of the support nozzle arrangement or the gas nozzle can be adapted to the respective strip run of the metal strip. In addition, this can be adapted to the respective weight of the metal strip, the admission of the metal strip with the gas cushion or the supporting effect of the gas cushion. For example, the support nozzle assembly or the gas nozzle in a lighter weight metal band deeper, ie at a greater distance to the metal strip, and higher weight metal band, that are arranged at a smaller distance to the metal strip. The height adjustment of the support nozzle arrangement or the gas nozzle can be automated by means of a controllable actuator or manually. In the first case, the device may have a signaling technology connected to the actuator control and / or control electronics, the data supplied to the respective weight, the material thickness and / or width of the metal strip and with which these data are processed to generate actuating signals for the actuator ,

According to a further advantageous embodiment, a strength of a gas mass flow emerging from the support nozzle arrangement can be varied. As a result, the supporting effect of the gas cushion can be varied. As a result, the loading of the metal strip with the gas cushion or the supporting effect of the gas cushion can be adapted to the respective weight of the metal strip. For example, the weight of the gas mass flow may be lower for a lighter weight metal band than for a heavier weight metal band. The variation of the strength of the gas mass flow can be automated or manual. In the first case, the device may have a signaling and control electronics connected to a blower of the device,

page 6 the data is supplied to the respective weight, the material thickness and / or width of the metal strip and with which these data are processed to generate control signals for the fan. It is furthermore advantageous if a temperature of the gas emerging from the support nozzle arrangement can be varied. The temperature of the gas can be selected, for example, such that the metal strip is kept warm or cooled via the gas cushion. The temperature of the gas can be selected, for example, as a function of a temperature of the metal strip emerging from the annealing furnace. The apparatus may include at least one heater for heating the gas prior to exiting the support nozzle assembly. The variation of the temperature of the gas can be automated or manual. In the first case, the device may have a signaling and control electronics connected to a heater, the data supplied to the respective temperature of the metal strip and with which these data are processed to generate control signals for the heater.

According to a method according to the invention for forming a transverse curvature on a metal strip emerging from an annealing furnace, the transverse curvature is formed without contact on the metal strip.

With the method, the advantages mentioned above with respect to the device are connected accordingly. The above apparatus can be used for carrying out the method. With the method according to the invention, the transverse curvature can be formed on the metal strip without impairing the surface quality of the metal strip.

According to an advantageous embodiment, a gas cushion supporting the metal band from below is produced in such a way that the transverse curvature is formed by the gas cushion on the metal band. For this purpose, the above device

Page 7 be used according to one of said embodiments or any combination of at least two of the embodiments. Consequently, with this embodiment, the advantages mentioned above with respect to the device are connected accordingly.

According to a further advantageous embodiment, a transverse to a strip running direction of the metal strip width of the gas cushion is varied. With this embodiment, the advantages mentioned above with respect to the corresponding embodiment of the device are connected accordingly. The design variants mentioned for this embodiment of the device can be used to implement this embodiment of the method. In particular, the width of the support nozzle assembly or gas nozzle can be varied accordingly to vary the width of the gas cushion. A further advantageous embodiment provides that a thickness of a gas mass flow emerging from the support nozzle arrangement is varied. With this embodiment, the advantages mentioned above with respect to the corresponding embodiment of the device are connected accordingly. The design variants mentioned for this embodiment of the device can be used to implement this embodiment of the method.

It is furthermore advantageous if a temperature of the gas emerging from the support nozzle arrangement is varied. With this embodiment, the advantages mentioned above with respect to the corresponding embodiment of the device are connected accordingly. The design variants mentioned for this embodiment of the device can be used to implement this embodiment of the method.

In the following, the invention will be explained by way of example with reference to the attached figures with reference to preferred embodiments, the features explained below being taken both individually and in each case

page 8 different combination with each other can represent an aspect of the invention. Show it:

Figure 1: a schematic representation of an embodiment of an inventive device; and

Figure 2 is a schematic representation of a support nozzle assembly of another embodiment of an inventive device.

In the figures, identical or functionally identical components are provided with the same reference numerals.

Figure 1 shows a schematic representation of an embodiment of an inventive device 1 for forming a transverse curvature on a emerging from an annealing furnace 2, flat formed metal strip 3. In the tape running direction 4 is followed by the device 1, a cooling line 5 at. Both in the annealing furnace 2 and in the cooling line 5 (water cooler), the metal strip 3 is guided without contact by means of floating nozzles, not shown.

The device 1 comprises a arranged below a strip of the metal strip 3 support nozzle assembly 6, which is adapted to produce a metal band 3 from below supporting gas cushion 7 between the metal strip 3 and the support nozzle assembly 6 such that through the gas cushion 7 on the metal strip 3 the Transverse curvature can be formed without contact.

The nozzle assembly 6 comprises transversely to the strip running direction 4 of the metal strip 3 a substantially over the entire width of the metal strip 3 extending gas nozzle 8. The gas nozzle 8 comprises an outlet opening 9 with a continuously or stepped formed transverse curvature corresponding to the trachea to be formed on the metal strip 3 transverse curvature, as for example from FIG

Page 9 2 can be seen. A width of the support nozzle arrangement 6 or of the gas nozzle 8 given transversely to the strip running direction 4 of the metal strip 3 can be variable. The support nozzle arrangement 6 or the gas nozzle 8 can be arranged to be height-adjustable according to the double arrow 10.

A thickness of a gas mass flow emerging from the support nozzle arrangement 6 or the gas nozzle 8 can be variable. For this purpose, the device 1, a fan 1 1 and a signal technically connected to the fan 1 1 control and / or control electronics 12 for controlling the blower 1 1 have. The control and / or regulating electronics 12 can be supplied with data which are processed by the control and / or regulating electronics 12 for controlling the blower 1 1 or the variation of the intensity of the gas mass flow.

A temperature of the gas leaving the support nozzle arrangement 6 or the gas nozzle 8 can be variable. For this purpose, the device 1 may have a blower 1 1 connected downstream heater 13, which is technically connected to the control and / or control electronics 12 and controllable with this. The control and / or regulating electronics 12 can be supplied with data which are processed by the control and / or regulating electronics 12 for controlling the heating device 13 or the variation of the temperature of the gas.

FIG. 2 shows a schematic representation of a support nozzle arrangement 6 of a further exemplary embodiment of a device 1 according to the invention for forming a transverse curvature on a planely formed metal strip 3 emerging from an annealing furnace, not shown. FIG. 2 shows the positive or concave transverse curvature of the metal strip 3.

The support nozzle arrangement 6 is arranged below a strip run of the metal strip 3 and is set up, a gas cushion 7 supporting the metal strip 3 from below, between the metal strip 3 and the support nozzle arrangement 6

Page 10 to produce that by the gas cushion 7 on the metal strip 3, the transverse curvature can be formed.

The nozzle assembly 6 comprises transversely to a strip running direction 4 of the metal strip 3 a substantially over the entire width of the metal strip 3 extending gas nozzle 8. The gas nozzle 8 comprises an outlet opening 9 with a continuously formed transverse curvature corresponding to the trachea to be formed on the metal strip 3 transverse curvature. A width of the support nozzle arrangement 6 or of the gas nozzle 8 given transversely to the strip running direction 4 of the metal strip 3 can be variable. The support nozzle arrangement 6 or the gas nozzle 8 can be arranged to be height-adjustable according to the double arrow 10.

A thickness of a gas mass flow emerging from the support nozzle arrangement 6 or the gas nozzle 8 can be variable. For this purpose, the device 1, a fan 1 1 and a signal technically connected to the fan 1 1 control and / or control electronics 12 for controlling the blower 1 1 have. The control and / or regulating electronics 12 can be supplied with data which are processed by the control and / or regulating electronics 12 for controlling the blower 1 1 or the variation of the intensity of the gas mass flow.

A temperature of the gas leaving the support nozzle arrangement 6 or the gas nozzle 8 can be variable. For this purpose, the device 1 may have a blower 1 1 connected downstream heater 13, which is technically connected to the control and / or control electronics 12 and controllable with this. The control and / or regulating electronics 12 can be supplied with data which are processed by the control and / or regulating electronics 12 for controlling the heating device 13 or the variation of the temperature of the gas.

Page 1 1 LIST OF REFERENCE NUMBERS

1 device

 2 annealing furnace

 3 metal band

 4 tape direction

 5 cooling line (water cooler)

 6 support nozzle arrangement

 7 gas cushions

 8 gas nozzle

 9 outlet opening

 10 double arrows (height adjustment of 6, 8)

1 1 blower

 12 control and / or control electronics

 13 heating device

page 12

Claims

claims: 1 . Device (1) for forming a transverse curvature on a metal strip (3) emerging from an annealing furnace (2), characterized by at least one support nozzle arrangement (6) arranged below a strip run of the metal strip (3), which is arranged to hold the metal strip (3). from below supporting gas cushion (7) between the metal strip (3) and the support nozzle assembly (6) to produce such that by the gas cushion (7) on the metal strip (3) the transverse curvature can be formed without contact. 2. Device (1) according to claim 1, characterized in that the support nozzle arrangement (6) transversely to a strip running direction (4) of the metal strip (3) at least one substantially over the width of the metal strip (3) extending gas nozzle (8) , 3. Device (1) according to claim 2, characterized in that the gas nozzle (8) has at least one outlet opening (9) with a continuously or stepped formed transverse curvature according to the on the metal strip (3) trainees transverse curvature. 4. Device (1) according to one of claims 1 to 3, characterized in that a transverse to the strip running direction (4) of the metal strip (3) given width of the support nozzle assembly (6) is variable. 5. Device (1) according to one of claims 1 to 4, characterized in that the support nozzle arrangement (6) is arranged vertically adjustable. Page 13 6. Device (1) according to one of claims 1 to 5, characterized in that a strength of a gas jet flow exiting the support nozzle arrangement (6) can be varied. 7. Device (1) according to one of claims 1 to 6, characterized in that a temperature of the out of the support nozzle assembly (6) exiting gas is variable. 8. A method for forming a transverse curvature at one of an annealing furnace (2) emerging metal strip (3), characterized in that the transverse curvature is formed without contact on the metal strip (3). 9. The method according to claim 8, characterized in that the metal strip (3) from below supporting gas cushion (7) is generated such that by the gas cushion (7) on the metal strip (3), the transverse curvature is formed. 10. The method according to claim 8 or 9, characterized in that a transversely to a strip running direction (4) of the metal strip (3) given width of the gas cushion (7) is varied. 1 1. Method according to one of claims 8 to 10, characterized in that a thickness of a gas mass flow emerging from the support nozzle arrangement (6) is varied. 12. The method according to any one of claims 8 to 1 1, characterized in that a temperature of the out of the support nozzle assembly (6) exiting gas is varied. Page 14