EP4348143A1 - Device and method for thermal treatment of a metal strip - Google Patents

Abstract

The invention relates to a strip treatment system for the continuous thermal treatment of a metal strip (6), comprising an annealing furnace and a heatable overageing chamber (11) downstream thereof. In the overageing chamber (11), the metal strip (6) is guided over a plurality of vertically spaced deflecting rollers (12, 12', 13, 13') so that the metal strip meanders through the overageing chamber (11). According to the invention, at least one deflecting roller (12', 13') is movable in the vertical direction, thus allowing the strip length or the residence time of the metal strip (6) in the overageing chamber (11) to be adjusted. The invention also relates to a method for the thermal treatment of a metal strip (6).

Description

DEVICE AND METHOD FOR THE HEAT TREATMENT OF A

METAL BANDES

The subject of this invention is one

Strip treatment plant for the continuous heat treatment of a metal strip with an annealing furnace and a subsequent heatable overaging chamber. The metal strip is guided in the aging chamber over a plurality of vertically spaced rollers, so that it meanders through the aging chamber.

Conventional strip treatment plants consist of several chambers in which the metal strip is first heated to the annealing temperature and kept at this temperature for a certain period of time. It is also possible that a defined temperature curve is followed. Such annealing furnaces are well known. The metal strip is then cooled down according to a specified cooling rate, to a defined one

brought to over-aging temperature and held at that temperature for a predetermined period of time. So-called overaging chambers are used to keep a metal strip at a specific temperature for a precisely defined period of time (overaging temperature). These chambers are often also referred to as "holding chambers" or "soaking chambers" or also as "partitioning chambers". The temperature within the overaging chamber should be as constant as possible and is between 150°C and 500°C, depending on the metal strip alloy. In these overaging chambers there is usually also a protective gas atmosphere or a reducing atmosphere, for example a hydrogen-nitrogen mixture.The metal strip can then be cooled to room temperature or, for example, brought to the coating temperature in galvanizing plants, such as galvanizing plants.

All of these heat treatment steps affect the mechanical properties of the metal strip. It is important that the metal strip is not only heated to a certain temperature, but also kept at a defined temperature for a precisely defined period of time in the overaging chamber. The heating rates and the cooling rates also influence the strip properties. Metal strips of different thicknesses or compositions also require different heat treatment parameters.

The dwell time of the metal strip in the overaging chamber is determined by the strip speed and strip length in the overaging furnace. The length of the strip in conventional aging chambers is determined by the arrangement of the deflection rollers, so that the dwell time can only be regulated via the strip speed. However, the line speed can only be varied to a very limited extent, since every change in speed naturally also affects the production capacity, the heating rate and the cooling rate.

The object of the present invention is to provide a strip processing line in which the dwell time of the metal strip in the overaging chamber can be adjusted within broader ranges, so that completely different metal strips can be treated with the same strip processing line, whereby always an optimal residence time in the overaging chamber can be set.

This object is achieved by a strip treatment system according to patent claim 1. In the aging chamber, at least one deflection roller can be moved in the vertical direction, so that the length of the metal strip in the aging chamber can be adjusted. As a result, the dwell time of the metal strip in the overaging chamber can also be adjusted.

Thus, the dwell time can be adjusted independently of the line speed by changing the length of the line in the chamber. As a result, one and the same strip processing line can meet different production requirements and can also be flexibly adapted to new conditions.

Ideally, for a given strip format (strip thickness, strip composition, strip width) and a given heat cycle (annealing temperature, cooling temperature, cooling rates...), the strip speed is set with regard to maximum production capacity. The required strip length in the aging chamber is set on the basis of this strip speed, so that the optimal dwell time of the metal strip in the aging chamber, or that specified by the heat cycle, is achieved.

The aging chamber described here should not be confused with a conventional tape storage device (looper). Loopers also have movable rollers and can accommodate different tape lengths. However, they serve to compensate for different belt speeds in the system. For example, if a new to the plant strip that has been introduced has to be welded to the end of the previous strip and the strip has to be stopped for this purpose, the strip accumulator ensures by releasing stored strip that the strip speed in the subsequent treatment systems does not change. However, such loopers are

Ambient temperature operated in ambient air. They only serve to compensate for different belt speeds and do not carry out any heat treatment.

It is advantageous if several deflection rollers can be moved in the vertical direction in the aging chamber according to the invention. As a result, the tape length recorded can be varied greatly.

Advantageously, one or more upper deflection rollers can be moved in the vertical direction.

It is advantageous if one or more movable deflection rollers are supported or fixed in a specific position, into which they were moved to achieve a predetermined belt length. For the treatment of a specific metal strip, the deflection rollers remain in this defined position anyway. By supporting or fixing the lifting mechanism for the deflection rollers can be relieved.

The overaging chamber is preferably heated electrically, for example with radiant tubes. However, the gas in the aging chamber can also be sucked off, electrically heated and then injected again. The overaging chamber according to the invention is arranged, for example, in front of a coating system.

It is advantageous if a cooling section is arranged between the annealing furnace and the overaging chamber, since such a cooling step is required for many heat treatments.

In addition to the device, the invention also relates to a method for the continuous heat treatment of a metal strip according to patent claim 9.

A dwell time is set for the heat treatment of the metal strip in the overaging chamber and then the strip length and thus also the dwell time is set by moving at least one deflection roller.

It is favorable here if the metal strip is heat-treated in the overaging chamber in a hydrogen-nitrogen atmosphere.

Several exemplary embodiments of the invention are described below with reference to drawings. Show it:

1 is a schematic view of a prior art overaging chamber.

2 shows an exemplary embodiment of an overaging chamber according to the invention with a movable upper deflection roller;

3 shows a further exemplary embodiment of an overaging chamber according to the invention with a movable lower deflection roller; 4 shows an exemplary embodiment of an overaging chamber according to the invention with a plurality of movable upper deflection rollers;

5 shows a schematic view of a possible roller movement system;

Figure 6 shows three different roll positions in an overaging chamber 11;

Figures 7 and 8 show an embodiment of a roller motion system;

9 and 10 show a schematic representation of the heating and cooling, respectively, of the overaging chamber 11;

The same reference symbols in the individual figures denote the same parts of the system.

FIG. 1 shows an overaging chamber 1 according to the prior art. A metal strip 6 is introduced from the left into the aging chamber 1 and is deflected vertically upwards by a lower, fixed deflection roller 2 . In the upper area of the aging chamber 1, the metal strip 6 is then deflected downwards by 180° by an upper, fixed deflection roller 3. The metal strip 6 is thus guided in a meandering manner through the aging chamber 1 until it is finally deflected in the horizontal direction by the last lower deflection roller 2 and leaves the aging chamber 1 . The interior of the overaging chamber 1 is tempered to a predetermined temperature, which is typically between 150°C to 500°C lies. Importantly, the interior of the aging chamber

I is kept at a constant temperature as possible. The housing 4 of the aging chamber 1 is provided with insulation 5 to reduce heat losses. The aging chamber is heated by electrically heated radiant tubes 7.

In order to achieve optimal material properties, the metal strip 6 should spend a defined period of time (dwell time) in the overaging chamber 1 .

Since in the aging chamber 1 according to FIG. 1 the lower and the upper rollers 2, 3 are stationary, the length of strip taken up is always the same. The dwell time can therefore only be changed by changing the belt speed.

FIG. 2 now shows an embodiment of the overaging chamber

II according to the invention. The housing 14 is also provided with an insulation 15 here and the metal strip 6 is also guided in a meandering manner through the aging chamber 11 via lower, fixed deflection rollers 12 and upper, fixed deflection rollers 13 . However, here an upper deflection roller 13' can be moved (moved) in the vertical direction. In the present example, it was reduced to half the height. In the present example, the aging chamber is heated by electrically heated radiant tubes 17. These radiant tubes 17 are not arranged here in the area of the movable deflection roller 13', since this would impede the freedom of movement of the deflection roller 13'. Of course, it is also conceivable for this overaging chamber 11 to be heated by the supply of hot gas, as will be described further below. Since the deflection roller 13' can now be moved in the vertical direction, the strip length of the metal strip 6 in the aging chamber 11 can be changed. The dwell time of the metal strip 6 in the overaging chamber 11 can thus be adjusted without the strip speed having to be changed for this purpose.

As a rule, the optimum dwell time for a specific metal strip 6 is determined in advance. The necessary strip length in the aging chamber 11 is then calculated by specifying a specific strip speed and is set by moving the upper deflection roller 13' or the upper deflection rollers 13'. The displaceable upper deflection rollers 13' are preferably no longer moved (moved) during the treatment of a specific metal strip 6, but fixed in their position.

FIG. 3 shows an overaging chamber 11 in which a lower deflection roller 12' can be moved in the vertical direction.

FIG. 4 shows an embodiment in which several upper deflection rollers 13' can be moved in the vertical direction.

The upper deflection rollers 13' can be moved independently of one another.

FIG. 5 shows a possible embodiment for a mechanism by which the deflection rollers 12' and 13' can be moved in the vertical direction.

The bearing housing 23 of the upper movable deflection roller 13 'hang each on a chain 25, which are deflected in the upper region of the aging chamber 11 by gears 21. At the other end of the chains 25 are counterweights 20 fastened. The two gear wheels 21 are coupled to one another via a shaft 22 and connected to a drive 18 . By rotating the shaft 22, the upper deflection roller 13' can be moved in the vertical direction. The arrangement would look similar if a lower deflection roller 12' is to be moved with it.

Roller supports 19, 19' are provided at different heights on the side of the wall. To this

The deflection roller 13' or 12' can be laid down or fixed in place on roller supports. Thus, during the heat treatment of a specific metal strip 6, the chains 25 and the drive 18 can be relieved. The stationary lower deflection roller 12 and the shaft 22 are mounted outside the aging chamber 11 here. Thus, these bearings 46 do not have to withstand high temperatures. The lower deflection roller 12 has a drive 45.

Three different strip lengths in an overaging chamber 11 are shown in FIG.

In the middle illustration, both upper deflection rollers 13' are in their uppermost position, the strip length in the aging chamber 11 is thus at a maximum and the dwell time at a given strip speed is the longest.

In the illustration on the left, one of the two moveable upper deflection rollers 13' has been lowered somewhat, thus shortening the belt length and thus also the dwell time at a given belt speed.

In the illustration on the right, both upper deflection rollers 13' are in their lowest position. Here the tape length in the overaging chamber 11 is shortest and thus the dwell time at a given belt speed is also minimized.

The adjustment mechanism for the movable deflection rollers 12' and 13' is shown in somewhat more detail in FIGS. Since the deflection rollers 12 ′ and 13 ′ are located inside the heated overaging chamber 11 , in which temperatures of up to 500° C. can certainly prevail, they are supported by high-temperature bearings 31 . An ordinary roller bearing 27 housed in a bearing housing 26 is sufficient for supporting the shaft 22 . The bearing housing 26 is connected to the support structure 30 via a bearing support 29 . On this

Support structure 30 also rests the motor support 28 and the drive 18.

An expansion bellows 24 is arranged between the housing 14 of the aging chamber 11 and the bearing housing 26 in order to be able to better compensate for any thermal expansions and to protect against dust.

FIG. 8 shows the function of the roller support 19, 19'. The roller support 19, 19 'is housed in a housing 32 and can

Overaging chamber 11 are retracted. The housing 32 rests on a steel structure 44 via a substructure 33 . A plurality of roller supports 19, 19' are generally arranged at different heights over the height of the chamber, so that the deflection roller 12' or 13' can be supported at different heights.

In FIG. 9, one possibility for heating the overaging chamber 11 is shown. The Aging Chamber 11 should have a temperature that is as constant as possible inside for the treatment of a specific metal strip 6; this temperature is between 150° C. and 500° C., depending on the material and treatment. Since there is always heat loss, the chamber must be heated in order to be able to keep the temperature level as constant as possible. Of course, there can be smaller temperature differences within the overaging chamber 11, but these are usually only a few degrees Celsius. For heating, hot gas, for example an inert gas or a reducing gas such as a nitrogen-hydrogen mixture, is blown into the overaging chamber 11 via a supply box 34 arranged on the side and sucked off again by a blower 36 via a suction box 35 on the opposite side. The gas is then fed either to an electric heater 40 or to a heat exchanger 39 and fed back into the overaging chamber 11 via a recirculation line 37 . The hot gas can be fed to either the heat exchanger 39 or the electric heater 40 via valves 38 and 41 . The gas temperature is increased again by the electric heater 40 . If the gas is passed over the heat exchanger 39, it can also be cooled. This is necessary, for example, when switching from one type of steel to another. If, for example, the following steel grade requires a lower overaging temperature, the gas is cooled so that the optimal temperature in the overaging chamber 11 is reached as quickly as possible. At the same time, the length of the strip in the overaging chamber 11 can be adjusted by moving the deflection rollers 12' and 13', so that the subsequent steel grade can be optimally heat-treated. FIG. 10 shows the heating or cooling device from FIG. 9 again. It can be seen here that the heat exchanger 39 is supplied with cooling water 43 . The motor 42 for the blower 36 is also shown. In this illustration, a hydrogen-nitrogen mixture (HNX) is used as the heating medium.

reference sign

1 State-of-the-art overaging chamber

2 lower fixed pulley

3 upper fixed pulley

4 housing

5 insulation

6 metal band

7 jet tube

11 Aging Chamber

12 lower pulley (fixed)

12' lower pulley (movable)

13 upper pulley (fixed)

13' upper pulley (movable)

14 housing

15 insulation

17 jet tube

18 drive

19 Roller Support (Extended)

19' roll support retracted into the aging chamber 11

20 counterweight

21 gear

22 wave

23 bearing housing expansion bellows

Chain

bearing housing

roller bearing

engine support

warehouse support

support structure

high temperature storage

Roller support housing 19

substructure

feed box

suction box

fan

recirculation line

Valve

heat exchanger electric heating

Valve

engine

cooling water

steel construction

Drive for the deflection roller 12

Bearing for the fixed deflection roller 12

Claims

patent claims

1. Strip treatment plant for the continuous heat treatment of a metal strip (6) with an annealing furnace and a subsequent heatable overaging chamber (11), the metal strip (6) being guided in the overaging chamber (11) via a plurality of vertically spaced deflection rollers (12, 12', 13, 13' ) is guided so that the metal strip (6) runs through the aging chamber (11) in a meandering manner, characterized in that at least one deflection roller (12', 13') can be moved in the vertical direction, so that the length of the material received in the aging chamber (11) is thereby increased Metal strip (6) is adjustable and thereby the dwell time of the metal strip (6) in the overaging chamber (11) is adjustable.

2. Strip treatment plant according to claim 1, characterized in that several deflection rollers (12', 13') can be moved in the vertical direction.

3. Strip treatment plant according to claim 1 or 2, characterized in that one or more upper deflection rollers (13') can be moved in the vertical direction.

4. Strip treatment plant according to one of claims 1 to

3, characterized in that the movable deflection roller (12', 13') or the movable deflection rollers (12', 13') can be supported or fixed in a specific position by a roller support (19').

5. Strip treatment plant according to one of claims 1 to

4, characterized in that the

Overaging chamber (11) is electrically heated.

6. Strip treatment plant according to one of claims 1 to

5, characterized in that the

Overaging chamber (11) can be heated by injecting heated gas.

7. Strip treatment plant according to one of claims 1 to

6, characterized in that the

Aging chamber (11) is arranged in front of a coating plant, preferably in front of an electroplating plant.

8. Treatment installation according to one of claims 1 to 7, characterized in that a cooling section is arranged between the annealing furnace and the overaging chamber (11).

9. Process for the continuous heat treatment of a metal strip with an annealing furnace and in a subsequent overaging chamber (11), wherein the metal strip (6) in the overaging chamber (11) is guided in a meandering manner over vertically spaced deflection rollers (12, 12', 13, 13'). characterized in that a dwell time is specified for the heat treatment of the metal strip (6) in the overaging chamber (11) and that by moving at least one deflection roller (12', 13') in the overaging chamber (11) the strip length and thus also the dwell time of the metal strip (6) in the overaging chamber (11) is adjusted.

10. The method as claimed in claim 9, characterized in that the gas or gas mixture located in the overaging chamber (11) is sucked off, heated and fed back to the overaging chamber (11).

11. The method according to claim 10, characterized in that the gas or gas mixture is electrically heated.

12. The method according to any one of claims 9 to 11, characterized in that the metal strip (6) in the

overaging chamber (11) at a temperature of 150°C to 500°C, preferably at 400 to 500°C.

13. The method according to any one of claims 9 to 11, characterized in that the metal strip (6) in the overaging chamber (11) is heat-treated in a hydrogen-nitrogen atmosphere.