WO2011032890A1 - Method and device for continuously stretch-bend-leveling metal strips - Google Patents

Abstract

The invention relates to a method and a device for continuously stretch-bend-leveling metal strips, wherein a strip under a tensile stress below the elastic limit is alternatingly bent about at least four straightening rollers in the plastic or elastic-plastic region and thereby undergoes plastic stretching. The bending radii of all four straightening rollers are thereby set individually and independently of each other, as the straightening rollers are set up having individually controlled positions.

Description

 metal strips

Description:

The invention relates to a method and a device for stretch bending of metal strips, wherein a standing under a tensile stress below the elastic limit or yield strength band is mutually bent by at least four straightening rollers in the plastic or elastic-plastic region and thereby undergoes a plastic stretching. The plastically or elastically plastic straightening rollers are also referred to as stretch rollers. The extent to which the tape is stretched plastically (in total) and thus elongated is called the degree of stretching. With such a stretch bending method, unplane metal bands can be straightened out and consequently eliminate planets. Unplanarity means, for example, waviness and / or banding due to length differences of the band fibers in the band plane. However, unevenness also means strip curvatures in the longitudinal and / or transverse direction, which arise as a result of bending moments in the strip, for example if the strip has been elastically plastically bent around deflection rollers or by elastic-plastic deformations during winding of the strip. Longitudinal curves are also referred to as coil set, Querkrüm rules as Crossbow. In the course of stretch bending, the unplane band is bent under a tensile stress which is below the elastic limit RE or the technical elastic limit R _p o, oi of the band material around rollers of sufficiently small diameter (mutually), so that the superposition of the tensile stress with the bend an elastic / plastic deformation is produced in the band. The strip is elongated plastically, the height of the plastic elongation being called the degree of stretching. During plastic elongation, the originally short ribbon fibers are elongated relatively more strongly. Ideally, have After straightening all the ribbon fibers the same length, so that in principle an ideally directed band should be free of ripples or bandsaw.

In the case of the stretch bending methods known from practice, residual bending moments can remain in the band after straightening due to the mutual bending in the elastic-plastic region, which bending moments can be seen in the band treatment line as transverse curvature and in the case of a cut-out panel to a plastic residual curvature in the longitudinal and / or Can lead transverse direction. The residual bending moments arise when the individual bends are not optimally matched in their intensities. The bending radii depend on the band data (thickness, elastic modulus, cyclic strength behavior, transverse contraction number), the strip tension, the roll diameters and the geometry of the strip run around the rolls. In a first approximation, the latter can be described by the angle of wrap of the band around the rollers. If the wrap angle or tension is sufficient, the tape will take on the radius of the roll. Then the band curvature reaches its maximum and remains constant as the wrap angle or tension increases. As a rule, however, the wrapping angles are set such that the strip no longer follows the roller wheel, at least for the last rollers in the stretch bending stage. Even with an optimal setting of a given stretch bending stand, residual bending moments result from fluctuations in the process parameters. For in practice, both the tensile stress and consequently the degree of stretching and the strength values and the strip thickness of the strip are fundamentally subject to certain fluctuations. The known from practice stretch bending methods react more or less sensitive to such fluctuations. This means that in conventional stretch bending processes such variations are more or less dependent on the remaining or generated residual curvatures impact. This also applies to stretch bending, in which the band is elastically-plastically deformed by four straightening rollers.

In such stretch bending stands with four straightening rollers, it is known to set the geometry of the stretch bending stage to achieve the best possible straightening results. For example, DE 696 08 937 T2 (or EP 0 767 014 B1) discloses a stretch bending stage with four straightening rollers, in which both the upper straightening rollers and the lower straightening rollers can be changed with respect to their position. While the lower straightening rollers can be adjusted with a certain degree of accuracy using mechanical spindle drives to improve the straightening result, the upper straightening rollers are hydraulically actuated. In this way, a desired overlap of roles should be set. The same applies to the stretch bending jigs known from DE 695 14 010 T2 (or EP 0 665 069 B1) and DE 38 85 019 T2 (or EP 0 298 852 B1).

Similarly, the article "Benefits of New Level Technology for Packaging Steels: Multi-Roller Tension Leveler" (Emmanuel Dechassey, Irsid, Arcelor group, METEC Congress June 2003) describes a stretch bender having four straightening rollers. The overlapping of the first straightening unit (first and second roller) and the overlap of the second straightening unit (third and fourth roller) are adjustable.

DE 691 01 995 T2 (or EP 0 446 130 B1) also mentions the possibility of changing the position of all four straightening rollers. However, this is primarily the change between a waiting position and a working position. For a stretch bending stand, it is usually necessary for the purpose of passing a junction between two coils or bands, the Open scaffolding and then close again. In any case, it has been shown in practice that the known stretch bending or stretch bending straightening processes are relatively sensitive to fluctuations in the process parameters, so that the residual curvatures can not be minimized in the desired manner.

Basically less sensitive to the process parameters react so-called multiroll levelers, which are also referred to as multi-roll straightening devices. In multi-roll straightening, the belt is subjected to a variety of bends around small diameter rollers. By using many rolls, the tape can be produced with little residual curvature. The disadvantage here is the fact that the large number of roles associated with a high maintenance and spare parts. In addition, the lower and upper rollers are each frictionally connected to each other via the support rollers or intermediate rollers and support rollers such as a 1: 1 gear. Since the belt is elongated plastically during the passage through the multi-roller stand, the belt speed also increases to the same extent. Thus, the tape is synchronized only in one roll, slip occurs between the other rolls and the tape. The reels often run at high speed belt handling speeds in a number of revolutions. This slip can cause the rollers to vibrate, producing chatter marks on the belt surface. This is unacceptable in practice for a variety of applications. For these reasons, conventional stretch bender stands have also been combined with multi-roll straightening units (compare EP 0 665 069 B1 and DE 695 14 010 T2).

Moreover, DE 27 50 752 describes a method for straightening and improving the quality properties of metal strips, in particular electrical strips, in which the metal strip to be treated is bent counter pressure-free and subjected to a plastic alternating bending. The metal band is bent while maintaining its plastic bending state in plan position, which are made to the last bend deflections of the metal strip exclusively in the elastic or nearly elastic range. Preferably, only two counter-pressure roller-free bending rollers are realized with the interposition or downstream of one or more deflection rollers. It can also be provided several bending rollers. It is always important that the last bend is carried out with the highest possible plastic bending deformation and that the metal strip is subsequently bent only elastically or predominantly elastically.

Starting from the known prior art, the technical problem underlying the invention is to provide a stretch bending method which provides optimum flatness results with low equipment costs and, in particular, is insensitive to fluctuations in the process parameters (tensile stress, strip strength and strip thickness). In addition, a device is to be specified, which is characterized by a simple and inexpensive construction and yet provides the desired results.

To solve this problem, the invention teaches in a generic method for continuous stretch bending of metal bands of the type described input that the bending radii are set individually and independently of each other on all four straightening rollers. For this purpose, the invention proposes that all four bending rollers are employed position-controlled. If the band is bent alternately by more than four straightening rollers, the invention proposes that the bending radii of each of the last four rollers are adjusted individually and independently relative to the band running direction, preferably by at least the last four rollers being adjusted individually in a position-controlled manner.

Investigations by means of a computer model, which takes into account stresses in longitudinal and transverse direction, as calculation parameters the tape thickness, the modulus of elasticity, the transverse contraction number, the cyclic strength behavior of the tape, the tape tension, the roller radii and the geometry of the tape running around the rollers, have surprisingly revealed that this Provides excellent residual curvature results and in particular reacts relatively insensitive to variations in the process parameters. It is of particular importance that the four elastically-plastically acting flexures can be adjusted or adjusted in a position-controlled manner with sufficient accuracy. The positions of the straightening rollers are then adjusted with an accuracy and control accuracy which corresponds to an accuracy in relation to the wrap angle of the belt around the straightening rollers of ± 0.05 ° or less, preferably ± 0.02 ° or less. The wrap angle of the band around one or more straightening rollers, preferably around all straightening rollers can be 0.5 ° to 60 °, preferably 1 ° to 35 °. The (total) degree of stretching is, for example, 0.1% to 1.5%, preferably 0.2% to 0.6%. The band tension is preferably from 10% to 90%, preferably from 30% to 60%, of the elastic limit of the band or band material.

The simulation calculations have shown that a two-roller configuration usually does not lead to stretch bending when straightening, since the longitudinal and transverse bending moment curves as a function of belt curvatures do not behave mirror-inverted, as in pure bending, but are shifted against each other due to the tensile stress , In order to correct the plastic belt curvatures in the longitudinal and transverse directions produced on the first roll, therefore, only one further roll is not sufficient, since this brings into equilibrium only either the longitudinal or the transverse bending moments can be. The minimum number of rollers for producing an ideal rest-curvature-free band for given process parameters is thus three. The calculations have shown, however, that the residual bending moments achieved or the elimination of such residual bending moments in the case of a stretch bend, for example, with increasing wear resistance, react to variations in the process parameters. The same applies to a four-roller stand, in which the individual rollers can not be adjusted individually and independently of one another with the required accuracy. A remedy here is the method according to the invention, in which the four rollers are adjusted individually and independently of each other in a position-controlled manner.

Furthermore, the invention proposes that the distance between at least two (immediately) successively arranged straightening rollers (based on the strip running direction) at least 15% of the (maximum) bandwidth, for example at least 30% of the (maximum) bandwidth, particularly preferably at least 50% of (maximum) bandwidth is. It may be expedient if the above distances in all four straightening rollers between two pairs (immediately) arranged successively straightening rollers. For example, the distances between two such straightening rollers may be at least 150 mm, preferably at least 300 mm. The model-based investigations have here led to the surprising result that can be minimized or eliminated by the favorable choice of the distances between the elastically-plastically acting straightening rollers, the process-related degree of stretch differences over the bandwidth. It has been found that generally larger horizontal distances have a favorable effect. Given the maximum length of the stretch bending stand, it is favorable to carry out at least a distance between elastically-plastically acting rolls with at least 30% of the maximum width, but at least 500 mm. The decisive factor is the distance between the straightening rollers along the direction of belt travel. This corresponds to a stretch bending Scaffolding in horizontal construction the horizontal distance. In principle, however, a distance in an oblique or vertical direction may be meant, depending on the direction in which the tape is guided. Depending on the application spectrum of the products to be straightened, different roller spacings are optimal, so that a further improvement of the straightening results with respect to ripple can be achieved if these distances are variable or adjustable. Consequently, it is provided according to a further proposal of the invention, the independent significance, provided that the distance in the direction of tape travel between at least two straightening rollers is set variably or can be. The optimum distances can then be specified model-based for a specific band.

The invention further proposes that the setpoint values for the position of the straightening rolls and / or the setpoint values for the wrap angles of the strip around the straightening rolls be determined with a mathematical model which takes into account at least stresses in the longitudinal and transverse direction, as the calculation parameter the strip thickness. the modulus of elasticity, the transverse contraction number, the cyclic strength behavior of the belt, the belt tension, the roller radii and the geometry of the belt run are processed around the rollers, for the target values of the strip thickness and the strength, for example the yield strength, are calculated such that the residual longitudinal and lateral curvature Becomes zero or at least negligible. Ideally, therefore, bands are produced with vanishingly small residual curvatures. Optionally, however, it is also possible to use the calculation model to determine the setpoint values with the proviso that, although a negligible or negligible residual cross-curvature value is achieved, the residual longitudinal curvatures assume a defined value. The invention is based on the recognition that there are definitely applications in which residual curvatures must be completely avoided, but in which certain Restlängskurümmungen are tolerable, provided that they are exclusively in a certain direction and consequently have only a specific sign. Furthermore, the invention optionally proposes that after or behind one or more straightening rollers, for example after the last straightening roller, particularly preferably after each straightening roller, the transverse curvature of the belt is measured across the belt width. These measured transverse curvatures can then be incorporated into a regulation which, on the basis of the measured values, corrects the wrap angles or roll positions such that a strip with sufficiently small residual longitudinal and residual transverse curvature is produced.

The invention thus comprises, first of all, such embodiments in which the set values for the bending radii and consequently for the roll position and / or the wrap angles are determined by means of a mathematical model, the system then being operated with these values. Simulations have shown that such a procedure leads to excellent results even with certain variations of the process parameters. Optionally, it is possible to correct the setpoints during commissioning of the system or, if necessary, during operation, based on experimentally obtained results. Such a correction can be carried out "off-line". As described, however, it is also optionally possible to carry out a correction "on-line" taking into account the measured values in the sense of a control or regulation. This regulation can also be based on a mathematical model which takes into account at least stresses in longitudinal and transverse directions, as calculation parameters the strip thickness, the modulus of elasticity, the transverse contraction number, the cyclic strength behavior of the strip, the strip tension, the roller radii and the geometry of the strip run around the Rolls processed, and a certain transverse curvature Bandrestlängs- or -verkrümmung is assigned.

The computational models described can be based on a finite element method, which is able to take into account stresses and strains across the bandwidth. On the basis of the maximum expected or before straightening measured Bandunplanheit the optimum degree of stretching and / or the optimal horizontal distances of the elastically-plastically acting rollers can be calculated by the finite element method, which give the minimum residual unevenness, in particular ripples and band saber ,

The invention also relates to an apparatus for continuous stretch bending of metal strips with a method of the type described. Such a device has at least four bending rollers around which a standing under a tensile stress below the elastic limit band in the plastic or elastic-plastic region is mutually bent. Furthermore, such a device has at least one control and / or regulating device. The invention proposes that the bending radii are individually and independently adjustable on all four straightening rollers. For this purpose, the invention preferably proposes that all four straightening rollers are connected to the control device and can be adjusted in a position-controlled manner. For this purpose, the individual straightening rollers are each provided with one or more finely adjustable actuators, preferably Spindelhubelementen. The diameter of one or more or preferably all four straightening rollers is for example 15 mm to 150 mm, preferably 25 mm to 80 mm. It has already been explained that it is particularly preferred to work with relatively large distances between the individual straightening rollers. Particularly preferably, the device is designed so that these distances adjustable are, for example, by the position of at least one straightening roller along the strip running direction is variably adjustable.

Another requirement for a straightening process is the minimization of waviness / band saber, in addition to the freedom of residual curvature. The ripples present in the tape before straightening should be removed, and the straightening process itself should not produce a new one. In the case of stretch bending, the problem arises here that the strip deforms elastically plastically on the roll and thereby elongates plastically. The plastic elongation is accompanied by a plastic reduction of the bandwidth. So the band section is wider in front of the roll than the one directly after the roll. However, since the band can not change the width abruptly, resulting in shear stresses in the band level, which vary over the bandwidth and band length seen. The shear stresses in turn lead to an overall uneven plastic band deformation over the bandwidth, so that different plastic elongation over the bandwidth and thus caused by the straightening ripples. These are usually center ripples, which become stronger with increasing degree of stretch. The model-based investigations here have led to the surprising result that these process-related yield differences in the band width can be minimized or eliminated by a favorable choice of the distances between the elastically-plastically acting rollers. It has been found that generally larger horizontal distances have a favorable effect. Depending on the range of applications of the products to be straightened, different roller distances are optimal, so that a further improvement of the straightening results in relation to the waviness, if at least one straightening roller is designed to be horizontally adjustable.

For large horizontal distances of the elastically-plastically acting straightening rollers, the insertion depths of the rollers are angle relatively large. To pass through a joint of two coils, such as a punched connection or weld, usually the stretch bender must be opened, that is, the roles are turned off. If the paths to be covered are large, this process takes a long time. As a consequence, if the tape continues to run in the event of a conti line, then the undirected tape lengths around the joint become large. This is basically undesirable. The invention therefore proposes in an optional further development that at least one elastically-plastically acting straightening roller is preceded by an adjacent deflection roller and / or an adjacent deflection roller is disposed downstream, such an adjacent deflection roller preferably having at least three times the diameter, more preferably at least ten times the diameter of the straightening roller , In this way, the Anstellwege and thus the non-directional tape sections are considerably shortened. The deflection rollers have such a large diameter that only a purely elastic band deformation occurs for at least part of the band thickness spectrum to be straightened. Preferably, at least the last two rollers should be executed without intermediate deflection rollers in order to achieve as high a geno as possible in the resetting of the wrap angle.

Furthermore, it is possible that at least one of the adjacent deflection rollers has a concave or convex roller contour. Further, one of the two adjacent pulleys or both adjacent pulleys can be equipped with a Rollenverbiegung in the horizontal and / or vertical direction. The first elastic-plastic straightening roller may be preceded by a contour variable tension roller or deflection roller wound around at least 120 °. By means of these measures it is achieved that a specific tensile stress distribution over the bandwidth is set on at least one elastically-plastically acting straightening roller in order to be able to influence the degree of stretch distribution over the bandwidth so that after straightening Band with the least possible residual wave is present. Specifically, increasing the tension at the tape edges would counteract center ripple. Incidentally, the elastically-plastically acting straightening rollers can be supported against deflection by support rollers. For example, segmented support rollers can be used. Thus, the elastically-plastically acting rollers can be supported against deflections by two rows of segmented support rollers or two intermediate rollers and three rows of segmented support rollers.

In the following the invention will be explained in more detail with reference to a drawing showing only one exemplary embodiment. 1 shows a device according to the invention for stretch bending straightening in a simplified, schematic representation,

FIG. 2 shows the object according to FIG. 1 in a modified embodiment, FIG. 3 calculated residual longitudinal curvatures for a metal strip which has been directed with a device according to FIG. 1 and FIG

Fig. 4, the residual longitudinal curvature, which is achieved with a conventional three-roller stand with single employment.

In the figures, an apparatus for continuous stretch bending of metal strips 1 is shown. In the exemplary embodiments, the device has four straightening rollers 2 around which a band 1 under a tensile stress below the elastic limit is bent alternately in the plastic or elastic-plastic region. Each of the straightening rollers 2 is in supported by known manner of at least two support rollers 3. The band 1 is under a tensile stress below the elastic limit. For this purpose, tension rollers, not shown, for example, a brake roller set on the inlet side and a Zugrollensatz provided on the outlet side.

According to the invention, the bending radii are adjustable individually or independently of each other on all four straightening rollers. For this purpose, all four straightening rollers 2 with a control device, not shown, and, for example, Spindelhubelmenten, positionally adjustable adjustable, in a direction of tape R vertical direction V. This is indicated in the figures by the dot-dashed functional positions of the rollers 2. The parameters and in particular the roller radii and the belt tension are matched to one another in such a way that the belt does not (yet) follow the roller radius on all four straightening rollers. Consequently, by controlling the setting depth and consequently by regulating the position and the associated setting of the wrap angle, the respective bending radius can be varied.

In the embodiment according to FIG. 1, no further rollers are arranged between the four straightening rollers 2. Only before and behind the entire straightening roller arrangement pulleys 4 are provided.

In contrast, Fig. 2 shows a modified embodiment in which each straightening roller 2 upstream of a respective deflection roller 4a and a deflection roller 4b are arranged downstream. Also in this embodiment, however, all four straightening rollers 2 are positionally variable in their position perpendicular to the strip running direction R.

Although the embodiment of FIG. 1 is to be preferred in principle, as they roll out of the inlet and outlet side elastically acting passport Without further (purely elastically acting) roles, the embodiment according to FIG. 2 can optionally be advantageous. Combinations of the two versions are possible. Regarding the purely elastic deflection pulleys, it should be noted that they only have a purely elastic effect on thin and / or higher-strength belts, for example in the case of aluminum in the band thickness range below one millimeter. In addition, they also have a slight elastic-plastic effect and can influence the straightening result with regard to residual curvatures. If a stretch bending scaffold is to cover a larger band thickness range, it is particularly preferable to dispense with the deflection rollers.

For the commissioning of such a system, the exact nominal positions of all four straightening rollers 2 are now determined using a mathematical model. In this case, it is possible to first determine the desired wrap angle with a mathematical model which takes into account at least stresses in longitudinal and transverse directions, as calculation parameters the strip thickness, the modulus of elasticity, the transverse contraction number, the cyclic strength behavior of the strip, the strip tensile stress, the roller radii and the geometry of the strip For example, the strip is processed around the rolls for which the setpoint values of the strip thickness and the strength, for example the yield strength, are calculated such that the residual longitudinal and residual transverse curvatures become zero or virtually zero. In this way, the positions of the straightening rollers 2 can be set exactly. It is then possible, depending on experimental results "off-line" make a correction of these positions.

Of particular importance is the fact that the once exactly specified setting ensures that the residual curvature behavior are extremely insensitive to fluctuations in the process parameters such as in particular the tensile stress and the strength values and the strip thickness of the strip. As in practice a band of a coil usually certain Subject to changes in strength and thickness and also the tensile stress can not always be maintained exactly constant, the residual curvatures obtained were also subject to considerable fluctuations with the hitherto known methods. This is avoided in the invention. The inventive method shows a particularly good-natured residual curvature behavior. Reference is made to a comparative consideration of Figs. 3 and 4.

FIG. 3 shows the residual longitudinal curvature k L (in 1 / m) for an aluminum strip as a function of the degree of stretching S (in%), which was directed by a device according to FIG. These are calculated values generated with a mathematical model. In the embodiment, a yield strength of 250 MPa was assumed with variations of ± 10 MPa and a strip thickness of 0.28 mm with variations of ± 0.05 mm. The figure also shows the limits of the residual longitudinal curvature of ± 0.5 m ^"1 , which are considered permissible, and it can be seen that the residual longitudinal curvature in the given tolerance window lies within a fairly large degree of stretching of 0.31 to 0.59% moreover, the fact that the residual longitudinal curvature in a draft window of ± 0.05% is only ± 0.15 m ^"1 . T heights of rest are always lower than the remaining longitudinal curvatures. The residual longitudinal curvatures are also within a draft window of 0.36 to 0.52% defined in the negative range with very little variation. By adjusting the wrap angle at the last roll, the remaining curve in the diagram can be moved up or down. Thus, a defined positive Längsrestkrümmung is adjustable.

In contrast, Fig. 4 shows a corresponding simulation with a three-roller scaffold, the individual roles also position-controlled are adjustable. It can be seen that the residual longitudinal curvature varies with variations in the degree of stretching in a considerably larger range. The limit value is maintained only in a range for the degree of stretching of 0.33 to 0.36%. This can hardly be guaranteed in practice, for example in acceleration and deceleration phases.

Incidentally, the fact that the results described are achieved with relatively few straightening rollers is noteworthy, so that the overall system is characterized by simple and cost-effective design.

Is worked in a variant with more than four straightening rollers, so at least the last four straightening rollers according to the invention individually adjustable in their wrap angles, so that a similar good-natured residual curvature behavior is achieved. In the case of the method according to the invention, the residual transverse curvature of the amount is significantly smaller than the residual longitudinal curvature for suitably selected angles of wrap. The residual longitudinal curvature of a panel cut out after straightening then corresponds approximately to a transverse curvature of the band measured in the stretch-bending machine under strip tension. Therefore, it is optionally proposed to measure at least the outlet side, the transverse curvature, to close from the measured value on the remaining longitudinal curvature and deviation from the desired value, the setting of the wrap angle and thus the positions to change until the desired residual longitudinal curvature corresponding transverse curvature sets.

A simple method is to vary the angle of wrap in the last elastic-plastic roller and thereby to shift the residual curvature curve shown in FIG. 3 upwards or downwards. Here is also a closed loop conceivable. Furthermore, it may be useful after Each elastic-plastic bend to measure the transverse curvature in order to optimize the setting of all wrap angles and to be able to compare with the calculation model. For this purpose, corresponding measuring devices can be provided, which are connected to a control and regulating device. In the figures, this is not shown. For example, with a finite element model, theoretically optimum transverse curvature can be predicted after each roll. Then the rollers can be set so that the measured and the calculated match as well as possible. Then one can assume that the actual straightening process differs only slightly from the theoretically calculated and therefore also the straightening result agrees well.

As already explained, the position-controlled adjustment of the straightening rollers (transversely to the direction of belt travel) preferably takes place by means of finely adjustable spindle lifting elements. Such a fine adjustment usually works with a setting speed of 2 to 3 mm / sec For the passage of a joint of two coils, such as a punched connection or a weld, it may be appropriate to open the stretch bender, that is, the roles are turned off. If the paths to be traveled are large, this process takes a relatively long time with the finely adjustable spindle lifting elements. For this reason, the upstream deflection rollers 4a and the downstream deflection rollers 4b are provided in the embodiment shown in FIG. In this way, the Anstellwege be shortened considerably.

Alternatively or additionally, it is possible to provide a quick adjustment in addition to the fine adjustment (via spindle lifting elements, for example). This possibility is recommended in particular in the embodiment of FIG. 1, but in principle also in the embodiment of FIG. 2 be provided. The straightening rollers are then additionally provided with a quick adjustment, for example with hydraulic or pneumatic cylinder actuators. It may be appropriate to provide a common Schnellanstellung for several straightening rollers. Thus, it may be useful, for example, in the embodiment of FIG. 1, to arrange the first straightening roller and the third straightening roller on a common upper frame, which can be adjusted with one or more cylinder actuators. Accordingly, the second straightening roller and the fourth straightening roller can be arranged on a subframe, which is likewise adjustable with one or more cylinder actuators. The quick setting can be done, for example, between two end stops for driving on and driving the Streckbiegerichtgerüstes. These possibilities are not shown in the figures.

Claims

1 . Method for the continuous stretch bending of metal strips, wherein a standing under a tensile stress below the elastic limit band is alternately bent around at least four straightening rollers in the plastic or elastic-plastic area and thereby undergoes plastic stretching, characterized in that the bending radii on each of the four straightening rollers individually and be set independently.

2. The method according to claim 1, characterized in that all four straightening rollers are adjusted positionally adjusted for adjusting the bending radii.

3. The method of claim 1 or 2, wherein the band is bent by more than four straightening rollers, characterized in that the bending radii at least at the last four straightening rollers (relative to the strip running direction) are set individually and independently, preferably by at least the last four straightening rollers are individually position-controlled.

4. The method according to any one of claims 1 to 3, characterized in that the positions of the straightening rollers are set with an accuracy, for example, control accuracy, which is an accuracy based on the Umschlingswinkel the tape to the straightening rollers of ± 0.05 ° or less, preferably ± 0.02 ° or less.

5. The method according to any one of claims 1 to 4, characterized in that the wrap angle of the band by one or more, preferably by all four straightening rollers 0.5 ° to 60 °, preferably 1 ° to 35 °.

6. The method according to any one of claims 1 to 5, characterized in that the degree of stretching is 0.1% to 1, 5%, for example 0.2% to 0.6%.

7. The method according to any one of claims 1 to 6, characterized in that the band tensile stress 10% to 90%, preferably 30% to 60% of

Elastic limit of the band or the strip material is.

8. The method according to any one of claims 1 to 7, characterized in that the distance between at least two (immediately) successively arranged straightening rolls with respect to the strip running direction at least 15% of the (maximum) bandwidth, preferably at least 30% of the (maximum) bandwidth , more preferably 50% of the (maximum) bandwidth.

9. The method according to any one of claims 1 to 8, characterized in that the distance between two (immediately) arranged one behind the other

Straightening rolls at least 150 mm, preferably at least 300 mm.

10. The method according to claim 8 and 9, characterized in that the distance between each two (immediately) successively arranged straightening rollers is provided in all four straightening rollers.

1 1. A method for the continuous stretch bending of metal strips, wherein a below a tensile stress below the elastic limit band is alternately bent around a plurality of straightening rollers in the plastic or elastic-plastic region and thereby undergoes a plastic stretching, in particular according to one of claims 1 to 10, characterized in that the distance in the direction of tape travel between at least two straightening rollers is variably adjusted.

12. The method according to any one of claims 1 to 1 1, characterized in that the setpoint values for the positions of the straightening rollers and / or the setpoint values for the wrap angle of the band around the straightening rollers are determined with a mathematical model which at least stresses in longitudinal and transverse the computational parameters are the band thickness, the modulus of elasticity, the transverse contraction index, the cyclic strength behavior of the belt, the belt tension, the roller radii and / or the geometry of the belt run around the rollers and / or the nominal values of the belt thickness and / or or the strength, for example, the yield strength processed.

13. The method according to claim 12, characterized in that the desired values are determined with the calculation model with the proviso that the residual longitudinal curvature and the residual transverse curvature becomes (approximately) zero.

14. The method according to claim 1 2, characterized in that the setpoint values are determined with the calculation model with the proviso that the residual transverse curvature becomes (approximately) zero and the residual longitudinal curvature assumes a defined value.

15. The method according to any one of claims 1 to 14, characterized in that after one or more straightening rollers, for example after the last straightening roller, preferably after each straightening roller, the transverse curvature of the band is measured over the bandwidth.

16. The method according to claim 15, characterized in that the regulation of the position or wrap angle takes place taking into account the obtained measured values for the transverse curvature.

17. The method according to claim 16, characterized in that the control is based on a calculation model which at least stresses in Longitudinal and Querhchtung taken into account as processing parameters, the strip thickness, the modulus of elasticity, the transverse contraction number, the cyclic strength behavior of the strip, the belt tension, the roller radii and the geometry of the tape run around the rollers processed, and a particular transverse curvature Bandrestlängskrümmung or Bandlängsquerkrümmung assigned.

18. Method according to claim 1, characterized in that the calculation model or models are based / are based on the finite element method, the optimal degree of stretching and / or .alpha. Being preferably determined on the basis of the maximum expected or pre-straightening band unevenness the optimal horizontal distances of the elastically / plastically acting straightening rollers are calculated according to the finite element method, which results in the minimum residual unevenness.

19. An apparatus for continuous stretch bending of metal strips (1) according to a method according to any one of claims 1 to 18, comprising at least four straightening rollers (2) around which under a tensile stress below the elastic limit band (1) in the plastic or elastic-plastic Area is alternately bent, and with at least one control and / or regulating device, characterized in that the Biegerad ien len len all four Richtrol (2) each nu nu are independently adjustable.

20. The apparatus according to claim 19, characterized in that all four straightening rollers (2) are connected to a control device and are positionally adjusted adjustable.

21. Apparatus according to claim 19 or 20, characterized in that the diameters of one or more and preferably all four straightening rollers (2) are 15 mm to 150 mm, for example 25 mm to 80 mm.

22. Device according to one of claims 19 to 21, characterized in that of the four straightening rollers (2) at least the last two straightening rollers (2), preferably the last three straightening rollers (2) are arranged directly behind one another without the interposition of other rollers.

23. The apparatus according to claim 22, characterized in that the four straightening rollers (2) are arranged directly behind one another without the interposition of other rollers.

24. An apparatus for continuous stretch bending of metal strips according to a method according to one of claims 1 to 18, with a plurality of straightening rollers (2) about which under a tensile stress below the elastic limit band (1) in the plastic or elastic-plastic region is alternately bent , in particular according to one of claims 19 to 23, characterized in that the distance between at least two straightening rollers (2) in the strip running direction (R) is variably adjustable.

25. The apparatus according to claim 24, characterized in that the position of at least one straightening roller (2), preferably all straightening rollers (2) along the strip running direction (R) is adjustable.

26. Device according to one of claims 19 to 25, characterized in that at least one straightening roller (2) upstream of an adjacent deflection roller (4, 4a, 4b) and / or downstream, wherein the deflection roller or the deflection rollers (4, 4a, 4b ) preferably at least three times the diameter, particularly preferably have at least ten times the diameter of the straightening roller.

27. The method according to claim 26, characterized in that the upstream deflection roller (4, 4a) and / or the downstream deflection roller (4,

4b) has a concave or convex roller contour.

28. The apparatus of claim 26 or 28, characterized in that the upstream deflection roller (4, 4a) and / or the downstream deflection roller (4, 4b) is equipped with a Rollenverbiegung in the horizontal and / or vertical direction.

29. Device according to one of claims 19 to 28, characterized in that the first straightening roller (2) is preceded by a tensioning roller or deflection roller, preferably a contour variable tensioning roller or guide roller, which is looped by the metal strip, for example by at least 120 °.

30. Device according to one of claims 19 to 29, characterized in that the straightening rollers (2) by means of actuators, for example Spindelhubelementen, are adjustable.

31. Device according to one of claims 19 to 30, characterized in that individual position adjustable straightening rollers (2) or a plurality of positionally adjustable straightening rollers (2) together are additionally provided with a quick adjustment.