The invention relates to a method for braking a metal strip which runs off from an unwinding reel and runs onto a winding-up reel again. The invention also relates to a unit for carrying out the method, in which unit the braking is performed by means of an eddy-current brake. In this case, the eddy currents to be induced are generated by a rotating magnet system.
During the lengthwise division of a rolled metal strip using circular blade cutters, it is known to use braking assemblies which are arranged downstream of the circular blade cutters in the running direction of the strip and which, if required, brake the running metal strip by means of frictional force and in as slip-free a manner as possible.
In known units for lengthwise division of a strip, the braking assembly comprises a main brake and/or a preliminary brake. The main brake comprises groups of individually braked rings around which the sections, which are divided lengthwise, of the strips are wrapped in the manner of an S-shaped set of rollers. A preliminary brake is also provided in order to transmit a braking torque from these braking rings onto the sections. A suitable preliminary brake is an eddy-current brake. However, to date eddy-current brakes have the disadvantage that they can apply a sufficient braking action only in the case of highly conductive metal strips such as aluminum or non-ferrous metal.
In a known unit for lengthwise division of strips according to DE-A 23 06 029 for the lengthwise division of a rolled metal strip, a two-stage braking assembly was arranged downstream of a cutter fitted with circular blade disks. This assembly has disadvantages and exhibits increased wear, does not prevent the surfaces of the metal strip from being scratched and does not provide sufficient lateral guidance for the metal strip.
In order to eliminate these disadvantages, the invention according to DE 195 40 748 C2 aims to provide a unit for the lengthwise division of strips with braking means, in which pressure-exerting means act on the sections in the wrapping region of the braking rings, said pressure-exerting means acting on the sections in a slip-free manner either without contact or with contact on the side facing away from the braking rings, both with and without transmission of a braking force.
The present invention aims to preclude this approach on account of the relatively complicated elements of the braking assembly and instead examine the extent to which following the operating principle of the eddy-current brake leads to a usable solution for braking running metal strips.
Analysis of the implemented prior art shows that attempts have already been made, in accordance with the teaching as per DE 195 24 289 C2, to design an apparatus for braking electrically conductive strips by means of eddy-current effects, in which the magnetic field-generating device comprises at least one magnet roller which can rotate in the opposite direction to the conveying direction.
Although this solution appears to be heading in the right direction, it prevents technically/technologically usable implementation at the same time due to the further refinements, such as
In practice, it has disadvantageously been found that contactless introduction of the braking torques by the induced eddy currents from rotating magnet rollers cannot exert any actual braking action. The (variable and, on account of the eddy currents, also varying) distance of the magnet rollers prevents the effective introduction of braking torques.
This is demonstrated by the following effects:
When a magnet roller is used, the problem arises that the strip is pushed out of the magnetic field and the eddy-current brake is ineffective. If, in contrast, two magnet rollers are provided, the magnet systems influence one another (possibly with disadvantageous heating), as a result of which no mechanical force can be transmitted to the strip and rotation may even occur in the longitudinal direction and, given a small distance, the strip rubs against the magnet roller and also, given a large distance, a braking action is likewise not transmitted.
Therefore, the problem of wanting to manage without additional braking means is not solved by the use of magnet rollers as opposed to static eddy-current generators.
Even developing the teaching, according to the patent, of DE 195 24 289 C2, for example with regard to the lower second magnet roller, no approach can be found for avoiding the described problems and disadvantages; instead, this is accompanied by the lower magnet roller acting as a virtual abutment face on account of the tendency of the strips to rotate about the axis in the conveying direction and not fulfilling the intended function anyway.
Furthermore, the use of two magnet rollers shows, with regard to the variable distance, that, given a small distance, the strip may be damaged and, given a large distance, an effective braking force is not applied and/or an oversized magnet system is required, on account of the excessively small magnetic field.
The object of the invention is therefore to provide a method and a unit for braking a metal strip, which runs off from an unwinding reel as a coil and runs onto a winding-up reel again, by means of a braking assembly with an eddy-current brake as a rotating magnet system, which unit firstly ensures that the surface of the metal strip is not damaged and secondly exerts a braking force on the metal strip with full effect. In this case, additional brakes should be dispensed with, the unit should be of simple design overall and the braking action should be performed on one side in a contactless fashion. The intention is for the current, which is induced in the magnetic field by the magnetic alternating field in the metal strip to be braked (as an electrical conductor), to generate a counter-torque on the metal strip; it was previously not possible to use this action as a braking torque for units of the type mentioned in the introduction without disadvantages.
According to the invention, this is achieved in accordance with the method having the features of claims 1 to 12. A unit which exhibits the features of claims 13 to 25 is proposed for carrying out the method.
Even if the invention with the rotating magnet system uses the part of a principle already disclosed according to DE 195 24 289 C2, the present inventive measure is not suggested. A usable solution can be realized only on account of the invention in a surprising and effective manner by means of the principle of a contact-making abutment as a mating roller which is arranged beneath the metal strip.
To date, it has not been possible to generate, in a practical and space-saving manner without further braking assemblies, an effective counter-tension with a complete braking action on the metal strip on account of the counter-torque induced from the torque of the eddy current solely with a rotating magnet system: the solution according to DE 195 24 289 C2 had to be abandoned.
Overall, the following advantageous features and effects, which are related to the above-described invention and likewise cannot be found in the teaching of the prior art closest to the present invention, can be used:
The invention which is therefore provided in a complex respect can be used both for simple unwinding/winding-up units for metal strips and also for units for lengthwise division of the type described in the introduction.
The previous disadvantages of eddy-current brakes in any case, and the non-operation of rotating magnet systems as eddy-current braking systems in particular, are eliminated by the invention. Eddy-current braking by means of rotating magnet systems can therefore also take over the function of a single main brake, without having to act only as a preliminary brake.
The invention is explained in greater detail using an exemplary embodiment. In the drawings
In order to brake the metal strip 1, a braking assembly 3 is provided as an eddy-current brake 3.1 which uses a rotating magnet system 3.2 whose speed can be set and which is arranged above the metal strip 1 on one side in a contactless fashion. A counter-torque which is able to deploy the fully required braking force on its own is now generated in the running metal strip 1 by the rotating magnet system 3.2 as a result of the current induced by the magnetic field.
A prerequisite for this is that an abutment 4 for counteracting the deviation or ensuring a (contactless) distance a of the metal strip 1 in relation to the rotating magnet system 3.2 is provided beneath the metal strip 1. According to
The rotation speed of the rotating magnet system 3.2 can be set. In order to realize all the action options of the rotating magnet system 3.2 as a braking assembly, the physical position of said rotating magnet system in relation to the metal strip 1 can be adjusted.
An optional variant of the invention may also involve the rotating magnet system 3.2 being surrounded by a respective drum (roll casing) 3.2.1, with the magnet system 3.2 being driven at a high speed and a higher speed than that of the drum 3.2.1.
In this case, it is possible to steplessly set the rotating magnet system 3.2 in the drum 3.2 in an eccentric manner, about the center point of the respective drum 3.2.1, such that it can pivot and/or such that it can be radially adjusted, and to provide the distance up to a contactless distance between the magnet system 3.2 and the drum 3.2.1 in a steplessly set manner.
According to
As can be seen from
A frequency converter (not illustrated), a control loop 5 corresponding to
A frequency converter (not illustrated), a control loop 5 corresponding to
With this embodiment of a unit, the method according to the invention can attain the used eddy-current brake 3.1 as a main brake. The entire braking action is generated solely by the rotating magnet system 3.2 by means of the mating roller 4.1 and exerted on the running metal strip 1 as a counter-torque.
Overall, the disadvantages of the prior art described in the introduction, such as scratching of the surfaces of metal strips, for example in the case of anodized aluminum strips, are eliminated because the braking action firstly can be set on one side in a contactless fashion and can be exerted with full effect on the metal strip 1 without S-shaped wrapping-around means and secondly is generated solely by the rotating magnet system 3.2 by means of the mating roller 4.1.
Furthermore, the method is executed such that the braking action can be set and therefore also can be controlled by the rotation speed of the respective magnet system 3.2 independently of the speed of the metal strip 1.
In accordance with the claims, other forms of the method can also be implemented.
According to the method, this can be performed by the local adjustment of the respective magnet system 3.2 independently of the speed of the metal strip 1. In the process, the local adjustment of the respective abutment 4.1 can also be set or controlled independently of the speed of the metal strip 1.
The method and the unit according to the invention provide the option of using the rotating magnet system 3.2 to implement a computer-assisted program for the open-loop control or rather closed-loop control of braking of the rolled metal strip 1, which program optionally or cumulatively comprises the program steps
In this case, the control loop 5 can be used which, in accordance with
The method uses the frequency converter for setting the rotational speed of the rotating magnet systems 3.2.
The method is formed by
Finally, it is therefore possible, in practice, to control the induced braking force by fine adjustment of the rotational speed of the pole drum 3.2.4 of the rotating magnet system 3.2, it being possible to variably set the rotational speed by means of the frequency converter.
The distance of the mating roller 4.1 in relation to the rotating magnet system 3.2 can likewise be variably set after the presetting operation by means of an electromotive apparatus (not illustrated).
The preselection program according to the claims integrates a data calculation from the input of strip thickness, strip width, material, number of items and desired strip tension in order to determine the distance of the mating roller 4.1 and/or the frequency (rotational speed) of the rotating magnet system 3.2. Therefore, the frequency, for example, would have to be changed if it is outside the range of 40-60 Hz.
After the unit is started (beginning of production), the frequency converter is controlled by measuring the strip tension. In this case, the restraint tension corresponds to a reduction in the braking force/strip tension by changing the distance and/or the rotational speed starting from a strip speed which is less than the tip speed (for example, approximately 10 m/min). This provides the advantage of less heating of the metal strips 1 by the rotating magnet system.
The open-loop controller 6.2.2 comprises the frequency converter and the closed-loop control system 5.1 with the strip-tension sensor 5.2, the PLC 6.1, the open-loop control means, for example a pneumatic means 6 for setting the mating roller 4.1, the input module 6.2 when data is interchanged with the main controller (not illustrated) of the unit (definition as interface), as a result of which no separate input module is required.
A dedicated switchgear cabinet 6.2.1 is feasible, in which the inputs provided are the input module 6.2 with data interchange, a supply line (power supply), a measurement line for strip-tension sensors and a measurement line for the strip speed. Outputs are provided to pneumatic valves 3.4.1, to the actuating motor and to the supply line for the motor 3.4. The input data (as setpoint values) and the measurement data (as actual values) appear on the display which displays information.
Compared to the solution according to DE 195 24 289 C2, which, however, constitutes an apparatus for braking electrically conductive strips by means of eddy-current effects which cannot be used in practice because a further magnet roller which can rotate in the opposite direction to the conveying direction was assigned to the magnetic field-generating device, the invention, according to which an abutment 4 for counteracting the deviation or ensuring a (contactless) distance a of the metal strip 1 in relation to the rotating magnet system 3.2 is provided beneath the metal strip 1, presents a solution which has proven successful in practical tests and functions in a surprisingly simple manner.
Number | Date | Country | Kind |
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10 2004 061 174 | Dec 2004 | DE | national |
10 2005 036 570 | Aug 2005 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/DE2005/002199 | 12/6/2005 | WO | 00 | 6/14/2007 |
Publishing Document | Publishing Date | Country | Kind |
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WO2006/063559 | 6/22/2006 | WO | A |
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Number | Date | Country | |
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20090026303 A1 | Jan 2009 | US |