EP0716998A2 - Device for laterally guiding a running material web - Google Patents

Abstract

The material is fed over a pair of parallel rollers (5,7) on a swivel mounting (8) about an axis (6) to one side of the system. A first alignment sensor (1) is positioned near the output roller, in the forward feed setting, and furthest away from the swivel axis. A second sensor (2) is mounted further down the feed direction and operates for the reverse feed direction. The reverse fluid control has the alignment sensor mechanically coupled to the swivel control - either directly or by virtual coupling. Alternately the sensor and the swivel control positions are monitored electronically.

Description

The present invention relates to a device for the lateral guidance of a running material web with a pivoting frame pivotable about an off-center pivot axis and a stationary web cantan run-out sensor at a short distance from the deflection roller remote from the pivot axis for obtaining a position deviation signal of the web running from this deflection roller for one on the Swing drive of the swing frame acting control loop.
Such a device is known from the article "Basic Techniques for Controlling Web Position" by Sorsen in "Automation", April 1966, p. 105 ff., Fig. 3 (b).

Such devices usually have two deflecting rollers carried by the swivel frame and only require a short inlet length because the swivel axis runs approximately in the plane of the surface line of the deflecting roller near the swivel axis, onto which the incoming material web section runs, so that this only has one torsion during the corrective swivels, but not one Undergoes offset.

The deflection roller, which is remote from the swivel axis and over which the web runs, also performs a lateral translation movement during the swivels, which causes an immediately effective proportional portion of the control intervention, while the angular rotation of the swivel frame brings the running belt into the desired position.

The known guiding devices with such swivel frames are only provided for one web running direction. However, it occurs in some applications that the web must also run in the opposite direction (in reverse operation) and web edge guidance is required or desired even in this operating state.

A complex solution to this task is to provide a swivel drive on both sides of the swivel frame and to have it act here to effect a lateral offset, and also to provide a stationary outlet sensor near the outlet point of both deflecting rollers. Depending on the direction of web travel, the swivel drive is then locked in the central position on the entry side and the associated web edge sensor is switched off, while the sensor and the swivel drive on the other side of the swivel frame effect the known regulation on the exit side. This solution is complex not only because of the need for two swivel drives, but also because simple and advantageous mounting and guide kinematics of the swivel frame cannot be used, as are known from DE-PS 26 35 631 or DE-PS 31 25 852. In these designs, the swivel frame is guided by sliding guide elements in such a way that it can only execute movements around a stationary instantaneous pole as a virtual swivel axis.

Another device for lateral guidance of running material webs intended for both running directions is known from DE-AS 21 37 706. In this case, two deflecting rollers are mounted in a swivel frame, the swivel axis lying centrally between the roller axes, namely intersecting the center of the plane defined by the roller axes at right angles. Fixed web edge sensors are arranged in the vicinity of both run-off points, the sensor detecting the running web section being active and the error signal for one Control process to eliminate the error provides.

With this solution, the design of the swivel frame and its storage is difficult and expensive. In addition, when the swivel frame is pivoted correctively, the incoming web section is also subjected to a lateral displacement, which results in mechanical stresses. This also creates an additional error in the inlet, which must be eliminated by the control. These less favorable conditions of the web run are equally present in both running directions. If one of the two running directions represents the predominant primary operation, this is subject to the mentioned disadvantage.

The above invention includes the knowledge that in most cases the use of devices for lateral material web guidance effective in both running directions is one of the running directions which is predominant and for this primary running direction the regulation should be effective which does not subject the incoming web section to lateral displacements and the like The control process is based on a lateral position signal generated by a fixed web edge sensor located near the discharge point.

For the secondary direction of travel, on the other hand, a lateral displacement of the incoming web section can be accepted, whereby for this case a control can be used for the lateral web guidance, as is known per se in rewinders, for example from the source cited at the beginning, "Basic Techniques for Controlling Web Position ", Fig. 6. In this operating state, the known and kinematically advantageous pivot frame with eccentric pivot axis is used in a new way and included in a control process.

The object of the present invention is therefore to provide a device for the lateral guidance of a running material web which can be operated while maintaining a simple and proven mechanical construction and known control quality in one running direction in the other running direction with a satisfactory result of the web lateral guidance.

Starting from the known design mentioned at the outset, the object is achieved by a web edge inlet sensor which is at least virtually connected to the side of the swivel frame remote from the swivel axis for obtaining a position deviation signal of the web approaching the deflection roller remote from the swivel axis for a control circuit acting on the swivel drive of the swivel frame.

The inlet sensor, which is effective in reverse operation, is rigidly attached to the swivel frame in the simplest form and thus detects the changes in the position of the monitored web edge relative to the side of the swivel frame remote from the swivel axis. In large systems, hydraulic or electrical tracking can be used instead of a rigid mechanical connection. However, a virtual connection is also possible, in which the web edge sensor is fixed in place, but its signal is superimposed by a signal for the lateral position of the side of the pivot frame remote from the pivot axis in such a way that a signal is obtained for only the relative changes mentioned.

It goes without saying that the swivel frame can also be constructed with only one deflection roller instead of two deflection rollers, in which case instead of the deflection roller near the swivel axis and away from the swivel axis, the surface lines of the one deflection roller on which the material web runs up or down, i.e. a swivel axis near it, must be considered and a surface line distant from the swivel axis. On the other hand The swivel frame can also have three or more deflecting rollers instead of two to increase the frictional engagement.

The invention is explained in more detail below by the description of an exemplary embodiment with reference to the accompanying drawing. This shows schematically a device for lateral guidance of a running material web for forward and backward operation.

On a fixed mounting frame 10, a swivel frame 8 is guided and mounted by means of sliding guide elements 13 such that it can execute swivel movements whose axis 6 runs eccentrically, approximately in the plane of the section of the material web 12 that runs in forward operation (arrow V). The swivel drive 9 is indicated as a hydraulic cylinder.

In the swivel frame 8, two deflection rollers 7 and 5 are mounted and the material web 12 rotates in front of and behind the deflection rollers of the swivel frame, fixed rollers 11 and 4. In forward operation with the direction of travel V 11 is the fixed inlet roller and 4 the fixed outlet roller.

In the vicinity of the discharge point of the material web from the deflection roller 5 remote from the swivel axis, a web edge sensor 1 is fastened in the mounting frame 10 and is only active in the forward mode, i.e. if the material section monitored by him is the outgoing section, and which therefore represents a discharge sensor 1.

A web edge sensor 2 is held on the swivel frame 8 by means of a carrier 3 in such a way that it is in the vicinity of the fixed roller 4. This sensor is only active in reverse operation (arrow R) and then monitors the incoming section of the material web, which is why it is referred to as the inlet sensor 2.

In forward operation with the web running direction V, the sensor 1 is active and supplies the position deviation signal, which is processed in a control circuit which acts on the swivel drive 9 as an actuator and regulates any web position deviations that occur. This operation does not differ from the operation known and customary with these swivel frame side guiding devices.

In reverse operation, the outlet sensor 1 is switched off and the inlet sensor 2, which is now monitoring the incoming material web section, is switched on, which due to its mechanical connection with the swivel frame 8 participates in its lateral movements and detects lateral position deviations occurring in the inlet before they reach the swivel frame 8. The drive 9 is controlled in such a way that the inlet sensor 2 and thus the run-up point on the deflection roller 5 remote from the pivot axis follows the position changes of the web edge, whereby the position error is eliminated without success, i.e. the web edge position behind the pivot frame 8, being checked. This operating state is therefore a controller.

The swivel drive 9 is indicated here in the form of a hydraulic cylinder; however, an electromechanical drive or another suitable swivel drive can be used.

It goes without saying that instead of the mechanical connection of the inlet sensor 2 to the swivel frame 8 in large web guiding systems, an electrical or hydraulic tracking of the inlet sensor 2 can also be used, that is to say the connection is established in another suitable way, apart from the virtual connection already described .

It is also understood that instead of a web edge guide A web center guide can be implemented with one sensor each for a web edge, in which case an exit sensor and an inlet sensor are then to be provided for each web edge. Instead of sensor 1, two sensors would have to be used, one for the right and one for the left web edge. Likewise, a right and a left web edge sensor would then have to be provided instead of sensor 2.

The sensors themselves can be of any suitable type, for example also diode line cameras.

Claims (5)

Device for the lateral guidance of a running material web (12) with a swivel frame (8) which can be swiveled about an eccentrically located swivel axis (6) and a stationary web edge run-out sensor (1) at a short distance from the deflection roller (5) remote from the swivel axis to obtain a position deviation signal from this deflecting roller web (12) for a control circuit acting on the swivel drive (9) of the swivel frame (8),
characterized by a web edge inlet sensor (2) at least virtually connected to the side of the swivel frame (8) remote from the swivel axis for obtaining a position deviation signal of the web (12) approaching the deflection roller (5) remote from the swivel axis for a web drive (9 ) of the swivel frame (8) acting control circuit. Apparatus according to claim 1, characterized in that the inlet sensor (2) is arranged at a greater distance from the deflection roller (5) remote from the web edge than the outlet sensor (1). Apparatus according to claim 2, characterized in that the inlet sensor (2) is arranged in the vicinity of a fixed roller (4) upstream of the swivel frame (8) in reverse operation (R). Device according to one or more of the preceding claims, characterized in that the inlet sensor (2) is arranged in a fixed position and its signal is combined with a signal for the side position of the side of the pivot frame (8) remote from the pivot axis, from this a signal for the web edge position relative to the pivot axis remote Swing frame side determined and this is used to control the swivel drive (9). Device according to one or more of the preceding claims, characterized by mounting and guiding the swivel frame (8) on a mounting frame (10) by means of sliding guide elements (13) known per se in such a way that the instantaneous pole of the swivel frame movement remains stationary and with the swivel axis ( 6) coincides.

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