EP3177554A1 - Web guiding device and device for processing a web of material - Google Patents

Abstract

The invention relates to a web guiding device (3) for guiding a web of material (2), in particular film web, comprising a first frame element (31) and a second frame element (32) which - are mounted on a first shaft (33) in such a way as to be pivotable in first end regions (311, 321), - are connected in the second end regions (321, 322) by means of a rotatably mounted web guiding roll (34), and - are connected by means of a second shaft (35) that is attached to the first shaft (33) by means of a fastening element (37).

Description

 Web guiding device and device for processing a

 web

The invention relates to a web guiding device for guiding a

Material web, in particular a film web, and a device for processing a material web, in particular a film web.

When processing material webs, such as film webs or paper webs, in embossing device, printing devices or the like, the material webs are usually provided on coils, for

Unwinding processing, fed via pulleys to the processing position and sometimes rewound.

Is the web of material when providing a new coil oblique or

asymmetrically retracted, different tensile forces act on opposite edge regions of the material web, which can lead to buckling, unfolding or tearing of the material web. In some cases, however, an asymmetric, ie oblique insertion of a material web may also be desirable, for example, to guarantee that an edge region of the material web is under high

Material tension - and thus smooth - is to enable in particular a reliable reading of registration marks or the like.

Regardless of whether an asymmetrical intake of the material web is targeted or undesirable, it is necessary to correct such an asymmetry as early as possible in order to avoid the above-mentioned defects.

It is known to use web guide rollers with integrated differential gear to compensate for an oblique feed. Also, a detection of an oblique intake and an active correction of the web guide by active actuating means, such as pneumatic, hydraulic or electrical

Stellzylinder or the like, are known. However, such devices are expensive, expensive to buy and prone to failure.

To compensate for symmetrical web tensions, as they can occur even with straight entry of the web, for example, due to an ovality of the coil, so-called dancers are also known. These oscillate under alternating tensile stress of the web perpendicular to their extension direction and thus compensate for the tension again. However, they are not suitable for compensating an oblique intake. The object of the present invention is therefore to provide a web guiding device and a device for processing a material web, by means of which an oblique intake of a material web can be corrected in a simple, cost-effective and reliable manner. This object is achieved by a web guiding device having the features of patent claim 1 and by an apparatus for processing a material web having the features of patent claim 13.

Such a web guiding device for guiding a material web, in particular a film web, comprises a first and a second web

Frame element which: are pivotally attached to a first axis in respective first end regions,

 in respective second end regions via a rotatably mounted

 Web guide roller are connected and

 are connected via a second axis, which by means of a

 Fixing element is connected to the first axis.

Compared to a usual dancer, only to compensate

symmetrical web tension of the web, i. is designed for not obliquely or asymmetrically incoming material webs, by the second axis and the fixing element is a point of attack for asymmetrically acting forces, as they may arise when obliquely pulling a web of material created. Under axes are understood to mean components that have a

Can support rotational movement of other components. Axes may be round in cross-section but also shaped differently, where appropriate, the cross-sectional profile may vary over the longitudinal extent of an axis.

Acts on the one side edge of the web-facing side of the

Web guide roller of a stronger tensile force than on the opposite side, This creates a moment around the fixing element. This leads to a

Twisting of the axles, the frame elements and the

Web guide role formed frame around the fixing element. As a result, the web guide roller is deflected in the direction of stronger traction. This relieves the side of the material web which is under greater tension and compensates for the asymmetry created by the oblique intake.

The web thus leaves the web guide roller straight and with balanced tension. For this purpose, no external control, so no external sensor and / or actuator is necessary, but the necessary forces to correct the web run are provided solely by the tension of the material web available. The desired twisting of the web guiding device can already be achieved if the frame elements and / or the second axle are designed to be flexible. The necessary flexibility can be achieved by suitable choice of material and by adjusting the material thickness as a function of tensile forces occurring in a specific processing machine.

For example, the frame elements and / or the second axis can be made of one or more elastomeric materials in one piece or in several parts. It is also possible to form only a part of the frame elements and / or the second axis of an elastomeric material, which part then provides the necessary flexibility. For example, only the joints between the frame members and the second axis and / or the joints between the frame members and the web guide roll may be made of an elastomeric or partially elastomeric material Be formed bearing element. It is also possible that only the second axis is formed of an elastomeric and therefore twistable material and / or the second axis of twisted or stranded sub-elements of elastomeric and / or non-elastomeric materials is formed. The elasticity of the elastomeric material and / or the proportion of elastomeric materials on the overall construct of the second axis determines their overall Verwindbarkeit and thus allows the adjustment of the flexibility of the web guiding device according to the invention. However, it is alternatively expedient if the web guide roller and / or the second axle are attached to the frame elements by means of articulated bearings.

Such spherical bearings allow a pivoting movement of the web guide roller or the second axis about the respective bearing point and thus allow the distortion of the device, without unnecessary material stresses are introduced into this. This increases the life of such

Contraption.

Preferably, the joint bearings are further designed as a ball bearing. Thus, all necessary degrees of freedom are provided with a simple and stable construction of the bearing.

It is also advantageous if the second axis is arranged between the first axis and the web guide roller. The arrangement of the second axis between the other two transverse elements of the device is in cooperation with the fixing element of the desired

Force application point created. It is particularly expedient if a ratio between the distance of the second axis to the first axis and the distance of the second axis to the web guide roller of 1: 3 to 1: 10, preferably 1: 4 to 1: 7, particularly preferably 1: 5 to 1: 6.

Preferably, the second axis is located closer to the first axis than to the web-guiding roller.

It is also advantageous if the fixing element is arranged to be movable on the first axis in the axial direction. The one described above

 Traction compensation takes place in particular in the middle positioning of the

 Fixing element with respect to the first and the second axis symmetrically.

If the fixing element displaced from the center position, so if desired, a defined asymmetry of the tensile forces on the

opposite sides of the film web are set, as in this

Case different lever paths between the opposite sides of the

Web guide roller and the fixing element are present.

It is expedient if the fixing element can be fixed to the first axis by means of a locking element, so that a desired

Setting the fixing element can be secured.

Preferably, the fixing element is in an operating position of

Web guiding device centrally between the first and the second

Frame element set on the first axis. In this way, the complete compensation of asymmetrical tensile forces described above can be accomplished, so that the material web leaves the web guide roller free of transverse stresses. By a central position is meant the distances between the fixing element and the frame elements do not differ by more than 20%, preferably not more than 10%. Furthermore, the fixing element on the second axis is preferred

stored floating. This also facilitates the desired twisting of the device without unduly stressing its materials.

It is particularly expedient if the fixing element is mounted by means of a bearing sleeve on the second axis. Thus, a certain sliding of the fixing element is made possible, without leading to tilting or the like.

Preferably, an inner diameter of the bearing sleeve by 5% to 20%, preferably from 10% to 12%, greater than an outer diameter of the second axis. Thus, the range of motion of the bearing sleeve and thus the ease of twisting the device can be adjusted.

It is also expedient if a sliding resistance between the fixing element and the second axis by means of another

 Locking element is adjustable. As a result, it can be influenced how quickly the twisting of the device follows a changed force distribution on the web guide roller, so that possibly occurring vibrations or oscillations of the device can be damped or completely avoided

In an apparatus for processing a material web by means of a

Web guiding device of the type described, it is advantageous if the first axis of the web guiding device fixed to the frame on the device is fixed. This allows the desired relative movement of the

Web guide roller to the web in a twist of the

Web guiding device due to asymmetrical tensile forces. Further, it is advantageous if the web guide device is arranged so that the web guide roller of the web guiding device in a

Hibernation and / or symmetrical application of force

Web guide roller is arranged perpendicular to a conveying direction of the material web and in the conveying plane of the material web. In this state, no undesired forces are introduced into the material web by the web guiding device.

In this case, the device is preferably designed as an embossing device, in particular a hot stamping device, and / or as a printing device. However, the described principles are applicable to all types of devices in which webs of material are processed.

The invention will now be explained in more detail with reference to exemplary embodiments. Show it

Fig. 1 is a perspective view of a rolling device for a

 Material web with an embodiment of a web guiding device for compensating an oblique

 Fabric intake;

Fig. 2 The unwinding device of Figure 1 in side view.

Fig. 3 is a front view of the web guiding device of

Unwinding device according to FIG. 1; 4 shows a side view of the web guiding device according to FIG. 3 with symmetrical web feed;

5 shows a side view of the web guiding device according to FIG. 3 with left-sided asymmetrical web feed; Fig. 6 is a side view of the web guiding device according to FIG. 3 in the case of the asymmetric web feeder on the right side.

Figures 1 and 2 show the responsible for the web provision part of a device 1 for processing a material web 2. The material web 2 is provided on a spool 21 which is received on a roll 1 1 of the device 1. Via a plurality of deflection rollers 12, which are arranged fixed to the frame and rotatable on a frame 13 of the device 1, the unwound material web 2 is fed to the processing. The real one

Processing device, such as a printing or embossing station, is not shown in the figures.

If, when inserting a new coil 21, the material web is introduced obliquely, so when pulling the material web 2 different tensile forces on the opposite sides 22, 23. This can lead to web breaks that make a standstill of the device 1 necessary.

To prevent this, the device 1 comprises a

Web guiding device 3. This comprises two frame elements 31, 32, which are attached with their respective end portions 31 1, 321 pivotally mounted on a first axis 33. The axis 33 is attached to an end portion 331 on the frame 13 of the device 1 and not rotatable itself. At the opposite end regions 312, 322, the frame elements 31, 32 are connected to one another via a web guide roller 34, over which the material web 2 is guided during operation of the device 1. A further axis 35 also connects the frame members 31, 32 and extends parallel to the axis 33 and the web guide roller 34. Both the axis 35 and the web guide roller 34 are hinged to the frame members 31, 32 with ball bearings 36. The axis 35 and the web guide roller 34 can thus not only rotate about their respective extension axes, but are also tiltable relative to the frame members 31, 32.

The axis 35 is also connected by means of a fixing element 37 with the axis 33. The fixing element 37 consists of two halves 371, 372, which can be fixed by means of screws 373 and 374 against each other and the respective receptacles 375, 376 for the axes 33, 35 have. The axis 35 is received with a sliding sleeve 38 in the fixing member 37, the inner diameter is preferably greater by 5% to 20%, more preferably by 10% to 12% greater than the outer diameter of the shaft 35. Depending on the game of recordings 375, 376 and according to the tightening force of the screws 373, 374 can thus also be determined how firmly the fixing element 37 sits on the axes 33, 35.

If the screws 373, 374 loosened, so the fixing member 37 can be moved on the axes 33, 35. The figures show the fixing element 37 in a lateral position. During operation of the device 1, it is expedient to position the fixing element 37 centrally on the axes 33, 35, so that the respective distances between the fixing element and the frame elements 31, 32 in FIG Are substantially the same and preferably not more than 20%, more preferably not more than 10% differ from each other. Thus, the desired symmetrical orientation of the web guide roller 34 to

Material web 2 ensured.

If the material web 2 is inserted obliquely into the device 1, the tensile forces acting on the material web 2 are not symmetrical. Traction and web speed therefore differ for the two sides 22, 23 of the web.

As soon as the material web 2 is guided over the web guide roller 34, different forces also act on the opposite sides of the web guide roller 34. The frame elements and the second axis can now act as levers which transmit these forces to the fixing element 37. This results in a torque around the fixing element 37.

Since the first axis 33 is mounted fixed to the frame with the end portion 331, this does not lead to movement of the axis 33 itself. As can be seen in FIGS. 5 and 6, however, the frame elements 31, 32 can pivot about the axis 33 and move relative to their axis Fig. 4 shown balance position are deflected. The axis 35 and the web guide roller 34 can follow this movement and thereby tilted due to their storage by means of the ball bearings 36 obliquely to the axis 33 and thus also obliquely to the original web guide plane.

In other words, therefore, the web guide roller 34 can follow the asymmetrical forces caused by an obliquely inserted material web 3. The web guide roller 34 is thereby further deflected until the on their End regions acting forces are the same again, so no more moment is transferred to the fixing member 37. As a result, the faster-running side edge of the material web 2 is braked and accelerates the slower-running side edge of the material web 2. The oblique entry of the

Material web 2 is thus corrected and the material web 2 runs evenly through the device 1. In the course of this correction, the web guide roller 34 returns to the neutral position shown in FIG. 4 and remains in this, as long as the web 2 continues to run straight.

Overall, so a simple correction of an oblique web feed can be achieved, which does not require any active adjusting or sensor devices. The device is thus particularly inexpensive and failsafe.

LIST OF REFERENCE NUMBERS

1 device

 1 1 roll

 12 pulley

 13 frames

 2 material web

 21 coil

 22 side edge

 23 side edge

 3 web guiding device

31 frame element

 31 1 end area

 312 end area

 32 frame element

321 end area

 322 end area

 33 first axis

 331 end area

 34 web guide roller

35 second axis

 36 ball bearings

37 fixing element

 371 half

 372 half

 373 screw

 374 screw

375 recording Recording sleeve

Claims

Claims

Web guiding device (3) for guiding a material web (2), in particular a film web, with a first and a second frame element (31, 32), which

 - in respective first end regions (31 1, 321) are pivotally attached to a first axis (33),

 - Are connected in respective second end regions (321, 322) via a rotatably mounted web guide roller (34) and

 - Are connected via a second axis (35) which is connected by means of a fixing element (37) with the first axis (33).

Web guiding device (3) according to claim 1,

 characterized,

 in that the web guide roller (34) and / or the second axle (35) are attached to the frame elements (31, 32) by means of articulated bearings (36). 3. web guiding device (3) according to claim 2,

 characterized,

in that the joint bearings (36) are designed as articulated ball bearings. Web guiding device (3) according to one of Claims 1 to 3, characterized

 in that the second axis (35) is arranged between the first axis (33) and the web-guiding roller (34).

5. web guiding device (3) according to claim 4,

 characterized,

 a ratio between the distance of the second axis (35) to the first axis (33) and the distance of the second axis (35) to

 Web guide roller (34) of 1: 3 to 1: 10, preferably from 1: 4 to 1: 7, particularly preferably from 1: 5 to 1: 6.

Web guiding device (3) according to one of the preceding

 Claims,

 characterized,

 that the fixing element (37) on the first axis (33) in

 Axially movable.

Web guiding device (3) according to claim 6,

 characterized,

 in that the fixing element (37) can be fixed to the first axis (33) by means of a fixing element (374). 8. web guiding device (3) according to claim 7,

 characterized,

that the fixing element (37) in an operating position of the Web guiding device (3) is fixed centrally between the first (31) and the second frame member (32) on the first axis (33).

Web guiding device (3) according to one of the preceding

 Claims,

 characterized,

 in that the fixing element (37) is attached to the second axis (35)

 is floating. 10. Web guiding device (3) according to claim 9,

 characterized,

 in that the fixing element (37) is mounted on the second axis (35) by means of a bearing sleeve (38).

Web guiding device (3) according to claim 10,

 characterized,

 in that an inner diameter of the bearing sleeve (38) is greater than an outer diameter of the second axis (35) by 5% to 20%, preferably by 10% to 12%.

Web guiding device (3) according to one of claims 9 to 11, characterized in that

a sliding resistance between the fixing element (37) and the second axis (35) can be set by means of a further locking element (373). A device (1) for processing a material web (2), in particular a film web, with a web guiding device (3) according to one of claims 1 to 12.

Device (1) according to claim 13,

characterized,

the first axis (33) of the web guiding device (3) is secured to the device (1) in a frame-fixed manner.

Device (1) according to claim 13 or 14,

characterized,

in that the web guiding device (3) is arranged such that the web guiding roller (34) of the web guiding device (3) is in a state of rest and / or symmetrical loading of the web guiding roller (34) perpendicular to a conveying direction of the web guiding roller (34)

Material web (2) and in the conveying plane of the material web (2) is arranged.

Device (1) according to one of claims 13 to 15,

characterized,

that the device (1) as an embossing device, in particular

Hot stamping device, and / or designed as a printing device