EP1314668A2 - Apparatus for transporting web material - Google Patents

Abstract

The machine for the transport of strip materials (1), and especially cigarette paper, has a moving tensioner (8,10) to deflect the paper path and keep the paper taut. The drive (12) for the tensioner applies a force on it at a constant level, independently of its position. The paper tension control (2) sets the operation of the tensioner drive so that its position and the driving force are independent of each other to maintain a constant paper tension. The driving force is reduced on detection of a paper irregularity, e.g. an adhesive join, and the tensioner position is set according to the speed of paper travel.

Description

The invention relates to a device for transporting ribbon or strip Material, in particular wrapping material or covering paper for rod-shaped articles the tobacco processing industry, through a processing device, with a tension element movable at an angle to the direction of transport of the material, over which the material is guided in order to generate a tensile stress the material deflect from its path of movement, and with a drive device for Movement of the tension element and a method for regulating the tension in a band or strip material to be transported, in particular wrapping material or covering paper for rod-shaped articles of the tobacco processing industry Industry, particularly using the aforementioned device, in which the material is applied at an angle to its transport direction is going to generate a tension from its trajectory to be deflected.

In the tobacco processing industry, it is known that topping strips or Covering strip sections, which are usually made of more or less stiff paper, Cork film or similar materials exist, for example, mouthpiece sleeves for Rod-shaped smoking articles are made or mouthpieces such as filters and the like are encased and associated with cigarettes. The covering strips are made from a covering strip bobbin subtracted and then deflected over an edge of a crusher, glued and separated into individual sections.

The processing device through which the material with the help of the present device is transported, for example, have such a crusher or consist of such a crusher. Additionally or alternatively, that can Material processed otherwise in the processing device, for example perforated and / or printed.

In order from such a covering strip or from individual covering strip sections a perfect winding or a perfect wrapping of the rod-shaped As is well known, the rigidity of the covering strip is guaranteed reduces that the covering strip before it is finally shaped its

Inner surface over a relatively sharp, knife-like edge of a usually one Processing device forming crusher is pulled, causing the covering strip is pre-curved at the same time. Such a diversion around a crusher always causes a very heavy load on the covering strip, that of this load in particularly critical phases, e.g. when accelerating during the start-up process of the production machine, or at critical points, such as. at glue points, has not grown.

In order to generate the required tension in the material, it is used as a tension element usually uses a so-called dancer roller over the material to be led. The dancer roller is rotatably mounted on one end of a boom, while the boom with its other end on the device is pivotally arranged. By pivoting the dancer roller accordingly the material is deflected from its path of movement, creating a corresponding Tension occurs in the material. Here is the swiveling boom usually resiliently biased to its maximum pivot position. dancer rolls of the type described are, for example, in DE 40 08 475 A1 disclosed device provided.

In the case of a device of the type mentioned at the outset, the material is broken and depending on that, the cigarette quality at the crusher is crucial on the selection and arrangement as well as on the control of the individual Influenced transport elements, the covering paper feed a stable position Paper guidance regardless of the quality of the topping paper reels and a constant paper tension when breaking regardless of the setting one Bobbin brake should ensure.

DE 199 28 867 A1 therefore describes a transport device for one of a strip of wrapping material pulled off the bobbin of the tobacco processing industry proposed, which has a first and a second tension roller device. The first draw roller device guides the covering paper strip pulled off the bobbin in a loop storage. The second draw roller device pulls the Tipping paper strips from the loop storage via a crusher. Between the crusher and the exit of the loop storage is also a deflection roller arranged, which can be acted upon by a controllable negative pressure, whereby the tensile stress of the strip fed to the strip crusher on constancy is regulated. Accordingly, in this known device, the through a controllable negative pressure acting deflection roller as a tension control device.

Even if the known devices described above are in practice have proven well, the present invention proposes in a device of type mentioned to design the drive device such that it on the tension member exerts a force regardless of the position of the Tension member is adjustable to a substantially constant value.

The invention thus allows the tension in the material to be regulated to one desired constant value and can be used in all areas of a machine Find application where material in strip or strip form is transported and processed. This is done by moving the tension member Material brought out of flight and around one end of the tension member diverted.

In a preferred embodiment, the train control device for control of tension in the material, the tension control device controls the Drive device such that the force exerted on the tension element and the position of the tension member independently of each other a predetermined value can be regulated.

The tension control device usually has a device for detection discontinuities such as Glue points in the material, so that with such Execution of the tension control device based on the drive device the tension element exerted force compared to that for normal operation set value is reduced if the detection device has a discontinuity in the material. This contributes to the fact that was previously established Invoice that the material at points of discontinuity such as Glued spots, weakened is and therefore in particular a deflection around a crusher very high stress on the material at such critical points Has.

The tension control device preferably deactivates the control of the position of the tension element when regulating the drive device to the Tensile force exerted on a reduced value.

Usually at least one pair of draw rollers is used to transport the material provided, so that then the tension control device expediently Speed of the pair of pull rollers on one from the position of the tension member dependent value regulates. If at least two pairs of pull rollers are provided, which is usually the case, regulates the train control device the transport speed difference of the pairs of pull rollers to one of the Position of the tension member dependent value. Because with such an arrangement tensile stress in the material already arises from the fact that in Direction of transport viewed behind the first pair of draw rollers second Pull roller pair runs a little faster than the first pair of pull rollers, causing the material is stretched between these two pairs of pull rollers.

Depending on the operating state of the regulation of the position of the tension member a specific setpoint can be specified.

At a standstill of the device or even the entire machine in which the device forms part, the tension member should be movable into a rest position be in which the material under no or at least none essential Tension is there. In this way, the material is relieved at a standstill.

The tension control device can be designed in such a way that the tension element remains in the rest position as long as the device is in Standstill. If the drive device or even the entire device is electrically operated, the drive device should expediently be designed such that in the de-energized state the tension element moved into the rest position and / or remains in the rest position.

The movement of the tension member into the rest position has the advantage that especially when changing the material, the new material into the device easily can be threaded.

A currently particularly preferred embodiment is characterized in that that the drive device is a torque-controlled and on an essentially constant torque adjustable rotary drive. This execution allows the tension to be regulated in a structurally particularly simple manner in the material to a desired constant value, independently from the position of the tension member, for example when in use a spring would not be the case because the spring force is proportional to the travel and is therefore changeable accordingly. Advantageously, the Rotary drive on a torque-controlled rotary motor.

Another currently particularly preferred embodiment, in which the tension member is pivotable, over which the material is drawn is characterized in that the tension member can be pivoted by the rotary drive is. By pivoting the tension member, the material is made of it Brought and thereby deflected around one end of the tension member. Depending on the swivel position of the tension element, the material becomes weaker or more deflected.

The axis of rotation of the torque-controlled rotary motor should expediently also the pivot axis of the tension member substantially aligned, whereby the tension member is pivoted directly from the torque-controlled rotary motor becomes.

Another currently particularly preferred embodiment, in which the Tension element a rotatable dancer roller and a swiveling boom has one end is pivotally mounted and the other free The end of the dancer roller is characterized by the fact that the moment-controlled Rotary drive exerts a torque on the boom, reducing the deflection force the tension member or the boom to particularly simple Way can be regulated to a constant value.

The boom is expediently at one end on the output shaft attached to the rotary motor and extends at an angle, preferably at right angles, to the axis of rotation of the output shaft of the rotary motor.

If the processing device has a crusher with a crusher edge for the touching intervention with the material to be pulled over it the crusher, viewed in the direction of transport of the material, can be optional be arranged in front of or behind the tension member. When ordering the Crusher in front of the tension element can be the one that determines the refraction process Traction behind the crusher with the help of the tension control device directly to be controlled. When placing the crusher behind the tension element can decrease the drive torque of a material transporting Pull roller pair serve as an indication of a blunt crusher.

The engagement of the crusher is preferably dependent on the position of the Tension member controllable, because expediently by regulating the position of the tension element also influences the action of the crusher can be. With the help of the invention it is thus possible to define defined geometrical shapes Achieve conditions at the crusher edge. Because different types of material cause different deflection angles at the crusher edge.

The tension member should be movable into a rest position in which Material is out of engagement with the crusher and therefore not on the crusher edge rests. In this way, not only the material is relieved in the rest position, but can also be easily threaded into the device.

When the crusher is rotatably mounted, the rotary position of the crusher can be dependent be controlled by the pivoting position of the tension element. The axis of rotation of the crusher should expediently be aligned with the pivot axis of the tension member essentially aligned. With further training In this version, the axis of rotation of the crusher can essentially be aligned with the crusher edge aligned. The crusher is preferably on the tension member non-rotatably fastened and thus forms a structural unit with the tension element. In a further development of this version, the crusher is on the Cantilever arm, preferably on one end, secured against rotation.

It is already known from DE 24 21 394 A1, the crusher by one Arrange swivel axis rotatably; however, the swivel axis is not aligned the crusher edge and the crusher does not form a structural unit with the Dancer roller, which is also contained in the device according to DE 24 21 394 A1 is.

Alternatively, the crusher can be separated from the movable tension member and in Be arranged stationary with respect to the device. In the case of further training in this alternative design, the crusher with its crusher edge at a distance arranged by the trajectory of the material when the material is out Intervention from the crusher.

Finally, a position sensor for the detection of the Swivel position of the tension member and a calibration device are provided be when the device for calibrating the position transmitter is activated the tension member in a rest position and also in a complete deflected swiveled position. This can be done for the resting position and the fully deflected swivel position each has an end stop be arranged.

Finally, the present invention proposes, according to a further aspect, in the case of a method of the type mentioned at the outset for the application of the Material generated force regardless of the degree of deflection to a constant Set or regulate the value.

Fig. 1

eine schematische zweidimensionale Darstellung einer ersten Ausführung einer Transportstrecke für band- oder streifenförmiges Material mit einer schwenkbaren Tänzerwalze-Brecher-Einheit in ihrer Arbeitsstellung;

Fig. 2

eine Fig. 1 entsprechende schematische dreidimensionale Darstellung der ersten Ausführung;

Fig. 3

eine schematische dreidimensionale Darstellung der ersten Ausführung gemäß Fig. 2 mit der Tänzerwalze-Brecher-Einheit in ihrer Ruhestellung;

Fig. 4

eine schematische dreidimensionale Darstellung einer zweiten Ausführung einer Transportstrecke für band- oder streifenförmiges Material, welches sich von der ersten Ausführung gemäß den Figuren 1 bis 3 dadurch unterscheidet, dass der Brecher stationär angeordnet ist, wobei sich die Tänzerwalze in ihrer Arbeitsstellung befindet;

Fig. 5

eine schematische dreidimensionale Darstellung der zweiten Ausführung gemäß Fig. 4 mit der Tänzerwalze in ihrer Ruhestellung; und

Fig. 6

eine schematische dreidimensionale Darstellung einer dritten Ausführung einer Transportstrecke für band- oder streifenförmiges Material ohne Brecher mit einer Tänzerwalze in ihrer Arbeitsstellung.

Preferred exemplary embodiments of the invention are explained in more detail below with reference to the accompanying drawings. Show it:

Fig. 1

is a schematic two-dimensional representation of a first embodiment of a transport route for strip or strip-shaped material with a pivotable dancer roller-crusher unit in its working position;

Fig. 2

a schematic three-dimensional representation of the first embodiment corresponding to FIG. 1;

Fig. 3

is a schematic three-dimensional representation of the first embodiment of FIG 2 with the dancer roller-crusher unit in its rest position.

Fig. 4

is a schematic three-dimensional representation of a second embodiment of a transport route for strip or strip-shaped material, which differs from the first embodiment according to Figures 1 to 3 in that the crusher is arranged stationary, the dancer roller is in its working position;

Fig. 5

is a schematic three-dimensional representation of the second embodiment of FIG 4 with the dancer roller in its rest position. and

Fig. 6

is a schematic three-dimensional representation of a third embodiment of a transport route for strip or strip-shaped material without crusher with a dancer roller in its working position.

The transport routes shown in the figures can, for example, in one Cigarette filter attachment machine such as that of the applicant under the designation "MAX" machine included and doing so for a wrapping material strip in the form of a covering paper strip for connecting cigarettes and Filters are provided, but are not exclusive to such an application limited.

As shown in Fig. 1, the first embodiment has a transport route for one Material strips 1 on a sensor device 2, the discontinuities, such as Sticky spots, recognizes. The sensor device 2 is connected downstream first pair of pull rollers 4, which strip of material 1 from a not shown Bobine pulls in the direction of arrow A. Behind the first pair of draw rollers 4 the material strip 1 passes through a processing station 14, the construction of which follows is described in more detail. After leaving the processing station 14 the material strip 1 passes through a second pair of pull rollers 16 and becomes final deflected around a deflection roller 18, in order to then a further, not shown here, Processing to be fed.

In Fig. 2 the arrangement of Fig. 1 is again in a three-dimensional view shown, the sensor device 2 and the deflection roller 18 for reasons the clarity are omitted.

As can be seen in FIGS. 1 and 2, the processing station in FIG Embodiment a dancer roller 8 around which the material strip 1st is redirected. The dancer roller 8 is rotatable on its central axis Leg 10a of an L-shaped double lever 10 mounted. The double lever 10 is again on the output shaft 12a of a torque-controlled motor 12 attached. The axis of rotation of the output shaft 12a runs parallel at a distance to the axis of rotation of the dancer roller 8. Accordingly, at least the leg 10a is used of the double lever 10 as a boom, at the free end of the dancer roller 8 is.

The torque-controlled motor 12 can preferably be one Act electric motor.

On the double lever 10, a crusher 22 is rotatably fastened so that the crusher edge 22a is aligned with the axis of rotation of the output shaft 12a of the motor 12. Thus forms in the first execution of the crusher 22 a constructive unit with the dancer roller 8th.

While in Fig. 2 the unit of dancer roll 8 and crusher 22 by a corresponding Swiveling the double lever 10 using the motor 12 in their full deflected working position is shown in the illustration of FIG. 3 Dancer roller 8 and the crusher 22 in their rest position. As can also be seen in FIG. 3 leaves, the dancer roller 8 and the crusher 22 are arranged to each other, that in the rest position of the material strips 1 contactless between the dancer roller 8 and the crusher 22 is passed. In contrast, the Material strip 1 in the working position according to FIG. 2 at the breaker edge 22a kinked and guided around the dancer roller 8, so that the crusher 22 with his Crusher edge 22a and the dancer roller 8 each in touching engagement with the Material strips 1 are.

As can be seen from a comparison of FIGS. 2 and 3, this is in the exemplary embodiment shown the arrangement made so that the angle of rotation for pivoting of the double lever 10 between the rest position shown in FIG. 3 and the full deflected working position according to FIG. 2 is 180 °.

3, the material strip 1 straight from the first pair of pull rollers 4 runs to the second pair of pull rollers 16 is by pivoting of the double lever 10 from the rest position into a working position Dancer roller 8 in engagement with the material strip 1 between the two pairs of pull rollers 4 and 16 brought. This has the consequence that with further pivoting of the double lever 10 of the material strip 1 from its direct straight line Path of movement between the two pairs of pull rollers 4 and 16 deflected and is not only deflected around the dancer roller 8, but also in contact with the crusher edge 22a of the crusher 22 (see FIG. 2).

The torque-controlled motor 12 is controlled by a regulating device 20, which is only shown schematically in Fig. 1, but in Figures 2 and 3 is omitted for reasons of clarity. The motor 12 is with applied a constant torque, whereby the double lever 10 and thus the dancer roller 8 carried on one leg 10a into a specific one Swivel position is pivoted. The torque determines the tension in the material strip 1. The greater the torque with which the motor 12 pivoted the double lever 10 and thus the dancer roller 8 the strip of material 1 deflects, the more material strip 1 is subjected to tensile stress.

The control device 20 controls the motor 12 such that the motor 12 generated torque is regulated to a predetermined value, the regulation of the torque regardless of the swivel position of the double lever 10 takes place.

In addition, the control device 20 is also with the pairs of pull rollers 4 and 16 linked. Usually the conveying speed of the second is Pull roller pair 16 a little higher than that of the first pair of pull rollers 4, whereby A tensile stress already arises in the material strip 1. This speed difference regulates the control device 20 depending on the Swivel position of the double lever 10 and thus the position of the dancer roller 8.

The control device 20 not only controls the torque of the motor 12, but also receives information about the rotational position of the output shaft 12a of the motor 12 and thus the pivot position of the double lever 10. This is a Position sensor, not shown, is provided, which sends this information to the control device 20 forwards. The position encoder is usually in the motor 12 integrated. To calibrate this position transmitter when starting the device The motor 12 is controlled by the control device 20 so that it has the double lever 10 first in the rest position shown in FIG. 3 and then in the full deflected working position pivoted according to FIG. 2. Two corresponding ones can be used for this End stops may be provided, which are not shown in the figures are.

When the device is at a standstill, the control device 20 controls the motor 12 so that the double lever 10 is pivoted into its rest position according to FIG. 3. In addition, the arrangement shown is such that in the de-energized state the device, the double lever 10 remains in its rest position. In the The material strip 1 can then be at rest, for example after a change the paper type, can be easily threaded.

If the sensor device 2 has a discontinuity during operation, such as, for example an adhesive point, in the material strip 1, controls the control device 20 the engine 12 such that the torque of the engine 12 is reduced becomes. As a result, the pressure of the dancer roller 8 on the material strips 1 and thus the tensile stress thereby acted upon in the material strip 1 is reduced. This is important because the glue naturally forms a weak point at which the Material strips 1 can easily tear. The weight of the dancer roller is also included 8 to be considered. With paper, the tensile stress should e.g. usually about 7 N, but only about 0.5 N for a bond. Under the assumption, that the weight of the dancer roll is about 2 N is a total force of about 9 N in normal operation and about 2.5 N at an adhesive point, which is easily possible with the help of the torque-controlled motor 12 is. In another configuration or different weight distribution, it is but also conceivable that the torque to be applied at an adhesive point the sign changes. While reducing the torque of the Motor 12 and the resulting reduction in tension in the material strip 1 can the position control for the double lever 10 and thus for the dancer roller 8 can also be turned off until the discontinuity, such as e.g. a glue point, the second pair of pull rollers 16 has passed.

As can be seen in particular in FIG. 2, on the other leg 10b of the double lever 10 attached a counterweight 24, which is mainly intended for this is, when the motor 12 is switched off, the double lever 10 by gravity to pivot into its rest position according to FIG. 3. By appropriate dimensioning the counterweight 24 can, however, depending on the application also influence the torque ratios during operation accordingly, for example, a counterforce in the manner described above To be able to generate a predetermined size.

The crusher 22 can, in its working position in the transport direction of the material strip 1 considered, optionally arranged in front of or behind the dancer roller 8 his. In the first embodiment shown in FIGS. 1 and 2, the crusher 22 lies in Direction of transport A of the material strip 1 viewed, in front of the dancer roller 8. If you reverse the transport direction, so that the material strip 1 in the direction of arrow A 'runs, and the sensor device 2 is moved to the other end the transport route shown, as in Fig. 1 by dashed lines and that Reference numeral 2 'is indicated, there is a modified embodiment in which the crusher 22, viewed in the transport direction A ', now behind the dancer roller 8 lies.

By arranging the dancer roller 8, in the transport direction A of the strip of material 1, behind the crusher 22 can be used for the refraction process determining tensile force through the dancer roller 8 directly behind the crusher 22 to be controlled.

When arranging the dancer roller 8, in the transport direction according to the dashed arrow A 'viewed in Fig. 1, in front of the crusher 22 there may be a decrease in drive torque the pair of traction rollers behind, here the first pair of traction rollers 4, serve as an indication of a blunt crusher edge 22a of the crusher 22.

Finally, the target value of the position of the dancer roller 8 can be used as the brand parameter and thus the paper angle over the crusher 22 can be specified.

A currently particularly preferred second embodiment is shown in FIGS. 4 and 5 shown, which are different from that previously described with reference to Figures 1 to 3 first embodiment differs in that - instead of a rotatable bearing by arrangement on the double lever - the crusher 22 'from the double lever 10' is physically separated stationary. Accordingly, this second version the crusher 22 'does not move together with the dancer roller 8, but instead is fixed and the dancer roller 8 is pivoted by the motor 12 only accordingly. The crusher edge 22a 'of the crusher 22' has a fixed one Orientation.

In the working position of the dancer roller 8 shown in FIG. 4 - in the same way as in the first embodiment according to FIG. 2 - the material strip 1 over the Crusher edge 22a 'of the stationary crusher 22' is drawn and deflected there. In 5, in contrast, the material strip runs 1 free from crusher 22 ', d. H. at a distance from this. So is Even in the second version, the arrangement is such that the stationary Crusher 22 'at a distance from which the two pairs of pull rollers 4 and 16 directly connecting line that the path of the strip of material 1 in the rest position of the Dancer roll 8 forms, sits and in its rest position the dancer roll 8 also in a distance from the material strip 1. Thus runs in the rest position Dancer roller 8 of the material strips 1 without contact between the dancer roller 8 and the crusher 22 ', as shown in FIG. 5.

With regard to the other design features and the regulation of the second Execution is referred to the description of the first embodiment.

It should also be mentioned at this point that the material strip in the processing station 14 1 optionally processed in another way, for example printed and / or perforated.

Finally, it is also conceivable to implement a version in which a crusher is not provided. Such a third embodiment is shown in FIG. 6.

The third embodiment according to FIG. 6 thus differs from the embodiments according to Figures 1 to 5 in particular in that the crusher is missing and instead of the double lever, a simple radial arm 10 "is provided the dancer roller 8 is rotatably mounted at the free end of this boom 10 ", while the boom 10 "with its other end radially on the output shaft 12a of the torque-controlled motor 12 is attached. The one shown in Fig. 6 third version is - instead of the crusher - a free-running deflection roller 6 is provided, which is mounted on the boom 10 "in such a way that its axis of rotation is aligned with the axis of rotation of the output shaft 12a of the motor 12.

The processing station 14 shown in Fig. 6 is for other processing of the material strip 1 is provided, in which the material strip 1, for example can be perforated and / or printed.

The deflection roller 18 shown in Fig. 1 can also in the third embodiment be provided, but is not shown in Fig. 6.

The sensor device 2 and the control device are also not shown in FIG. 6 20 of Fig. 1. Nevertheless, the sensor device and the control device in the same way part of the third version as it is are also in the first and second versions. Therefore, regarding the Control of the motor 12 and the pivoting of the dancer roller 8 on the previously reference made in connection with the first embodiment.

The arrangement of free-running deflection roller 6 and dancer roller 8 is so met that in the (not shown) rest position of the boom 10 "of Strips of material 1 without contact between the free-running deflection roller 6 and the dancer roll 8 is passed through. 4 is the boom 10 "and thus the dancer roller 8 shown in the working position in which the dancer roller 8 the strip of material 1 from its direct path of movement between the two pairs of pull rollers 8 and 16 deflects, whereby the material strip 1 also in contact with the free-running deflection roller 6 arrives and is deflected there accordingly.

Claims (27)

Device for transporting strip or strip-shaped material (1), in particular wrapping material or covering paper for rod-shaped articles of the tobacco processing industry, through a processing device (14), with a tension element (8, 10; 8) that can be moved at an angle to the direction of transport of the material (1) 10 '; 8, 10 ") over which the material (1) is guided in order to deflect the material (1) out of its path of movement in order to generate a tensile stress, and with a drive device (12) for moving the tensile stress element (8, 10; 8, 10 '; 8, 10 "),
characterized in that the drive device (12) is designed such that it exerts a force on the tension element (8, 10; 8, 10 '; 8, 10 ") which is independent of the position of the tension element (8, 10; 8 , 10 '; 8, 10 ") can be set to an essentially constant value. Device according to claim 1, with a tension control device (2, 20) for controlling the tension in the material (1),
characterized in that the tension control device (2, 20) controls the drive device (12) such that the force exerted on the tension element (8, 10; 8, 10 '; 8, 10 ") and the position of the tension element (8, 10 ; 8, 10 '; 8,10 ") are regulated independently of one another to a predetermined value. Device according to claim 2,
in which the tension control device has a device (2) for detecting discontinuities, such as, for example, glue points, in the material (1),
characterized in that the tension control device reduces the force exerted by the drive device (12) on the tension element (8, 10; 8, 10 '; 8, 10 ") when the detection device (2) detects a discontinuity in the material (1). Device according to claim 3,
characterized in that when the force exerted by the drive device (12) on the tension element (8, 10; 8, 10 '; 8, 10 ") is reduced to a reduced value, the tension control device (2, 20) regulates the position of the tension element (8, 10; 8, 10 '; 8, 10 ") deactivated. Device according to at least one of claims 2 to 4,
with at least one pair of pull rollers (4; 16) for transporting the material (1),
characterized in that the tension control device (2, 20) controls the speed of the pair of tension rollers (4; 16) to a value dependent on the position of the tension element (8, 10; 8, 10 '; 8, 10 "). Device according to claim 5,
with at least two pairs of pull rollers (4, 16),
characterized in that the tension control device (2, 20) regulates the transport speed difference of the tension roller pairs (4, 16) to a value dependent on the position of the tension element (8, 10; 8, 10 '; 8, 10 "). Device according to at least one of claims 1 to 6,
characterized in that , depending on the operating state of the regulation of the position of the tension element (8, 10; 8, 10 '; 8, 10 "), a specific target value can be predetermined. Device according to at least one of claims 1 to 7,
characterized in that, when the device is at a standstill, the tension element (8, 10; 8, 10 '; 8, 10 ") can be moved into a rest position in which the material (1) is under no or at least no substantial tension. Device according to claim 8,
characterized in that the tension control device is designed such that the tension element (8, 10; 8, 10 '; 8, 10 ") remains in the rest position as long as the device is at a standstill. Device according to claim 8 or 9,
in which the drive device is operated electrically,
characterized in that the drive device is designed such that in the de-energized state it moves the tension element (8, 10; 8, 10 '; 8, 10 ") into the rest position and / or holds it in the rest position. Device according to at least one of claims 1 to 10,
characterized in that the drive device has a torque-controlled rotary drive (12) which can be adjusted to an essentially constant torque. Device according to claim 11,
characterized in that the rotary drive has a rotary motor (12). Device according to claim 11 or 12,
in which the tension element (8, 10; 8, 10 '; 8, 10 ") is pivotally mounted,
characterized in that the tension element (8, 10; 8, 10 '; 8, 10 ") can be pivoted by the rotary drive (12). Device according to claims 12 and 13,
characterized in that the axis of rotation of the rotary motor (12) is substantially aligned with the pivot axis of the tension element (8, 10; 8, 10 '; 8, 10 "). Device according to at least one of claims 11 to 14,
in which the tension member (8, 10; 8, 10 '; 8, 10 ") has a rotatable dancer roller (8) and a pivotable arm (10; 10';10"), one end of which is pivotally mounted and the other free End (10a) carries the dancer roller (8),
characterized in that the rotary drive (12) exerts a torque on the boom (10; 10 '; 10 "). Device according to claims 14 and 15,
characterized in that the boom (10; 10 '; 10 ") is attached at one end to the output shaft (12a) of the rotary motor (12) and extends at an angle, preferably at right angles, to the axis of rotation of the output shaft of the rotary motor (12). Device according to at least one of claims 1 to 16,
in which the processing device (14) has a crusher (22; 22 ') which is provided with a crusher edge (22a; 22a') for the contacting engagement with the material (1) to be drawn over it,
characterized in that the crusher (22; 22 '), viewed in the transport direction (A or A') of the material (1), is arranged in front of or behind the tension element (8, 10; 8, 10 '). Device according to claim 17,
characterized in that the engagement of the crusher (22; 22 ') depending on the position of the tension member (8, 10; 8, 10') is controllable. Device according to claim 8 and according to claim 17 or 18,
characterized in that the tension member (8, 10; 8, 10 ') can be moved into a rest position in which the material (1) is disengaged from the crusher (22; 22'). Device according to at least one of claims 17 to 19,
in which the crusher (22) is rotatably mounted,
characterized in that the rotational position of the crusher (22) can be controlled as a function of the pivoting position of the tension element (8, 10). Device according to claim 20,
characterized in that the axis of rotation of the crusher (22) is substantially aligned with the pivot axis of the tension element (8, 10). Device according to claim 21,
characterized in that the axis of rotation of the crusher (22) is substantially aligned with the crusher edge (22a). Device according to at least one of claims 20 to 22,
characterized in that the crusher (22) is non-rotatably fastened on the tension member (8, 10). Device according to claims 15 and 23,
characterized in that the crusher (22) is rotatably attached to the boom (10), preferably at one end thereof. Device according to one of claims 17 to 19,
characterized in that the crusher (22 ') is separated from the movable tension member (8, 10') and is stationary with respect to the device. Device according to at least one of claims 1 to 25,
characterized by a position sensor for detecting the pivoting position of the tension element (8, 10; 8, 10 '; 8, 10 ") and a calibration device (20) which, when the device for calibrating the position sensor, activates the tension element (8, 10; 8 , 10 '; 8, 10 ") in a rest position and in a fully deflected pivot position. Method for regulating the tensile stress in a strip or strip-like material (1) to be transported, in particular wrapping material or covering paper for rod-shaped articles of the tobacco processing industry, in particular using the device according to at least one of the preceding claims, in which the material (1) is at an angle its direction of transport is acted upon in order to be deflected from its path of motion to generate a tensile stress,
characterized in that the force generated for the application of the material (1) is set or regulated to a constant value regardless of the degree of deflection.

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