EP2574244A2 - Device for transporting material in the form of strips or tape - Google Patents

Abstract

The device has a fitting unit that changes the tensile force in band-or-strip-shaped material. A deflecting unit (18) deflects the band-or-strip-shaped material to an angle in the conveying plane. A sensor device senses the tension in the band-or-strip-shaped material. The fitting unit controls the tension of the band-or-strip-shaped material based on the signal of the sensor unit.

Description

The invention relates to a device for transporting strip or strip material having the features of the preambles of claims 1, 6 or 7.

Devices for transporting strip or strip-like materials, in particular covering material or tipping paper, are used in machines for producing rod-shaped products of the tobacco-processing industry. The wrapping paper or tipping paper must thereby with a high accuracy at very high conveying speeds of e.g. 600 m / min and more are performed. Even small deviations of the wrapping material or covering paper in the transverse orientation of a few 1/100 mm can lead under unfavorable circumstances to a production stop of the entire device. In order that the wrapping material or the tipping paper is accurately guided, this is stretched over a plurality of draw rollers, in which case care must also be taken that a predetermined maximum stress in the material is not exceeded and the strip or tape does not tear. Furthermore, compliance with the desired position during the transport movement must be sensed several times via corresponding sensors and, if necessary, be restored in the case of deviations via appropriately actuated actuators.

A particular problem in this case are the deflections of the wrapping material or of the padding paper required during the transport movement of the wrapping material or of the padding paper the longitudinal axis, as is the case for example with an angular supply of the wrapping material or the lining paper from a reel and a subsequent deflection.

If double-width wrapping material or tipping paper is supplied, this must be cut in the middle into two individual strips, which can then be laterally offset in each case in a spreading device by repeatedly deflecting. Even after the spreading device, compliance with the desired position of the wrapping material or covering paper can be problematic due to the lateral offset, so that it must be checked by means of one or more sensors and readjusted if necessary by deviations via appropriate actuators.

Further, it is a particular problem when the product is to be wrapped with two superimposed layers of wrapping or tipping paper, fed in two separate paper runs, then superimposed and passed over a gluing section in a superimposed arrangement and wrapped around the product in a format section , In this case, a deviation of the desired positions and desired widths of the two webs or strips can lead to an erroneous application of the glue trace in the gluing section and a consequent erroneous wrapping of the products by the wrapping material or covering paper. Thus, it is conceivable in this case, for example, that an inner layer of a wrapping material, which is actually not visible from the outside, is not completely covered by the outer second layer of the wrapping material or covering paper, and / or that it is not glued correctly, and the product as a result, this does not completely fix its shape.

Furthermore, in the case of products with an outer wrapper and an inner wrapper, there is the problem that the inner wrapper in the production machine does not bear directly on the format tape, so that this position is not transported directly by the overspeed format tape and if the contact force of the overfeed is too low Tobacco or filter material strip dammed or can form a lot. Furthermore, different grades of the strip or strip material may in this case lead to unfavorable friction conditions between the inner and outer layers of the wrapping material, which may also result in loose material in the wrapping material and consequent wrinkling.

Against this background, the invention has the object to provide a generic device with which the strip or band-shaped material can be transported with increased accuracy transverse to the transport direction under the conditions mentioned. Furthermore, the invention has for its object to provide a device which allows a wrapping of the products with two superimposed layers with a reduced probability of error.

• eine erste an dem band- oder streifenförmigen Material anliegende Einrichtung zur Veränderung der Zugkraft in dem band- oder streifenförmigen Material,
• eine das band- oder streifenförmige Material um den ersten Winkel in die Transportebene umlenkende Umlenkeinrichtung,
• eine Sensoreinrichtung zur Sensierung der Zugkraft in dem band- oder streifenförmigen Material, wobei

die erste Einrichtung zur Veränderung der Zugkraft in Abhängigkeit von dem Signal der Sensoreinrichtung ansteuerbar ist.To solve the problem, a device for transporting strip or strip-shaped material for a machine for the production of rod-shaped products of the tobacco-processing industry, which is fed at a first angle to a transport plane proposed, the accuracy of the transport of the band or Strip-shaped material is increased transversely to the transport movement thereof by the following devices are provided in the order of naming in the direction of movement of the strip or strip-shaped material starting from the feed:

• a first device, acting on the strip or strip material, for changing the tensile force in the strip or strip material,
• a deflecting device deflecting the band-shaped or strip-shaped material about the first angle into the transport plane,
• a sensor device for sensing the tensile force in the strip or strip-shaped material, wherein

the first device for changing the tensile force in response to the signal of the sensor device is controllable.

The proposed solution, the band or strip-shaped material can be deflected from the angular feed into the transport plane, without the deflection effect on the tensile force in the strip or strip-shaped material or a negative impact on the guidance accuracy of the material after the deflection Has. The transport plane of the strip or strip material is to be understood as a plane which is spanned by the different transport directions of the material after the deflection device. The transport plane may be e.g. may also be formed only by a short section in which the material is guided at least shortly after leaving the deflection and from which the material is then further deflected. The transport plane preferably runs parallel to a housing wall, on which the deflections and drives are arranged.

In principle, deflections always result in a more restless running of the material after passing through the deflections, since the tensile forces in the band-shaped or strip-shaped material are increased by the frictional forces acting on the deflecting point. To compensate for this disadvantage, the deflection device between a sensor device and a controllable, arranged a tensile force in the band or strip-shaped material generating device. By controlling the tensile force in the strip or strip material in front of the deflection device, the tensile force additionally generated in the deflection device can be compensated by reducing the tensile force exerted by the device so that the strip or strip-shaped material after the sensor device substantially constant tensile force is transported independently of the frictional forces acting on the deflection. This compensation of the frictional forces is therefore of particular advantage, since different frictional forces on the deflection device are automatically set for different directions of feeding the strip or strip material. These different friction forces can then be compensated for by a corresponding control of the force exerted by the device tensile force to a constant, acting according to the deflection in the material, independent of the feed direction of the material tensile force.

Because of this much more uniform tensile force and the transport movement of the strip or strip material is then overall calmer and more accurate. This can be made possible by the proposed device, a supply of the strip or strip-shaped material from different angles in a simultaneously very precise registration of the strip or strip-shaped material in a subsequent manufacturing machine.

It is further proposed that the deflection device has an adjusting device, by means of which the angle between the longitudinal axis of the deflection device to the longitudinal axis of the fed strip or strip-shaped material is adjustable. By adjusting the angle, the angle the deflection even after mounting the device in a parent unit are still changed, so that the device must not be dismantled at a change in the inlet angle. In addition, can be made by adjusting the adjustment during the operation of the device with the passing material and a compensation of errors in setting up the bobbin.

It is also proposed that at least the first device for changing the tensile force and the deflection device are mounted on a common frame. The proposed holder, the deflection and the means for exercising the tensile force in a fixed spatial relationship to each other and can also be pre-assembled easy to install and installed together. Furthermore, the two units can also be mounted at different angles in the device, without losing the important fixed spatial relationship to each other.

A particularly simple construction can be provided by the deflection device is formed by a fixed deflection pin, which is arranged such that its longitudinal axis forms an angle to the longitudinal axis of the fed strip or strip-shaped material which is half as large as the obtuse angle between the longitudinal axis of the fed strip or strip-shaped material and the transport plane.

In this case, the disadvantage of the increased friction between the stationary deflection pin and the strip or strip-shaped material and the associated increase in the released particles can be compensated for by a deflection on the flow side of the band or strip-shaped Material directed suction device is provided.

Further, to achieve the object, a device for transporting strip or strip material for a machine for the production of rod-shaped products of the tobacco-processing industry, which is adapted to the band or strip-shaped material from different first angles to a transport plane of the band or strip-shaped material can be supplied in the device, proposed, in which a device for displacing the strip-like or strip-shaped material transversely to its longitudinal axis is provided on the entry side of the strip-like or strip-like material, which device is arranged in the running direction of the strip or strip-shaped material arranged according to a spreading device position sensor can be controlled. The course of the strip or strip material after the spreader corresponds to the orientation as the material is introduced into a subsequent format section of a subsequent production machine. By the proposed control, a positional deviation of the strip or strip material from a desired position after passing through the spreading can be compensated as quickly as possible by the orientation of the material is already changed transversely to the longitudinal axis at the inlet to the paper path. This control has the advantage that the material is introduced with a laterally corrected alignment in the paper path, so that the deviation is compensated for independently of the cause directly by adjusting the pre-alignment of the material.

Further, to solve the problem, a device for transporting strip or strip material for a machine for the production of rod-shaped products of the tobacco-processing industry, which is guided in two superimposed layers over a deflection and placed on the layers further transporting format tape, the layers are respectively supplied in different paper runs, proposed in which in the paper run, not directly on the format band to the plant reaching position, a tension roller is provided which can be controlled indirectly or directly in response to a arranged between the tension roller and the deflection force measuring device. The proposed solution, the tensile force can be actively changed in the paper run of the inner layer, so that the likelihood of wrinkles can also be reduced in the inner layer. As a tension roller, for example, an already existing pull roller pair can be used. As a force measuring device, for example, a DMS measuring roller can be used, on which the band or strip-shaped material is deflected.

It is also proposed that a device be provided by means of which the not reaching the format tape to the plant layer in the region of the deflection with an additional pressure can be acted upon. At the deflection of the superimposed layers are sucked by means of a negative pressure and held during the deflection of the deflection. Since the negative pressure basically acts only on the directly adjacent layer, the second layer resting thereon generally tends to lose contact with the first layer. This disadvantage is solved by the solution according to the invention in that an additional, directed in the direction of the first layer pressure is exerted on the second layer, which presses against the two layers or at least prevents the release.

Constructively, the pressure can be applied particularly easily if the device is an air pressure device. By the air pressure device, a particularly low pressure can be generated, which only very slightly loads the situation, but nevertheless provides the necessary contact pressure on the first layer. The air pressure device may be the layers e.g. blow tangentially after deflecting, so that the second layer is additionally pressed in the direction of movement and in particular prevents the second layer from lifting away from the first layer.

Fig. 1:

eine schematische Darstellung einer Gesamtvorrichtung zum Transport eines band- oder streifenförmigen Materials;

Fig. 2:

einen vergrößerten Ausschnitt der Gesamtvorrichtung;

Fig. 3:

eine schematische Darstellung des in der Figur 2 gezeigten Ausschnitts von oben;

Fig. 4:

eine schematische Darstellung eines Ausschnitts der Gesamtvorrichtung mit einem sich anschließenden Formatabschnitt;

Fig. 5:

die Regelung der Zugkraft der inneren Lage.

The invention will be explained below with reference to preferred embodiments with reference to the accompanying figures. Showing:

Fig. 1:

a schematic representation of an overall apparatus for transporting a strip or strip-shaped material;

Fig. 2:

an enlarged detail of the overall device;

3:

a schematic representation of the in the FIG. 2 shown detail from above;

4:

a schematic representation of a section of the overall device with a subsequent format section;

Fig. 5:

the regulation of the tension of the inner layer.

In the FIG. 1 is a schematic overview of the course of the strip or strip-shaped material, hereinafter generally referred to as paper to recognize in a device according to the invention. The device is between one Bobine, from which the paper is unwound, and a manufacturing machine, in which the paper is wrapped around a tobacco or filter rod and glued, arranged. In the present embodiment, it is a device in which the paper fed into two double-width paper strips, cut into two parallel strands, superimposed and then fed one above the other to a subsequent manufacturing machine.

The entire paper path can be divided into a first paper run I and a second paper run II, wherein in the first paper run I the outer layer of the product, such as e.g. a cigarette wrapping layer, in the form of a double-width paper strip, and in the second paper path II the inner layer of the product, e.g. a cigarette wrap (double wrap), also in the form of a double-width strip of paper is supplied. The double-width paper strips are cut in the paper runs I and II respectively into two single-width parallel paper strips and then stacked to two parallel, double layers. The double-ply paper strips are then deflected in a deflection section in a horizontal orientation and introduced into a format section of the manufacturing machine. Before inserting the superimposed layers in the format section, an endless tobacco rod or filter strand is placed on the superimposed layers, which are fixed in the format section by folding and gluing the edges of the endless paper strips to a respective rigid strand endless.

The first paper run I, the double-width endless paper strip is supplied in a later shown in more detail angular alignment via a guide roller M31S. In front of the pulley M31S, an optical sensor B10S is provided, which senses an actual position of the edge of the paper strip, and then transmits a corresponding actuating signal to the controllable deflection roller M31S when a predetermined tolerance range of the actual position of the desired position is exceeded. The deflection roller M31S itself or a guide arranged thereon is designed to be transversely displaceable and, given a corresponding activation, performs a transverse movement for the correction of the paper edge position. By a correspondingly fast control and the proximity of the optical sensor B10S to the deflection roller M31S or the paper inlet of the first paper path I, the paper strip is introduced into the first paper path I with a very high positional accuracy. After the entry of the paper strip into the first paper run I, the paper strip is gripped by a first draw roll paper Z / W1 and deflected in a device to be described later in a predetermined transport direction or transport plane. Close behind the first draw roller pair Z / W1 after the first deflection, an ultrasonic sensor B21S is arranged, which recognizes the knurling point after a change of the reel and then ejects the products produced in a predetermined time window from the subsequent production process.

After the paper strip has been deflected into the transport plane, it is guided over a pivotally mounted tension pulley M2S, which increases or decreases the tension in the paper strip by carrying out a pivoting movement. At the same time, the tension pulley M2S comprises a measuring device by means of which the actual tensile force in the paper strip is sensed. The double-width paper strip is then passed through a Z / S / W1 pull-and-cut roller combination, which is driven by a M9S guide roller. In the pull-cutting roller combination Z / S / W1 the double-width paper strip of one on the pulley M9S adjacent and driven by this cutting roller S / M1 cut into two single-width paper strips. After leaving the train-cutting roller combination Z / S / W1, the two parallel strips of paper, in the event that a printing unit is present, past this and then separated by a spreading device 15. The spreader 15 is formed by a plurality of successively arranged tapered rollers or cylindrical rollers arranged at an angle to the transverse orientation of the paper strip, which offset the individual paper strips in parallel by their conical orientation or alignment of the longitudinal axes of the angular rollers. The tapered rollers or the angular rollers are fixed such that the center distance between at least two of the rollers is adjustable perpendicular or parallel to their longitudinal axes by one or two drives M25 / 26S, whereby the lateral offset of the single-width paper strips emerging from the spreading device 15 is variable , In the direction of the paper strip behind the spreader 15, a sensor B19S is provided which senses and compares the widths of the paper strips. In the event that the sensed difference of the widths exceeds a predetermined target difference, a signal is given to the controllable deflection roller M31S, which laterally shifts the double-width paper strip before entering the first paper path I, whereby the relative position of the paper strip to the cutting roller S / M1 and thus the position of the cut edge of the double-width paper strip is changed. After sensor B19S, another ultrasonic sensor B60S directed at the edges of the paper strips is provided, the function of which will be explained in more detail later.

The second paper run II of the inner layer (double wrap), also referred to below as a paper strip, is also unwound as a double-width paper strip from a reel, not shown, and fed in the transport direction or the transport plane spanned by the transport directions. Before the paper strip enters the second paper path II, the paper strip comes to rest on a deflection roller M32S and is previously guided past an optical sensor B11S, which has the same function as the optical sensor B10S in the first paper path I. After the paper strip has entered the second paper run II this is passed to an ultrasonic sensor B22S for detecting the knurling produced by a change of bobbins and then fed to a train-cutting roller combination Z / S / W2 with a drive roller M11S and a cutting roller S / M2, which has the same function as the train Cutting cylinder combination Z / S / W1 of the first paper run I has. After the exit of the now cut, single-width paper strips, they are offset laterally outwards in a spreading device 16 and then in the same way as the paper strips of the first paper path I on an optical sensor B20S for sensing the width of the paper strips and on an ultrasonic sensor B61S for sensing passed the paper edge layer. The sensor B20S senses the width of the single-width paper strips and, in the event of deviations in the difference of the widths from a predetermined maximum target difference, controls the deflection roller M32S, which laterally shifts the double-width paper strip before passing through the tension-cutting roller combination Z / S / W2. The B60S and B61S ultrasonic sensors are aimed at the paper edges of the single-width paper strips. In the event that the actual position of the paper edges is outside a specified tolerance range, the drives M25 / 26S and / or M27 / 28S driven, whereby the lateral offset and thus the paper edge position of each individual paper strip or paper strips can be changed in pairs. This has the advantage that the relative position of the paper edges of the superimposed layers in the format section can be controlled with each other by the regulation of the paper edge position. As a result of the thus improved alignment of the paper edges in the format section, the glue trace is applied to an edge provided with increased accuracy, and the folding and gluing can be carried out with a considerably higher accuracy.

After the entry of the double-width paper strip into the tension-cutting roller combination Z / S / W2, the second paper path II corresponds to the first paper path I, with the difference that no printing unit is provided, as may be the case with the first paper path I. Further, the paper feed to the second paper run II is not angled, and there is no first draw roller, deflection and no tension roller provided before the train-cutting combination.

A particularly important feature for precise guidance of the paper strips and in particular for a precise arrangement of the paper strips on top of each other, is the sensing of the width of the strips with the sensors B19S and B20S and a control of the pulleys M31S and M32S in case of deviations of the actual widths from the desired widths As a result, compliance with the desired widths of the paper strip is regulated before stacking the layers and thereby adhering to the relative orientation of the paper edges to each other, ie also controlled after the superimposition of the layers. Since the position of the paper strips is controlled in each case by actuators arranged on the entry sides of the paper runs I and II, the paper strips are already introduced with a corrected advance direction in the paper runs I and II, so that the paper strips are ideally in the desired position after passing through the paper runs I and II when passing the sensors B19S and B20S.

The paper strips emerging from the first and second paper runs I and II are superposed on two parallel running, double-layered strips and placed on a format belt 9 via a deflection device 7, 18, as well as in FIG FIG. 4 can be seen. Basically, the format tape 9 is driven at an overspeed increased by a constant preset factor from the speed of the two double plies of the paper strips, thereby generally avoiding wrinkling of the adjacent paper strips and jamming of the paper strips. According to the in the FIG. 4 illustrated embodiment of the invention, a tensile force in the paper strip of the second paper run II sensational DMS roller is provided in the second paper run II, which controls the pulley M11S in the train-cutting roller combination Z / S / W2 at a falling below or exceeding predetermined limits, so that the tensile force in the paper strip of the second paper path II is increased. The guide roller M11S corresponds to the tension roller claimed in claim 7, and the DMS roller 12 corresponds to the force measuring device claimed there. At the deflection device 7,18 a device 19 is provided, by means of which the second resting on the first layer layer can be acted upon with compressed air. The compressed air is thereby inflated obliquely from above to the second layer or in the transport direction of the second layer, so that the second layer can not lift off from the first layer before the launched tobacco rod presses both layers on each other.

In the FIG. 5 is the regulation of the tensile force FPFI in the inner layer and the regulation of the tensile force FPFA in the outer layer of the two paper runs I and II shown in more detail. First of all, various parameters, such as the cigarette length ZL, the overfeed speed VFÜ and the tensile force FP in the paper strip are specified. In addition, various predetermined speeds of the format tape 9 and the paper strips in the paper runs I and II are stored in a master M and read. Furthermore, the Istzugkräfte FP1 and FP2 are sensed in the paper runs I and II, which takes place in the described embodiments by the tension roller M2S in the first paper run I and in the second paper run II by the DMS roller 12. The Istzugkraft FP1 in the first paper run I is processed together with the predetermined format tape overspeed VFÜ in the controller R2 to a manipulated variable for the Zugwalzenpaar Z / W1. The actual tensile force FP2 in the second paper path II is fed together with the predetermined tensile force FP to the controller R1, and processed in this to a manipulated variable for the Zugwalzenpaar Z / W2. The traction force FPFI in the inner layer then results from the delta between a characteristic value determined from the cigarette length ZL and a preset speed stored in the master and the characteristic variable determined from the transmission ratio between the control of the traction roller pair Z / W2 and the master. The tensile force FPFA in the outer layer results from the delta between a characteristic value determined from the cigarette length ZL and a characteristic value determined in dependence on the velocities stored in the master and a parameter determined from the transmission ratio between the control of the draw roller pair Z / W2 and the master. This allows the tensile force in the inner layer of the two-ply, on the format tape 9 adjacent paper strip are determined and regulated accordingly.

In the FIGS. 2 and 3 is provided at the beginning of the first paper run I device for deflecting the paper strip, also called twist device, shown in more detail. The paper strip is fed in an angular orientation to the transport plane of the paper strip during the subsequent transport movement. The transport plane of the paper strip in the production machine is the plane which is spanned by the various transport directions into which the paper strips are fed before entering the format section of the production machine. The transport plane may include a very short section which connects directly to the twisting device or extends to the manufacturing machine. Due to the structure of the device, the transport plane usually runs parallel to a housing wall, on which the deflections, the Zugwalzenpaare, the train-cutting roller combinations and the sensors are mounted or attached.

After the entry of the paper strip into the device, it is first guided past the first pair of drawing rollers Z / W1, which generates a pulling force acting on the paper strip, through which the paper strip is transported. The first Zugwalzenpaar Z / W1 corresponds in function to the proposed in claim 1 device to change the tensile force. After leaving the draw roller pair Z / W1, the paper strip is guided over two deflections 1 and 2, between which the sensor B21S directed onto the paper strip is arranged. In the further course of the paper strip is passed over a fixed deflection fU / B, which with its longitudinal axis L3 in the direction of or parallel to the bisector aligned between the longitudinal axes L1 and L2 of the paper strip in the feed and after leaving the deflection pin fU / B. The orientation of the paper strip after leaving the deflection pin fU / B in the direction of the longitudinal axis L2 corresponds to the transport plane, in which the paper strip is then transported by multiple deflections in different transport directions up to the format strip 9. The paper strip simple width is divided when cutting into two single-width paper strips, which are offset after leaving the train-cutting roller combination Z / S / W1 from the transport plane laterally into two planes offset parallel to the transport plane, so that the original transport plane between the single-width paper strips runs.

In the FIG. 3 The guide of the double-width paper strip can be seen from above. The paper strip is fed at a first angle A1 to the transport plane extending through the longitudinal axis L2 of the paper strip after the deflection and deflected and driven at the draw roller pair Z / W1. In the course of the paper strip is deflected twice at the deflections 1 and 2 and led to the fixed deflection fU / B out, the deflector 2 is not visible in this illustration. As far as the paper strip runs in the feed direction in the direction of the first angle A1. The fixed deflecting pin fU / B is aligned such that its longitudinal axis L3 in the direction bisector of the angle A2 or parallel thereto, as proposed according to claim 4. In addition, the fixed deflecting pin fU / B is arranged so that the center line of the paper strip from the feeding direction cuts the deflection pin fU / B exactly in the middle, so that the paper strip is deflected without causing stress in the Side edges of the paper strip arise. The angle A2 results from the difference of 180 degrees and the first angle A1.

After the deflection of the paper strip on the fixed deflection pin f.U / B, the paper strip is again guided over two deflections 3 and 4 to the tension roller M2S, at which the tensile force in the paper strip for the proposed control of the Zugwalzenpaares Z / W1 is measured. The tension roller M2S thus corresponds to the sensor device for sensing the tensile force, as proposed in the claim 1.

The stationary deflecting pin f.U / B is provided with an adjusting device 13, by means of which the angle A2 or C1 can be slightly adjusted for fine adjustment. During the passage of the paper strip, the fixed deflection pin f.U / B after the fine adjustment is considered fixed, i. the once set angle A1 is then constant. For this purpose, the adjusting device 13 is provided with a lockable locking device, not shown.

After deflecting the paper strip into the transport plane, the paper strip is guided over the pivotally mounted tension pulley M2S, over which the paper strip is tensioned. In addition, the tensile force acting in the paper strip is sensed by means of the tension roller M2S and compared in a control device with a predetermined tensile force. In the event that the sensed Istzugkraft deviates from the predetermined reference tensile force, a control signal to the first Zugwalzenpaar Z / W1 is given to reduce or increase the tensile force, so that compensated for the control difference of the tensile force becomes. The advantage of this solution is the fact that by the arrangement of the fixed deflection pin fU / B between the first Zugwalzenpaar Z / W1 and the tensioning roller M2S, acting on the fixed deflecting pin fU / B on the paper strip frictional forces on the during the further transport movement in the paper strip acting tensile force, since the tensile force is controlled in the paper strip in front of the fixed deflecting fU / B.

The deflection pin fU / B is to be regarded as fixed during the transport movement of the paper strip, but it can be pivoted once for fine adjustment and for the realization of different directions of feeding the paper strip in a small angular range by means of an adjusting device 13. Furthermore, the entire apparatus with the first pair of drawing rollers Z / W1 and the fixed deflecting pin fU / B is arranged on a common frame 14, which can be mounted, if necessary, for the realization of feed directions at a significantly different angle in different orientations, so that feed directions of the paper strip in Any angle can be realized. At the deflecting pin fU / B, a suction device 5 is arranged below the paper strip on the discharge side of the paper strip, by means of which the paper particles dissolving on the stationary deflecting pin fU / B are sucked off. In the present embodiment, the fixed deflection fU / B correspond to the proposed according to claim 1 deflection and the Zugwalzenpaar Z / W1 of the device for changing the tensile force. The sensor device is realized in this case by the measuring device in the tension roller M2S. Of course, a twist device can also be provided on the second paper path II, provided that the paper strip also has to be fed at an angle or should be.

The invention has been described in terms of several individual preferred features and feature combinations. However, it is possible to further develop the device in any other combination of features compared to the prior art, since the features already provide individually recognizable advantages for the skilled person, who individually improve the device in the respective sections. In particular, the novel paper edge control in conjunction with the control of the position of the paper strip at the entrance of the paper runs I and II is a very important control for improving the positional accuracy of the layers in the format section. Furthermore, the novel second-order traction control and the air pressure device offer advantages when using double-layered shell material.

If ultrasound sensors, optical sensors or the like have been described in the embodiment, it is obvious to replace them with other types of sensors at a comparable measurement accuracy.

Claims (9)

Device for transporting strip or strip material for a machine for the production of rod-shaped products of the tobacco-processing industry, which is fed at a first angle (A1) to a transport plane of the strip-like or strip-like material in the device,
characterized in that
in the direction of movement of the strip or strip-like material, starting from the feed, the following devices are provided in the order of their designation: a first device applied to the strip or strip material for changing the tensile force in the strip or strip material, - A the band or strip-shaped material about the first angle (A1) in the transport plane deflecting deflection, and - A sensor device for sensing the tensile force in the band or strip-shaped material, wherein the first means for changing the tensile force in response to the signal of the sensor device is controllable. Apparatus according to claim 1, characterized in that the deflection device has an adjusting device (13) by means of which the angle (C1) between the longitudinal axis (L3) of the deflecting device to the longitudinal axis (L1) of the fed strip or strip-shaped material is adjustable. Device according to one of the preceding claims, characterized in that at least the first device to change the tensile force and the deflection device on a common frame (14) are supported. Device according to one of the preceding claims, characterized in that the deflection device is formed by a fixed deflection pin (fU / B), which is arranged such that its longitudinal axis (L3) an angle (C1) to the longitudinal axis (L1) of the supplied band - or strip-shaped material which is half as large as obtuse angles (A2) between the longitudinal axis (L1) of the supplied strip or strip material and the transport plane. Apparatus according to claim 4, characterized in that on the fixed deflecting pin (fU / B) directed towards the discharge side of the strip or strip material suction device (5) is provided. Device for transporting strip or strip-shaped material for a machine for the production of rod-shaped products of the tobacco-processing industry, which is set up so that the strip or strip-like material from different first angles (A1) to a transport plane of the strip or strip-shaped material in the device is fed, characterized in that on the inlet side of the strip or strip-shaped material, a device for displacing the strip or strip-shaped material transversely to the longitudinal axis (L1) is provided, which in dependence of a in the direction of the belt or strip-shaped material according to a spreading device (15) arranged position sensor (B19S) can be controlled. Device for transporting strip or strip-shaped material for a machine for the production of rod-shaped products of the tobacco-processing industry, which is guided in two superimposed layers by means of a deflection device (7, 18) and placed on a format strip advancing the layers, the layers respectively in different paper runs (I, II) are fed, characterized in that in the paper path (II), not directly on the format strip (9) to the plant reaching position, a tension roller is provided which indirectly or directly depending on a between the tensioning roller and the deflection device (7,17) arranged force measuring device (12) is controllable. Apparatus according to claim 7, characterized in that a device (19) is provided, by means of which the non-reaching on the format tape position in the area of the deflection device (7,18) can be acted upon with an additional pressure. Apparatus according to claim 8, characterized in that the device (19) is an air pressure device.

Images