EP0566933A2 - Method of and device for transporting a material web - Google Patents

Abstract

A method and a device for transporting a material web (13 or 32) are described, in which a material web is transported by means of a feed-roller pair (7, 22) along a transport path (1, 2) into the cutting zone (3) of a circulating knife (38) interacting with a stationary knife (39). To interrupt the material web transport for reasons of specific operating conditions, in the last operating cycle before stoppage it is first accelerated to an excess velocity and then brought to a stop in the next step. On restarting the same web or starting a different material web (32), on bobbin exchange, the material web is first accelerated to an excess velocity in the first operating cycle after the stoppage and then slowed to the intended operating velocity, so that the first cut takes place already in register at operating velocity. This procedure has the advantage that reject material is reduced because no unrequired web sections are produced. <IMAGE>

Description

The invention relates to a method for conveying a material web, in particular a strip of contiguous labels, in which a material web is drawn off from a supply and moved to a cutting device with at least one revolving knife, successive sections (labels) of a predetermined length by successive cuts of the knife predetermined work cycle are separated from the material web and the movement of the material web is interrupted at least temporarily depending on predetermined operating conditions.

The invention also relates to a device for conveying a material web, in particular a strip of contiguous labels, from a supply to a cutting device, which has at least one revolving knife for separating sections (labels) of a predetermined length from the moving material web, with one oriented towards the cutting device Conveyor line for a material web and conveying means for moving the material web along the conveyor line to the cutting device and for interrupting the material web movement depending on predetermined operating conditions.

It is known from a running material web with a revolving knife, which interacts with a counter knife, to successively cut off sections of a predetermined length, such as, for example, packaging material blanks in a packaging machine or labels in a labeling machine. A corresponding device for feeding a packaging material web to a packaging machine is described, for example, in DE 24 35 441 C 2. While packaging material blanks are continuously cut off from a running material web, this is the beginning of a second material web in a starting position so that the supply of packaging material to the cutting device or to the connected packaging machine does not have to be interrupted when the end of the first material web is reached. As soon as the first material web has been used up, the second material web is started, so that the packaging material blanks are now separated from it. When changing from one material web to another, incorrect cuts result, which lead to products that are not packed or packaged incorrectly. With the device described in DE-PS 12 33 686, it is possible to connect the beginning of a second material web without gaps and without adhesion to the end of a running first material web. However, none of these devices allows the supply of the material web to be briefly interrupted as required and to be started again as required after the interruption.

The invention is therefore based on the object of further improving a method and a device of the type specified at the outset. In particular, the conditions when stopping and starting a material web in a labeling machine or in a packaging machine are to be optimized.

In a method of the type described in the introduction, this object is achieved according to the invention in that the material web is moved into a register-correct cutting position in the last work cycle before and / or in the first work cycle after an interruption of the material web movement. If the supply of the material web is to be interrupted, its movement is controlled in the last working cycle before stopping so that the material web stops in its next cutting position in accordance with the register. Conversely, the movement of the material web in the first work cycle of the start-up is controlled in such a way that at the end of this work cycle it is already at its intended conveying speed passes through the following cutting position in accordance with the register.

According to the invention, the material web is moved between the penultimate and the last cut before an interruption of the material web movement into a register-correct cutting position and stopped there, so that the last cut is made while the material web is still. In order to achieve this, the conveying speed of the material web according to the invention is first increased to a predetermined overspeed in the last work cycle before a material web stoppage, the material web is decelerated from the overspeed and stopped in the intended cutting position in accordance with the register in order to separate the next section. The fact that the material web is conveyed at a predetermined excess speed before stopping compensates for a loss of length which occurs when the material web is braked from its regular conveying speed to zero. In this way it is possible to bring the material web to a standstill in its cutting position in accordance with the register within one work cycle. Conversely, according to the invention, when the material web is started after a standstill, the material web is first accelerated to a predetermined overspeed in the first working cycle after an interruption of the material web movement and is then conveyed at its operating speed in the first cut after the material web stoppage. Here the temporary excess speed of the material web compensates for the loss of length caused by the acceleration of the material web from zero to the operating speed.

Further continuations and refinements of the method are contained in subclaims 5 to 8. This includes claim 5 special features for controlling the conveying speed of the material web during stopping and starting. Claim 6 contains features that relate to the change of the material web. An uninterrupted supply of the strip material is thus possible when a supply of strip material runs out and a second supply has to be accessed.

In the case of a device of the type described in the introduction, the object on which the invention is based is achieved in that the conveying means comprise a feed means which moves the material web to the cutting device and that the feed means is controlled in such a way that the material web moves towards or before the material web movement is interrupted following the stopping or starting of the material web, the cut is in register with its intended cutting position.

Further developments and refinements of the device according to the invention are contained in subclaims 10 to 22.

The invention offers the advantage of always feeding a material web to a cutting device according to the register, which separates sections, such as labels, of predetermined length from the material web. For this purpose, the invention makes it possible to stop the material web specifically for individual or several cycles even at high production speeds of modern high-performance machines and then to start it up again in accordance with the position and register. In this way, the cutting of sections that are not currently required from the material web can be prevented, which leads to a reduction in rejects and an increase in economy. The invention is also of particular use for the reel change at the end of a material web, because it provides a seamless, register-correct and scrap-free connection of the new material web to the guaranteed end of the old material web guaranteed. It is not necessary that the running web of material is used up to the end, which can have certain disadvantages. Rather, the invention allows the running material web to be stopped at any point in accordance with the register and the subsequent sections to be separated from a new material web. If necessary, different sections can be separated from both material webs.

The invention will now be explained in more detail with reference to the drawing.

Figur 1

eine Vorrichtung nach der Erfindung in einer ausschnittsweisen Schnittansicht,

Figur 2

eine Ansicht der Vorschubwalzen in Richtung des Pfeils B in Figur 1, teilweise geschnitten,

Figur 3

ein Kenngrößendiagramm, das das Anhalten der Materialbahn zeigt,

Figur 4

ein Kenngrößendiagramm, das das Anfahren der Materialbahn zeigt und

Figur 5

eine schematische Detaildarstellung des Konvergenzbereichs K der Förderstrecken der Materialbahnen.

Show it

Figure 1

a device according to the invention in a sectional view,

Figure 2

2 shows a view of the feed rollers in the direction of arrow B in FIG. 1, partly in section,

Figure 3

a characteristic diagram which shows the stopping of the material web,

Figure 4

a characteristic diagram showing the start of the material web and

Figure 5

a schematic detailed representation of the convergence area K of the conveyor lines of the material webs.

In Figure 1, a device according to the invention is shown in a partially sectioned schematic side view. The drawing contains only the parts of the device which are necessary for an understanding of the invention. The device has two conveyor lines 1 and 2, which converge towards the cutting zone 3 of a cutting device 4. The conveyor sections 1 and 2 are delimited against each other by a wedge-shaped guide body 6, the tip of which points towards the cutting zone 3.

The conveyor track 1 is assigned a pair of feed rollers 7, which consists of axially parallel feed rollers 8 and 9, which touch on their circumference with a predetermined force. The feed roller 8 is driven by means of a motor 11, which also drives the other feed roller 9 synchronously via a gear transmission 12 made of gear wheels 12a and 12b shown in FIG. The feed roller pair 7 detects a material web 13 between the rollers 8 and 9 and conveys them in the direction of arrow 14 to the cutting zone 3. From the feed roller 8 to a front deflecting roller 16 arranged in the region of the cutting zone 3, at least one suction conveyor belt 17 rotates, the conveying run of which includes one Vacuum chamber 19 connected to a vacuum source 18 is subjected to suction air, so that the material web 13 bears against the suction conveyor belt 17 under the action of the suction air and is safely moved to the cutting zone 3. The suction conveyor belt 17 is driven by a drive 21 via the front deflecting roller 16.

The conveyor section 2 is assigned a second pair of feed rollers 22 with feed rollers 23 and 24, of which the feed roller 23 is driven by a motor 26, while the second feed roller 24, like the pair of feed rollers 7, has a gear mechanism 12 made of gear wheels 12a and 12b (FIG. 2) is driven. The conveyor section 2 is also a suction belt conveyor 27 assigned, which is driven by its motor 21 via its front deflecting roller 28 and whose conveying run is acted upon by a negative pressure source 31 from a negative pressure source 31 via a negative pressure chamber 29, so that a material web 32 moving in the conveying path 2 of the one acting through the conveying run of the suction belt conveyor 27 Suction air is attracted.

The feed rollers 8 and 9 or 23 and 24 have a rubber jacket 33 on their circumference (see FIG. 2) and are pressed in pairs against each other with springs, not shown. A flattening occurs in the contact zone of adjacent rollers, which is a straight line on both rollers due to the rubber coating. This avoids that the material web bends due to the pressure of the feed rollers. This is advantageous particularly in the case of small roller diameters, which are expediently chosen with regard to a low moment of inertia. In addition, there are defined speed ratios between the feed rollers and the material web, because the transmitted frictional force is greater than with the generally common pairings of steel rollers and rubber rollers.

The cutting device 4 consists of a knife roller 36 rotating in the direction of the arrow 34, in the circumference of which a knife 38 is inserted, which is oriented transversely to the conveying direction 14 or 37 of the material webs 13 or 32. Of course, several knives can also be provided on the circumference of the knife roller 36. The knife 38 interacts with each rotation of the knife roller 36 for cutting with a stationary counter knife 39 in order to separate successive web sections from the respectively running material web 13 or 32 in a work cycle predetermined by the cutting sequence of the knife 38. To minimize wear on the knives, they are preferably made of hard metal. The knife roller 36 with the knife 38 is preferably driven continuously. For this reason, a relatively large radius can be selected for the knife roller, which has the advantage that the material web is always guided and pulled before and after cutting by the outer surface of the knife roller, from which the knife 38 protrudes only by a small amount .

The sections separated from the respectively running material web 13 or 32 are successively taken over by a suction belt conveyor 41, the conveying section of which is subjected to a negative pressure from a vacuum source 42 via a vacuum chamber 43, so that the sections on the suction belt conveyor 41 are held securely while they are in motion be transported away for further processing. The vacuum chambers 19, 29 and 43 can of course all be connected to a common vacuum supply.

The machine control has a control arrangement 44, which has sensors 46 and 47 on the input side for detecting print marks on the material webs 13 and 32, as well as with rotary angle transmitters 48, 49 and 51 for detecting the speed and the phase position of the knife roller 36 and the feed rollers 8 and 23 connected is. On the output side, the drive motors 11 and 26 are connected to the control arrangement 44.

FIG. 2 shows, in a partially sectioned view in the direction of arrow B in FIG. 1, the feed roller pair 7 with the feed rollers 8 and 9. As already mentioned above in connection with the description of FIG. 1, the feed rollers have a rubber jacket 33 on their peripheral surface. which increases the frictional resistance to the material web to be conveyed. The rollers are provided with radial constrictions 52 and 53 at a uniform axial distance. In the radial constrictions 52 of the feed roller 8 (and correspondingly also the feed roller 23 of the pair of feed rollers 22), deflection rollers 54 are freely rotatable, by which a suction conveyor belt 17 rotates axially next to each other. This results in a belt section consisting of suction conveyor belts 17 running parallel to one another, which reliably moves the material web 13 to the cutting zone 3. The roller bodies of the feed rollers 8 and 9 are provided with cutouts 56 in order to reduce their inert mass. For the same reason, the diameter of the rollers is chosen to be as small as possible. In the radial constrictions 53 of the feed roller 9 (correspondingly also the feed roller 24 of the feed roller pair 22), webs 57 of the stationary guide body 6 (see FIG. 1) engage, which ensure reliable guidance of the material web. The rollers 8 and 9 as well as the rollers 23 and 24 are mounted partly in the machine frame 58 and partly in the motor flange 59 carried by the machine frame.

3 and 4, the function of the device shown and the method according to the invention are described. Figure 3 shows in a diagram the course of the speed v and the length L of the material web drawn off in two successive cycles T₁ and T₂ when stopping the material feed. It is assumed that, for example, the material web 13 is moved in regular operation at an operating speed V _B in the direction of arrow 14 to the cutting zone 3. In Figures 3 and 4, the curve of the speed curve is marked with crosses (x). While the material web 13 is conveyed in the work cycle T 1 at a constant speed V _B , a section of the length L _{B (1) of} the material web is conveyed through the cutting zone 3. At the end of the cycle T ₁ , a cut is made with the knife 38 with which the section of length L _{B (1) is separated} from the material web. The length L _{B (1)} is equal to the useful length of the section that has been cut off.

In the following work cycle T₂, the material web is to be stopped depending on predetermined operating conditions, for example because precisely no article to be labeled or packaged is available or because the material web is coming to an end and must be changed to a new material web. For this purpose, the drive 11 of the feed roller pair 7 is controlled by the control arrangement 44 according to a predetermined program so that the material web 13 is first accelerated to an overspeed V _M and is decelerated from this overspeed to a standstill. At the end of the work cycle T₂, that is, in the following cut with the rotating knife 38, the material web has reached its standstill position. If the material web were brought to a standstill directly from its operating speed V _B , the section separated from the material web at the end of the cycle T 2 would be shorter than the sections which are separated from the web conveyed at operating speed V _B because of the conveying speed falling below the operating speed . This section should be treated as a committee. By accelerating the material web to the overspeed V _M , this is avoided since at the beginning of the cycle T₂, more is deducted from the material web than at operating speed due to the overspeed, so that the web feed deficit caused by the deceleration of the material web to a standstill by the the excess speed of the material web caused excess web feed is compensated. The extended part of the length curve L in the work cycle T₂ shows the temporary excess length caused by the overspeed compared to the length shown in the dashed part of the curve of the length curve L, deducted with a constant conveying speed. The overspeed is dimensioned so that the deducted excess length is just sufficient to cause the speed deceleration to a standstill Compensate for loss of length. The length L _{B (2)} of the section separated from the stopped material web at the end of the work cycle T₂ is therefore equal to the length L _{B (1) of} the sections separated from the material web at a constant operating speed v _B in the preceding work cycles.

The reverse process is shown in the diagram in FIG. During the feed interruption of the material web, the knife roller 36 rotates further with the knife 38. At the beginning of the work cycle T _n , the feed of the material web is started again. A simple interruption of the feed can be the same material web that was previously stopped, but a new material web can also be started when the reel is changed, the prepared start of which has been brought into a register-correct starting position. In both cases, the process is the same. As the curve curve of the speed marked again with cross (x) in FIG. 4 shows, the material web is first accelerated to an overspeed v _M in the first working cycle T _n after the standstill, before it decelerates again to the operating speed v _B towards the end of the working cycle is reached at the latest at the end of the work cycle, ie the following cut. Here, too, the excess length of the drawn-off material web end achieved with the excess speed compensates for the length loss which occurred in the start-up phase with the conveying speed being below the operating speed. At the end of the start-up cycle T _n , a section of material of just the intended useful length L _{B (1)} has therefore been pulled off, so that the material web is exactly in its register-correct cutting position. In the next cycle T _{n + 1} , the material web moves exactly at the predetermined operating speed V _B , so that the useful length L _{B (2) is again} subtracted and separated from the material web in each cycle. The procedure described thus enables the feed of a running material web to be interrupted for a short time and in the process to cut off sections of the intended useful length from the material web to the last cut or from the first cut without registering material loss and waste. It is therefore a very efficient process that can be used with great advantage to separate labels from running material webs.

With the aid of the measurement signals emitted by the speed and phase sensors 48, 49, 51 and the print mark sensors 46 and 47 and the control arrangement 44, which processes the measurement signals into corresponding control signals for the drives, the speeds of the material web and the knife are controlled such that a guaranteed promotion of the railway and separation of the sections are always guaranteed. The speed of rotation of the suction belts 17 and 27 is greater than that of the roller pairs 7 and 22. The speed of the suction belt 41 in turn exceeds that of the belts 7 and 22. This keeps the web taut and the separated sections are brought apart from one another. which is necessary for their further processing. As already mentioned above, before a reel change, the start of a second material web (for example 32) is already brought into a register-correct starting position in the cutting area 3 of the cutting device 4 when the first material web (for example 13) is still being fed and processed. In order to facilitate the process of inserting the start of the web into the starting position and to prevent both webs from interfering with one another in the cutting area, a slot nozzle 64 is arranged in the convergence area K of the guide surfaces 61 and 62 of the guide body 6, the air outlet slot 66 between the material webs 13 and 32 is aligned with the cutting area 3. Figure 5 shows in connection with figure 1 the arrangement and design of this slot nozzle. As can be seen in FIG. 1, the guide body 6 consists of two plates 67 and 68, which are beveled in a wedge shape along a front joining surface and are assembled to form the guide body 6 converging towards the cutting region 3. The joining surfaces of the plates 67 and 68 enclose a blowing air channel 63 which runs transversely to the conveying direction of the material webs and to which a blowing air nozzle 64 with a slot-like blowing air opening 66 is connected. The blown air opening 66 is directed towards the cutting area 3 of the knife 38. In FIG. 5, which shows a side view of the convergence region of the material web guides with the plate 67 removed in the direction of arrow K, it is shown that the blown air channel 63 is guided laterally out of the guide body 6 and through the machine frame 69 and is connected to a pressure source 71. The blow air flow through the slot nozzle 66 can be switched on and off with an interposed valve 72.

The slot nozzle 66 extends over the entire width of the material webs 32 and 13 and is very flat. Their width in the direction of the surface normal on the joint surface is approximately 0.1 mm, but can of course also be chosen larger or smaller if the operation requires it. In order to realize such a slot nozzle, one or both joining surfaces of the plates 67 and 68 can be ground or milled accordingly. A simpler method consists in inserting a paper seal 73 of appropriate thickness into the joining surface, which, as shown in FIG. 5, can be approximately U-shaped. The two side legs of the u-shaped paper seal limit the blown air duct 64 in the area of the joint surface to the sides, and the base U seals the joint surface on the rear side of the blown air duct 63. The thickness of the paper seal 73 determines the width of the blown air line and the size of the blown air nozzle. These Arrangement thus ensures that the system can be operated without problems, even if two webs of material are at the same time in the cutting zone of the rotating knife 38. The blow air flow from the slot nozzle 66 forms an air cushion between the two web ends positioned there and ensures a smooth movement of the material web to be processed. For this reason, the blown air flow only needs to be switched on during the lane change. As long as only one path passes through the Schnaid zone, the blown air flow is interrupted by means of the valve 72. Instead of a single wide slot nozzle, it is of course also possible to provide a plurality of narrower nozzles, it being only important that the emerging air flow between the two supplied or positioned webs forms an air cushion which facilitates the relative movement.

For the sake of completeness, it is pointed out that FIG. 1 shows a top view and FIG. 5 shows a side view in the direction of arrow K of the device according to the invention. The material webs 13 and 32 are therefore preferably moved horizontally in vertically oriented conveyor tracks.

Claims (22)

Method for conveying a material web, in particular a strip of contiguous labels, in which a material web is drawn off from a supply and moved to a cutting device with at least one revolving knife, successive sections (labels) of a predetermined length in a work cycle predetermined by successive cuts of the mass Material web are separated and the movement of the material web is at least temporarily interrupted depending on predetermined operating conditions, characterized in that the material web is moved in the last working cycle before and / or in the first working cycle after an interruption of the material web movement in a register-correct cutting position. A method according to claim 1, characterized in that the material web is moved and stopped in a cutting position according to the register between the penultimate and the last cut before an interruption of the material web movement, and in that the last cut is made while the material web is at a standstill. A method according to claim 1 or 2, characterized in that the conveying speed of the material web in the last working cycle before a material web stoppage is first increased to a predetermined overspeed and that the material web is then decelerated and stopped in accordance with the registration in the intended cutting position for the separation of the next section. Method according to one of claims 1 to 3, characterized in that the material web in the first working cycle after an interruption of the material web movement, it is first accelerated to a predetermined overspeed and then decelerated to a predetermined operating speed, and that the first section is separated from the material web conveyed at the operating speed after the material web stoppage. Method according to one of Claims 1 to 4, characterized in that the conveying speed of the material web during the last work cycle before and / or during the first work cycle after a standstill is controlled in such a way that the material web is decelerated to a standstill or when starting due to your acceleration from standstill to operating speed, the web feed deficit is compensated for by a web feed excess caused by an excess speed of the material web. Method according to one of claims 1 to 5, characterized in that, during the continuous conveyance of a first material web to the cutting device, the front end of a second material web is brought into a register-correct starting position with respect to the cutting line of the knife, so that the conveying speed of the first material web initially increases in one working cycle a predetermined overspeed is increased and then reduced to zero, so that the first material web is stopped in register position and the next section is separated from the holding material web, that in the following working cycle the second material web is first accelerated to a predetermined operating speed and then to the first cut is promoted in register law with the operating speed. Method according to one of claims 1 to 6, characterized in that the sections separated from the material web are conveyed away at an increased speed for further use. Method according to one of claims 1 to 7, characterized in that the knife continues to rotate at its predetermined peripheral speed even during a material web standstill. Device for conveying a material web, in particular a strip of labels attached to one another, from a supply to a snap device, which has at least one revolving knife for separating sections (labels) of a predetermined length from the moving material web, with a conveying line for a material web running towards the cutting device and Conveying means for moving the material web along the conveying path to the cutting device and for interrupting the material web movement depending on predetermined operating conditions, characterized in that the conveying means comprise the feed means (7, 22) moving the material web (13, 32) to the cutting device (3) and in that the feed means (7, 22) is controlled such that the material web is in its intended cutting position in accordance with the index before or after an interruption of the material web movement to the cut following the stopping or starting of the material web indet. Apparatus according to claim 9, characterized in that the feed means (7, 22) is connected to a control arrangement (44) which controls the feed means in such a way that the material web (13, 32) between the penultimate and the last cut before an interruption the material web movement in moves a register-correct cutting position and stops there to make the last cut. Apparatus according to claim 9 or 10, characterized in that the control arrangement (44) of the feed means (7, 22) is designed to be snowing and then to stop when a predetermined operating condition occurs in the last working cycle (T₂) before a material web stoppage to a predetermined overspeed (v _M ) , in such a way that the material web (13, 32) comes to a standstill in a designated cutting position in order to separate the next section. Device according to one of claims 9 to 11, characterized in that the control arrangement (44) accelerates the material web (13, 32) in the first working cycle (T _n ) after a material web stoppage to a predetermined overspeed (v _M ) and then to the operating speed ( v _B ) is designed to be delayed in such a way that the material web for separating the first section is moved in register with its predetermined conveying speed (v _B ) after a standstill. Device according to one of claims 10 to 12, characterized in that the control arrangement (44) pre-forms the speed of the feed means (7, 22) including its overspeed (v _M ) such that a material web (13, 32 ) until standstill or as a result of their acceleration, the speed deficit arising from standstill is compensated for in the current work cycle (T₂, T _n ) before the next cut. Device according to one of claims 9 to 13, characterized in that pairs of rollers driven as feed means (7, 22) are provided, which grip the material web (13, 32) non-positively between them and move them at the respectively provided conveying speed. Apparatus according to claim 14, characterized in that the respective cooperating rollers (8,9; 23,24) of a pair of feed rollers (7,22) have a rubber-elastic peripheral surface covering (33). Device according to one of claims 9 to 15, characterized in that the conveying means have at least one revolving suction belt conveyor (17.27) downstream of the feed rollers (7, 22). Apparatus according to claim 16, characterized in that the suction belt conveyor (17.27) rotates at a higher web speed than the feed rollers (7.22). Device according to one of claims 9 to 17, characterized in that two conveying sections (1, 2) converging in the cutting zone (3) of the rotating mass (38) are provided, that each conveying section is provided with conveying means for moving a material web (13, 32) Are assigned to the cutting zone and that the conveying means (7, 22) are driven separately, connected to the control arrangement (44) and controlled. Apparatus according to claim 18, characterized in that the control arrangement (44) is designed to control the feed means (7, 22) of both conveyor lines (1, 2) in such a way that the cutting device (4) receives the in two successive work cycles (T₂, T _n ) Material web (13) in the first conveyor section (1) in the first working cycle (T₂) first accelerated to an overspeed (v _M ) and then for separation of the last section is stopped in accordance with the register and the material web (32) in the second conveyor section (2) is accelerated from standstill to an excessive speed (v _M ) in the second working cycle (T _n ) and then for the first cut to the intended conveyor speed (v _B ) is delayed. Device according to one of claims 9 to 19, characterized in that measuring means (46, 47) for detecting printing marks on the material web (13, 32) are assigned to each conveyor section (1, 2), that measuring means (48, 49, 51) for detecting the angular position of the rotating knife (38) and the speed of the feed rollers (7, 22), it is provided that the measuring means are connected to the control arrangement (44) and that the control arrangement means the feed rollers as a function of the measured values of the detected quantities web sections (labels) of equal length and register-oriented separating cuts are designed to control. Device according to one of claims 9 to 20, characterized in that two guide surfaces (61, 62) tapering in a wedge shape towards the cutting zone (3) of the knife (38) are provided for the material webs, and in that at least one to a blown air line (63 ) connected blowing air nozzle (64) and is aligned with the convex area of the guide surfaces. Apparatus according to claim 21, characterized in that at least one slot-like blown air opening (66) is arranged in the cutting line of the wedge-shaped converging guide surfaces (61, 62) and is aligned with the cutting zone (3) of the knife (38).

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