EP0666152A1 - Apparatus for the deformation of blanks or webs - Google Patents

Abstract

The device has a roller device (8,9) that presses the section or band against the deformation components (6,7), whereby the table and roller arrangement (2,3,8,9) are movable relative to one another parallel to the processing side. The table device has two processing tables (2,3) with deformation components (6,7) and the roller device has two pressure roller units (8,9). For each processing table, its own pressure roller unit (8,9) is provided. The pressure roller units and/or the processing table are driven counterwise. The pressure roller units are arranged adjacent to the operating sides of the processing table. A transport unit is provided for moving the sections through the device.

Description

The invention relates to a device for deformation, in particular for punching and / or embossing blanks or tapes, in particular made of cardboard, with a table device which bears protruding deformation elements on the processing side, and with a roller device for pressing the blank or strip against the deformation elements, table - And roller arrangement can be moved relative to one another parallel to the processing side by means of a drive.

Various devices are known for punching and embossing blanks or strips. Basically, they have a processing table, which is usually provided with deformation elements on the top. These are essentially vertical punching knives or embossing bars. In order to press the material web to be processed against these deformation elements, the devices have pressure elements in the form of press rams or cylindrical or conical pressure rollers. The latter have the advantage that a high local stamping or embossing pressure can be generated due to the line contact of the jacket with low forces. However, it is necessary to move the pressure roller and processing table relative to each other so that the jacket of the pressure roller can sweep over the entire processing side.

There are various suggestions as to how this relative movement can be realized. It is known from DE-GM 78 31 892, a pair of pressure rollers arranged one above the other simultaneously over the top and bottom of a flexible, however, to move the stationary work table. Similar arrangements can be found in DE-OS 36 14 575 and DE-OS 21 56 829 with the difference that pressure rollers are only moved over the top, which is also the processing side. DE-PS 36 0̸8 113 shows a kinematically reversed solution, in which fixedly mounted pressure rollers are provided on the top and bottom of a flexible processing table and the processing table with the blank to be processed is moved through the press nips formed by the pressure rollers.

The known devices can sometimes only be operated discontinuously. Their flexibility in terms of the type and extent of the deformations is also insufficient compared to today's requirements.

The invention is therefore based on the object of designing the simplest possible device of the type mentioned at the outset in such a way that blanks or strips can be processed as quickly and flexibly as possible.

This object is achieved in that the table arrangement has two processing tables with deformation elements and that the roller device has two pressure roller units, each processing table being assigned its own pressure roller unit and the processing tables and / or the pressure roller units being driven in opposite directions. The alternative with oppositely moving pressure roller units and stationary processing tables is particularly advantageous because it can be designed in a structurally simple manner and enables the blanks or strips to be pulled through quickly and easily.

With the aid of the device according to the invention, the processing of the blanks or strips is distributed over two processing tables within one device. This leaves it for example to only provide punching knives on the first processing table in the processing direction and only embossing strips on the second processing table, i.e. to distribute punching and embossing over two work steps. This opens up more processing options and also better mutual coordination. It is particularly advantageous that the moving parts of the device are driven in opposite directions, so that no free inertia forces occur during their acceleration and deceleration, so that short cycle times can be achieved with a simple and therefore inexpensive device construction.

The basic idea of the invention can be realized in any configuration of the pressure roller units, that is to say also in those which have one or more pressure rollers on both sides of the processing tables, the processing tables being able to be rigid or flexible. For most purposes, however, it is sufficient if the pressure roller units are arranged only adjacent to the machining sides of the machining tables, which presupposes the rigidity of the machining tables, and if the pressure roller units each have only one pressure roller.

In a further embodiment of the invention it is provided that a transport device for transporting the blanks through the device is provided, which has transport elements for gripping the blanks on an edge lying transversely to the transport direction, and that the pressure rollers have recesses on the circumference which are designed in this way and are arranged so that they are opposite the transport device in the region of the dead center of the roller movements so that a collision with the transport elements is avoided. This can be designed in such a way that the pressure rollers have a smaller diameter over a first circumferential section than over a second circumferential section, the second circumferential sections interacting with the deformation elements during the movement over the processing tables. This training enables it to arrange the usual transport devices in these areas without collisions between the pressure rollers and the transport elements.

According to a further feature of the invention, it is provided that at least one guide device is provided for the precise rotation of the pressure rollers. This guide device can be designed as one or more roller tracks on which guide wheels seated on the axis of rotation of the pressure rollers roll. This can also be done in such a way that at least one of the roller tracks is designed as a toothed rack and the guide wheels are designed as toothed wheels. Due to the positive engagement, it is ensured that the rotational position is always such that a collision between the transport element and the pressure rollers is excluded.

The processing tables are expediently arranged next to one another in a plane and preferably so that the processing sides of the processing tables lie horizontally on the top. This conventional arrangement has proven itself in single table devices. However, this does not conflict with arranging the processing tables vertically and with their backs facing each other.

In a further embodiment of the invention it is provided that the drive is designed such that the speed of the movement of the pressure roller units and / or the processing tables has a maximum in the middle of the path and does not decrease linearly to the end points of the path. This should preferably be a sinusoidal movement, as is caused by crank drives.

It is further provided that the pressure roller units are held on both sides on drive belts, for example drive belts designed as toothed belts, which can be moved back and forth via the drive. The drive should at least have a meshing gear pair that cooperates with the drive belts, the gear pair being driven by a crank mechanism. In order to be able to adjust the stroke of the pressure roller units, the angle of rotation of the gear pair (s) should be adjustable.

According to the invention it is proposed that the drive has a motor and a gear unit which causes the opposite movement. The gear unit should be designed in such a way that the dead centers of the roller movements of the pressure roller units lie outside the processing tables. This design is particularly advantageous if the pressure rollers have recesses in the sense mentioned above in order to avoid a collision with the transport elements.

At least one crank drive is particularly suitable as a gear here, expediently with a common crankshaft which has two crank pins offset by 180 °, which are connected to the pressure rollers and / or the processing tables. In addition, a step gear can be connected upstream of the gear. Such a stepping gear converts the continuous rotary movement coming from the motor into a stepping movement of the output shaft, with the aid of a globoid roller on the input side and an output disk provided on the circumference with roller bolts. The advantage of such a step mechanism is that the Globoïd roller enables a particularly smooth and low acceleration movement sequence of the opposing elements. Operation and motor should preferably be arranged between the processing tables in order to use this space.

Finally, it is provided according to the invention that the roller axes of the pressure roller units are inclined to the deformation elements. In this way, there is at most point contact with elongated deformation elements and not line contact. This allows punching and Emboss the blanks or strips with much less force.

Figur 1

eine perspektivische Draufsicht auf eine Vorrichtung zum Stanzen und Prägen von Zuschnitten und Bändern;

Figur 2

eine schematische Seitenansicht der Vorrichtung gemäß Figur 1 in der Ansicht C mit außenliegenden Andrückwalzen und

Figur 3

die Seitenansicht gemäß Figur 2 mit innenliegenden Andrückwalzen;

Figur 4

eine perspektivische Draufsicht auf eine gegenüber Figur 1 abgewandelte Vorrichtung zum Stanzen und Prägen von Zuschnitten;

Figur 5

eine schematische Seitenansicht der Vorrichtung gemäß Figur 4 in der Ansicht C mit außenliegenden Andrückwalzen und

Figur 6

die Seitenansicht gemäß Figur 5 mit innenliegenden Andrückwalzen und

Figur 7

eine perspektivische Draufsicht auf eine weitere abgewandelte Vorrichtung zum Stanzen und Prägen von Zuschnitten.

In the drawing, the invention is illustrated in more detail using an exemplary embodiment. Show it:

Figure 1

a top perspective view of a device for punching and embossing blanks and tapes;

Figure 2

is a schematic side view of the device according to Figure 1 in view C with external pressure rollers and

Figure 3

the side view of Figure 2 with internal pressure rollers;

Figure 4

a perspective top view of a device modified compared to Figure 1 for punching and embossing blanks;

Figure 5

is a schematic side view of the device according to Figure 4 in view C with external pressure rollers and

Figure 6

the side view of Figure 5 with internal pressure rollers and

Figure 7

a top perspective view of another modified device for punching and embossing blanks.

The device (1) has two stationary processing tables (2, 3), which are arranged horizontally next to one another and rest on a device frame (not shown here). There is a frame on the top of each of the processing tables (2, 3) (4, 5) fixed. In the frame (4) lying first in the machining direction, vertically upright punching knives - designated by way of example (6) - are arranged. In the other frame (5) there are also vertically upstanding embossing strips - designated by way of example with (7) - the embossing stamp.

Above the processing tables (2, 3) two cylindrical pressure rollers (8, 9) are arranged in such a way that their roller shells (10̸, 11) have horizontal surface lines. They can be moved horizontally in the directions of the double arrows (A, B), these directions being inclined at a small angle to the sides of the frames (4, 5). The stub axles (12, 13) and (14, 15) of the pressure rollers (8, 9) are guided in slot guides (not shown here) in such a way that they carry out a horizontal translation movement over the processing tables (2, 3). In Figure (1) they are located near the outer end points.

At the free ends, the stub axles (12, 13) or (14, 15) are connected to crank rods (16, 17) or (18, 19). The crank rods (16, 17) or (18, 19) on one side each lead to a common crank mechanism (20̸, 21). Both crank drives (20̸, 21) are connected by a common drive shaft (22).

The crank mechanism (20̸) seated at the free end of the drive shaft (22) has two crank disks (23, 24) which are connected via a crank pin (25) to which the crank rod (16) is articulated. On the free outside of the outer crank disk (24) there is another crank pin (26) which is offset by 180 ° from the crank pin (25) and on which the crank rod (17) is articulated.

The crank mechanism (21) located on the other side has three crank disks (27, 28, 29), which are each connected via crank pins (30̸, 31) offset by 180 °. On one crank pin (30̸) are the crank rod (19) and on the other crank pin (31) the crank rod (18) articulated.

Another section of the drive shaft (22) adjoins the crank disk (29). It leads into the driven side of a stepping gear (32) and is connected on the inside to a driven pulley which carries on its jacket a plurality of roller bolts which are freely rotatable about axes extending in the radial direction. The roller bolts engage in a Globoïd roller, which carries cams on its jacket, on which the roller bolts are supported. The globoid roller is connected to an electric drive motor (34) via an input shaft (33).

The drive motor (34) performs a constant rotary movement. This is converted into a stepping movement in the stepping gear (32). The drive shaft (22) carries out a rotary movement of 180 ° with each step. As this also causes the crank pins (25, 26, 30̸, 31) to be pivoted through 180̸ °, the result is that the pressure rollers (8, 9) are moved from one dead center position to the other dead center position. The cams on the Globoid roller within the stepping gear (32) are shaped so that a gentle, i.e. smooth movement with low accelerations is guaranteed.

The sequence of movements of the pressure rollers (8, 9) is illustrated in more detail in FIGS. (2) and (3). The crank disks (23, 24, 27, 28, 29) as well as the stepper gear (32) and the drive motor (34) are omitted in these figures. In addition, the crank rods (16, 17) are only shown as lines and the crank pins (25, 26) only as points.

Figure (2) shows the position of the pressure rollers (8, 9) in the outermost dead center position, in which the roller shells (10̸, 11) of the pressure rollers (8, 9) no longer come into contact with the punching knives (6) or embossing strips (7) to have. The crankpin (25, 26) are accordingly located on the side of the crank rods (16, 17) articulated on them. In this position, a sheet blank can be placed on the punch knives (6) or embossing strips (7) with the aid of a conventional transport device, not shown here, in a precisely defined position. The transport device can be a transport device that moves over both processing tables (2, 3) in the plane of the drawing and that successively cuts into the device (1).

After storing the blanks, the drive shaft (22) is turned by 180 °. Accordingly, the crank pins (25, 26) pivot by the same amount and then assume the position shown in Figure (3). As a result of this rotary movement, the pressure rollers (8, 9) are moved over the punching knives (6) or embossing strips (7), whereby they exert such pressure on the blanks that the punching knives (6) cut through the blank and the embossing strips (7 ) Cause embossing, for example in the form of folds or embossing patterns. The distance between the crank pins (26, 27) and the center point of the drive shaft is dimensioned such that when the drive shaft (22) rotates 180 °, both pressure rollers (8, 9) are moved over the entire surface, which the frame (4 , 5) is narrowed down. The pressure rollers (8, 9) then assume the inner dead center position, as can be seen in FIG. (3).

The punched blank is moved horizontally with the transport device from the first frame (4) to the second frame (5) and deposited there. At the same time, the embossed blank located in the frame (5) is removed and, if necessary, fed to a further station for breaking out the punched sections. At the same time, a new blank is placed on the punching knives (6) in the frame (4). Once these transport processes have been completed, the drive shaft (22) is rotated again by 180 °. The pressure rollers (8, 9) are thereby moved apart and move again over the punching knives (6) or embossing strips (7) with the result that the respective blanks are punched or embossed. At the end point of the movement, the pressure rollers (8, 9) again assume the position that results from FIG. (2). After carrying out another transport process, the cycle described above can start again.

The basic structure of the device (41) shown in FIG. 4 corresponds to the device (1) according to FIG. 1. The same reference numerals are therefore used for the same or functionally identical parts, reference being made in this respect to the description of the device (1) according to FIG. (1). Therefore, only the deviations from the device (1) according to FIG. (1) are described below.

The device (41) no longer has a stepping gear. Rather, the drive motor (34) sits directly on the drive shaft (22) and drives the crank mechanisms (20̸) and (21) directly.

Furthermore, the stub axles (12, 13) or (14, 15) of the pressure rollers (8, 9) continue outwards beyond the crank rods (16, 17) or (18, 19). The stub axles (13, 15) on the side of the crank mechanism (21) end in rollers (42, 43) that roll on a support rail (44) over the entire range of motion of the pressure rollers (8, 9). The same is also provided at the ends of the opposite stub axles (12, 14). They also carry rollers (45, 46) that roll on a mounting rail (47). On the outside of the rollers (45, 46) gear wheels (48, 49) are attached, which are non-rotatably connected to the stub axles (12, 14) and fit into a rack (50̸) which runs parallel to the mounting rail (47). In this way it is ensured that the respective rotational positions of the pressure rollers (8, 9) are reproducible at the respective location.

The pressure rollers (8, 9) are in contrast to the embodiment in the device (1) according to Figure (1) is not cylindrical. They each have cylindrical circumferential sections (51, 52) with a large diameter that extend over the entire width and cylindrical circumferential sections (53, 54) with a diameter that is smaller in comparison, the circumferential sections (51, 52, 53, 54) being transverse to the directions of movement A , B extending paragraphs (55, 56) or (57, 58) are connected. The meaning of this design of the pressure rollers (8, 9) is clear from the following description of the figures (5) and (6).

In these figures, the device (41) is shown schematically similar to the device (1) in Figures (2) and (3). The processing tables (2, 3) are also omitted here. In addition, the inclination of the pressure rollers (8, 9) has been omitted for reasons of clarity.

In figure (4) it is not shown that the device (41) includes a transport device (59). It results from the figures (4) and (5). The transport device (59) has deflection rollers (60̸, 61) at its end points, one of which is driven and run over the endless chains (62). The endless chains (62) have transport brackets at regular intervals - designated by way of example (63) - which each protrude outwards. Perpendicular to the drawing level, i.e. transverse to the direction of movement of the endless chains (62) there are several - usually four - transport clamps. On the top of the endless chains (62), the transport clamps (63) serve to transport blanks introduced into the device (41) - designated by way of example with (64) - in the transport direction (arrow D) through the device (41) by the transport clamps (63) each comprise the front edge of a blank (64).

In Figure (5), the pressure rollers (8, 9) are in the outermost dead center position. The blanks in positions II and IV each lie on one of the processing tables (2, 3). The blank in position III (64) is held between the two processing tables (2, 3) while the blank (64) in position I is in a waiting position.

The pressure rollers (8, 9) assume such a position that the peripheral sections (53, 54) with a small diameter are directed essentially downwards. The diameter of these peripheral sections (53, 54) is such that the transport clamps (63) and thus also the blanks (64) can pass under the pressure rollers (8, 9) without colliding with them. It can also be seen that the pressure rollers (8, 9) have moved outwards beyond positions II and IV and thus over the processing tables (2, 3). In this position of the pressure rollers (8, 9), the transport device (59) is actuated in such a way that a transport operation for displacing the blanks (64) takes place by an amount which moves them up by one position in the direction of arrow D, so that then the blanks (64) assume the positions shown in FIG. (6) and a new blank has moved to position I. The extent of the circumferential sections (53, 54) with a small diameter in the circumferential direction is such that, despite further rotation of the drive shaft (22), there is no collision with the transport clamps (63), especially since the pressure rollers (8, 9) are in the area of their dead centers Movements due to the geometry of the crank drives (20̸, 21) have only a low translation speed and thus peripheral speed.

As the drive shaft (22) continues to rotate, the pressure rollers (8, 9) are moved over the blanks (64) in positions (II and IV) and thus over the processing tables (2, 3). The circumferential sections (51, 52) with a large diameter then roll over the blanks (64), the transition from the circumferential sections (53, 54) with a small diameter to the circumferential sections (51, 52) with a large diameter being coordinated exactly in this way that the peripheral portions (51, 52) Roll up with a large diameter at the intended location while avoiding a collision with the transport clamps (63) on the blanks (64) and then roll on them. As a result, the deformations already described for the figures (2) and (3) are brought about.

In Figure (6) the transport rollers (10̸, 11) have almost reached their inner dead center position. Also in this position are the peripheral sections (53, 54) with a small diameter essentially opposite the transport device (59), the transition from the peripheral section (53) with a small diameter to the peripheral section (51) with a large diameter at the pressure roller ( 8) is designed so that a collision with the transport bracket (63) in position II is avoided. In this position of the pressure rollers (8, 9), a further transport operation of the transport device (59) can be initiated in order to move the blanks (64) by a further position. Here, too, a collision of the transport rollers (8, 9) with the transport clamps (63) is avoided. The pressure rollers (8, 9) then roll back onto the processing tables (2, 3) in order to machine the blanks (64) in positions II and IV with the aid of the large diameter peripheral sections (51, 52).

The basic structure of the device (71) shown in FIG. 7 corresponds to the device (41) according to FIG. 4 and - insofar as this is the same as the device (1) according to FIG. 1 - corresponds to it. The same reference numerals are therefore used for the same or functionally identical parts, reference being made to the description of the device (1) according to FIG. 1 or device (41) according to FIG. 4 for the explanation of the reference numbers. For this reason, only the deviations from the device (41) according to FIG. (4) are described below.

The stub axles (12, 13) and (14, 15) now do not have - how in the embodiments according to the figures (1) and (4) - connection with crank rods, but are rotatably supported at the ends in carriages (72, 73, 74, 75). These slides (72, 73, 74, 75) run on guide rails (76, 77, 78, 79) which extend parallel to the rack (50̸), which is divided here into rack sections (50̸a, 50̸b).

Each carriage (72, 73, 74, 75) is permanently provided with a circumferential toothed belt (80̸, 81, 82, 83), each with its upper run above and with its lower run below the associated guide rail (76, 77, 78, 79) run. At the end, the toothed belts (80̸, 81, 82, 83) each loop around a toothed deflection roller (84, 85) or (86, 87) or (88, 89) or (90̸, 91). These are rotatably mounted, which is not shown here for the sake of clarity.

The mutually facing deflection rollers (85, 88) and (87, 90̸) carry spur gears (92, 93) and (94, 95). A pair of opposing spur gears (92, 93) or (94, 95) meshes with a pair of gears, each consisting of two intermeshing gears (96, 97) or (98, 99) of equal size. The left-hand gear (96) or (98) in this view meshes with another gear (10̸0̸) or (10̸1) of larger diameter. Both other gears (10̸0̸, 10̸1) are rotatably connected to each other via a shaft (10̸2).

The other gear (10̸1) in the foreground carries a pinion (10̸3) which meshes with a drive gear (10̸4) which has a much larger diameter than the pinion (10̸3). This drive gear (10̸4) is eccentrically connected to a crank rod (10̸5), the other end of which is also eccentrically seated on a crank disk (10̸6). The crank disc (10̸6) is driven by an electric motor (34).

The sequence of movements is basically similar to that in the device (41) according to the figures (4) to (6). The rotation of the crank disc (10̸6) in the direction of arrow D periodically produces an up and down movement of the crank rod (10̸5) (arrows E) and thus a back and forth rotation of the drive gear (10̸4) by the angle indicated by the double arrow (F). It is possible to set this angle by radial adjustment of the pivot point of the crank rod (10̸5) on the drive gear (10̸4). The movement of this drive gear (10̸4) is transmitted to the pinion (10̸3) and from there to the further gear (10̸1). The additional gear (10 (1) on the top side in this view also executes the same movement via the shaft (10̸2).

The other gears (10̸0̸) or (10̸1) transmit the back and forth movement to the gears (96) or (98), which the movement on the one hand the spur gears (92, 94) and on the other hand to the adjacent gear (97, 99) pass on. The latter then mesh with the spur gears (93) and (95).

On the basis of this gear construction, the spur gears (92, 93) and (94, 95) perform opposite movements and transmit them to the toothed belts (80̸, 81, 82, 83) via the deflection rollers (85, 88; 87, 90̸). The movement is such that a maximum speed is reached in the middle of the path, which does not decrease linearly towards the end points, however, because of the drive gear (10̸4), crank rod (10̸5) and crank disc (10̸6) Crank drive.

For the rest, the pressure rollers (8, 9) are also not cylindrical, but correspond to those of the device (41) according to FIG. (4). This also applies to their movement over the processing tables (2, 3). In this respect, reference can be made to the figures (5) and (6) and the associated description. As in FIG. 4, the illustration of the transport device 59 is also missing in FIG. 7 for reasons of clarity. In this respect, there are also no deviations from the device (41) according to the figures (4) to (6).

Claims (23)

1. Device (1, 41, 71) for deformation, in particular for punching and / or embossing blanks or tapes, in particular made of cardboard, with a table device (2, 3) which bears deformation elements (6, 7) projecting on the processing side, and with a roller device (8, 9) for pressing the blank or tape against the deformation elements (6, 7), the table and roller arrangement (2, 3, 8, 9) being movable relative to one another parallel to the processing side by means of a drive,
characterized in that the table device has two processing tables (2, 3) with deformation elements (6, 7), and in that the roller device has two pressure roller units (8, 9), each processing table (2, 3) having its own pressure roller unit (8, 9 ) is assigned and the pressure roller units (8, 9) and / or the processing tables (2, 3) are driven in opposite directions. 2. Device according to claim 1,
characterized in that the pressure roller units (8, 9) are arranged adjacent to the actuating sides of the processing tables (2, 3). 3. Device according to claim 2,
characterized in that the pressure roller units each have only one pressure roller (8, 9). 4. Device according to one of claims 1 to 3,
characterized in that a transport device (59) for the transport of the blanks (64) through the device (1, 41) is provided which has transport elements (63) for gripping the blanks (64) on an edge lying transversely to the transport direction, and that the pressure roller units (8, 9) are circumferential Have recesses (43, 44) which are designed and arranged in such a way that they lie opposite the dead center of the roller movements of the transport device (59) in such a way that a collision with the transport elements (63) is avoided. 5. The device according to claim 4,
characterized in that the pressure roller units (8, 9) have a smaller diameter over a first peripheral section (53, 54) than over a second peripheral section (51, 52), the second peripheral sections (51, 52) moving over the processing tables (2, 3) interact with the deformation elements (6, 7). 6. The device according to claim 4 or 5,
characterized in that at least one guide device (42 to 50̸) is provided for the precise rotation of the pressure rollers (8, 9). 7. The device according to claim 6,
characterized in that the guide devices are designed as roller tracks (44, 47) on which guide wheels (42, 43, 45, 46) seated on the axis of rotation of the pressure rollers (10̸, 11) roll. 8. The device according to claim 7,
characterized in that the runway is designed as a rack (50̸) and the guide wheels as gears (48, 49). 9. Device according to one of claims 1 to 8,
characterized in that the processing tables (2, 3) are arranged side by side. 10. The device according to one of claims 1 to 9,
characterized in that the machining sides of the machining tables (2, 3) lie horizontally on the upper sides. 11. The device according to one of claims 1 to 10̸,
characterized in that the drive is designed such that the speed of the movement of the pressure roller units (8, 9) and / or the processing tables (2, 3) has a maximum in the middle of the path and decreases non-linearly towards the end points of the path. 12. The device according to one of claims 1 to 11,
characterized in that the pressure roller units (8, 9) are held on both sides on drive belts (80̸, 81, 82, 83) which can be moved back and forth via the drive. 13. The apparatus according to claim 12,
characterized in that the drive belts are designed as peripheral drive belts (80̸, 81, 82, 83). 14. The apparatus according to claim 13,
characterized in that the drive belts are designed as toothed belts (80̸, 81, 82, 83). 16. The device according to one of claims 12 to 14,
characterized in that the drive has a meshing gear pair (96, 97, 98, 99) which interacts with the drive belts, the gear pair (96, 97, 98, 99) via a crank mechanism (10̸4, 10̸5, 10̸6) is driven. 17. Device according to claim 16,
characterized in that the angle of rotation of the gear pair (s) (96, 97, 98, 99) is adjustable. 18. Device according to one of claims 1 to 17,
characterized in that the drive has a motor (34) and a gear unit which causes the opposite movement. 19. The apparatus of claim 18,
characterized in that the gear (20̸, 21, 10̸4, 10̸5, 10̸6) is designed such that the dead centers of the roller movements of the pressure roller units (10̸, 11) lie outside the processing tables (2, 3). 20. The apparatus according to claim 19,
characterized in that the transmission has at least one crank mechanism (20̸, 21, 10̸4, 10̸5, 10̸6). 21. The apparatus of claim 20̸,
characterized in that each crank mechanism (29, 21) has two crank pins (25, 26; 30̸, 31) offset by 180 °, which are connected to the pressure rollers (8, 9) and / or the processing tables. 22. The device according to one of claims 18 to 21,
characterized in that a step gear is connected upstream of the gear (20 Schritt, 21). 23. The device according to one of claims 11 to 12,
characterized in that the gear (20̸, 21) and motor (34) are arranged between the processing tables (2, 3). 24. The device according to one of claims 1 to 13,
characterized in that the roller axes of the pressure roller units (8, 9) are inclined to the deformation elements (6, 7).

Images