EP0422562A2 - Device for conveying a sub-pile of sheets from a pile to a further processing station - Google Patents

Abstract

The invention relates to a device for transferring a partial stack (5) made of sheet material from an entire stack (2) to a further processing station, in particular a vibrating station (3). The device has a table (15) mounted in a movable frame (13). This is provided, at least in the area of one end, with a table part (21) which can be folded up from the horizontal table plane. The frame (13) has a lowerable pressure element (40) above the table part (21) on the area of the partial stack (5) assigned to the table part (21), the table (15) being in a first end position for taking over the partial stack (5). into the stack (2) between the partial stack (5) and the remaining stack (6) and is positioned in a second end position above the further processing station (3). A device designed in this way makes it possible to take over the partial stack (5) from the overall stack (2) with actuation of the foldable part (21) in cooperation with the in a structurally simple design and at the same time adjacent arrangement of the entire stack (2) and further processing station (3) Pressure element (40) to break up the partial stack (5), then the broken partial stack (5) is deposited on the further processing station (3). <IMAGE>

Description

The invention relates to a device for transferring a partial stack of sheet material from an entire stack to a further processing station, in particular a vibrating station, with a device for transferring the partial stack to a device for breaking up the partial stack and a device for transferring the broken partial stack to the further processing station. The term "rupture" is to be understood to mean the separation of the individual sheet layers which, for example, adhere to one another due to atmospheric pressure, static charge, adhesive effect by applying paint, etc.

From DE-OS 27 23 162 it is known to use a gripper To remove partial stacks from an entire stack and to move to a vibrating station. The partial stack is broken up during transport to the vibrating station. This is a prerequisite for the fact that the individual sheet layers can be displaced relative to one another in the vibrating station, whereby an exact alignment of the individual sheet layers is possible. The partial stack is broken open by a pivoting movement of the grippers, which grip the partial stack on the outside, with which the sheet stack is deformed from a flat into a curved shape, which leads to the relative movement of the individual sheet layers. The transfer and breaking open of the sheet-like material by means of a gripping arrangement requires a great deal of design effort with regard to the gripping arrangement, in particular because of the precise coordination of the movement of the grippers. Apart from this, high gripper forces must be exerted on the partial stack in order to securely grasp it, with the risk that the sheet layers of the stack will be damaged. In this context, it should be taken into account that the stack can have a considerable weight, which is to be seen in direct connection with the gripper forces to be applied. From DE-OS 26 49 959 it is known to pull the part stack removed from a whole stack by means of grippers through a feeder, into which is arranged between the whole stack and the vibrating station and is evenly formed at its introducer and from there continuously into that The vibrating station turns towards the circular end of the delivery, which is open at the top. The disadvantage here is that the device for transferring the partial stack requires an increased installation space because of the arrangement of the feed between the entire stack of the vibrating station, and furthermore, due to the described design of the feed, it is not guaranteed that the partial stack will be broken up in its central areas. From DE-AS 19 51 887 it is finally known to use a gripper to grip the partial stack over an upwardly curved guide pad for the vibrating station to pull on. Again, the disadvantage is to be seen in the fact that this device requires an increased installation space and there is no breakup of the partial stack in its central areas.

The object of the present invention is to provide a device of the type mentioned which is structurally simple and which provides an adjacent arrangement of the entire stack and the further processing station, with which the respective partial stack can be transferred within a very short time.

The object is achieved in that the device for breaking up the partial stack has a table mounted in a movable frame, which has at least in the area of one end a table part that can be folded up from the horizontal table plane, and in the frame above the table part one in contact with the table part The associated area of the partial stack can be brought with a pressure element, the table being moved into the stack between the partial stack and the remaining stack in a first end position for taking over the partial stack and being positioned in a second end position above the further processing station.

Of particular importance in connection with the features according to the invention of the movability of the table between the two end positions described. The table serves on the one hand as a means of transport for the partial stack, on the other hand the at least one foldable table part of the table, in cooperation with the associated pressure elements, forms the device for breaking up the partial stack. Because the table on the one hand can be completely retracted into the stack between the remaining stack and the partial stack, and on the other hand can be positioned directly above the further processing station, there is the possibility of the entire stack and the further to position the processing station essentially adjacent to one another. The device can be structurally simple because the transfer of the partial stack to the further processing station and the breakup of the partial stack takes place essentially through the table or the table associated elements, apart from auxiliary elements which transfer the partial stack to the table or from the table lose weight.

The transfer of the partial stack to the device for breaking up the partial stack is expediently carried out by means of at least one take-over gripper which, after separating the partial stack, grips it in particular on the side facing away from the further processing station and moves it slightly over the remaining stack in the direction of the further processing station. Advantageously, the table on its side facing the entire stack is provided with a drivable conveyor roller which, after passing under the protruding part of the partial stack, supports its being pushed onto the table when the table is moved in between the remaining stack and the partial stack. Immediately when the table has reached its end position on the stack side, in which it releases the further processing station for further work steps assigned to it, the partial stack can be broken open. The interaction of the pressure element with the partial stack is essential here. Thus, when the table part and thus the edge region of the partial stack are folded up, there is a relative displacement of the individual sheet layers of the stack, the individual sheets primarily consisting of paper, cardboard, plastic film or the like, which can be printed or unprinted. The pressure element either comes into contact with the assigned area of the partial stack by its lowering movement or the pivoting movement of the table part; when the pressure element acts, the table part is folded back into the table plane. Depending on an action or a lack of action on that area of the Stack, which faces away from the fold-up table part, can be broken open differently. In principle, it is sufficient to achieve the break-open effect if only one end of the table is provided with a table part that can be folded up. After this table part has been folded up and the pressure element has been placed on the partial stack, the lowering of the table part with the pressure element acting on it results in the partial stack being present with the sheet layers shifted in one another, thus the partial stack being broken up. It is not absolutely necessary that the end of the table facing away from the foldable table part is provided with a stop for the partial stack in order to prevent the partial stack from sliding away from the latter when the foldable table part is raised. This will not be necessary because the partial stack is usually in the form of a block due to the sheets sticking together, which is only partially broken up by lifting the table part that can be folded up; apart from this, there is usually no shift when the table part is folded up due to the weight of the partial stack. If necessary, however, additional means can be provided which fix the partial stack in a force-fit or positive manner until the pressure element rests on the folded-up stack area. However, it is regarded as preferred if the table has two table parts which can be pivoted in the region of opposite table ends about pivot axes arranged parallel to one another and a pressure element which can be brought into contact with the partial stack is provided above each table part. It is assumed that two fold-up table parts move the partial stack in opposite edge areas from the table level, which has the advantage that the partial stack is broken open in both edge areas and, in addition, the counter-moving table parts counteract a displacement of the partial stack during the folding up of the table parts . Even when using two table parts, the workflow results follow different possibilities with regard to the action on the partial stack by means of a pressure element assigned to the edge area of the partial stack or to pressure elements assigned to each edge area. For example, provision is made to act only on an edge region of the partial stack by means of a pressure element. This leads to the previously described displacement of the individual sheet layers of the partial stack, which is essentially parallelogram-shaped after the table parts have been folded back. There is also the possibility that the folding back of both table parts into the table plane takes place with pressure elements acting, in particular that the folding back takes place simultaneously. Such action of the pressure elements leads to the fact that the upper sheet layers are stretched in a less curved arc between the pressure elements than the lower sheet layers and the sheet layers thus tend to separate from one another. From the point of view of the two pressure elements acting simultaneously, the forces introduced via these into the partial stack are of greater importance. For example, the pressure force of the respective pressure element acting on the stack should be such that the sheet layers facing it can slip under the sheet before it reaches the tensile strength. The pressure elements are advantageously designed as rotatable rollers, which extend in particular over the entire narrow side of the table. The pressure elements should be provided with braking devices, in particular with braking devices that can be adjusted with regard to the braking torque. The braking torque of the rollers must be dimensioned so that they roll off before the tear limit of the sheet layers is exceeded. The braking torques can be introduced, for example, by means of disc springs which can be preloaded and act on the rollers in the region of the bearings.

To optimize the break-up effect of the partial stack, should this can be transferred from the flat position into a position that is as evenly curved as possible. In order to accomplish this approximately, it is provided that the two table parts receive a center table part between them and each table part is assigned a bridge segment which partially covers the respective pivotable table part and is pivotably mounted in this or the center table part parallel to the pivot axis of the pivotable table part.

The partial stack on the table is expediently broken open while the table is being moved to the further processing station. After the break-up process, in which the table parts are folded into the table level and after the table is positioned in its end position above the further processing station, at least one depositing gripper preferably grips this on the side of the partial stack facing away from the entire stack, then the table is again turned in the direction of the Move the entire stack between the newly separated partial stack and the remaining stack, as soon as the table has moved out from under the partial stack gripped by the depositing gripper, the partial stack comes into contact with the further processing station. Here, after releasing the depositing gripper, the processing step assigned to this station is carried out. At the same time, the next partial stack is transferred to the table and the partial stack is broken open.

Further features of the invention are shown in the description of the figures and in the subclaims, it being noted that all individual features and all combinations of individual features are essential to the invention.

• Figur 1 eine erfindungsgemäße Vorrichtung in schematischer Darstellung in einer Seitenansicht,
• Figur 2 eine detailliertere Darstellung der Einrichtung zumAufbrechen des Teilstapels in einer Seitenansicht,
• Figur 3 eine Stirnansicht der Einrichtung zum Aufbrechen gemäß Pfeil A in Figur 2, aus zeichnerischen Gründen ohne Druckelement gezeigt und
• Figuren 4 bis 15 Ansichten gemäß der Darstellung in Figur 1, zur Verdeutlichung der mit der erfindungsgemä­ßen Vorrichtung erzielbaren Arbeitsabfolgen, gezeigt in vereinfachter Darstellung.

In the figures 1 to 14, the invention is shown for example in one embodiment, without being limited to this embodiment. It shows:

• FIG. 1 shows a device according to the invention in a schematic illustration in a side view,
• FIG. 2 shows a more detailed illustration of the device for breaking up the partial stack in a side view,
• Figure 3 is an end view of the device for breaking open according to arrow A in Figure 2, shown for reasons of drawing without a pressure element and
• Figures 4 to 15 views as shown in Figure 1, to illustrate the work sequences achievable with the device according to the invention, shown in a simplified representation.

Figure 1 shows an overall stack 2 arranged on a lifting pallet 1, which consists for example of printed sheets of paper. A vibrating station 3 is arranged directly adjacent to the entire stack 2, with a known, designable lifting, lowering and tilting vibrating table 4. The purpose of the device according to the invention and to be described in more detail below is to remove a partial stack from the entire stack 2 and break it open, so that the individual sheets of the partial stack 5 can be shaken to the exact edge after being placed on the vibrating table 4. A buffer shelf or a cutting machine, for example, can be connected to the vibrating station 3.

It can be seen from FIG. 1 that a stationary support frame 7 with upper and lower, horizontally running guides 7a, 7b is arranged laterally and partially above the entire stack 2 and the vibrating station 3. In the upper guide 7a there is mounted a transfer gripper 8 which can be brought into contact with the stack side facing away from the vibrating table 3 and which, in relation to the sheet plane, can be moved vertically and horizontally. The transfer gripper 8 has a fixed support plate 9 and a clamping plate 10 arranged parallel to it, which is adjustable in the direction of the support plate 9 and in the opposite direction by means of adjustment elements (not shown). In the support frame 7, a blowing nozzle 11 is also mounted, this is located adjacent to the transfer gripper 8 and is also horizontally and vertically movable. The air outlet of the blowing nozzle 11 is directed towards the side of the entire stack 2 facing away from the vibrating station. Finally, a hook-shaped hold-down device 12 is assigned to the opposite side of the entire stack 2 and is likewise arranged to be horizontally and vertically movable in the supporting frame 7.

In the guides 7a and 7b of the support frame 7, as is additionally illustrated in FIG. 3, a frame 13 is mounted so as to be horizontally displaceable. The frame 13 receives a horizontally oriented table 15, which forms an essential element of the device for breaking up the partial stack 5. The frame 13 can be moved horizontally by means of force means which are not illustrated in any more detail, and the table 15 which is firmly connected to the lower region of the frame 13 can thus be moved horizontally.

Figures 2 and 3 illustrate in detail the storage and design of the table 15, which is constructed essentially symmetrically with respect to the planes 17 and 18 perpendicular to the image planes. The table 15 has a center table part 19 and two table parts 21 which adjoin directly on the front sides of the center table part 19 opposite in the longitudinal direction of the table 15 and can be pivoted about axes 20. The middle table part 19 is in each case adjacent to the table parts 21 in the area of its support plane, that is to say above, provided with a recess 22 and the respective table part 21 also above and adjacent to the middle table part 19 with a recess 23. In the transition from the middle table part 19 to the recess 22 the respective recess has a bridge segment 25 which can be pivoted about an axis 24. The strength of the table parts 21 and the bridge segments 25 and the dimensions of the recesses 22 and 23 are dimensioned such that when the table parts 21 and thus also the bridge segments 25 are pivoted in, the surface of the center table part 19 forms a plane with the upper surfaces of the table parts 21 and bridge segments 25. When the table parts 21 are folded up, the bridge segments 25 slide with their free ends 26 in the recesses 23 until they reach the undercut 27 in each case, when the maximum position of the table parts 21 swung out by an angle of approximately 55 ° is reached Table part 21 come to rest. The illustration in FIG. 2 illustrates that in the folded-up position of the table parts 21 and the bridge segments 25, an almost uniformly curved curve is predetermined by this and the middle table part 19, whereby it is of course also possible to provide further bridge segments, so that when the Table parts 21 approximates the support contour of the table to a continuous curve shape.

With the table parts 21, adjacent to the swivel axes 20, downwardly directed swivel arms 28 are rigidly connected, at whose free end a piston rod 29 of a pneumatic cylinder 30 mounted in the table 15 engages. At point 29a, the respective piston rod 29 is articulated to the swivel arm 28, at point 30a the respective cylinder 30 is articulated to the table 15.

FIGS. 2 and 3 illustrate the mounting of the table 15 in the frame 13. Above the table 15, the frame 13 has a horizontal support 31 which extends perpendicularly to the longitudinal guides 7a and 7b up to almost the opposite end of the table 15, on the vertical guides 32 which are arranged at a distance from one another and which extend almost over the entire width of the table 15, vertically movable portal frame 33 is guided. The portal frame 33 consists essentially of a horizontally arranged frame part 34, which receives the guides 32 and can be raised and lowered by means of a pneumatic cylinder 35 on the carrier side. On each of the two long sides of the table 15, the portal frame 33 also has a downwardly directed support frame part 36, in the end points of which supports 37 are pivotally mounted about pivot axes 38. In the lowered position of the portal frame shown in FIG. 2, the position of the pivot axes 38 coincides with the position of the bearing axes 20 for the table parts 21. In each case two supports 27 assigned to a table part 21 are connected by means of a cross support, between each of these and the frame part 34 of the portal frame 33 a pivotably mounted pneumatic cylinder 39 engages to pivot the supports 37. A pressure roller 40 is mounted between assigned carriers 37 in the region of the carrier ends parallel to the pivot axes 38 and thus extends almost over the entire width of the table 15. The two pressure rollers 40 are provided with adjustable braking devices, not shown, for example in the form of disc springs, so that they can rotate when a defined torque is exceeded. In the area of each end face of the pressure rollers 40, each support 37 is assigned a pivotably mounted pneumatic cylinder 41 which receives a relief hook 42 which can be brought into operative connection with a holding pin 43 assigned to the respective table part 21. The relief hook 42 is designed such that it is pivoted out of the way of the holding pin 43 in the extended state by contact with a stop pin 44. Finally, it can be seen from the illustration in FIG. 3 that two bridge segments 25 are arranged next to one another, each of which is approximately 1/4 as wide as the table 15. Furthermore, a further pneumatic cylinder 45 is mounted in the portal frame 33 on one side of the table. in the plane 17 movable hold-down 46. FIG. 2 illustrates that the table 15 is provided on the end face facing the entire stack 2 with a conveyor roller 47 for pushing the partial stack 5 onto the table 15. The storage of the conveyor roller 47 in the table 15 is not clarified, the conveyor roller 47 can be driven clockwise and extends essentially over the entire width of the table 15.

The working sequences that can be achieved with the device according to the invention are illustrated below with reference to FIGS. 4 to 14:

As shown in FIG. 4, the entire stack 2 is first raised to such a level that the lowest sheet position of the partial stack 5 to be removed comes to lie slightly higher than the surface of the table 15. It is then moved by a corresponding vertical movement, possibly superimposed by a horizontal movement , the transfer gripper 8 with its support plate 9 brought to the level of the lowest sheet position of the partial stack 5 and the clamping plate 10 move so far from the support plate 9 that the two plates 9 and 10 can accommodate the partial stack 5 between them. The transfer gripper 8 is then moved into the entire stack 2, separating the partial stack 5 from the remaining stack 6, and then the transfer gripper 8 is closed. The hold-down device 12 is moved into the gap between the partial stack 5 and the remaining stack 6 and lowered onto the remaining stack 6, so that the partial stack 5 can be moved in the direction of the vibrating table 4 and the table 15 by means of the transfer gripper 8. This process is supported by the blowing nozzle 11, which blows air between the partial stack 5 and the remaining stack 6. During the separation of the sub-stack 5, the table 15 located slightly below the level of the sub-stack 5 becomes in when the table parts 21 are retracted and the supports 37 are pivoted up (support position according to FIG. 2) Direction of the total stack 2 moves. As soon as the conveying roller 47 of the table 15 has arrived below the area of the partial stack 5 projecting beyond the partial stack 6, the entire stack 2 is lowered so that the end of the partial stack 5 facing the conveying roller 47 rests thereon (FIG. 5). The table 15 is moved further between the partial stack 5 and the remaining stack 6 until it has penetrated the entire stack 2 and the partial stack 5 rests on the table 15 symmetrically to the plane 17 (FIG. 6). From this position, the transfer gripper 8 moves back into its rest position, furthermore the hold-down device 12 is released and the blowing nozzle 11 is deactivated. While the table 15 is in the area of the remaining stack 6, sheet material deposited on the vibrating table 4 can be vibrated following a previous cycle.

The partial stack 5 can already be broken open in a position of the table 15 above the remaining stack 6, which is illustrated in FIG. 7. First of all, the partial stack 5 lying on the table 15 forms a closed block, that is to say the individual sheets 48 cannot easily be shifted one above the other, which is a prerequisite for the precise alignment of the partial stack 5 in the subsequent vibrating table 4. Therefore, after the stack 5 has been placed on the table 15, the pneumatic cylinders 30 are acted upon, which causes the table parts 21 and thus also the bridge segments 25 to be flipped up into the position likewise shown in FIG. In this position, as can be seen from the illustration in FIG. 7, the sheet layers are increasingly displaced from the neutral plane 17 to the edges 49, so that the block formation is already eliminated in the displacement region. When the table parts 21 and the bridge segments 25 are folded up, the two pressure rollers 40 are lowered onto the partial stack 5 in the region of the two edges 49 by acting on the pneumatic cylinders 39. The extended relief hooks 42 engage behind the retaining pins 43; by retracting the relief hook 42, the pressure force of the pressure rollers 40 on the partial stack can be adjusted to a desired level, whereby the partial stack 5 is clamped in its edge regions between the pressure rollers 40 and the table parts 21. If the table parts 21 and thus the bridge segments 25 are now pivoted back, with simultaneous tracking of the pressure rollers 40 by acting on the pneumatic cylinders 39, this causes the individual sheets 48 to stretch from the lower to the upper sheet layers, and thus separate from one another. At this moment, air can additionally be blown between the individual sheets 48 by means of a large number of air nozzles 50 (FIG. 3) arranged laterally on the table 15. When the table parts 21 and the bridge segments 25 are lowered further while the pressure rollers 40 are being adjusted at the same time, the set braking torque of the pressure rollers 40 is exceeded when the upper sheet layers are fully tensioned, so that they roll outwards on the top sheet 48. As soon as the table parts 21 and the bridge segments 25 are completely folded in, the relief hooks 42 are extended, whereby they come out of engagement with the holding pins 43, then the supports 37 can be pivoted up by means of the pneumatic cylinders 39, so that the partial stack 5 is now fed to the vibrating station 3 could be. As a rule, however, the break-open process is repeated again, that is to say the table parts 21 are extended again, the pressure roller 40 is lowered again, possibly even after the partial stack 5 has been previously rotated on the table 15 by 90 °.

FIG. 8 illustrates that the table 15 can already be moved into its other end position above the vibrating station 3 during the breaking process. As soon as this position has been reached, the next partial stack 5 can already be separated from the remaining stack 6 by the transfer gripper 8 again acting.

FIGS. 9 and 10 illustrate a process section which is particularly suitable after the above-described breaking process. Following the process sequence described, the table parts 21 and the bridge segments 25 are to be pivoted again into the extended position shown in FIG. 7, but then only the pressure roller 40 assigned to the right edge 49 is lowered onto the partial stack 5 (FIG. 9) or the pressure roller 40 assigned to the left edge 49 onto the partial stack 5 (FIG. 10). When folding in the table parts 21 and the bridge segments 25, whereby the table parts 21 do not necessarily have to be lowered at the same time, the pressure roller 40 assigned to the respective edge 49 fixes this stacking area, so that the partial stack 5 is present in a parallelogram shape when the table parts 21 and bridge segments 25 are retracted. Such breaking open is expedient if the partial stack 5 is then to be shaken in the vibrating table 4, lying to the left (FIG. 9) or to the right (FIG. 10).

FIG. 11 shows the partial stack 5 broken open with respect to the left-hand system when the table parts 21 are folded in. A depositing gripper 51 which can be moved in accordance with the transfer gripper 8 is moved into a position which grips the partial stack 5 on the right. The table 15 is now moved in the direction of the entire stack 2, which was previously lowered so far that the conveyor roller 47 of the table 15 can pass under the next projecting partial stack 5. When the table 15 is moved further into the gap formed between the partial stack 5 and the remaining stack 6, the already opened partial stack 5 is deposited on the previously shaken sheet layers picked up by the vibrating table 4 by a substantially vertical movement of the depositing gripper 51 (FIG. 12). With regard to the transfer of the partial stack 5 from the entire stack 2, the method sections described for FIGS. 5 to 11 follow.

FIG. 13 illustrates that during the takeover of the next partial stack 5 on the table 15 and following the shaking of the partial stack 5 last placed on the vibrating table 4, the shaken total stack 52 is clamped on one side by means of a hold-down device 53 and then an air squeezing roller 54 is moved over the shaken total stack 52. While the partial stack 5 last removed from the entire stack 2 is broken open, the vented overall stack 52 can be fed to a buffer shelf 56 or a cutting machine, for example by means of a gripper 55 (FIG. 14) or a slide 57 (FIG. 15).

The device described is not limited to the handling of sheets of paper, but generally relates to sheet-like material. In particular, it is thought of sheet-shaped goods made of paper, cardboard, plastic film or the like in unprinted or printed form

Reference symbol list

• 1 lifting pallet
• 2 total stacks
• 3 vibrating station
• 4 vibrating table
• 5 partial stacks
• 6 remaining stacks
• 7 support frame
• 7a leadership
• 7b leadership
• 8 transfer grippers
• 9 support plate
• 10 clamping plate
• 11 blow nozzle
• 12 hold-down devices
• 13 frame
• 15 table
• 17 level
• 18 level
• 19 middle table section
• 20 axis
• 21 table part
• 22 Return
• 23 return
• 24 axis
• 25 bridge segment
• 26 end
• 27 undercut
• 28 swivel arm
• 29 piston rod
• 29a point
• 30 pneumatic cylinders
• 30a point
• 31 carriers
• 32 leadership
• 33 portal frame
• 34 frame part
• 35 pneumatic cylinders
• 36 support frame part
• 37 carriers
• 38 swivel axis
• 39 pneumatic cylinders
• 40 pressure roller
• 41 pneumatic cylinders
• 42 relief hooks
• 43 holding pin
• 44 stop pin
• 45 pneumatic cylinders
• 46 hold-down device
• 47 conveyor roller
• 48 sheets
• 49 rand
• 50 air nozzle
• 51 Drop gripper
• 52 total stacks
• 53 hold-down device
• 54 air squeeze roller
• 55 grippers
• 56 buffer rack
• 57 slider

Claims (11)

1. Device for transferring a partial stack of sheet-like material from an overall stack to a further processing station, in particular a vibrating station, with a device for transferring the partial stack to a device for breaking up the partial stack and a device for transferring the broken partial stack to the further processing station,
characterized in that the device for breaking open the partial stack (5) has a table (15) mounted in a movable frame (13), which has at least in the region of one end a table part (21, 25) which can be folded up from the horizontal table plane, and in The frame (13) above the table part (21, 25) has a pressure element (40) which can be brought into contact with the area of the partial stack (5) assigned to the table part (21, 25), the table (15) being in a first end position Transfer of the partial stack (5) into the stack (2) between the partial stack (5) and the remaining stack (6) is inserted and positioned in a second end position above the further processing station (3). 2. Device according to claim 1, characterized in that the table (15) has two in the region of opposite table ends about mutually parallel pivot axes (20) pivotable table parts (21) and above each table part (21) one on the partial stack (5) lowerable Pressure element (40) is provided. 3. Apparatus according to claim 2, characterized in that the two table parts (21) between them receive a central table part (19) and each table part (21) at least one Bridge segment (25) is assigned, which partially covers the respective pivotable table part (21) and is pivotably mounted parallel to the pivot axis (20) of the pivotable table part (21) in this or the center table part (19). 4. Device according to one of claims 1 to 3, characterized in that the respective pressure element is designed as a rotatable roller (40) which extends in particular over the entire narrow side of the table (15). 5. Device according to one of claims 1 to 4, characterized in that the respective pressure element (40) is provided with a braking device, in particular with a braking device adjustable in its braking torque. 6. Device according to one of claims 1 to 5, characterized in that the frame (13) in the region of one side in a support frame (7) is mounted horizontally movable. 7. The device according to claim 6, characterized in that the respective pressure element (40) in a swivel frame (37, 37) is rotatably mounted, and the swivel frame (37, 37) in a vertically movable portal frame (33) in the frame (13) is pivotally mounted. 8. Device according to one of claims 1 to 7, characterized in that the table (15) on its side facing the entire stack (2) is provided with a drivable conveyor roller (47) for sliding the partial stack (5) onto the table (15) is. 9. Device according to one of claims 1 to 8, characterized in that the device for transferring the Partial stack (5) for the device for breaking up the partial stack (5) has at least one transfer gripper (8) and the device for transferring the broken partial stack (5) to the further processing station (3) has at least one depositing gripper (51). 10. The device according to claim 9, characterized in that the grippers (8, 51) can be moved horizontally in the direction of movement of the frame (13) and vertically. 11. The device according to claim 9 or 10, characterized in that the gripper (8) in the region of its receiving openings blow nozzles (11) are assigned.

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