EP1350750A1 - Method and device for forming piles of continuously delivered, flat ojects - Google Patents

Abstract

The procedure for the forming of stacks of flat objects entails feeding the objects in an upright position to an inlet station (5.11) with the leading edge abutting against an alignment element (5.3). The objects (3) when in a stacked arrangement (4') in an effective area (5.12) at a distance from the inlet station are accelerated in the stacking direction with action on two oppositely-lying edge regions, whereby a downstream orientated part (4.2) of the stacked arrangement is compressed and an inlet-side part (4.1) to which the objects are delivered is held loosely. An Independent claim is included for a device for forming a stack of flat objects.

Description

The invention relates to a method and a device according to the preambles the corresponding independent claims. The method and device serve for the production of stacks of essentially continuously fed flat objects, especially printed products such as Newspapers, magazines, Brochures or partial or intermediate products from newspapers, magazines or brochures.

It is known to print products such as newspapers, magazines, brochures or partial or Intermediates thereof in a substantially upright position, the means with an essentially vertical orientation of its planar extent, and overlapping each other like a scale in a vertical or horizontal, for example Feed direction to form a stack. The printed products will then for stacking with essentially constant spatial Alignment by approx. 90 ° in a usually approximately horizontal or slightly sloping Direction of stack deflected and thereby arranged in a stack. In this stack-like The printed products are usually arranged by the newly supplied ones Printed products are pushed in a stacking direction across the feed direction promoted, being essentially transverse to the stacking direction and on top of each other are aligned, with a downstream end of the stack-like arrangement is supported and wherein the printed products are so closely arranged that they stabilize each other in the essentially upright posture. The downstream end of the stack-like arrangement then becomes discrete Stacks, each a predetermined number of printed products or a predetermined Length, separated and for example a strapping or packaging fed.

An apparatus for generating stacks is of the type briefly described above for example, disclosed in US 4,772,003.

It is an object of the present invention to provide a method and an apparatus create with which, in the manner briefly described above, stacks of flat objects can be created, the inventive stack formation at continuous feeding of the objects should be possible, the objects are used as little as possible by the stack formation according to the invention should be so that less stable such objects can be stacked, and it should still be possible to stack the objects in the Arrangement and to align exactly in the stacks generated from it. Furthermore, it should easily possible with the aid of the method and the device according to the invention be irregularities in the incoming shingled stream, especially gaps or to process multiple scaled-up objects (piles) without any problems. The The device according to the invention should be simple and, in particular, should be simple Different formats of stackable, flat objects can be customized.

This object is achieved by the method and the device as described in the Claims are defined.

According to the method according to the invention, the flat objects are thus as Scale stream in which they are arranged essentially upright, that is, theirs planar extent is oriented approximately vertically, in a feed direction Entry point fed. In the entry point they meet with their leading Edge on an alignment element aligned transversely to the feed direction and deflected by this by approximately 90 ° and thereby arranged in a stack. The stack-like Arrangement grows along in, for example, a horizontal stacking direction the alignment member with its downstream end supported and wherein periodically discrete stacks from this downstream end be separated.

According to the invention, the stack-like arrangement is now located in an inlet-side loco Divided part and a downstream, dense part, in that in an impact area that is spaced from the entry point in the stacking direction, acted in an accelerating manner in the stacking direction on the objects arranged in a stack becomes such that it accelerates towards the downstream end the stack-like arrangement moves and to the objects already there be pressed. The stack-like arrangement is in the Impact area and downstream of it compacted while between impact area and entry point is kept loose. The accelerating effect will exerted on two opposite edge regions of the objects.

Objects that are newly fed at the entry point of the stack-like arrangement are pushed into the loose part of the stack-like arrangement, so that this supply is opposed to a significantly smaller resistance than the The case is when the newly added items all in the stack-like arrangement present objects are to be moved in the stacking direction. Furthermore is this resistance is independent of the current length of the stack-like arrangement. The effect is advantageously enhanced by the objects in the loose part of the stack-like arrangement not only due to the newly added items but can also be actively moved in the stacking direction with suitable means. The loose arrangement of the objects on the first path in the stacking direction not only enables almost resistance-free feeding, but also for less stable objects is easily possible, but also a safe alignment the objects on the alignment element and, if necessary, by additional, the objects aligning means which orientation in the loose Arrangement is less hindered by neighboring objects than this in a tight arrangement would be the case.

When the stack-like arrangement growing in the stacking direction is a predetermined one Has reached length in the stacking direction, the loose part against the dense part pushed and the discreet stack thus formed is removed while moving immediately a new loose part forms from which downstream from the impact area dense part is formed.

The device according to the invention essentially has the following parts: a feeding means for feeding the upright and overlapping one another Objects, an alignment element for deflecting the supplied objects in a stack-like arrangement, means for guiding and supporting the stack-like Arrangement, a release agent for pushing the loose and compacted together Part of the stack-like arrangement to form a stack and a compacting agent in the working area in the stacking direction distanced from the entry point in the stacking direction accelerating towards opposite edge areas of the stack-like arranged objects acts. For the separation of the stack are the Means for guiding and supporting advantageously designed to be movable and in one A plurality is provided so that the means are separated with the stack and at the same time new funds can be positioned for a next batch.

The stack formation according to the invention has a conventional stack formation same type in particular the advantage that the objects in the area of Entry point, i.e. immediately before and after being deflected by 90 ° with only minimal Forces interact with each other, making them easy for stacking and be aligned precisely, even if they are not very stable. The loose arrangement of the objects in the inlet-side part of the stack-like Arrangement also makes it possible to slightly bend the objects and thereby stabilized and stiffened, which is also the exact deflection and alignment is useful. Furthermore, it is easily possible to thicker places in the To supply the shingled stream (heap).

Figur 1

eine beispielhafte Ausführungsform der erfindungsgemässen Vorrichtung (Blickrichtung senkrecht zu Zuführungsrichtung und Stapelrichtung);

Figuren 2 und 3

Einlaufstelle und Einwirkbereich der Vorrichtung gemäss Figur 1 in zwei aufeinanderfolgenden Stadien der Stapelbildung (Blickrichtung wie in Figur 1);

Figur 4

der Ausschnitt gemäss Figuren 2 und 3 mit Blickwinkel parallel zur Zuführungsrichtung und senkrecht zur Stapelrichtung;

Figuren 5 und 6

weitere Details der Ausführungsform gemäss Figur 1;

Figur 7 und 8

zwei weitere Ausschnitte der Ausführungsform gemäss Figur 1 in zwei aufeinanderfolgenden Stadien der Abtrennung eines diskreten Stapels von der stapelartigen Anordnung der Gegenstände (Blickwinkel wie in den Figuren 1 bis 3);

Figur 9

eine weitere, vorteilhafte Ausgestaltung des Einlaufteils der erfindungsgemässen Vorrichtung (Darstellung wie Figur 3);

Figur 10

ein Teil des Einlaufteils gemäss Figur 9 in dreidimensionaler Darstellung;

Figuren 11 bis 13

beispielhafte Ausführungsformen des Einlaufteils in schematischer Draufsicht.

The method according to the invention and exemplary embodiments of the device according to the invention are described in detail with reference to the following figures. Show it:

Figure 1

an exemplary embodiment of the inventive device (viewing direction perpendicular to the feed direction and stacking direction);

Figures 2 and 3

Inlet point and area of influence of the device according to FIG. 1 in two successive stages of stack formation (viewing direction as in FIG. 1);

Figure 4

the section according to Figures 2 and 3 with a viewing angle parallel to the feed direction and perpendicular to the stacking direction;

Figures 5 and 6

further details of the embodiment according to FIG. 1;

Figures 7 and 8

two further sections of the embodiment according to FIG. 1 in two successive stages of separating a discrete stack from the stack-like arrangement of the objects (viewing angle as in FIGS. 1 to 3);

Figure 9

a further, advantageous embodiment of the inlet part of the device according to the invention (illustration as in FIG. 3);

Figure 10

a part of the inlet part according to Figure 9 in a three-dimensional representation;

Figures 11 to 13

exemplary embodiments of the inlet part in a schematic plan view.

FIG. 1 shows an exemplary embodiment of the device 1 according to the invention. A shingled stream of flat objects 3, for example of folded or bound printed products, from which stacks 4 are formed, is fed to this device via any feed 2. The device 1 essentially has an inlet part 5 and a stack part 6, which cooperate for the stack formation.

The essential components of the inlet part 5 are feed means, for example Feed belts 5.1 and 5.2, an alignment element 5.3, a compacting agent 5.4 and a separating element 8. The feed belts 5.1 and 5.2 are used for feeding of the scale flow, the objects 3 for the supply essentially are arranged upright in the shingled stream. The alignment element 5.3 is transverse arranged to the feed direction 5.10 and serves to deflect the feed Objects from the feed direction 5.10 to the stacking direction 4.3 Alignment and, if necessary, also their movement in the stacking direction 4.3. The Compression means 5.4 arranged in an impact area 5.12 is used for compression of the downstream part of the stack-like arrangement 4 '. His Function is described in more detail in connection with Figures 2 to 4. The separating element 8 is used to separate the shingled stream and pushing the loose part onto the compacted part of the stack-like arrangement 4 '.

The flat objects 3 are in the feed direction 5.10 between the at least two endless belts 5.1, 5.2 promoted against the alignment element 5.3. On the entry point 5.11 they meet with their leading edge against the cross to the feed direction 5.10 extending alignment element 5.3 and are thereby arranged in a stack and in the stacking direction 4.3 (perpendicular to the feed direction 5.10) moved along the alignment element 5.3, pushed on the one hand by further supplied objects and advantageously also actively moved in this direction, for example in that the alignment element 5.3 as shown in FIG Stack direction 4.3 driven conveyor belt is formed or such a conveyor belt having.

The stack part 6 has at least two receiving devices 6.5, the essential ones Components of a support document 6.2 and a support element 6.3 are. The Recording devices 6.5 serve to record the continuously growing, stack-like arrangement 4 'and the removal of one from this stack-like arrangement 4 'separated stack 4 from the inlet part 5. The support document 6.2 and the support element 6.3, which during the recording of the stack-like arrangement 4 ' both are moved in the stacking direction 4.3, guide, support and convey the objects in this arrangement 4 '. If necessary, the funding document 6.2 can also be replaced by a stationary pad on which the objects stand up push each other.

For the separation of discrete stacks 4 from the stack-like arrangement 4 ', the is possible with the device shown without interrupting the feed the stack part 6, for example, four identical receiving devices 6.5, the spaced from each other by 90 ° about an axis of rotation 6.1, such that with each rotation through 90 ° a receiving device with a stack 4 pivoted away from the inlet part 5 and a further, empty receiving device the inlet part 5 is connected.

The receiving device 6.5, which is designated by I in FIG. 1, is on the inlet part 5 connected. The stack-like arrangement 4 'grows in this receiving device into it, the support element 6.3 being continuously shifted in the stacking direction 4.3 is and the conveyor support 6.2 moves in the stacking direction. Once the support element 6.3 has reached its end position, that is, the receiving device 6.5 is sufficiently filled, the stack part 6 is turned counterclockwise by 90 degrees, whereby the receiving device with the stack 4 just formed in the position designated II is moved. The stack 4 is here on a support surface with grooves 6.7, in which the arms of an ejection device 7 engage. With the help of the ejection device 7, the stack 4 becomes the receiving device 6.5 encountered. By further rotations by 90 °, the receiving device 6.5 in the position labeled III, and then in the position labeled IV Position rotated. It is advantageous to use diagonally opposite one another Coupling receptacles 6.5 in such a way that the support element 6.3 of a receiving device connected to the inlet part 5 (position I) of its starting position is moved to its end position while in the pickup device in position III the support element 6.3 from its end position in the Starting position is moved. In positions II and IV is the support element then stationary.

The separation of discrete stacks 4 from the stack-like arrangement 4 'is used also the separating element acting between the area 5.12 and the inlet 5.11 8, which for the exercise of its function in the vertical direction 8.1, 8.3 and is mounted movably in the horizontal direction 8.2, 8.4. The function of the Separating element 8 is shown in more detail in connection with FIGS. 6 to 8 described.

The spatial position of the device according to the invention shown in FIG. 1 is to be chosen in such a way that the flat expansion of the flat objects 3 in the feed to the entry point 5.11 and in the stack-like arrangement 4 'in essentially perpendicular, that is, aligned parallel to gravity and the Stack direction 3.4 runs essentially horizontally. The axis 6.1 is for example essentially horizontal, so that the objects 3 on the alignment element 5.3 and get up on the subsequent funding document 6.2. However, the axis 6.1 can also be oriented essentially vertically. In one In such a case, the feed direction 5.10 is essentially horizontal and is located stack-like arrangement 4 'on the side of the alignment element 5.3. For this reason is a separate from the alignment element 5.3 for the support and conveying function Provide funding on which the objects stand after the deflection and to which the funding document 6.2 then connects. Another side one Guide element 6.4 for the stack-like arrangement would be advantageous in this case.

It is not relevant to the invention that the at least two receiving devices 6.5 of the stack part about an axis perpendicular to the stacking direction 4.3 6.1 are rotatable, as shown in Figure 1. It can make more sense in others Way for an exchange of a full with an empty cradle be taken care of.

The formation of the stack-like arrangement 4 ', which according to the invention has an inlet-side, loose part 4.1 and a downstream, compressed part 4.2 is described in more detail with reference to Figures 2 to 4. These figures show the formation of the stack-like arrangement 4 'with the loose inlet side Part 4.1 and the downstream, compressed part 4.2 in an enlarged view Representation with viewing angle perpendicular to the feed direction 5.10 and stacking direction 4.3 (Figures 2 and 3) and parallel to the feed direction (Figure 4). Same Elements are identified by the same reference numbers as in FIG. 1.

FIG. 2 shows an inner feed belt 5.1 and outer feed belts 5.2 (central) and 5.2 '(laterally) which are deflected on deflection rollers 5.7 and 5.7' on the inlet side. The formation of the outer feed belts as a central belt 5.2 and lateral belts 5.2 ′ arranged further inward with respect to the central belt and an elastic pressing of the inner belt 5.1 against the central outer belt 5.2 result in a bending of the supplied objects 3 about a bending axis parallel to the feed direction, whereby these are stabilized and stiffened until they strike the alignment element 5.3.

The support element 6.3 is in its starting position in the active area in FIG 5.12 shown, that is in a position in which it is, if just a Stack has been separated from the stack-like arrangement 4 '. In this position it is spaced from the entry point 5.11 in the stacking direction 4.3, the stack-like Arrangement 4 'therefore only has a loose part 4.1 on the inlet side.

During the loose part 4.1 of the stack-like arrangement at the entry point 5.11 objects 3 are continuously fed and fed by further Objects 3 and possibly by the conveyor belt of the alignment element 5.3 driven in the stacking direction 4.3 against the support element 6.3, the support element 6.3 is advantageously coupled to the support base 6.2 moved away from the entry point 5.11. The tape of the Alignment element 5.3 with the same, on the feed stream (speed and distances between the objects) and the thickness of the supplied objects coordinated feed rate driven.

In the impact area 5.12, the alignment element 5.3 is connected, for example, as Double conveyor belt trained support 6.2 through which the stack-like Arrangement 4 'is guided and conveyed into the receiving device 6.5, whereby it is supported downstream at its end by the support element 6.3.

FIG. 3 shows the same section from the embodiment of the device according to the invention as shown in FIG. 1 as already shown in FIG. However, the stack-like arrangement 4 'has grown further here and has more objects 3. In the illustrated stack-like arrangement 4 ', a cross stack is pre-formed; the bundle of objects 3.2 is directed upwards and the bundle of objects 3.1 is directed downwards. For such a crosswise arrangement, the objects 3, 3.1, 3.2 are to be fed accordingly.

The compression means 5.4 is at a distance from the entry point 5.11 in the stacking direction 4.3 arranged such that it is on two opposite edge regions the objects 3 of the stack-like arrangement 4 'accelerating in the stacking direction 4.3 can work. This acceleration makes the downstream one Part 4.2 of the stack-like arrangement 4 'compared to the inlet-side part 4.1 driven against the support element 6.3 and thereby compressed. The densifying agent 5.4 is for example as a synchronous and oppositely arranged pair of endless Bands formed, the speed of these bands is greater than that Speed of the belt of the alignment element 5.3, the conveyor base 6.2 and of the support element 6.3.

FIG. 4 shows the stack-like arrangement 4 'of objects 3 with the compressed part 4.2 and the loose part 4.1 with a viewing angle parallel to the feed direction. Deflection rollers 5.5 and the two endless belts 5.6 are visible from the compression means 5.4. Due to their effect, the objects in the impact area 5.12 may be slightly bent. The objects 3 are loosely arranged in the loose part 4.1 of the stack-like arrangement 4 'between the entry point 5.11 and the acting area 5.12 and exert only slight forces on one another. The objects 3 stand within the loose part 4.1 on the alignment element 5.3 (or on a corresponding conveying means) and are moved by it in the stacking direction 4.3. Due to the mutual freedom of movement of the objects 3 in this loose part 4.1 and due to gravity, they can align themselves exactly on the alignment element 5.3 (or corresponding funding).

FIG. 4 also shows that already mentioned in connection with FIG. 2 curved feed of the objects 3 visible. Through this curved feeder each object is given additional stability in the feed direction, whereby the insertion of each new item is even safer and more precise becomes. As soon as the trailing edge of the object is no longer between the Feed belts 5.1 and 5.2 is held, it stretches again. For the bend of the supplied objects are the outer guide bands 5.2 and 5.2 'as already mentioned at least in the area of the entry point 5.11 in the stacking direction 4.3 slightly offset from each other, which is achieved for example is that the deflection rollers 5.7 'of the lateral outer feed belts 5.2' (here shown as a pair of strings) have a larger diameter than that Deflection roller 5.7 of the central, outer guide band 5.2. As a result, the lateral, outer feed belts 5.2 ', as shown in that shown in Figures 2 and 3 Side view can be seen, in contrast to the central, outer feed belt 5.2 not exactly perpendicular to the stacking direction 5.4 but slightly to the stacking direction 4.3 inclined. This arrangement of the outer feed belts 5.2 and 5.2 ' becomes an object to be fed 3 around a bending axis parallel to the feeding direction bent, as shown in Figure 4 on the newly added item 3.3 is.

FIG. 5 shows a holding element 10 which, as indicated by the positions 10.1 and 10.2, is mounted displaceably along the path shown by arrows. The holding element 10 is then moved into its working position, shown in solid lines, if there is a gap in the supply flow of objects 3, such that two successive objects do not overlap. The holding element 10 keeps the objects supplied in front of the gap away from the entry point, so that the objects supplied after the gap can be supplied without coming into conflict with the previously supplied objects. As soon as the feeder works continuously again, the holding element 10 is moved into the position denoted by 10.1 in order to be moved again against the last object fed in at a further gap via the position 10.2.

Figure 6 shows the operation of the separating element 8 in detail. The separating element 8 is shown in dashed lines in a waiting position. As soon as the stack-like arrangement 4 'has reached the predetermined size of a stack 4, the separating element 8 is moved in the direction 8.4 (stacking direction) through the entry point (position shown in solid lines). This movement is synchronized with the feed flow of the flat objects 3 in such a way that during the movement of the separating element 8 a last object 3 is fed into a still loose part of the stack-like arrangement 4 ′ before the separating element 8 and a subsequent object 3 behind the separating element 8 ,

FIG. 7 shows the separating element 8 in its end position, at a distance from the entry point 5.11 in the stacking direction and at the beginning of the action area, where the conveying base 6.2 connects to the aligning element 5.3. By moving the separating element 8 into this position, the loose part of the stack-like arrangement 4 'is pushed against the dense part, so that a discrete, dense stack 4 is formed between the separating element 8 and the support element 6.3. Objects 3 are further fed behind the separating element 8, so that a loose part 4.1 of a stack-like arrangement is formed again.

Obviously, the distance between the entry point and the end position of the Separating element 8 or starting position of the support element 6.3 (beginning of the area of action) to be chosen in such a way that it is large enough to withstand the separation of stack 4 pick up objects in a loose arrangement to be able to, and such that the first after the separation of a stack objects placed in it can maintain an upright position.

FIG. 8 shows the rotation of the stack part of the device according to the invention in the direction 6.6, through which the stack 4 is moved away from the inlet part and a further, empty receiving device 6.5 with the support element 6.3 is connected to the inlet part in its starting position.

During the rotation, the separating element 8 remains in that already shown in FIG Position and temporarily takes over for the further fed objects the function of the support element. Even the densifying agent that is in the Figure 8 is not shown, is not moved. This leads during the rotation Separating element 8 the one of the rear edges of the stack 4 in the stacking direction for guiding the stack edges at the rear in the stacking direction is advantageous an additional guide part that extends the guidance of the separating element 8 9 provided.

As soon as the further, empty pick-up device is connected to the inlet part, the separating element 8, as shown in Figure 1, in directions 8.1, 8.2 and 8.3 move and thereby into the waiting position shown in dashed lines in Figure 3 and Figure 6 brought. From Figure 4, which is in this waiting position Separating element 8 shows from above, it can be seen that this consists of two parts, between the central outer feed belt 5.2 and the lateral outer Feed belts 5.6 'or between the deflection rollers 5.7 and 5.7' can be moved.

FIG. 9 shows a further, advantageous embodiment of the inlet part of the device according to the invention in the same representation as FIG. 3. The same elements are identified with the same reference numbers. In this embodiment, the input-side revolving roller 5.15 of the inner feed belt 5.1, which is arranged directly above the loose part of the stack-like arrangement 4 ', has a brush roller 20 rotating with the revolving roller 5.15 on both sides of the feed belt 5.1. These brush rollers 20 serve as a further means of driving the objects released from the holder between the inner and outer feed belts 5.1 and 5.2 in the stacking direction 4.3. The brush rollers 20 also take on the function of the holding elements 10 described in connection with FIG. 5, but they act continuously in such a way that no special measures need to be taken when the shingled stream is interrupted and a corresponding sensor system can be omitted.

Furthermore, the inlet part according to FIG. 9 instead of the inlet side shown in FIG Ends of the lateral, outer feed belts 5.2 'laterally from the central, outer feed belt 5.2 arranged guide plates 21. These guide plates 21 each have a spacing from the alignment element 5.3 in the stacking direction 4.3 projecting area 21.1, from which the lower areas of the supplied Objects are bent forward in the 4.3 direction and in the loose Area of the stack-like arrangement 4 'for the newly fed object Make space even better. The lateral, outer feed belts 5.2 'can each after designing the guide plates 21 completely missing or the objects supplied lead to the upper edge of the guide plates 21 and possibly also in the manner shown in Figure 4 about a bending axis parallel to the feed direction 5.10 bend, as shown in Figure 4.

FIG. 10 shows in a three-dimensional representation an exemplary embodiment of the guide plates 21 already described in connection with FIG. 9 with the regions 21.1 facing the alignment element (not shown) and projecting in the stacking direction 4.3. FIG. 10 shows only the guide plates 21 and the central, outer feed belt 5.2 of the inlet part with the deflection roller 5.7 on the inlet side. The guide plates 21 are arranged slightly obliquely relative to the central, outer guide belt 5.2, that is to say they take over an object which has already been bent by the lateral outer feed belts (5.2 'in FIG. 9), not shown, and guide it in the same bent state against the alignment element. While the object is still held between the inner and outer feed belt in an area facing away from the aligning element, its area facing the aligning element is bent forward in the stacking direction 4.3 by the areas 21.1 of the guide plates 21 projecting in the direction of the strap 4.3 and thus displaces objects previously deposited on the aligning element in the stacking direction 4.3, in order to make room for its own positioning.

It can be seen that the regions 21.1 of the guide plates projecting in the stacking direction 4.3 21 advantageously approximately in the middle between the inlet end the inner feed belt 5.1 and the alignment element 5.3 are arranged, as shown in Figure 9.

Figures 11 to 13 show in a very simplified plan view (parallel to the feed direction seen against the alignment element) different embodiments of the area of the inlet part of the inlet part of the device according to the invention, in particular the inner and outer feed belts 5.1, 5.2, 5.2 'and, if necessary the guide plates 21.

The embodiment according to FIG. 11 is essentially that according to the figures 1 to 8. It therefore has an inner feed belt 5.1 with an inlet-side deflection roller 5.15 on and a central, outer feed belt 5.2 with an inlet side Deflection roller 5.7 and two lateral, outer feed belts 5.2 'with Infeed pulleys 5.7 '. The deflection rollers 5.7 and 5.7 'of the outer feed belts 5.2 and 5.2 'are arranged coaxially, the diameter of the Deflection rollers 5.7 'are larger than the diameter of the deflection roller 5.7, so that a fed object 3 is bent in the manner shown.

FIG. 11 also shows in the area of action of two opposing ones Sides acting on the objects in the stack-like arrangement (not shown) Compaction agents 5.4. The compression means 4.5 differ from the compression means shown in Figures 1 to 4 in that they additionally also perform a lateral alignment function for the compression function. This is followed by the downstream and in the stacking direction 4.3 an alignment part upstream from the entry point of the compression part 5.4 ' 5.4 ". While the two compression parts 5.4 'parallel to the stacking direction 4.3 are aligned, the alignment parts 5.4 "run towards each other and thus form a funnel-like inlet into the area in which the objects the stack-like arrangement also perpendicular to the feed direction aligned with each other. This alignment is only possible thanks the inventive, loose arrangement of the objects in the first part of the stack-like arrangement.

For an adjustment to different formats of the objects to be stacked are the compression means 5.4 advantageously adjustable transversely to the stacking direction (Arrows A).

Figure 12 shows the same plan view as Figure 11 essentially the arrangement according to FIG. 9. The one from the lateral, outer feed belts 5.2 ' Bending axis objects bent (not shown) parallel to the feed direction are continued by guide plates 21 and through in the stacking direction 4.3 protruding areas 21.1 of the guide plates 21 in the stacking direction 4.3 curved at the front.

FIG. 13 shows a further embodiment as the same top view as FIGS. 11 and 12 of the feed-side area of the inlet part of an inventive Contraption. The deflection rollers 5.7 'of the lateral outer feed belts 5.2 'have the same diameter as the pulley 5.7 of the central, outer Feed belt 5.2 or may be missing entirely. The side, outer feed belts 5.2 'against the alignment element detaching guide plates 21 are wound in such a way that it first moves an object parallel to a bending axis Bend the feed direction and then its leading area in the stacking direction 4.3 Bend forward.

In an advantageous embodiment of the device according to the invention, the Feed part 5, as shown in Figure 1, a switch 5.9, so that the objects 3 can be controlled accordingly either left or right along the conveyor belt 5.2 can be fed continuously to the alignment element 5.3. On the right side of the alignment element 5.3 could be a further stack part 6 to form stacks 4 be arranged or a device for forming rods. The switch 5.9 could also serve as an overflow function or the removal of defective objects serve.

Claims (22)

Method for forming stacks (4) of flat objects (3), the objects (3) being fed overlapping and essentially upright in a feed direction (5.10) to an entry point (5.11), the objects (3) being fed at the Entry point (5.11) with a leading edge is struck against an alignment element (5.3) extending transversely to the feed direction (5.10) and thereby deflected essentially at right angles into a stacking direction (4.3) and arranged in a stack-like manner (4 '), the stack-like arrangement (4 ') of the objects (3) and supported at their downstream end in the stacking direction (4.3), and wherein from the downstream end of the stack-like arrangement (4') stack (4) are separated, characterized in that the objects (3 ) in the stack-like arrangement (4 ') in an action area (5.12) which is spaced from the entry point (5.11) in the stacking direction (4.3), attacking at two opposite edge areas are accelerated in the stacking direction (4.3), whereby a downstream part (4.2) of the stack-like arrangement (4 ') compresses and an inlet-side part (4.1), to which the objects (3) are fed, is loosely held becomes. A method according to claim 1, characterized in that the objects (3) in the compressed part (4.2) and / or in the loose part (4.1) of the stack-like arrangement (4 ') additionally with a speed, distance and thickness of the supplied objects (3 ) coordinated speed in the stacking direction (4.3). Method according to one of claims 1 or 2, characterized in that for the separation of a stack (4) from the stack-like arrangement (4 ') the loose part (4.1) is pushed against the compressed part (4.2) of the stack-like arrangement (4') and both parts (4.1 and 4.2) are separated together as a stack (4). Method according to claim 3, characterized in that the stack (4) is separated by turning away about an axis (6.1) perpendicular to the stacking direction (4.3). Method according to one of claims 3 or 4, characterized in that a further loose part (4.1) is formed during the separation of the stack (4) by further supply of objects (3). Method according to one of claims 1 to 5, characterized in that the objects are bent about a bending axis aligned parallel to the feed direction (5.10) before they strike the alignment element (5.3). A method according to claim 6, characterized in that leading areas of the objects are additionally bent forward in the stacking direction (4.3) before they strike the alignment element (5.3). Method according to one of claims 1 to 7, characterized in that the feed direction (5.10) is substantially vertical or substantially horizontal and the stacking direction (3.4) is substantially horizontal or slightly sloping. Device (1) for forming stacks (4) of flat objects (3), which device feed means for supplying a shingled stream of the overlapping and upright objects (3) in a feed direction (5.10) to an entry point (5.11), a cross Alignment element (5.3) extending to the feed direction (5.10), on which the supplied objects (3) are struck at the entry point (5.11) with a leading edge and are thus deflected essentially at right angles in a stacking direction (4.3) and arranged in a stack-like manner (4 ') , a receiving device (6.5) with means for guiding the growing, stack-like arrangement (4 ') in the stacking direction (3.4) and with a support element (6.3) for supporting the stack-like arrangement (4') at its downstream end, and means for separating of discrete stacks (4) from the downstream end of the stack-like arrangement (4 '), characterized in that the pre direction further comprises a compacting means (5.4) arranged in an effective area (5.12), the effective area (5.12) being spaced apart from the entry point (5.11) in the stacking direction (4.3) and wherein the compacting means for one on two opposite edge areas of the stacked objects (3) attacking, in the stacking direction (4.3) acting acceleration of the objects (3) is equipped. Apparatus according to claim 9, characterized in that the compression means (5.4) has two counter-rotating endless belts (5.6) which are arranged on opposite sides of the stack-like arrangement (4 '). Apparatus according to claim 9 or 10, characterized in that the alignment element (5.3) is designed as a conveying means or that a conveying means is provided parallel to the aligning element (5.3), the conveying means in the stacking direction (4.3) with a speed, spacing and thickness of the supplied objects (3) coordinated speed can be driven. Device according to one of Claims 9 to 11, characterized in that the receiving device (6.5) has a conveying means which can be driven in the stacking direction (3.4) at a speed which is matched to the speed, distances and thickness of the objects (3) fed. Device according to claim 12, characterized in that the support element (6.3) is coupled to the conveying means of the receiving device (6.5). Device according to one of claims 9 to 13, characterized in that a separating element (8) is provided for the separation of discrete stacks (4) from the stack-like arrangement (4 '), which separates from a position in the stacking direction behind the entry point into the action area is movable and can be designed and driven in such a way that it can separate the shingled stream supplied during the said movement and can temporarily take over the function of the support element (6.3) in its position in the area of action. Device according to one of claims 9 to 14, characterized in that for the separation of discrete stacks (4) at least two receiving devices (6.5) are provided which can be moved coupled to one another, one receiving device removing the stack (4) from the stack-like arrangement (4 ') separates and the other receiving device (6.5) is positioned for further receiving the stack-like arrangement (4'). Apparatus according to claim 15, characterized in that four receiving devices (6.5) are provided which are arranged rotatably about an axis (6.1) perpendicular to the stacking direction (3.4). Device according to one of claims 9 to 16, characterized in that an inner feed belt (5.1) and a plurality of outer feed belts (5.2, 5.2 ') are provided for the feed, the inner and at least one of the outer feed belts being elastically pressed against one another , Apparatus according to claim 17, characterized in that a central, outer feed belt (5.2) is pressed against the inner feed belt (5.1) and that, in the stacking direction (3.4) in front of the central, outer belt (5.2), lateral, outer feed belts (5.2 ' ) are provided. Apparatus according to claim 17 or 18, characterized in that a deflection roller (5.15) of the inner feed belt (5.1) arranged on the inlet side has brush rollers (20) arranged laterally and rotating with the deflection roller (5.15). Device according to one of claims 17 to 19, characterized in that guide plates (21) which replace the lateral outer feed belts (5.2 ') or detach them on the inlet side are provided, the guide plates (21) between the alignment element (5.3) and an inlet side Deflection roller (5.15) of the inner feed belt (5.1) has an area (21.1) projecting in the stacking direction (4.3). Device according to claim 20, characterized in that the projecting area (21.1) of the guide plates (21) are arranged centrally between the alignment element (5.3) and the inlet-side deflection roller (5.15) of the inner feed belt. Device according to one of claims 20 or 21, characterized in that the guide plates (21) are arranged obliquely or twisted relative to the central, outer feed belt (5.2).

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