EP1299298A1

EP1299298A1 - Method and device for the suspended transport of objects on a transport track comprising an accumulated store

Info

Publication number: EP1299298A1
Application number: EP01940041A
Authority: EP
Inventors: Carl Conrad MÄDER; Erwin Müller; Markus Felix
Original assignee: Ferag AG
Current assignee: Ferag AG
Priority date: 2000-07-07
Filing date: 2001-06-26
Publication date: 2003-04-09
Anticipated expiration: 2021-06-26
Also published as: US6968937B2; DE50101995D1; AU7375701A; EP1299298B1; CA2414169C; ES2218420T3; US20030098219A1; DK1299298T3; WO2002004330A1; ATE264257T1; CA2414169A1; AU2001273757B2

Abstract

The invention relates to retaining elements (1), which are equipped for the suspended transport of individual objects (2) that can be displaced independently of one another in at least a limited manner along a section of rail (5) and that maintain a uniform minimum distance between one another, when being pushed along. During transport, the retaining elements accumulate at an accumulation point by means of an accumulation element (16), in such a way that a reserve store (12) is formed upstream of the accumulation point and said elements are then released from the reserve store (12) in a controlled manner. The retaining elements (1) are not released and transported away from the reserve store (12) individually, but in groups (15) of retaining elements. In said groups, (15) the retaining elements (1) advantageously maintain the aforementioned minimum distance between one another. An additional accumulation element (16), which acts at an additional accumulation point upstream of the first accumulation point, is used to form in advance the groups (12) that are to be released in the reserve store (12). In said manner, the formation of groups is integrated into the accumulation operation in the form of a concentration of the process and the stream of groups that is transported away from the accumulated store (12) can be fed, without further modification, to a unit (4), in which groups of objects suspended by retaining elements (1) are processed, for example, stacked and packaged in batches.

Description

METHOD AND DEVICE FOR HOLDING

PROMOTION OF OBJECTS ON ONE

CONVEYOR LINE WITH BUFFER STORAGE

The invention lies in the field of conveyor technology: and relates to a method and a device according to the preambles of the corresponding independent claims. The method and device are used to convey objects on a conveyor line, the objects being held individually and being conveyed along the conveyor line one behind the other and at least to a limited extent independently of one another, and the objects passing through a buffer store during the conveyance along the conveyor line.

Funding in the manner mentioned above is known in particular for flat objects such as newspapers and magazines from the publications DE-2822060 (or US-4201286, F091), CH-382768 (or US-3032341, F002) EP-0276409 (or US-4892286 , F236), EP-0309745 (or US-4888265, F245) or WO-99/33731 (F475). Each of the flat objects is supported by a holding element in such a way that its main surfaces are oriented essentially transversely to the conveying direction. The holding elements can be moved individually and at least to a limited extent independently of one another along a rail track and are configured in such a way that they can be driven in an abutting manner. The extent of the holding elements in the conveying direction is the same for all holding elements and is advantageously greater than the corresponding extent of the objects (thickness of the flat objects), so that they were defined in rushed operation Set the distances between holding elements (distance, for example, between the front ends of two successive holding elements) or between objects held by holding elements, which distances are the smallest possible distances in a given system.

The advantages of the conveying method briefly described above for conveying flat objects compared to conveying methods with holding means, which are arranged equidistantly on a single conveying element, for example on a revolving chain, are, among other things, that the distances between the mutually independent holding elements are local with a great deal simple means, in particular without transferring the objects to other holding means, can be changed, that very dense and yet precisely arranged delivery streams can be formed and that conveyor lines can be designed in a very simple manner as a buffer store.

To form a buffer store, the holding elements are simply dammed up on the conveying path and released and conveyed in a controlled manner from the head end of the traffic jam. The jam, which has a stationary head end and a variable length, represents the buffer store. For the implementation of such a buffer store on a conveyor line of the type mentioned, drives (motor drives or

Gravity) with which holding elements with constant or variable speed and with constant or variable distances to the tail end of the buffer store and with variable speed and minimum distances are conveyed through the buffer store (feed and buffer drive) and with which drives at the head end of the buffer store released holding elements from

Buffer storage are transported away (removal drive). Means are also to be provided with which holding elements are stowed in the buffer memory from which

Buffer storage can be released and transferred to the conveyor drive. Buffer memories are used wherever an object-delivering and an object-receiving unit are to be flexibly connected to one another in such a way that the units perform well (in objects per unit of time) within wide limits without mutual dependencies (decoupled) and yet without ejecting the objects from a common one Process regulations should be operated. If the performance of the object-delivering unit is greater than the performance of the object-receiving unit, the fill level of the buffer store increases. If the performance of the object-delivering unit is less than the performance of the object-receiving unit, the fill level of the buffer store drops.

According to the state of the art (see above-mentioned publications), buffer stores on conveyor lines for holding and independently conveying holding elements or objects held by holding elements, as described above, have a clock wheel on their stationary head end as a stowage or discharge means , This cycle wheel has teeth adapted to the holding elements and rotatably detects with each of its teeth the foremost holding element in the buffer memory in order to separate it from the head end of the buffer memory and to transfer it to the removal drive. For a variable discharge performance (in holding elements or held objects per unit of time), the speed of rotation of the cycle wheel is varied as required or the cycle wheel is switched (predetermined, unchangeable speed or standstill).

The object of the invention is to make conveying and buffering as described above more flexible in such a way that the flow of objects or holding elements (with or without holding objects) conveyed away from the head end of the buffer store to a greater extent different, downstream conditions can be adjusted as with Methods and arrangements according to the prior art is possible. The application of the method and the device according to the invention are therefore intended to provide a discharge flow which can be led directly to a unit which places conditions on the discharge flow, if possible without further conversion or with a considerably reduced degree of further conversion. In comparison with the prior art, the method and device according to the invention are intended, in particular, to bring about an increased process density and a reduction in conveyor line lengths necessary for flow flow conversions, in such a way that the conveying / buffering retains its essential features but is arranged closer to a downstream, object-receiving unit can and, if possible, does not require any other means for converting electricity.

This object is achieved by the method and the device as defined in the patent claims.

The method according to the invention essentially consists in not releasing holding elements (with held objects or without) individually but in groups from the buffer store and transferring them to a removal conveyor drive, that is to say, when discharging, not a stream of individual holding elements as in the prior art but to generate a stream of holding element groups. In this group flow conveyed away, the holding elements within the groups, such as in the buffer store or in interrupted conveying operation, advantageously have the minimum distance from one another, the distances between groups and the conveying speed are optionally constant or variable, and the number of holding elements in the groups is constant or variable. However, the objects conveyed away from the head end of the buffer are still kept individually. Obviously, with the method according to the invention, it is also possible to create a flow of holding element groups in which each group has only one holding element. According to the prior art, only such discharge flows can be created, according to the invention, whose task (see above) is to increase flexibility, the creation of such discharge flows represents a special case that is possible, but for which the method and the device are not specific are suitable.

The method and device according to the invention are particularly suitable for feeding object groups to units in which objects are processed in narrow groups, for example stacked or packaged.

The groups of holding elements, which are released from the buffer storage and transferred to the removal conveyor drive according to the method according to the invention, are pre-formed in the buffer storage, in which the holding elements are already arranged at minimal distances from one another. In addition to the formation of groups, other conversions of the delivery flow that are oriented to downstream conditions of the discharge flow can also be carried out in the buffer memory, for example reorientation of the objects, marking of the objects as members of a specific group, marking of objects as specific group members (e.g. group member, the in the group as the foremost or rearmost) or the formation of sub-groups within the groups.

The device according to the invention has for the serial conveying of

Holding elements or of objects individually held by holding elements along a conveying path on a plurality of holding elements, one behind the other and at least limited independently of one another along one of the Conveying track defining rail track are movable. Furthermore, the device has a feed drive for feeding holding elements to the tail end of a buffer store, a buffer drive for feeding holding elements from the tail end of the buffer store towards the head end and a conveying drive for conveying away holding elements from the head end of the buffer store, and a means for forming holding element groups in the buffer store and a means for releasing groups of holding elements from the buffer store and for transferring the groups to the removal drive.

Gravity can be used at least partially as a feed, buffer and removal drive. Feed, buffer and removal drives can be designed as separate drives or as one or two drives, at least one of the drives taking on more than one of the drive functions mentioned. In the same way, the functions of the above-mentioned means for forming groups and for releasing and transferring can be performed by a separate device part or together by the same device part.

As already indicated in the above sections, it is of no importance for the method according to the invention or for the device according to the invention whether the holding means carry objects in the feed flow, in the buffer store or in the discharge flow or not. In most applications, either all of the holding elements will be loaded or all of the holding elements will be unloaded. Applications with partially loaded and partially unloaded holding elements are also conceivable.

The method according to the invention and various embodiments of the device according to the invention are described in more detail in connection with the following figures. Show: Figure 1 shows the principle of the inventive method;

FIGS. 2 and 3 the sequence of a group layoff for two exemplary embodiments of the method according to the invention;

Figures 4 to 6 schemes of various exemplary embodiments of the device according to the invention;

Figures 7 and 8 application examples for the inventive method and the inventive device.

Figure 1 is a schematic diagram of the inventive method. According to this method, objects 2, e.g. flat objects such as newspapers or magazines, for example conveyed from an object-delivering unit 3 to an object-receiving unit 4 along a conveyor line defined by a rail track 5. The holding elements 1 are independent of one another, that is to say advantageously not connected to one another, possibly connected to one another by connecting elements which have a variable length in the conveying direction F. The holding elements 1 are rolling or sliding bodies, each having a gripper for gripping an object 2. In the conveying direction, all of the holding elements 1 advantageously have the same, as short as possible length, such that, when pushed against one another, they form a dense conveying flow with uniform distances between the grippers or between the objects held by the grippers.

The conveying section is divided into three parts in terms of function: an infeed section 10, an outfeed section 11 and between the infeed section 10 and outfeed section 11 a buffer store 12 with a head end 13 and a tail end 14, whereby the position of the head end 13 on the conveyor line is substantially constant and the position of the tail end 14 varies depending on the fill level of the buffer store 10.

According to the invention, individual holding elements 1 or individual, held objects 2 are not released at the head end 13 of the buffer memory 10, but rather holding element groups 15 are released and conveyed away, which holding element groups 15 are pre-formed in the buffer memory 12 before they are released. As will be described in detail below, two stowage means 16 arranged one behind the other in the conveying direction are provided for this group formation and group discharge at the head end of the buffer store.

As with any buffering, the performance in holding elements per unit of time must be the same for the conveyance as for the conveyance away. This condition, the maximum buffer storage capacity and, of course, other features of a given device set limits on the distances and speeds that are possible for feeding and conveying away. Distances and / or speeds for the feed can be freely selected within these limits. When transporting away, the distances within the groups essentially correspond to the minimum distance, while the distances between the groups are freely selectable. In the buffer store 12, the distances are equal to the minimum distance and the speed is such that for each group discharge the corresponding group is present and preformed at the head end of the buffer store.

The following variants are possible for the supply: • Speed variable and distances between holding elements constant (with gaps if necessary)

• Constant speed and distances between holding elements variable (sometimes also minimal distances: "groups");

• variable speed and distances between holding elements variable;

• Constant speed and distances between holding elements constant (with gaps if necessary).

The following variants are possible, for example, for releasing the groups from the buffer storage and transporting them away (distances between groups: distance between the first or last holding element from successive groups), the groups being in each case the same size or comprising different numbers of holding elements can:

• Group release from memory on demand (time intervals between group releases variable) and removal speed constant, which leads to variable group intervals;

• Group layoffs are clocked regularly (time intervals between group layoffs are constant) and variable transport speed, which leads to variable group spacings;

• Group release is clocked regularly and the conveying speed is constant, which leads to constant group distances. As will be shown later, devices are particularly simple if the feed speed and the removal speed are the same and also the same as the maximum buffer speed. In this case, the device according to the invention can be implemented with a single drive for feeding, buffering and conveying away, if the drive is designed in such a way that it grinds in the buffer against jammed holding elements, or in such a way that holding elements jammed in the buffer can be temporarily decoupled from the drive. An example of such a conveyor system with a drive running continuously along the conveyor line, to which the holding elements can be magnetically coupled, is described, for example, in publication WO-99/33731 (F475).

Gravity can be used instead of mechanical means, in particular for the feeding and for the buffering, if the conveyor line is laid down in a correspondingly sloping manner. For the stowage function, another braking effect can be used instead of an active stowage agent, for example gravity on a rising piece of the rail track, the friction between the rail track and holding elements or just the momentary lack of a driving force (passive stagnation point).

The objects 2 are supplied to the object-delivering unit 3, for example in a stream of shingles or individually, for example from a storage unit (winding, feeder), and are taken over there by the holding elements 1. In the object-receiving unit 4, the objects 2 are, for example, delivered or processed in groups by the holding elements 1 and conveyed further for delivery in any order. A return path is to be provided for empty holding elements 1, on which they are conveyed back to the unit delivering objects 2 for taking over objects 2 again. The objects delivering and the objects Acquiring unit (3 and 4) determine the function of conveying and buffering to a large extent, but like the conveying route for the return transport of the empty holding elements 1 are not within the scope of the invention.

FIGS. 2 and 3 show very schematically, using two examples, how holding element groups 15 are pre-formed at the head end 13 of the buffer store 12, released and transferred to a conveying drive in the method according to the invention. Parts and functions that have already been described in connection with FIG. 1 are identified by the same reference numbers.

FIG. 2 shows a buffer store 12, at the head end 13 of which two stowage means 16.1 and 16.2 are provided, which stowage means alternately define a front stagnation point P.l and a rear stagnation point P.2 (upstream from the front stagnation point P.l). The stowage means 16.1 and 16.2 can be moved parallel to the conveying direction F and can be switched into an active configuration (with an effect on the conveying flow) and an inactive configuration (without an effect on the conveying flow) and they can also assume a conveying function if necessary.

FIG. 2 shows five process stages a) to e) which are followed for the release of a group 15 from the buffer store 12. The holding element group 15 to be released consists of five holding elements 1 in the illustrated case. While the first stowage means 16.1 is active in a front stagnation point P. 1 and thereby stalls the feed and buffer flow, the second stowage means 16.2 is used to prepare the group 15 in a rear stagnation point activated (a, b). As soon as the group 15 is to be released, the first stowage means 16.1 is deactivated (c) and the second stowage means 16.2 is moved in the active configuration to the front stowage point P.1 (d), pushing the group to be released in front of it. At the front stowage point, the second stowage agent then takes over the stowage function, while the released one Group 15 is promoted away from the front stagnation point Pl. The roles of the two stowage means 16.1 and 16.2 are reversed for the formation and discharge of a subsequent group.

Various conveyor drives can be used to carry out the method shown in FIG. 2, the conveyor drive being designed in such a way that it can take over the group 15 pushed out of the buffer by the storage means as such. Suitable drives for feed and buffer conveyor are, for example, gravity or a grinding drive. A further or the same grinding drive or a group conveyor can be used for the conveyance away. When conveying away with a grinding drive, it must be ensured that the speed of the expelling stowage is at least as high as the conveying speed.

In the example shown in FIG. 2, the groups released from the buffer store 12 comprise different numbers of holding elements 1, so that the position of the rear stowage point P.2 and the stroke of the stowage means parallel to the conveying direction differ according to the group size. The groups are released at regular intervals, the distances dG between the last holding elements of successive groups remaining the same. Within the groups, the holding elements are lined up with minimal distances d.

For equal distances dσ between the first holding elements of successive groups, each group would have to be pushed over the front stagnation point P1 by the expelling stowage means (16.1 or 16.2) in such a way that the first holding element of the group reaches a defined starting position, or a pre-formed group would have to do so Dismissal already in a position behind the front stagnation point Pl actively coupled to a removal drive (front stagnation point of the same defined starting point) and released from the buffer store by the action of this drive.

FIG. 3 shows, in the same way as FIG. 2, a method variant with a front stowage means 16.3 and a rear stowage means 16.4, which in turn can be switched into an active configuration and a rest configuration. In contrast to the variant according to FIG. 2, the two stowage means 16.3 and 16.4 do not work alternately in the front or rear stagnation point but are fixedly assigned to the front stagnation point P.l or the rear stagnation point P.2. For the discharge of groups of different sizes, one (16.4) of the accumulation means can be moved parallel to the conveying direction F. The stowage means 16.3 and 16.4 cannot take on a conveying function, so that in any case a drive must be provided over the entire conveying path, the function of which in the feed area and in the buffer store can be taken over by gravity.

The discharge of a group 15 takes place in the following phases: the front stowage agent is active in the front stagnation point P. 1, the rear stowage agent is positioned and activated in order to prepare the group 15 to be released in the rear stowage point P.2 (a, b); for the release of group 15, the front stowage means 16.3 is deactivated and the group is carried away (c); when the group has passed the front stowage point, the front stowage means 16.3 is reactivated, the rear stowage means 16.4 is deactivated and, if necessary, shifted parallel to the conveying direction for the discharge of a next group (d, e).

For the discharge of groups of different sizes, the front stowage means 16.3 can be displaced in the same way instead of the rear stowage means 16.4 parallel to the conveying direction, that is to say the front stagnation point P.1 is variable and the rear stagnation point to be stationary. Both stagnation points P1 and P.2 are stationary for the discharge of the same groups.

Figures 4 to 6 schematically show some exemplary embodiments of the device according to the invention.

FIG. 4 shows an embodiment with two stowage means 16, which work alternately as described in connection with FIG. 2 and assume a promotional function for the discharge of groups. Gravity is used as the feed and buffer drive (rail track falling towards the head end of the buffer store) and the removal drive is a driver chain 30, the drivers of which are spaced apart from one another to match the minimum spacing of the holding elements. The stroke of the stowage means 16 parallel to the conveying direction F is set up in such a way that a group 15 to be released is pushed so far beyond the front stagnation point P. 1 that the last holding element of the group also comes into the effective range of the driving chain 30. The speed of this ejection stroke must be the same as the speed of the drive chain 30.

FIG. 5 shows an embodiment with more than two stowage means 16, which are coupled to a rotating transport element 31 (for example a chain), which are spaced apart from one another by the minimum spacing of the holding elements and which, for example, can be pivoted into an active configuration (filled or shown in black) ) or a rest configuration (empty or shown in white) can be switched. The function of the stowage means 16 is essentially the same as the function of the alternating stowage means 16.1 and 16.2 according to FIG. 2, but for the formation of groups of different sizes, stowage means are not positioned accordingly, but rather a correspondingly selected stowage means is activated (distance between two active stagnation means is equal to the length of a group to be released). With the device according to FIG. 5, it is also possible to have more than two accumulation means in an active state, that is to say, to form more than one group 15 to be released. The transport member 31 is driven in a controlled manner in such a way that it moves in the specified direction for the discharge of a group by the group length and thus releases the group to be discharged and stands still between discharges. The stowage means can be flexibly linked with one another and driven against one another in the area of the buffer store , For a group discharge, the foremost active stowage agent is then deactivated and the second foremost is accelerated in a controlled manner and moved to the front stowage point P1.

FIG. 6 shows an embodiment of the device according to the invention, in which the function of the front stowage means is taken over by gravity, as a result of which a non-stationary front stagnation point Pl (passive stagnation point) can be realized very easily. The rear stowage device is a stationary cycle wheel 16.5. The removal conveyor drive is a group conveyor, for example a driver chain 32, the drivers of which are at a distance from one another which is at least as long as the length of the largest group to be expected. The clock wheel 16.5 forms the groups by rotating intermittently and counting the holding elements 1 necessary for a group to be released. The counted holding elements remain jammed by gravity (passive stagnation point P1) and are conveyed away by the next driver of the driver chain 32. They can also be actively coupled to an appropriately equipped drive. As soon as a counted group has been transported away from the driver assigned to it, the clock wheel 16.5 can start counting the holding elements for the next group. The feed and buffer drive is, for example, a grinding drive. It is also conceivable for the rail track to drop against the clock wheel 16.5 and for the holding elements to be fed to the buffer store by gravity and to be pushed against the clock wheel 16.5. In the embodiment of the device according to the invention according to FIG. 6, instead of the clock wheel 16.5, a single stowage means can also be used, which is controlled in such a way that a group is formed (or counted) between its deactivation and further activation, that is to say via the stationary stagnation point P.2 is promoted. If the distances within such a pre-formed group do not have to correspond very precisely to the minimum distance, instead of gravity, friction can also act as a stowage agent in the variable, passive stagnation point Pl, and friction between the rail track and holding means, for which purpose the rail track can also run downstream from P.1.

FIGS. 7 and 8 show two examples for the application of the method and device according to the invention or for the further processing of group streams created according to the method according to the invention.

FIG. 7 very schematically illustrates a possibly double buffering with group discharge. The system shown is used to produce a predetermined sequence of packages, which all contain different predetermined numbers of types A, B and C printed products (newspapers or magazines). The printed products of types A, B and C are taken individually on different conveying paths, for example driven by gravity, each fed to a buffer store 12.1, 12.2, 12.3, from which buffer stores the printed products in groups according to the inventive method or individually according to the state of the art are released into a central buffer memory 12 such that they are premixed in the central buffer memory 12 for the sequence of packets to be created. At least this buffer store 12 works according to the method according to the invention, that is to say the products which are premixed in the buffer store 12 are pre-formed in the buffer store into groups 15, each representing a packet, released as groups 15 from the buffer store 12 and transferred to a group conveyor 40. For the preparation and dismissal of the Groups are provided, for example, with two alternating stowage means 16.1 and 16.2, as described in connection with FIG. 2. The group conveyor 40 conveys the groups 15 of the products, which are still kept individually, into a packaging machine 41 which, for example, processes the groups supplied by the group conveyor 40 into packages 42, for example by cross-laying and tying or wrapping, in a regular cycle.

A control unit 43 controls the packaging machine 41, synchronizes the group conveyor 40 with the packaging machine 41 and controls the buffer memories 12.1, 12.2, 12.3 and 12 in accordance with a specified package sequence and the specified package contents. A device 44 for printing and placing cover sheets 45 integrated in the packaging machine 41 is also controlled by the control unit 43.

Figure 8 shows double buffering and grouping. This is used to store printed products 2 conveyed by holding elements 1 in a buffer store, to release them in the form of sections 15.1 (groups of products) from the buffer store and to insert a separating sheet 50 between sections 15.1. Sections 15.1 are then jammed again and released in the form of pack stacks 15.2 (group of sections), the pack stacks for example containing different numbers of sections 15.1. These stacks of packages can also be fed to a packaging machine in the manner shown in FIG.

Claims

PATENT CLAIMS

1. A method for conveying and buffering objects (2) with the aid of a plurality of holding elements (1) which can be moved at least to a limited extent independently of one another and one behind the other along a rail track (5), an object (2) with each holding element (1) in a defined

Position held on a conveying path defined by the rail track (5) can be conveyed in a conveying direction (F), the holding elements (1) being accumulated during the conveyance from a stowage point upstream to a buffer store (12) and in a controlled manner downstream from the buffer store (12) are released and conveyed away and the stowed holding elements (1) are at a defined minimum distance (dmin) from one another, characterized in that in the buffer store (12) between a front stagnation point (P.1 and a rear stagnation point (P.2) upstream of the front stagnation point (Pl) holding element groups (15) are pre-formed and that holding element groups (15) are released from the buffer store (12) and conveyed away.

2. The method according to claim 1, characterized in that the holding elements (1) in the released and removed holding element groups (15) have the said minimum distance (d _M i _n ) from each other.

3. The method according to claim 1 or 2, characterized in that successively formed in the buffer (12) and released from the buffer (12) and transported away holding element groups (15) comprise a different number of holding elements (1) and that the distance between the front and rear stagnation point (Pl and P.2) corresponds to the extent of a group (15) to be discharged in the conveying direction (F), one of the stagnation points (Pl or P.2) is stationary for the preparation and discharge of all groups and the other stagnation point (P.2 or Pl) is shifted parallel to the conveying direction (F).

4. The method according to any one of claims 1 to 3, characterized in that the holding element groups (15) with the aid of stowage means (16, 16.1, 16.2, 16.3, 16.4, 16.5) are pre-formed and released from the buffer store (12), whereby a stowage agent acts at the front and at the rear stowage point (P.1 and P.2).

5. The method according to claim 4, characterized in that at least one of the storage means (16.1, 16.2, 16.4) is moved between successive discharges parallel to the conveying direction (F).

6. The method according to any one of claims 4 or 5, characterized in that groups (15) are pushed out of the buffer store (12) by stowage means (16.2).

7. The method according to claim 5 or 6, characterized in that the stowage means (16.1, 16.2) are used alternately at both stowage points (P.l and P.2).

8. The method according to claim 5 or 6, characterized in that more than two stowage means (16) are used and that more than one rear stowage point (P.2) is formed.

, A method according to claim 8, characterized in that the more than two stowage means (16) are coupled to a rotating transport member (31) and can be activated optionally.

10. The method according to claim 4, characterized in that at least one of the stagnation points (P.1 and P.2) is assigned a stowage means (16.3, 16.4, 16.5).

11. The method according to claim 10, characterized in that the rear stagnation point (P.2) is stationary and it is assigned a stowage means by which the groups (15) are formed, and that the front stagnation point (Pl) is a passive stagnation point , in which the holding elements of the preformed group are stowed by gravity, by friction or by the momentary absence of a force that transports them away.

12. The method according to claim 11, characterized in that the rear stagnation point (P.2) is assigned a clock wheel (16.5) as a stowage means.

13. The method according to any one of claims 1 to 12, characterized in that the holding elements (1) for the supply to the buffer store (12) for

Funding through the buffer store (12) to the front stagnation point (P. l) and for the conveyance away from the front stagnation point (P. l) are coupled to a single drive, with the stuck holding elements sliding relative to the drive or being decoupled from it.

14. The method according to any one of claims 1 to 12, characterized in that the holding elements (1) for the supply to the buffer memory (12) and / or for the promotion through the buffer (12) to the front stagnation point (Pl) or to the rear stagnation point (P.2) are driven by gravity.

15. Device for conveying and buffering objects (2), which device has a plurality of holding elements (1) and a rail track (5), the holding elements (1) being independent of one another at least to a limited extent and in succession in a conveying direction (F) along the Rail track (5) can be moved and each holding element (1) is equipped for holding an object (2) in a defined position, and which device is also used to form a buffer store (12) by stowing the holding elements (1) at a stagnation point Optionally stowing or releasing holding means (1) and at least one drive for conveying the holding means (1) against the stagnation point and away from the stagnation point, the holding elements (1) being equipped in such a way that they have defined minimum distances (d in) in the stowed state. have each other, characterized in that the device has means with which the

Holding elements are stowable in a front stagnation point (P.1) and a rear stagnation point (P.2) positioned upstream from the front stagnation point (Pl), at least one of the stagnation points being stationary and at least one stowage means being provided in this The stagnation point acts and the removal drive is equipped to remove holding element groups (15).

16. The apparatus according to claim 15, characterized in that at least one stowage means (16, 16.1, 16.2, 16.3 16.4) is provided for each of the two stagnation points (P1 and P.2) and that at least one of the stowage means is displaceable parallel to the conveying direction.

17. The apparatus according to claim 16, characterized in that a plurality of selectively activatable stowage means (16) are coupled to a rotating transport member (31).

18. The apparatus according to claim 15, characterized in that the rear stagnation point (P.2) is stationary and that for stowage in the front stagnation point

(P.l) the rail track and the removal drive is designed such that a group pre-formed between the two stowage points is optionally by

Non-removal is stowed or removed.

19. The apparatus according to claim 18, characterized in that the rail track rises from the rear to the front stagnation point, so that gravity acts as a stagnant force for the front stagnation point (P.1).

20. The apparatus according to claim 18 or 19, characterized in that the rear stowage point (P.2) associated stowage means is a clock wheel (16.5).

21. Device according to one of claims 15 to 20, characterized in that it has at least in the region of the buffer store (12) a drive which grinds relative to jammed holding elements (1).

22. The method according to claim 21, characterized in that a drive is provided along the entire rail track (5) or along parts of the rail track, to which the holding elements (1) can be magnetically coupled.

23. The device according to any one of claims 15 to 22, characterized in that the rail track (5) at least upstream from the front stagnation point (P.l) is falling in the conveying direction (F) and gravity acts as a drive in this area of the rail track (5).

24. Use of the method according to one of claims 1 to 14 or the device according to one of claims 15 to 23 for the creation of groups of individually held printed products.