Patent Grant
6901726
The invention relates to a method and an apparatus for putting piece goods into containers.
A generic method is disclosed by EP-A-0 856 465. Here, piece goods and containers are guided along a picking line in countercurrent. In this case, the relative speed of the piece goods supplied to the containers supplied is controlled by the controller of the last picker, in the conveying direction of the containers, in such a way that only completely filled containers leave the working area of this last picker. This method has the disadvantage that the piece goods and containers have to be supplied in countercurrent. However, since packaging systems have to be integrated into the overall production circuit, this very severely restricts the physical configuration of the system.
In addition, EP-A-0 749 902 discloses a method of putting piece goods into containers in which the piece goods and containers are transported in cocurrent along a picking line. Here, the piece goods supplied are counted by a counting device. The empty containers are backed up upstream of the picking line. Only when a number of pieces sufficient to fill a container has been reached is in each case an empty container released into the working area of the pickers.
A further apparatus for putting piece goods into containers by means of pickers, delta robots here, is described in EP-A-1 160 166. Here, too, the attitude and position are registered by means of an optical registration station, notified to the controller of the individual pickers, and the piece goods are put into the containers individually by means of the gripping apparatus of the pickers.
These known systems have the disadvantage that they relatively quickly reach limits with regard to their achievable packaging performance.
It is therefore an object of the invention to provide a method and an apparatus for putting piece goods into containers which permit an increase in the packaging performance.
This object is achieved by a method and an apparatus having the features of patent claim 1 and, respectively, 10.
According to the invention, a storage element is used and the relative speed between a container conveyor and a piece goods conveyor is controlled as a function of this storage element.
In a simple variant of the method, the relative speed remains constant until a maximum storage capacity has been reached. In a preferred variant of the method, the relative speed is adapted even before this capacity is reached. The speed of the supply of the containers into the area of the picking line or the individual pickers is preferably controlled. In another variant, only the speed of supply of the piece goods into the aforementioned area is controlled, or both speeds are controlled.
In one embodiment, the storage element is used for storing piece goods, in other embodiments it is used for storing containers.
The storage element is preferably arranged upstream of a last picker in the conveying direction of the containers. The speed of a conveying section of the container conveyor in the area of this last picker is controlled as a function of the capacity of this last picker in preferred embodiments. However, it is also possible not to control the speed in this area and to operate the conveying section at constant speed.
With the method and the apparatus according to the invention, with a relatively high packaging performance, it is possible to achieve the situation where the containers are always completely filled. In addition, it is possible for all the piece goods always to be packed.
Further advantageous variants of the method and advantageous embodiments emerge from the dependent patent claims.
In the following text, the subject of the invention will be explained by using preferred exemplary embodiments, which are illustrated in the appended drawing, in which:
The general fundamentals of the apparatus according to the invention will be described by using the first embodiment illustrated in FIG. 1. The apparatus has a first feed conveyor 1 for feeding piece goods S. The feed conveyor 1 is preferably a conveyor belt. However, other conveyor types are also possible. The piece goods S are generally supplied in a disordered formation on the first feed conveyor 1. In this case, there is usually at least one optical registration station, not illustrated here, to detect the attitude and/or orientation of the individual piece goods S, as is known from the prior art. If they are supplied in an ordered fashion, the optical registration station is rendered superfluous or is used merely for quality control.
In addition, there is at least a second feed conveyor 2 for feeding containers B. Illustrated here are two feed conveyors 2, which in each case extend along one side of the first feed conveyor 1 and extend at least approximately parallel to the latter. However, it is also possible for them to be at an angle thereto. The second feed conveyors can likewise be belt conveyors or other known types of conveyors, depending on the type of containers. In the example illustrated here, the conveying directions of the first and second feed conveyors may be represented by antiparallel vectors, which means that the piece goods S and containers B are transported in countercurrent. The conveying directions are in each case identified by large arrows in the figures.
The apparatus also has a picking line with a plurality of pickers PN, PN-1. Only four pickers are illustrated here, in each case two placing the piece goods S into the container B belonging to a second feed conveyor 2. However, a plurality of pickers are normally arranged one after another in the conveying direction. The pickers PN, PN-1 have gripping means for grasping the piece goods S from the first feed conveyor 1 and depositing the piece goods S in the containers B. Depending on the transfer desired, the piece goods S are grasped individually or in groups and transferred into the containers B. These pickers are known from the prior art. What are known as delta robots, for example, are suitable.
According to the invention, the apparatus additionally comprises a storage element which temporarily stores containers B which have not yet been filled completely and/or piece goods S. In the example illustrated here, this storage element is used for the temporary storage in the picking line of containers B which cannot yet be filled completely. For this purpose, the second feed conveyor 2 is subdivided into at least two conveying sections 20, 21. Two different conveying sections 20, 21 are preferably assigned at least to the last and penultimate pickers PN, PN-1 in the conveying direction of the containers B. In each case, a storage element in the form of a separately driven intermediate conveyor 3 is arranged between these conveying sections 20, 21. This intermediate conveyor 3 preferably forms an extension to the conveying sections, so that the containers B can be backed up therein until the last picker PN has sufficient capacity to completely fill the containers B arriving on the second conveying section 21. The intermediate conveyor 3 can be of the same conveyor type as the second conveyor 2, the containers B being held back and therefore backed up on the intermediate conveyor 3 by retaining means. In one variant, what is known as a yoyo store is used. However, it is also possible to use a transport system for the second feed conveyor 2 and also for the intermediate conveyor 3 in which each container B is provided with its own motor and can therefore be controlled individually. This enables movement and storage in the transport system without contact and without static pressure.
Within the storage element, here the intermediate conveyor 3, the number of containers B is detected and monitored by means of position sensors and/or distance measuring means. These sensors and means are known and will therefore not be described in detail.
The relative speed between the first and the second feed conveyor 1, 2, in this case between the first feed conveyor 1 and the first conveying section 20, is controlled as a function of the storage element, according to the invention. A control unit 5 present for this purpose is illustrated merely schematically in FIG. 1. Control units for conveyor speeds are known per se and will therefore not be described in detail. The relative speed is preferably controlled even before the maximum capacity of the storage element has been reached. The speed of the second conveying section 21 is preferably controlled as a function of the last picker PN. In this way, it is additionally possible to ensure not only that all the containers B are completely filled but that also at least approximately all the piece goods S are deposited in containers B. In one preferred embodiment, the control unit 5 also receives signals from at least one picker, preferably the last picker, which are taken into account in the control.
A second embodiment is illustrated in FIG. 2. It has substantially the same features as the embodiment according to FIG. 1. However, here the conveying directions of the first and of the at least one second feed conveyor 1, 2 run parallel to one another, that is to say in cocurrent.
Further embodiments are illustrated in
In the embodiment according to
A fifth embodiment is illustrated in FIG. 5. Here, not only the containers B but also the piece goods S are temporarily stored. In this embodiment, the first and the at least one second feed conveyor 1, 2 now run parallel to each other, the piece goods S and containers B being transported in cocurrent. At the end of the first feed conveyor 1 that is arranged downstream, there is a storage element in the form of a piece goods storage conveyor 4. This runs at least approximately parallel to the conveying direction of the piece goods S and thus forms the extension to the first feed conveyor 1. It preferably comprises the same conveyor type as the first feed conveyor 1, for example it is a conveyor belt. However, it is driven separately. Its drive is preferably reversible in this case, so that the piece goods S remain as far as possible in the working area of the last picker PN. In the event of a lack of piece goods S on the first feed conveyor 1, the temporarily stored piece goods S are taken by the last picker PN in order to fill the containers B completely. Here, too, the relative speed of the two feed conveyors is again controlled as a function of the storage capacity.
Combinations of the aforementioned embodiments are possible. For example, both piece goods S and containers B can be temporarily stored in the same system. It is also possible to arrange storage elements along the picking line and not just in the area of the last picker.
The apparatus according to the invention permits efficient transfer of piece goods into containers with the most complete filling possible of the containers, specifically independently of the manner of the relative transport direction of the piece goods and containers in relation to one another. Said apparatus may be integrated in particular into cocurrent and countercurrent systems.
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|---|---|---|---|
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| 5477663 | Smith et al. | Dec 1995 | A |
| 5501064 | Ingram et al. | Mar 1996 | A |
| 5771657 | Lasher et al. | Jun 1998 | A |
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| 20030150193 | Gasser et al. | Aug 2003 | A1 |
| Number | Date | Country |
|---|---|---|
| 298 17 239 | Sep 1998 | DE |
| 0 856 465 | Jan 1997 | EP |
| 2 754 239 | Oct 1996 | FR |
| Number | Date | Country | |
|---|---|---|---|
| 20030182898 A1 | Oct 2003 | US |
