The invention relates to a method for the automatic joint packaging of at least a first and a second part in a packaging, whereby the two parts have different sizes and geometries.
In a known method of this kind, a first part and a second part are placed in pairs side by side on a transport device designed as a conveyor belt and transported to a tubular bag packaging machine. The first part is, for example, a plastic bottle, for example a medical infusion bottle, and the second part is an adapter welded in a blister for later attaching or screwing onto the bottle. The disadvantage here is that the bottle and the blister can easily slip inside the tubular bag and therefore the automatic handling of the individual tubular bags including their contents by means of a robot during the subsequent collective packaging of the tubular bags into cartons or similar is difficult.
It is the task of the present invention to optimize the packaging of at least a first and a second part in a common packaging.
This task is solved by a method having the features set forth herein. Additional objects and advantages of the invention will be set forth in part in the following description, or may be obvious from the description, or may be learned through practice of the invention.
The invention relates to a method including both the first and the second parts being automatically fed to the transport device by a first or second feeding device, respectively. The first parts are automatically placed on the transport surface in such a way that they are aligned in a defined manner in the transport direction, with a front side of the first parts facing in the transport direction and a rear side facing against the transport direction. Furthermore, the second parts are automatically placed on the transport surface, each in front of a first part, seen in the transport direction. The first and second parts are then conveyed together in pairs on the transport device to a packaging device. The pushing device, which is part of the transport device, grips the rear side of the respective first part and pushes it in the transport direction. The first part, on the other hand, takes a second part at its front side.
The advantages of the invention lie in particular in the fact that only the first part is pushed directly by a pushing device, taking the second part with it on its front side. “Front side” means the front area of the first part (not only its front face). The two parts to be packed together are therefore not next to each other on the transport device, but essentially in one line, preferably behind and/or above each other. During this transport, the respective geometries of the first and the second part are especially preferable taken into account, or even matched to each other, so that the two parts have an essentially defined position during transport. In this relative position to each other, the two parts are then packed together, whereby this relative position can be maintained if the packaging is tight-fitting. In this way, slippage of the second part relative to the first part in the packaging can be prevented.
Lateral guides along the transport surface can also be provided as an option in order to prevent second parts from slipping past the respective first parts in case of an imprecise relative position assignment between first and second part.
It is particularly preferred that each first part has a driver area in the area of its front side, which is preferably curved. This driver area is aligned in the direction of transport and takes the second parts with it. It is preferred if the driver area at least partially covers the second part in top view of the transport device. In other words, the second part is taken along by the first part on a lower side of the first part. This effectively prevents the second part from slipping sideways during pushing transport by the first part.
Every second part preferably has an entrainment area that is placed on the transport device in front of the driver area of the first part. When transporting together, the entrainment area of the second part is located at the driver area of the first part, preferably partly covered by the first part in top view, so that the first part can push the second part in front of it in a defined position with its driver area.
In this respect, it is advantageous if the driver area of the first part is an inward or outward projection and the entrainment area of the second part is an outward or inward projection. In this case, the outward or inward projection of the second part can be located at the inward or outward projection of the first part. In this case no exact form fit between the first and the second part is necessary. Preferably, it is sufficient if the second part cannot slip past the first part against the transport direction.
According to a particularly preferred design, the first part is a bottle whose driver area is the bottle neck. This bottle neck is aligned especially preferable on the transport surface in transport direction. The second part, according to this particularly preferred design, is a blister that is placed on the transport surface and, at the latest when the first part is pushed forward, at least partially reaches under the bottle neck of the first part and is carried along by it. The belly of the bottle has no direct contact with the blister. The blister preferably contains a bottle top for the bottle. Preferably, the blister has a defined area as the entrainment area, whereby the blister is then placed on the transport device in such a way that this entrainment area is aligned in the direction towards the bottle neck.
Preferably, the pushing device comprises plates or fingers spaced in the transport direction, each of which engages on the rear of a first part and pushes the corresponding first part together with the second part in the transport direction. Such pushing devices are known in principle. One finger each grips the rear side of a first part.
Preferably, a first robot places the first part and/or a second robot places the second part on the transport surface. Robots are predestined for this work because they work quickly and precisely and can also pick up the first or second part and align it as desired before depositing it on the transport device. Advantageous robots are, for example, designed as delta pickers with an additional fourth axis.
Preferably, the respective position of the first and/or second parts on the first or second feeding device is detected by preferably one detection device each. Based on the detected signal, the respective robot, as the first and/or the second robot, is then activated to place the first part or the second part with a defined orientation on the transport surface. In this way, randomly delivered first and/or second parts with a defined orientation can be placed on the transport surface.
According to an advantageous respective design, the second parts each have an identification mark, e.g. a barcode, at the same position. This identification mark is read by a detection device before the respective second part is placed on the transport device. The signal is processed by a control device to control the second robot, which then places the second part on the transport device with a defined orientation with respect to the placement of the identification mark. If, for example, in the above-mentioned example, an identification mark is placed on the top of the blister, the second robot can rotate the blister and place it on the conveyor in front of the first part such that the designated entrainment area always faces the driver area of the first part.
The first and/or the second parts are transported to the transport device by means of feeding devices, whereby the first and/or the second parts are preferably located on these feeding devices without a respective defined orientation. The feeding devices are designed as conventional conveyor belts, for example. The first and/or second parts can therefore be delivered non-ordered, for example by automatic or manual removal from a bulk packaging. The transfer of the first and/or second parts from the feeder(s) is then preferably done by one or more robots, preferably by a first robot for the first parts and a second robot for the second parts.
A preferred embodiment provides for a first part to be conveyed a defined distance by the pushing device before entraining a second part with its front side. The two parts can thus be placed on the transport surface with a mutual distance between them before the first part is conveyed by the pusher to the nearest second part and then pushes the second part in front of it, preferably by contacting its said driver area with the said entrainment area of the second part.
According to an alternative, a first part and a second part to be pushed by this first part are both already placed on the transport device in such a way that they lie against each other and are then immediately pushed together in the transport direction by the pushing device.
A tubular bag packaging machine (also called flow pack machine or flow wrap machine) is particularly preferred as the packaging device. The two parts conveyed on the transport surface in accordance with the invention can then be packed adjacent to each other and in the defined relative position in which they were already conveyed on the transport surface. The two parts thus remain in their respective positions in the tubular bag and can be easily grasped by a machine and without any troubles during further handling, especially when they are placed in larger packaging containers.
Advantageous further embodiments are characterized by the features of the subclaims. In the following, the invention is explained in more detail by means of figures. These show:
Reference will now be made to embodiments of the invention, one or more examples of which are shown in the drawings. Each embodiment is provided by way of explanation of the invention, and not as a limitation of the invention. For example, features illustrated or described as part of one embodiment can be combined with another embodiment to yield still another embodiment. It is intended that the present invention include these and other modifications and variations to the embodiments described herein.
In the left half of
In the right half of
In order to realize a defined entrainment of the second part 20 by the first part 10, the first part has a driver area 13 in the area of its front side 11. This driver area 13, which in the case of the bottle shown in the figures is formed by its bottle neck 15, has a section 13a which is spaced from the transport surface 2. The second part 20 gets between this section 13a and the transport surface 2 when the first part 10 reaches the second part 20 by the pushing action of the pushing device 3. Then, the first and the second part 10, 20 are pushed together over the transport surface 2.
Every second part 20 has an entrainment area 23. In the embodiment shown in the figures, this results from the essentially rectangular or oval geometry of the second part 20 with two broad sides and two narrow sides. A safe contact of the second part 20 with the first part 10 is achieved if the second part 20 lies with one of its broad sides against the driver area 13, in this case in the area of the bottle neck 15, i.e. between bottle neck 15 and transport surface 2. The area of this broad side of the second part 20 serves as said entrainment area 23.
If the second part 20 is a blister with a bottle adapter for the first part 10 inserted therein, the first part 10 being embodied as a bottle, the irregular shape of this adapter determines the entrainment area 23 of the second part 20. The adapter has, for example, a broad side, whereby the second part 20 is then placed on the transport surface 2 with the broad side of the adapter being aligned in the direction of the first part 10.
Furthermore, a second feeding device 7 is provided, on which second parts 20 are fed in feeding direction Z2 perpendicular to the transport direction T according to the present example. If a second part 20 enters the working area of a second robot 8 (also symbolized by a dotted circle), this robot grips this second part 20 and deposits it on the transport surface 2 in front of a first part 10. A first and a second part 10, 20 are placed between two fingers 4 of the pushing device 3.
The first parts 10 are already delivered in an order on the first feeder 5, for example standing upright. Alternatively, the first parts 10 are disordered on the feeder 5. Each first part 10 is gripped by the first robot 6 and placed on the transport surface 2 with a defined orientation. For the first parts 10, which are in the form of bottles, the bottle neck is placed on the transport surface 2 in transport direction T.
The second parts 20 are also placed on the transport surface 2 with a defined orientation. Their infeed on the feeding device 7 is disordered. A detection device 9, e.g. a camera or other optical device, is located near the transport device 1, which detects the position of every second part 20. In this case, every second part 20 has an identification mark 24, for example in the form of a bar code, on its upper side. The detection device 9 detects the rotational position of the second parts 20 around their respective vertical axis on the basis of the position of this identification mark 24 and transmits corresponding signals to a (not shown) control device, which in turn controls the second robot 8 and commands it to deposit the second part 20, which has been detected by the detection device 9, in a defined orientation on the transport surface 2. In this case, the second part 20 is deposited with a broad side in front of the first part 10. This broadside serves as the entrainment area 23 and is captured by the driver area 13 of the first part 10 so that the second part 20 can be pushed safely by the first part 10.
The pairs of first and second parts 10, 20 conveyed one after the other on the transport surface in transport direction T are conveyed into a known packaging device 29, which is designed as a tubular bag packaging machine and seals a first and a second part 10, 20 into a packaging 30, here a tubular bag. The packaging 30 can be tightly fitted to the two parts 10, 20, especially with respect to the two long sides facing in transport direction T. In this way, the two parts 10, 20 cannot slip relative to each other in transport direction T, so that especially a subsequent collective gripping of the packed first and second parts 10, 20 for packing into larger containers is possible without any problems.
The equipment of the packaging machine, including the transport device 1, the feeding devices 5, 7, the robots 6, 8, the recognition device 9 and the packaging device 29 are preferably controlled by a (not shown) control device.
The present invention was explained in more detail by means of an exemplary embodiment, but is not limited to this exemplary embodiment. Variations within the claims are possible without further ado. For example, the first and the second feeding device can also be aligned and/or designed differently in order to deliver the first and second parts, respectively. For example, the feeding directions Z1 and Z2 are arranged in opposite directions or at different angles to each other.
1 Transport device
2 Transport surface
3 Pushing device
4 Fingers
5 First feeding device
6 First robot
7 Second feeding device
8 Second robot
9 Detection device
10 First part
11 Front side of the first part
12 Rear side of the first part
13 Driver area
13
a Section
14 Support section
15 Bottle neck
20 Second part
23 Entrainment area
24 Identification mark
29 Packaging device
30 Packaging
T Transport direction
Z1 Feed direction
Z2 Feed direction
Number | Date | Country | Kind |
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10 2018 111 666.7 | May 2018 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2019/062470 | 5/15/2019 | WO | 00 |