EP3181311A1 - Device for separating out parts from a material sheet - Google Patents

Abstract

A device (10) for extracting partial regions (12) from a material web (14) has a vacuum cutting cylinder (20) and a counter-cylinder (30) for cutting the partial regions (12). In addition, a vacuum transfer roller (50) for removing the portions (12) from the vacuum cutting cylinder (20) is present. Subsequently, the partial areas (12) of the vacuum transfer roller (50) on a conveyor belt (70) are stored. The vacuum cutting cylinder (20) and the vacuum transfer roller (50) can preferably be rotatably driven by means of two separate motor drives, so that the rotational speed of the vacuum transfer roller (50) can be set greater than the rotational speed of the vacuum cutting cylinder (20).

Description

TECHNICAL AREA

The present invention relates to a device for extracting portions of a material web. The material web can be a single-layer or a multi-layer material and be present, for example, wound up on a reel body. From this reel body, the web can be deducted and processed in a timed or continuously running work process. Such web-processing processes are used, for example, in the production of wound plasters or other therapeutic plasters. It may be necessary to detach portions of the web to place these portions on other webs.

STATE OF THE ART

It is known to punch out parts of a material web. Depending on the type and thickness of the material web to be cut as well as the size and length of the punching line very high punching forces may be required. The corresponding punching devices must then be dimensioned correspondingly strong. The heavier the punching devices become, the less suitable they are to be moved during the punching process with the material web moving in the transport direction. Punching devices are therefore mainly suitable for stationary punching operations.

From the DE 299 11 914 U1 a device for extracting portions is known in which a cutting edge is pulled in a pulling section through the web. Furthermore From this document, a device is known in which a cutting edge is pressed in a rolling movement through the material web. The required forces that must be applied by the device are relatively small in this case, so that the corresponding devices can be made comparatively slim and light and thus can be moved during the separation process with the moving in the transport direction web. However, only relatively large partial areas can be separated out of the material web with both devices.

PRESENTATION OF THE INVENTION

Based on this prior art, the present invention seeks to provide an improved device for extracting portions of a material web, which is also suitable for very small portions and allows continuous processing.

The device according to the invention is given by the features of the main claim 1. Useful developments of the invention are the subject of further claims that follow this claim.

The device according to the invention for extracting partial regions from a material web has a vacuum cutting cylinder and a counter-cylinder, by means of which the partial regions are cut. In addition, a vacuum transfer roller is present, by means of which the cut portions can be removed from the vacuum cutting cylinder. From the vacuum transfer roller, the cut portions are then placed on a conveyor belt, so that the sections can be further processed.

The combination of the three rollers - vacuum cutting cylinder, counter cylinder and vacuum transfer roller - makes it possible, even small product sizes of only about ten to ten millimeters or Cut out even smaller from the material web. The subregions can be used, for example, as a drug reservoir in transdermal therapeutic systems. Such patches are getting smaller, so that always small portions of the web must be cut out.

Particularly in the case of adhesive-containing material webs, the transfer of the cut portions from the vacuum cutting cylinder directly to a conveyor belt is a critical step, since this removal is often difficult and leads to increased rejects. Thus, the cut portions may remain stuck in the vacuum cutting cylinder, which can complicate the transfer to the conveyor belt. The use of the vacuum transfer roller, however, allows a clean and accurate removal of the cut products from the vacuum cutting cylinder and an exact storage of the cut products on the conveyor belt.

Especially in the production of transdermal therapeutic systems, the material web containing the drug is so valuable that as little waste and waste as possible when cutting the required areas should arise. Therefore, as little space as possible should be present between the subregions necessary for further processing. The subregions therefore, in the direction of travel of the material web, generally adjoin one another directly and are only separated from each other by the cutting line. However, in particular with the use of adhesive-containing material webs, a so-called cold flow of the adhesive material may occur. Due to the cold flow, the adhesive material flows slightly outward, so that the adjacent subregions stick together again when they are no longer separated by the cutting edges of the vacuum cutting cylinder. In an advantageous embodiment of the device according to the invention, therefore, the rotational speed of the vacuum transfer roller may be slightly larger than the rotational speed of the vacuum cutting cylinder. As a result, the cut portions are slightly in the direction of travel Spread apart, so that a bonding of the sections by cold flow is no longer possible. The slightly greater rotational speed of the vacuum transfer roller can preferably be effected by a separate motor drive of the vacuum transfer roller.

The transfer of the cut portions of the vacuum cutting cylinder to the vacuum transfer roller can be done by differently set negative pressures of the two rolls. Thus, it may be sufficient if the vacuum transfer roller identifies a greater negative pressure than the vacuum cutting cylinder in order to ensure exact removal of the sections from the vacuum cutting cylinder. In particular, with adhesive-containing material webs, however, it may be advantageous to connect the vacuum cutting cylinder to a compressed air channel, so that the transfer of the cut portions can be facilitated and accelerated by one or more blasts of compressed air.

In order to enable a continuous production process with the greatest possible web speed, a fixed hollow cylinder may be present below the lateral surface of the vacuum cutting cylinder, which has at least two chambers in cross-section. One of the two chambers may be connected to a vacuum pump, while the other of the two chambers may be connected to a compressed air channel. In this way, the vacuum cutting cylinder in the area of the counter-cylinder permanently and reliably have a constant negative pressure, so that an exact cutting result can be achieved. In the area of the vacuum transfer roller, on the other hand, normal pressure or even a slight overpressure may be present, so that a simple and safe removal of the cut products from the vacuum cutting cylinder is possible.

The transfer of the cut portions of the vacuum transfer roller on the conveyor belt may preferably by a blast of compressed air respectively. For this purpose, the vacuum transfer roller may be connected to a compressed air channel, so that in the transfer region between the vacuum transfer roller and conveyor belt no negative pressure prevails on the vacuum transfer roller. For this purpose, in the case of the vacuum transfer roller, in an advantageous embodiment, below the lateral surface, a stationary hollow cylinder may be present, which has at least two chambers in cross-section. One of the two chambers may be connected to a vacuum pump, while the other of the two chambers may be connected to a compressed air channel. In this way, the vacuum transfer roller in the region of the vacuum cutting cylinder can permanently and reliably have a constant negative pressure, so that a reproducible and safe removal of the cut portions from the vacuum cutting cylinder is possible. In the area of the conveyor belt, however, normal pressure or even a slight overpressure may be present, so that a simple and safe transfer of the cut products to the conveyor belt is possible.

In an advantageous embodiment, the conveyor belt may be formed as a vacuum conveyor belt. This allows a safe transport of the cut products. Especially with products made of adhesive-containing material webs, a slipping of the cut products on the conveyor belt could lead to subsequent sticking of the cut products, so that they can no longer be processed and disposed of as scrap. This slippage can be prevented by the use of a vacuum conveyor belt.

In a particularly preferred embodiment, the transport speed of the conveyor belt may be slightly greater than the rotational speed of the vacuum transfer roller. As a result, the cut portions are further spread apart in the transport direction, so that the risk of sticking of the portions by cold flow of the adhesive material can be further reduced.

Further advantages and features of the invention are given in the claims further specified features and the following embodiment.

BRIEF DESCRIPTION OF THE DRAWING

Fig. 1

eine perspektivische Ansicht der erfindungsgemäßen Vorrichtung zum Herauslösen von Teilbereichen aus einer Materialbahn und

Fig. 2

eine perspektivische Seitenansicht der erfindungsgemäßen Vorrichtung gemäß Fig. 1.

The invention will be described and explained in more detail below with reference to the embodiment shown in the drawing. Show it:

Fig. 1

a perspective view of the device according to the invention for extracting portions of a material web and

Fig. 2

a perspective side view of the device according to the invention according to Fig. 1 ,

WAYS FOR CARRYING OUT THE INVENTION

The inventive device 10 for extracting portions 12 of a material web 14 is in the Fig. 1 and 2 shown in perspective. The device 10 has a vacuum cutting cylinder 20, which is rotatably mounted and is moved by a motor drive, not shown here. The lateral surface 22 of the vacuum cutting cylinder 20 has a plurality of cut edges 24 which form a plurality of identical depressions 26. The outer shape of the recesses 26 corresponds to the shape of the sections to be cut 12. In each recess 26 a plurality of apertures 28 are present. The openings 28 are - depending on the rotational position of the vacuum cutting cylinder 20 - connected to a compressed air channel or connected to a vacuum line.

The vacuum cutting cylinder 20 cooperates with a counter-cylinder 30. The material web 14 is fed via not shown transport rollers of the device 10 and passes in the transport direction 40 between the vacuum cutting cylinder 20 and the counter cylinder 30. In the present example, the direction of rotation 42 of the counter-cylinder 30 extends in the clockwise direction, while the rotational direction 44 of the vacuum cutting cylinder 20 runs counterclockwise. When passing the material web 14 between the counter-cylinder 30 and the vacuum cutting cylinder 20, the individual portions 12 are cut out of the material web 14. The partial regions 12 are first transported further in the depressions 26 of the vacuum cutting cylinder 20 until they are transferred to the vacuum transfer roller 50.

The vacuum transfer roller 50 has in its otherwise smooth lateral surface 52 a plurality of apertures 54 which can be acted upon by compressed air or negative pressure. The vacuum transfer roller 50 is mounted rotatably and is rotatably driven by its own motor drive. The direction of rotation 56 of the vacuum transfer roller 50 runs in the present example in the clockwise direction. The rotational speed of the vacuum transfer roller 50 can be selected independently of the rotational speed of the vacuum cutting cylinder 20 due to the separate motor drive. In the present example case, the rotational speed of the vacuum transfer roller 50 is slightly greater than the rotational speed of the vacuum cutting cylinder 20. This makes it possible to separate the cut portions 12 when passing to the vacuum transfer roller 50 in the transport direction by a certain amount 58 from each other and thus aufzuspreizen. Two adjacent in the transport direction portions 12 are thus no longer directly behind each other on the vacuum transfer roller, but between them a small distance (amount 58) is present. This small distance reduces the risk that the subregions 12 stick together again due to cold flow of the adhesive present in the material web 14 and can no longer be separated from each other cleanly later.

It is therefore not necessary, between two seen in the transport direction 40 of the web 14 successive portions 12 already provided when cutting with the vacuum cutting cylinder 20 a distance, as this can be subsequently generated by the transfer to the vacuum transfer roller 50. This reduces the unusable remainder of the material web 14, so that it consists of only three narrow strips 60, 62, 64.

The two edge strips 60, 64 are required in order to cut slightly rounded portions 12 at the corners can. If it is possible to dispense with the rounding of the corner regions, no edge strips 60, 64 would be required. The middle strip 62 is required in the present example, to be able to ensure a certain distance between two in the longitudinal direction of the vacuum cutting cylinder 20 adjacent portions 12, so that they can not stick together again by cold flow. Depending on the width of the material web 14 and the product size of the partial regions 12, more or fewer central strips 62 may also result.

Depending on the material of the material web 14, it may be sufficient if the negative pressure of the vacuum transfer roller 50 is greater than the negative pressure of the vacuum cutting cylinder 20. Should This pressure difference may not be sufficient, the vacuum of the vacuum cutting cylinder 20 can be lifted in the transfer area between the vacuum transfer roller 50 and vacuum cutting cylinder 20. Optionally, a blast of compressed air could take place to eject the cut portions 12 from the recesses 26 and quickly and accurately passed to the vacuum transfer roller 50.

From the vacuum transfer roller 50, the cut portions 12 are transferred to a vacuum conveyor belt 70. The transport speed As a result, the distance 72 between two successive partial regions 12 on the vacuum conveyor belt 70 is slightly greater than the distance 58 between two partial regions 12 on the vacuum transfer roller 50 Reduce sticking by cold flow.

The vacuum conveyor belt 70 can then transfer the cut sections 12 to further web-processing stations in order to further process the sections 12, for example, into transdermal therapeutic plasters. Due to the low waste produced, the device 10 is particularly suitable when the material web 14 contains the therapeutic agent, since such material webs are correspondingly expensive and should be used optimally.

Depending on the size and shape of the desired partial regions 12, different vacuum cutting cylinders 20 can be inserted into the device 10 according to the invention. The storage of the vacuum cutting cylinder 20 can be selected so that even vacuum cutting cylinders 20 of different diameters can be used without major problems in the device 10, so that a rapid format change of the device 10 is possible.

Claims (9)

Device (10) for extracting partial regions (12) from a material web (14) - With a vacuum cutting cylinder (20) and a counter-cylinder (30) for cutting the portions (12) - With a vacuum transfer roller (50) for removing the portions (12) from the vacuum cutting cylinder (20), - With a conveyor belt (70) on which the portions (12) of the vacuum transfer roller (50) can be stored. Device according to claim 1, - characterized in that - The rotational speed of the vacuum transfer roller (50) is greater than the rotational speed of the vacuum cutting cylinder (20). Device according to claim 2, - characterized in that a first motor drive is provided, by means of which the vacuum cutting cylinder (20) is rotatably drivable, - A second motor drive is present, by means of which the vacuum transfer roller (50) is rotatably driven. Device according to one of the preceding claims, - characterized in that - The vacuum cutting cylinder (20) is connected to a compressed air channel. Device according to claim 4, - characterized in that - Below the lateral surface (22) of the vacuum cutting cylinder (20) has a fixed hollow cylinder is present, the fixed hollow cylinder has at least two chambers in cross-section, - One of the at least two chambers is connected to a vacuum pump, - The other of the at least two chambers is connected to a compressed air channel. Device according to one of the preceding claims, - characterized in that - The vacuum transfer roller (50) is connected to a compressed air channel. Device according to claim 6, - characterized in that - below the lateral surface (52) of the vacuum transfer roller (50) a fixed hollow cylinder is present, the fixed hollow cylinder has at least two chambers in cross-section, - One of the at least two chambers is connected to a vacuum pump, - The other of the at least two chambers is connected to a compressed air channel. Device according to one of the preceding claims, - characterized in that - The conveyor belt is designed as a vacuum conveyor belt (70). Device according to one of the preceding claims, - characterized in that - The transport speed of the conveyor belt (70) is greater than the rotational speed of the vacuum transfer roller (50).

Images