DE102010006172A1 - Method for manufacturing public suburban transportation ticket, involves perforating data carrier material tape such that bars of perforation lines do not lie immediately one above other when data tape is folded in fan-shape - Google Patents

Abstract

The method involves perforating a data carrier material tape by a punching device such that a data tape (10) is folded in fan-shape along a data carrier (20) forming perforation lines (40-42) with bars (30-32). The material tape is perforated such that the bars of the lines do not lie immediately one above the other when the data tape is folded in the fan-shape. The bars are arranged in different sequences and arrangements to form perforation patterns (A-C). The material tape is made of multilayer material that comprises a thermally activatable layer, a fiber layer and a paper layer. An independent claim is also included for a device for manufacturing isolatable, card-shaped data carrier.

Description

The present invention relates to a method and an apparatus for producing a separable, card-shaped data carrier comprising data carrier tape by perforating a data carrier material tape and a corresponding data carrier tape.

Various card-shaped data carriers, for example, entrance tickets, public transport tickets and the like, are made of a thin film material which is in the form of a ribbon. This material is generally multi-layered and comprises, for example, a base layer made of plastic or paper, a middle plastic layer and a thermally activatable layer arranged on the upper side. The middle plastic layer may comprise elements required for providing contactless data communication, for example a chip, an antenna or the like. The final thermoactivatable layer, which itself may be multilayered again, is suitable for printing on the data carrier tape by means of thermal printing.

The data carrier tape is perforated for the production of the data carrier tape at regular intervals. This creates perforation lines, which on the one hand have continuous openings, on the other hand remaining webs of residual data carrier material. These perforation lines define the edges of the data carriers present in the data carrier tape and enable a later separation of the data carriers, for example by tearing off.

Such a data carrier tape is folded for further processing usually along different perforation lines fan-shaped or Z-shaped and packaged in the folded state. It happens that the data carrier material fibrillates in the region of the webs, in particular if at least one paper layer is present. This relates in particular to the webs of such perforation lines which form folded edges of such a fold. Due to the frayed data carrier material in the region of the webs and under further influence of such variables as pressure, moisture and heat, the folded data carrier tape tends to clump or block by fibers when folding superimposed next webs connect with each other. A later separation of the disk is made difficult or even prevented.

The object of the present invention is to prevent blocking or clumping of a folded data carrier tape.

This object is achieved by a method, a data carrier tape and a device having the features of the independent claims. Advantageous embodiments and further developments are specified in the dependent claims.

In a method for producing a data carrier tape comprising separable card-shaped data carriers, a data carrier tape is perforated in such a way that the data carrier tape can be fan-folded along perforation lines which form the data carriers and comprise webs. According to the invention, the data carrier material strip is perforated in such a way that the webs of different perforation lines do not come to lie directly above one another when the perforated data carrier tape is folded in a fan shape.

In this way it is prevented that the fan-shaped folding fibers may possibly ausfasernder webs connect, since the webs, when the volume tape is folded, not directly adjacent to each other or come into contact, but are sufficiently spaced. Webs of such perforation lines, which are arranged one above the other during folding of the data carrier tape, are so spatially offset from each other due to the perforation according to the invention that a connection of the fibers of corresponding webs and thus blocking or clumping of the folded data carrier tape can be effectively prevented. The fact that webs when folding superimposed perforation now no longer directly adjacent to each other or even touch, but rather sufficiently offset from each other, the pressure on each of these webs is reduced, whereby the tendency to blocking is further reduced. Finally, there is the further advantage that due to the staggered webs of the perforation lines when folding, the height of the stack, which results in the fan-shaped folding of the data carrier tape, is reduced. This makes it possible to package a data carrier tape, which in comparison to the conventional method, in which all perforation lines are identical, comprising more data carriers, in the same packaging volume as before.

A corresponding data carrier tape according to the invention with separable, card-shaped data carriers which are formed in the data carrier by webs comprehensive perforation lines, characterized accordingly by the fact that the data carrier tape along the perforation lines is fan-shaped foldable that the webs of different perforation lines do not come to lie directly above each other.

A device according to the invention for the production of such a card-shaped, separable data carrier comprehensive data carrier tape by perforating a data carrier tape comprises a perforation device which is adapted to perforate the data carrier tape so that it can be folded fan-shaped along the perforation lines forming the data carrier. According to the invention, the perforation device is in particular designed to perforate the data carrier material strip such that the webs of different perforation lines do not come to rest directly above one another in the fan-shaped folding of the data carrier strip.

According to a preferred embodiment of the method according to the invention, the data carrier material band is perforated in such a way that webs of perforation lines provided as folding edges do not come to lie directly above one another. By folding along the perforation lines, the possible fraying of the data carrier material in the area of the webs is further promoted. In this respect, it is essential for webs of such perforation lines that they are spaced apart when folding the data carrier tape and preferably do not touch, so that they do not come to lie directly above one another. This embodiment further offers the already mentioned advantages, according to which the pressure on individual webs of fold edges forming perforation lines is reduced in the folded state and then reduces the stack height of the folded data carrier tape with a constant number of data carriers per band. These effects are a consequence of the fact that according to the invention, such perforation lines adjoin one another directly at the corresponding fold edges, which are characterized in that one of the perforation lines adjoins another perforation line at a location where it itself has a web Place a recess, so in particular no web has.

According to a further embodiment, the data carrier material band is additionally perforated in such a way that webs of perforation lines not provided as folding edges (which can occur when the data carrier tape is folded in such a way that at least two data carriers lie next to one another in the resulting stack) do not directly overlap one another when folding the data carrier tape to come to rest. This is advantageous if the data carrier tape is not folded at each perforation line but, for example, only at every second or third perforation line. A clumping risk exists in conventional methods, in which only identical perforation lines are provided, even on the webs of such non-folded edges as perforation lines, especially in unfavorable environmental conditions such as high temperature and high humidity, even if the fraying of the webs within such not provided as folding edges perforation lines compared to actual folding edges usually less noticeable. This lower clumping risk can be further reduced according to this embodiment.

The perforation is generally carried out in such a way that perforation lines, which can be arranged one above the other in the fan-shaped folding of the data carrier tape, respectively form perforation patterns defined by different sequences and / or arrangements of webs. That is, such a Perforationslinie perforation pattern is defined by the arrangement of webs and these webs interrupting, through openings or recesses in the data carrier tape. The number of webs and recesses per perforation pattern can vary. In the same way, the width of the webs and recesses may vary in perforation patterns of different perforation lines.

Preferably, the data carrier material band is perforated in such a way that different perforation patterns repeat periodically along the longitudinal direction of the data carrier band. Ie. Perforation patterns associated with different perforation lines periodically return. For example, it is possible to provide three different perforation patterns which alternate periodically in the same order, thus defining a periodically repeating sequence of three different perforation lines. The number and design of the repeating patterns may vary.

According to another preferred embodiment of the method according to the invention, the data carrier material band is provided with periodically repeating perforation patterns in such a way that the resulting data carrier tape can be folded in a fan-shaped manner without the webs of different perforation lines-due to an identical perforation pattern-being arranged directly above one another. If, for example, as mentioned above, three different, periodically repeating Perforationsmuster provided so the corresponding volume tape can be fan-shaped folded on each perforation line or alternatively only on every second perforation as folding edge, without thereby perforation lines are arranged directly with the same perforation patterns, d , H. without the webs of the corresponding perforation lines come to lie directly above each other.

The data carrier material strip is preferably perforated by means of a punching device, ie the device according to the invention comprises a punching device as the perforation device. The punching device comprises different punching elements, which in turn are suitable for producing different perforation patterns during perforation. The perforation patterns are, as mentioned, defined by different sequences or arrangements of webs and the webs interrupting recesses in the data carrier material. The punching elements, for example, punching blades or the like, can be arranged on a rotatable roller of the punching device. It is also possible that the different punching elements are present separately in the punching device, ie not together on a roller or the like, but for example on each separate rollers or deviating means, for example, individually controllable punches or the like.

As a further method step, the perforated data carrier tape can then be fan-shaped, for example for packaging, in such a way that perforation lines with different perforation patterns are arranged one above the other. Such a folded data carrier tape is then protected due to the perforation carried out according to the invention against lumping or blocking, since webs of such perforation lines which adjoin one another directly after folding, do not come to lie directly above one another.

Preferably, a data carrier material made of a multilayer material is provided for the method according to the invention. As a rule, such a material comprises at least one fibrous layer, in particular paper, and a thermoactivatable layer, in particular for simple printing of the data carriers by means of a thermal printing process. Other layers, for example made of plastic, can be provided.

The present invention will be described by way of example with reference to the accompanying drawings. Show:

1 a preferred embodiment of a data carrier tape according to the invention;

2A . 2 B the volume tape off 1 folded fan-shaped in two different ways; and

3A . 3B only schematically, two preferred embodiments of a device according to the invention.

1 shows a volume tape 10 , which is a plurality of isolable, card-shaped data carriers 20 includes. The volume tape 10 consists of a multilayer material which is composed of an upper thermal layer, a middle plastic layer and a lower paper layer, which may alternatively be made of plastic. The middle plastic layer may contain components which the individual data carriers 20 to equip for contactless or contact data communication, such as a chip and an associated data communication interface, eg. In the form of an antenna or the like. The thermal layer itself is usually in turn multi-layered and comprises a thermally activated paper layer as well as this paper layer surrounding protective layers of plastic, which protect the paper layer against moisture and other influences. Other layer structures of the data carrier material are also possible, with individual of the abovementioned layers, for example the middle plastic layer, being dispensed with or being able to be replaced by alternative layers.

In the production of the data carrier tape 10 is a volume of tape 11 (see. 3A . 3B ) has been perforated at regular intervals perpendicular to its direction of extension in the manner described below, with different perforation lines 40 . 41 . 42 have arisen. The distance between every two adjacent perforation lines 40 . 41 . 42 defines the longitudinal extent of a volume 20 , The width of a volume 20 is the width of the data carrier tape 11 established. Each of these perforation lines 40 . 41 . 42 has webs 30 . 31 . 32 on, which consist of remaining at the perforation data carrier material, wherein individual webs through through openings or recesses 50 . 51 . 52 in the volume tape 10 to be interrupted. Below the volume tape 10 in 1 are those through the given sequence of webs 30 . 31 . 32 and the footbridges 30 . 31 . 32 each separating and limiting recesses 50 . 51 . 52 defined perforation pattern A, B, C separately illustrated.

The perforation pattern A of the perforation line 40 for example, consists of an arrangement of three equal width webs 30 passing through four recesses 50 . 50 ' . 50 '' . 50 ''' in the volume tape 10 are separated and limited, with the recesses 50 . 50 ' . 50 '' . 50 ''' have substantially the same width, which in turn the uniform width of the webs 30 exceeds.

The different perforation pattern B of the perforation line 41 has only two bars 31 on, which through recesses 51 . 51 ' . 52 '' in the volume tape 10 limited and are spaced. The recesses 51 . 51 ' . 51 '' each have different widths, in contrast to the similar recesses 50 . 50 ' . 50 '' . 50 ''' the perforation line 40 ,

The perforation pattern C to the perforation line 42 Finally, the perforation pattern B is similar in that it is in each case an equal number of webs 32 and recesses 52 . 52 ' . 52 '' However, which in comparison to the perforation pattern B different, ie arranged in different order. In an analogous manner, any other perforation pattern can be formed and used. The number of different perforation patterns used can vary. The number and width of the webs and the number and width of the webs limiting and separating recesses in the data carrier tape may vary from pattern to pattern.

As in 1 indicated, repeat the perforation A, B, C periodically along the tape volume 10 in that order, ie perforation lines 40 . 41 . 42 Repeat cyclically along the entire length of the volume tape 10 , A periodic repetition of perforation patterns, no matter what number, is not mandatory, but brings various advantages - especially in the manufacture - which will be described in more detail below.

The choice of the perforation pattern A, B, C in the volume tape 10 is not accidentally hit. Rather, these patterns fulfill the essential property that when the volume tape 10 along individual perforation lines 40 . 41 . 42 is folded fan-shaped (see. 2A . 2 B ), the footbridges 30 . 31 . 32 such perforation lines 40 . 41 . 42 , which are placed directly on top of each other when folding, do not come to lie directly above each other.

So for example, the volume tape 10 along the perforation line 41 folded so that the perforation lines 40 and 42 adjoin one another (see also 2A . 2 B ), so the webs fall 30 the perforation line 40 each in areas of the perforation line 42 , which exist there as recesses. The same applies to the bars 32 the perforation line 42 , These are to the jetties 30 the perforation line 40 arranged offset so that where the perforation pattern C a web 32 has, the perforation pattern A a recess 50 pretends. This situation is in 1 illustrated by the variously dashed and dash-dot lines indicated, each indicating that webs 30 . 31 . 32 a perforation line 40 . 41 . 42 lie in an area where the other two perforation lines 40 . 41 . 42 recesses 50 . 51 . 52 exhibit.

Thus, the above-mentioned essential property is satisfied, that is so when folding the volume tape 10 Stege 30 . 31 . 32 different perforation lines 40 . 41 . 42 do not necessarily come to rest on top of each other, three different perforation patterns do not necessarily have to be used, nor do these or other perforation patterns have to repeat periodically. A selection of the perforation patterns A, B, C as in 1 However, facilitates the production of the data carrier tape 10 for certain, frequent use cases considerably.

The selection of perforation patterns A, B, C in 1 has the advantage that the property described above is satisfied both when the volume tape 10 , as in 2 B illustrated at each of the perforation lines 40 . 41 . 42 is folded fan-shaped, as well as when the folding is such that only every second perforation line 40 . 41 . 42 is provided as a folding edge, as in 2A is shown. In the folding according to 2A applies in particular that also webs of such perforation lines 40 . 41 . 42 , which are not intended as folding edges, not directly over webs 30 . 31 . 32 such perforation lines 40 . 41 . 42 come to rest, which are arranged according to the folding directly adjacent - also not as folded edges. For both folds, according to 2A and 2 B Of course, the corresponding essential property also applies to such perforation lines 40 . 41 . 42 that form fold edges of the respective fold.

The perforation of the data carrier tape 11 can generally be done using any number of perforation patterns that are periodically re-arranged, such that of the 2A . 2 B deviating folds are possible without webs of such perforation lines, which directly adjoin one another after folding, come to lie directly above one another. The perforation patterns used for this also have the property described above, that for every two of the perforation pattern applies that in such a region in which the one perforation pattern has a web, the respective other perforation shows a recess. For example, if an odd number of such perforation pattern, z. B. d many, used periodically arranged, the described essential property, according to which webs of different perforation lines do not come to lie directly above each other when folding, obtained for all such convolutions in which each k-th perforation line is provided as a folding edge (where k is a can be any number between 1 and d - 1), if for all j = 2 (k - t), t = 0, ..., k - 1, then: j ≠ rd, where r is a natural number, in particular r = 1. In 2A is an example with d = 3 and k = 2 to see 2 B illustrates the case d = 3 and k = 1.

Will the volume tape 10 like in the 2A . 2 B folded in suitable containers 70 . 71 packaged, wherein, as mentioned, the perforation of the data carrier tape 11 in the production of the data carrier tape 10 has been carried out such that - in a fan-shaped folded state - webs 30 . 31 . 32 different perforation lines 40 . 41 . 42 do not come to lie directly above each other, there are several advantages. The first is a blocking or clumping of the data carrier tape 10 This prevents, possibly in the area of the webs 30 . 31 . 32 frayed data carrier material due to the offset arrangement of the webs 30 . 31 . 32 different, adjacent perforation lines 40 . 41 . 42 can not connect. A separation of the data carrier 20 remains possible in the desired manner.

The second becomes a single bridge 30 . 31 . 32 of the packaged volume tape 10 compared to the conventional method - with identical perforation patterns - applied with less pressure, as mentioned - webs 30 . 31 . 32 such perforation lines 40 . 41 . 42 that when folded volume tape 10 are arranged one above the other, not directly adjacent to each other. A risk of clumping the data carrier tape 10 , which would be favored by such pressure, is thus further reduced. The, as described, spatially offset arrangement of the webs 30 . 31 . 32 different perforation lines 40 . 41 . 42 has the further effect that the volume tape 10 packaging more effectively. One in the conventional method with increasing packing height in the container 70 . 71 occurring bending of the disk 20 such that the stack in question fails at the fold edges higher than in the middle, essentially eliminates. This has the further positive side effect that, in comparison to the conventional method with identical perforation patterns, a larger number of data carriers 20 in containers 70 . 71 consistent size can be packed.

The 3A and 3B show, only highly schematic, two preferred embodiments of inventive devices for producing the data carrier tape 10 out 1 , The devices 100 . 200 are set up, the volume of tape media 11 which is introduced, for example, continuously or in discrete steps by means of a conveyor in the direction of the arrow P to perforate in such a way, and thereby the data carrier tape 10 produce that in the subsequent fan-shaped folding of the data carrier tape 10 (see. 2A . 2 B ) Webs of different perforation lines do not come to lie directly above one another.

The perforation device 100 is in the form of a rotatable, cylindrical roller, on which three different perforation elements 100A . 100B . 100C are arranged in the form of punching blade sets. Each of these punch sets is 100A . 100B . 100C respectively, in the data carrier tape 11 on a perforation line resulting therefrom of one of the perforation patterns A, B, C to produce, if the data carrier tape 11 suitably under the rotating roller 100 is passed. It is understood that the perforation device 100 can be equipped with any number of perforation elements, which in turn can be configured to produce any perforation pattern. In this way can be with the perforation device 100 all embodiments of the data carrier tape described above 10 produce which have periodically repeating Perforationsmuster.

The device off 3B differ from the in 3A in that the perforation device shown therein 200 perforation 200A . 200B . 200C which are arranged separately from each other - ie in particular not on a common rotatable roller. Here are the perforation elements 200A . 200B . 200C set up, perpendicular to the conveying direction P of the data carrier tape 11 to be movable. The material band 11 In this embodiment, it is preferably forwarded in discrete steps in each case by the length of three data carriers to be produced. Then the punching elements 200A . 200B . 200C , which again as punching sets equal to those in 3A are formed, as indicated by the vertical arrows, lowered and generate perforation lines having the perforation pattern A, B, C. Subsequently, the volume tape 11 accordingly further promoted. Also in this embodiment, it is possible to produce various perforation patterns. For this purpose, only an exchange of perforation elements is required. Their number is variable.

Both devices, in 3A and 3B , generate a volume tape 10 which has perforation lines whose perforation patterns repeat periodically. At least the device off 3B would also allow the production of volume tapes with no or only occasionally periodic repetitive Perforationsmustern. This would require the individual perforation elements 200A . 200B . 200C be individually controlled, the promotion of the material band 11 should also be matched to which of the punching elements 200A . 200B . 200C is provided, the next perforation line in the data carrier tape 11 to create.

Claims (18)

Method for producing a separable, card-shaped data carrier ( 20 ) comprehensive volume tape ( 10 ) by perforating a data carrier tape ( 11 ) such that the volume tape ( 10 ) along the volumes ( 20 ), webs ( 30 ; 31 ; 32 ) comprehensive perforation lines ( 40 ; 41 ; 42 ) can be folded fan-shaped, characterized in that the data carrier material band ( 11 ) is perforated such that in the fan-shaped folding of the data carrier tape ( 10 ) the bridges ( 30 ; 31 ; 32 ) of different perforation lines ( 40 ; 41 ; 42 ) do not come to lie directly above each other. Method according to Claim 1, characterized in that the data carrier strip ( 11 ) is perforated such that webs ( 30 ; 31 ; 32 ) provided as folding edges perforation lines ( 40 ; 41 ; 42 ) do not come to lie directly above each other. Method according to claim 1 or 2, characterized in that the data carrier material strip ( 11 ) is perforated such that webs ( 30 ; 31 ; 32 ) of perforation lines not provided as folding edges ( 40 ; 41 ; 42 ) do not come to lie directly above each other. Method according to one of claims 1 to 3, characterized in that the data carrier tape ( 11 ) is perforated such that perforation lines ( 40 ; 41 ; 42 ), which in the fan-shaped folding of the volume tape ( 10 ) are arranged one above the other, each by different sequences and / or arrangements of webs ( 30 ; 31 ; 32 ) define defined perforation patterns (A; B; C). Method according to claim 4, characterized in that the data carrier strip ( 11 ) is perforated in such a way that the perforation patterns (A; B; C) of different perforation lines (A; 40 ; 41 ; 42 ) repeat periodically. Method according to Claim 5, characterized in that the data carrier strip ( 11 ) is provided with periodically repeating perforation patterns (A; B; C) in such a way that the data carrier tape ( 10 ) can be fan-shaped in several different ways without the webs ( 30 ; 31 ; 32 ) of different perforation lines ( 40 ; 41 ; 42 ) come to lie directly above each other. Method according to one of claims 4 to 6, characterized in that the data carrier tape ( 11 ) by means of a punching device ( 100 ; 200 ) with different perforation patterns (A; B; C) forming punching elements ( 100A ; 100B ; 100C ; 200A . 200B ; 200C ) is perforated, wherein the punching elements ( 100A ; 100B ; 100C ; 200A . 200B ; 200C ) in the punching device ( 100 ; 200 ) on a rotatable roller ( 100 ) or separately ( 200 ) are arranged. Method according to one of claims 4 to 7, characterized in that the data carrier tape ( 10 ) is folded fan-shaped in such a way that in each case perforation lines ( 40 ; 41 ; 42 ) with different perforation patterns (A; B; C) are arranged one above the other. Method according to one of claims 1 to 8, characterized in that a data carrier strip ( 11 ) is provided from a multilayer material which comprises at least one fibrous layer, in particular a paper layer, and / or a thermally activated layer. Data carrier tape ( 10 ) along with ridges ( 30 ; 31 ; 32 ) comprehensive perforation lines ( 40 ; 41 ; 42 ) formed singular, card-shaped data carriers ( 20 ), characterized in that the data carrier tape ( 10 ) along the perforation lines ( 40 ; 41 ; 42 ) is fan-foldable such that the webs ( 30 ; 31 ; 32 ) of different perforation lines ( 40 ; 41 ; 42 ) do not come to lie directly above each other. Data carrier tape ( 10 ) according to claim 10, characterized in that the data carrier tape ( 10 ) Perforation lines ( 40 ; 41 ; 42 ) such that webs ( 30 ; 31 ; 32 ) provided as folding edges perforation lines ( 40 ; 41 ; 42 ) do not come to lie directly above one another and / or webs ( 30 ; 31 ; 32 ) of perforation lines not provided as folding edges ( 40 ; 41 ; 42 ) do not come to lie directly above each other. Data carrier tape ( 10 ) according to claim 10 or 11, characterized in that the data carrier tape ( 10 ) in the fan-shaped folding superimposed perforation lines ( 40 ; 41 ; 42 ), which in each case by different sequences and / or arrangements of webs ( 30 ; 31 ; 32 ) define defined perforation patterns (A; B; C). Data carrier tape ( 10 ) according to one of claims 10 to 12, characterized in that the data carrier tape ( 10 ) is produced by a method according to one of claims 1 to 9. Device for producing a card-shaped, separable data carrier ( 20 ) comprehensive volume tape ( 10 ) by perforating a data carrier tape ( 11 ), comprising a perforation device ( 100 ; 200 ), which is set up, the data carrier tape ( 11 ) in such a way that the data carrier tape ( 10 ) along the volumes ( 20 ), webs ( 30 ; 31 ; 32 ) comprehensive perforation lines ( 40 ; 41 ; 42 ) can be folded fan-shaped, characterized in that the perforation device ( 100 ; 200 ), the volume of media ( 11 ) perforate such that the fan-shaped folding of the data carrier tape ( 10 ) the bridges ( 30 ; 31 ; 32 ) of different perforation lines ( 40 ; 41 ; 42 ) do not come to lie directly above each other. Apparatus according to claim 14, characterized in that the perforation device ( 100 ; 200 ) is designed as a punching device. Apparatus according to claim 15, characterized in that the punching device ( 100 ; 200 ) various punching elements ( 100A ; 100B ; 100C ; 200A . 200B ; 200C ), which are set up, each different by different sequences and / or arrangements of webs ( 30 ; 31 ; 32 ) to create defined perforation patterns (A; B; C). Apparatus according to claim 16, characterized in that the different punching elements ( 100A ; 100B ; 100C ; 200A . 200B ; 200C ) in the punching device ( 100 ; 200 ) on a rotatable roller ( 100 ) or separately ( 200 ) are arranged from each other. Device according to one of claims 14 to 17, characterized in that the device is arranged to carry out a method according to one of claims 1 to 9.

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