DE10243084B3 - Device for the precise joining of two strands of material - Google Patents

Abstract

An arrangement for the precise positional coupling of a first material web (1), comprising elements (B) of sections separated at a separation point (T) with section length (A1), with a second material web (2), comprising markings (2a) with a given separation (A2) from each other, corresponding to the section length (A1) with an optional difference of up to (D), comprises a first device (3), by means of which the both material webs (1, 2) are coupled together. The both material webs (1, 2) are sectionally further transported by the given separation (A2), using a transport device (5). An element (B) is applied to the first material web (1), by means of a second device (4), when, after further transporting both material webs (1, 2) by one section, the length of the first material web (1), between the first device (3) and the second device (4), corresponds to a given multiple of the section length (A1), optionally with an offset, adjusted by means of an offset device (6, 6a). A sensor (7) is provided, by means of which the difference (D) can be recorded. The offset is adjusted depending on the difference (D).

Description

The invention relates to an arrangement according to the preamble of claim 1, for the positionally accurate assembly of a first strand of material, which is separated by separation points Sections with a section length has elements with a second strand of material which has markings which have a predetermined distance from one another, which is up to a possibly existing difference of the section length corresponds, with a first device, by means of which the two strands of material together are connected, a transport device by means of which two strands of material be transported further by the predetermined distance, and with a second device, by means of which on the first strand of material An element is always applied when the two strands of material by a section the length of the first strand of material between the first device and of the second device a predetermined multiple of the section length if necessary plus corresponds to an offset which can be set by means of an offset device.

By means of such an arrangement So-called blister packs are produced, for example, by means of which tablets are sold, for example. A Blister packaging usually consists of a plastic or paper existing thermoforming film, in which as a so-called Höfe designated Recesses are formed in which the tablets are located, and which are sealed with a cover sheet. On the cover sheet is a regular Printed image, which is usually Information about which contains tablets such as data about when to take which tablets. It is therefore crucial that this information according to the position of the tablets and thus the courtyards are attached to the cover film.

Although a very high degree of dimensional accuracy can also be achieved with the printing techniques known today, the precise positional assignment of the printed image of the cover film to the thermoformed film is a major problem, since existing deviations can add up. Over time, the position of a printed image would therefore deviate from the required position by an intolerable amount. Printing devices have therefore been developed by means of which the positional accuracy of the printed image on the cover film has been significantly increased. For example, from the DE 195 25 713 C1 a device for precise printing of a mark-free continuous film is known, by means of which printed images of a first predetermined length are applied to a metal foil, the foil being divided into sections of a second predetermined length by means of a separating device after printing, and the printed images with respect to the separation points between the Sections must be applied to the film in the exact position.

In the known device a printer is available which has an input for triggering a precise printing process. There is also a sensor available, which always emits a signal at its output, if the length the film between the separator and the beginning of one point corresponding to a section to be printed on a predetermined Multiples of the second predetermined length.

Since the output of the sensor with the Output of the printer is connected to the beginning of a section of the film to be printed is always redefined becomes. By constantly The beginning of a printing section may change a possible error does not add up. So are yourself relatively large deviations usually harmless, since the deviation in a section has no influence on the Beginning of the next section to be printed.

Furthermore, from the DE 198 50 275 C2 a further device for the precise printing of a marking-free continuous film is known, which works as a result on the same principle as the previously mentioned printing device. The most important difference from the above-mentioned printing device is that in the above-mentioned printing device the transport of the continuous film takes place discontinuously, whereas the transport in the further printing device takes place continuously. However, the printer is also always activated when the length of the continuous film between the section boundary generated by the last division carried out and the printing device is a predetermined multiple of the second predetermined length.

Although using the known Devices also have excellent results it turned out nevertheless that due to external influences a Shift of the printed image with respect to the courtyards can take place. In particular after a standstill of the orders are partially no longer tolerable deviations exist.

It is an object of the invention to initially form the arrangement so that position shifts from elements applied to the first strand of material to the Markings applied to the second strand of material reduced become.

The solution to this problem arises from the features of the characterizing part of claim 1. Advantageous further developments of the invention result from the subclaims.

According to the invention, an arrangement for positional assembly of a first strand of material which is separated by separation points Sections with a section length has elements with a second strand of material which has markings which have a predetermined distance from one another, which is up to a possibly existing difference of the section length corresponds, with a first device, by means of which the two strands of material together are connected, a transport device by means of which two strands of material be transported further by the predetermined distance, and with a second device, by means of which on the first strand of material an element is always applied if after further transport of the two strands of material by a section the length of the first strand of material between the first device and of the second device a predetermined multiple of the section length if necessary plus corresponds to an offset which can be set by means of an offset device, characterized in that a Sensor is present, by means of which the difference is detected, and the offset depending is set by the difference.

Because there is a sensor, by means of which the differences are recorded is more advantageous Way that occurs Position shifts of those applied to the first strand of material Detected elements for the markings of the second strand of material become. By setting the offset depending on the difference can the position shifts are corrected.

That is, the predetermined one changes Distance between the marks of the second strand of material changes the transport path by which the second strand of material moves forward will and, since the first strand of material with the second strand of material is connected, the corresponding transport path of the first strand of material. Since the elements are moved by one after the two material strands have been transported on However, section always applied to the first strand of material if the length of the first strand of material between the first device and of the second device is a multiple of the section length a shift of the elements relative to that due to the changed Transport route newly defined separation points instead. By hiring of the offset depending the difference can be compensated for the shift. Thus takes place a correction of the position of the elements on the first strand of material too then take place when the transport route of the first strand of material for example through a change the distance of the markings present on the second strand of material changed.

It is particularly advantageous arrangement according to the invention for precise assembly of a printed aluminum foil and a so-called Courtyards To use plastic film.

Has proven to be particularly advantageous one embodiment of the invention, in which the sensor is arranged in this way is that the Length of the second Strands of material between the sensor and the first device the length of the first strand of material between the first device and the second device in triggering the application of the element equivalent. In this way, the sensor detects the up to the sensor position summed up differences. The position is also corrected of the element on the first strand of material with respect to the first Device takes place in the same place where the occurrence of a Section length difference is detected. This has the advantageous consequence that the Correction of the position of the element on the first strand of material very much just do it leaves. to Correction of the position of the element on the first strand of material are essentially no special measures are required.

If the offset corresponds to the difference, as provided in a further special embodiment of the invention almost a 100% correction takes place, whereby an error is no longer recognizable.

In another embodiment the invention provides that that detected by the sensor Difference divided by the number of marks which that part of the second strand of material which is between the sensor and the first device when triggering the application of the element is located, and the offset is the product of the result of the division and corresponds to the predetermined multiple of the section length. Such one embodiment the inven tion is particularly advantageous when the sensor cannot be located at the point where the Length of second strand of material between the sensor and the first device the length of the first strand of material between the first device and the second device in triggering the application of the element equivalent. Because if the sensor cannot be arranged in this way, that the Length of second strand of material between the sensor and the first device the length of the first strand of material between the first device and the second device in triggering the application of the element corresponds, it is necessary to calculate the offset.

By dividing the total difference by the number of markings which the part of the second strand of material has, which is between the sensor and the first device when triggering the application of the element the difference per marker is determined. If this difference is multiplied by the predetermined multiple of the section length, which corresponds to the length of the first strand of material between the first device and the second device when the application of the element is triggered, a difference is obtained which would result if the length of the second strand of material between the sensor and the first device corresponds to the length of the first strand of material between the first device and the second device when the application of the element is triggered. If you set the offset according to the difference calculated in this way, you get a very good correction of the deviation.

By means of the arrangement according to the invention it possible especially after a blister packaging machine has come to a standstill, after the position of the printed image B relative to the wells moved regularly has the positional accuracy of the printed image B in a very short time manufacture.

Although the invention is essentially based on one of the DE 195 25 713 C1 Known printing device has been described, its uses are not limited to the use of such a printing device. If the two strands of material are two foils to be joined together, in which a printed image is applied to a foil, this printed image can be applied with any printing device, in particular with a so-called plate printer, flexographic printer or screen printer.

Furthermore, it is not necessary for the two material strands to be transported in sections discontinuously. The invention can also be used in an arrangement in which, for example, according to the DE 198 50 275 A1 the strands of material are continuously moved.

The following is a description of an embodiment with reference to the drawing.

It shows

1 1 shows a schematic representation of an arrangement according to the invention,

2 2 shows a schematic representation of two foils to be joined, in which the predetermined distance corresponds to the section length,

3 a schematic representation of two foils to be joined, in which the predetermined distance of the markings is smaller than the section length, and

4 is a schematic representation of two foils to be joined, in which the predetermined distance of the markings is greater than the section length.

How 1 can be removed, in the manner according to the invention, a first strand of material formed as aluminum foil 1 in a first device designed as a sealing station 3 with a second strand of material designed as a plastic film 2 connected. The plastic film 2 has depressions called so-called courtyards. Several wells are each combined into a group, of which the front edge of the first ho fes seen in the direction of transport is a marking 2a represents. The markings 2a are at a predetermined distance A2 from each other.

The courtyards are made with an embossing tool 15 into the plastic film 2 shaped by a role 14 is handled.

In one in 1 Tablets, not shown, are placed in the courtyards. After inserting the tablets, the courtyards are in the sealing station 3 with the aluminum foil 1 sealed. This creates a so-called blister pack. Since such blister packs must contain regular information, the aluminum foil shows 1 a printed image B. It is imperative that the printed image B is positioned precisely relative to the courtyards.

For printing on the aluminum foil 1 which of a role 13 is processed by a printer 4 led in which the aluminum foil 1 is continuously transported. The printer has to trigger a printing process 4 an entrance 4a , In the direction of transport of the aluminum foil 1 this is behind the printer 4 around a first pulley 12 diverted. Behind the first pulley 12 wraps around the aluminum foil 1 S-shaped dancer roller 10 as well as an often roll 6 , The dancer roller 10 as well as the offset roller 6 are located in the bottom of each loop, which is due to the course of the aluminum foil 1 be formed. Behind the offset roller 6 becomes the aluminum foil 1 around a second deflecting roller 11 diverted. Behind the second deflection roller 11 there is a transport device 5 , by means of which the aluminum foil 1 moved discontinuously by the length A1 of a section within which the printed image B must be arranged in a precise position. There is a theoretical separation point T between the sections.

In front of the removal device 5 is the sealing device 3 arranged in the aluminum foil 1 with the plastic film 2 is connected. By means of the transport device 5 thus also the plastic film 2 advanced.

The two slides 1 . 2 are by means of the transport device 5 in each case moved forward until the mark formed by the front edge of a first depression 2a each a fixed point T0 of the sealing station 3 located. That is, the two slides 1 . 2 are moved on until the leading edge 2a the first well of the next group of wells is located at fixed point T0. Because the leading edges 2a are at a predetermined distance A2 from each other, both foils 1 . 2 each moved further by the predetermined distance A2.

The dancer roller 10 and the offset roller 6 are arranged so that they can be moved towards and away from each other. During the offset roller 6 can be determined and only by means of an adjustment unit 6a is movable, the dancer roller 10 versatile.

In the lower area of the dancer roller 10 looping loop of aluminum foil 1 is a dancer roller sensor 9 arranged. The dancer roller sensor 9 is designed as a light barrier and has an output 9a , At the exit 9a of the dancer roller sensor 9 a signal always appears when the dancer roller is moving 10 in a certain position in front of the dancer roller sensor 9 located. The exit 9a of the dancer roller sensor 9 is with the entrance 4a of the printer 4 connected.

During the time while the slides 1 . 2 at rest increases with a continuous passage of aluminum foil 1 through the printer 4 the part of the aluminum foil 1 , which is between the fixed point T0 and the printer 4 located. This lowers the dancer roller 10 downward. The dancer roller 10 descends until the two foils 1 . 2 through the transport device 5 be moved on. The representation in the 1 corresponds approximately to the time at which the transport device 5 starts the two slides 1 . 2 keep moving.

By transporting the two foils 1 . 2 , which happens at a speed which is a multiple of the speed at which the aluminum foil 1 through the printer 4 is moved, the length of the aluminum foil shortens 1 between the fixed point T0 and the printer 4 , By shortening the length, the dancer roller 10 moves upward so that it is above the dancer roll sensor 9 located.

After moving the two slides 1 . 2 through the transport device 5 is finished and the two slides 1 . 2 are at rest again, the dancer roller lowers 10 through the continuous transport of aluminum foil 1 through the printer 4 down again. The moment the dancer roll 10 has the position in which the dancer roller sensor 9 about his exit 9A a signal to the input 4A the length of the aluminum foil 1 between the fixed point T0 and the point T corresponding to the beginning of a section to be printed, for example twelve times the length A1 of a section. Because the printer 4 receives a signal for printing at exactly the moment, the print image is set exactly at the beginning T of a section to be printed.

As long as the length A1 of a section to be printed with the predetermined distance A2, in which the markings 2a are arranged to each other, a very precise positioning of a printed image B is achieved in a respective section to be printed. However, since the predetermined distance A2 can change, for example due to external influences, and no longer corresponds to the section length A1 but to the section length A1 plus or minus a difference D, the two foils 1 . 2 and with it the aluminum foil 1 moved by the section length A1 plus or minus the difference D. Since the printed image B is independent of the size of the further transport of the aluminum foil 1 on the aluminum foil 1 is applied, there is a shift in the position of the printed image B relative to the depressions of the plastic film.

The arrangement therefore has an edge sensor 7 on, by means of which it can be determined by which way the position of a front edge 2a the first well of a group of wells. Has the groups of wells, which are between the edge sensor 7 and the fixed point T0, the predetermined distance A2 of the leading edge of the first depression of a group of depressions to the leading edge 2a the edge of the first well of the next group of wells is not changed 7 a signal that corresponds to a correct distance.

Has the groups of wells, which are between the edge sensor 7 and the fixed point T0, the predetermined distance A2 of the front edge 2a the first depression of a group of depressions towards the leading edge 2a The edge sensor gives the first recess of the next group of recesses 7 a signal from which the sum of the individual shortenings of the distance A2 of the front edges 2a corresponds to the first wells.

Has the groups of wells, which are between the edge sensor 7 and the fixed point T0, the predetermined distance A2 of the front edge 2a the first depression of a group of depressions towards the leading edge 2a the first well of the next group of wells, the edge sensor gives 7 a signal which is the sum of the individual increases in the distance A2 of the front edges 2a corresponds to the first wells.

In one with the edge sensor 7 connected control 8th becomes from the signal of the edge sensor 7 shortening or increasing the distance A2 of the front edges 2a the first wells of two successive groups of wells. This ge happens because the edge sensor 7 detected sum of all shifts is divided by the number of groups of wells that are between the edge sensor 7 and the fixed point T0. This value is in the controller 8th then multiplied by a multiple of the section length A1, which is the length of the portion of the aluminum foil 1 underlying which is between the fixed point T0 and the printer 4 located. The offset roller is around this value 6 then by means of the adjustment device 6a postponed. This will correct the position of the printed image B on the aluminum foil 1 reached.

The correction process described above is described below using the 2 to 4 described.

At the in 2 State shown corresponds to the section length A1 of the aluminum foil 1 the predetermined distance A2 of the plastic film 2 in which the leading edges 2a the first wells of two successive groups of wells. The leading edge 2a the first depression, which is in front of the edge sensor 7 is in the middle of one of the edge sensor 7 detectable area 7b , The offset roller 6 is in its basic position. That is, it is set so that the printer 4 so the printed image B on the aluminum foil 1 applies that it begins at the point of separation T between two successive sections.

At the in 3 shown state has the predetermined distance A2 at which the leading edges 2a the front wells of two successive groups of wells are reduced, such as when the plastic film shrinks 2 can occur. The predetermined distance A2 therefore no longer corresponds to the section length A1 of the aluminum foil 1 , It has decreased by a difference D-. The aluminum foil is thus transported further 1 no longer by the section length A1 but by the predetermined distance A2 which is smaller by the difference D-, which in turn has the consequence that the printed image B would start in the previous section with reference to the preceding separating points T. By correcting the position of the offset roller 6 the position of the printed image B is shifted until it is related to the further transport of the aluminum foil 1 by the section length A1 minus the difference D- corresponding new separation point T-.

By reducing the predetermined distance A2, the front edge is located 2a the first depression, which is in front of the edge sensor 7 is no longer in the middle of the edge sensor 7 covered area 7b but on the right edge. The leading edge 2a the first depression has the amount F-, which is the sum of the differences D- between the fixed point T0 and the edge sensor 7 corresponding groups of depressions, shifted to the right. The consequently changed output signal of the edge sensor 7 is used to correct the offset roller 6 set offsets used. That is, the position of the offset roller 6 is changed until the printed image B is at the new separation point T-.

At the in 4 shown state, the predetermined distance A2 has increased. The predetermined distance A2 therefore no longer corresponds to the section length A1 of the aluminum foil 1 , It has increased by a difference D +. The aluminum foil is thus transported further 1 no longer by the section length A1 but by the predetermined distance A2 increased by the difference D +, which in turn means that the printed image B would start at a distance from the separation point T with respect to the preceding separation points T. By correcting the position of the offset roller 6 the position of the printed image B is shifted until it is related to the further transport of the aluminum foil 1 by the section length A1 plus the difference D + corresponding to the new separation point T +.

By reducing the predetermined distance A2, the front edge is located 2a the first depression, which is in front of the edge sensor 7 is no longer in the middle of the edge sensor 7 covered area 7b but on the left edge. The leading edge 2a the first depression has the amount F +, which is the sum of the differences D + between the fixed point T0 and the edge sensor 7 corresponding groups of depressions, shifted to the left. The consequently changed output signal of the edge sensor 7 is used to correct the offset roller 6 set offsets used. That is, the position of the offset roller 6 is changed until the printed image B is at the new separation point T +.

Claims (5)

Arrangement for the precise joining of a first strand of material ( 1 ), which has elements (B) in sections with a section length (A1), with a second strand of material ( 2 ), which has markings (2a), which are at a predetermined distance (A2) from one another, which corresponds to the section length (A1) except for a possibly existing difference (D), with a first device ( 3 ), by means of which the two strands of material ( 1 . 2 ) are connected to each other, a transport device ( 5 ), by means of which the two strands of material ( 1 . 2 ) are transported further by the predetermined distance (A2), and with a second device ( 4 ), by means of which the first strand of material ( 1 ) an element (B) is always applied if after the further transport of the two strands of material ( 1 . 2 ) by one Section the length of the first strand of material ( 1 ) between the first device ( 3 ) and the second device ( 4 ) a predetermined multiple of the section length (A1) if necessary plus one by means of an open set device ( 6 . 6a ) corresponds to adjustable offsets, characterized in that a sensor ( 7 ) is available, by means of which the difference (D) can be detected, and the offset is set as a function of the difference (D). Arrangement according to Claim 1, characterized in that it is used for the precise joining of an aluminum foil (having a printed image (B)) ( 1 ) and a so-called courtyards ( 2a ) having plastic film ( 2 ), is used. Arrangement according to claim 1 or 2, characterized in that the sensor ( 7 ) is arranged such that the length of the second strand of material ( 2 ) between the sensor ( 7 ) and the first device ( 3 ) the length of the first strand of material ( 1 ) between the first device ( 3 ) and the second device ( 4 ) when triggering the application of the element (B) and the sensor ( 7 ) detects the difference (F) added up to the sensor position. Arrangement according to claim 3, characterized in that the offset corresponds to the difference sum (F). Arrangement according to one of Claims 1 to 4, characterized in that the difference sum (F) is determined by the number of markings ( 2a ) divided by which part of the second strand of material ( 2 ) which is located between the sensor ( 7 ) and the first device ( 3 ) when triggering the application of the element (B), and the offset corresponds to the product of the result of the division and the predetermined multiple of the section length (A1).