EP1528976A1 - Packaging, blank therefor and method for the production thereof - Google Patents

Abstract

A packaging for liquids is made of a flat packaging material. This material has fold lines (6) and a mark (11) placed on a wall area of the packaging. The invention also relates to a blank and to a method for producing a packaging of this type, in which fold lines (6) and the mark (11) are placed in a moving packaging web of material. Afterwards, the web of material is shaped, filled and closed. The aim of the invention is to simplify the production of the packaging and to provide it with a more economical and more precise design. To this end, the invention provides that the mark (11) is formed by stamp lines (25), which lie on a plane and of which at least two straight stamp lines (25) intersect at least in the extension thereof. It is advantageous when the mark (11) has at least one centra-symmetric structure. According to the method, the invention provides that the mark (11) is made by the placement of stamp lines (25) so that the cross-section of the material is U-shaped after stamping, whereby the thickness of the material remains essentially the same.

Description

Tetra Lava- Holdings & Finance S.A.

Packaging, cutting for the same and processes for their production

The invention relates to a packaging for a liquid and / or a bulk material, which is formed from flat packaging material which has fold lines and a marking applied to a wall field of the packaging. Furthermore, the invention relates to a blank for the production of such a packaging and to a method for producing a packaging which is produced from a moving web. A device for carrying out the method is characterized by special reading devices.

Packaging of the type mentioned at the outset is widely known and is frequently used for packaging liquid foods, for example milk or juices, which can also contain pieces of pulp. Packaging, its blanks and also its production methods are known in which a web of packaging material is moved through different processing stations and is given folding lines which are used to form the material web and form the packaging. The nascent packaging is filled and sealed before, during or after molding.

It is also known to print markings on packaging and to read them photoelectrically in order to control devices during the production of the packaging. The known marking consists of a register or bar code and is printed with tolerances of ± 1 mm. One wants to control printing units by reading this barcode so that they print a decor in different colors on the surface of the packaging in register. However, it has been shown that an imprint is often positioned incorrectly and can be offset with respect to the path of the packaging material. In addition, the bars of the bar code and in particular their transition from black to white can change due to environmental influences, with the result that reading and control errors occur. It has thus been found that the effects of temperature and moisture have a significant effect on composite material with paper as the carrier material. A stretch of the web can already occur in the paper mill when processing the raw material. In the paper mill, the paper is optionally coated (plastic, aluminum foil, etc.), provided with fold lines and usually also with cut lines. The web material is often delivered on rolls and, after processing, also leaves the paper mill on rolls, possibly individual rolls. The filling machine is often arranged separately from the paper mill and receives the individual rolls from which filled and closed packaging is made. Influences due to temperature, humidity, etc. can also occur in the filling machine. Such changes in the paper mill, between the paper mill and the filling machine or in the filling machine should be recorded and used to control the material web, so that not only a decor, possibly also multi-colored, can be correctly printed on the surface in the desired manner, but also that the shaping and folding on the correct place, including the laying of cuts when separating the filled packs.

A printed marking is largely helpful, but is sometimes subject to the same errors as the errors in printing in general.

The invention is based on the idea that the lines of a marking cannot necessarily be formed only by printing, but according to the invention by embossing. The embossing of the material for the manufacture of a pack has essential properties for the quality of the pack. If the embossing is in the right place on the packaging material or information about the position of the embossing is passed on to the processing machine, the package can be shaped precisely, is stable in itself, firm and has a correct stand. With the composite material Paper or cardboard, as a carrier material there are packs with corner flaps that have to be folded over in the right place. With correct embossing, this is also easy and precise.

The invention therefore takes up the idea of applying the marking by embossing instead of printing. Reading a printed mark is another source of error because, as is well known, many optical systems are sensitive and are sources of error. Printed markings also only allow measurement in a linear direction.

The invention is therefore based on the object of providing a packaging, its cutting and a method for its production, so that the production of the packaging can be achieved more simply, inexpensively and with greater precision.

According to the invention, this object is achieved for the packaging in that the marking is formed by embossing lines lying in one plane, of which at least two straight embossing lines intersect at least when they are extended. In this embodiment, the marking is flat, at least essentially as flat as is possible with the known natural substances. You can emboss paper, cardboard, plastics and metal foils. The embossing of various line shapes is achieved using known tools, for example two counter-rotating rollers, one of which has raised parts and the opposite recessed parts. It has proven to be expedient according to the invention that the marking with the embossing lines has at least two straight embossing lines which either already intersect in the marking or at least intersect when extended or mathematically (virtually). Such patterns allow the marking to be read quickly and precisely and contain important information that is either can be recorded on the aisle side of the machine in question and used for the further course of the Matenal web, or which can be determined and used on an upstream machine to control the Matenal web in a downstream machine accordingly. For example, information relating to the elongation of the material can be obtained from the paper mill measured after embossing up to the exit from the paper mill

According to the invention, it has also been considered to use the folding lines required for folding and shaping the package at the same time as a marking, but the embodiment described above is preferably explained, in which a separate marking with separate embossing lines is applied to the material of the packaging The marking can be created by embossing without comparable material consumption while printing is disadvantageously used. The surface of the packaging in the case of a marking created by embossing does not need to be provided in a wall area untouched by the decor or left white At first glance, the marking made by embossing could not even reach into a decor

According to the invention, it has proven to be particularly advantageous if the marking has at least one centrally symmetrical structure. All geometric structures that lie in one plane and coincide with each other after a rotation through 180 ° in this plane around a fixed point are central symmetries For example, every line is centrally symmetrical to its center point. Every straight line is centrally symmetrical to every point lying on it. Each ray is centrally symmetrical to its opposing ray Two intersecting straight lines are centrally symmetrical to their apex Also apex angles are centrally symmetrical structures The diamond or the rhombus and the rhomboid also result from this as centrally symmetrical structures. because a lot of important information can be read or derived from the marking, which is useful for the control of the subsequent processing stations

Thus, according to the invention, it is expedient in a preferred embodiment if the marking has an outer rectangular frame, the sides of which run parallel to the longitudinal folding lines of the packaging, and if a parallelogram is inscribed in this outer rectangle (the frame). It is more specific It is particularly advantageous according to the invention if, in the case of a rhombus as a parallelogram, its two diagonals run parallel to the longitudinal and transverse folds of the packaging when the package is cut. In the case of the rhombus, the diagonals are perpendicular to one another. The diagonals halve the angles of the parallelogram Such a marking creates a more precise positioning of the packaging material in the manufacture of the packaging

It is well known a square is an equilateral, right-angled parallelogram; a rectangle an equilateral, right-angled parallelogram, a rhombus an equilateral, oblique-angled parallelogram and a rhomboid an unequal-sided, oblique-angled parallelogram. If such a parallelogram is used as a centrally symmetrical structure in the marking, then this parallelogram describes the type of packaging. For example, the rhombus describes a square packing, the rhomboid a rectangular packing.

If you cut a cuboid packing perpendicular to its longitudinal center axis, generally along a horizontal plane, the cross section of such a packing is square or rectangular according to the cutting line. UHT milk is currently usually packaged in rectangular packaging in Europe, fresh milk in square packaging. The rectangular packaging has two wide side wall panels and between them two narrow side wall panels, opposite one another. The diagonal of the pack is known to be an important factor in determining the pack volume. The packing diagonal e can be calculated from the width of the side wall fields. In the case of the square packing, the two side wall fields are of equal width, for example have a width of B '. Then

Pack diagonal e = B 'x V2.

In the case of rectangular packaging, for example, the wide side wall panel has the width B 'and the narrow side wall panel has the width C. In this case, the following applies to the packaging diagonal:

As is well known, the repeat length of the package blank also plays an important role, i.e. the length in the running direction of the blanks in the machine. If you have this repetition length on the one hand and the package diagonal e on the other, then you can draw conclusions about the package volume that ultimately matters.

From the marking with the parallelogram inscribed in the manner described, for example rhomboid, values can be measured and read out which provide information about the shape and the correct volume of the pack. The path of the pack blanks runs past at least one stationary sensor in such a way that the sensor beams have the opportunity to scan the marking and read out the relevant sizes. These are compared with previously read setpoints. If the difference is zero, the pack being created has the correct angular position, the correct volume and the correct shape. Regardless of the design of the mark in question, the invention has also thought of making two separate markings at different locations on the surface of the packaging. In this way, for example, different diameters of a tube can be measured and the overlap seam set. On the other hand, it is also known that three sides of the packaging are determined by the production. The third side, through which the longitudinal seam runs, depends on how exactly the machine operator sets the overlap (a trapezoidal packaging is created if the overlap is too small or too large). The position of the overlap can be precisely determined and automatically set by a second marking.

It is also advantageous if, according to the invention, a second, inner rectangle is inscribed in the outer rectangle (the frame) such that two sides coincide with the sides of the outer rectangle, which run parallel to the longitudinal fold lines of the packaging, and the two touch the other side of the connecting corners of the rhombus so that the connecting corners cut the sides in half. In the case of cuboid packaging, the sides of the marking are not halved by the rhombus. A special embodiment of packaging is that which is produced from a material web in which one cut follows the other. In addition, each pack has a longitudinal central axis, to which two sides of the outer rectangular frame run parallel in the cut. Parts of these two sides coincide with the said two sides of the inscribed, smaller rectangle. This smaller rectangle is placed around the rhombus so that all four sides of the smaller rectangle coincide with or touch the corners of the rhombus. The smaller rectangle has been described for the rhombus.

It is particularly advantageous if, according to the invention, the marking has a mathematical correlation with the packaging cut such that the distances between points on the marking describe the geometry of the folding lines. For example, the distances between the transverse sides of the large rectangle have the task of describing the so-called repetition length of the blank of the packaging, ie the length of the packaging material. The cut has longitudinal and transverse fold lines, which can also be created by embossing, for example. The repetition length or the length of the packaging material is the length which can be measured between two markings which follow one another in the conveying direction of the blanks during the production at the corresponding location thereof, since each blank carries a mark. The said rectangle of the marking gives an encrypted measure of this repetition length. The same also applies to the height of the smaller, inscribed rectangle, which means, for example, the width of a narrow side wall field. Likewise, the total transverse length of a blank transverse to the longitudinal folding lines, the width of a wide wall area of the packaging or the diagonal of the blank can be read from other distances. The position (rotation around the longitudinal and transverse axes) of the packaging material can also be determined. The invention is further characterized in that the embossing lines protrude at least partially from the surface of the wall panel and / or protrude deeply into the surface of the wall panel. In the preferred, first embodiment, the embossing lines protrude from the surface of the wall field. You can feel them as increases when you touch the wall of the packaging. If the light and shade are suitable, they can of course also be seen. In the same or in a different marking or in a different batch in the production of other packagings, it is expedient if, in another embodiment, the embossing lines protrude deeply into the surface of the wall field, that is to say they are negatively shaped. One can say that in the first-mentioned embodiment, where they protrude outwards, they are positively shaped. The person skilled in the art knows that the height of the U, ie the embossing line, by which the latter protrudes from the wall field, depends on the thickness of the paper or the thickness of another material to a greater or lesser extent from the wall field. The height of the embossing says something about the thickness of the material and its thickness. According to the invention, a measurement in the Z direction is therefore possible, as are the measurements in the XY plane which are also possible with other markings. It goes without saying that the positive embossing upwards and / or the negative embossing downwards can be used to insert additional information into the marking or to read it from the marking.

If the new marking is used, the stroke of the filling machine can be changed in the event of deviations and adapted to the actual embossing lines. The volume of the packaging can also be detected. Furthermore, you can determine the position of the longitudinal sealing seam and make a correction when the material web runs, if the angle setting of the running direction should deviate from the target value. It is also possible to sense the connection seam between two material webs. Such a seam is always necessary when a feed roll with material is exhausted and has to be replaced by a new roll. The end of the exhausted roll must then be glued or welded to the beginning of the new roll. The shape of the entire package can be achieved with greater precision, and the simplicity of the means clearly results in cheaper measurement and control. The production of packs of the type mentioned at the outset and also their blanks is thus considerably improved over the known solutions. If the repetition length is read out over several packs (between 5 and 15 packs), the frequency of the repetition length can be analyzed and read in as an additional parameter.

If, according to the method according to the invention, the marking is created by introducing embossing lines in such a way that the cross section of the material after the embossing is U-shaped and the thickness of the material remains essentially the same, a very advantageous signal option has been created. Detectors, which scan the marking on different physical properties, - seen in cross section - determine the embossing lines by the fact that the embossing line on the surface in question, from which it protrudes, is convex; and is concave on the opposite side. Therefore, additional information can be placed in a fairly simple marking if one undertakes both positive and negative embossing of the relevant field of the material web.

It can be particularly advantageous that the embossing lines are introduced according to the invention during the processing of the material web in the paper mill. The embossing lines can either be provided together with the introduction of the folding lines for the formation of the packaging, simultaneously or afterwards. Since folding lines have to be provided in any case and these can also be created by embossing, for example, the simplicity of the method according to the invention for creating a marking by embossing catches the eye. In many embodiments, the printing unit for applying a decoration is located in the downstream area of the machine. The marking with the help of the embossing lines can then be introduced beforehand in such a way that the information for the further processing of the material web or the subsequent cutting can be observed and controlled via the marking.

According to the invention, the observation takes place when the pack manufacturing process is carried out with reading devices. Various physical principles are available here, and successful operational tests have already shown that the embossing lines can be sensed, recorded and registered mechanically by means of a sensor or optically or acoustically by an appropriate measuring sensor. A version with an acoustic transducer has been particularly advantageously designed. The web of material is allowed to pass between an ultrasound transducer and a recording device arranged at a distance therefrom. An ultrasound beam penetrates the material web and dampens it. This enables very precise results to be achieved very quickly. It is also possible to measure ultrasound beams reflected on the surface of the material web. Such an ultrasonic measurement succeeds with or without an optical sensor. It can be seen that previously known sources of error, which arise in particular in connection with optical measurements, can be very advantageously eliminated.

In all measuring methods, which send a beam on the marking and take advantage of the influence of the marking for the measurement, it is expedient if the relevant beam (an optical, an acoustic, or also a mechanical movement path) hits all lines of the marking. If one considers the embodiment with the rhombus described above and inscribed in the two rectangles, then all lines of a marking can be hit with a beam in the special borderline case that the scanning beam lies in the line of symmetry of the marking. This beam therefore runs parallel to the longitudinal center line of the blank, parallel to the long side walls of the large rectangle and in the middle through this so that it also runs through the connecting corners of the rhombus. If one leaves this borderline case, it is expedient to use two sensors arranged at a distance from one another as the reading device according to the invention, be they mechanical sensors, optical or acoustic sensors. In operation, the two sensor beams span a window that allows the optimal amount of information from the marking to be detected.

In this way, you can very effectively create, read and use the marking from the tube in the paper mill not only in the filling machine, but also in the case of the composite material with paper as the backing material and manufacture of packaging, and use it to control the subsequent steps. For example, the cutting process can be controlled in the paper mill, which was previously only possible after an additional marking was printed on. The angular orientation of the transported paper web can be measured. As with the filling machine, the connection seam between two rolls, the empty, old, exhausted roll and the new roll can also be detected in the paper mill.

So that the values measured and read out from the marking can be compared with predetermined target values and ultimately the actual value is set congruently to the target value, there is the above-mentioned mathematical correlation between the marking on the one hand and the packaging blank on the other hand. Distances between points on the marking are measured, which arise or are determined by cutting lines of the marking on the one hand and cutting sensor beams with certain lines of the marking on the other hand. The main value that is compared (target and actual) is the value e of the package diagonals. It is important for the mathematical correlation that each measure is multiplied by a factor that could be called a ratio factor. Each measure is multiplied by such a factor Xi. In this way, the geometry of the packaging can be brought into line with the embossed marking. If the factor is selected accordingly, the actual cutting values are reduced. This has the advantage that the measurement, which takes place at the marking, gets greater accuracy, because the miniaturized dimensions allow variations in the reading speed to be excluded. This can make the measurement more precise.

In the preferred embodiment, the sensors arranged stationary at a distance from the marking scan the marking with at least one and preferably two sensor beams which run at a distance from one another and parallel to one another over the marking. Depending on the type of packaging (square or rectangular packaging), the sensor is given which lines on the marking should be cut and measured as measuring points.

Further advantages, features and possible applications of the present invention result from the following description of preferred exemplary embodiments in conjunction with the attached drawings. In these show: Figure 1 is a perspective and schematic of a machine for producing a packaging from the tube, which is produced by a partially continuously and partially intermittently driven web of composite material with paper as the carrier material, Figure 2 enlarges a special embodiment of a liquid pack before folding the triangular tabs with two fixed sensors

3 shows the top view of the blank of a packaging, the lines of the double arrows A and G reflect the direction of the blanks during the manufacture of the packaging and only the marking of the second blank lying above is shown, FIG. 4 greatly enlarges the marking produced by embossing which is first on the material web, then on the blank and finally on the packaging, and

FIG. 5 schematically shows the rhombus in the middle part of the marking in FIG. 4, the embossing lines being shown as continuous lines.

Without restricting importance, the focus here is on the production of a liquid packaging for liquid foods. The packaging is produced with the machine generally designated 1 from the web 2 of packaging material, which has paper as the carrier material, in the manner shown in FIG. 1. The packaging material in web form is pulled off from a supply roll 3 and bears the fold lines generally designated 4, from which one can be picked out for illustration, for example the longitudinal fold lines 5 and the transverse fold lines 6. After the deflection roller shown at the top in the machine 1 has passed, the web 2 moves downwards in the conveying direction 7 of the web according to FIG. With the aid of the longitudinal sealing device, generally designated 8, the tube 9 is folded and provided with a longitudinal sealing seam that moves downward. This hose 9 is filled with product, for example milk or juice, via the filling tube 10. Markings 11 are provided at a distance from one another on the outside of the tube 9, which can be read with the aid of a sensor 12 and processed in a processing and control unit 13. The arrangement of two sensors 12 with their supply lines 12 ′, which are fixed to the machine and emit the sensor beams S1 and S2, is expedient. In the downstream in the conveying direction 7, shown in the machine 1 Fo mungs- and cross-sealing unit 14 is essentially the final shaping of the filled package and also the cross-sealing. The filled and closed packaging 15 can be seen below this. After passing through a final shaping unit 16, the cuboid packing 17 shown in FIG. 1 is produced.

A so-called rectangular pack is shown in perspective in FIG. 2. This is the enlarged packaging 15 with the transverse sealing seams 18 and 19 and the bottom wall panel 20, on which the marking, generally designated 11, is embossed. Other essentially flat wall fields could also serve as supports for the marking 11. The bottom wall panel 20 of the packaging 15 is, however, particularly well visible and can also be used in a machine. ordered sensors easily accessible, which is why this location is preferred for the embodiment described here.

A person skilled in the art knows that the cuboid pack 15 shown in FIG. 1 or also in FIG. 2 is produced from blanks, since the person skilled in the art knows the machine of FIG. 1 in principle. For simplification and explanation, reference is made here to a blank which is shown in FIG. 3 and also allows the creation of a cuboid pack in the manner described above. The web 2 is formed from a series of adjacent blanks in the manner of FIG. 3. Accordingly, when looking at FIG. 3 below and above the blank, one has to think of further cuts so that the position of the material web can be recognized. The conveying direction 7 of the web and thus also of the blank is parallel to the longitudinal folding lines 5 of the blank, generally designated 21. Correspondingly, one recognizes transverse fold lines 6 arranged perpendicular to the longitudinal fold lines 5, between which triangular fields 22 form. The Bodeπwandfeld 20 is located in the blank 21 of Figure 3 bottom right. There you can see the marking 11. With 11 'the next marking of the next blank, which is no longer shown, is indicated at the top. The distance between the two markings 11 and 11 'is the so-called repetition length G, that is to say the total height of the blank 21. D corresponds to the position about the transverse and longitudinal axes.

Between the two narrow side wall panels 23 and 23 ', separated by two longitudinal fold lines 5, is the wide side wall panel 24. Its width is indicated by B in FIG. The width of the respective narrow side wall panel 23 or 23 'is indicated by C in Figure 3. A is the total height of the cut from the upper cross-sectional line to the lower cross-sectional line, one can also call the repeat length, which can represent a target value. The total width of the blank 21 measured perpendicular thereto is indicated by the dashed line of the double arrow E. A more detailed explanation of the cut and its lines does not appear to be necessary here, because the person skilled in the art knows the cut shapes for the various folding boxes and rectangular packs, etc. The person skilled in the art even knows markings applied to one or the other wall field of a blank, albeit not in the form shown here and certainly not in the form described here.

The shape and shape of the marking 11 will now be described with reference to FIG. 4. It is essential that the material processed according to the invention is an embossable packaging material. The marking 11 consists of a wide variety of embossing lines 25. If the packaging material web is guided through an appropriately designed embossing roller and counter-roller, the packaging material bulges between the rollers to form the embossing lines 25. If one were to lay a cross-section through these, one would get into known U-shape. The thickness of the material in front of and behind the embossing line and even within the embossing line remains essentially unchanged. Therefore, an embossing line always protrudes to one side of the material web. According to the invention, it is assumed here that the outside of the pack is the top and in a preferred embodiment the embossing lines are positively embossed in the sense that the lines protrude from the bottom wall panel 20 of the packaging 15. With reference to FIG. 4, the embossing lines 25 thus protrude from the viewing direction.

The marking 11 has a particularly selected shape in the embodiment shown here. At least two straight embossing lines 25, namely all embossing lines, intersect. It can be seen that the structure shown in FIG. 4 is centrally symmetrical. The marking has an outer rectangular frame 26 with two long sides 27, 27 ', which run in the conveying direction 7 of the material web, and two short sides 28, 28' perpendicular to it. The long sides 27, 27 'of the rectangular frame 26 run parallel to the longitudinal folding lines 5 in the flat blank 21 according to FIG. 3. An inner rectangle 29 is inscribed in this outer rectangle (the frame 26), the transverse sides 30, 30' of which are spaced apart extend from the short sides 28, 28 'of the outer frame 26, and the long sides of which coincide with the long sides 27, 27' of the frame 26. The outer rectangle, the frame 26, is bypassed if one follows lines 27, 28 ', 27' and finally 28 one after the other. The inner rectangle 29 is circumvented by following the following lines, the middle part of the long side 27, the transverse side 30 ', the middle part of the other long side 27' and the transverse side 30.

A rhombus 31 is inscribed in the inner rectangle 29 such that its vertical diagonal 32 also runs parallel to the longitudinal fold lines 5 in the cut. The two transverse sides 30, 30 'of the inner rectangle 29 touch the connecting corners 33L and 33N of the rhombus 31 at their center. The two transverse sides 30, 30' of the inner rectangle 29 touch the corners 33L and 33N of the rhombus 31 such that the connecting corners 33L and 33N cut or touch the respective side 30 or 30 'of the inner rectangle 29 at the center, so that in other words the center of the respective side is 30 or 30' here. Therefore, the diagonal 32 of the rhombus 31 in the extension is the line of symmetry of the entire marking 11.

The middle part of the marking from FIG. 4 is enlarged and shown schematically again in FIG. 5. The rhombus 31 has four connecting corners K, 33L, M and 33N. The vertical diagonal 32 would be the connecting line between the corners 33L and 33N. The transverse sides 30 'and 30 also run through these last-mentioned corners 33L and 33N. The sensor beam S1 of the first sensor shown runs perpendicular to these. The second sensor beam S2 of the second sensor 12, which is likewise fixed in place, runs at a distance and parallel to this (not shown in FIG. 5).

If one considers the cut of FIG. 3, then the nominal dimensions A, B, C and E are assumed as given. The rectangular type of packaging should also be selected. According to this type of pack, the sensor sets which of the points on the marking 11, which it all sweeps, to be recorded, in the example of FIG. 5 and in the case of the so-called rectangular packing, for the one sensor beam S1, the points P1 and P2; and for the other sensor beam S2, points P3 and P4.

The distances A ', B', C sensed from the marking are correlated to the actual distances via a factor X1 or X2. A '= A x X2 C' = C x X1 B '= B x X1.

The actual value D 'is also measured from the marking. It gives an indication of the position of the marking and thus the cut in the machine, for example the angular position. Due to temperature or moisture influences and the operation of the machine, changes can occur in the run of the material web, which affect the position of the material web. D 'also gives an indication of the diagonal. This above-mentioned packing diagonal e is specified and then compared with the calculated value e ', which results from the correlation of measured values:

With e = ΛIB ' ² + C' ² for rectangular packaging.

The value e is compared with the actual value e '. Ideally, the difference is zero.

The further correlations With e '= B'x ϊ for square packaging help for the calculation and thus the actual-target comparison.

E '= 4 x D' + Ü x X1, where Ü is the overlap of generally 8 mm. This overlap is caused by the longitudinal sealing seam, which is why it must be added to the blank width E in the cut of FIG. 3. E = 4B + Ü if B = C, ie the square packing.

E = 2B + 2C + Ü, if B ≠ C, if the packaging is rectangular.

The person skilled in the art thus recognizes that the marking 11 described represents a mathematical correlation to the packaging blank 21. This makes it possible to describe or determine the geometry of the fold lines 4 - 6 of the blank 21 according to FIG. 3. By measuring the values shown from the marker 11, the actual values of a blank can be determined, for example the values A ', B', C and E ', and then compared with the target values. It is understood that E 'is a calculated mathematical value as stated above. LIST OF REFERENCES

1 machine

2 web of packaging material

3 supply roll

4 fold lines

5 lengthways fold

6 cross fold lines

7 Direction

8 Langseiegelemπchtung

9 hose

10 filler pipe

1 1 mark

12 sensor

12 'supply and connection lines

13 processing and control unit

14 forming and cross sealing unit

15 packaging

16 final forming unit

17 boxes of cubes

18, 19 cross seal seam

20 bottom wall panel of the packaging 15

21 cutting

22 triangular fields

23, 23 'narrow side wall panel

24, 24 'wide side wall panel

25 embossing lines

26 outer rectangular frame

27, 27 '' long side of frame 26

28, 28 'short side of the frame 26

29 inner rectangles

30, 30 'transverse side of the inner rectangle 29

31 rhombus

32 vertical diagonals 33K 33L, M, 33N

Connecting corners 34 horizontal diagonal = largest diagonal of the rhombus 31

A Repeat length (nominal value) of the blank 21 B Width of the wide side wall field (nominal value)

C Width of the narrow side wall field (setpoint)

D Size measured from the marking for the correct position of the pack

G Repetition length (actual value)

E Cutting width (setpoint) S1. S2 Sensor scanning beam e diagonal (nominal size) of the packaging

A 'felt repeat length (actual value) of the blank

B 'Sensed width (actual value) of the wide side wall field 24, 24'

C sensed width (actual value) of the narrow side wall field 23, 23 'e' calculated length of the diagonals (actual value) of the packaging

U overlap

E 'cutting width calculated after measurement (actual value)

Claims

P ate π tan β test

1. Packaging for a liquid and / or a bulk material, which is formed from flat packaging material, which has folding lines (4, 5, 6) and one on a wall panel (20) of the packaging

(15) applied marking (11), characterized in that the marking

(11) is formed by embossing lines (25) lying in one plane, of which at least two straight embossing lines (25) intersect at least when they are extended.

2. Packaging according to claim 1, characterized in that the marking (11) has at least one centrally symmetrical structure.

3. Packaging according to claim 1 or 2, characterized in that the marking (11) has an outer rectangular frame (26) whose sides (27, 27 ') in the blank (21) run parallel to the longitudinal folding line π (5) of the packaging, and that in this outer rectangle

(Frame 26) a parallelogram (31) is inscribed.

4. Packaging according to one of claims 1 to 3, characterized in that in the case of a rhombus as a parallelogram, its two diagonals (32, 34) in the blank (21) of the packaging (15) parallel to the longitudinal (5) and Cross fold lines (6) of the packaging run.

5. Packaging according to one of claims 1 to 4, characterized in that a second, inner rectangle (29) is inscribed in the outer rectangle (frame 26) such that two sides with the sides (27, 27 ') of the outer rectangle (26), which run parallel to the longitudinal folding lines (5) of the packaging in the blank (21), collapse and the two other sides (30, 30 ') touch the corners (33) of the rhombus (31) such that the Halve the corners (33) of the sides (30, 30 ').

6. Packaging according to one of claims 1 to 5, characterized in that the marking (11) has a mathematical correlation to the packaging blank (21) such that the

Distances (A, B, C, E) between points on the marking (11) describe the geometry of the fold lines (4, 5, 6).

7. Packaging according to one of claims 1 to 6, characterized in that the embossing lines (25) protrude at least partially from the surface of the wall panel (20) and / or are deep in the surface of the wall panel (20).

8. Blank for the production of a packaging for a liquid and / or a bulk material, the blank being longitudinal (5) and transverse folding lines (6) and one on a wall panel (20). brought marking (11), characterized in that the marking (11) is formed by embossing lines (25) lying in one plane, of which at least two straight embossing lines (25) intersect at least when they are extended.

9. Blank according to claim 8, characterized in that the marking (11) has at least one centrally symmetrical structure.

10. Blank according to claim 8 or 9, characterized in that the marking (11) has an outer rectangular frame (26), the sides (27, 27 ') of which run parallel to the longitudinal fold lines (5), and in that outer rectangle (frame 26) a parallelogram

(31) is inscribed.

11. Cutting according to one of claims 8 to 10, characterized in that in the case of a rhombus as a parallelogram, its two diagonals (32, 34) run parallel to the longitudinal (5) and transverse fold lines (6) of the packaging.

12. Blank according to one of claims 8 to 11, characterized in that a second, inner rectangle (29) is inscribed in the outer rectangle (frame 26) such that two sides with the sides (27, 27 ') of the outer rectangle ( 26), which run parallel to the longitudinal fold lines (5) of the packaging, collapse and the other two sides (30,

30 ') touch the connecting corners (31) of the rhombus (31) such that the connecting corners (33) halve the sides (30, 30').

13. Blank according to one of claims 8 to 12, characterized in that the marking (11) has a mathematical correlation to the packaging blank (21) such that the distances (A, B, C, E) between points on the marking (11 ) describe the geometry of the fold lines (4, 5, 6).

14. Cutting according to one of claims 8 to 13, characterized in that the embossing lines (25) protrude at least partially from the surface of the wall panel (20) and / or are deep in the surface of the wall panel (20).

15. A method for producing a packaging for a liquid and / or a bulk material, which is formed from flat packaging material, which has folding lines (4, 5, 6) and a marking (11) applied to a wall panel (20) of the packaging (15). Fold lines (4, 5, 6) and a marking (11) are applied to the material web (2) in a moving web (2) of packaging material, after which the material web (2) is shaped, filled and closed, characterized that the marking (11) is created by introducing embossing lines (25) such that the cross section of the material after Embossing is U-shaped, the thickness of the material remaining essentially the same and at least two straight embossing lines (25) intersecting at least when they are extended.

16. The method according to claim 15, characterized in that the embossing lines (25) together with the fold lines (4, 5, 6) in the processing of the material web (2) are introduced in the paper mill and then read.

17. The method according to claim 15, characterized in that the material web (2) provided with fold lines (4, 5, 6) is provided with embossing lines (25) in the filling machine.

18. Device for performing the method according to one of claims 15 to 17, with reading devices (12), characterized in that the reading device (12) has a mechanical sensor, an optical or an acoustic sensor.