The present invention relates to a device fox embossing and/or perforating foils for tobacco goods, comprising a pair of embossing rolls, one of the embossing rolls halving teeth for perforating the foil, according to patent claim 1. Here, the term “foil” covers a foil encasing a cigarette, for example made of paper, which is possibly pre-printed or pre-embossed and can have so-called LIP (Low Ignition Propensity) zones or stripes or is entirely provided with a fire-retardant substance, and also the mouthpiece paper, the so-called tipping paper, which is wound around the cigarette filter.
Embossing devices from the prior art having rolls are predominantly used for embossing packaging foils, for example for the foodstuffs industry, the pharmaceutical industry and in particular for the tobacco goods industry. In the tobacco goods industry, devices having embossing rolls have been used for more than 30 years for embossing packaging foils, in particular so-called innerliners, these innerliners not only being provided with decorative effects but also with authentication features. Here, the paper component is stabilized in such a way that the foil can be processed without inconvenience in the following packaging plant.
However, in the tobacco goods industry, it is not just packaging foils that are processed or embossed but also the paper and the mouthpiece, also called tipping, for encasing the individual cigarette. During the processing of cigarette paper and of the mouthpiece, in addition to the decorative effect, endeavors are primarily made to make perforations deliberately in the cigarette paper and in the mouthpiece, in order to increase the throughput of air during smoking.
As opposed to the increased throughput of air of a cigarette during drawing, in various states, including in the EU, statutory regulations have been granted or are being prepared to the effect that the cigarettes, when not being smoked, will extinguish themselves after a specific time interval. This is achieved by means of a fire-retardant substance which initially was applied in the LIP zones and which, for example, can consist of a coating in the interior of the cigarette paper, in order to reduce the porosity. In recent times, it has transpired that this zonal coating is too complicated for mass production and the trend to providing the entire cigarette paper with the fire-retardant substance before the processing has therefore become widespread. The result of this is that perforations become necessary in order to achieve the necessary throughput of air. However, the perforations cannot extend randomly over the length of the cigarette but must be arranged at specific points.
Most of the devices known at present for producing perforations in cigarette paper are implemented by means of a laser system since, in principle, the quantity and size of holes can be set well thereby. Such laser systems for producing relatively large holes are very complicated, however, and cannot be used online in a cigarette production machine.
Within the content of the present invention, the term tobacco goods production machine is understood to mean equipment for encasing individual tobacco goods items such as cigarettes, this machine being designated a “maker” in this application. Here, the embossed foil can be fed to the maker directly or indirectly by a robot. Both methods are designated online methods. From there, the cigarettes pass to a tobacco goods packaging machine, also called a “packer” for short, in which a number of cigarettes are packed. In the present application, only the maker following the perforation is of interest.
In the case in which porous cigarette paper is used to increase the draw during smoking, the area in which the cigarette paper is porous can be embossed in such a way that the cigarette paper becomes corrugated at this point, so that when this cigarette paper is encased with the mouthpiece paper, additional air-conducting areas are produced, which increase the quantity of air during drawing. Examples of such perforation systems are disclosed in U.S. Pat. No. 3,596,663, EP 0 536 407 A1 and GB 2 133 269 A.
It is also known, for example from WO 2011/131529 A1, to apply perforations by means of embossing rolls, it being possible for the perforations to be applied only at specific points, for example outside the LIP zones which effect the extinguishing of the cigarette after a certain time. In this WO application, it is primarily emphasized that the film must not be weakened by the perforations in such a way that, during the further processing, tearing of the same can be caused. For the perforations, the teeth, which have been known per se for a long time, are used in a pin-up pattern, the teeth being disclosed as pyramidal. The WO application likewise discloses a monitoring unit which examines the foil following the embossing, in order to determine various properties of the embossed foil and, with regard to the tearing resistance, in order to control the mutual pressure of the embossing rolls and therefore the penetration depth of the teeth into the paper.
On the basis of this known prior art, it is an object of the invention to specify a device for embossing and/or perforating foils for tobacco goods with which it is possible to perforate these foils for further processing in a tobacco goods production machine accurately online at specific points, it being possible for the perforations also to serve as a decoration, and predefined standards with regard to the drawing and extinguishing quality of the cigarette being satisfied. This object is achieved by a device according to patent claim 1.
The invention will be explained in more detail below by using drawings of exemplary embodiments.
If the foil already has LIP zones applied, any embossing or printing patterns and the hole patterns must be applied as a local function of said LIP zones. However, in addition if the entire foil has already been treated entirely with a fire-retardant substance, any embossing or printing patterns and the hole patterns must be produced at specific points. Here, suitable markings, so-called “eyes marks” can already be present for this purpose or can be applied continuously. These zones, printing patterns or other markings are detected by a position sensor. The various markings, patterns and zones on the foil, possibly having to be taken into account, are combined by the term “character”.
According to
If the embossing unit 2 is used, the processing cycle P can be defined, for example, by a length section of the foil 1 to be fed in per unit time of the maker, to which length section the operating cycle A1 of the embossing unit 2 must be matched during the pre-treatment of the foil 1. A positionally accurate arrangement of the surface structure impressed by the embossing unit on the length section of the foil to be supplied in each case corresponds thereto. The surface structures can be, for example, one or more logos, which are produced by removing or changing teeth on a roll or multiple rolls. It can also be a printed pattern. The embossing unit 2 can also contain a male-female embossing roll pair.
The synchronization unit 3 contains a determining apparatus 8, it being possible for the latter, for example, to include continuous optical detection of the position of the surface structure which has been impressed on the film 1 in the embossing unit 2. The detection is carried out on the transport path between the embossing unit 2 and the perforation apparatus 5. The operating cycle 1 determined is matched to the processing cycle P in a positioning apparatus 9. A manual and/or automated adaptation method is conceivable for this purpose. For instance, the embossing roll of embossing unit 2 can be uncoupled temporarily from the drive in order in this way to lengthen the transport path of the foil 1 by a desired extent, which is then in harmony with the processing cycle P. The requisite lengthening of the transport path of the foil is absorbed by a buffer unit 7, which is arranged after the embossing unit 2.
For the purpose of defining and monitoring the operating cycle A2 of the perforation apparatus 5, the device additionally comprises a control unit 10. The latter contains a comparison apparatus 11, by means of which detection of a quantitative deviation between the operating cycles A1 and A2 of the embossing unit and of the perforation apparatus is made possible. This can be carried out, for example, continuously optically by means of a lamp, which is formed in the manner of a stroboscope for regularly chronologically spaced emissions of light onto the foil. The emission frequency preferably corresponds to the processing cycle P. In this way, optical detection of the relative position between the patterns applied in the embossing unit 2 and the perforation structures molded in the perforation unit 5 on the film 1 and 1E, respectively, is carried out.
In addition to the optical synchronization, other means are also conceivable, for example visual detection or manual adjustment of the positioning apparatus, by means of which the operating cycle A1 of the synchronization unit 3 is synchronized with the operating cycle A2 of the control unit 10. Instead of optical synchronization signals, electronic synchronization signals or else mechanical synchronization means can be used, such as, for example, a plurality of gear wheels and/or belts, which can be equipped with an angle and/or position adjusting mechanism.
Instead of synchronizing the control unit 10 via synchronization unit 3, the converse procedure of adapting the operating cycle of the embossing unit 2 controlled by the control unit 3 by the control unit 10 is also conceivable, in order as a result to achieve uniform incorporation in the processing cycle P. In both types of synchronization, two-stage synchronization is carried out in series, in order to detect the possible deviations of the operating cycle of both embossing units both from the processing cycle P and from one another, by which means more precise equalization is achieved.
The information determined in such a way is used further in a positioning apparatus 12 in order to match the operating cycle A2 to the operating cycle A1 in such a way that the perforation patterns 25 formed have the desired relative position on the foil 1E. For instance, the positioning apparatus 12 can be designed for the manual and/or automated adjustment of the initial relative position of the driven perforation roll 13 with respect to the foil 1. For this purpose, the markings 40 on the embossing rolls can be used. To this end, a clutch for uncoupling the perforation roll 13 from the roll drive 50 is conceivable. This additionally permits a necessary or process-dependent change in the relative position of the perforation patterns 25 on the foil 1.
Furthermore, the comparison apparatus 11 can also be used to detect the relative deviation of the operating cycle A2 from the processing cycle P, for once more checking the synchronization with the subsequent encasing process. Furthermore, in this way indirect conclusions can also be obtained about an unintended deviation of the operating cycle A2 with respect to the operating cycle A1, since the operating cycle A1 has already been synchronized with the processing cycle P by means of the synchronization unit 3. The second buffer unit 7A is provided to change the transport path of the film 1 as required during an intervention of the positioning apparatus 12 after the perforation unit 5.
As will be explained more extensively further below, both the spacing of the two perforation rolls 13 and 14 and also the pressure of one roll on the other roll are controlled in order to produce the desired perforation patterns. The pressure transducer 16 suitable for this purpose is controlled via a control unit 17. The schematic drawing of
In a simplified device, it is possible to arrange for the embossed film 1E after the perforation apparatus to reach the maker but it is advantageous and imperative for many applications to monitor the hole pattern following the processing by the perforation rolls and possibly to intervene in the control loop. For this purpose, after the pair of perforating rolls and before the second buffer unit 7A there is arranged a quality checker 6 with pressure control sensor 18.
The quality checker unit 6 is connected to the control unit 17 in order to control the pair of perforating rolls via the pressure transducer 16. In addition, this unit 6 is connected to an evaluation unit 19. A template 20, which is present in electronic form here, also belongs to the quality checker unit.
The quality checker 6 is explained in detail in
The template 20 serves both as a template for the production of the perforation elements on the perforating rolls and for monitoring the embossed hole pattern on the foil. As a result, a reliable and easily checked authentication of the cigarettes or other smoking goods encased by such foils can be performed.
By using the process control described above, it is possible to position both the LIP zones and the decorative pattern accurately on the foil, in order to be able to produce the rows of holes at the desired points. The control unit 17 is equipped to intervene in a controlling manner in the process if the various zones change, wherein various parameters can exert an influence thereon.
In
In order to obtain a better embossing quality, which, amongst other things, depends on the fluctuating paper thickness, it is expedient to provide the area of the rolls with a smaller diameter where the embossing elements are arranged. The length L of this zone 32 is somewhat greater than the width of the foil 1. The reduction S can be arranged on one or both embossing rolls, the total reduction then being the same.
The female embossing roll 14A has depressions 34 assigned to the perforating teeth 33 on the male embossing roll 13A. The depressions 34 are not necessarily inversely congruent with the teeth 33 and can have shapes and geometric dimensions differing from the teeth, as will emerge from the description of
The male embossing roll 13B in
The pair of rolls 13C and 14C according to
In the design variant of
The pair of rolls 13E and 14E from
The pair of rolls 13F and 14F from
The pair of rolls 13G and 14G according to
The difference between the pair of rolls 13G and 14G according to
In the pair of toothed rolls according to
The pair of rolls 13K and 14K according no
While the rectangles in the device according to
The pair of rolls 13M and 14M according to
In the pair of rolls according to
In
Exemplary dimensions are:
where the pitch is defined as the distance between two adjacent teeth.
These statements are exemplary, as described above, and not to be understood as limits. Depending on applications, larger, possibly also smaller, dimensions can also be chosen.
In
In the pair of rolls from
In
In
In the male-female die pair according to
In the exemplary embodiments according to
In the embodiments according to
In the following exemplary embodiments 33-36, which, in a way analogous to the exemplary embodiments according to
Because of the very complicated technology during the production of a male-female roll pair by means of mechanical tools or by using the etching technique, the application of these for industrial purposes is very restricted. In general, such systems are used for individual productions or for special purposes. In addition, a conventional male-female die system having inversely congruent structures has, amongst other things, the serious disadvantage that the foil exhibits distortion in the transverse direction, in particular following the embossing of row structures, which makes further processing in a maker very difficult.
On the basis of the above description, for a substantial improvement in the embossing possibilities and quality and, above all, also for use in the online method, it is primarily required that the surface structures of the rolls, in particular of the female embossing rolls, can be produced in a great variety and more logically and above ail more accurately. While, according to the prior art, the accuracy could be ensured by etching or by means of mechanical machining with high outlay, this is not true of the logical and consequently also quicker production of the male-female embossing rolls in a large variety of the perforating elements.
Furthermore, there is the requirement that measures be taken to reduce the transverse stresses in the embossed foil, which occur to a greater extent in the case of inversely congruent structures, in such a way that said stresses are no longer disruptive to the further processing.
One solution resides in forming the surface structures of the rolls of a set independently of one another, i.e. that it is not necessary for the male embossing roll to be shaped first and for the female embossing roll to be shaped physically dependently thereon. At present, this is conceivable for the required precision and production time, preferably when use is made of a suitable laser system which makes it possible to produce not only male embossing rolls but also female embossing rolls logically, accurately and above all in many shapes and independently of one another.
An exemplary laser system can contain a laser which contains a deflection unit having a beam splitter and acousto-optical or electro-optical modulators or polygonal mirrors. The deflection unit and a focusing optical unit and deflection mirrors form an engraving unit which can be displaced linearly in the X axis. However, provision can also be made to displace the entire laser device in the X axis. The rotating workpiece is driven by a drive. By means of the combination of the linear displacement of the engraving unit and the rotation of the workplace, a constant spiral is produced, which permits uniform machining.
The use of a deflection unit which, for example, can contain one or more beam splitters and electro-optical or acousto-optical modulators or one or more polygonal mirrors, permits the original laser beam to be split into two or more laser beams which are incident simultaneously on two or more tracks but have a spacing from each other such that they do not interfere with each other. In addition, the time interval between the impingement of the individual pulses can be chosen to be so large that thermal overloading does not take place.
As a result of the use of short-pulse lasers, the laser pulses of which lie between 10 femtoseconds and 100 picoseconds, the energy is applied in a very short time period, so that so-called “cold removal” is made possible, in which the material is evaporated very quickly without unacceptable heating of the adjacent material. The undesired liquid state of the material, which produces cratered rims and splashes, can be avoided thereby virtually completely. The desired structures are generated on a computer which controls the laser system, so that it does not matter whether a surface structure for a male embossing roll or for a female embossing roll is being produced. For the rolls or the surface thereof, a suitable steel, hard metal or ceramic, for example, is used.
Two different housings for accommodating a pair of embossing rolls are illustrated in
The male embossing roll 13 is pushed in from the rear, non-visible opening 53 and fixed in an accurate position. In
One of the adjusting means in the direction of the longitudinal axis of the rolls consists in two very accurately machined adjusting rings 55 being produced on one of the rolls, the female embossing roll here, and an exact central ring 56, which comes to lie between the two rings 55, being produced on the opposing roll. Therefore, a very accurate alignment of the two rolls in the longitudinal direction can be achieved. One possible adjustment in the radial direction consists in the accurate production of the gear wheels 31 and 32, which permit very accurate radial positioning.
Located on the housing is a pneumatic block 59, which is controlled so as to set the pressure and, derived therefrom, the distance between the two rolls accurately. The non-driven roll—here the upper roll—is mounted on its axles in such a way that it is possible for the axles to give way in all three coordinates. As a result, the accurate synchronization of the teeth and depressions becomes possible. Furthermore, the connecting flange 58 of the axle of the lower roll, at which the lower roll is driven, can be seen in the drawing.
In the design variant according to
Number | Date | Country | Kind |
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12171255.8 | Jun 2012 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2013/054656 | 6/6/2013 | WO | 00 |