KR101975313B1 - Method for producing an aluminum foil with integrated security features - Google Patents

Abstract

The present invention relates to an aluminum foil with an integrated security feature 6 and to a method of making an aluminum foil 1. In a number of cold rolling passes, the aluminum foil 4 is rolled up to a thickness of less than 150 μm, and at the same time a structure 5a, 5b is made which proceeds in the rolling direction on both sides of the aluminum foil. A loose compound 8 is formed from at least two of the aluminum foils 4, the compound being supplied to a pair of drive rollers 9 in the final cold rolling pass, a relief made in the rolling direction by a polishing treatment. The shaped surface structure 11a is reduced by 10 to 50% with respect to the average roughness height in one zone 6 'in a contrast and motif dependent manner on at least one roller surface to form a motif relating to security features. It was. This security feature is transferred onto the aluminum foil face 2a facing the roller surface, after which the loose composite 8 of the aluminum foil 1, 4 ′ is separated.

Description

TECHNICAL FOR PRODUCING AN ALUMINUM FOIL WITH INTEGRATED SECURITY FEATURES

The present invention relates to a method of making aluminum foil with integrated security features and to an aluminum foil with integrated security features produced by such a manufacturing method.

In general, medical products packaged with the help of aluminum foils are often targets for counterfeiting. Therefore, anti-counterfeiting devices should be as close as possible to such medical products, which means that the direct application of security features during the manufacturing process of the primary packaging provides the best conditions for it.

Therefore, as is common with banknotes, the pharmaceutical industry has sought to provide holograms for packaging materials. But it turns out that holograms can be faked even if they are complex in production.

The present invention therefore provides a solution to this.

According to the invention, a method of the type described above is presented, in which the aluminum foil is rolled to a thickness of less than 150 μm, while at the same time a texturing is created on both sides of the aluminum foil extending in the rolling direction, A loose composite is formed from at least two of the aluminum foils, the composite being guided to the drive roller pair in the last rolling pass, and on at least one roller surface, transferred to the outer surface of the aluminum foil facing the roller surface. For the formation of motifs relating to losing security features, relief type surface structures made by grinding are reduced according to the contrast and motif in the range of 10 to 50% relative to the average depth of roughness, the relief Loose composite of aluminum foils are separated after type surface structure is reduced .

Further embodiments of the production process of the invention are disclosed in subclaims 2 to 5.

The present invention also relates to an aluminum foil with integrated security features, which is manufactured according to the process of the invention and has at most 30% security features per unit surface.

Further embodiments of the aluminum foil according to the invention are disclosed in the dependent claims 7 to 10.

The invention is also illustrated in the following description by FIGS. 1 to 8 and by possible exemplary embodiments for the incorporation of the invention.

1 shows a drive roller for executing a process according to the invention.
2 is a detailed view of one drive roller and its surface design.
3 shows a Stribeck curve for the documentation of relevant process parameters in the roller gap.
4 illustrates a processing sequence of a process for fabricating integrated security features.
5-8 illustrate possible embodiments of an integrated security feature.

The fabrication method for an aluminum foil 1 according to the invention incorporating security features 6 first comprises a subprocess of strand casting, homogenization, hot rolling, cold rolling and subsequent annealing above the recrystallization temperature. ) This is followed by a thin cold rolling process. This causes the aluminum foil 4 to be rolled down to a thickness of less than 150 μm in several cold rolling passes, thereby simultaneously as shown in FIG. 4 (b) on both outer faces 4a and 4b of the aluminum foil. Similarly texturings 5a and 5b are produced in the rolling direction. This structured roughness formed in the rolling direction results in an induced reflection of the incident light, which causes the outer surfaces 4a, 4b to have a glossy appearance.

This method has been modified for the last rolling pass as shown in FIG. 4 (a) as well as in FIG. 1, so that the drive roller pair 9 is used with at least one roller surface having a motif 6 'for security features. do. This motif 6 'is characterized by the motif and contrast in which the surface structure 11a, such as a relief made in the rolling direction by grinding, is in the range of 10% to 50% with respect to the average roughness depth. Is reduced. This can be done, for example, by the action of laser beams as shown in Figs. 2 (b), 2 (c) and 4 (c). During the last cold rolling step, a loose composite 8 is formed from the two shiny aluminum foils 4 by the release agent 7, for example as shown in FIGS. 1 and 4 (b). This loose compound 8 is fed into a closed roller gap 9 ′ formed between two drive rollers 10, 11. The motif regarding the security feature 6 is now transferred onto the outer surface 4a of the aluminum foil facing towards the drive roller. Now blurry random texturing is formed in the area of the security feature 6 of the aluminum foil 1-see FIG. 4 (d)-which is the remaining outer surface area 2a with the glossy and induced texturing 3. ) Is distinct from. Because of this random texturing, the diffuse reflection of the incident light is made in the region of the security feature 6 so that the region of the security feature 6 appears blurred. The outer surface 2b of the aluminum foil 1 facing away from the roller surface is covered by the release agent 7 together with the second aluminum foil marked 4 'for clarity. The contact sides of the two foils are identified by the roller grooves of the rolling step in progress and the roughness newly generated during the combined rolling, which roughly faces transversely in the rolling direction. Diffused scattering occurs because of the random structuring of these surfaces. After cold rolling, the loose composite of the aluminum foil 1 with the integrated security feature 6 and aluminum foil 4 'made according to the invention is separated. The aluminum foil 4 'has a directional structuring 5'a on its outer surface 4'a so that this outer surface is shiny and the second outer surface 4'b has a random structuring. Thus providing a blurred surface.

However, both drive rollers are provided with a motif 6 'and another aluminum foil 1 with an integrated security feature 6 is made in place of the aluminum foil 4'.

The thin rolling process which is the basis of the process according to the invention belongs to the subcategory called "flat rolling" and is defined in particular through process end products with a thickness of 20 μm. Cold rolling processes in this thickness range require explicit application of surface roughness values to the tools in combination with procedural liquids that create frictional conditions in the rotor cap required for plastic deformation.

Reference is made to the streamback curve-see FIG. 3-for the documentation of the process parameters related to the procedure. Coefficients of friction appear on the X axis and functions of velocity, pressure, and viscosity are shown on the Y axis. Mixed friction ranges are required for cold rolling of foils. In areas where there is little lubrication, continuous contact with the rolled material occurs, and reduction of material in this area is not possible, which then results in poor surface properties and damage of the roller. In the fluid lubrication zone-in this respect see 14 of FIG. 2 (a)-the drive roller 11 starts to float so that direct control of the rolling process, in particular the reduction of the material thickness, is no longer possible. Thereby the range of mixed friction can be adjusted by changing the parameters V, P and N.

It is possible to generate longitudinal and pressure tensions that load up to material beyond the shape change resistance to cause reshaping only in the mixed friction range, which means a reduction in material thickness. The parameters of the rolling oil required for the reshaping process, namely the adjustment of the viscosity, pressure, safety and lubrication effect, are on the one hand a precise selection of a base oil such as kerosene, a highly refined hydrocarbon with precisely defined viscosity. It is achieved only by the addition of about 5 percent by volume of rolling oil additives which brings the pressure stability of the medium to a certain level but also significantly affects the friction conditions in the rolling gap 9 '.

Adjustment of these parameters represents the basic requirements for the method according to the invention. Therefore, these parameters are permanently monitored and readjusted. In specific applications, the concentration of the rolled oil additive is measured directly through sampling from the buffer container of the roller rack and maintained within the precisely defined range by additive adjustment. For accurate dose control, the treatment liquid is sprayed onto the drive rollers 10, 11 by a nozzle beam.

In the roller gap 9 ', mixed friction conditions are required, since only the prescribed friction conditions allow the application of longitudinal tensile stress. This longitudinal tensile stress acts against the strain strength and is an essential factor for achieving strain resistance during foil rolling. Such thickness reduction without longitudinal tension stress is not possible from a technical point of view.

A reduction from this method is made during cold rolling into the closed roller gap, whereby the band thickness in the roller output is controlled by the primary parameter of the entry tension, which is this primary This is because the parameter acts against the deformation resistance of the aluminum foil 4. After achieving the maximum entry tension, the roller speed is used as the secondary control parameter to change the lubrication film thickness (fluid lubricant input).

During cold rolling, mixed friction conditions are required which are characterized by the simultaneous occurrence of boundary friction and liquid friction. During liquid friction, which is fluid lubrication 14, both sides are completely separated from each other. The transferred shear stress depends on the dynamic viscosity of the lubricant and the speed difference between the drive roller and the aluminum foil. In contrast, during boundary friction, both sides are separated only by a lubrication layer, which is only a few thick molecular layers, so that the viscosity of the lubricant plays a dependent role. The ratio between boundary friction and liquid friction with respect to the length of the roller gap depends on the layer thickness of the input lubricant and the roughness of the drive roller and the aluminum foil.

The mechanism for influencing the lubrication film thickness depends on the fluid lubricant input, the lubricant input to the roughness valley 11b, and the adhesion of the lubricant particles, see FIG. 2 (b).

Fluid lubricant input mainly occurs in the input zone into the roller gap 9 '. This input zone forms a wedge shaped gap 12 through which the driving roller 11 and the aluminum are restricted surfaces as they move in the direction of the wedge tip pull along the lubricant 13 in the form of a membrane. Foil 4 is formed, see FIG. 2 (a). The resulting fluid pressure composition in the rolling oil is thus dependent on the rolling speed, the viscosity of the lubricant, and the geometry of the roller gap. As soon as the yield criterion for the aluminum foil 4 is met, the aluminum foils deform flexibly and the layer thickness of the lubricant present in this position is pulled into the roller gap 9 '.

In the roller gap 9 ', the lubricant enters into a surface depression called roughness valley 11b on the drive roller 11 and the aluminum foil 4, see FIG. 4 (c). This process is also dependent on the orientation of the surface structure, independent of the oil storage of the surfaces. Such a mechanism can be used for the induced change in friction conditions, and then serves to create changed surface tissue due to the generated liquid friction. This occurs because it misses contact with the drive rollers and hence the texturing in the rolling direction.

Boundary layers are formed on the surface of the aluminum foil and the drive roller conveyed into the roller gap 9 'due to the physical and chemical adsorption of lubricant components, for example surface active additives. This mechanism is influenced by the roller composition and the rolled material, and the chemical composition and temperature of the rolled oil. This mechanism is no longer discussed, as the temperature and composition of the rolling oil with respect to the attachment of lubricant components in the process according to the invention is not different from the conventional cold rolling process.

However, making it possible to bring into the hydrodynamic range the associated changes in the lubricant film thickness and the frictional conditions in the roller gap from the mixed friction range in the region of the motif is the ground-in of the drive roller. It is a combination of the above effects by directed and partial destruction of the structure. This results in floating of the drive rollers and creates a randomly visible but clearly visible random tissue that is barely measurable in the measured roughness, which is due to partial contact with the drive rollers. This is due to the reflectivity of the remaining surface regions which have been made and have a surface configured in the rolling direction.

The aluminum foil 1 made with the integrated security feature 6 is replicated through optical treatments in several passes for analysis purposes. For a clear illustration of the surface structure, representative foil samples are made in format A4. For the measurement of the surface structure of the tools required for fabrication, epoxy resin imprints of the surface are made and measured by a reflecting optical microscope and infinite focus.

With the help of this analysis it is now possible to carry out optical recognition for identifying the security features 6 made in accordance with the invention. FIG. 5 illustrates a security feature 6 consisting of lettering security combined with an example of a staff of Asclepius customary in the medical industry. Of course, the latter is illustrated by way of example only and does not claim rights for any exclusion. In any case, it is important to point out that the outer surface illustrated in Fig. 5 (b), which faces away from the roller surface during the rolling process, does not contain any unwanted negative print motifs, whatever the aforementioned security features are.

An example of a fantasy of guarantee features 6 is shown in FIG. 6, in section b as in FIG. 6 (b), there are blurry surfaces in the area of security feature 6 and each bordering. In the surface zones the structuring in the longitudinal direction is continued to keep the surface glossy.

7 also shows an image taken by scanning electron microscopy of the security feature 6. In the area of security features the surface is blurred, thereby making the surface appear glossy in the boundary surface areas. The detailed views according to FIG. 7 (a) or 7 (b) show that this different effect is caused by the roughness of the surface in the region of the security feature 6 and is constructed longitudinally in the bordering regions. Shows.

This applies similarly to the image shown in FIG. 8 of an aluminum foil 1 made according to the invention with an integrated security feature 6, secured according to infinite focus analysis. From those shown in FIGS. 8 (a), 8 (b), 8 (c), and 8 (d), there are random texturings in the zone of security feature 6, while the bordering zone It is also clear that there is an induced structure in these.

In summary, the following fundamental differentiating features are listed for accurate recognition of the method according to the invention:

Direct application of security features 6 with aluminum foil 4 thickness reduction; Therefore no additional processing steps are required;

High operating efficiency through high speeds during the manufacture of the aluminum foil according to the invention;

More complex imitations due to the complexity of the basic process;

-Due to the shape and arrangement of the surface structure, a clear association of the treatment with the rolling process;

No possibility of removal of security features 6 without destruction of the surface of the aluminum foil;

The security feature 6 does not break through the back side of the aluminum foil 1;

No change in physical and / or chemical properties of the aluminum foil 4 such as roughness, foldability, stretch, tensile strength and hygroscopicity;

A change in surface composition in the range of the fourth order, measurable by the average roughness depth RZ;

No significant change in arithmetic mean roughness index (RA) in the region of security feature 6;

In the range of first degree (shape changes such as unevenness or out of roundness), second degree (waviness), or third degree (grooves) There is no change in shape.

In cold rolling used according to the invention, optical features such as security feature 6 are applied by the induced application of different surface textures of aluminum foils in the fourth range. No significant difference in roughness depth can be determined, but a difference in the type of texturing of the grooves and scaling is achieved. Changes in the shape of the aluminum foil are undetectable, so passing through the back of the foil does not happen either.

Finishing techniques such as graphical relief-type shaping and embossment (pressure stamping methods) of flexible packaging materials made with the aid of conventional fabrication methods, are the starting materials due to the optical or mechanical properties of the final product. In the art, technology, and fabrication processes, the method according to the invention is significantly distinguished, since the motifs to be raised in the stamping process often penetrate the backside of the raised material in an undesired manner.

During rolling in the course of the treatment according to the invention, the surface structure of the aluminum foil 4 is changed during the machining operation, which makes it possible to construct one or more security features 6 on the surface. Imitation by conventional finishing techniques is not possible or as such is readily recognizable. The production and further processing of the aluminum foil 1 according to the invention with an integrated security feature 6, in terms of the number of fabrication steps, is indistinguishable from the processing of conventional rolled aluminum foils, and thus pharmaceutical products It can be easily implemented in the conventional manufacturing method relating to these.

Claims (10)

A method of making an aluminum foil (1) with integrated security features (6),
The aluminum foil 4 is rolled to a thickness of less than 150 μm in several cold rolling passes, and at the same time a texturing 5a, 4b is produced which extends in the rolling direction on the outer surfaces 4a, 4b of the aluminum foil, and these A loose composite 8 is formed from two of the aluminum foils 4, which are fed to the drive roller pair 9 in the last cold rolling pass and, on at least one roller surface 11, the roller surface is Depending on the contrast and motif in the range 6 'in the range of 10 to 50% with respect to the average depth of roughness, for the formation of a motif relating to the security feature 6 being transferred to the outer face 2a of the aluminum foil facing Fabrication of aluminum foil, in which the relief type surface structure 11a made by grinding is reduced, and the loose composite 8 of the aluminum foil is separated after the relief type surface structure 11a is reduced. Way. The method of claim 1,
The last cold rolling pass is done with a closed roller gap 9 'and the defined mixed friction range is adjusted according to the streak curve by parameters such as coefficient of friction, dynamic viscosity of rolling oil, rolling speed, and rolling pressure. At the same time, a longitudinal tension is applied to the aluminum foil (4) which acts against the shape change resistance of the aluminum foils in the closed roller gap (9 '). The method according to claim 1 or 2,
For the last cold rolling pass on the roller surface (11), the relief type surface structure (11a) made in the rolling direction is reduced in the average depth of roughness by laser beams. The method according to claim 1 or 2,
In the aluminum foils used, due to providing a release agent 7, any unwanted bleeding of the motif with respect to the security feature 6 onto the remaining outer face 2b of the aluminum foil 1 (strikethrough) does not occur, The manufacturing method of the aluminum foil characterized by the above-mentioned. The method of claim 2,
Due to the friction conditions in the closed roller gap, the physical and / or chemical properties of the aluminum foil (4) are also retained in the final product (1) of the production method.
delete delete delete delete delete

Images