Patent Application
20210008915
The invention relates to a method for printing an imprint that is structured as a color-shift surface, at least in certain regions, onto the surface of at least one object. The application furthermore relates to such an imprint, which serves for individual marking of the surface of an object, as well as to a set of objects that are provided with such imprints.
In numerous areas of application, objects of the most varied types must be marked and inscribed, generally with the aid of labels, but also, in part, by means of marking the surface of the object itself. Marking generally takes place by means of printing onto the label, a container or the other object. The information to be imprinted includes, for example, the type, content, and amount of the object (for example in the case of chemicals, medications, and other products in medicine or pharmaceutics) or special information regarding use, administration, operation or warnings for dealers, sellers, end consumers and other relevant members of the public. For this purpose, common printing techniques are used, just as in the case of written materials, printed materials or other documents. Bar codes and QR codes can also be imprinted in this manner.
Furthermore, special security features exist, which are not or not exclusively intended for overt information for everyone, but rather serve as forgery protection, copying protection or as a feature that is relevant to security in some other manner, for example as security features of banknotes, of documents or badges issued by state or other authorized offices and administrations, of authorization IDs, insurance cards and check cards, etc.
Such security features have a more complicated structure; they include those having a color-shift effect, among others. For example, it is possible to print color-shift surfaces, the color, brightness or other visual impression of which depends on the line of sight, i.e. the viewing direction of the human eye relative to the orientation of the color-shift surface.
Conventionally, two different methods exist for producing an imprint that has a color-shift effect. In the case of the one method, a relief pattern composed of many parallel ridges composed of printing ink having a second, contrasting color is imprinted onto a substratum that possesses a first color; narrow strips of the substratum surface remain more or less visible between the ridges, depending on the line of sight. The strip pattern is so delicate that the strips and their interstices cannot be individually resolved with the naked eye, or this is only possible with difficulty. In contrast, the color impression of the relief-type surface can be very well perceived with the naked eye, and changes with the viewing angle when looking at the surface at a slant, at least when the plane formed by the line of sight and the normal line to the surface lies perpendicular to the course of the relief lines. In this plane, viewing at a flat angle leads to the result that the grooves between the ridges are covered, in whole or in part, i.e. they seem to disappear, more or less, and for this reason the relief-type surface appears to assume a changed color from this direction, which color is predominantly determined by the color of the material of the ridges. In contrast, in the direction parallel to the ridges, the color impression observed is essentially no different, even when looking at a slant, than when looking at a right angle, looking from the normal line direction.
The above effect is based on the geometric coverage of relief grooves by raised lines, i.e. by line-shaped or, to state it more precisely, strip-shaped ridges. This mechanism has mirror symmetry within an intersection plane in the case of different lines of sight, with reference to the normal line direction of the surface, i.e. it is identical for the lines of sight at the angles α and −α, and is most strongly marked in the intersection plane perpendicular to the ridges.
The other method is based on the appearance of specific printing ink layers themselves, which varies in color depending on the line of sight. There are printing inks having small particles, in particular having thin-layer structures, which are shaped in flake-like manner, i.e. essentially have a planar structure and possess an appearance and, in particular, a color, due to interference effects, that is optically anisotropic. Depending on the viewing direction relative to the plane of the layer boundaries, theses flake-shaped particles appear in a changeable color; the same holds true for a sufficiently thin printed layer having such particles, which deposit, for the most part, parallel to the underlying surface or boundary surface, and as a result, the coated surface is also given a color that appears to change as a function of direction.
If one were to print such optically anisotropic printing inks onto a structured surface, for example a relief-type surface, most of the particles would collect in depressions under the effect of gravity, or would get hung up on slanted side walls of ridges, but least of all on the top of ridges or other elevations, where they would be most easily visible. If uneven surface, nevertheless covered with anisotropic printing ink, are supposed to be produced, this is generally done in that first, the anisotropic color-shift ink is applied to the surface, which is still level, and subsequently the shape of the surface is changed by means of a mechanical effect, namely by means of an embossing process. For this purpose, a correspondingly structured embossing punch is pressed onto the surface, and an opposite punch is pressed against the back side of the object. This forming assumes that the object is sufficiently thin and formable. However, mechanical deformation is actually not necessary, since a planar printing ink layer composed of optically anisotropic printing ink as such already possesses a sufficient color-shift effect, based on the thin-layer particles.
Both methods for production of a color-shift effect, whether by means of a relief structure or by means of optically anisotropic ink particles, have in common that the resulting color change has mirror symmetry with reference to the surface normal line of the imprinted surface. A further commonality, in spite of different mechanisms, consists in that the imprint producing the color-shift effect has been produced by means of conventional printing techniques until now, in which a fixed printing plate is produced and used to carry out the imprint. The uniform printing plate ensures that on all objects, for example all labels, banknotes or other objects, the appearance of the color-shift surface, which serves as a security feature, is always identical within close tolerance limits, and can easily be checked for authenticity. Counterfeited or forged products, the color-shift surface of which was merely copied or counterfeited in some other manner, can easily be distinguished from authentic products, due to deviations as compared with the uniform appearance of color-shift surfaces on authorized products of the original manufacturer. As a result, it can be determined, for example, whether a label that has a color-shift field comes from the manufacturer, and whether the other imprinted information is authorized and accurate.
The present application pursues the opposite approach, namely the idea of configuring an imprint in such a manner that it can be variably structured, even though it is supposed to serve as an original reference object or comparison object for recognition of forgeries and, at the same time, as a color-shift surface.
It is therefore the task of the present invention to make available a method with which imprints structured as a color-shift surface can be printed onto the surface of objects, wherein the imprints can be structured in individually modified manner, in spite of their function as a reference object or comparison object (for example to distinguish between authentic and counterfeit products). For this purpose, a method that is as simple as possible, and is advantageous in terms of cost and time, is to be indicated.
This task is accomplished by means of the method according to claim 1.
According to claim 1, it is provided that a relief structure is formed, which is overprinted with a pattern of ink strips and thereby brings about a novel and individually variable color-shift effect. In this regard, at least the ink strips are printed by means of a digital printing technique. The ridges are preferably also printed by means of a digital printing technique, but alternatively can also be printed by means of a non-digital, i.e. a conventional printing technique. The non-digital printing technique can also comprise a step of embossing to form the relief structure.
In the case of the method according to claim 1, the color-shift effect occurs not by means of a color contrast between ridges of one color, formed entirely from the same ink, relative to a substratum of a different color, but rather by means of a color contrast of additional ink strips on top of and relative to the ridges, relative to which the ink strips are imprinted with an offset. The resulting color-shift effect generally does not have mirror symmetry with reference to the normal line direction of the imprinted surface, and above all it can be varied more flexibly than in the case of conventional color-shift surfaces, since on the one hand, exclusively digital printing techniques, without a printing plate, are used, but on the other hand, the use of anisotropic printing inks, in terms of color, which is conventionally usual, is circumvented.
According to claim 1, therefore, not just ridges are printed, but rather subsequently, at least first ink strips are also printed, specifically with a lateral offset relative to the ridges, wherein with the aid of the digital printing technique, a printing compound that is isotropic, in terms of color, is used to print the ridges, and a printing ink that is also isotropic, in terms of color, is used to print the ink strips. Suitable digital printing techniques are inkjet printing (inkjet printing), laser printing (electrophotography method) or thermal printing. Conventionally, in contrast, color-shift surfaces are produced, in terms of printing technology, by means of conventional techniques such as offset printing, flexographic printing or, above all, screen printing, in particular if they serve as a security feature for a great number of objects.
Using the method according to claim 1, it is possible to produce imprints that have a different type of color-shift effect than conventional color-shift surfaces, and which can be produced in individually varied manner, in spite of their function as a reference object or comparison object for tests of authenticity, without losing their suitability as a security feature.
Some exemplary embodiments, which can serve as examples, will be described below, making reference to the figures. These show:
For this purpose,
From the normal line direction n (
Seen from a line of sight b in a slanted view relative to the surface 50, in contrast, the surface appears in a different color and/or brightness, etc., because now the rear side flanks of the ridges 5, seen from the line of sight b, are covered or appear only with a reduced width compared with the front side flanks of the ridges 5, seen from the line of sight b. In addition, however, the visual impression that the surface 50 leaves when viewed at a slant from a first viewing direction r1 is different from the visual impression of the same surface when viewed from the direction r2 that is its mirror opposite, even when undertaken at the same inclination angle relative to the surface, because one of the two ridge sides is covered with an ink strip of a different color (see below). For this purpose, different embodiments relating to an asymmetrical structure, in particular a color-related structure without mirror symmetry, of the outside of the ridges 5 are proposed below. Since the two side flanks of the ridges 5 of the relief structure 21 are configured differently, in terms of color, they change the overall color impression of the color-shift surface in different ways; a color transition between the viewing angles r1 and r2 occurs.
According to
Preferably, a digital printing method is used for printing the ridges 5, in particular inkjet printing (inkjet printing), laser printing (electrophotography printing) or thermal printing. In particular, it is preferably provided that printing of the ridges 5 is carried out using the same digital printing technique that is subsequently used (see below) also for printing ink strips. This makes it possible to print both the ridges 5 and the ink strips in one and the same printing machine.
Alternatively, however, printing of the ridges 5 can also take place by means of a non-digital printing method, and such a conventional printing method can also include an embossing method. However, this also holds true for printing the ridges 5, but not for printing of ink strips as will be described below.
Preferably, a white or light-colored (but isotropic) printing compound or ink is used to print the ridges 5; fundamentally, however, other printing inks can also be used. Preferably, the printing ink 5a is highly pigmented, i.e. provided with a high concentration of pigment, so that intensive colors can already be produced even when printing comparatively thin layers.
Alternatively, however, the printing compound 5a can also be configured to be colorless or, in any case, without any marked inherent coloration. Regardless of the color or coloring of the printing ink or printing compound 5a for printing the ridges 5, this printing ink or printing compound 5a is isotropic, in terms of color, in any case, and, in particular, is free of anisotropic particles, in terms of color.
The printing compound 5a (whether as a colorless printing varnish or colored printing ink) is printed, according to step a) of claim 1, as a relief structure 21 composed of a plurality of strip-shaped ridges 5 that project above the surface 50, i.e. are raised and preferably have a distance between them that remains the same. Gaps 4 having the gap width g remain between the ridges 5, where the uncovered regions of the surface 50 are exposed. Printing in step a) takes place at a ridge height of at least 30 μm, preferably at least 60 μm; however, the center lines m can also project above the surface 50 by 70 μm or even higher. In comparison with the distance p ([in English:] pitch distance) between ridge centers, the height of the ridges amounts to at least 7%, preferably more than 15% and, in particular, between 20 and 30%.
The ridges run along one and the same lateral direction y (here, perpendicular to the drawing plane of
The ridges 5 possess two side flanks 1 and 2, which lie opposite one another, between which the uppermost center region 3 is arranged; the line of its highest elevation corresponds to the center line m. Due to the different orientation of the two side flanks 1, 2 of the ridges, the first side flanks 1 appear to be relatively wide when viewed at a slant—for example from the direction r1 of these flanks—whereas the second side flanks 2, which are in the rear from this direction, either appear to be narrowed or are covered by the ridge; this holds true, in particular, for greatly inclined viewing angles above 60° relative to the surface normal line of the surface. Although the first and second side flanks 1, 2 cannot be individually resolved with the naked eye, or this can be done only with difficulty, they nevertheless exert a differing influence on the overall color of the color-shift surface (which will still be completed subsequently) perceived as a function of the direction, because the uniform color impression that results from visual melding of the ridge contours (which still have to be covered with ink), is dominated by the side flanks that point closer to the observer and face him, in each instance.
Preferably, the printing compound 5a for the ridges 5 is printed onto the surface 50 by means of one-time printing, i.e. by means of a single printing step or pass through a single printing station (with a sufficiently thick printing ink application). Alternatively, the ridges 5 can be produced successively by means of two or more printing processes or passes through two or more printing stations, in other words in at least two partial layers, for example in order to achieve an even greater height of the ridges 5, above 100 μm. Optionally, printing of the ridges can also comprise in each instance an additional, immediately following whole-area overprint with a conformal printing layer (
The above variants with regard to the configuration of the ridges can be combined with every exemplary embodiment of this application.
According to
According to
As compared with conventional relief structures based on purely geometrical coverage, the ridges of which appear in one color on all sides, but contrasting to the gaps between them, the imprint 25 formed jointly by the ridges 5 and the ink strips 10 overprinted offset to them produces a color-shift surface 30 having a color-shift effect, which, although it is most strongly marked (as in the case of the above conventional relief structures) in a preferential plane perpendicular to the progression of the ridges, does not, however, have mirror symmetry relative to the surface normal line of the surface 50 in this preferential plane. In a slanted view r1 onto the first side flanks 1 (or onto the ink strips 10 printed onto them), the color-shift surface 30 as a whole appears in a different color or brightness, etc. than from the opposite viewing direction r2 onto the second side flanks 2. Even though the height of the ridges is relatively small in comparison with the ridge width and the distance between the ridges (gap width g), a color-shift effect that can be clearly perceived and reviewed can be implemented, since due to the structure, which does not have mirror symmetry, brought about by the lateral offset d, the angle range available for the color transition between two observable colors, brightness values or other visual properties that are maximally different from one another is twice as great as in the case of conventional relief structures.
In method step b), the first side flanks 1 do not have to be overprinted completely, i.e. not over the entire length of all the ridges 5, but rather, depending on the use, for example in the manner of a desired (first) color-shift motif, it can be provided, in particular, that selectively determined partial sections of the first side flanks 1, having a length that is shorter than the complete length of the corresponding ridge 5, are overprinted, and/or their positions along the length expanse of the ridge (perpendicular to the drawing plane of
At least in step b), it is provided that printing is carried out by means of a digital printing technique. As a result, the lateral dimensions, positions and/or contours, at least of the ink strips 10, can be predetermined variably, in particular changeably for every renewed printing of the printed image 25 structured as the color-shift surface 30, for example individually per unit for every individual imprint, i.e. for every copy of the printed image, which has a color-shift effect at least in certain regions.
Preferably, it is furthermore provided that also in step a), printing is carried out by means of a digital printing technique. As a result, the lateral dimensions, positions and/or contours of the ridges 5 can also be determined variably, in particular changeably upon every renewed printing of the printed image 25, structured as a color-shift surface 30, for example also individually per unit for every individual imprint.
Furthermore, it is preferably provided that an isotropic printing compound 5a, in terms of color (for the ridges) or printing ink 10a (for the ink strips 10) is printed in steps a) and b). Such printing inks possess no material-related, intrinsic color-shift properties, but rather bring about a color-shift effect only in combination with one another, in the case of a suitable lateral offset d between ink strips 10 and ridges 5.
This makes the use of color-shift inks that can be processed using embossing technology, having optically variable ink pigments, unnecessary. Since the same (specifically digital) printing method, for example inkjet printing, laser printing or thermal printing is used in both method steps a) and b) (and also in step c) according to claim 4), the ridges 5 and the first and second ink strips 10, 20 (see below) can easily be positioned relative to one another. The relative positions of ridges and conformal ink strips relative to one another, i.e. the lateral offset d; d′ between them (see below), can be precisely established in digital manner and can furthermore be varied individually, in particular individually per unit, in the case of every individual, renewed imprint.
Some alternative exemplary embodiments with regard to overprinting of the first and/or second side flanks 1, 2 of the ridges 5, starting from step b), will be described below, making reference to
According to
The design of the second motif, produced using the second ink strips 20, in partial sections of the second side flanks 2, or at least visually influenced, determined and/or dominated by them, in terms of color or some other way (for example an image motif, written motif or a motif serving as a security feature), can be selected independent of the design of a possible first first motif formed from the first ink strips 10. In particular, such a second motif does not necessarily have to represent a first motif that is merely contrast-inverted, color-inverted or otherwise inverted (or its complementary or inverted counter-motif). In particular, if both a first motif (using the first ink strips 10) and a second motif (using the second ink strips 20) are supposed to be produced, a first selection of ridges can have corresponding length sections (in a direction perpendicular to the drawing plane in
The second ink strips 20 possess a color, brightness or other visual quality that contrasts with or at least is different from the first ink strips 10, for example. For example, the color of the first ink strips is cyan C and that of the second ink strips 20 is magenta M, but any desired two individual colors can be chosen for the first and second ink strips 10, 20, that are supposed to meld within the color-shift surface 30 to form an overall color that changes as a function of the line of sight. The second ink strips 20 can optionally be printed with or without a lateral offset d′ relative to the ridges or their center lines; preferably, printing takes place with an established offset d′ that is different from the period or half-period of the relief structure 21. Here and in all the other figures and other embodiments of the applications, the regions of the surface 50 between the ridges 5 that have remained planar can optionally also be printed with the first and/or second ink strips 10; 20 (either only in certain regions or completely) or can remain unprinted, depending on the desired color distribution over the width dimension x of the color-shift surface 30. According to
Preferably, the distance between adjacent ridges 5 is selected to be as small as possible, but large enough so as to prevent adjacent ridges or contrasting ink strips deposited on them from running into one another and unintentionally melding. The entire color space of the digital printing technology being used, for example composed of the process colors CMYK or another color system, is available for configuring the color-shift surface. In particular, UV-curable inkjet printing inks or printing inks can also be used. All overprinting of the surface to be undertaken one after the other, at first by means of the ridges 5 and then by means of one or more different, in particular differently colored strips 10, 20, etc. can take place with a slight time offset, one after the other, in particular in passing through multiple printing stations of one and the same printing machine, arranged one behind the other; the great register accuracy when using the same digital printing method such as inkjet printing, for example, for all the printing steps allows precise control of the intended color-shift effect.
Although specific colors for the corresponding ink strips, for example a first color for the first ink strip 10 (for example cyan), a second color for the second ink strip 20 (for example magenta) or optionally, a third color for a third ink strip (see below) are mentioned in this application, this does not necessarily mean that spot colors, i.e. ready-mixed, pure and homogeneous printing ink compounds having the desired color impression of the first, second and/or third ink strip must be used for the corresponding ink strips of the pattern 22, 23, etc., in question. Alternatively, each pattern of the same kind of ink strips, simultaneously printed by means of the same method step, can also consist of a pixel pattern or print dot pattern, wherein the color composition and the mixing ratio of the corresponding print dots (particularly those having different colors), which make up an ink strip, is such that all the first ink strips 10 as a whole (by means of visual melding of the colors of all the print dots involved) yield precisely the intended first color of the pattern 22. The same holds true analogously for the second and, if applicable, third ink strips 20 and 12 printed subsequently, which also do not have to be ready-mixed spot colors. Whether the ink strips are printed as print dot patterns composed of spot colors or as a print dot pattern composed of print dots composed of multiple different basic colors C, M, Y, K depends on the configuration of the printer of the digital printing method.
In addition to or in place of spot colors or different basic colors C, M, Y, K (for melding of differently colored print dots to produce the desired strip color), special inks can furthermore be used to form the ridges and/or ink strips, as long as they can be printed using the corresponding digital printing technique, for example, safety inks having further effects, for example fluorescent inks, infrared inks, inks for marking (taggants), as well as special inks that shimmer or shine in silver or different colors, for example for a pearly shine, etc. The color-shift effect can, in particular, also be observed in the UV or infrared range, for example.
The desired color-shift effect can furthermore be controlled by the geometry of the relief structure 21; for example, the height of the ridges, which is essentially determined by the relief structure that is formed in step a), can be selected to be between 40 and 100 μm, preferably between 60 and 70 μm. The distance p ([in English:] pitch distance) between ridge centers of the ridges 5 from one another can be selected to be between 150 and 400 μm, in particular between 250 and 350 μm, for example. The proportion of the distance p between ridge centers can amount to between 60 and 85% of the distance p between ridge centers. However, even very narrow ridges can be formed at a great distance from one another, for example ridges having a width of 100 μm and with gaps having a gap width g of 300 μm. First and second ink strips 10; 20, each having a width of 200 μm, i.e. approximately half the distance p between ridge centers, can be printed onto this pattern. In this regard, the relief height can amount to 50 μm, for example. Furthermore, any desired combinations of two, three or even more different colors in the form of colored ink strips 10, 20, 12, . . . can be combined with one another in the part of the print image 25 that is structured as a color-shift surface 30.
As has been mentioned, the color-shift effect can also be observed or measured outside of the visible spectrum, for example with the aid of fluorescent inks, infrared inks, up-converters, etc. (see above). The term color-shift effect and of “color” of the corresponding ink strips (and, if applicable, the ridges 5) therefore also includes qualities and properties of the corresponding isotropic printing inks 5a, 10a, 20a that are wavelength-related or spectrum-related, if applicable that can only be determined using measurement technology, which can only be detected with the aid of additional illumination (UV, IR) or measurement devices. As a result, even hidden security features can be implemented as a function of angle by means of the imprint 25. For example, a standard color (CMYK process color) can be used for the first ink strips 10, and a fluorescent color can be used for the second ink strips 20, or vice versa, so that the color impression of the color-shift surface that is dominated by the standard color under normal daylight or interior light contrasts with the color impression dominated by the fluorescent color under UV light. Furthermore, inks that appears to have a different color under infrared light can be used, for example in that the first ink strips 10 composed of a pigment-based printing ink for infrared-transparent black (black free of carbon black; “[in English:] photo black”) is used, but for the second ink strips 20, a pigment-based printing ink that yields an infrared-absorbing black (black that contains carbon black; “[in English:] pigment black”) is used. While the strip pattern on the relief structure formed in this way looks black under daylight or normal interior light, a shift effect can be observed in the near infrared range, using an infrared camera, for example, because depending on the line of sight, an infrared-reflecting relief line that appears white or at least light in color becomes visible through the space between two infrared-absorbing lines that appear black or at least dark.
The color-shift surface, formed from ridges and ink strips, can be refined or coated with transparent varnish in a final step, for mechanical protection and to increase the degree of gloss.
All of the characteristics of the respective embodiments described up to this point can be combined both individually and in combination with one another with each of the figures and further embodiments that will still be described below; for this reason, repetition will be refrained from.
Alternatively, according to
According to a modification shown in
Furthermore, according to
In this manner, the surface of the ridges 5 of the relief structure 21 can be divided into three print zones, for example, which correspond to the first side flanks 1, the center regions 3, and the second side flanks 2.
In
The surface 50 remains unchanged in color in the gap surfaces 4 not covered by the ridges, which surfaces are square or rectangular here; their color can be, for example, black or white or some other additional color that deviates from those of the ridge side flanks. The first ridges 5, which run vertically in the top view, possess first side flanks 1, which bring about a color effect of the overall color-shift surface 30 as yellow (Y; [in English:] yellow) when viewed at a slant approximately from their normal line direction, whereas the overall color impression of the color-shift surfaces from the viewing direction approximately perpendicular to the second side flanks 2 is predominantly influenced by the second side flanks 2 and the second ink strips 20 arranged on them, and thereby a color impression as cyan (C) occurs, for example. The color transition between them corresponds to a change in the viewing direction within the yz section plane (at the top in
The production of special color-shift surfaces 30 by means of printing technology, as proposed in this application, can be used, among other things, for implementing motifs 7 that become visible or invisible, depending on the viewing angle.
According to
Alternatively, according to
Furthermore, according to
According to
Alternatively, according to
Since the label 62 is a color-shift label, the first label section appears as cyan to the camera 44, for example, while the second label section, which has a different orientation, appears in a contrasting color such as yellow, for example. This can be utilized for automatic detection of the position of the packaging on a transport belt 41, as shown.
Furthermore, simply by gluing the imprinted label around the edge of an object, a self-aligning, self-adjusting color change of the label occurs relative to the bending line or the edge around which the label was glued (for example on outer edges of any desired objects 42 or packaging 43), and thereby the bending edge of the label 62 automatically appears to the human eye (conceptually in the same position as the video camera 44 in
In
Furthermore, in
Here, too, the second color-shift motif 7′ is not a motif that is simply inverted as compared with the first color-shift motif 7, but rather can be designed completely independently of it and can therefore assume surface dimensions and outlines (here, for example, in the form of the letter T instead of U) that can be selected completely independently. In this regard, a first selection of ridges 5 can have corresponding (first) length sections in which not only is the first side flank 1 overprinted with the corresponding first ink strip 10, but also the second side flank 2 is overprinted with the corresponding second ink strip 20, in
Such a color-shift surface 30, as it is illustrated as an example in
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2018 106 966.9 | Mar 2018 | DE | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2019/057440 | 3/25/2019 | WO | 00 |
