WO2003039888A1 - Multilayer body with a first laser-sensitive layer and a second laser-sensitive layer and method for generation of a multilayer image in said multilayer body - Google Patents

Abstract

A multilayer body is disclosed, comprising two laser-sensitive layers (4, 32). Said multilayer body is a laminated body of overlay films (30, 32), inlays (90, 90) and further overlay films (30,30). The upper overlay film (30) comprises a layer structure applied to the underside thereof by application of a hot-stamp film. The layer structure comprises a lacquer layer (50), a reflection layer (5r), a laser-sensitive layer (4), a background layer (5) and an adhesive layer (6). A diffraction and/or hologram structure (5b) is embodied in the lacquer layer (5c), the reflection layer (5r) and the laser-sensitive layer (4). The second laser-sensitive layer is embodied as a carbon-doped overlay film (32). A laser-induced, preferably coloured image component can be generated in the upper laser-sensitive layer (4) and a further, preferably grey-scale image generated in the carbon-doped laser-sensitive layer (32) thereunder by means of laser treatment. A laser-induced multilayer image can thus be produced.

Description

Multi-layer body with a first laser-sensitive layer and a second laser-sensitive layer and method for producing a multi-layer image in such a multi-layer body

The invention relates to a multi-layer body as a multi-layer film, preferably transfer film or laminating film or as a layer composite formed from laminated at least one overlay film and preferably inlet, with a laser-sensitive layer. The invention further relates to a method for producing a multilayer image in such a multilayer body.

Bodies are known which consist of laser-sensitive material. For example, from WO 96/35585 different versions of plastic bodies are known, namely as a solid body or coating, each containing a mixture of different pigments. Color treatment is performed on the plastic body or in the coating by laser treatment. WO 98/19868 describes a process which works with special yellow, magenta and cyan pigments which can be activated by UV light in a first step and are only bleached in a subsequent second step.

DE 199 55 338 also discloses a method for producing color markings by laser treatment using a mixture of cyan pigment, magenta pigment and yellow pigment, these pigments being selectively bleached by red laser light, green laser light and blue laser light. This method is described for the use of a plastic body which is made of a material with the pigment mixture in question.

From WO 94/12352 it is also known to produce colorful color markings on a plastic body that contains a pigment mixture and can be designed as a solid body and as a coating by laser treatment with different wavelengths. The color is formed in that the pigments change their color due to a color change during laser treatment. EP 0 327 508 discloses a process in which a laser-sensitive dye A and a laser-insensitive dye B are contained in two separate layers one above the other or alternatively in a common layer and the dye A is bleached by laser treatment. With the laser treatment, a color marking is thus obtained which, however, only contains a color change in the dye A, that is to say that only a maximum of two-color image is obtained.

A method is known from EP 0 190 997 B1, in which in a plastic layer designed as a coating of a metal plate or in a Plastic plate an additive is included, which should change color during laser treatment, either by changing color from one color to another or by converting it to black.

From DE 37 38 330 A1 a laser marking process for use in surface pigment coating is known, wherein pigments of the pigment coating change their internal molecular structure at different temperatures and provide different colors. The specific surface temperatures are achieved locally with the laser radiation, whereby colored laser markings are obtained.

GB 2 240 948 A also describes the laser marking of identity cards. Laser marking is done here by removing different layers of color. The laser marking obtained appears as a colored marking.

DE 41 31 964 A1 describes laser inscriptions on a multilayer film with a metal layer and hologram structure. Labeling is achieved by destruction of the metal layer carrying the hologram in certain areas.

A hot stamping foil with a hologram structure is known from EP 0 420 261, which is individualized via laser treatment for the purpose of security against forgery. The laser beam is used to change the material or color or to remove partial areas in the layer structure of the film.

EP 0 219 011 B1 describes a special method for laser marking identification cards. In this process, black markings are made in various transparent layers of the card using the laser. In Paralax images are obtained in this way with the interacting transparent layers.

The invention has for its object to provide a multi-layer body which ensures particularly high security against forgery by laser treatment and enables special laser-induced markings. The object of the invention is to provide a method for producing new types of complex laser-induced markings.

The invention solves the problem with the multilayer body according to claim 1 and the method for producing a laser-induced multilayer image in such a multilayer body according to method claim 9.

The fact that the multilayer body has a first laser-sensitive layer and a second laser-sensitive layer, in which differently designed laser-induced image components can be generated, creates the possibility of generating a complex composite laser-induced multilayer image. In the laser-sensitive layer with the laser-sensitive colorant, it becomes possible to generate a colorful laser-induced image component which can be designed as a multicolor or full-color image when using a corresponding laser-sensitive colorant mixture of two or three bleachable colorant components. Another laser-sensitive material can be used in the other laser-sensitive layer, ie a different colorant mixture or also a material doped with carbon or carbon black, in which a different color marking, preferably multi-colored, is used in the laser treatment Color image or a black marker, preferably a grayscale image can be generated.

The various laser-sensitive layers can be arranged more or less, preferably overlapping one another in some areas, and more or less, if necessary, can only be made transparent in some areas. With specific control of the laser treatment of the different laser-sensitive layers, specific different image components can be generated in a laser-induced manner, which can work together to form an arbitrarily complex multilayer image.

Multilayer images with particularly interesting optical effects are possible if, in addition to the several laser-sensitive layers, the layer structure also contains diffraction and / or hologram structures, which e.g. result in different optical effects in different viewing angles in connection with the different laser-induced image components arranged in the different layers.

Preferred exemplary embodiments are explained in more detail below with reference to the attached figures.

In order to be able to produce the desired laser-induced marking as selectively as possible in the individual laser-sensitive layers during laser irradiation, the laser-sensitive layers can be formed in such a way that they are sensitive only under certain laser conditions, for example only at a certain laser wavelength or angle of incidence. In addition, a special background layer can be arranged as an intermediate layer between the laser-sensitive layers, which acts like a barrier layer for certain layers Laser radiation, for example depending on the laser wavelength, the angle of incidence etc. In preferred embodiments, this background layer, which acts as a barrier layer, can also be formed only in regions, that is to say only under a partial region of the laser-sensitive layer arranged above it, preferably only in an region which lies below the laser-induced marking. By arranging such barrier and intermediate layers only in regions, special additional effects can also be obtained, namely that, for example in laser irradiation in regions with an intermediate layer, only laser-induced marking in the upper laser-sensitive layer and then in regions without an intermediate layer in both laser-sensitive layers, different laser-induced layers lying one above the other Markers can be obtained as combined markers. Particularly interesting optical effects are obtained when the laser-sensitive materials of the layers are different, so that, for example, a color marking is generated in one layer and a black marking, preferably a grayscale image, is generated in the other layer.

Show it:

1 shows a sectional view of an exemplary embodiment of a transfer film with two laser-sensitive layers;

FIG. 2 shows a sectional view of an exemplary embodiment of a laminating film with a structure corresponding to that of the transfer film in FIG. 1;

Fig. 3 is a sectional view of another embodiment of a

Transfer film with two laser-sensitive layers with a modified layer sequence; Fig. 4 is an exploded view of a laminated body made of several overlay foils and inlets, two laser-sensitive layers also being present.

Fig. 5 is a sectional view of another embodiment

Fig. 6 is a sectional view of the embodiment in Fig. 5 for

Illustration of laser treatment

Fig. 7 is a plan view of a laser-induced image of the

5 and 6

The hot stamping foil shown in FIG. 1 is a multilayer body with two laser-sensitive layers 4, which are formed on both sides of a reflection layer 5r. By laser treatment of this multilayer body, different laser-induced markings can be made in the laser-sensitive layers, so that a composite laser-induced multilayer image is generated. The same applies to the laminating film shown in FIG. 2, which corresponds in its layer structure to the transfer film in FIG. 1. The same applies correspondingly to the hot stamping foil shown in FIG. 3, which has a modified layer structure, but also has two laser-sensitive layers 4, 4a. The laminated body shown in FIG. 4 also has two laser-sensitive layers, namely layer 4, which is arranged on the underside of upper overlay film 30 in a hot stamping film applied there, and layer 32, which is designed as a separate doped overlay film. The structure of the individual multilayer bodies in connection with the figures is described in detail below, as is the laser treatment with which a laser-induced image component designed as a full-color image can be generated. The method is also described as to how a grayscale image can be generated as a laser-induced image component in another laser-sensitive layer.

The layers in the film in FIG. 1 are in the following order:

Backing layer 1, release layer 2, protective layer 3, laser-sensitive layer 4, reflection layer 5r, laser-sensitive layer 4, additional lacquer layer 7 and adhesive layer 6. The laser-sensitive layers 4 formed on both sides of the reflection layer 5r can be identical, ie the reflection layer is then in this laser-sensitive overall layer arranged. However, the laser-sensitive layers can also be designed differently. A diffraction structure 5b is formed in mutually adjacent regions of the laser-sensitive layer 4 and the reflection layer 5r. Alternatively, structure 5b can also be designed as a hologram structure. In the exemplary embodiment, increased security against forgery results from the fact that two laser-sensitive layers adjoin the diffraction or hologram structure, which can be of the same or different design. The lacquer layer 5, which is optional, is designed here as a transparent layer or as a light backup layer. Alternatively, the lacquer layer 5 and the adhesive layer 6 can also be omitted and the second laser-sensitive layer 4 shown in FIG. 1 under the reflection layer 5r can be designed as a laser-sensitive adhesive layer. Fig. 2 shows an embodiment of a laminating film with an order of the layers corresponding to the structure of the hot stamping film. It comprises a so-called overlay film 30, a laser-sensitive layer 40, an intermediate layer 50 forming a background layer, which is optional, and an adhesive layer 60, which is also optional. The laser-sensitive layer 40 is arranged in a corresponding manner like the laser-sensitive layer 4 on both sides of the reflection layer 50r, in a corresponding manner as in FIG.

1 it is provided that the two laser-sensitive layers are designed differently or identically. In a manner corresponding to that of the hot stamping film in FIG. 1, a diffraction and / or hologram structure 50b is also provided in the laminating film in FIG. 2, likewise in the area of the two laser-sensitive layers 40 and the reflection layer 50r in between.

During the laser treatment of the hot stamping foil in FIG. 1 or the laminating foil in FIG.

2, laser-induced image components, which are present in different layers, are produced in the laser-sensitive layers lying one on top of the other. The laser treatment is preferably carried out after the film in question has been applied to the substrate, ie by irradiating the film applied to the substrate from the outside. Alternatively, however, it is also possible for the film to be laser-treated before being applied. In this case, the laser irradiation can take place from different sides of the film.

Different laser-induced image components in the superimposed laser-sensitive layers are obtained in that the laser-sensitive layers have different laser-sensitive material and thus the laser-induced under different material-specific laser conditions Components can be generated in the different laser-sensitive layers. Alternatively, it is also possible to treat only the upper or the lower laser-sensitive layer by varying the angle of incidence. This possibility arises from the fact that the reflection layer 5r is transparent to the laser radiation in the case of perpendicular radiation, but is not or less transparent when irradiated at an acute angle. There are also differences for the transmission of radiation through the diffraction structure, so that the upper laser-sensitive layer can be treated separately by appropriately adjusting the angle of incidence of the laser radiation in order to generate a specific laser-induced image component there without the radiation reaching the lower laser-sensitive layer. In this way, it is also possible to treat the laser-sensitive layers lying one above the other separately, even if they are made of the same laser-sensitive material.

In the exemplary embodiment of the hot stamping foil in FIG. 3, two laser-sensitive layers 4, 4a are also provided. However, these are separated from one another by a background layer 5 arranged between them. The background layer is a layer which is highly reflective for the laser radiation used in laser treatment. In addition, the layer is not transparent and absorbent with regard to the non-reflected portion of the laser radiation, so that during laser treatment to generate the laser-induced marking in the upper laser-sensitive layer 4, no laser radiation enters the laser-sensitive layer 4a underneath. The background layer 5 is arranged under the laser-sensitive layer 4 exclusively in the area in which a laser-induced image component is to be generated in the laser-sensitive layer 4. In the area outside, the background layer 5 is not formed, ie in this area there is a for the laser radiation-permeable material or preferably the laser-sensitive material of the lower laser-sensitive layer 4a is arranged. In those areas in which the background layer is not formed, the laser-induced image component can be generated in the lower laser-sensitive layer 4a by laser irradiation.

The two laser-sensitive layers 4, 4a are preferably formed from different laser-sensitive material, for which different material-specific laser treatment conditions apply. In this way, it is also possible that a laser-induced change in the upper laser-sensitive layer 4 does not take place simultaneously in the lower laser-sensitive layer 4a during the generation of the laser-induced marking.

To protect the substrate from incident laser light, a further background layer 5a is arranged on the underside of the lower laser-sensitive layer 4a. This background layer 5a prevents laser radiation from reaching the substrate during the laser treatment.

4 is a body laminated from various overlay foils and inlets. The upper overlay film has a layer structure on its underside, consisting of a lacquer layer 5c, a reflection layer 5r, a laser-sensitive layer 4, a background layer 5 and an adhesive layer 6. In the lacquer layer 5c, the reflection layer 5r and the laser-sensitive layer 4 there is a diffraction - And / or hologram structure 5b formed.

These layers applied to the underside of the overlay film 30 are layers of a hot stamping film which are there on the underside of the overlay film is applied. The overlay film 32 arranged under the overlay film 30 is designed as a laser-sensitive film. It therefore forms a second laser-sensitive layer. In the exemplary embodiment shown, the laser-sensitive material is designed as carbon and / or soot-doped material. It is material which carbonizes when exposed to laser, so that a laser-induced image component is blackened in this layer formed by the overlay film 32. A grayscale image can be generated by varying the laser conditions, for example varying the laser power and / or laser wavelength.

An inlet 90 is arranged below the doped overlay film 32 and a further inlet 90 below it. These inlets can preferably be made of paper material, but also of plastic material, preferably as inlet foils. An overlay film 30 is applied to the underside of the lower inlet 90 and a further overlay film 30 is applied thereon.

The laser treatment for generating the different laser-induced image components in the laser-sensitive layers 4 and 32 takes place in exemplary embodiments in a manner corresponding to that in FIGS. 1 to 3.

In the following it will be described in detail how a full-color image component can be produced in a laser-sensitive layer, which consists of a colorant mixture of three laser-sensitive colorant components, by laser-induced bleaching. The laser-sensitive material is a three-component mixture with a cyan pigment component, a magenta pigment component and a yellow pigment component. In the first step of bleaching, a blue or green or red color marking is produced by irradiating this area with a specific laser wavelength with which a specific pigment component is bleached.

In order to produce the color blue, only the yellow pigment component may be bleached. Blue laser light is used for this. A certain minimum intensity is required for bleaching. Furthermore, a certain pulse duration must not be exceeded. In order to obtain a green color marking in the first step, only the magenta pigment component may be bleached. Green laser light is used for this. In order to obtain a red color marking in the first step, only the cyan pigment component may be bleached. Red laser light is used for this.

In order to produce a color marking in the color cyan or magenta or yellow at this point, this point is laser-treated in a second step, with a laser wavelength with which one of the pigment components not yet bleached at this point is bleached. If a blue color marking was created in the first step, the cyan pigment component and the magenta pigment component are unbleached at this point. In order to produce the color cyan at this point, the magenta pigment component must be bleached in this second step. This is done with green laser light. This results in a cyan marking at this point.

If a magenta-colored marking is to be obtained in the second step instead of this cyan-colored marking, the blue color marking generated in the first step must be treated with red laser light. This bleaches the cyan pigment at this point, leaving the magenta pigment unbleached at this point. This results in the magenta marking at this point.

Correspondingly, a green color marking generated in the first step, which is formed from the unbleached cyan pigment and yellow pigment remaining there, can be used to produce a cyan marking or a yellow marking, by treatment with blue laser light or red laser light.

Correspondingly, a red color marking generated in the first step can be converted into a yellow or magenta colored marking in the second step, by laser treatment in the second step with green laser light or blue laser light.

In order to obtain a transparent area at the point treated in the first and second step, i.e. To obtain a white spot when the background layer 5 is white, in a third step this spot must be treated with a laser beam whose wavelength is set in such a way that the pigment component remaining unbleached at this point after the second step is bleached, i.e. the yellow color marking must be bleached with blue laser light, the magenta colored marking with green light and the cyan colored marking with red laser light.

In the same way, further adjacent locations are then treated in the laser-sensitive layer 4 in order to produce further color markings in the layer 4 of the embossing foil. In this way, a full color image can be produced. Laser treatment can also be used to generate color markings or a full-color image in the colorant or the colorants in the laser-sensitive layer by color change. The laser treatment can be carried out in a corresponding manner with successive process steps. Pigments can be used as colorants, ie coloring substances. These are mostly insoluble and are usually inorganic substances. However, soluble, organic colorants are also usually suitable as colorants. The color change occurs in each case under specific laser conditions, which are then used in the laser treatment in the individual steps.

In a corresponding manner, the bleaching and color conversion process described can also be used if the laser-sensitive material consists of only one or two colorant components. Other colorant components and also other laser conditions, in particular other laser wavelength ranges, can also be used in the laser treatment.

The laser treatment is usually carried out on the film applied to the substrate. Alternatively, however, it can also take place before the film is applied by irradiating the film alone, in particular when the protective layer 3 or some other layer, for example a background layer 5, is used as a layer which is not or only partially transparent for laser radiation or one for laser radiation certain wavelength range non-transparent layer is formed or an additional UV-absorbing protective layer is provided. The laser treatment then takes place, preferably before the film is applied, by placing the laser beam on the back of the film, ie on the lower one Background layer 5 or the adhesive layer 6 is directed and thus the laser-sensitive layer 4 is thus treated from the other side in order to generate the color markings in the same way. In these applications, the background layer 5 and the adhesive layer 6 are transparent or at least partially transparent for the laser radiation in question.

The recipe for the layers used in the exemplary embodiments is as follows:

Peeling layer 2 (separation layer):

Toluene 99.5 parts

Ester wax (dropping point 90 ° C) 0.5 parts

Protective layer 3 (protective lacquer layer):

Methyl ethyl ketone 61.0 parts

Diaketone alcohol 9.0 parts

Methyl methacrylate (Tg = 122 ° C) 18.0 parts of polyethylene dispersion (23% in xylene) (softening point 140 ° C) 7.5 parts

High molecular weight dispersing additive (40%, amine number 20) 0.5 parts

Extender (aluminum silicate) 4.0 parts

Laser-sensitive layer 4 (first colored lacquer layer):

Methyl ethyl ketone 34.0 parts

Toluene 26.0 parts Ethyl acetate 13.0 parts

Cellulose nitrate (low viscosity, 65% in alcohol) 20.0 parts

Linear polyurethane (mp.> 200 ° C) 3.5 parts

High molecular weight dispersing additive (40%, amine number 20) 2.0 parts e.g. Pigment Blue 15: 4 0.5 parts

Pigment Red 57: 1 0.5 parts

Pigment Yellow 155 0.5 parts

Background layer 5 (second colored lacquer layer):

Methyl ethyl ketone 40.0 parts

Toluene 22.0 parts

Ethylene vinyl acetate terpolymer (mp = 60 ° C) 2.5 parts

Polyvinyl chloride (Tg: 89 ° C) 5.5 parts

Polyvinyl chloride (Tg: 40 ° C) 3.0 parts

Dispersing additive (50%, acid number 51) 1.0 part

Titanium dioxide (d = 3.8-4.2 g / cm ³ ) 26.0 parts

Adhesive layer 6:

Methyl ethyl ketone 55.0 parts

Toluene 12.5 parts

Ethanol 3.5 parts

Polyvinyl acetate (softening point 80 ° C) 6.0 parts

Butyl / methyl methacrylate (Tg: 80 ° C) 8.0 parts

Ethyl methacrylate resin (Tg: 63 ° C) 3.0 parts

Methacrylate copolymer (Tg: 80 ° C) 5.0 parts Unsaturated polyester resin (softening point 103 ° C) 3.5 parts

Silicon dioxide 3.5 parts

Finally, the subject matter of the invention is briefly explained again with its essential advantages and functions in connection with FIGS. 5 to 7:

A multi-layer data carrier is created which contains at least two different laser-sensitive layers, one laser-sensitive layer 1 preferably being laser-personalizable in multiple colors and another laser-sensitive layer 2 preferably being monochrome laser-personalizable.

For this purpose, the laser-sensitive materials can be set in such a way that a marking can be achieved in both materials by means of laser radiation of a defined wavelength and intensity.

The laser-sensitive layers are preferably superimposed over part of the area.

Between these laser-sensitive layers, a layer 3 that is not transparent to the laser radiation is arranged over part of the surface. This optical barrier layer 3 is a reflective layer, in a preferred embodiment a diffusely reflective layer. It preferably contains a sufficient proportion of white pigment and thus prevents the laser light from penetrating into the layers below. This is the prerequisite for the arrangement according to the invention of the different laser-personalizable layers. Separated by the optical barrier layer, the multi-colored laser-personalizable layer 1 can lie above the monochrome laser-personalizable layer 2 without the color laser personalization there is an unintentional carbonization in the underlying monochrome laser-personalizable layer 2.

The optical barrier layer can be installed as an additional layer in various ways. The optical barrier layer is preferably applied to one of the cover layers in decorative printing.

The multi-layer data carrier described can be produced using one of the following methods:

Injection molding process, preferably multi-component injection molding or in-mold

Decoration,

Lamination of film composites,

Lamination of mixed structures, preferably made of paper and plastic films,

Coating of paper carriers or plastic carriers,

Printing on paper carriers or plastic carriers,

Foil transfer process on paper or plastic carriers, or a combination of the methods mentioned.

1 shows a preferred structure of a data carrier.

The optical barrier layer can also be arranged above the laser-sensitive layers and thus cause partial coverage of the laser-sensitive layers. This optical barrier layer is then preferably designed as a decorative print, preferably in the form of line patterns such as guilloches. The image information of the decor print is then, after the laser personalization, into the laser-personalizable layers transmit that here the laser-personalized image information is interrupted by the image information of the optical barrier layer.

Since the graphic element generated with the help of color laser personalization appears as part of a document in the sense of a color image, security must be provided against falsification. There is a risk of falsification by separating the color image from the document and replacing it with another one. There is a high level of protection against falsification when graphic elements of laser personalization combine the color image with other elements of the document in the sense of a photo-integrated background.

An integration of the different features: color laser personalization and laser personalization in grayscale in a data carrier takes place in such a way that the different laser-personalizable layers are only partially superimposed on one another. This results in different options for integrated color laser personalization.

6 shows the possibilities of laser marking on a preferred structure of a data carrier.

If the laser personalization takes place at the point where only the monochrome laser-personalizable layer 2 is located, a monochrome black marking 9 is generated.

The laser personalization takes place at the point where only the multi-colored layer 1 that can be personalized by laser is not above that for the laser radiation permeable layer 3 and lies above the monochrome laser-personalizable layer 2, a multicolored marking 8 is generated.

If the laser personalization takes place at the point where only the multi-color laser-personalizable layer 1 lies above the monochrome laser-personalizable layer 2 without being separated by the optical barrier layer 3, a superimposition of multi-colored 9 and monochrome black marking 8 is generated. This marking is also multi-colored, but due to the opposing effects of bleaching and blackening it appears darker than the pure, multi-colored marking.

FIG. 7 shows how integrating picture elements can be achieved by combining laser personalization in color with classic grayscale lasering. For this purpose, the absorption of the laser-personalizable layers is set such that the laser power required for bleaching is sufficient to carbonize in the monochrome laser-personalizable layer additionally used in the document. If the monochrome laser-personalizable layer 2 lies under the multi-color laser-personalizable layer 1 and if this is only partially covered by the optical barrier layer 3, this structure allows image elements such as lines or alphanumeric characters which are lasered beyond the boundary of the optical barrier layer 3, cause the background to carbonize. In this way, continuous image elements can be generated by changing the type of marking within the element. If the boundary of the optical barrier layer 3 coincides with the boundary of the multi-colored laser-personalizable layer 1, there is a change from colored to achromatic. This continuous image information has an integrating effect. Integrating image elements are also possible, which are achieved by combining laser personalization in color with other graphic elements. The transparency of the multi-color laser-personalizable layer increases with increasing bleaching. This allows layout elements such as guilloches, which are printed on layers below the multi-color laser-personalizable layer, for example on the core material, to appear in the color image after the color laser. Thus, picture elements, such as printed lines, which are only partially covered by the multi-colored laser-personalizable layer 1, appear as integrating elements after the color laser personalization. Integrating elements such as these, which extend over the edge of a personalized feature, make it very difficult to falsify the data carrier.

Another feature of the invention is that the additional layer allows a targeted adjustment of the brightness of the background, regardless of the carrier material used. For example, an additional effect can be achieved by using optical brighteners or by using pigment additives.

It follows from all of this that the subject of the invention is a multi-layer data carrier which contains at least two different laser-sensitive layers, one laser-sensitive layer being laser-personalizable in multiple colors and another laser-sensitive layer being monochrome laser-personalizable. These laser-sensitive layers are superimposed over part of the area, and preferably the multi-color laser-personalizable layer lies over the monochrome laser-personalizable layer. The laser-sensitive layers can be designed such that in a laser marking step with the same wavelength and energy Laser radiation can be achieved in both the multicolor laser-personalizable layer and in the monochrome laser-personalizable layer.

A layer which is not transparent to the laser radiation is preferably arranged at least over part of the area between these laser-sensitive layers.

The layer which is not transparent to the laser radiation is preferably a reflective layer, which in a preferred embodiment can be a diffusely reflective layer and contains a sufficient proportion of an additive which reflects or scatters the laser light.

The laser personalization can take place in an upper laser-personalizable layer, preferably in a multi-color laser-personalizable layer, without a laser-personalizable layer lying below this layer being changed by the laser radiation, in that the laser personalization takes place where the laser-sensitive layers are provided by a layer that is not transparent to the laser radiation are optically separated from each other.

Laser personalization can be carried out with a laser beam both in an upper laser-personalizable layer, preferably in a multi-color laser-personalizable layer, and in a laser-personalizable layer lying below this layer, in that the laser personalization takes place where the laser-sensitive layers are not transparent to the laser radiation Layer are optically separated. The laser personalization can be carried out with a laser beam both in an upper laser-personalizable layer, preferably in a multi-color laser-personalizable layer, and in a laser-personalizable layer lying below this layer, in that the laser personalization takes place in such a way that graphic image elements over the partial areas of the respective laser-personalizable Layer, preferably the multi-colored laser personalizable layer, are arranged so that a change from multi-colored to monochrome is achieved within the picture element.

The laser personalization can be carried out with a laser beam in a laser-personalizable layer, in that the laser personalization takes place in such a way that graphic image elements are arranged beyond the partial areas of the optical barrier layer arranged above the laser-personalizable layer, so that an interruption of the so in the laser-personalizable layer generated graphic picture elements is achieved. Printed elements, such as guilloches, can preferably be arranged above the laser-personalizable layer as interrupting elements in the sense of an optical barrier layer.

The laser personalization can be carried out with a laser beam in a multi-color laser-personalizable layer, so that design elements, preferably printed elements such as guilloches, which are printed on layers below the multi-color laser-personalizable layer, for example on the carrier material, appear after the color laser in the color image, by increasing the transparency of the multi-colored laser-personalizable layer through the process of laser marking. An important advantage of the invention is that the known laser personalization in gray levels is combined with the new method of color laser personalization. The security of documents can be significantly increased by the combination in the manner described.

Claims

claims

1. multilayer body,

designed as a multi-layer film, preferably transfer film or laminating film, or as a laminate laminated from at least one overlay film and inlet,

with a first layer comprising laser-sensitive material - hereinafter referred to as the first laser-sensitive layer - and a second layer comprising laser-sensitive material - hereinafter referred to as the second laser-sensitive layer - which are at least partially overlapping with one another,

being provided

a) that the laser-sensitive material of the first laser-sensitive layer has a colorant which can be bleached by the action of laser radiation or changes its color by the action of laser radiation with a change in color; and b) that the laser-sensitive material of the second laser-sensitive layer has a colorant which can be bleached by the action of laser radiation or changes its color due to the action of laser radiation with a color change, or the laser-sensitive material of the second laser-sensitive layer has a doped material which can be blackened by the action of laser radiation is.

2. Multi-layer body according to claim 1, characterized in that on a side of the substrate facing at least one of the laser-sensitive layers at least in a partial area a reflective and / or non-transparent or largely non-transparent and / or absorbent background layer is arranged for the laser radiation used.

3. Multi-layer body according to claim 2, characterized in that the background layer is arranged between the first laser-sensitive layer and the second laser-sensitive layer.

4. multilayer body according to claim 2 or 3, characterized in that the background layer is transparent to light in the visible spectral range and / or is transparent or not transparent to laser radiation only certain laser conditions, in particular only certain laser wavelength ranges and / or angle of incidence, preferably for laser radiation, the for the Generation of the laser-induced marking is used in the laser-sensitive layer, is transparent or not transparent.

5. Multi-layer body according to one of the preceding claims, characterized in that the laser-sensitive material of the first laser-sensitive layer differs from the laser-sensitive material of the second laser-sensitive layer, preferably in such a way that the specific laser processing conditions of the two materials differ.

6. Multi-layer body according to one of the preceding claims, characterized in that the laser-sensitive colorant is formed as a mixture of at least two, preferably three, laser-sensitive colorant components,

it applies to each of these two or three laser-sensitive colorant components that under the laser conditions specific to one colorant component the other colorant components cannot be changed or can essentially not be changed, preferably bleached.

7. Multi-layer body according to claim 6, characterized in that the mixture has two or three of the following colorant components:

Cyan colorants, magenta colorants, yellow colorants

8. Multi-layer body according to one of the preceding claims, characterized in that the doped material, which can be blackened when exposed to laser radiation, is formed as a carbon and / or soot-doped material.

9. A method for generating a multilayer image in a multilayer body, preferably according to one of the preceding claims, characterized in that the multilayer image from a plurality of laser-induced

Image components is composed by a first laser-induced image component by the action of

Laser radiation is produced under first laser conditions in a first laser-sensitive layer of the multilayer body and a second laser-induced image component by the action of

Laser radiation under second laser conditions is produced in a second laser-sensitive layer of the multilayer body.

10. The method according to claim 9, characterized in that the first laser conditions and the second laser conditions are designed differently, preferably with regard to laser wavelength and / or radiation intensity and / or angle of incidence.

11. The method according to claim 9 or 10, characterized in that the first laser-induced image component and the second laser-induced image component are generated at different times or at the same time.

12. The method according to any one of claims 9 to 11, characterized in that at least one of the laser-induced components is designed as a color marking.

13. The method according to any one of claims 9 to 12, characterized in that at least one of the laser-induced image components is designed as a black marking, preferably gray-scale marking.

14. The method according to any one of claims 9 to 13, characterized in that the laser-induced image component is introduced in a region of the laser-sensitive layer, which is not transparent and / or over a reflective for the laser radiation used and / or for the non-reflected portion of the laser radiation absorbent background layer is arranged.

15. The method according to any one of claims 9 to 14, characterized in that the laser-induced image component is formed as a multicolor image, preferably a full-color image, by laser-induced bleaching or laser-induced color change.

16. The method according to any one of claims 9 to 15, characterized in that the laser-induced image component is preferably formed as a grayscale image by laser-induced blackening.

17. The method according to any one of claims 9 to 16, characterized in that the laser-sensitive material is formed as a mixture of at least two, preferably three laser-sensitive colorant components, wherein each of the two or three colorant components can be changed by laser, preferably for the component specific laser conditions is bleachable, it being true for each of the three colorant components that under the laser conditions specific for one colorant component the other or both other colorant components are not or are essentially not bleachable.

18. The method according to claim 17, characterized in that a colorant mixture of two or three of the following colorant components is used:

Cyan colorants, magenta colorants, yellow colorants, it being preferably provided that for bleaching the cyan colorants red laser light, green laser light is used to bleach the magenta dye and blue laser light is used to bleach the yellow dye.