EP1747905A2 - Security feature and method for producing it - Google Patents

Abstract

The production process is for a document having a carrier layer (20) and a covering layer (26) Some regions (34) are free of coating. A laser wavelength it identified to bring in the coated regions. The carrier layer with opposite first and second (24) main surfaces is prepared. The absorbent covering layer (26) is applied, followed by a mask (28) defining the coating-free regions. Laser radiation is then applied.

Description

The invention relates to a security element for security papers, documents of value and the like having a carrier film with a cover layer, which in particular has visible in transmitted light coating-free areas in the form of patterns, characters or codes. The invention further relates to a method for producing such security elements.

Security documents are often provided with security elements for the purpose of security, which allow verification of the authenticity of the value document and at the same time serve as protection against unauthorized reproduction. Value documents within the meaning of the present invention are, in particular, bank notes, shares, bonds, certificates, vouchers, checks, high-quality admission tickets, but also other papers which are subject to counterfeiting, such as passports and other identification documents, as well as product security elements such as labels, seals, packaging and the like. The term "value document" in the following includes all such documents and product assurance means.

To increase security and as counterfeit protection, the security elements are often provided with a so-called negative writing. This negative writing is formed for example by metal-free areas in an otherwise continuous metallic coating of the carrier material of the security element.

For the preparation of such metal-free areas is in the document WO 99/13157 describes a washing method in which a translucent carrier sheet is printed with a desired pattern using a high pigment ink. Due to the high pigment content, the ink forms a porous, sublime color after drying. On the printed carrier film is then a thin Coating formed, which only partially covers the color body in the field of paint because of its large surface and the porous structure. The application of paint and the overlying covering layer can then be removed by washing with a suitable solvent, so that recesses are produced in the covering layer in the originally printed regions of the carrier film. By the achievable sharp contours can be introduced by printing a logo, for example, a legible negative writing in the cover layer.

With such a washing process, however, only relatively thin layers can be demetallized. Layer structures with a greater total thickness can often not be demetallized or only partially demetallized, since the layer structure encloses the wash ink in this case too much for a complete washout. The achievable line width for negative writings is also limited to values above about 60 μm by the size of the pigments of the wash ink.

It has also been proposed to generate negative fonts in security elements with a laser. However, this is currently possible only on a stationary film or at very low web speeds. Due to the round geometry of the laser beam and the pulsed mode of operation of the laser no sharp edges can be generated. Rather, the shape of the laser spot of the individual shots is visible at the boundary lines of the introduced patterns or characters. The resolution is limited by the focus diameter, which is typically above 10 μm. If the material is removed with a small focus diameter, the demetallization takes much too long for economical production use.

Based on this, the present invention seeks to propose a method for producing a generic security element, which avoids the disadvantages of the prior art. In particular, the method should combine a fast production suitable for production conditions with high quality and high security against forgery of the generated security elements.

This object is achieved by the method for producing a security element having the features of the main claim. A thus produced security element is specified in the independent claim. Further developments of the invention are the subject of the dependent claims.

• Festlegen einer Laserwellenlänge zum Einbringen der beschichtungsfreien Bereiche;
• Bereitstellen einer Trägerfolie mit einander gegenüberliegenden ersten und zweiten Hauptflächen;
• Aufbringen einer die festgelegte Wellenlänge absorbierenden Deckschicht auf eine erste Hauptfläche der Trägerfolie;
• Aufbringen einer Maske, die die Gestalt der gewünschten beschichtungsfreien Bereiche definiert, auf die erste oder zweite Hauptfläche der Trägerfolie; und
• Beaufschlagen der mit der Maske versehenen Hauptfläche der Trägerfolie mit Laserstrahlung der festgelegten Wellenlänge, um die absorbierende Deckschicht der ersten Hauptfläche lokal abzutragen.

According to a first aspect of the invention, a method for producing a security element of the aforementioned type comprises the method steps:

• Determining a laser wavelength for introducing the coating-free regions;
• Providing a carrier film having opposing first and second major surfaces;
• Applying a predetermined wavelength absorbing cover layer to a first major surface of the support film;
• Applying a mask defining the shape of the desired coating-free regions to the first or second major surface of the carrier film; and
• Subjecting the masked major surface of the carrier film to laser radiation of the predetermined wavelength to locally ablate the absorbent overcoat of the first major surface.

It has proven to be particularly favorable if the carrier film is transparent for the predetermined laser wavelength and the mask is applied to the second main surface of the carrier film, that is to say on the main surface opposite the absorbent covering layer. For example, the mask can then be applied directly after a hologram embossing, so that an excellent registration to the hologram design can be achieved.

Of course, the process steps do not have to be carried out in the stated order. Rather, it may be advantageous if first the mask is applied to the second main surface of the carrier film, and only then the absorbent cover layer is applied to the first main surface of the carrier film.

Preferably, the mask is printed on the first or second major surface of the carrier film.

• Festlegen einer Laserwellenlänge zum Einbringen der beschichtungsfreien Bereiche;
• Bereitstellen einer für die festgelegte Laserwellenlänge transparenten Trägerfolie mit einander gegenüberliegenden ersten und zweiten Hauptflächen;
• Aufbringen einer Maske, die die Gestalt der gewünschten beschichtungsfreien Bereiche definiert, auf eine erste Hauptfläche der Trägerfolie;
• Aufbringen einer die festgelegte Wellenlänge absorbierenden Deckschicht direkt oder über Zwischenschichten auf die Maske; und
• Beaufschlagen der zweiten Hauptfläche der Trägerfolie mit Laserstrahlung der festgelegten Wellenlänge, um die absorbierende Deckschicht der ersten Hauptfläche lokal abzutragen.

In a second aspect of the invention, a generic method comprises the method steps:

• Determining a laser wavelength for introducing the coating-free regions;
• Providing a carrier film that is transparent to the predetermined laser wavelength and having opposing first and second major surfaces;
• Applying a mask defining the shape of the desired coating-free regions to a first major surface of the carrier film;
• Applying a predetermined wavelength absorbing cover layer directly or via intermediate layers to the mask; and
• Subjecting the second major surface of the carrier film to laser radiation of the predetermined wavelength to locally ablate the absorbent covering layer of the first major surface.

The printing layer of the mask can be formed in both process variants by a thin ink layer, in particular a thin opaque white layer.

According to an advantageous development, the mask is applied directly after a step of embossing a diffraction structure in the carrier film. Preferably, the mask is thereby positioned to the diffraction structure, so that the information formed by the openings of the mask in the register is an information formed by the diffraction structure.

In an advantageous embodiment, the mask is applied as a negative mask whose areas transparent to the laser radiation of the defined wavelength define the shape of the desired coating-free areas. The mask must not be completely impermeable in the non-transparent areas, it is sufficient if there is such a large part the laser radiation absorbs that the remaining residual radiation no longer has the intensity required to remove the cover layer. In particular, it is advisable that the negative mask has openings in the form of the desired coating-free areas.

In particular, an opaque cover layer or a color layer can be applied as the absorbent cover layer. It is self-evident that not only a single layer but also a layer sequence with a plurality of superimposed layers can be applied as cover layer, such as the color shift effect thin-layer element mentioned below.

In preferred embodiments, a metal layer or a layer sequence containing a metal layer is applied as cover layer, wherein the metal layer preferably consists of aluminum, copper, gold, iron, chromium, nickel, silver, platinum, palladium, titanium, another non-ferrous metal, or an alloy of these metals consists. In an advantageous embodiment, the cover layer forms the metallization layer of a diffractive diffraction structure. The metal layer is locally removed by the action of the laser radiation or converted into a transparent modification. Both cases are referred to in this description as ablation of the cover layer.

The method according to the invention is suitable not only for the local removal of thin cover layers (about 10 nm or more), but in particular also for the local removal of comparatively thick layers or layer sequences. For example, a layer sequence with a total thickness of more than 400 nm, in particular more than 800 nm, can be applied as cover layer.

According to an advantageous embodiment, a thin-film element with a color-shift effect is applied as the cover layer. Such a thin-film element expediently has a reflection layer, an absorber layer and a dielectric spacer layer arranged between the reflection layer and the absorber layer. Such a thin-film element can be applied with a layer thickness of up to about 1 .mu.m and according to the invention provided with coating-free regions. In the case of thin-film elements having a plurality of successive dielectric layers with different refractive indices, even several μm of layer thickness are possible. These extremely thick layers can also be locally removed by the method according to the invention in order to produce desired patterns, characters or codes in the cover layer.

In the context of the invention, the mask may represent an auxiliary layer which is removed after the laser application. However, the mask can also be formed by a layer which itself becomes part of the finished security element, and therefore does not have to be removed after laser application. In the latter case, the mask may be formed in particular by a metal layer. Before the laser application, the mask is advantageously structured by a washing process or an etching process.

In an advantageous embodiment, the security element contains a thin-film element with a color-shift effect, the absorber layer of the thin-film element assuming the role of the cover layer and the reflection layer of the thin-film element assuming the role of the mask. After the structuring of the reflection layer to produce the desired negative information, which can take place, for example, by a washing process or an etching step, the absorber layer is then removed by means of laser application through the reflection-layer mask.

In another, likewise advantageous embodiment, a color layer is applied as the cover layer and a reflection layer is applied as the mask. Again, the top layer is removed after the structuring of the reflection layer by the mask thus formed.

A further advantageous embodiment is obtained when a color layer or a colored hologram embossing lacquer is used as the cover layer, and the metallization layer of a diffractive diffraction structure is used as the mask. In this way, attractive color effects can be produced in hologram films.

In order to achieve a high processing speed, the loading of the carrier film with the laser radiation advantageously takes place over a large area in order to simultaneously detect a plurality of mask openings or transparent regions of the mask.

When using the method according to the invention on a moving film web, a laser spot is advantageously generated in the plane of the carrier film with a laser source and the carrier film is guided past the laser spot along a web running direction. In one variant of the invention, the laser spot is smaller than the relevant width of the carrier foil or a benefit of the carrier foil, so that the laser spot is moved over a deflection device at high speed along the width direction of the running carrier foil.

According to another, likewise preferred variant of the invention, the laser spot is produced with such an extent in the plane of the carrier film that it covers substantially all the width of at least one benefit of the carrier film extending perpendicular to the web running direction without beam deflection. It is understood that the laser spot has peripheral areas in which the mask contains no openings, no longer needs to capture. In this variant, the carrier film advantageously passes the laser spot at a high web speed of about 50 m / min or more, preferably even about 100 m / min or more. If several benefits are arranged side by side on the carrier foil, a plurality of laser sources can be used, each of which detects one of the benefits.

For laser application, the use of one or more lasers in the visible or infrared spectral range has been found to be advantageous. In particular, Nd: YAG lasers at 1.064 μm, frequency doubled Nd: YAG lasers at 532 nm or diode lasers in the near infrared, at about 808 nm or 940 nm can be used.

• Festlegen einer Laserwellenlänge zum Einbringen der beschichtungsfreien Bereiche;
• Bereitstellen einer Trägerfolie mit einander gegenüberliegenden ersten und zweiten Hauptflächen;
• Aufbringen einer die festgelegte Wellenlänge im Wesentlichen nicht absorbierenden Deckschicht auf eine erste Hauptfläche der Trägerfolie;
• Aufbringen einer Positivmaske mit die festgelegte Wellenlänge absorbierenden Bereichen, die die Gestalt der gewünschten beschichtungsfreien Bereiche definieren, auf die Deckschicht; und
• Beaufschlagen der mit der Maske versehenen Hauptfläche der Trägerfolie mit Laserstrahlung der festgelegten Wellenlänge, um die Deckschicht der ersten Hauptfläche unterhalb der absorbierenden Bereiche der Positivmaske lokal abzutragen.

According to a further variant of the invention, a method for producing a security element of the type mentioned at the outset comprises the steps:

• Determining a laser wavelength for introducing the coating-free regions;
• Providing a carrier film having opposing first and second major surfaces;
• Applying a cover layer substantially non-absorbing the predetermined wavelength to a first major surface of the support film;
• Applying a positive mask having the predetermined wavelength absorbing regions defining the shape of the desired coating-free regions to the cover layer; and
• Subjecting the masked major surface of the carrier film to laser radiation of the predetermined wavelength to locally ablate the first major surface cap layer below the positive mask absorbent regions.

The cover layer is permeable or reflective in this variant of the invention for the fixed laser wavelength, so that it is not removed by the laser radiation. The absorbent areas of the positive mask, on the other hand, strongly absorb the laser radiation and heat up until the underlying cover layer is dissolved or converted by the resulting heating or chemical reaction. With regard to the further embodiments of the method, reference is made to the above statements, which mutatis mutandis also apply to the method of this variant of the invention.

The invention also includes a security element for security papers, documents of value and the like having a carrier film with a cover layer, which has coatable regions in the form of patterns, characters or codes which can be produced in particular by transmitted light, which can be produced according to one of the method variants described above. The security element may in particular be a security thread or a wide security band. The security element is preferably equipped with an optically variable effect, preferably with a diffractive diffraction structure, in particular in the form of an embossed relief structure, and / or a Farbkippeffektschicht.

Further embodiments and advantages of the invention will be explained below with reference to the figures, in the representation thereof to a scale and proportioned reproduction has been omitted in order to increase the clarity.

Fig.1

eine schematische Darstellung einer Banknote mit einem eingebetteten Fenstersicherheitsfaden nach einem Ausführungsbeispiel der Erfindung,

Fig. 2 und 3

einen Querschnitt eines Sicherheitsfadens wie in Fig.1 jeweils bei einem Zwischenschritt des erfindungsgemäßen Herstellungsverfahrens,

Fig. 4

eine Aufsicht auf den fertigen Sicherheitsfaden,

Fig. 5 bis 9

jeweils einen Zwischenschritt bei der erfindungsgemäßen Herstellung verschiedener Sicherheitselemente, wobei der linke Bildteil die Situation vor der Laserbeaufschlagung und der rechte Bildteil die Situation nach der Laserbeaufschlagung zeigt, und

Fig. 10 und 11

das Prinzip der Laserdemetallisierung mit Maskentechnik an laufenden Folienbahnen.

Die Erfindung wird nun am Beispiel einer Banknote näher erläutert. Fig.1 zeigt dazu eine schematische Darstellung einer Banknote 10 mit einem Fenstersicherheitsfaden 12, der mit einer vor allem in Durchsicht erkennbaren Negativschrift 14 versehen ist. Die Negativschrift besteht im Ausführungsbeispiel zur Illustration lediglich aus der Buchstabenfolge "PL", es versteht sich jedoch, das in der Praxis auch längere Zeichenfolgen oder Zeichenfolgen, verbunden mit Mustern oder Codierungen, vorgesehen sein können.Show it:

Fig.1

a schematic representation of a banknote with an embedded window security thread according to an embodiment of the invention,

FIGS. 2 and 3

a cross section of a security thread as in Figure 1 in each case at an intermediate step of the manufacturing method according to the invention,

Fig. 4

a view of the finished security thread,

Fig. 5 to 9

in each case an intermediate step in the inventive production of different security elements, wherein the left part of the image shows the situation before the laser application and the right part of the image shows the situation after the laser application, and

10 and 11

the principle of laser demetallization with mask technology on running film webs.

The invention will now be explained in more detail using the example of a banknote. 1 shows a schematic representation of a banknote 10 with a window security thread 12 which is provided with a negatively recognizable font 14, which can be seen in particular. The negative writing in the embodiment for illustration only from the letter sequence "PL", it understands However, in practice, longer strings or strings, associated with patterns or codes, may be provided.

The layer structure and the production of a security thread according to the invention will now be explained with reference to Figures 2 to 6, wherein Figures 2 and 3 each show a cross section of the security thread at an intermediate step of the manufacturing process and Fig. 4 is a plan view of the finished security thread.

To produce a security thread according to the invention, first a transparent carrier foil 20 is provided, which has opposing main faces 22 and 24.

In a further method step, a mask 28 is printed on the second main surface 24 of the carrier film, which has openings 30 in the form of the desired negative writing. In the exemplary embodiment, the mask 28 is formed by a thin opaque white layer.

On a first major surface 22 of the carrier film, a full-surface opaque cover layer 26 is then applied. In the exemplary embodiment, a 30 nm thick aluminum layer is vapor-deposited on the carrier film 20 as cover layer 26. FIG. 2 shows the carrier film after the mask 28 has been printed and the aluminum layer 26 has been vapor-deposited.

The cover layer 26 may in particular be the metallization layer of a diffractive diffraction structure, which is subsequently impressed into the carrier film, such as a hologram. The cover layer 26 may also be formed by a more complex layer sequence, for example, by a thin-film element in other embodiments Color-shifting effect comprising a metallic reflection layer, a dielectric spacer layer and a semi-transparent absorber layer. Even such comparatively thick outer layers can be completely removed locally by the procedure described below and thus provided with a high-contrast negative information.

Subsequently, as shown in FIG. 3, the carrier foil 20 is exposed from the side of the second main face 24 to the radiation of a pulsed Nd: YAG laser with λ = 1.064 μm (arrows 32). The laser radiation 32 is incident through the openings 30 of the mask and the transparent support film 20 on the aluminum layer 26, which is locally removed by the action of the laser radiation in the exposed areas or converted into a transparent modification. In this way, coating-free regions 34 are formed in the otherwise opaque cover layer 26, as best seen in the plan view of FIG. 4.

If the security thread produced in this way is viewed in transmitted light, the introduced information appears as negative writing 34 in light of the dark metallic background of the cover layer 26. It is understood that other characters, patterns or codes can be introduced into the cover layer in the manner described.

The generation of negative information by masking and laser ablation offers two major advantages: Firstly, a color with fine pigments can be used for the printing of the mask, so that when using laser radiation in the near infrared line widths down to 5 microns can be achieved. With shorter wavelength laser radiation, the resolution may even be increased even further. On the other hand, the demetalization with the laser with a suitable choice of Beam parameters and beam guidance done very quickly, so that a high throughput is achieved.

The method according to the invention can advantageously also be combined with conventional demetallization methods, as explained below with reference to FIGS. 5 to 9.

5 shows a security element 60 with a transparent carrier foil 62, an optional hologram embossing lacquer layer 64 and a color shift effect thin-layer element 66 which comprises an absorber layer 68, for example an 8 nm thick chromium layer, a dielectric spacer layer 70, for example a 450 nm thick layer of SiO ₂ or MgF ₂ , and a reflector layer 72, for example, a 40 nm thick aluminum layer consists.

In the situation shown in FIG. 5, the reflector layer 72 is already provided with recesses 74 in the form of the desired negative writing, which were produced in an upstream process step, for example by a washing process of the type mentioned above or by an etching process.

The structured reflector layer 72 acts as a mask for the subsequent laser demetallization, wherein FIG. 5 shows a situation in which the layer structure of the right image part 76 has already been exposed to laser radiation 80, while the security element in the left image part 78 has not yet been processed.

The thin chromium layer 68 can already be removed with such a low irradiation energy that the reflector layer 72 substantially remains intact, so that the laser creates a structured thin-film element with recesses 74 in the reflector layer 72 and congruent uncoated regions 82 in the absorber layer 68. The dielectric spacer layer 70 is still present in the exemplary embodiment after laser application, but this does not affect the visual impression of the negative information, since the spacer layer 70 is transparent.

The described two-stage approach has the advantage that the removal of the thin absorber layer requires a significantly lower laser energy than the removal of the entire thin-film element. With a suitable adjustment of the laser energy, the structured reflector layer itself is not removed and can therefore serve as a mask, so that it is possible to dispense with the application of a separate mask. For the structuring of the reflector layer, existing devices and process steps for a washing process or an etching step can be used further.

The layer structure of the thin-film element 66 may also be applied in reverse order to the carrier foil 62, as shown in FIG. The laser application 80 then takes place from the opposite side of the security element through the transparent carrier film 62. In this design too, the reflector layer 72 structured by a washing process acts as a mask for the laser ablation of the thin absorber layer 68.

A laser application 80 from the rear side of the carrier film 62 also lends itself to other designs. For example, as illustrated with reference to FIG. 7, an aluminum layer 84 is first applied to a carrier film 62 and with a washing process in the form of the desired negative information be structured. On the aluminum layer 84, a color layer 86 is then printed to produce an example copper or gold-colored color impression of the security element. During the laser treatment, the layer sequence of aluminum layer 84 and color layer 86 is subsequently exposed to laser radiation 80 from the rear side of the carrier film 62, wherein the structured aluminum layer 84 acts as a mask for the removal of the color layer 86. With a suitable adjustment of the laser energy, it is possible in this way to remove only the color layer 86 matched to the aluminum layer 84 and thus to introduce a negative information in a copper or gold-colored reflection layer.

Such color effects can also be advantageously used in hologram films. For example, FIG. 8 shows a hologram foil 90 in which a color layer 92 is printed on a transparent carrier foil 62. Over the color layer 92, a hologram embossing lacquer layer 94 and a metal layer 96 of aluminum are deposited. Recesses 98 in the form of the desired negative information were introduced into the metal layer 96 by means of an etching process. In order to remove the ink layer 92 in the region of the recesses 98, the structure formed in this way is exposed to laser radiation 80, the structured metal layer 96 acting as a mask. The resulting hologram sheet 90 shows an example copper or gold hologram with transparent negative information.

Instead of a separate color layer 92, it is also possible to use a colored hologram embossing lacquer 94, the transparency being achieved by destruction of the color pigments contained in the lacquer by the laser radiation.

The design of FIG. 8 is used when the laser energy needed to remove the color layer 92 is small enough not to significantly affect the metal layer 96. If a higher energy is required, then, for example, after the etching process, the resist layer 100 applied to the metal layer 96 can initially be retained, as shown in FIG. 9. The resist 100 then protects the metal layer 96 from undesired damage during the laser application and is removed only after the laser has been applied.

The designs of FIGS. 8 and 9 can, of course, also be carried out with reverse layer construction. The sequence of the mask and the layer to be removed is then reversed and the laser application takes place from the back of the film.

FIGS. 10 and 11 show the principle of laser demetallization with mask technology on a moving film web. The running film web 40, of which only one section is shown schematically in FIGS. 10 and 11, has the same structure as the security thread of FIG. 2, thus containing a carrier film 20, on one major surface of which an opaque cover layer 26 and on the latter other major surface a mask 28 is applied. The running direction of the film web 40 is indicated by the arrow 42. In order to achieve a high throughput, a possible high value compatible with the reliable introduction of the laser markings is selected for the web speed of the film web 40.

The film web 40 generally has a plurality of adjacent benefits, of which only one is shown in FIGS. 10 and 11 for the sake of clarity. The side-by-side benefits can be achieved either by deflecting the laser beam or by using multiple, For example, the width of a benefit detecting laser sources are covered.

The infrared radiation 44 of a diode laser 46 is deflected via an optical device 48 and thrown in the form of a laser spot 50 in the plane of the running film web 40. The mask openings 30 of the mask 28 are shown exaggerated in FIG. 10 for the sake of clarity compared to the laser spot 50. In practice, mask apertures 30 are typically designed to produce microfonts or other micropatterns and thus significantly smaller than the extent of the laser spot, which may be a few millimeters or even a few tens of mm.

In the embodiment of Fig. 10, the extent of the laser spot 50 is smaller than the relevant width of the film web 40. The laser beam is therefore reciprocated to be inscribed in a direction 52 perpendicular to the direction 42 of the web to move all along the width of the film web To reach mask openings. This can be achieved for example in a conventional manner by a movable mirror or a mirrored polygon in the optical device 48.

If a sufficiently strong laser source 46 is used, it is also possible to dispense with scanning the width of the film web 40, as shown in the illustration of FIG. The laser spot is generated in this variant by a suitable optics of the optical device 48 with such an extent in the plane of the film web 40 that it covers substantially the entire width of the film web or a benefit on the film web. The local removal of the cover layer 26 can thus be done without deflection of the laser beam and thus at the highest possible speed.

In the embodiment of FIG. 11, for example, a 13 mm wide film web 40 is driven at a web speed 42 of 100 m / min. The laser source used is a continuous-wave diode laser 46 with an output power P of 2.8 kW. By means of suitable optics, an approximately rectangular laser spot 54 with a size of 13 × 8 mm ^{2 can be set} on the film web, so that the entire width of the film web is covered by the laser spot.

With the mentioned parameters, an energy density of 130 kJ / m ² , which is sufficient for demetallizing a 30 nm thick aluminum layer 26 in the region of the mask openings 30, is obtained for each surface element applied.

If the method according to the invention is combined in the manner described above, for example with a washing method or an etching step, then substantially lower energy densities are sufficient for ablation. For example, in thin-film elements with a color-shift effect, it is then possible to introduce negative information of the desired shape at energy densities below 2.5 kJ / m ² .

Claims (36)

A method for producing a security element for security papers, documents of value and the like, which comprises a carrier film with a cover layer, which has coatable regions in the form of patterns, characters or codes which can be seen in transmitted light, the method comprising the following method steps: - Setting a laser wavelength for introducing the coating-free areas; - Providing a carrier film with opposite first and second major surfaces; - applying a predetermined wavelength absorbing cover layer on a first major surface of the carrier film; Applying a mask defining the shape of the desired coating-free regions to the first or second major surface of the carrier film; and - Applying the masked main surface of the carrier film with laser radiation of the predetermined wavelength to locally ablate the absorbent cover layer of the first major surface. A method according to claim 1, characterized in that the carrier film is transparent for the predetermined laser wavelength and the mask is applied to the second main surface of the carrier film. A method according to claim 1 or 2, characterized in that the mask is printed on the first or second major surface of the carrier film. A method for producing a security element for security papers, documents of value and the like, which comprises a carrier film with a cover layer, which has coatable regions in the form of patterns, characters or codes which can be seen in transmitted light, the method comprising the following method steps: - Setting a laser wavelength for introducing the coating-free areas; - Providing a transparent laser wavelength for the predetermined carrier film with opposite first and second major surfaces; Applying a mask defining the shape of the desired coating-free regions to a first major surface of the carrier film; - applying a predetermined wavelength absorbing cover layer directly or via intermediate layers on the mask; and - Applying the second main surface of the carrier film with laser radiation of the predetermined wavelength to locally ablate the absorbent cover layer of the first major surface. Method according to at least one of claims 1 to 4, characterized in that the mask is formed by a thin ink layer, in particular a thin opaque white layer. Method according to at least one of claims 1 to 5, characterized in that the mask is applied directly after a step of impressing a diffractive structure in the carrier film. A method according to claim 6, characterized in that the mask is positioned to the diffraction structure, so that the information formed by the openings of the mask in the register is an information formed by the diffraction structure. Method according to at least one of claims 1 to 7, characterized in that a negative mask is applied as a mask whose areas transparent to the laser radiation of the defined wavelength define the shape of the desired coating-free areas. A method according to claim 8, characterized in that the negative mask has openings in the form of the desired coating-free areas. Method according to one of claims 1 to 9, characterized in that an opaque cover layer is applied as the absorbent cover layer. Method according to one of claims 1 to 10, characterized in that a color layer is applied as the absorbent cover layer. Method according to one of claims 1 to 11, characterized in that a layer sequence with a plurality of superimposed layers is applied as a cover layer. Method according to one of claims 1 to 12, characterized in that a metal layer or a layer sequence containing a metal layer is applied as the cover layer. A method according to claim 13, characterized in that the metal layer of aluminum, copper, gold, iron, chromium, nickel, silver, platinum, palladium, titanium, another non-ferrous metal, or an alloy of these metals. A method according to claim 13 or 14, characterized in that the cover layer forms the metallization layer of a diffractive diffraction structure. Method according to at least one of Claims 1 to 15, characterized in that a layer sequence having a total thickness of more than 400 nm, in particular more than 800 nm, is applied as cover layer. Method according to at least one of Claims 1 to 16, characterized in that a thin-film element with a color-shift effect is applied as the cover layer. A method according to claim 17, characterized in that the thin-film element with a reflection layer, an absorber layer and a dielectric spacer layer disposed between the reflective layer and the absorber layer. Method according to at least one of claims 1 to 18, characterized in that the mask is removed after the laser application. Method according to at least one of claims 1 to 18, characterized in that the mask is not removed after the laser application and forms part of the security element. A method according to claim 20, characterized in that the mask is formed by a metal layer. A method according to claim 20 or 21, characterized in that the mask is patterned before the laser application by a washing process or an etching process. Method according to at least one of Claims 20 to 22, characterized in that the absorber layer of a thin-film element is applied as cover layer and the reflection layer of the thin-film element is applied as mask. Method according to at least one of Claims 20 to 22, characterized in that a color layer is applied as cover layer and a reflection layer is applied as mask. Method according to at least one of claims 20 to 22, characterized in that a color layer or a colored hologram embossing lacquer, and as a mask, the metallization layer of a diffractive diffraction structure is applied. Method according to one of claims 1 to 25, characterized in that the carrier film is applied over a large area with the laser radiation to simultaneously detect a plurality of mask openings or transparent areas of the mask. Method according to at least one of claims 1 to 26, characterized in that a laser spot is generated in the plane of the carrier foil with a laser source and the carrier foil is guided past the laser spot along a web running direction. A method according to claim 27, characterized in that the laser spot is reciprocated along the direction perpendicular to the web running direction width direction of the current carrier film. A method according to claim 27, characterized in that the laser spot is generated with such an extent in the plane of the carrier film, that it detects without beam deflection substantially all, extending perpendicular to the web direction width of at least one benefit of the carrier film. A method according to claim 29, characterized in that the carrier film at the laser spot at a web speed of about 50 m / min or more, preferably about 100 m / min or more, is passed. Method according to at least one of Claims 1 to 30, characterized in that one or more lasers in the visible or infrared spectral range, in particular Nd: YAG lasers or diode lasers, are used for laser application. A method for producing a security element for security papers, documents of value and the like, which comprises a carrier film with a cover layer, which has coatable regions in the form of patterns, characters or codes which can be seen in transmitted light, the method comprising the following method steps: - Setting a laser wavelength for introducing the coating-free areas; - Providing a carrier film with opposite first and second major surfaces; - Applying a predetermined wavelength substantially non-absorbing cover layer on a first major surface of the carrier film; Applying a positive mask having the predetermined wavelength absorbing regions defining the shape of the desired coating-free regions to the cover layer; and - Applying the masked main surface of the carrier film with laser radiation of the predetermined wavelength to locally ablate the cover layer of the first major surface below the absorbent regions of the positive mask. Security element for security papers, documents of value and the like, having a carrier film with a cover layer, which in particular has visible coating-free regions in the form of patterns, characters or codes, which can be produced in transmitted light, can be produced according to one of claims 1 to 32. Security element according to claim 33, characterized in that the security element is a security thread or a wide security band. Security element according to claim 33 or 34, characterized in that the security element is equipped with an optically variable effect, preferably with a diffractive diffraction structure, in particular in the form of an embossed relief structure, and / or a Farbkippeffektschicht. Security document, in particular banknote, which is equipped with a security element according to one of claims 1 to 32.

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