DE102009034896B4 - Security document and method for producing a security document - Google Patents

Abstract

Security document (1 to 9) comprising a carrier layer (20) and a film body (10) fixed to the carrier layer (20) by means of an adhesive layer (21), which at least one carrier film (11) and at least one electrically conductive layer (12, 13 ), wherein the at least one electrically conductive layer (12, 13) for forming an antenna structure (26) is formed, wherein the structure of the carrier film (11) in one or more first zones (31) of the film body opposite one or more second zones (32) of the film body to reduce the stiffness of the carrier film is changed and in the region of the antenna structure (26) a second zone (32) and none of the first zones (31) is arranged and in an area adjacent to the region of the antenna structure (26) a plurality of first zones (31) is provided.

Description

The invention relates to a security document, in particular a passport, and a method for producing such a.

It is known to provide security documents with a transponder chip and an antenna for contactless reading of data from the transponder chip with a reader.

For example, describes the DE 196 306 648 A1 a bill with a transponder chip. The transponder chip is electrically connected to a metal security strip of the bill, which is designed as an antenna. The transponder chip is then embedded in a tough impact resistant potting compound.

It has now been found that numerous technical problems occur in the embedding of electrically conductive layers in security documents, which in particular adversely affect the lifetime, resistance to environmental influences and the reject rate in the production of the security document.

The DE 10 2007 050 495 A1 describes a document in book form with an integrated in the region of the back and / or lid assembly with an antenna device. In order to improve the security against forgery of such an identification document, the layer composite with the antenna device is designed to be irreversibly destructible.

The EP 1 502 765 A1 describes a passbook in which a data page is integrated. A flexible layer is connected to the data page. This flexible layer has breakthroughs to allow a particularly intimate mechanical connection to the data side.

The invention is based on the object to provide an improved security document with electrically conductive layers and a method for producing such.

The object is achieved by a security document according to claim 1 and a method for producing a security document according to claim 36.

Investigations have shown that the embedding of film bodies which have one or more electrically conductive layers and a carrier film suitable for this purpose results in production-related problems in security documents and also a reduced service life. It has further been shown here that the thickness of the carrier film can not simply be reduced to reduce the rigidity, since this results in production problems in the production of the electrically conductive layers which are used for electrical applications such as antenna structures or printed conductors for connecting electrical or electronic components electronic circuits, in particular transponder chip, are suitable. On the other hand, in many cases, the thickness of the carrier film can not be reduced either, as this would affect the performance of double-sided antennas, for example, by changing the capacity. The invention now ensures that carrier films can be used which have sufficient stability for the production process of the film body. By reducing the rigidity of the carrier film by changing the structure of the carrier film in first zones of the film body is further made possible to adapt the stiffness of the carrier film to the embedding process of the film body in the security document and the stiffness of the carrier film in this case, depending on the direction, on the other material layers the security document, thus improving the lifetime and security of the security document.

To change the structure of the carrier film in the first zones, it is possible, for example, to introduce recesses (laser ablation) into the carrier film in the first zones, to mold a surface relief structure in the first zones into the carrier film on both sides, or to mold the polymer structure into one or multiple first zones by irradiation or application of a reactant.

Advantageous embodiments of the invention are designated in the subclaims.

According to a preferred embodiment of the invention, the security document is a security document in the form of a booklet, for example a passbook, which has a multiplicity of sheets which are joined together to form the booklet. A first sheet of the security document in this case comprises the carrier layer and the film body. The first sheet of the security document may be a single sheet or a double sheet of the booklet, and further preferably the first sheet is a cover sheet of the booklet, around the front cover sheet forming the front portion of the cover of the booklet , or the back cover, which forms the back of the cover of the booklet. In such an embodiment of the security document, the design of the security document as described above is particularly advantageous.

Furthermore, it is also possible that the security document is a security document designed differently, for example an ID card or a value document.

The one or more electrically conductive layers preferably each consist of a metal layer with a layer thickness between 0.1 μm and 1 mm, more preferably between 5 μm and 100 μm. The carrier film preferably has a layer thickness between 4 μm and 500 μm, more preferably between 30 μm and 100 μm. The carrier film preferably consists of a plastic film of a non-conductive plastic, for example PET, PETG, PMMA, PC, PEC, ABS, ABS-PC, PE, PS, PVC, polyamides, PAN, SAN, SBS, PSU, PES, PEEK or PP.

According to a preferred embodiment of the invention, one or more of the electrically conductive layers are each formed as a partial electrically conductive layer having first regions in which the material of the respective electrically conductive layer is provided and have second regions in which the material of the respective electrically conductive layer is not provided. Preferably, one or more of the electrically conductive layers is in this case formed as an antenna structure, LCR resonant circuit or as a coil-shaped structure and more preferably connected to an electronic circuit, such as a transponder chip.

According to a preferred embodiment of the invention, a second zone and none of the first zones is provided in the regions in which one of the electrically conductive layers has the first region, ie. H. the structure of the carrier film is not changed in the region in which an electrically conductive region is provided. As a result, various advantages are achieved. On the one hand, this ensures that the carrier film has sufficient stability in the region in which the material of an electrically conductive layer is present, and thus, for example, line breaks due to a lack of stability of the carrier material are avoided. In addition, it is thus also ensured that in the areas in which the conductive material and thus, for example, a conductor track is provided, sufficient resistance to excessive bending of the carrier foil and thus of the foil body in this area (possibly at the expense of the surrounding areas ), which significantly prolongs the life of the security document. In addition, it ensures that the capacity in the example of a double-sided antenna and thus its performance is not affected.

Likewise, preferably in the region of an antenna structure, an LCR resonant circuit, a capacitance and / or an electronic circuit, a second zone and none of the first zones are arranged and in one of the area of the antenna structure, the LCR resonant circuit, the capacitance and / or electronic circuit adjacent area provided a variety of first zones. Deviating from this, however, it may also be advantageous if one or more of the electrically conductive layers are formed to form at least one coil-shaped structure, to provide a multiplicity of first zones in the region enclosed by the coil-shaped structure. The first zones then also influence the electrical properties of the coil-shaped structure, so that this arrangement of first zones makes it even more difficult to imitate the security document, thereby improving the security of the security document.

Preferably, the coil-shaped structures used here have between 1 and 15 turns, preferably between 2 and 4 turns. The width of the conductor tracks of the coil-shaped structures is preferably less than 5 mm, and is preferably between 0.05 mm and 2 mm. The spacing of the turns of the track of the coil-shaped structures is preferably less than 1 mm, more preferably between 0.05 mm and 0.5 mm.

The capacity-forming conductive surfaces preferably have a length between 1 mm and 100 mm, more preferably between 10 mm and 50 mm, and a width between 1 mm and 75 mm, more preferably between 10 mm and 40 mm.

According to a preferred embodiment of the invention, the film body has a plurality of first zones, which are arranged according to a one- or two-dimensional grid and are separated from each other by one or more second zones. In this case, it is possible for the grid to be a regular grid, so that the rigidity of the carrier film in the region of the grid is largely uniformly reduced by the first zones.

Furthermore, it is also advantageous for certain applications, for example passports, identity cards, driver licenses, tickets, labels, cards for security checks and identification, to submit an aperiodic grid in order to vary the stiffness of the film body as a function of location through the first zones. Thus, for example, it is possible that the grid width of the grid varies in a first spatial direction, for example, is reduced and so the stiffness of the Carrier film constantly reduced by the first zones in this direction. Furthermore, it is also possible to achieve, for example by using a two-dimensional grid with different screen rulings in a first spatial direction and in a second spatial direction or by using a one-dimensional grid and the shaping of the first zones, that the stiffness of the carrier foil in a first spatial direction of their Stiffness deviates in a second spatial direction. As a result, interesting effects and advantages can be achieved, for example in the case of a passbook, a higher rigidity parallel to the spine and a lower stiffness in the vertical direction, which allows a certain shape of the security document within predetermined limits. Furthermore, the processability in various coating and lamination systems is optimized.

The grid width of the grid is preferably between 0.2 mm and 25 mm, preferably between 1 mm and 5 mm.

It has been proven that the one or more first zones have a point-symmetrical shape, for example, have the shape of a circle or a point-symmetrical quadrilateral or have an elliptical shape. By using first zones whose length differs from their width, it is further possible to achieve the effect already described above of a different rigidity of the film in a first spatial direction and in a second spatial direction.

The term "width of a first zone" here means the smallest distance between the intersections of a straight line passing through the centroid of the first zone and the boundary line of the first zone.

The term "length of the first zone" accordingly means the largest distance between such intersections. Accordingly, a longitudinal direction of a zone is understood to mean a direction parallel to this straight line.

According to a preferred embodiment of the invention, one or more of the first zones are formed as line-shaped first zones, which have a linear shape. By means of such a configuration of the zones, direction-dependent differences in the stiffness of the carrier film can be achieved particularly well.

In this case, the width of the first zones in the plane spanned by the upper side or lower side of the carrier film is preferably between 10 μm and 5 mm and the length of the first zones is between 10 μm and 30 mm.

Preferably, the width of the first zones is at least a factor of 2 less than the length of the first zones.

According to a preferred embodiment of the invention, the line-shaped first zones have a periodically varying azimuth angle and are thus formed, for example, serpentine. For example, it is possible for the azimuth angle of the line-shaped first zones to be varied according to a sine function. By such a configuration of the first zones, interesting effects can be achieved. Thus, for example, it is possible to change the bending stiffness in a first solid angle range with respect to the bending stiffness in a second solid angle range substantially constant, resulting in, for example, the advantage: The targeted specification of bending lines loads are redirected from certain areas of the electrical component or the conductive structures and thus increases the long-term stability of these. Furthermore, the reduced stiffness leads to fewer break points, for example, when inserting into the trouser pocket, to better machine readability in the border control and higher sensitivity to manipulation attempts.

Furthermore, it has proved to be advantageous to form the line-shaped first zones as closed lines, which in particular have an annular shape. This makes it possible to set a stiffness of the carrier film which is relatively constant in all spatial directions in a surface area of the carrier film.

According to a further preferred embodiment of the invention, a first group of two or more first zones is formed as line-shaped first zones, which are arranged parallel to one another in each case separated from one another by one or more second zones. The spacing of the line-shaped first zones of the first group is in this case preferably aligned with a one-dimensional grid, wherein by selecting the screen rulings the advantages already described above can be achieved.

Furthermore, it has proved to be advantageous in this case that the mean azimuth angle of the first zones of the first groups encloses an angle of 35 to 55 ° with a fold line of the security document. If the security document is a booklet with a plurality of sheets, the fold line used is preferably the line on which the booklet is folded and the sheets of the booklet are connected to one another.

According to a further preferred embodiment of the invention, the Security document further on a group of two or more first zones, which are formed as a line-shaped first zones and are arranged parallel to each other and separated from each other by one or more second zones. The first group of first zones and the second group of second zones are in this case preferably arranged relative to each other such that the first zones of the first group overlap with the second zones of the second group. In addition, the mean azimuth angle of the first zones of the first group and the mean azimuth angle of the first zones of the second group are preferably selected such that they differ from one another and preferably in the range between 40 ° and 50 °. In this case, it is also advantageous if the mean azimuth angle of the first zones of the first group is oriented along a fold line of the security document and the mean azimuth angle of the first zones of the second group is oriented transversely to the fold line of the security document.

Further, it is also possible that the carrier film has different areas in which the average azimuth angle of linear zones, the shape of the first zone and their spacing differs, so that in different areas of the carrier film is a different, possibly directional and location-dependent stiffness the carrier film results.

As already mentioned above, it is advantageous to modify the structure of the carrier film in the one or more first zones in the top side and in the underside of the carrier film to form a surface relief structure. This is realized, for example, by means of an embossing punch or embossing roll, which acts on the carrier foil in the first zones by heat and pressure, whereby corresponding surface relief structures are molded into the top side and the underside of the carrier foil.

Preferably, in this case the same surface relief structure is molded into the top and the bottom of the carrier film. If the surface relief structures shaped into the top side and the underside of the carrier film are register-accurate, in particular phase-aligned, aligned with each other and have no phase shift, the film thickness of the carrier film in the one or more first zones is kept constant overall, as a result of the resulting greater effective Length of the carrier film and the overall resulting smaller layer thickness, the stiffness of the carrier film in the first zones, however, this significantly affected.

According to a further preferred variant of the solution, if the surface relief structures formed in the top side and the underside of the carrier film are the same, a phase offset is provided between the surface relief structures or different surface relief structures are molded into the top side and bottom side of the carrier film, so that the layer thickness of the carrier film in FIG varies one or more first zones. This also reduces the rigidity of the carrier film in the first areas accordingly.

It has proven to be particularly advantageous here to mold surface relief structures into the upper side and into the lower side of the carrier film, which have a spatial frequency between 1000 mm ^-1 and 0.05 mm ^-1 and a structure depth of 200 nm to 250 μm.

According to a preferred embodiment of the invention recesses are introduced in the one or more first zones for changing the structure of the carrier film, as already stated above. The recesses can be introduced, for example by means of a laser or by a mechanical method, for example by means of a cutting tool, a punch or a stamping process in the carrier film.

In this case, the recesses preferably extend as far as the upper side and / or lower side of the film body and thus also penetrate optional layers of the film body arranged above or below the carrier film in the first zones. However, it is also possible for the recesses to extend only in the carrier film and not to pierce optional layers of the film body arranged above or below the carrier film.

It is also possible that the processing method (eg laser, embossing, punching), which is used to produce the recesses, is also used for structuring the electrically conductive layer or for producing plated through-hole. Furthermore, it is also possible to use this machining method for tuning a resonant circuit, for example by means of a laser to reduce the area of a capacitor plate.

It is possible in this case for the one or more recesses to break through the carrier film. However, it is also possible for the recesses to be smaller than the layer thickness d of the carrier film. As a result, the advantage is achieved that the tensile strength of the carrier film over the embodiment is increased with the recesses which penetrate the carrier film. It has proved to be particularly advantageous here to choose the depth t of the recess between 10 and 85% of the layer thickness d.

Preferably, the recesses are introduced into the top and the bottom of the carrier film.

According to a preferred embodiment of the invention, the edge inclination of one or more of the recesses with respect to the plane defined by the top or the underside of the carrier film is between 20 and 90 or 90 and 170 °, more preferably between 45 ° and 80 ° or between 100 ° and 135 °. Further advantages are achieved by selecting the edge inclination smaller than 90 ° and in the other first zone greater than 90 ° in the case of two adjacently arranged first zones in the one first zone. As a result, a uniform rigidity is achieved both when bending in the direction of the top and in bending in the direction of the underside of the carrier film.

According to a further preferred embodiment of the invention, the recesses are filled with the adhesive of the adhesive layer. As a result, better adhesion of the film body to the carrier layer of the security document is achieved by the recesses as an additional benefit, which on the one hand increases the security of the security document and on the other hand improves the mechanical stability of the security document. The following embodiment is particularly advantageous: The security document further has a cover layer, wherein the film body is arranged between the cover layer and the carrier layer. The recesses break through the film body in the first zones and are completely filled with the adhesive layer so that the adhesive layer in the first zones is adjacent to the carrier layer on the one hand and to the cover layer on the other hand. As a result, a subsequent separation of the layers of the security document is made considerably more difficult and a particularly firm bond of the layers covering layer, foil body and carrier layer is achieved.

In the following, the invention will be explained by way of example with reference to several embodiments with the aid of the accompanying drawings.

1 shows a schematic sectional view of a security document.

2 shows a schematic sectional view of a security document.

3a to 3f each show schematic representations of a security document.

4 to 5b each show schematic sectional views of a security document.

6a to 8b each show a schematic sectional view of a carrier film.

1 shows a leaf 24 a security document 1 which is a carrier layer 20 , a film body 10 and a cover layer 22 having.

In the carrier layer 20 it is preferably a plastic film with a thickness between 4 and 250 microns, which consists for example of TESLIN. However, it is also possible that it is the carrier layer 20 is a paper layer or a multi-layered substrate. The layer thickness of the carrier layer 20 in this case is preferably between 50 .mu.m and 500 .mu.m and the rigidity of the carrier layer 20 is preferably between 0.5 mNm and 200 mNm. In this case, the stiffness of the carrier film by means of the measuring method according to Taber (standards: ASTM D5342, D5650, D747, JIS P8125) determined, whereby the force is determined, which is required to deflect a 1/5 gram loaded sample by 15 °.

The cover layer 22 preferably consists of a plastic film with a layer thickness between 4 microns and 350 microns. The cover layer 22 more preferably still has one or more decorative layers, which the visual appearance of the sheet 24 affected. So can the topcoat 22 For example, one or more resist layers, reflective layers and / or layers or layer systems which generate an optically variable effect.

However, it is also possible that the topcoat 22 consist of a transparent plastic film or a transparent lacquer layer and the visual appearance of the sheet 24 through the film body 10 is determined.

The rigidity of the carrier layer 20 is preferably between 4 mNm and 50 mNm and that of the topcoat 22 is preferably between 5 mNm and 80 mNm.

Further, it is also possible on the topcoat 22 to renounce.

The film body 10 is by means of adhesive layers 21 on the carrier layer 20 and on the topcoat 22 established. The film body 10 this can be the same size as the carrier layer 20 own and the carrier layer 20 thus covering the whole area. However, it is also possible that the film body 10 only a portion of the carrier layer 20 covered. It is particularly advantageous if the edge regions of the carrier layer 20 not from the film body 10 are covered and in these border areas the top layer 22 through the adhesive layer 21 directly with the carrier layer 20 connected is. This will increase the durability of the sheet 24 further improved against environmental influences.

The film body 10 has a carrier film 11 , electrically conductive layers 12 and 13 as well as protective lacquer layers 14 and 15 on.

On the protective lacquer layers 14 and 15 could also be dispensed with. Furthermore, it is also possible, instead of the protective lacquer layers 14 and 15 Provide adhesion promoting layers or even provide instead of these layers or in addition to these layers one or more decorative layers. Thus, it is possible, for example, one or more colored coating layers or one or more layers forming an optically variable security feature in the film body 10 provided. In particular, layers which have a microscopic or macroscopic surface relief, in particular a surface relief having an optical diffraction effect or a surface relief in the form of lens structures, matt structures or blaze gratings, can be used as the layer forming an optically variable security feature. Furthermore, as such layers, it is also possible to use thin-film layer systems which have one or more spacer layers which have an optical layer thickness in the region of half or quarter wavelength in a wavelength range in the visible light range and thus exhibit a viewing angle-dependent color shift effect. Furthermore, it is also possible to use liquid crystal layers or layers with optically active pigments, in particular effect pigments, UV- or IR-activatable pigments in the film body 10 provided.

For the electrically conductive layers 12 and 13 they are preferably metallic layers, for example of Cu; al; Ag; Au; Ni or the like, which have a layer thickness between 0.3 .mu.m and 1 mm, more preferably between 3 .mu.m and 100 .mu.m and thus are also suitable to be used as electrically conductive layers of a component of an electrical circuit, for example an RFID transponder , It is also possible that only one of the two electrically conductive layers 12 and 13 is provided or that more than two electrically conductive layers in the film body 10 are provided. It is also possible that the electrically conductive layers 12 and 13 represent a multi-layer structure of different conductive materials. The electrically conductive layers 12 and 13 are preferably formed as structured layers, ie the electrically conductive layers 12 and 13 have first areas, in which the material of the electrically conductive layers is provided, and second areas, in which the material of the electrically conductive layers is not provided, as in 1 is indicated.

In the carrier film 11 it is a plastic film, which preferably has a layer thickness between 3 .mu.m and 200 .mu.m, more preferably between 12 .mu.m and 75 .mu.m. The carrier foil 11 consists preferably of PET, PEC, PC, PMMA, ABS, ABE-PEC, PVC, PE, PS, PAN, SAN, SBS, PEEK, PSU, PES; Polyamides or PP.

The film body 10 is preferably prepared as follows:
The carrier foil 11 , which preferably has a rigidity of 0.5 mNm to 20 mNm, is provided.

On the carrier foil 11 On the front and on the back of a starter layer (Seedlayer), for example, an Ag paste is applied in a structured pattern in a printing process, in the areas in which later the metal of the electrically conductive layers 12 and 13 should be provided. Then optional holes through the carrier film 11 for vias etc. introduced. Subsequently, in a galvanic bath by galvanic reinforcement, the electrically conductive layer 12 and 13 deposited by current-carrying galvanic reinforcement.

Subsequently, the other layers of the film body 10 partially printed in most cases, for example the layers 14 and 15 ,

In a subsequent process step, the structure of the carrier film is now in one or more first zones 31 towards one or more second zones 32 of the film body 10 changed to reduce the stiffness of the carrier film. For this purpose, for example, in the slides 31 recesses 51 in the film body 10 introduced, as in 1 is indicated. As a result, the stiffness of the carrier film is preferably reduced between 10% and 80%.

Subsequently, in a further process step, the film body 10 by means of the adhesive layers 21 on the carrier layer 20 and on the topcoat 22 established. This can be carried out, for example, by the action of heat and pressure in a laminator, which the carrier layer 20 , the film body 10 and the topcoat 22 is supplied.

Furthermore, it is also possible that before printing the starter layer (seed layer) on the top and bottom of the carrier film 10 Structures are introduced by means of a laser in the non-printed areas or a UV activatable layer on the carrier film 11 is applied, and the UV-activatable layer is irradiated in the areas in which the starter layer is to be printed.

Further, it is also possible that the security document 1 instead of the leaf 24 a leaf 24 ' which according to 2 is constructed.

The leaf 24 ' has the carrier layer 20 , the film body 10 ' and the topcoat 22 on. The film body 10 ' is by means of the adhesive layer 21 on the carrier layer 20 and on the topcoat 22 established. The film body 10 ' is according to the film body 10 to 1 constructed and has the carrier film 11 , the electrically conductive layers 12 and 13 and the protective lacquer layers 14 and 15 on, in contrast to the film body 10 to 1 in the zones 31 on the one hand recesses 52 are provided, which the carrier film 11 but not the remaining layers of the film body 10 ' break through and recesses 53 are provided, which the carrier film 11 do not break completely.

Incidentally, the sheet is 24 ' like the leaf 24 and it will be explained in the relevant remarks in 1 directed.

The figure 3a now shows a possible embodiment of the security document 1 in which the leaf 24 is involved.

3a shows the security document 1 , which is in the form of a booklet with several leaves, the leaf 24 and the leaves 25 is trained. The leaves 24 and 25 are connected by stapling and gluing together. The leaf 24 forms the front and back cover pages of the booklet and thus the front and back cover of the security document 1 , The leaf 24 is like in 1 shown constructed, wherein the electrically conductive layers 12 and 13 as in 3a have shown a coil-shaped shape and together to form an antenna structure 26 connected to an electronic circuit 27 are connected. The electronic circuit 27 In this case, it is preferably formed by a silicon chip with a thinly ground silicon carrier or by a polymer chip. The area where the antenna structure 26 is provided, decreases in the embodiment 3a for example, a dimension of 78 * 48 mm. The carrier foil 11 of the film body 10 consists in this embodiment of a PET film with a thickness of 50 microns and the resonant frequency of the antenna structure 26 is 16.5 MHz. As in 3a indicated, are the zones 31 formed as circular disk-shaped zones, which in a regular two-dimensional grid in the region of the sheet 24 are arranged, wherein in the region of the antenna structure 26 none of the zones 31 but only one zone 32 is provided. Each of the zones 31 is here from the neighboring zone 31 through the zone 32 separated.

The diameter of the zones 31 is preferably between 0.1 mm and 20 mm and the grid pattern of the grid in the longitudinal direction of the sheet 24 is 7 mm to 10 mm and in the transverse direction of the sheet 24 8 mm to 12 mm.

3b shows a security document 2 , The security document 2 is like the security document 1 to 3a built with the difference that the shape of the zones 31 and 32 of the film body 10 - as in 3b indicated - by the shape of the zones 31 and 32 of the security document 1 to 3a different. Furthermore, the security document 2 to 3b the zones 31 Also provided within the coil-shaped structures, which of the conductive layers 12 and 13 be formed, as well as in 3b is indicated.

The zones 31 here have an oval shape, with the length of the zones 31 from the width of the zones 31 differs by a factor of 1.1 to 20. The width of the zones 31 is preferably between 0.1 mm and 5 mm. The length of the zones 31 is preferably between 0.3 mm and 100 mm. Again, the zones 31 preferably aligned on the basis of a regular two-dimensional grid, wherein the screen widths in the longitudinal direction of the sheet 24 between 6 mm and 10 mm and the screen widths in the transverse direction to the sheet 24 between 0.6 mm and 3 mm. The longitudinal direction of the zones 31 is hereby preferably parallel to the fold line of the security document 2 oriented so that the stiffness of the film body 10 in the direction parallel to the fold line is less than transverse to the fold line, in particular by 5 to 80% less.

The security document 3 to 3c is like the security document 1 to 3a formed with the difference that the zones 31 and 32 the carrier film 11 in their shape from those of the zones 31 and 32 of the film body 10 according to the security document 1 differ. The zones 31 here have a linear shape with a width of the linear zones 31 between 100 μm and 10 mm. Next are the line-shaped zones 31 arranged here in the form of concentric circles, wherein the circular rings are spaced apart from each other between 0.5 mm and 20 mm and preferably the spacing of the circular rings from one another is constant. Next is in the range of the antenna structure 26 no zone 31 but the zone 32 provided, as has also been explained above.

The security document 4 to 3d is like the security document 3 to 3c built, with the difference that the linear zones 31 have no annular shape, but are designed as straight lines. Next is the security document 4 a first group of linear zones 31 provided, which are arranged parallel to each other and with a grid width between 0.5 mm and 20 mm apart. The areas of a second group of linear areas 31 are also arranged parallel to each other and with a grid spacing between 0.5 mm and 20 mm apart, the line-shaped areas 31 the first group and the linear areas 31 the second group are arranged at right angles to each other. By different choice of line widths and grid widths of the linear zones 31 The first and the second group, it is possible, the stiffness of the carrier film 11 in the direction along the fold line of the security document 4 and in the direction transverse to the fold line of the security document 4 adjust.

Furthermore, the security document 4 unlike the security document 3 to 3c only an electrically conductive layer, the electrically conductive layer 12 provided, which in this case the antenna structure 26 for the electronic circuit 27 formed.

The security document 5 to 3e is like the security document 4 to 3d formed, with the difference that the linear zones 31 have a different shape and that in addition to the antenna structure 26 with the electrical circuit 27 an LCR resonant circuit 28 is provided, which by a corresponding structuring in the electrically conductive layer 12 is trained.

The linear zones 31 of the security document 5 wise, as in 3e shown, a varying azimuth angle, which is varied, for example sinusoidally, so that the in 3e shown serpentine shape of the linear zones 31 results.

The mean azimuth angle of the linear zones 31 is here at a 45 ° angle to the fold line of the security document 5 oriented.

The linear zones 31 in this case preferably have a width between 100 microns and 10 mm and are spaced from each other between 0.5 mm and 5 mm.

The security document 6 to 3f is like the security document 5 to 3e constructed, with the difference that the line-shaped zones 31 in their arrangement of the linear zones 31 to 3e differ. The security document 6 here has a first group of line-shaped zones 31 on, whose azimuth angle - as with 3e described - is periodically varied and which are arranged parallel to each other, and a second group of line-shaped zones 31 on, which also have a periodically varying azimuth angle and are arranged parallel to each other. The mean azimuth angle of the first group of linear zones 31 is here transverse to the fold line of the security document 6 oriented and the mean azimuth angle of the second group of line-shaped structures is along the fold line of the security document 6 oriented so that the mean azimuth angles of the first and second group of line-shaped zones 31 include about a 90 ° angle.

4 shows a security document 7 with the topcoat 20 , the film body 10 and the carrier layer 22 ,

The film body 10 is like the foil body 10 to 1 constructed and has zones 31 in which the structure of the carrier film 11 is changed to reduce the stiffness of the carrier film. Next here are additionally in the carrier layer 20 zones 33 provided in which the carrier layer 20 in the same way as described above with respect to the carrier film has been changed in the structure to the rigidity of the carrier layer 20 to reduce. For example, in the plastic film, for example a TESLIN film, which is the carrier layer 20 forms corresponding recesses introduced. As a result, the stiffness of the carrier film is reduced by 25%, for example. With regard to the manner in which these recesses are introduced and how these recesses are formed, reference is made to the relevant explanations regarding the recesses introduced into the carrier film.

The figures 5a and 5b show the security documents 8th and 9 , each covering the topcoat 22 , the film body 10 , the adhesive layer 21 and the carrier layer 20 exhibit. The cover layer 22 , the backing layer 20 and the film body 10 are like in 1 described constructed. As in 5a and 5b shown are the recesses 51 which are in the zones 31 are provided completely with the adhesive of the adhesive layer 21 filled, so in the area of the zones 31 the adhesive of the adhesive layer both on the cover layer 22 as well as on the carrier layer 20 liable. This results in a particularly strong connection of the layers of security documents 8th and 9 achieved, as stated above. At the security document 8th to 5a have the recesses 51 preferably a width between 100 microns and 10 mm and a length between 500 microns and 15 mm, the zones 31 preferably between 0.1 mm and 10 mm apart. At the security document 9 is the area of the zones 31 higher and the spacing of the zones 31 also higher, the width of the zones 31 is here preferably between 1500 microns and 15 mm, the length of the zones 31 between 500 μm and 250 mm and the spacing of adjacent zones 31 between 1 mm and 5 mm, which, for example, in addition to different bending stiffness values and the local transparency can be adjusted or influence on the rheological properties of the adhesive can be influenced. An adhesive layer for joining three film layers reduces the number of production steps and makes manipulation of the document more difficult.

6a . 6b and 6c show each differently shaped recesses 51 and 54 , which are in the carrier film 11 to 1 can be molded. In the embodiment according to 6a is in the zone 31 which of a zone 32 surrounded, the recess 51 whose edge is substantially perpendicular to that of the top and the bottom of the carrier film 11 spanned level and so a corresponding slope 42 of 90 °. The layer thickness 41 the carrier film 11 in this case is between 9 microns and 250 microns.

In the embodiment according to 6b points those in the zone 31 provided recess 54 a slope inclination 42 between 25 ° and 80 °, more preferably between 30 ° and 50 °. The differently inclined flanks influence the flow and the distribution of the adhesive, which makes it possible to influence the direction of the bending strength in a targeted manner.

In the embodiment according to 6c are in neighboring zones 31 recesses 54 molded, the edge slope is different. Here, the one recess has a slope of less than 90 ° and the other recess has a slope of greater than 90 °. As a result, on the one hand, a particularly uniform formation of the stiffness is achieved when bending in the direction of the upper side as well as on bending in the direction of the underside and, on the other hand, the mechanical strength of the security document is improved.

The figures 6d to 6f show further possibilities of embodiments of recesses 55 and 56 , which are in the carrier film 11 to 1 in zones 31 are provided.

So are according to 6d and 6e in the top of the carrier film 11 the recesses 55 and 56 introduced, which is a depth 43 have. The depth 43 in this case is preferably between 5% and 70% of the thickness 41 the carrier film 11 , Furthermore, the recess 55 to 6d a slope inclination 42 between 10 ° and 85 ° the recess 56 to 6e a slope inclination 42 from 90 ° up.

In the embodiment according to 6f are the recesses 56 both in the top and in the bottom of the carrier film 11 brought in. The depth 43 the recesses 56 in this case is preferably between 5% and 70% of the thickness 41 the carrier film 11 ,

The recesses 51 to 56 are - as already stated above - preferably introduced by means of a laser or a mechanically abrasive method, for example by means of punching, cutting or milling. However, it is also possible recesses in the zones 31 by means of a mechanically displacing process, for example by means of an embossing process. This is the figures 7a and 7b clarified. 7a and 7b show the carrier film 11 , where in zones 31 a recess 57 by means of an embossing stamp in the top ( 7a ) or in the top and in the bottom ( 7b ) has been introduced. The depth 43 the recess 57 is here preferably between 3% and 30% of the thickness 41 the carrier film 11 ,

Furthermore, it is also possible, the carrier film 11 in the zones 31 by shaping a surface relief in the top and in the bottom in their structure to change the stiffness of the carrier film 11 to reduce. This is in the figures 8a and 8b shown. In the embodiment according to 8a is in the area 31 in the top of the carrier film 11 a relief structure 61 and in the bottom of the carrier film 11 a relief structure 62 molded, for example by means of a correspondingly shaped hot stamping stamp. In the surface relief structures 61 and 62 These are similar structures, which also have no phase offset against each other. This results in the in 8a illustrated design of the carrier film 11 when in the zone 31 the effective length of the carrier film 11 extended and the effective thickness of the carrier film is reduced, so that the rigidity of the carrier film 11 is reduced in this area.

In the embodiment according to 8b is in the zone 31 in the top of the carrier film 11 the relief structure 61 and in the bottom of the carrier film 11 the relief structure 63 molded, the relief structures 61 and 63 have a phase offset of 180 ° from each other. As a result, the thickness of the carrier film varies 11 in the zone 31 , whereby the stiffness of the carrier film 11 in the zone 31 is greatly reduced.

The spatial frequency of the surface structures 61 . 62 and 63 in this case is between 1000 mm ^-1 and 0.05 ^-1 and their structure depth between 100 nm and 100 microns or up to 80% of the total layer thickness.

Claims (36)

Security document ( 1 to 9 ) with a carrier layer ( 20 ) and with one on the carrier layer ( 20 ) by means of an adhesive layer ( 21 ) ( 10 ), which comprises at least one carrier film ( 11 ) and at least one electrically conductive layer ( 12 . 13 ), wherein the at least one electrically conductive layer ( 12 . 13 ) for forming an antenna structure ( 26 ) is formed, wherein the structure of the carrier film ( 11 ) in one or more first zones ( 31 ) of the film body with respect to one or more second zones ( 32 ) of the film body to reduce the rigidity of the carrier film is changed and in the region of the antenna structure ( 26 ) a second zone ( 32 ) and none of the first zones ( 31 ) and in one to the area of the antenna structure ( 26 ) adjacent area a plurality of first zones ( 31 ) is provided. Security document ( 1 to 6 ) according to claim 1, characterized in that the security document ( 1 - 6 ) has the form of a booklet containing a plurality of sheets ( 24 . 25 ), which are connected to each other with the booklet, wherein a first sheet ( 24 ) of the security document the carrier layer ( 20 ) and the film body. Security document ( 1 to 9 ) according to one of the preceding claims, characterized in that the one or more electrically conductive layers ( 12 . 13 ) each consist of a metal layer with a layer thickness between 0.1 .mu.m and 1 mm. Security document ( 1 to 9 ) according to one of the preceding claims, characterized in that the one or more electrically conductive layers ( 12 . 13 ) are each formed as a partial layer, which has first regions in which the material of the respective electrically conductive layer is provided and has second regions in which the material of the respective electrically conductive layer is not provided, and that in the areas in which one of the electrically conductive layers having a first region, a second region ( 32 ) and none of the first zones ( 31 ) is provided. Security document ( 1 to 6 ) according to one of the preceding claims, characterized in that the film body ( 10 ) one with the antenna structure ( 26 ) connected electronic circuit ( 27 ) having. Security document ( 5 . 6 ) according to one of the preceding claims, characterized in that the one or more electrically conductive layers ( 12 . 13 ) for forming at least one LCR resonant circuit ( 28 ) are formed. Security document according to one of the preceding claims, characterized in that in the one or more first zones ( 31 ) in the top and in the bottom of the carrier film ( 11 ) a surface relief structure ( 61 . 62 . 63 ) for changing the structure of the carrier film ( 11 ) are molded. Security document according to claim 7, characterized in that in the top and in the bottom of the carrier film ( 11 ) the same surface relief structure ( 61 . 62 . 63 ) is molded and molded into the top and in the bottom of the carrier film surface relief structure ( 61 . 62 ) are aligned in phase with each other, so that the layer thickness of the carrier film in the one or more first zones ( 31 ) is constant. Security document according to claim 7, characterized in that in the top and in the bottom of the carrier film ( 11 ) different surface relief structures are molded and / or molded into the top and in the bottom of the carrier film surface relief structures ( 61 . 63 ) have a phase offset from each other, so that the layer thickness of the carrier film ( 11 ) in the one or more first zones ( 31 ) varies. Security document according to one of claims 7 to 9, characterized in that the surface relief structures ( 61 . 62 . 63 ) have a Spatialfrequenz between 1000 mm ^-1 and 0.05 mm ^-1 or a texture depth of 100 nm to 25 microns and / or up to 80% of the thickness of the affected individual layer. Security document according to one of the preceding claims, characterized in that the carrier film ( 11 ) is made of a polymer and the polymer structure in the one or more first zones is weakened by irradiation or application of a reactant. Security document ( 1 to 6 ) according to one of the preceding claims, characterized in that in the one or more first zones ( 31 ) for changing the structure of the carrier film ( 11 ) Recesses ( 51 to 57 ) are introduced in the carrier film. Security document ( 1 to 6 ) according to claim 12, characterized in that the recesses ( 51 ) up to the top and / or bottom of the film body ( 10 ) and optional, above or below the carrier foil ( 11 ) in the first zones ( 31 ) arranged layers ( 14 . 15 ). Security document ( 1 to 6 ) according to one of claims 12 or 13, characterized in that the recesses ( 51 to 56 ) by means of a laser or a mechanical process in the carrier film ( 11 ) are introduced. Security document according to one of the preceding claims, characterized in that the depth t of the recesses ( 53 . 55 . 56 ) smaller than the layer thickness d of the carrier film ( 11 ). Security document according to claim 15, characterized in that the depth t is between 5% and 70% of the layer thickness d. Security document according to one of claims 12 to 16, characterized in that the recesses ( 53 . 56 . 57 ) in the top and in the bottom of the carrier film ( 11 ) are introduced. Security document ( 1 to 6 ) according to one of claims 12 to 17, characterized in that one or more of the recesses ( 51 . 52 . 54 ) break the carrier foil. Security document according to one of claims 12 to 18, characterized in that the edge inclination of one or more of the recesses ( 54 . 55 ) is between 25 ° and 80 ° or between 100 ° and 135 ° with respect to the plane defined by the top or bottom of the carrier sheet. Security document according to one of Claims 12 to 19, characterized in that, in the case of two adjacent first zones ( 31 ) in the first zone, the edge inclination of the recess ( 54 ) is less than 90 ° and in the other first zone ( 31 ) the edge inclination of the recess ( 54 ) is greater than 90 °. Security document ( 1 to 6 . 8th . 9 ) according to one of claims 12 to 20, characterized in that the recesses ( 55 ) with the adhesive of the adhesive layer ( 21 ) are filled. Security document ( 1 to 6 . 8th . 9 ) according to claim 21, characterized in that the security document further comprises a cover layer ( 22 ) and the film body ( 10 ) between the cover layer ( 22 ) and the carrier layer ( 20 ) and that the recesses ( 51 ) the film body ( 10 ) in the first zones ( 31 ) and completely with the adhesive of the adhesive layer ( 21 ) are filled so that the adhesive layer ( 21 ) in the first zones ( 31 ) on the one hand to the carrier layer ( 20 ) and on the other hand to the cover layer ( 22 ) adjoins. Security document ( 1 . 2 ) according to one of the preceding claims, characterized in that the film body has a plurality of first zones ( 31 ) arranged according to a one- or two-dimensional grid and separated from each other by one or more second zones. Security document according to claim 23, characterized in that the grid width of the grid is between 0.5 mm and 30 mm. Security document ( 1 . 2 ) according to one of the preceding claims, characterized in that one or more of the first zones ( 31 ) have a point-symmetrical shape. Security document ( 3 to 6 ) according to one of the preceding claims, characterized in that one or more of the first zones are formed as line-shaped first zones and have a linear shape. A security document according to claim 26, characterized in that the width of the first zones is at least a factor of 2 less than the length of the first zones. Security document ( 3 - 6 ) according to one of claims 26 to 27, characterized in that the width of the first zones in the from the top or bottom of the carrier film ( 11 ) plane spanned between 100 and 3000 microns. Security document ( 5 . 6 ) according to one of claims 26 to 28, characterized in that the line-shaped first zones ( 31 ) have a periodically varying azimuth angle, in particular serpentine shaped. Security document ( 3 ) according to any one of claims 28 to 29, characterized in that the line-shaped first zones ( 31 ) are formed as closed lines, in particular have a circular shape. Security document ( 3 to 6 ) according to one of claims 26 to 30, characterized in that a first group of two or more first zones ( 31 ) are formed as line-shaped first zones and parallel to one another and in each case by one or more second zones ( 32 ) are arranged separately. Security document ( 5 ) according to claim 31, characterized in that the mean azimuth angle of the first zones ( 31 ) of the first group an angle of 40 ° to 45 ° with a fold line of the security document ( 5 ). Security document ( 4 . 6 ) according to one of claims 31 to 32, characterized in that a second group of two or more first zones ( 31 ) are formed as line-shaped first zones and are arranged parallel to each other and separated from each other by one or more first zones and that the mean azimuth angle of the first zones of the first group differs from the mean azimuth angle of the first zones of the second group and at least two or more of the first zones ( 31 ) of the first group with at least two or more first zones ( 31 ) of the second group overlap. Security document ( 4 ) according to claim 33, characterized in that the mean azimuth angle of the first zones ( 31 ) of the first group along a fold line of the security document ( 4 ) and that the mean azimuth angle of the first zones of the second group is transverse to the fold line of the security document ( 4 ) is oriented. Security document according to one of the preceding claims, characterized in that the film body ( 10 ) further comprises one or more layers forming an optically variable security feature, in particular a layer having a microscopic or macroscopic surface relief, in particular a diffractive surface relief or a surface relief in the form of lens structures, matt structures or blazed gratings, a thin film layer system, a liquid crystal layer or a layer optically active pigments, in particular with effect pigments, UV or IR-activatable pigments. Method for producing a security document ( 1 - 9 ) comprising the steps: - providing a film body ( 10 ) the at least one carrier film ( 11 ) and at least one electrically conductive layer ( 12 . 14 ), wherein the at least one electrically conductive layer ( 12 . 13 ) for forming an antenna structure ( 26 ) is formed. Change in the structure of the carrier film ( 11 ) into one or more first zones ( 31 ) of the film body with respect to one or more second zones ( 32 ) of the film body to reduce the stiffness of the carrier film ( 11 ) in the region of the antenna structure ( 26 ) a second zone ( 32 ) and none of the first zones ( 31 ) and in one to the area of the antenna structure ( 26 ) adjacent area a plurality of first zones ( 31 ) and - fixing the film body ( 10 ) with a modified structure of the carrier film in the first zones on a carrier layer ( 20 ) by means of an adhesive layer ( 21 ).

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