DE102017111639B4 - Electronic identification document and method for producing an electronic identification document - Google Patents

Abstract

An electronic identification document (200) comprising: a carrier (102), an identification element over the carrier (102), a microwave interaction structure (220, 222) adapted to interact with microwave radiation, anda modifying element (226) wherein the modifying element (226) is part of, or is in contact with, the microwave interaction structure (220, 222) and adapted to, upon interaction of the interaction structure (220, 222) with microwaves, change its state from an initial state to a permanently changed state wherein the permanently changed state differs from the initial state by a change in color, brightness, saturation, transparency and / or shape of the change element (226), the microwave interaction structure (220, 222) comprising a plurality of graphite particles ( 556); and wherein the plurality of graphite particles (556) form at least 20% by weight of the microwave interaction structure (220, 222).

Description

Technical area

Various embodiments generally relate to an electronic identification document and a method of manufacturing an electronic identification document.

background

Documents used for identification of a document owner (ID documents), for example ID documents having only printed information, are typically generated by manipulating optical features, i. a photograph of the document owner, falsified from written content on the document or hologram, etc.

ID documents, for example, in addition to printed information also electronically stored information can be referred to as electronic identification documents, identification documents with an electronic function or eID documents.

Because the information stored in an electronic identification document, such as a chip, such as a semiconductor chip, of an eID document can not be easily manipulated, a counterfeiter's strategy may typically be to destroy the electronic device by being exposed to microwave radiation.

At present, microwave manipulation can not be detected by optical inspection or other inspection methods, and the ID card, for example the electronic function of the eID card, is simply considered defective.

Here, the counterfeiter can take advantage of an at least provisionally legal situation that the eID document is considered valid even if the electronic part of the document is flawed. In other words, if the electronic part is faulty, the document may be accepted after verification of the electronic identification document, for example by customs officials, solely on the basis of the optical information present on the document (which, for example, can be more easily forged).

At present, there is no method available to detect the microwave attack on eID documents. In the publication DE 10 2016 113 656 A1 a use of metal inlays is proposed.

The FR 2 827 618 A1 discloses a document with a security feature, which in an emergency situation can be converted into a permanently changed state by means of microwave irradiation. The FR 2 929 033 A1 discloses a document that has a security feature that permanently changes upon exposure to microwaves to detect recognition of tampering with the document. The DE 10 2012 211 150 A1 discloses an identification document having an electrically conductive induction structure having a heating section.

short version

According to various embodiments, an electronic identification document is provided. The electronic identification document may include a carrier, an identification element over the carrier, a microwave interaction structure adapted to interact with microwave radiation, and a modifying element, which modifying element may be part of or in contact with the microwave interaction structure, and may be adapted to change its state from an initial state to a permanently changed state in the interaction of the interaction structure with microwaves, wherein the permanently changed state from the initial state by a change of color, brightness, saturation, transparency and / or the shape of the change element may differ and wherein the microwave interaction structure may comprise a plurality of graphite particles.

list of figures

• 1 einen schematischen Querschnitt eines elektronischen Identifikationsdokuments,
• die 2A, 2B und 2C schematische Schnittansichten elektronischer Identifikationsdokumente gemäß verschiedenen Ausführungsformen,
• 2D einen schematischen Querschnitt eines Abschnitts eines elektronischen Identifikationsdokuments gemäß verschiedenen Ausführungsformen,
• 3 eine schematische Ansicht eines elektronischen Identifikationsdokuments gemäß verschiedenen Ausführungsformen vor (oben) und nach (unten) einer Bestrahlung mit Mikrowellen und
• 4 eine schematische, perspektivische, teilweise explodierte Ansicht eines elektronischen Identifikationsdokuments gemäß verschiedenen Ausführungsformen,
• 5 ein Wechselwirkungselement, das mehrere Graphitteilchen gemäß verschiedenen Ausführungsformen aufweist, und
• 6 einen Prozessablauf eines Verfahrens zur Bildung eines elektronischen Identifikationsdokuments gemäß verschiedenen Ausführungsformen.

In the drawings, like reference characters generally refer to the same parts throughout the several views. The drawings are not necessarily to scale, the emphasis generally being placed on the explanation of the principles of the invention. In the following description, various embodiments of the invention will be described with reference to the following drawings. Show it:

• 1 a schematic cross section of an electronic identification document,
• the 2A . 2 B and 2C schematic sectional views of electronic identification documents according to various embodiments,
• 2D 12 is a schematic cross section of a portion of an electronic identification document according to various embodiments;
• 3 a schematic view of an electronic identification document according to various embodiments before (top) and after (below) irradiation with microwaves and
• 4 3 is a schematic, perspective, partially exploded view of an electronic identification document according to various embodiments;
• 5 an interaction element comprising a plurality of graphite particles according to various embodiments, and
• 6 a process flow of a method of forming an electronic identification document according to various embodiments.

description

The following detailed description refers to the accompanying drawings, in which specific details and embodiments in which the invention may be practiced are shown by way of illustration.

The term "serving as an example" is intended to mean "serving as an example, case or explanation". Any embodiment or design described herein as "exemplary" should not necessarily be construed as preferred or advantageous over other embodiments or designs.

The word "via" used herein with respect to a deposited material formed "above" a side or surface may be used herein to indicate that the deposited material is formed "directly on," for example, in direct contact with, the side or surface in question can be. The word "via" used in relation to a deposited material formed "above" a side or surface may be used herein to indicate that the deposited material may be formed "indirectly on" the particular side or surface, with one or more additional ones Layers are arranged between the relevant side or surface and the deposited material.

As used herein, the term "optically transparent" means that a material enables at least a portion of the electromagnetic radiation directed into the material to have an optical wavelength (the optical wavelength range may range from about 380 nm to about 780 nm) passes through without being scattered.

Microwave radiation is intended here to refer to electromagnetic radiation having a frequency between about 300 MHz and 300 GHz. Most commonly used microwave radiation for the manipulation of electronic identification documents may be microwave radiation having a frequency of about 2.45 GHz provided by a microwave oven.

1 shows a schematic cross section of a typical electronic identification document 100 , The eID document 100 can be a carrier 102 and an electronic identification element 104 , For example, have a chip. Identification information can here by an antenna 108 , which conducts with the identification element 104 connected, and a gain antenna 106 that is inductive with the antenna 108 can be coupled and used to communicate with the exterior of the eID document, provided to the outside of the eID document.

The identification element 104 For example, radiation may be sensitive to certain radiation, such as microwave radiation, for example, radiation typically provided by a microwave oven.

This feature may be counterfeiters of electronic identification documents by deliberately damaging the electronic identification element 104 and faking only the identification information provided for optical inspection that is easier to forge.

The known eID document can not determine at least from outside the eID document whether the electronic identification element 104 spontaneously or by deliberate attack, such as a microwave attack.

According to various embodiments, a method of detecting microwave manipulation of eID documents is provided by providing a feature, also referred to as a security feature or modifier, that can specify a microwave attack on the eID document. The change element may be an optically visible feature or a feature providing other types of information, such as an electronically readable feature such as a capacitance or the like.

According to various embodiments, an element including graphite (eg, pure graphite or active carbon that at least partially contains graphite, for example, as graphite domains) may be supported on a support (in conjunction with an identification document the carrier may also be referred to as an Inlam layer). The element including graphite may be covered by a cover layer.

According to various embodiments, the graphite may be designed such that its delocalized electrons may be produced by an oscillation of microwaves, for example by microwaves, such as those produced by a standard kitchen appliance (for example at 2.45 GHz (with a corresponding wavelength of 12 cm) ), are stimulated. As a result, temperatures of several hundred degrees Celsius can be generated. This effect can also be produced with granular active carbon because of the graphite domains it contains.

According to various embodiments, the intensity of the reaction and thus the temperatures reached may be the thickness and / or total mass of graphite in the graphite / carbon element (also referred to as graphite element or graphite element), for example a layer containing (pure) graphite or containing the active carbon and / or the intensity of a stimulation (which may for example depend on the position of the carbon element in a microwave device known to have localized areas of higher microwave intensity, so-called "hotspots") and depend on the heat transfer by surrounding material ,

According to various embodiments, the action of microwaves may increase the temperature of the graphite element. For example, a strong reaction can lead to burning of the graphite-containing element, while a weaker one can lead to a glow of the graphite-containing element.

According to various embodiments, the temperature increase may be sufficient to damage the cover layer and / or the support (the Inlam layer) in a manner that may be visible, for example, from outside the cover layer (brown, black discoloration, delamination, etc.). ...).

According to various embodiments, a distinction may be made between "random" patterns (eg, localized external burns, stains, etc.) by patterning the microwave sensitive element (eg, the layer, eg, the graphite element) and / or a change element thermally associated with the graphite element a certain shape, for example in the manner of a logo or a letter, be facilitated. This can lead to a specific structured appearance, for example of the graphite element, the carrier, the cover layer or a separate change element on and / or in the eID document, after the microwave attack.

According to various embodiments, the graphite may be provided as a plurality of graphite particles, for example, as particles made from substantially pure graphite, and / or as particles made from active carbon, at least some of which comprise graphite or consist of graphite. The graphite particles may, according to various embodiments, have a size between 0.05 mm and 2 mm. The size between 0.05 mm and 2 mm may be understood as a graphite particle having a size in the specified range in at least one dimension. In at least one other dimension, the particle may be small enough to be included in a layered structure of an identification document. Accordingly, depending on the thickness of a portion of the layered structure in which the graphite particles are to be accommodated (for example, within a dedicated layer, for example, a resin layer which may have a thickness of, for example, a few micrometers to a few hundred micrometers, or, for example, a structure which may vary in thickness) Extending substantially between both cover layers of the identification document and which accordingly may have a thickness of up to, for example, about 1 mm), each of the graphite particles has a maximum size in at least one dimension which may be less than the thickness of the portion, for example less than about one mm, smaller than a few hundred microns, for example, less than a few microns. According to various embodiments, the graphite particles may include or consist of graphite flakes. Here, a flake may be understood as a particle that may be considerably smaller in one direction (one thickness direction) (for example, by a factor of two or more) than in directions orthogonal to the thickness direction. The diameter of the flake can be understood as the maximum length of a line through the center of the flake oriented orthogonal to the thickness direction and measured between two points where the line intersects the edges of the flake. For round (for example, coin-shaped) flakes, the diameter of the flake can accordingly correspond to a common use of the term "diameter". According to various embodiments, the graphite flakes may have a diameter between 0.05 and 2 mm, for example about 1 mm. According to various embodiments, the graphite particles may be spheroidal or ellipsoidal particles. In a case of the spheroidal particle, the diameter may correspond to the usual use of the term. In In a case of the ellipsoidal particle, the diameter may be the maximum diameter of the ellipsoid.

According to various embodiments, the graphite particles may be dispersed in a matrix, for example a polymer matrix, for example a resin, for example an epoxy resin.

According to various embodiments, the matrix comprising the graphite particles may be deposited on a chip of the eID document and / or on an encapsulated chip encapsulation material.

According to various embodiments, the graphite element may have various advantages over a metal structure as a microwave interaction structure. According to various embodiments, the microwave absorbing material (i.e., the graphite) itself may be combustible, therefore, the thermal stress may be increased. According to various embodiments, the graphite may be difficult or impossible to recognize in X-ray images due to a similar (eg, nearly identical) X-ray absorption cross section as a plastic substrate (eg, a plastic substrate). According to various embodiments, the graphite element may be readily patterned into any desirable three-dimensional shape.

According to various embodiments, a black sheet of material may be inserted to prevent optical detection / localization of the carbon inlay structure (eg, prior to interaction with the microwaves).

According to various embodiments, a graphite substance may be integrated in an encapsulation, for example a chip encapsulation, or in a laminated structure of an electronic identification document, which can be stimulated by microwaves more easily, or at least as easily as an integrated circuit (IC), which is also included in the encapsulation can be. This means that when interacting with microwaves, the encapsulation / card can be visibly damaged before the integrated circuit is destroyed, or at least at the same time as the IC. Because the IC can currently be destroyed by microwaves without a visible sign, the possibility of detecting a microwave attack on the electronic identification document can be significantly improved.

According to various embodiments, the graphite material (for example, the substantially pure graphite and / or the active carbon) may be inserted into a molded enclosure or a smart card. According to various embodiments, an advantage over metal inserts may be better adhesion of the graphite / polymer inserts to polymer substrates.

According to various embodiments, to improve the absorption of microwave radiation, a polymer matrix comprising the graphite may comprise an organic material or consist of an organic material containing a high density of dipoles, for example an epoxy resin.

According to various embodiments, metal particles (for example Al particles), for example flakes, can be added to the graphite flakes, whereby the microwave absorption can be improved.

According to various embodiments, the graphite / polymer composite material may be deposited by a printing technique, such as transfer printing or stencil printing.

For example, in various embodiments, the graphite / polymer composite material may be disposed in a layered structure of the electronic identification document by attaching an extruded composite film.

According to various embodiments, visible damage may be produced by the reaction temperature of the microwave radiation-exposed graphite material.

According to various embodiments, the graphite material may be combined with a very reactive substance, for example a substoichiometric Li transition metal oxide. In this case, the temperature increase induced by microwaves in the graphite may act in the nature of a fuse for the reactive substance (which may be, for example, a reactive compound).

According to various embodiments, a reaction of the reactive substance (e.g., compound) may cause greater, more obvious damage.

A thermochromic substance may, according to various embodiments, be arranged in thermal contact with a module, for example a chip module, for example around it. The temperature increase induced by the microwave radiation in the graphite (and / or optionally in the reactive substance) can be used to irreversibly change a color of the thermochromic substance. This can be a colored marking or made to change their color. Accordingly, the modification element according to various embodiments may comprise or consist of the thermochromic substance.

According to various embodiments, a security feature included in an electronic identification document may consist of a patterned layer comprising graphite, for example a plurality of graphite particles.

According to various embodiments, the layer may be applied to one of several layers, for example layer layers, of the eID card, for example by printing or applying an extruded film.

According to various embodiments, the thickness of the graphite element may range from about 1 μm to about 1 mm, for example from about 5 μm to about 500 μm, for example from about 20 μm to about 200 μm, and for example about 100 μm or about 50 μm be. According to various embodiments, the graphite element may be adapted to replace a portion of a polymer layer structure of the eID document. This may make it possible to incorporate even a relatively thick graphite element in the eID document because its mechanical properties (e.g., flexibility, etc.) and appearance (for example, in X-rays) can hardly change as compared with an eID document without the graphite element that the graphite element may be difficult to detect by optical inspection from outside the eID document before the eID document is exposed to microwave radiation.

According to various embodiments, the change element (the element that transitions to a permanently changed state when the eID document is exposed to microwave radiation, which may be the graphite element itself or another element that may be thermally coupled to the graphite element) may be interposed between one outer (at least partially transparent or, for example, substantially completely transparent) layer and a vertically adjacent layer are located. This positioning of the security feature (change element) can be used for optical detection of a microwave attack.

According to various embodiments, the altering element, for example the graphite structure or the other altering element, may alternatively or additionally be located between two of the inner card layers, which may typically be opaque. This positioning can be used, for example, for electrical detection of the manipulation, for example by measuring the capacitance and / or the inductance of the modifying element.

According to various embodiments, the change element may be disposed on an outer surface of the eID document, such as an eID card, and covered with an additional very thin protective layer to prevent tampering or mechanical removal in use.

According to various embodiments, the eID document, such as the eID card, may have a transparent window (in a vertical direction of the eID card, for example, in a region between the change element and a major surface of the eID document, transparent or at least partially transparent) , In this case, according to various embodiments, the change element may be in the region of the transparent window, for example in the transparent window or below it.

According to various embodiments, the change element can be arranged on or in a separate label, for example a layer or a layer, which can be accommodated in a layer stack of the eID document, for example a stack of cards. If the change element is different from the graphite-microwave interaction element, the graphite element may also be incorporated in the separate label according to various embodiments. According to various embodiments, the graphite element may not be included in the separate label but may be disposed adjacent (i.e., in thermal contact with) the label in the final eID document.

According to various embodiments, upon irradiation of the eID document with microwaves, the altering element may permanently change at least one optical property, such as color, brightness, saturation, and / or transparency.

According to various embodiments, upon irradiation of the eID document with microwaves, the modifying element may permanently change the shape, e.g., flatness and / or surface roughness.

According to various embodiments, upon irradiation of the eID document with microwaves, the altering element may permanently change at least one electrical property, such as capacitance, inductance, and / or electrical resistance.

According to various embodiments, the change element may interact directly with the microwave radiation to cause the permanent change to occur in at least one optical property, shape, and / or electrical property. In other words, it may be the graphite element itself, for example a matrix (for example a layer, for example an epoxy resin layer) containing the graphite particles, which can undergo the permanent change in the irradiation with the microwaves. For example, heat introduced into the graphite particles by the microwaves may cause the matrix (eg, the layer) containing the graphite particles to flex causing a visible (and / or tactile) deformation of the eID document.

According to various embodiments, the altering element may be part of a microwave interaction structure that may interact with the microwave radiation so that the permanent change occurs in at least one of optical and at least one electrical property of the altering element. For example, in the matrix, a thermochromic material may be dispersed together with the graphite particles or disposed in an outer layer of the matrix containing the graphite particles, wherein the thermochromic material may be adapted to undergo a permanent color change when heated by the heat, which is introduced by the interaction of the graphite with the microwaves in the graphite particles.

According to various embodiments, the change element may be in contact with the microwave interaction structure that may interact with the microwave radiation. The contact with the microwave interaction structure, for example by heat transferred from the microwave interaction structure to the change element, can cause the permanent change of at least one optical and / or at least one electrical property of the change element. For example, the thermochromic material may be disposed in a separate layer disposed on the matrix containing the graphite particles or, for example, disposed directly on (for example, printed on) one surface of the matrix.

In the following description, various embodiments of electronic identification documents will be described 200 presented. To distinguish the various embodiments, a suffix (a, b, c, etc.) is added to the reference number.

The 2A to 2C show schematic cross sections of electronic identification documents 200a . 200b and 200c according to various embodiments, 2D shows a schematic cross section of a portion of an electronic identification document 200d according to various embodiments, 3 shows a schematic view of an electronic identification document 200e According to various embodiments before (top) and after (below) irradiation with microwaves, 4 shows a schematic, perspective, partially exploded view of an electronic identification document 200f according to various embodiments, and 5 shows an interaction element 220 . 222 with several graphite particles 556 according to various embodiments.

The eID document 200 may according to various embodiments, an identification element 104 having identification information. The identification element 104 can be an electronic identification element. It can have an integrated circuit (IC). The identification element can be, for example, a chip, for example a semiconductor chip, a memory device or the like. The identification element 104 may be identification elements of known eID documents, for example in the nature of the eID document 100 out 1 , similar or identical.

According to various embodiments, additional optical identification information 332 (please refer 3 ) for optical inspection, for example as printed information. The optical identification information 332 For example, they may include a photograph, a name, an address, a signature, and the like. An information content of the optical identification information 332 can be an information content in the electronic identification element 104 stored identification information to be the same or different.

According to various embodiments, the eID document 200 a carrier 102 with one as the upper surface 102S1 designated first major surface 102S1 and one as a lower surface 102S2 designated second major surface 102S2 respectively.

The carrier 102 can have multiple layers 102 or consist of these, with only cover layers 102C ie the respective layers with the upper surface 102S1 and 102S2 , are denoted by an individual reference number. The carrier 102 may be similar or identical to known carriers 102 eID documents, such as the eID document 100 out 1 , except for differences specified here. For example, materials (including For example, polycarbonate (PC)), functionalities (for example, a support layer for the identification element 104 and / or a gain antenna 108 , the adhesion between different layers, the protection against mechanical damage caused, for example, by surface layers of the support 102 provided, etc.) to those of the wearer 102 of the eID document 100 similar or identical. The carrier 102 may be formed by known processes, for example by lamination using temperature and pressure, and / or other known processes.

According to various embodiments, the eID documents 200 one also as an interaction structure 220 . 222 designated microwave interaction structure 220 . 222 which is designed to interact with microwave radiation, symbolically as a lightning sign 224 is shown.

The reference number 222 was chosen to designate the microwave interaction structure designed to change the optical properties and / or shape of the modifying element 226 cause (see, for example 2A . 2 B . 2C . 3 ), and the reference number 220 was for a microwave interaction structure 220 chosen, which is adapted to a change in the electrical properties of the change element 226 to effect (see, for example 2 B) , However, it can be expected that each of the change elements 226 , the part of the microwave interaction structures 220 . 222 may be or may be in contact with one or more of the properties corresponding to the other designation.

According to various embodiments, the eID documents 200 a change element 226 respectively. The change element 226 may be part of the microwave interaction structure according to various embodiments 220 . 222 or in contact, for example, in physical contact with it.

According to the embodiments of the 2A and 2D can the microwave interaction structure 220 . 222 for example, the change element 226 form.

According to the embodiment of 2 B may be a section of the topcoat 102C that is above the microwave interaction structure 222 is the change element 226 form.

According to the embodiment of 2C can be a purpose-built change element 226 over the microwave interaction structure 222 , for example, in contact therewith.

According to the embodiment of 2D can a shape 242 as the change element 226 act, for example, as an alternative to the microwave interaction structure 220 . 222 which is also the change element 226 forms, or in addition to.

According to the embodiment of 3 can the microwave interaction structure 220 . 222 the change element 226 form, or the microwave interaction structure 220 . 222 and the change element 226 may appear superimposed in the top view of the eID document 200e.

According to the embodiment of 4 can change element 226 through the microwave interaction structure 220 . 222 (the graphite layer), through one of the inner support layers 102 (the so-called Inlam layer) and / or through one of the cover layers 102C be formed.

According to various embodiments, the change element 226 be designed for an interaction of the interaction structure 220 . 222 to change its state from an initial state to a permanently changed state with microwave radiation.

According to various embodiments, the permanently changed state may be due to a change in the color, the brightness, the saturation and / or the transparency of the change element 226 differ from the initial state. In other words, the permanently changed state can change from the initial state by a change of at least one optical property of the change element 226 differ. According to various embodiments, the permanently changed state may be due to a change in the shape, for example, the flatness and / or the surface roughness, of the change element 226 differ from the initial state.

2 B shows as a visualization of a change in the shape of the change element 226 a configuration of the electronic identification document 200b after irradiation with microwave radiation 224 , Before the irradiation, the eID document 200b as flat as the eID document 200a out 2A have been. The cover layer 102C can be considered the change element in the sense 226 be designed by a deformation, such as a curvature of the microwave interaction structure 222 , upon heating by the microwave interaction structure 222 can react. The shape change can be visual and by touching the eID document 200b be recognized from the outside.

3 shows as a visualization of a change of an optical property of the change element 226 a schematic view of an electronic identification document 200e according to various embodiments before (top) and after (below) microwave irradiation 224 , Here, as a result of irradiation with microwaves 224 a change in the color and / or the brightness of the change element 226 have occurred.

An outline of the change element 226 As shown in plan view, according to various embodiments, can be presented so that an inspecting person can know where to expect a change resulting from the change of the change element 226 results, or it may be omitted. In this case, the change element 226 be visible or substantially or completely invisible before irradiation with microwaves 224 he follows.

According to various embodiments, the electronic identification document 200 optically at least partially transparent, for example with a transparency between 20% and 100%, for example between 50% and 100%, for example between 75% and 100%, for example be substantially completely transparent, at least in one area 102T that is different from the change element 226 up to at least one major surface 102S1 . 102S2 of the carrier 102 extends. Thereby, the change of the optical property, for example the color, the brightness, the saturation and / or the transparency, for example for an inspecting person, from outside of the eID document 200 being visible. A transparency percentage, ie a percentage of the light passing through the (at least partially transparent) material of the eID document 200 may pass according to the thickness of the eID document 200 between the change element and the exterior of the eID document 200 and according to an expected intensity of the change element change 226 be selected, so that is expected to change the change element 226 by the (at least partially) transparent material from outside the eID document 200 is visible.

According to various embodiments, changes referred to as modifications may also be made, depending on the structure and position of the change element 226 be recognized optically in the eID document, for example an eID card, either with the naked eye or with optical instruments.

According to various embodiments, the permanently changed state may change from the initial state by a change in the inductance, the capacitance and / or the electrical resistance of the change element 226 differ. In other words, the change element 226 change an electrical property when the eID document 200 microwave radiation 224 is suspended.

According to various embodiments, a detection of the changed electrical property by an electrical measurement may be possible. For example, the change element 226 showing the microwave interaction structure 220 or another element, have a defined inductance, ohmic and capacitance property. The microwave radiation 224 may be a change in the structure of the change element 226 For example, structures may burn and / or melt, and / or altered distances may occur between electrically conductive / capacitive and / or inductive portions of the modifying element.

According to various embodiments, this phenomenon can be used by changing element 226 is formed as a structure having a defined electrical property during microwave irradiation 224 can be destroyed, so that the microwave attack can be proved.

According to various embodiments, the change element 226 with the defined electrical property, such as inductance, ohmic and capacitance, be designed so that an electrical non-contact reading one or more of the properties (also referred to as parameters) of the structure may be possible. For this, according to various embodiments, standard IS = 14443 readers with an operating frequency of 13.56 MHz can be used.

According to various embodiments, the change element may 226 with the defined electrical property in an opaque region of the carrier 102 are located. The electrical non-contact readout can not require that the change element 226 is visible. However, this may be the case according to various embodiments. For example, the change element 226 have a defined initial optical state and a defined initial electric state and undergo a change to a permanently changed state that differs from the initial state in both an electrical and an optical property.

According to various embodiments, the change element 226 part of Microwave interaction structure 220 and or 222 its being the microwave interaction structure 220 and or 222 can be designed with the microwave radiation 224 to interact.

According to various embodiments, the interaction between the microwave radiation 224 and the microwave interaction structure 220 . 222 cause a temperature increase of the microwave interaction structure. This can lead to at least a portion of the microwave interaction structure 220 . 222 changes from the initial state into a permanently changed state, which differs in an electrical and / or an optical property and / or in its shape from the initial state. In other words, the portion of the microwave interaction structure 220 . 222 in this case, the change element 226 form.

According to various embodiments, the temperature increase in the metallic microwave interaction structure 220 . 222 be caused when the electronic ID document 200 the microwave radiation 224 is exposed to the microwave interaction structure 220 . 222 However, their optical and / or electronic properties and / or their shape can not or not significantly change. The change element 226 which is in contact with the microwave interaction structure 220 . 222 can, however, be due to the interaction of the microwave interaction structure 220 . 222 with the microwave radiation 224 undergo a change of its optical and / or electronic state and / or its shape, wherein the heat generated by the interaction may be sufficient to change the optical and / or electronic properties and / or the shape of the change element 226 cause.

According to various embodiments, the change element 226 , so that such indirect interaction with the microwave radiation 224 occurs in contact, for example, in thermal contact, for example in direct physical contact, with the microwave interaction structure 220 . 222 stand.

According to various embodiments, the change element 226 that is in contact with the microwave interaction structure 220 . 222 an area of the material of the carrier 102 be, for example, the material of the wearer 102 showing the microwave interaction structure 220 . 222 surrounds, such as in 2 B and possibly in 2D and 4 is shown.

According to various embodiments, a particular material may be in contact with the microwave interaction structure 220 . 222 For example, a material that can undergo a desired color change, for example, structures that have or consist of multiple metal and metal oxide layers that can change the color after microwave treatment, or a thermochromic material that may be designed to have its color permanently changing when heated above a predefined temperature. The thermochromic materials may be known, for example, from application to temperature indicating chalks and labels. The predefined temperature, which may be for example a temperature above about 100 ° C, for example above 120 ° C, for example above 150 ° C, may be due to the microwave interaction structure 220 . 222 in an interaction with the microwave radiation 224 to be provided.

According to various embodiments, the temperature increase of the microwave interaction structure 220 . 222 a modification of the microwave interaction structure 220 . 222 and the surrounding material of the vehicle 102 (For example, a plastic material, typically polycarbonate, PC, may be used) and / or the material of the dedicated change element 226 cause. In this case, the change element 226 both the domains of the microwave interaction structure 220 . 222 which may have undergone the transition to the permanently changed state, as well as the material of the wearer 102 and / or the dedicated material.

According to various embodiments, for example in a case where it is expected that the change element 226 undergoes a change in its electrical properties, the microwave interaction structure 220 . 222 electrically from the electronic identification element 104 be isolated. This allows the change element 226 , which is part of the microwave interaction structure 220 . 222 or can be in contact with it, assume a stable initial state before microwave irradiation and assume a stable, permanently altered state after microwave irradiation.

According to various embodiments, the microwave interaction structure 220 . 222 Graphite, for example, a pure or substantially pure graphite or, for example, active carbon (also referred to as carbon black), or consist of it, the sections, such as domains, of pure graphite may have. The graphite-containing microwave Interaction structure 220 . 222 can also be used as the graphite element 220 . 222 be designated.

According to various embodiments, the microwave interaction structure 220 . 222 several graphite particles 556 have (see 5 ). The microwave interaction structure 220 . 222 According to various embodiments, it may be formed as a layer, for example as a layer comprising a material 552 in which the plurality of graphite particles 556 are included. The layer may be substantially parallel to the major surfaces 102S1 and or 102S2 of the carrier 102 be arranged. The layer may, according to various embodiments, be a structured layer, for example a layer which may be a letter, a word (see, for example, US Pat 3 ), is shaped as a symbol or the like. This may allow discrimination of "random" patterns (eg, localized external burns, stains, etc.) according to various embodiments.

According to various embodiments, the plurality of graphite particles may be at least 20 wt%, for example, in a range between about 20 wt% and about 50 wt%, for example between about 30 wt% and about 40 wt%, for example by 35% by weight forming the microwave interaction structure.

According to various embodiments, the action of microwaves may increase the temperature of the graphite element 220 . 222 to lead. For example, a strong reaction can lead to burning of the graphite-containing element, while a weaker one can lead to a glow of the graphite-containing element.

According to various embodiments, the temperature increase may be sufficient to cover the cover layer 102C and / or the carrier (the Inlam layer) 102 in a way that, for example, from outside the cover layer 102C , may be visible (brown, black discoloration, delamination .......).

According to various embodiments, the graphite may be in the form of multiple graphite particles 556 provided, for example, as particles made from substantially pure graphite, and / or as particles made from active carbon, at least some of which have graphite or consist of graphite. The graphite particles 556 According to various embodiments, they may have a size between 0.05 mm and 2 mm. As described above and here with reference to examples in 5 repeatedly, the size between 0.05 mm and 2 mm may be understood as a graphite particle having a size in the specified range in at least one dimension. In at least one other dimension (also called the thickness tP of the particle, see 5 for some examples of the thickness tP, the graphite particles 556 different forms are given), the graphite particle 556 be small enough to be in a layered structure 102 an identification document to be included. Accordingly, depending on the thickness of a portion of the layered structure in which the graphite particles are to be accommodated (for example, within a dedicated layer 552 For example, a resin layer 552 which may, for example, have a thickness tL between a few micrometers and a few hundred micrometers, or for example as a structure extending substantially between both cover layers of the identification document and which accordingly may have a thickness tL of up to, for example, about 1 mm), each the graphite particles 556 have a maximum size in at least one dimension, which may be less than the thickness tL of the layer or portion of the layer structure, for example less than about 1 mm, less than a few hundred micrometers, for example less than a few micrometers. According to various embodiments, the graphite particles 556 graphite flakes 556f have or consist of. Here can be a flake as a particle 556 which is considerably smaller in one direction (a thickness direction) (for example, by a factor of two or more) than in directions orthogonal to the thickness direction. The diameter d of the flake 556f can be understood as the maximum length of a line through the center of the flake oriented orthogonal to the direction of thickness tP and measured between two points where the line is the edges of the flake 556f cuts. For round (for example, coin-shaped) flakes, the diameter d of the flake 556f Accordingly, a common use of the term "diameter" correspond. According to various embodiments, the graphite flakes 556f a diameter d between 0.05 and 2 mm, for example about 1 mm. According to various embodiments, the graphite particles 556 be spheroidal, ellipsoidal or random shaped particles. In a case of the spheroidal particle 556 For example, the diameter may correspond to the usual use of the term, and the thickness tP may be equal to the diameter d. In a case of the ellipsoid particle 556 the diameter d can correspond to the length of the main axis of the ellipsoid.

According to various embodiments, the graphite particles 556 into a matrix 552 For example, be embedded in a polymer matrix, for example a resin, for example an epoxy resin. The material forming the matrix may be according to various embodiments be electrically insulating material. The material may, according to various embodiments, have a relatively low thermal conductivity, for example a thermal conductivity which is lower by a factor of five or more than the thermal conductivity of graphite. The material may comprise or consist of an organic material containing a high density of dipoles, as may be the case, for example, in the case of an epoxy resin.

According to various embodiments, the graphite particles 556 in the matrix material 552 be dispersed while the material is liquid, and the material may then be cured, for example, by evaporation of a solvent, heating, irradiation with ultraviolet radiation or the like.

The matrix 552 containing the multiple graphite particles 556 may include, according to various embodiments via (for example) the identification element 104 or on / in the support structure 102 the electronic identification document 200 to be ordered.

According to various embodiments, the matrix 552 which are the graphite particles 556 contains (the microwave interaction structure 220 . 222 ), while the matrix / graphite mixture 552 . 556 is still liquid, for example by a printing technique, for example by transfer printing or stencil printing. By using printing, the matrix / graphite blend can 552 . 556 be shaped as desired, for example as the letter, the logo, etc., as described above. According to various embodiments, the matrix / graphite mixture 552 . 556 as a layer, for example as a complete or partial layer, are formed (for example printed).

According to various embodiments, the graphite / polymer composite material 552 . 556 by applying an extruded composite foil, for example in a layer structure of the electronic identification document 200 , to be ordered. In other words, the graphite / polymer composite material 552 . 556 first as a layer, for example as an extruded composite foil, which are then attached to the support structure 102 and / or on the identification element 104 of the eID document 200 attached, for example, laminated, can be.

According to various embodiments, the matrix layer 552 with the graphite particles 556 (the microwave interaction structure 220 . 222 ) has a thickness tL of less than about 1 mm, for example between about 10 μm and about 500 μm, for example between about 20 μm and about 200 μm.

According to various embodiments, the change element may 226 that with the microwave interaction structure 220 . 222 may be identical or a separate change element 226 can be over most of the microwave interaction structure 220 . 224 or the entire microwave interaction structure 220 . 224 extend.

According to various embodiments, metal particles (for example Al particles), for example flakes, can be added to the graphite flakes, whereby the microwave absorption can be improved.

The metal particles (not shown) may have one with the graphite particles, according to various embodiments 556 have comparable typical size and / or shape and in their sizes (for example, their maximum thickness) by the above for the graphite particles 556 limited boundary conditions described. The metal particles can together with the graphite particles 556 in the matrix 552 be distributed. The weight ratio between the metal particles and the graphite particles 556 According to various embodiments, it may range from about 1:10 to about 1: 1, for example, between about 1: 5 and 1: 2.

According to various embodiments, the electronic identification may further comprise an exothermic reaction element (not shown) that is thermally coupled to the microwave interaction structure 220 . 222 and the change element 226 coupled, wherein the exothermic reaction element is formed of a material having a triggering temperature of more than about 200 ° C, wherein the triggering temperature triggers an exothermic reaction.

According to various embodiments, the material of the exothermic reaction element may be a thermodynamically metastable inorganic material, for example a lithium (Li) based compound, for example a lithium metal oxide, for example a lithium based compound having one or more transition metals.

According to various embodiments, the exothermic reaction element in the matrix 552 containing the graphite particles 556 (and optionally the metal particles), for example, as a plurality of exotherm reaction element particles, which may have sizes and / or shapes with those of the graphite particles 556 are comparable or at least have the same limiting conditions as in Correlation with the graphite particles 556 has been described.

According to various embodiments, the size 226W of the at least one change element 226 parallel to the at least one main surface 102S1 . 102S2 the electronic identification document 200 . 200b . 200c at least 0.2 mm, for example at least 0.5 mm, for example 1 mm. In a case where the change element 226 is substantially circular, the electronic identification document 200 . 200b . 200c a size 226W have, which can correspond to the diameter of the circle. According to various embodiments of the change element 226 with a polygonal, for example, rectangular, square, etc., shape, the size may be 226W refer to the largest size.

According to various embodiments, such as in 2C and 2D can be shown, the position of the microwave interaction structure 220 . 222 and the change element 226 in the eID document be chosen so that the microwave interaction structure 220 . 222 in the immediate vicinity of the identification element 104 may be, for example, at least partially arranged laterally overlapping. According to various embodiments, the microwave interaction structure 220 . 222 between the identification element 104 and the topcoat 102c to be ordered. According to various embodiments, the microwave interaction structure 220 . 222 be arranged directly on the interaction element. This can help in the event of possible destruction of the identification element 104 For example, the PICC may be prevented by partially shielded or directional microwaves (where the shield may be designed to prevent destruction of visible metallic features when the PICC is destroyed).

The microwave interaction structure 220 . 222 and the change element 226 According to various embodiments, between the identification element 104 and a main surface 102S1 . 102S2 of the identification element are arranged.

According to various embodiments, the microwave interaction structure 220 . 222 at a horizontal distance (ie parallel to one of the major surfaces 102S1 . 102S2 ) of less than 1 cm, for example less than 7 mm, for example less than 5 mm, to the electronic identification element 104 to be ordered.

According to various embodiments, the eID documents 200 a device 106 . 108 for providing the identification information outside the eID documents, for example, a first antenna 108 electrically conductive with the identification element 104 coupled, and a gain antenna 106 , which is inductive with the first antenna 108 and is adapted to wirelessly exchange information with a location outside the eID document. Alternatively or additionally, other devices may be used 106 for providing the identification information outside of the eID document, for example, electrical contacts provided on an outer surface of the eID document and electrically connected to the identification element 104 coupled, or the like.

6 shows a process flow 600 a method of forming an electronic identification document according to various embodiments.

According to various embodiments, a method for producing an electronic identification document is provided.

The method may include: providing a carrier (at 610 ), Providing an identification element above the carrier (at 620 ), Forming a microwave interaction structure designed to interact with microwave radiation 630 ), and forming a modifying element, wherein the modifying element may be formed as part of or in contact with the microwave interaction structure and configured to change state from an initial state to a permanently changed state upon interaction of the interaction structure with microwaves the permanently changed state may differ from the initial state by a change in color, brightness, saturation, shape and / or transparency of the modifying element, and wherein the microwave interaction structure may comprise a plurality of graphite particles 640 ).

As described above, according to various embodiments, the process sequence for forming the electronic identification document may differ from the sequence described above. For example, the microwave interaction structure may first be arranged on the identification element before the identification element with the microwave interaction structure is arranged on or in the carrier.

According to various embodiments, an electronic identification document is provided. The electronic identification document may be a carrier, an identification element over the support, a microwave interaction structure adapted to interact with microwave radiation, and having a modifying element, which modifying element may be part of or in contact with the microwave interaction structure and may be configured to interact in the interaction of the microwave interaction structure Microwave interaction structure to change its state from an initial state to a permanently changed state, wherein the permanently changed state from the initial state by a change in the color, the brightness, the saturation, the transparency and / or the shape of the changing element may differ and the Microwave interaction structure may have multiple graphite particles.

According to various embodiments, the average size of the plurality of graphite particles may be between 0.05 mm and 2 mm.

According to various embodiments, the microwave interaction structure may further comprise metal.

According to various embodiments, the microwave interaction structure may comprise a mixture of graphite particles and metal particles.

According to various embodiments, the plurality of graphite particles may be provided as a plurality of active carbon particles, at least a portion of which comprises or consists of graphite.

According to various embodiments, the plurality of graphite particles may be embedded in a carrier, wherein the carrier material comprises an electrically insulating matrix.

According to various embodiments, the electrically insulating matrix may comprise a resin.

According to various embodiments, the electrically insulating matrix may comprise an epoxy resin.

According to various embodiments, the electronic identification may further comprise an exothermic reaction element thermally coupled to the microwave interaction structure and the altering element, wherein the exothermic reaction element is formed of a material having a firing temperature greater than about 200 ° C, the firing temperature being one exothermic reaction triggers.

According to various embodiments, the material of the exothermic reaction element may be a thermodynamically metastable inorganic material.

According to various embodiments, the plurality of graphite particles may form at least 20% by weight of the microwave interaction structure.

According to various embodiments, the shape change may be a change in the surface roughness of the change element.

According to various embodiments, the electronic identification document may be optically at least partially transparent at least in a region extending from the alteration element to at least one major surface of the carrier.

According to various embodiments, the change element may comprise plastic.

According to various embodiments, the electronic identification document may further comprise a chip.

According to various embodiments, the microwave interaction structure may laterally cover a chip.

According to various embodiments, the change element may be embedded in the carrier.

According to various embodiments, an electronic identification document is provided. The electronic identification document may include an electronic identification element and a microwave interaction structure configured to interact with microwave radiation and having a modifying element, wherein the modifying element may be configured to receive its state from an initial state upon interaction of the microwave interaction structure a permanently changed state, wherein the permanently changed state may differ from the initial state by a change in the inductance, the capacitance and / or the electrical resistance of the change element, and wherein the microwave interaction structure may comprise a plurality of graphite particles.

According to various embodiments, the electronic identification document may further comprise a carrier, wherein the microwave interaction structure may be embedded in the carrier.

According to various embodiments, the microwave interaction structure may be spaced less than 5 mm from the electronic identification element.

According to various embodiments, the microwave interaction structure may be disposed between the electronic identification element and a major surface of the carrier.

According to various embodiments, the microwave interaction structure may be disposed below an upper surface of the electronic identification document to a depth in the range of about 200 μm to about 600 μm.

According to various embodiments, the electronic identification document may be configured to allow determination of the inductance, capacitance, and / or electrical resistance of the change element from outside the electronic identification document.

According to various embodiments, a method for producing an electronic identification document is provided. The method may include providing a carrier, providing an identification element over the carrier, forming a microwave interaction structure configured to interact with microwave radiation, and forming a modifying element, wherein the modifying element is part of the microwave interaction structure or in contact can be formed and adapted to change its state from an initial state to a permanently changed state in the interaction of the interaction structure with microwaves, whereby the permanently changed state changes from the initial state by a change in color, brightness, saturation, the shape and / or the transparency of the change element, and wherein the microwave interaction structure may comprise a plurality of graphite particles.

In accordance with various embodiments, an electronic identification document may include an electronic identification element, a microwave interaction structure configured to interact with microwave radiation, and a modifying element, which element may be configured to resonate with an interaction structure of the microwave Changing state from an initial state to a permanently changed state, wherein the permanently changed state may differ in at least one physical property from the initial state, wherein the microwave interaction structure may comprise a plurality of graphite particles, and wherein the microwave interaction structure and the electronic identification element are so configured can that the electronic identification element as a result of a temperature increase of the graphite during the interaction of the interaction structure r is damaged by microwaves when the change element is in a permanently changed state.

According to various embodiments, the size of the change element may be at least 0.2 mm parallel to the at least one major surface of the electronic identification document.

Although the invention has been shown and described in detail with reference to specific embodiments, it should be understood by those skilled in the art that various changes in form and detail may be made without departing from the spirit and scope of the invention as defined by the appended claims. The scope of the invention is, therefore, indicated by the appended claims, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

Various aspects of the disclosure are provided for devices, and various aspects of the disclosure are provided for methods. It should be noted that basic properties of the devices can also apply to the methods, and vice versa. Therefore, for brevity, a duplicate description of such properties may be omitted.

Claims (16)

An electronic identification document (200) comprising: a carrier (102), an identification element over the carrier (102), a microwave interaction structure (220, 222) adapted to interact with microwave radiation, and a modifying element (226 ), wherein the modifying element (226) is part of, or is in contact with, the microwave interaction structure (220, 222) and is adapted to change state from an initial state to a permanent state upon interaction of the interaction structure (220, 222) with microwaves Change state, wherein the permanently changed state differs from the initial state by a change in color, brightness, saturation, transparency and / or shape of the change element (226), wherein the microwave interaction structure (220, 222) comprises a plurality of graphite particles (556); and wherein the plurality of graphite particles (556) form at least 20% by weight of the microwave interaction structure (220, 222). Electronic identification document (200) according to Claim 1 wherein the average size of the plurality of graphite particles (556) is between 0.05 mm and 2 mm. Electronic identification document (200) according to Claim 1 or 2 wherein the microwave interaction structure (220, 222) further comprises metal. Electronic identification document (200) according to Claim 3 wherein the microwave interaction structure (220, 222) comprises a mixture of graphite particles (556) and metal particles. Electronic identification document (200) according to one of Claims 1 to 4 wherein the plurality of graphite particles (556) are provided as a plurality of active carbon particles, at least a portion of which comprises or consists of graphite. Electronic identification document (200) according to one of Claims 1 to 5 wherein the plurality of graphite particles (556) are embedded in a carrier (102), wherein the carrier material comprises an electrically insulating matrix (552). Electronic identification document (200) according to Claim 6 wherein the electrically insulating matrix (552) comprises an epoxy resin. Electronic identification document (200) according to one of Claims 1 to 7 further comprising: an exothermic reaction element thermally coupled to the microwave interaction structure (220, 222) and the altering element (226), the exothermic reaction element being made of a material having a firing temperature greater than about 200 ° C, wherein the triggering temperature triggers an exothermic reaction. Electronic identification document (200) according to Claim 8 wherein the material of the exothermic reaction element is a thermodynamically metastable inorganic material. Electronic identification document (200) according to one of Claims 1 to 9 wherein the change of shape is a change in the surface roughness of the change element (226). Electronic identification document (200) according to one of Claims 1 to 10 wherein the electronic identification document (200) is optically at least partially transparent at least in a region (102T) extending from the modifying element (226) to at least one major surface (102S1, 102S2) of the substrate (102). Electronic identification document (200) according to one of Claims 1 to 11 wherein the altering element (226) comprises plastic. Electronic identification document (200) according to one of Claims 1 to 12 further comprising: a chip (104). Electronic identification document (200) according to Claim 13 wherein the microwave interaction structure (220, 222) laterally covers the chip (104). Electronic identification document (200) according to one of Claims 6 to 14 wherein the altering element (226) is embedded in the carrier (102). A method of making an electronic identification document, the method comprising: Providing a carrier (610), Providing an identification element above the carrier (620), Forming a microwave interaction structure adapted to interact with microwave radiation (630), and Forming a modifying element, wherein the modifying element is formed as part of or in contact with the microwave interaction structure and is adapted to change state from an initial state to a permanently changed state upon interaction of the interaction structure with microwaves; wherein the permanently changed state differs from the initial state by a change of the color, the brightness, the saturation, the shape and / or the transparency of the modifying element (640), and wherein the microwave interaction structure comprises a plurality of graphite particles; and wherein the plurality of graphite particles form at least 20% by weight of the microwave interaction structure.

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