METHOD FOR PRODUCING BANKNOTES INCLUDING IN EACH CASE AT LEAST ONE INTEGRATED CIRCUIT

Abstract

A method is provided for producing banknotes, which include, in each case, at least one integrated circuit. The banknotes are produced from a sheet or from a material web in a production panel. In at least a plurality of these banknotes, or in each of these banknotes, an aperture is created through their substrate. In each case, an integrated circuit is arranged in the relevant aperture. In a first method step, each of the integrated circuits to be arranged in one of the apertures is arranged, with respect to the intended position in each of the banknotes that include an aperture, in the correct position on a band-shaped foil, and, in the second method step, each of these integrated circuits is transferred from this band-shaped foil onto the relevant banknote. Owing to this transfer carried out in the second method step, one integrated circuit in each case, is arranged in the aperture created in the banknotes.

Description

FIELD OF THE INVENTION

The present invention relates to a method for producing banknotes including, in each case, at least one integrated circuit. The bank notes are produced from a sheet or from a material web in a production panel. At least in a plurality of the bank notes, or in each of these banknotes, an aperture is created through the banknote's substrate.

BACKGROUND OF THE INVENTION

A standard paper banknote is known from DE 697 22 403 T2, comprising a paper-based substrate that includes at least one integrated circuit, which is applied to the paper-based substrate, or is embedded therein, as an active identification and/or authentication element of the banknote, wherein the integrated circuit provides for secure storage and exchange of information with respect to the banknote, wherein the integrated circuit is inserted into an opening of the paper-based substrate, and wherein the thickness of the integrated circuit corresponds to the thickness of the paper-based substrate and is less than 100 μm.

A method for hot stamping at least part of at least one band-shaped stamping foil onto a band-shaped substrate is known from DE 10 2011 103 000 A1, wherein the substrate to be stamped is brought together with a stamping foil of the at least one stamping foil, the substrate and the stamping foil resting thereon are guided along the circumference of a first heated stamping roller, wherein, in a first stamping, the substrate and the stamping foil resting thereon are pressed against one another and against the heated surface of the first stamping roller by at least one first pressure roller arranged at the circumference of the first stamping roller, and a first stamping layer is stamped onto the substrate, the once-stamped substrate is guided away from the first stamping roller and is again brought together with the same or a further stamping foil of the at least one stamping foil downstream from first stamping roller, based on direction of travel of the substrate, the once-stamped substrate and the stamping foil resting thereon are guided along the circumference of a second heated stamping roller, wherein, in a second stamping, the substrate and the stamping foil resting thereon are pressed against one another and against the heated surface of the second stamping roller by at least one second pressure roller arranged at the circumference of the second stamping roller, and a second stamping layer is stamped onto the substrate, and the twice-stamped substrate is guided away from the second stamping roller.

A method for producing a security paper is known from DE 10 2004 018 081 A1, comprising the following steps: a) forming a paper web on a paper screen, and b) embedding a plastic film including antenna structures into the paper web during the formation of the sheet, wherein the plastic film is a plastic film network structured in a grid-like manner.

Sheet material including a circuit as well as a device and a method for processing the same are known from US 2005/0150740 A1, which reduce the effort for processing the sheet material and/or facilitate processing and/or enhance it and/or make it more reliable. For this purpose, the sheet material has at least one circuit, wherein energy and/or data are transmitted from the device to the circuit and/or from the circuit to the device, and wherein at least part of the transmitted data is used for processing the sheet material.

SUMMARY OF THE INVENTION

It is the object of the present invention to devise a method for producing banknotes including, in each case, at least one integrated circuit, which can be carried out economically in an industrial process.

The object is achieved according to the present invention by the provision, in each case, of an integrated circuit being arranged in the relevant aperture. In a first method step, each of the integrated circuits, which is to be arranged in one of the apertures, is arranged, with respect to the intended position of each of the banknotes that includes an aperture, in the correct position on a band-shaped foil. In a second method step, each of the integrated circuits is transferred from this band-shaped foil onto the relevant banknote. Owing to this transfer, that is carried out in the second method step, one integrated circuit, in each case, is arranged in each of the apertures created in the banknote.

The advantages to be achieved with the invention are, in particular, that banknotes including in each case at least one integrated circuit can be economically produced in an industrial process. Another advantage of the identified solution is that banknotes including in each case an integrated circuit that is inserted into an aperture are more durable and sturdier during use than banknotes including an integrated circuit that is applied to the surface, and more particularly when a structural height of the integrated circuit is less than the thickness or material thickness of the substrate of the banknote in question. Furthermore, it is advantageous that an integrated circuit configured as a capacitively coupled RFID tag does not require a separate antenna. Further advantages are apparent from the following description.

BRIEF DESCRIPTION OF THE DRAWINGS

An exemplary embodiment of the present invention is illustrated in the drawings and will be described in greater detail below.

The drawings show:

FIG. 1 a sheet including multiple banknotes;

FIG. 2 a banknote including an integrated circuit arranged in an aperture;

FIG. 3 a system for applying integrated circuits to a band-shaped foil in the correct position;

FIG. 4 a device for arranging the integrated circuits in the relevant apertures of the banknotes;

FIG. 5 a device for fixing the integrated circuit in one of the apertures, using an ink jet printing method;

FIG. 6 a device for fixing the integrated circuit in one of the apertures, using a screen printing method; and

FIG. 7 a device for fixing the integrated circuit in one of the apertures by rolling on a cover foil.

DESCRIPTION OF THE PREFERRED EMBODIMENT

FIG. 1, by way of example, illustrates that security documents that are needed in large quantities, in particular banknotes 02, are usually produced in an industrial process using a production panel format. The use of the multiple-up format means that, during the manufacturing process, multiple banknotes 02 are in each case arranged in a combination of rows R and columns S on a sheet 01 or on a material web, and these banknotes 02 are only detached from this combination at the end of their manufacturing process, and are thereby singulated. At the end of the manufacturing process, each of these banknotes 02 produced in the production panel is an autonomous product after singulation; however, a multiplicity of these typically identical products are jointly manufactured on the sheet 01 or on the material web so as to optimally utilize the surface area of the sheet 01 or of the material web, and thereby enable cost-effective mass production.

The banknotes 02 in general comprise a substrate 18 (FIG. 4), e.g., made of paper or plastic, in particular made of a polymer material, wherein this substrate 18 is preferably printed in one or more printing presses using several different printing methods. For example, an offset printing method and/or a gravure printing method, in particular the intaglio printing method, and/or a screen printing method and/or an ink jet printing method are used as printing methods. The banknotes 02 arranged in each case in columns S on the sheet 01 or on the material web are generally arranged lengthwise along the transport direction of the relevant sheet 01 or material web guided through the particular printing press, while the banknotes 02 arranged in rows R are generally arranged transversely to this transport direction.

To produce banknotes 02 including in each case at least one integrated electronic circuit 04, initially an aperture 03, which in each case perforates the substrate 18 of the relevant sheet 01 or of the relevant material web, is created at least in several, or preferably in each, of these banknotes 02, wherein such an aperture 03 is often also referred to as a window or an opening. The aperture 03 is created, e.g., by die cutting or cutting, in particular by laser cutting, wherein the contour of the relevant aperture 03 can be arbitrarily configured, but is usually configured in the form of a circle or a rectangle. FIG. 2, by way of example, shows a single copy of such a banknote 02.

Each of the integrated circuits 04 to be embedded into one of the banknotes 02 is encapsulated in a dedicated housing and is thus in each case configured as an autonomous component. As a result, each of the integrated circuits 04 to be embedded into one of the banknotes 02 is configured as a microchip. In the embodiment that is preferred here, the integrated circuit 04 to be embedded into the relevant banknote 02 is configured as a radio-frequency identification (RFID) tag, in particular as a capacitively coupled RFID tag, wherein a data exchange between the relevant integrated circuit 04 and an external transceiver, which is not shown, takes place in a non-contact manner. Each of these integrated circuits 04 has a generally rectangular format, in particular a square surface area having an edge length 104 of no more than 1 mm×1 mm, preferably of 0.5 mm×0.5 mm, wherein the structural height or thickness of these integrated circuits 04 to be embedded is no more than 90 μm, and preferably is in a range between 25 μm and 50 μm, and thus less than the material thickness of the substrate 18 of the relevant banknote 02. The aperture 03 to be created in the relevant banknote 02 is adapted to the format of the relevant integrated circuit 04 to be embedded, and its respective expansion is e.g., between 10% and 100% greater than the respective edge length 104 of the integrated circuit to be embedded. Information, e.g., about the currency and/or the value of the relevant banknote 02 and/or information about the issuing bank of this banknote 02 is stored in the respective integrated circuit 04, e.g., by appropriate programming, which can be read out elsewhere by means of the external transceiver (not shown) in a non-contact manner. Information as to whether this banknote 02 was already brought into circulation, or when this took place, can also be stored in the integrated circuit 04.

For the sake of simplicity and without limiting the invention, it is assumed hereafter that identical banknotes 02 are produced using the production panel, so that the respective aperture 03 in each of these banknotes 02 is in each case created in the same position, with respect to the relevant banknote 02. A center of the relevant aperture 03, and thus its position in the relevant banknote 02, with respect to, e.g., at least one boundary line, e.g., an edge or a lateral edge of the relevant sheet 01 or of the material web, e.g., is established in each case by corresponding coordinates x; y. These coordinates x; y are stored in a control processor, e.g., wherein this control processor provides the relevant coordinates x; y for each banknote 02 produced in the relevant production panel at least, e.g., to a cutting device 09 or a die-cutting device 28 (FIG. 4) creating the relevant aperture 03 in each case, on the one hand, and to a device providing the respective integrated circuits 04 on the other hand.

So as to arrange an integrated circuit 04 in each of the relevant apertures 03 of the banknotes 02 to be jointly produced in an industrial process, in a first method step the necessary number of integrated circuits 04 is arranged with register accuracy on a band-shaped foil 06 by the device providing the respective integrated circuits 04. An arrangement with register accuracy means that one of the integrated circuits 04 is in each case arranged in precisely such positions on the band-shaped foil 06 which correspond to the positions for the arrangement of the respective integrated circuit 04 that are established in each case on the relevant sheet 01 or the material web by the corresponding coordinates x; y. With this, the arrangement of the integrated circuits 04 on the band-shaped foil 06 in the lateral register and in the circumferential register corresponds precisely to the arrangement that is intended on the relevant sheet 01 or the material web.

As is only schematically illustrated in FIG. 3 by way of example, the band-shaped foil 06 is preferably provided in the form of a material roll 07 and is unwound from the material roll 07, wherein the fed integrated circuits 04 are then arranged in the correct position, and thus with register accuracy, on the unwound part of the material roll 07, i.e., on the band-shaped foil 06. The integrated circuits 04 can be fed to the band-shaped foil 06, e.g., assisted by blower air. The integrated circuits 04 are fixed on the band-shaped foil 06, e.g., electrostatically and/or by way of adhesion. After the integrated circuits 04 have been adhesively arranged, the band-shaped foil 06 can, e.g., be wound onto a reel 08 again.

In a second method step, the band-shaped foil 06, after having been wound onto the reel 08 according to the described example, is unwound from the reel 08 again, wherein the integrated circuits 04 arranged with register accuracy on the band-shaped foil 06 are transferred from the band-shaped foil 06 to the respective banknotes 02 created on the relevant sheet 01 or the relevant material web, wherein, as a result of this transfer carried out in the second method step, one of the integrated circuits 04 is arranged in each of the apertures 03 created in the banknotes 02.

The application of the integrated circuits 04 in the banknotes 02 is illustrated in FIG. 4, wherein FIG. 4, by way of example, shows the application, in particular the arrangement of integrated circuits 04 in the respective apertures 03 of sheets 01 conveyed in the transport direction T, wherein each of these sheets 01 has a length 101 in the transport direction T. In the shown example, several of these sheets 01 are consecutively fed from a first pile 24 at a distance a in the transport direction T to a device 12 for applying the integrated circuits 04, and after the application has been carried out, are deposited in a second pile 26 again. So as to enable economical production, at least some processing steps are combined locally, i.e., carried out in the same machine system, so as to avoid temporarily storing the sheets 01. The sheets 01 or the material web are thus, initially, fed preferably continuously from the first pile 24 to a cutting device 09 or a die-cutting device 28, wherein the respective apertures 03 are created in the relevant sheet 01 or the material web by way of this cutting device 09 or die-cutting device 28. Thereafter, the sheets 01 or the material web provided with the apertures 03 are preferably fed in the same machine system to the device 12 for applying the integrated circuits 04, which, e.g., comprises a roller pair and which, in a roller nip of the cooperating rollers 13, transfers the integrated circuits 04 arranged on the band-shaped foil 06 from the band-shaped foil 06 onto the relevant banknote 02, wherein, as a result of this transfer, in each case one of the integrated circuits 04 is arranged in the apertures 03 created in the banknotes 02. This application preferably takes place simultaneously for all integrated circuits 04 arranged in the same row R. As a result of the banknotes 02, in the production panel, being produced with multiple columns S arranged next to one another, and to ensure that in each case multiple banknotes 02 are arranged in each row R extending across multiple rows S, a very high mass throughput can be achieved compared to a serial processing operation of individual banknotes 02. At least at the transfer point 11 located in the roller nip, the transport speed of the band-shaped foil 06 to be unwound from the reel 08, e.g., is synchronized with the transport speed of the sheets 01 or the material web.

As the second method step is being carried out, or immediately after the second method step has been carried out, the band-shaped foil 06 is joined to the substrate 18 of the banknotes 02 of the relevant sheet 01 or of the relevant material web. In a preferred embodiment for producing banknotes 02, the band-shaped foil 06, on which the integrated circuits 04 are arranged with register accuracy in the first method step, is configured as a two-layer foil, wherein as the second method step is being carried out, or immediately after the second method step has been carried out, a first layer 16 of the band-shaped foil 06 is joined to the substrate 18 of the banknotes 02 of the relevant sheet 01 or of the relevant material web. The band-shaped foil 06, or its first layer 16, is, for example integrally, joined in each case to the substrate 18 of the banknotes 02 of the relevant sheet 01 or of the relevant material web, in particular by adhesive bonding. The band-shaped foil 06, or the first layer 16 of the two-layer band-shaped foil 06, is preferably configured in each case as a foil including a hologram and/or a Kinegram, wherein a second layer 17 of the two-layer band-shaped foil 06 is, e.g., made of paper or a plastic. A Kinegram is a security feature having a tilt effect, which means that, depending on the angle at which the Kinegram is observed, a fixedly defined movie-like sequence occurs. In contrast to a hologram, which has three-dimensional elements, a Kinegram, which usually has a silvery shine, represents a two-dimensional sequence of motions. In particular a metallic foil or a metallized foil or a security foil to be arranged on the substrate 18 of the banknotes 02 is used in each case as the band-shaped foil 06 or as the first layer 16 of the two-layer band-shaped foil 06. For reasons related to ultimate tensile strength and/or stability and/or processability, the second layer 17, e.g., forms a carrier for the first layer 16. When the band-shaped foil 06 or its first layer 16 is configured as a metallic foil or as a metallized foil, this foil is, e.g., made of aluminum or of another metallic material, or this foil comprises a carrier, e.g., made of a plastic material, the surface of which was metallized, e.g., by vapor deposition. In each of these embodiments, the integrated circuits 04 to be applied adhere to the band-shaped foil 06 or to the first layer 16 of the two-layer band-shaped foil 06. However, no electrically conducting connection exists between the respective integrated circuit 04 and the metallic foil 06 or the metallized surface of this foil 06. The band-shaped foil 06, or its first layer 16, is in each case joined to the substrate 18 of the banknotes 02 of the relevant sheet 01 or of the relevant material web, e.g., by rolling-on or by hot stamping. During hot stamping, the band-shaped foil 06 or its first layer 16 is applied to the substrate 18 of the relevant sheet 01 or of the relevant material web under the action of pressure and heat. The two layers 16; 17 of the two-layer band-shaped foil 06 are preferably separated from one another at the transfer point 11 or immediately thereafter, wherein the second layer 17 is, e.g., again wound onto another reel 14.

In a third method step, the integrated circuits 04 applied or arranged in the respective apertures 03 are fixed therein. This fixation is carried out, e.g., using a printing method, in particular an ink jet printing method or a screen printing method, and/or by rolling or hot stamping a cover foil onto the substrate 18 of the relevant banknotes 02. FIG. 5 shows that an electrically non-conductive printing fluid 21, e.g., an ink or a coating, is applied to the integrated circuit 04 arranged in one of the apertures 03 by way of an ink jet printing device 19, wherein the integrated circuit 04 is fixed in the relevant aperture 03 by drying and/or curing the printing fluid 21. FIG. 6 illustrates by way of example that an electrically non-conductive printing fluid 21 is applied to the integrated circuit 04 arranged in one of the apertures 03, and thus in these apertures 03, by way of a screen printing device 22, wherein here as well the integrated circuit 04 is fixed in the relevant aperture 03 by drying and/or curing the printing fluid 21. As an alternative or in addition to applying a printing fluid 21, the integrated circuits 04 arranged in the apertures 03 can be fixed by applying an electrically non-conducting cover foil 23 onto the relevant banknotes 02, in particular by rolling it on by way of a rolling device 27, if necessary additionally under the action of heat, which is schematically shown in FIG. 7 in a drastically simplified manner.

After the integrated circuits 04 have been applied or arranged and fixed in the relevant apertures 03 of the banknotes 02, in general several of the sheets 01 or the material web, each comprising copies of the banknotes 02 to be produced in the production panel, are printed in at least one printing press, or using at least one printing method, and are thereafter detached from their combination by way of a die-cutting device or by way of a cutting device, e.g., a guillotine cutter, and are thereby singulated.

During the production of banknotes 02, at least two, preferably all, of the aforementioned method steps can take place inline, i.e., the first method step of arranging the integrated circuits 04 in the correct position or with register accuracy on the band-shaped foil 06 and/or the second method step of applying or arranging the integrated circuits 04 in the apertures 03 of the banknotes 02 and/or the third method step of fixing the integrated circuits 04 arranged in the apertures 03 and/or printing the sheets 01 including the banknotes 02 or printing the material web including the banknotes 02 and/or singulating the copies of the banknotes 02 produced in the production panel, preferably take place in the same production machine, in particular in a rotary printing press used in security printing.

While a preferred embodiment of a method for producing banknotes including, in each case, at least one integrated circuit, in accordance with the present invention, has been set forth fully and completely hereinabove, it will be apparent to one of skill in the art that various changes could be made thereto without departing from the true spirit and scope of the present invention which is accordingly to be limited only by the appended claims.

Claims

1-25. (canceled)

26. A method for producing banknotes (02) including in each case at least one integrated circuit (04), the banknotes (02) being produced from a sheet (01) or from a material web in a production panel, at least in a plurality of or in each of these banknotes (02) an aperture (03) being created through their substrate (18), in each case an integrated circuit (04) being arranged in the relevant aperture (03), in a first method step each of the integrated circuits (04) to be arranged in one of the apertures (03) being arranged, with respect to the intended position in each of the banknotes (02) that includes an aperture (03), in the correct position on a band-shaped foil (06), and in a second method step each of these integrated circuits being transferred from this band-shaped foil (06) onto the relevant banknote (01), owing to this transfer that is carried out in the second method step one integrated circuit (04) in each case being arranged in the apertures (03) created in the banknotes (02).

27. The method according to claim 26, characterized in that the respective aperture (03) on each of the banknotes (02) is created in each case by die cutting or by laser cutting.

28. The method according to claim 26, characterized in that each of the integrated circuits (04) to be arranged in one of the apertures (03) created in the relevant banknotes (02) is in each case configured as a microchip encapsulated in a dedicated housing and/or that in each case an RFID tag is used as the integrated circuit (04).

29. The method according to claim 26, characterized in that each of the integrated circuits (04) to be arranged in one of the apertures (03) created in the relevant banknotes (02) in each case has a surface area having an edge length (104) of no more than 1 mm×1 mm and/or that an integrated circuit (04) having a structural height of no more than 90 μm is used or that an integrated circuit (04) having a structural height in the range between 25 μm and 50 μm is used.

30. The method according to claim 26, characterized in that the aperture (03) in the relevant banknote (02) in its respective expansion is in each case configured to be between 10% and 100% greater than the respective edge length (104) of the relevant integrated circuit (04).

31. The method according to claim 26, characterized in that, in the first method step, the integrated circuits (04) are arranged on the band-shaped foil (06) assisted by blower air and/or that, in the first method step, the integrated circuits (04) are fixed in their respective position on the band-shaped foil (06) electrostatically and/or by way of adhesion.

32. The method according to claim 26, characterized in that, as the second method step is being carried out, or immediately after the second method step has been carried out, the band-shaped foil (06) is joined to the substrate (18) of the banknotes (02) of the relevant sheet (01) or of the relevant material web.

33. The method according to claim 26, characterized in that a two-layer foil is used as the band-shaped foil (06), as the second method step is being carried out, or immediately after the second method step has been carried out, a first layer (16) of the band-shaped foil (06) being joined to the substrate (18) of the banknotes (02) of the relevant sheet (01) or of the relevant material web, the integrated circuits (04) adhering to the first layer (16).

34. The method according to claim 33, characterized in that a second layer (17) of the two-layer band-shaped foil (06) is made of paper or a plastic.

35. The method according to claim 26, characterized in that a foil including a hologram and/or a Kinegram is used as the band-shaped foil (06) and/or that a metallic foil or a metallized foil is used as the band-shaped foil (06) and/or that a security foil to be arranged on the substrate (18) of the banknotes (02) is used as the band-shaped foil (06).

36. The method according to claim 26, characterized in that, in a third method step, the integrated circuits (04) arranged in the respective apertures (03) are fixed therein, this fixation being carried out using a printing method.

37. The method according to claim 36, characterized in that an electrically non-conducting printing fluid (21) is applied by way of the printing method and/or that an ink jet printing method or a screen printing method is used as the printing method.

38. The method according to claim 26, characterized in that, in the third method step, the integrated circuits (04) arranged in the respective apertures (03) are fixed therein, this fixation being carried out by rolling or hot stamping a cover foil (23) onto the substrate (18) of the relevant banknotes (02).

39. The method according to claim 26, characterized in that information about the currency and/or the value of the relevant banknote (02) and/or information about the issuing bank of this banknote (02) is stored in the integrated circuit (04) and/or that information as to whether this banknote (02) was already brought into circulation, or when this took place, is stored in the integrated circuit (04).

40. The method according to claim 26, characterized in that at least two of the method steps to be carried out during the production of banknotes (02) including in each case at least one integrated circuit (04), namely the first method step of arranging the integrated circuits (04) in the correct position on the band-shaped foil (06) and/or the second method step of arranging the integrated circuits (04) in the apertures (03) of the banknotes (02) and/or the third method step of fixing the integrated circuits (04) arranged in the apertures (03) and/or printing the sheets (01) including the banknotes (02) or printing the material web including the banknotes (02) and/or singulating the copies of the banknotes (02) produced in the production panel, are in each case carried out inline in the same production machine.