WO2005095708A2 - Security document - Google Patents

Abstract

The invention relates to security documents (1), particularly banknotes, comprising at least one security feature (2) and a window (2), in addition to security paper for the production of said security documents and a method for authentication of said security documents. A verification element (5) checks the security feature (3) via the window (2). The verification element (5) is transparent in the visible spectral range and has one or several partial areas (7) which absorb or reflect in at least one spectral area of the non-visible spectrum. The security feature (3) has a visually perceptible color effect, which is visible through the verification element, when it is irradiated with at least one wavelength from the non-visible spectral range, thereby making it possible to verify the authenticity of the security document (1).

Description

 value document

The present invention relates to documents of value _/ in particular banknotes, with at least one visually verifiable security feature, as well as a security paper for producing such documents of value and a method for checking the authenticity of these documents of value.

Documents of value in the sense of the present invention are banknotes, identity cards, admission tickets, tickets, driver's licenses, shares and the like. Such documents of value have security features in order to increase their security against forgery and to ensure their authenticity check.

WO 03/054297 describes a document of value, in particular a bank note, with a through opening which is produced by paper technology. The opening is already created during the sheet formation of the security paper, from which the value document is then produced. Such an opening is characterized by its irregular edge structure. In one embodiment, the opening is closed with a security element projecting beyond the opening. In this case, the security element consists, for example, of a transparent plastic film on which security features that can be checked visually and / or by machine can be applied.

WO 98/15418 describes a self-authenticating banknote with a window made of transparent plastic. A security feature is applied to the banknote, which can be checked with the window when the window is folded onto the security feature. The security feature can be, for example, a micro script that is only readable, when the window is over the writing. In a special embodiment, the plastic film of the window is a polarizing film. This film can be used to check a polarizing authenticity feature applied to the banknote.

In order to be able to continue producing counterfeit-proof documents of value, there is a constant interest in the development of new security features that are easy to check and difficult to imitate.

The object of the invention is therefore to create a new authenticity feature for a self-authenticating value document.

This object is solved by the features of the independent claims. Further training is the subject of the subclaims.

The document of value according to the invention comprises at least one security feature and a window which has a verification element which serves to check the security feature and is transparent in a visible spectral range. The verification element has one or more sub-areas which are transparent in the visible spectral range, but which absorb or reflect in at least one non-visible spectral range. At the same time, this means that the corresponding other areas of the verification element are transparent both in the visible and in the at least one non-visible spectral area. When irradiated with at least one wavelength from this invisible spectral range, the security feature produces a color effect in the visible spectral range for which the window is transparent. During the authenticity check, the verification element of the value document is brought over the security feature, for example by folding the value document, and the security feature is then irradiated through the verification element with radiation from the invisible spectrum, for which individual partial areas of the verification element are absorbing or reflecting , Therefore, at least some of the radiation does not pass through the verification element in these partial areas and thus does not reach the security feature in these partial areas. In the other areas of the security feature, on the other hand, the radiation that passes through the verification element to the security feature produces a color effect in a spectral range for which the verification element is transparent. This means that the security feature emits visually perceptible radiation, which passes through the verification element and can therefore be perceived by an observer through the verification element. Since only part of the security feature is excited to produce the color effect, the security feature remains essentially unchanged among the absorbing or reflecting areas of the verification element. This creates a color contrast visible through the verification element between the irradiated and the non-irradiated or less irradiated areas of the security feature.

This authenticity feature is relatively simple to implement and easy to verify, but it is inconspicuous - because the absorbing partial areas of the verification element are not visually perceptible - and difficult to imitate - because the individual spectral areas of the verification element and the security feature must be exactly coordinated. The absorbing / reflecting partial areas of the verification element can form a motif characteristic of the value document. Methods for applying the motif can be, for example, printing, transfer of a printing layer, vapor deposition or transfer of a vapor-deposited layer in a known manner. If the motif is printed on the verification element, pigments or liquid crystal multilayers can be used as printing layers.

The motif applied to the verification element can, for example, represent a clear text. The absorbing partial areas can define either the motif (positive writing) or the areas around the motif (negative writing). This creates two opposite effects. In the case of positive writing, the motif becomes visible as a negative when irradiated with the corresponding wavelength, whereas in the case of negative writing, the motif becomes visible as a positive. In the first case, the motif absorbs the radiation before it hits the security feature. In the second case, the motif transmits the radiation, as a result of which only the areas of the security feature are excited to produce a color effect and become visible through the verification element, which are located below the motif.

Known security features, which may already be included in the value document, can serve as a security feature on the value document. These are, for example, luminescent substances, in particular fluorescent substances, contained in the imprint or in the substrate material of the value document, which luminesce when excited with radiation from a specific wavelength range of the invisible spectrum and thereby Emit radiation in the visible spectral range. However, thermochromic properties can also be used as a security feature. This means that a visible discoloration occurs when heated, for example when irradiated with a wavelength in the IR range.

In a first embodiment, the verification element is a transparent plastic film with an IR or UV absorbing imprint. The security feature is luminescent in one or more colors under I_R or UV radiation. In order for the absorbing imprint to be visible as a negative image, the imprint must at least partially absorb a certain area of the wavelength range provided by an IR / UV radiation source and the plastic film as such must at least partially transmit this particular area of the wavelength range provided by the IR / UV radiation source , Furthermore, the security feature contains a fluorescent substance which is excited by the transmitted wavelength range and emits radiation in the visible wavelength range. This radiation can be seen by a viewer through the transparent plastic film in the visible. In order to show colored images, different fluorescent substances which emit different fluorescent colors can be used. The different fluorescent substances can be mixed or divided into individual motif areas. They are excited by several individual wavelengths or a wavelength range.

The radiation source is arranged so that it shines through the window when the window with the verification element is arranged over the security feature. For example, mercury can be used as the UV radiation source. Silver vapor lamps with different pressure and with or without different doping, or UV light emitting diodes are used ". Certain radiation areas are absorbed in the absorbing partial areas, and the radiation is transmitted through the window to the security feature in the other areas. The transmitted Radiation stimulates the fluorescent substances differently at the points where it strikes the security feature, and the light emitted by the fluorescent agents passes back through the window to the observer, who compares the areas of the security feature located under the absorbing partial areas as relative perceives dark spots.

In a second embodiment, the verification element is a plastic film with an IR or UV reflecting print. When using a printed or transferred liquid crystal multilayer system, for example IR reflecting properties can be realized. Analogous to the first embodiment, certain wavelength ranges of an IR radiation source are then reflected by the IR-reflecting partial areas. In the non-IR reflecting areas, the IR radiation is transmitted through the film and strikes the security feature when the window is at least partially above the security feature. In this case, the fluorescent substances of the security feature are excited and emit light in the visible wavelength range, so that a user perceives the IR-absorbing imprint as a colored image hidden in the security feature when the emitted radiation is transmitted back again through the plastic film. In a third embodiment, the security feature has thermochromic properties. This means that if radiation hits the security feature, it changes color according to the temperature increase achieved by means of thermal radiation. If, as in the two embodiments just described, the motif is applied to the plastic film as an IR-absorbing or IR-reflecting print, this print at least partially blocks the transmission of the radiation from an IR radiation source. In the transmitting areas of the plastic film, however, the radiation is transmitted depending on the IR permeability of the film and strikes the thermochromic layer. In the areas of the security feature that the transmitted IR radiation encounters, the temperature of the thermochromic layer rises depending on the amount of radiation. The temperature increase causes the irradiated areas of the security feature to change color. The motif is thus visible as a negative image in the security feature, since the areas of the security feature below the IR-blocking areas of the motif are not stimulated to change colors. On the other hand, it is also possible to design the motif on the verification element to be transparent to IR radiation and to design the other areas which are not part of the motif to be IR-blocking. Then the motif becomes visible as a positive image hidden in the security feature when exposed to IR radiation.

The window in the value document, which is used with the verification element to check the security feature and is transparent in the visual spectral range, can be produced in different ways. First, the value document must have at least one through hole. In a first variant, the through hole is produced using paper technology. That is, the hole is created during sheet formation, i.e. during paper manufacture. Such a method is described in WO 03/054297 A2. The advantage of the through hole produced by paper technology is that the edge region of the hole has characteristic irregularities which cannot be subsequently produced on the finished paper, which increases the security against forgery. “Irregularities” means that the edge of the hole is not a sharp cut edge, but that paper fibers are arranged irregularly in the edge region of the hole. These irregularities can usually be checked with the naked eye or at least with a magnifying glass, which makes it easier to check the authenticity of the value document Way is possible.

In a second variant, the through hole is only produced after the paper production by punching out or cutting out an area. The advantage of this embodiment is that the hole can be produced with very little effort and the hole size or shape can be individually adapted to special conditions.

After the hole has been made, the plastic film is applied to the document of value in order to close the window according to the invention. As mentioned, this plastic film is transparent in a visual spectral range and partially absorbent or reflective in a non-visible spectral range. The film can have a size that projects beyond the hole by a certain amount on all sides. It is advantageous if the document of value has a recess into which the film is fitted, so that the advertising document has a stepless surface after the film has been applied. In order to obtain a stepless surface, the plastic film can also completely cover the valuable document. The recess for fitting the Tolie can be compressed by compressing the value document onto the corresponding one! Places are created, or are already provided during the paper production. In this case, sheet formation is hindered at the corresponding points, which creates thinner points in the paper.

The film can either be glued on or laminated onto the value document using hot stamping technology. This is possible on both sides. Furthermore, instead of a single through hole, a plurality of through holes can also be provided. Each hole can have its own contour, which means, for example, that a certain motif is formed by the totality of the holes. Several holes can be produced according to the production variants already described.

In a fourth embodiment, the document of value essentially consists of one or more plastic films and the verification element is part of this plastic film. In this case, there is no need for a through hole in the value document. The part of the plastic film which forms the verification element then has the properties according to the invention. This means that the verification element is transparent to a visible spectral range and has one or more partial ranges that absorb or reflect at least one spectral range of the invisible spectrum. Furthermore, this is on the plastic film security feature according to the invention provided. When irradiated with at least one wavelength, this security feature produces a color effect from the at least one spectral range of the invisible spectrum.

Furthermore, the value document of all of the above-mentioned embodiments can of course have one or more other known security features. For example, an optical diffraction structure, a security thread or a watermark can be used. It is also possible to combine luminescent and / or thermochromic color effects according to the invention with one another by means of IR and / or UV radiation.

The security according to the invention can be produced from a security paper which has some or all of the security document properties described above. Security paper is typically made in wide webs where multiple rows of panels are juxtaposed. After completion, the sheets are cut into sheets on which there are several uses. This sheet-like security paper is printed and then cut into individual pieces, an individual piece defining a single document of value. The security feature to be checked is preferably either introduced during paper formation, for example in the form of luminescent fibers, or is generated when the security paper is printed. The window film is preferably only applied to the finished sheets. However, it is also conceivable to embed them into the paper in the same way as a broad security thread in paper production. - left

paper formation is automatically prevented. A value document produced from the security paper according to the invention then has all the properties described above.

Further features and advantages of the invention result from your description of various exemplary embodiments and alternative embodiments according to the invention in connection with the accompanying drawings. In it show:

1 shows a document of value in supervision, comprising a security feature and a window;

FIG. 2 shows the document of value from FIG. 1 in cross section along the line A-A;

3 shows a document of value in cross section, which essentially consists of a plastic film with an imprint; and

Fig. 4 shows a document of value according to Figures 1 and 2 in cross section, which is folded so that the window lies over the security feature.

FIG. 1 shows a document of value 1 according to the invention in plan view. In the exemplary embodiment shown, it is a banknote. This bank note 1 has a window 2 and a security feature 3. The I window 2 is a through hole in the bank note 1, which in the exemplary embodiment shown is closed with a verification element 5. FIG. 2 shows the bank note 1 from FIG. 1 in cross section along the line AA. The window 2 was produced during the production of the security paper used for the banknote 1 and therefore has a fibrous, irregular edge structure 6. This edge structure 6 arises during the production of the security paper and can therefore not be reproduced by subsequently punching or cutting the paper.

The verification element 5 is essentially formed by a plastic film which is transparent in the entire visible spectral range. It also has one or more printed partial areas 7, which absorb or reflect in at least one spectral range of the invisible spectrum, but are transparent in the visible spectral range.

FIG. 2 shows that the window 2 in the banknote 1 is a through hole. The window 2 is closed on one side by the verification element 5. In the exemplary embodiment shown, the verification element 5 is fixed on a surface of the banknote 1 by means of an adhesive layer 8. Alternatively, the verification element 5 can also be glued into a depression surrounding the window 2. As mentioned, such a depression can be produced by subsequently compressing the paper fibers or by reducing the paper thickness during paper manufacture.

3 shows an alternative embodiment of a banknote 1 in cross section, which essentially consists of a transparent plastic film 10 that is visible. A printed image 11 with a recess 4 is applied to the film 10, the recess 4 defining the window 2. Within the Recess 4 is located in partial areas 7 of the absorbent imprints. The security feature (not shown) is located in or on the printed image 11. If the bank note 1 is now folded so that the window 2 lies over the security feature, the security feature will then pass through the window 2 and the transparent plastic 10 of the bank note 1 irradiated, at least some of the transmitted through the film 10 hits. Radiation on the security feature. At these points, the security feature is excited and emits radiation in the visually visible spectral range. In contrast, the locations of the security feature which lie below the absorbing partial regions 7 of the window 2 are not excited and thus appear as dark locations when irradiated.

4 shows a once folded banknote 1 according to FIGS. 1 and 2. The window 2 with the verification element 5 partially covers the security feature 3. The security feature is irradiated through the verification element 5. Since at least some of the radiation is partially absorbed or reflected in the verification element 5, the radiation is not completely transmitted through the window 2 and the verification element 5 to the security feature 3. A change in color of the security feature 3 accordingly occurs only in certain areas and can be seen through the window 2.

When irradiating the banknote, it is important to note that the absorber / reflector in the verification element only has to cover the spectral range which is emitted by the radiation source, transmitted by the film and absorbed by the security feature. In the example shown, the verification element 5 could be a PET film, for example. This type of film is transparent to radiation with a wavelength of 300 nm to at least 750 nm. This spectral range contains part of the UV spectrum and the entire visible spectrum (approx. 380 nm to 750 nm). In the present example, a UV radiation source supplies radiation in the wavelength range from 200 nm to 370 nm. A first fluorescent substance in security feature 3 absorbs radiation from 230 nm to 260 nm and from 350 nm to 380 nm. In order to prevent the fluorescence of the areas of security feature 3 , which lie below the absorbing partial areas, the verification element 5 has a UV absorber, which only absorbs between 350 nm and 370 nm. Because radiation with a wavelength of less than 300 nm is not transmitted through the PET film anyway. In addition, the use of further fluorescent substances in security feature 3 on bank note 1 is possible. In the example described here, for example, a second fluorescent substance can be used, which absorbs from 290 nm to 340 nm. The matching UV absorber in the verification element 5 should then absorb between 300 nm and 340 nm and absorb little or no absorption in the range between 350 nm and 370 nm in order to enable separate excitation of the two fluorescent substances. The two fluorescent substances used can emit in the entire visible range, with different fluorescent substances used also showing different fluorescent colors to achieve colored images. In order to generate multicolored fluorescence images, several excitation wavelengths or a range of excitation wavelengths are required, which can be easily implemented with corresponding radiation sources. A thermochromic layer on the document of value can be formed, for example, by encapsulated liquid crystals, which are advantageously located against a black background. The black background increases the absorption of the IR radiation, which is transmitted through the plastic film. This leads to an increase in temperature and thus to discoloration of the thermochromic layer. Since an IR-absorbing layer is already provided on the plastic film, there is also a temperature increase there under IR radiation. This heating of the plastic film could have an impact on the areas of the security feature that are not heated by the IR radiation due to the absorbing partial areas lying above them. However, the heating and thus the discoloration of the security material in these areas takes place much more slowly than in the areas that heat up around the IR radiation transmitted through the plastic film and discolour, so that the heating of the plastic film does not have any significant influence on the Discoloration of the security feature.

Claims

Patent claims

1. document of value (1) with at least one visually verifiable security feature (3) and a window (2) which has a verification element (5) which serves for visually verifying the security feature (3) and is transparent in a visible spectral range, characterized in that the verification element (5) has one or more partial areas (7) which absorb or reflect in at least one non-visible spectral range, the security feature (3) having a color effect when irradiated with at least one wavelength from the at least one non-visible spectral range generated in the visible spectral range.

2. Value document (1) according to claim 1, characterized in that the verification element (5) is a plastic film (9) with a UV-absorbing imprint.

3. The document of value (1) according to claim 2, characterized in that the security feature (3) is luminescent in one or more colors under UV radiation.

4. document of value (1) according to one of claims 1 to 3, characterized in that the verification element (5) is a plastic film (9) with an IR-absorbing print.

5. document of value (1) according to claim 4, characterized in that the security feature (3) is luminescent in one or more colors under IR radiation.

6. document of value (1) according to claim 4 or 5, characterized in that the security feature (3) has thermochromic properties.

7. document of value (1) according to one of claims 1 to 6, characterized in that the security feature (3) is formed by a printed image printed on the document of value (1).

8. document of value (1) according to one of claims 2 to 7, characterized in that the window (2) is a paper-technical hole in the document of value (1).

9. document of value (1) according to one of claims 2 to 7, characterized in that the window (2) is a punched hole in the document of value (1).

10. document of value (1) according to one of claims 1 to 7, characterized in that the document of value (1) consists essentially of a plastic film (10) and the verification element (5) forms part of this plastic film (10).

11. document of value (1) according to one of claims 1 to 10, characterized in that it is at least one of the following security Features: diffractive structure, security thread, watermark.

12. Security paper for producing a value document (1), comprising a security feature (3) and at least one window (2), which has a verification element (5) that serves to check the security feature (3) and is transparent in a visible spectral range characterized in that the verification element (5) has one or more sub-areas (7) which absorb or reflect in at least one non-visible spectral range, the security feature (3) when irradiated with at least one wavelength from the at least one non-visible spectral range creates a color effect in the visible spectral range.

13. Security paper according to claim 12, characterized in that the verification element (5) is a plastic film (9) with a UV-absorbing imprint.

14. Security paper according to claim 13, characterized in that the security feature (3) is luminescent in one or more colors under UV irradiation.

15. Security paper according to one of claims 12 to 14, characterized in that the verification element (5) is a plastic film (9) with an IR-absorbing print.

16. Security paper according to claim 15, characterized in that the security feature (3) is luminescent in one or more colors under IR radiation.

17. Security paper according to claim 15 or 16, characterized in that the security feature (3) has thermochromic properties.

18. Security paper according to one of claims 12 to 17, characterized in that the security feature 3 is formed by a printed image printed on the security paper.

19. Security paper according to one of claims 13 to 18, characterized in that the window (2) is a paper-technical hole in the security paper.

20. Security paper according to one of claims 13 to 18, characterized in that the window (2) is a punched hole in the security paper.

21. A method for checking the authenticity of a value document (1) according to one of claims 1 to 11, comprising the steps:

Folding the value document (1) so that the window (2) at least partially covers the security feature (3); and

Irradiating the security feature (3) through the window (2) with at least one wavelength from an invisible spectrum ral range, for which one or more sub-areas (7) of the window (2) are absorbent or reflective, and in which the security feature (3) produces a color effect in a visible spectral range for which the window is transparent.