ES2287405T3 - SECURITY DOCUMENT WITH MEANS OF AUTHENTICATION AND METHOD FOR AUTHENTICATION OF SECURITY DOCUMENTS. - Google Patents

Abstract

A security document according to the invention comprises substrate means 2 and security means 5 for authentication provided on a predetermined area 4 of said substrate means. The security means comprises means selectively reflecting visible light depending on the temperature and means changing the temperature depending on the application of a magnetic field. The means selectively reflecting light and the means changing the temperature are arranged as to form said security means exhibiting different colors depending on a magnetic field applied to the substrate means. In a preferred embodiment of the invention, the means selectively reflecting visible light comprises liquid crystals and the means changing the temperature comprises gadolinium. <IMAGE>

Description

Security document with means of authentication and method for document authentication of security.

The present invention relates to a document security that includes security means for authentication  of the security document. In addition, the invention relates to a method for authentication of a security document.

Identification and authentication of documents security, for example banknotes, passports, cards identification, checks, stocks, bonds etc., is a problem for a long time. In order to achieve this goal, they have developed security means to allow users and / or machines distinguish between real and false banknotes and / or distinguish between different banknote values. Between the techniques adopted are the use of special papers, inks special, special patterns, the inclusion of security threads and also of watermarks.

With respect to the decreasing price and therefore the increasing availability of advanced playback equipment, it may be feared that printed copies of documents will occur of security. Depending on the degree of criminal expertise, some reproductions could not only fool the general public which uses security documents but also to machines of validation used for the evaluation of documents of security.

A method to generate a printed image that does not can be reproduced on a security document described in WO 01/69915 A2. The ink to be used reflects light from predetermined wavelengths.

Document DE 29 09 731 A describes a ticket of bench that comprises a material that changes the color depending of temperature as well as a material that changes the temperature depending on the application of an alternating electric field. He Temperature changing material consists of metallic particles. The metallic particles are heated inducing currents of Foucault

WO 02/25600 A2 discloses means of safety comprising an oscillating circuit that generates heat by means of a specific energy dissipation when exposed to an electromagnetic AF radiation. In addition, security means comprise a specific indicator reaction that changes its color depending on the temperature produced by the circuit oscillator.

It is an objective of the present invention provide a security document, in particular a ticket bank, which allows document authentication and which is not possible to reproduce it by making a photocopy or scanning and printing or other unauthorized reproduction.

A further objective of the present invention is to provide a method that allows an authentication of a Security document with high security.

The above objectives are solved with the characteristics of claims 1 and 8, respectively. The preferred embodiments are the subject of the claims independent.

The security document and the method according to the invention are based on a color change of a material depending of temperature and temperature change of other material depending on a magnetic field based on the effect magnetocaloric The person skilled in the art knows both physical or chemical effects of this type in other fields technicians

The combination of the above physical effects or chemical allows to change the color of a safety medium depending on the intensity of a magnetic field applied to a substrate on which or on which the medium of security.

The main advantage of the security document and the method according to the invention is that the security means do not can be reproduced by photocopying the document or by scanning and printing, even if the copy or print is the most high quality. In addition, the security document and method allow document authentication simply by applying a field magnetic and putting the document against the light. Color change It must be observed with the naked eye.

For the general public, recognition of the Authenticity of a document will be very easy. The effect of the change color will not occur on any copy, reproduction and, in In general, unauthorized printing of the original document is not possible since only one fixed aspect can be reproduced.

In a preferred embodiment of the invention, the means selectively reflecting visible light depending on the temperature comprise liquid crystal (LC, liquid crystals). The ability to display colors is a widely known attribute of liquid crystals. It is an aspect of the invention that the color change of the liquid crystal occurs in a temperature range of -50 to + 60 ° C depending on the specific LC used, preferably from -20 to + 40 ° C, more preferably from 15 to 25 ° C. If the liquid crystal changes its color at room temperature, authentication is possible without heating or cooling the security document.

In a further preferred embodiment, the media that change the temperature depending on a magnetic field They comprise gadolinium (Gd). The gadolinium is paramagnetic to room temperature and quickly becomes ferromagnetic with a Very high magnetic moment at lower temperatures. This transition occurs in a small interval around the so-called Curie temperature, and therefore implies a very variation large magnetization near the transition point. Whether apply a magnetic field adiabatically to a sample of Gd, its Temperature increases a few degrees. In the same way, if interrupts the applied magnetic field, then the temperature of The sample decreases.

An important advantage of gadolinium is that it produces the magnetocaloric effect in the temperature range preferred, that is, at room temperature, and the temperature of the gadolinium changes under the variation of magnetic fields relatively small

The media that reflect light selectively and the means that change the temperature can be formed as a mixture of gadolinium particles and liquid crystals in a Good thermal contact In a preferred embodiment, the means that selectively reflect light and the media that change the temperature are embedded in an ink suitable for gravure, lithographic printing, silk screen, by jet ink, flexography, rotogravure printing or any other printing technique For example, liquid crystals and the Gadolinium may be embedded as small particles (micro or nanoparticles) in the ink. The inclusion of these elements assets in an ink allows the production of documents from security with relatively low costs incurred.

A further aspect of the invention is provide an ink for a multicolored print, for example, four color printing using four different inks, each ink having a different color, for example yellow, red, blue and black at the same preferred temperature. Therefore a Printed image using the different inks may appear at the preferred temperature and disappears at other temperatures.

According to a specific embodiment, the document Security is a banknote.

In order to illustrate the present invention, show in the attached figures a preferred embodiment currently; it being understood that the invention is not limited to the precise arrangement and procedures shown.

Figure 1 shows the thermal variation of the saturation magnetization of a gadolinium sample for the purpose of illustration;

Figure 2 shows the thermal dependence of the dM / dT derivative of gadolinium for purposes of illustration;

Figure 3 shows the curves of isothermal demagnetization of the gadolinium sample for the purpose of illustration;

Figure 4 shows the entropy change magnetic for illustration purposes;

Figure 5 shows the coefficient of transmission of a liquid crystal against the wavelength of the  light at various temperatures for the purpose of illustration, and

Figure 6 shows a schematic view of a banknote comprising substrate media and media safety according to the invention.

The functional principle of changing media the temperature depending on a magnetic field is based on the magnetocaloric effect

The magnetocaloric effect is the change in temperature produced when a magnetic field variation is applied to a magnetic material. It can be measured as the change in adiabatic temperature or as the change in isothermal magnetic entropy ΔSM. The change in magnetic entropy of the system is related to the change in magnetization M as a function of temperature, T , and magnetic field, H , and can be calculated from the magnetization data using the widely known Maxwell relationship.

\Delta S_ {M} (T, H) = \ int (dM / dT) H dH.

The integral of the previous equation must be performed in the interval between H_ {max} and H_ {min}. It will be observed  a high magnetocaloric effect when magnetization varies sharply in a constant field. In this way, it can be observed a high change in entropy in the transition from ferro phase to paramagnetic when the magnetization drops sharply in the Curie temperature

The gadolinium is paramagnetic at temperature atmosphere and quickly becomes ferromagnetic with a moment Very high magnetic at lower temperatures. This transition is produces in a small interval around the so-called temperature of Curie and implies a very large variation of the moment magnetic.

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Figure 1 shows the magnetic moment of the gadolinium as a function of temperature when a magnetic field µH0 = 0.3 T. A sheet of gadolinium with a purity of 99.9% and 0.25 mm thick with a 16 mg mass The maximum negative variation of the magnetic moment is produces at 293 K which corresponds to the previous Curie temperature above which gadolinium behaves as a substance paramagnetic Figure 2 shows the thermal dependence of the dM / dT derivative of gadolinium to illustrate the rapid variation of the magnetization at approximately Curie temperature (293 K).

3 shows isothermal demagnetization curves in a temperature range from 285 K to 305 K with temperature step of 1 K. The magnetic entropy change was calculated from these values of magnetization at temperatures T {i} and T i + 1 respectively, under an applied magnetic field of intensity 00 H = 1T. Figure 4 shows the experimental values of the magnetic entropy change obtained from the experimental isothermal magnetization curves under a variation of the 1T magnetic field from saturation to a zero magnetic field. It is observed that the value of the maximum entropy change reaches approximately the Curie temperature.

The combination of color change induced by liquid crystal temperature and magnetocaloric effect of gadolinium is illustrated with the following experiment.

The gadolinium sample was surrounded with a crystal liquid with a widely known color change in the range of temperature between 292.9 and 294.6 K. Figure 5 shows the transmission coefficient of the liquid crystal against the wavelength of light at various temperatures that oscillate from 19.8 to 21.6 ° C.

The temperature change produced in the sample of Gd at the maximum entropy change is approximately 1.5 K also resulting in the cooling of the liquid crystal that surround the sample of Gd. As a consequence of this process, detected a color change in the liquid crystal. This process is reversible, it shows neither hysteresis phenomena nor effects of memory and is very fast.

In the experiments of color changes induced by magnetocaloric effect are put together the Gadolinium and the liquid crystal. The sample was prepared from a 1.5 x 2 cm2 sheet of gadolinium with a thickness of 0.25 mm One side of this sheet was covered with a thin film of liquid crystal. Sample temperature was controlled putting it in thermal contact with a Peltier plate. The effect Peltier consists of the production or absorption of heat as consequence of the application of an electric current through of the union of two different semiconductors. The address of the Current determines which side of the plate is heated or cooled. The Peltier effect is the opposite of the thermoelectric effect (or Seebeck). The current applied to the Peltier plate was chosen (approximately 0.3 amps in the experiments) in order to get a greenish blue color of the liquid crystal. The Peltier plate used in the experiments presents a temperature gradient very small (approximately 0.2 ° C) along its surface. This did not allow to observe a homogeneous color in the liquid crystal. A commercial NdFeB magnet of 1 tesla of 5 x 5 x 2.5 was used cm3 in size to magnetize the sample.

In the final experimental setup, it placed a thin glass plate (0.25 mm thick) between the Peltier plate and Gd sample to reduce thermal contact. This allowed to maintain the induced temperature difference for a few seconds The same effect can be obtained using, for example, a piece of paper.

The temperature of the sample was stabilized with that of the Peltier plate. The magnet was placed near the sample. The Sample temperature began to rise until the sample reached its maximum temperature so that the sample became violet blue. The temperature began to slowly decrease until which stabilized with the Peltier plate. The magnet was removed and the Sample temperature began to decrease so that the Sample turned red. The duration of this color change was enough to be seen with the naked eye.

Figure 6 shows the front of a document 1 security according to the invention, which is a banknote in the preferred embodiment Banknote 1 comprises a substrate 2 suitable printing, for example made of a sheet of paper. Be provides a print 3 of graphic design on the front and on the back of the substrate.

Print 3 graphic design on the side front comprises a rectangular zone 4 on which is provided a visible security pattern 5.

According to a first embodiment, the pattern of security consists of a sheet of Gd with a thickness of 0.25 mm. One side of this sheet is coated with a thin glass film liquid with a color variation centered on the temperature of Curie. This interleaved structure is applied on or embedded in the Banknote substrate.

According to an alternative preferred embodiment of the invention, the security pattern is printed on the substrate using an ink in which the liquid crystals are embedded and gadolinium as active elements (micro or nanoparticles). He Security pattern is printed using any one of the widely known printing techniques.

When you look at the banknote to simple view, security pattern 5 appears as an impression colored rectangular If a magnet is placed near the substrate on the one that prints the safety pattern, the temperature of the liquid crystals increase as a result of temperature Gadolinium crescent so that the safety pattern changes, for example, the color turns violet blue. When the magnet, the temperature of the liquid crystals decreases as result of the decreasing temperature of the gadolinium so that the color of the security pattern changes again, for example the Color turns red.

Claims (14)

1. Security document comprising means (2) of substrate and security means (5) for authentication provided in a predetermined area (4) of said substrate means, said security means (5) comprising means reflecting visible light selectively depending on the temperature and means that change the temperature depending on the application of a magnetic field, said means being disposed reflectively visible light and said means changing the temperature to form said security means (5) that they exhibit different colors depending on a magnetic field applied to the substrate media, characterized in that the functional principle of said media that changes the temperature depending on the application of a magnetic field based on the magnetocaloric effect. 2. Security document according to claim 1, characterized in that said means reflecting visible light selectively comprises liquid crystals. 3. Security document according to claim 1 or 2, characterized in that said temperature changing means comprise gadolinium. 4. Security document according to one of claims 1 to 3, characterized in that said means reflecting selectively visible light and said temperature changing means are embedded in an ink deposited on said predetermined area of the surface of said substrate means . 5. Security document according to one of claims 1 to 4, characterized in that the temperature range in which the media reflect light selectively is in the range of -50 to + 60 ° C, preferably -20 to + 40 ° C, more preferably from 15 to 25 ° C. 6. Security document according to one of claims 1 to 5, characterized in that said substrate means (2) comprise one or more materials selected from a group consisting of pals, plastics, polymers, metal sheets and metal alloy sheets. 7. Security document according to one of claims 1 to 6, characterized in that said security document is a banknote. 8. Method for authenticating a document of security that includes the following stages: provide means that reflect visible light from Selectively depending on the temperature and changing media the temperature depending on the application of a field magnetic, arrange said means that reflect visible light selectively and such means that change the temperature depending on the application of a magnetic field, to form security means that exhibit different colors depending on a magnetic field applied to substrate media, provide such security means on or in said substrate media, and apply a magnetic field to said substrate media, characterized in that the functional principle of said media that changes the temperature depending on the application of a magnetic field is based on the magnetocaloric effect. Method according to claim 8, characterized in that said means reflecting visible light selectively comprise liquid crystals. A method according to claim 8 or 9, characterized in that said temperature changing means comprise gadolinium. Method according to one of claims 8 to 10, characterized in that said means reflecting visible light selectively and said temperature changing means are embedded in an ink and said ink is deposited on said predetermined area of the surface of said means of substrate. 12. Method according to one of claims 8 to 11, characterized in that the temperature range in which the media selectively reflects visible light is in the range of -50 to + 60 ° C, preferably from -20 to + 40 ° C, more preferably from 15 to 25 ° C. 13. Method according to one of claims 8 to 12, characterized in that said substrate means comprise one or more materials selected from the group consisting of papers, plastics, polymers, metal sheets and metal alloy sheets. 14. Method according to one of claims 8 to 13, characterized in that said security document is a banknote.