DE10214369A1 - Value or security document with Seebeck or Peltier element - Google Patents

Abstract

The invention relates to a valuable document or security document (1) that comprises one or more LED elements (2) as a security feature. The LED element (2) is supplied with power by an energy source (3) via lines (4) and (5). Energy source (3) is preferably a passive energy source, that is a solar cell or an antenna. The invention allows for the provision of public features or biometric data for the purpose of identification and/or authentication by personalization of the LED element (2).

Description

The invention relates to a value or security document and a method for the production of such a value or security document.

It is known from the prior art to store value or security documents, such as banknotes, ID cards, driver’s licenses, stamps, Entry tickets, tokens, credit cards, check cards, shares, packaging and the like, to provide security features that counterfeit or make unauthorized modification of such documents difficult or even impossible to make impossible. In this sense, a "document" is also used in the following Product designated with a corresponding security feature is provided.

Well-known security features include watermarks. Such Watermarks are visible in the back light and then show a certain one Motive or a value number, such as the nominal value of the relevant Banknote.

Another security feature is the security thread. The The security check takes place in such a way that a darker line is visible in the backlight must become.

Furthermore, it is known to use special film strips with security features, such as applying holograms. Enable the holograms for example, that when tilting a banknote, depending on the Viewing angles, different symbols or numbers appear.

Furthermore, the use of Pearlescent stripes known. When tilting the banknote, this becomes a Example of gold-colored stripes visible in which a symbol and the respective Value number can be recognized. Such a pearlescent strip is for example on the 20 EURO note available.

From US 5,403,039 a printed document, such as. B. a Lottery ticket, known, which has a thermochromic layer. The thermochromic layer is applied over data printed on the document. to The thermochromic layer is heated by authentication touched with your finger, for example. If the document is real, come there is a reversible color change.

From US 5,826,915 is a security document with printed known thermochromic material. Rubbing turns the thermochromic Material warms up and then shows a corresponding security feature.

Furthermore, value or security documents are also from the prior art known that have a circuit:

From DE 69 50 9783 T2 a prepaid card is known which has a thin housing has, in which sound generating means for generating a preselected Tone pattern. There is also a power source in the housing, to supply the sound generating means with electrical current.

From DE 198 18 710 A1 a greeting card is known which a microphone for Has recording a voice message. The greeting card also has one Loudspeaker for playing the recorded voice message. The for Realization of the corresponding circuit required electrical components are interconnected by wires.

DE 42 20 762 A1 is a birthday card with an image display function known. For this purpose, a liquid crystal display and others are on the card Discrete components arranged, which are interconnected via wires are.

A security document is known from US Pat. No. 4,763,927, in which a Safety inlay with piezoelectric properties is located. The The presence of this inlay can be checked by contacting it from the outside.

The invention is based on the object, an improved value or Security document and an improved method of making a value or Creating security document.

The object underlying the invention is achieved with the features of independent claims each solved. Preferred embodiments the invention are specified in the dependent claims.

The present invention particularly makes use of the so-called Seebeck or use the Peltier effect:

The functional principle of the Seebeck effect is based on the fact that between two different metals that are brought into contact with one another Potential difference arises, which is called contact potential. This Contact potential is temperature dependent.

A Seebeck element can be realized in that at least two contact points are made between different metals and these contact points are connected to one another by a line. If the contact points are brought to different temperatures T _c and T _h , a voltage U, which is given by, can be tapped between the contact points

U = (Q _X - Q _Y ) (T _c - T _h ),

where Q _X and Q _{Y are} the so-called Seebeck coefficients of the different metals X and Y, which contact each other at the two contact points.

The Seebeck effect can be used to generate a tension that according to the invention for the voltage supply of a circuit of the value or Security document can serve.

The Peltier effect is based on a reversal of the Seebeck effect and is also referred to as thermoelectric cooling. For this purpose, an electrical voltage is applied across the contact points of two different conductors A and B. The voltage causes a temperature difference to occur between the contact points. The temperature difference T ₀ -T ₁ between the two contact points is as follows:

Where σ is the specific electrical conductivity, λ is the thermal conductivity and π _A and π _{B are} the Peltier coefficients of metals A and B.

According to the invention, such a Peltier element is used for converting electrical energy used in thermal energy so as a security feature to realize or to address.

According to a preferred embodiment of the invention, this is done in such a way that changed the temperature of a bimetal strip by means of the Peltier element which is on the value or security document for example is printed. By changing the temperature it comes due to the different coefficients of thermal expansion of the metals of the bimetallic strip to a bend of the bimetallic strip and thus to a deformation of the Value or security document.

For example, such a bimetal strip can be placed lengthwise on a banknote to be printed. Once the voltage source of the value or Security document is turned on, this creates a temperature difference that then due to the different coefficients of thermal expansion of the metals causes the banknote to curl up.

According to a further preferred embodiment of the invention, the temperature difference generated for a color change due to the Peltier effect used. For this purpose, an area of the value or security document is marked with a thermochromic ink or a film with a thermochromic dye applied. Does the temperature change due to the Peltier Effect in the area of thermochromic color, this leads to a Color change of the thermochromic color pigments. This effect is with sheer Eye visible; it is a so-called "public feature".

Preferred embodiments are described below with reference to FIG Drawings explained in more detail. Show it:

Fig. 1 is a block diagram of an embodiment of a value or security document with a Seebeck element,

Fig. 2 shows a first embodiment of the value or security document of FIG. 1,

Fig. 3 shows a second embodiment of the value or security document of FIG. 1,

Fig. 4 shows a third embodiment of the value or security document of FIG. 1,

Fig. 5 shows an embodiment of a value and security document with a Peltier element,

Fig. 6 is a partial view of an embodiment of value or security document of FIG. 5 with a thermochromic ink,

Fig. 7 shows an embodiment of the value or security document of Fig. 5 with a bimetal strip.

Fig. 1 shows a document 1. Document 1 is a value or security document, such as a bank note, a postage stamp, an identity card, passport, driver's license, label or the like. On the document 1 there is a printed circuit with an output or transmission unit 2 and an energy source 3 .

The energy source 3 is a passive energy source that is used to convert thermal energy into electrical energy. The energy source 3 is preferably based on the so-called Seebeck effect.

For this purpose, the energy source 3 contains two contacts, which are each formed between two different metals. As soon as a temperature difference is generated between the two contacts by supplying thermal energy, the energy source 3 converts this thermal energy into an electrical voltage due to the Seebeck effect. This electrical voltage is applied to the output or transmission unit 2 via lines 4 and 5 .

The output or transmission unit can be any security feature that requires electrical energy. The output or transmission unit 2 can be designed as a converter for converting the electrical energy supplied by the energy source 3 into another form of energy, such as light, sound or an electrical or magnetic field.

For example, the output or transmission unit has a light emitting diode that emits visible light as soon as the energy source 3 supplies an electrical voltage. An organic light emitting diode is particularly suitable for this. The production of suitable organic light-emitting diodes (OLEDs) is known per se from "OLED Matrix Displays: Technology and Fundamentals", Polytronic 2001, Conference Procedings, October 21-24, 2001.

It is particularly advantageous that OLEDs can also be printed on document 1 using various printing methods, for example by means of inkjet printing, screen printing, letterpress printing, gravure printing or planographic printing.

In a further embodiment, the output or transmission unit 2 is designed as an acoustic transducer. One possibility is the use of a so-called folding speaker. The production of a folding loudspeaker in film thickness is known per se from the prior art (http: / / www.heise.de, message of April 27, 2001 "folding loudspeaker for the pocket").

Alternatively, the output or transmission unit 2 is designed as an electroluminescent component. For this purpose, electroluminescent dyes or pigments are applied to document 1 . Such dyes can be excited in the electric field and return to their basic state under light emission. Such an electroluminescent element can be realized according to the invention by printing on an electroluminescent dye. Alternatively or additionally, electrochromic dyes are used, which are also printed on or applied using thin foils.

Polarization effects based on magnetic pigments can also be used be used to implement a security feature. The Polarization of paramagnetic pigments in an electrical field used. Alternatively, Liquid Christal Polymers (LCP) are used for this.

Alternatively, the output or transmission unit 2 can also have a coil for generating a magnetic field or a printed antenna in order to generate a field that can be detected from the outside.

A wide variety of physical and / or chemical conversion effects can therefore be used for the output or transmission unit 2 in order to convert at least part of the electrical energy supplied by the energy source 3 into another form of energy which is emitted by the output or transmission unit 2 in order to implement the security feature becomes. The authenticity of the document 1 can be checked on the basis of the energy emitted by the output or transmission unit 2 .

It is particularly advantageous to apply one or more elements of the circuit printed on the document 1 by means of printing ink in one print run. For example, an electrically conductive printing ink is used to implement conductor tracks or other electrically conductive structures of the circuit.

For example, an electrically suitable printing ink is suitable conductive polymer. Such electrically conductive polymers are inherently from the State of the art known (cf. Hans Hofstraat "Will Polymer Electronics Change the Electronics Industry? ", Polytronic 2001, Conference Proceedings).

The energy source 3 can also be realized in terms of printing technology by printing on pastes of different metals, such as copper and silver conductive paste, for example.

Printing at least parts of the circuit on the document 1 has the advantage that the circuit then forms an integral part of the document 1 and is particularly secure against manipulation. Furthermore, this also facilitates the handling of document 1 , since it can be bent, bent or folded. This is particularly advantageous for banknotes and similar applications.

Paper or a plastic film is particularly suitable as the carrier material for the document 1 , to which the circuit is at least partially printed.

FIG. 2 shows in detail an embodiment of document 1 of FIG. 1. In the embodiment of FIG. 2, document 1 has an energy source 3 designed as a Seebeck element. For this purpose, a first metal is applied to the document 1 in a strip-shaped area 6 .

Adjacent to area 6 is a likewise strip-shaped area 7 , to which a metal different from the metal of area 6 is applied. A region 8 adjoins the region 7 , to which the same metal as the metal of the region 6 is applied. A suitable choice of the different metals is, for example, copper and silver.

In one embodiment, there is 1 copper conductive paste on areas 6 and 8 of the document, while silver conductive paste is located on area 7 . However, the invention is not restricted to a particular choice of metals; the Seebeck effect basically works if two different metals are selected.

The metal paste of area 6 thus forms a contact area 9 with the metal paste of area 7 and the metal paste of area 7 forms a contact area 10 with the metal paste of area 8 . The temperature T ₁ prevails at the contact surface 9 and the temperature T ₂ prevails at the contact surface 10 . If there is no external influence, these temperatures T ₁ and T ₂ are essentially the same as the ambient temperature. In this case, no voltage is generated by the energy source 3 .

By placing a finger 11 of a user of the document 1 on the contact surface 9 , thermal energy is supplied there when the temperature of the finger (approx. 36 °) is higher than the ambient temperature.

There is then a temperature T ₁ of approximately 36 °, while the temperature T _{2 is,} for example, 20 ° room temperature. Because of this temperature difference, the energy source 3 generates a voltage due to the Seebeck effect which then becomes effective and is applied to the output or transmission unit 2 via the lines 4 and 5 .

In the exemplary embodiment considered here, the output or transmission unit 2 has an electroluminescent or electrochromic color 12 which changes color when the voltage supplied by the energy source 3 is applied or when the corresponding thermal current flows.

Depending on the color 12 used , this color change can be permanent or self-reversible. In the former case, the color change is retained even if the finger 11 is removed from the contact surface 9 and the energy source 3 can no longer supply thermal voltage. In the second case, after the finger 1 is removed from the contact surface 9, the color 12 changes again to the starting color.

If the color change is not self-reversible, such a color change back to the starting color can be provoked by removing the finger 11 from the contact surface 9 and instead placing it on the contact surface 10 , so that the energy source does, however, have a thermal voltage of the same level provides opposite polarity. This opposite polarity then causes the color 12 to return to its original color through a color change.

An alternative use of the document 1 in FIG. 2 is shown in FIG. 3. In this use of the document 1 , two different thermal energy sources are used, namely the finger 11 and a further external energy source 13 , which supplies thermal energy. The external energy source 13 can be a laser, for example, which emits a laser beam 14 for applying a temperature.

The two thermal energy sources, that is to say the finger 11 and the external energy source 13 , serve to produce a temperature difference between the contact surfaces 9 and 10 which is largely independent of the ambient temperature. For this purpose, the finger 11 is placed on the contact surface 9 , so that the temperature T ₁ of approximately 36 ° C. is established there.

On the other hand, the contact surface 10 is irradiated with a defined energy by the laser beam 14 , so that a certain temperature T _{2 is} established there. Because of this, the energy source 3 supplies a thermal voltage that is essentially independent of the ambient temperature, so that the security feature implemented by the output or transmission unit 2 can be checked under all circumstances.

In a further exemplary embodiment, the structure of the value or security element described with reference to FIG. 3 can also be used in two stages. In a first stage, only the finger is placed on the contact surface 9 , so that the temperature T _{1 is} established there. Analogous to the exemplary embodiment described with reference to FIG. 2, ambient temperature is present on the second contact surface. This temperature difference causes a first thermal voltage, which is applied to the output and transmission unit 2 and, for example, produces a first color change. In a second stage, as described above, the energy source 13 is now directed onto the contact surface 10 , so that a temperature T _{2 is} established there. There is ambient temperature at the other contact surface. This results in a second temperature difference, which generates a second thermal voltage, which at this stage is also applied to the output and transmission unit 2 . This second thermal voltage could, for example, cause a second color change in the output and transmission unit 2 , which can then be detected, for example, by machine.

FIG. 4 shows another possible use of document 1 of FIG. 2. In this case, a defined temperature difference between the temperature T _{1 of} the contact surface 9 and the temperature T _{2 of} the contact surface 10 is only produced by the external energy source 13 . For this purpose, the external energy source 13 is again preferably designed as a laser.

The laser beam 14 then alternately sweeps over the contact areas 9 and 10 in rapid succession, the average residence time of the laser beam 14 on the contact area 9 being shorter, for example, than on the contact area 10 , so that the temperature T _{1 is} less than the temperature T ₂ , The temperature difference can thus be set via the difference between the average dwell times of the laser beam 14 on the contact surface 9 or the contact surface 10 in order to arrive at a defined thermal voltage of the energy source 3 which is independent of the ambient temperature.

FIG. 5 shows a block diagram of a document 16 , which in turn is designed as a value or security document. Document 16 has an energy source 17 , which is an active or a passive energy source.

For the realization of an active energy source, for example, a printed one Battery suitable. Such a printed battery is manufactured preferably by means of multilayer printing of electrically active substances, such as for example lithium polymers.

According to a further preferred embodiment, the Energy source around a passive energy source, such as a solar cell or an antenna.

On the one hand, solar cells can be very thin films on the carrier layer be applied or on the other hand through the use of known per se Printing process (cf. Plastic Solar Cells ", Adv. Funct. Mater. 2001, 11, No. 1, February, pages 15 to 26).

The energy source 17 is connected to the output or transmission unit 20 via the lines 18 and 19 . In the exemplary embodiment shown, line 19 is interrupted in order to implement a switch.

The output or transmission unit 20 contains a Peltier element 21 for supplying a security feature 22 with thermal energy. The security feature 22 includes a transducer that converts the thermal energy supplied by the Peltier element 21 into another form of energy that is perceivable from the outside due to a physical and / or chemical effect.

To check the security feature 22 , the interruption of the line 19 is closed, for example by a user holding a coin over the interruption in order to close the circuit. The Peltier element 21 is then supplied with voltage by the energy source 17 , so that a temperature difference is established between the contact surfaces of the Peltier element. This temperature difference is used to supply the security feature 22 with thermal energy, so that it is activated. Because of this, the authenticity of the document 16 can be checked.

Fig. 6 shows a schematic view of an embodiment of the document 16 in section. The document 16 has a carrier 23 , which consists for example of paper or plastic. A metal paste 24, for example with copper particles, is printed on the carrier 23, as is a metal paste 25 with a metal other than copper, such as silver. The metal pastes 24 and 25 form contact surfaces 26 and 27 .

This arrangement of the metal pastes 24 and 25 realizes the Peltier element 21 (see FIG. 5), which is supplied with voltage via the lines 18 and 19 as soon as the interruption of the line 19 is closed and the energy source 17 supplies a voltage ,

As soon as a voltage is present, the temperatures at the contact surfaces 26 and 27 change in opposite directions, that is to say, for example, the temperature at the contact surface 26 drops by a certain amount, while the temperature of the contact surface 27 increases by the same amount.

The security feature 22 in the form of thermochromic paint 28 is applied above the contact surface 26 . The thermochromic color 28 changes its color when the temperature changes at the contact surface 26 . In a further exemplary embodiment, such a thermochromic color can also be applied over the contact surface 27 , which changes to a different color due to the lowering of the temperature.

FIG. 7 shows an alternative embodiment of the document 16 of FIG. 6. In the embodiment of FIG. 7, the security feature 22 (cf. FIG. 5) is implemented by a bimetal strip. This consists of a metal strip 29 and a metal strip 30 . The metal strip 29 is located above the contact surface 26 , while the metal strip 30 is located above the contact surface 27 .

If an electrical voltage is applied via the lines 18 and 19 , the temperature at the contact surface 26 increases, for example, while it decreases at the contact surface 27 by the same amount. As a result, the metal strip 30 contracts, while the metal strip 29 expands. This creates a mechanical tension that deforms the document 16 . For example, document 16 curls up as soon as the electrical voltage is applied.

Alternatively, the metal strips 29 and 30 are arranged one above the other and over the same contact surface 26 or 27 . Then both metal strips 29 and 30 are heated or cooled to the same temperature. The metal strips 29 and 30 have metals with different coefficients of thermal expansion. Due to the different coefficients of thermal expansion, mechanical stress also results in this case, which leads to the deformation of document 16 .

In a further exemplary embodiment of the invention, at least some of the elements on the value or security document and described above have at least partially an overlying protective layer which protects the elements from environmental influences. Such a protective layer can be partially transparent and / or insulating. The protective layer can consist, for example, of a plastic. The protective layer can be applied to the value or security document by an additional printing step or by lamininers. In the case of a configuration analogous to the exemplary embodiment which has been described with reference to FIG. 5, the protective layer has openings so that the interruption and the ends of the line 19 which form the interruption can be exposed and make contact.

Both the public feature security feature and machine-readable security features can be implemented by the above-mentioned exemplary embodiments of the invention. It is even possible to arrange both types of security features within one security feature. Reference Signs List 1 title
2 output or transmission unit
3 energy source
4 line
5 line
6 area
7 area
8 area
9 contact surface
10 contact surface
11 fingers
12 color
13 external energy source
14 laser beam
15 document
16 energy source
17 line
18 management
19 output or transmission unit
20 Peltier element
21 Security feature
22 carriers
23 metal paste
24 metal paste
25 contact surface
26 contact surface
27 thermochromic color
28 metal strips
29 metal strips
30 metal strips

Claims (21)

1. Value or security document with a circuit ( 2 , 3 , 4 , 5 ) and with means ( 3 , 6 , 7 , 8 ) for converting thermal energy into electrical energy for supplying the circuit. 2. Value or security document according to claim 1, wherein the means for Change are designed as a Seebeck element. 3. The value or security document according to claim 2, wherein the Seebeck element has a first area ( 6 ) with a first metal, a second area ( 7 ) with a second metal and a third area ( 8 ) with the first metal, wherein there is contact between the first and the second area and between the second and the third area. 4. Value or security document according to claim 3, wherein it is the the first metal is copper and the second metal is silver. 5. Value or security document according to one of the preceding Claims 1 to 4, wherein the means for converting preferably a carrier Have paper or plastic film. 6. Value or security document according to one of the preceding Claims 1 to 5, wherein the means for conversion to the value or Security document are printed. 7. Value or security document according to one of the preceding Claims 1 to 6, wherein one or more elements of the circuit by means of a Printing ink are printed. 8. Value or security document according to one of the preceding Claims 1 to 7, wherein the circuit for at least one component Realization of a security feature. 9. Value or security document according to claim 8, wherein the component is designed as a converter to convert the electrical energy into another Form of energy, especially electromagnetic radiation, sound or a convert an electric or a magnetic field. 10. Value or security document with means ( 21 ) for converting electrical energy into thermal energy and with a security feature ( 20 , 22 ) which is supplied by the thermal energy. 11. Value or security document according to claim 10, wherein the means for conversion are designed as a Peltier element ( 21 ). 12. A value or security document according to claim 11, wherein the Peltier Element a first area with a first metal, a second Area with a second metal and a third area with the first Metal, wherein between the first and the second region and a contact between the second and the third area consists. 13. Value or security document according to claim 11 or 12, wherein it is the first metal is copper and the second metal is silver is. 14. Value or security document according to claim 11, 12 or 13, wherein the means for conversion and / or one or more other elements ( 17 , 18 , 19 ) of the circuit are printed on the value or security document. 15. Value or security document according to one of the preceding claims 10 to 14 with an energy source ( 17 ) for the electrical energy, wherein the energy source is preferably a battery, a solar cell or an antenna. 16. Value or security document according to one of the preceding Claims 10 to 15 with a switch for checking the Security feature. 17. Value or security document according to claim 16, wherein the switch is realized by an interruption of a conductor track ( 19 ). 18. Value or security document according to one of the preceding claims 10 to 17, wherein the security feature comprises an arrangement ( 29 , 30 ) which is designed to deform the value or security document due to the thermal energy, the arrangement preferably being a bimetallic strip. 19. A method of producing a value or security document comprising the following steps: - provision of a carrier, - Application of a first metal in a first area ( 6 ), a second metal in a second area ( 7 ) and the first metal in a third area ( 8 ), so that between the first and the second area and between the second and the there is contact in the third area. 20. The method according to claim 19, wherein an electrical and / or electronic circuit is applied to the carriers. 21. The method of claim 19 or 20, wherein one or more elements the circuit can be applied by printing.