RU86773U1 - PROTECTIVE ELEMENT FOR CHECKING THE AUTHENTICITY OF THE PROTECTED OBJECT - Google Patents

Abstract

1. A security element for verifying the authenticity of the object of protection, including a substrate and a metallized layer, characterized in that said metallized layer is a single-layer or multilayer island metallized layer or a granular metal layer having a non-linear dependence of electrophysical properties when exposed to a weak constant or an alternating electric field, and further comprising a protective dielectric layer deposited over said metallized layer, while the detected sign of the authenticity of the object of protection is the nonlinear conductivity of the protective element, which is determined by measuring the conductivity of the protective element at two different amplitudes of the mentioned electric field applied to the protective element. ! 2. The protective element according to claim 1, characterized in that the said weak constant or alternating electric field is a constant or alternating electric field with an intensity of less than 50 V / cm, respectively. ! 3. The protective element according to any one of claims 1 or 2, characterized in that in the said single-layer or multilayer islet metallized layer or layer of granular metal, the islands or granules of said metallized layer are ordinary and ferromagnetic metals. ! 4. The protective element according to any one of claims 1 or 2, characterized in that in the said single-layer or multilayer island metal layer or a layer of granular metal, the islands or granules in said metal layer are metal magnetic or

Description

The utility model relates to the field of protection against counterfeiting of the object of protection, in particular, securities, banknotes, documents.

In connection with the continuous improvement of the quality of computer and multiplying equipment, the likelihood of reproducing, with a high degree of identity, almost any security increases. Improvements are also being made to counterfeit valuable products, such as paintings and antiques. In this regard, the urgent task of improving the methods of these objects of protection.

Currently, there are various methods of protection against counterfeiting, a significant part of which is based on the use of metal protective labels. Such marks can be formed both by directly applying the marking material, for example, in the form of paint, to the object of protection, and by embedding in the object of protection a separately manufactured protective equipment, for example, in the form of a metal strip.

A known method of protecting securities and products and a device for its implementation in the form of a two-sided information carrier, on the front and back sides of which are formed, by applying a magnetic composition, two images (magnetic marks), oriented in a certain way relative to each other. Detection is carried out using a semiconductor magnetic sensor that simultaneously reads information from the front and back sides of the information carrier. In this case, the output signal of the semiconductor sensor is passed through a complex circuit to form pulses at the boundaries of the images of magnetic marks. These pulses carry out the recognition of magnetic information on the medium by comparison with a given (reference) information (JP, application N057-177372, CL G07D 7/00, 1984).

The disadvantage of this protective equipment is that for the detection of these protective labels it is necessary to use complex and expensive electronic devices that are not available to the mass user.

A known method of protecting securities and a device for its implementation, according to which a strip of magnetic material is pressed into a paper base of a security. The authenticity of a security is determined by means of a magnetic detector detecting a change (gradient) in the magnetic field strength (EP, No. 005720, class G07D 7/00, 1982).

The disadvantage of these methods and devices of protection is their lack of reliability, since the magnetic material for this protective strip is available to a wide range of people and for a specialist its manufacture (fake) does not represent technical complexity and does not require significant material costs.

A known method of protecting securities from counterfeiting using a passive protective agent. A passive protective agent of a given structure is formed on a security, its presence is detected by registering informative features in the resonant response of the protective agent to the probing electromagnetic radiation of a given radio frequency, with automatic comparison of the registered informative features with reference values. As a passive protective agent, a metallized at least three-layer resonant filter structure is used. The microwave frequency is used as the probing radiation, the characteristic peak values of the frequency response of the direct transmission and back reflection coefficients are used as informative signs (RU No. 2276409).

The disadvantages of this method of protection include the complexity of manufacturing a passive protective device in the form of a metallized at least three-layer resonant filter structure, as well as the complexity of the detection means (presence control) of such protection.

Closest to the means of protection claimed in this utility model is a method of protecting securities and products using security strips having a specific structure, it is selected as a prototype of this utility model (RU 2291490). Known protective strips are constructed of several different components, coding means and electrically conductive layers, in various ways connected with the substrate. These protective strips are applied to or embedded in a valuable product. The technical result of the known protective bands is the creation of a coded system in which a randomly selected, known only to the manufacturer, combination of metallized surfaces with a certain gloss, electrical conductivity and a change in resistivity from strip to strip creates insurmountable difficulties in the manufacture of a fake.

The disadvantage of this method of protection is that it can be useful in protecting a single or small series of securities or securities. However, the protection of a large number of securities (for example, banknotes) is unreliable in this way, since it requires widespread use of physical means of authenticating products, in which case the code of the security strip repeated many times in many products can be easily decoded and reproduced. Another disadvantage is that the manufacture (fake) of these protective strips does not present technical difficulties.

These shortcomings are eliminated by using the claimed utility model of the security element for verifying the authenticity of the object of protection, for example, a banknote, which increases the reliability of protection against counterfeiting, is inexpensive to manufacture, and allows control using simple physical devices.

This problem is solved due to the fact that the protective element is created on the basis of nanoisland (island) or granular metal films, which under normal conditions are able to change their electrophysical properties (for example, conductivity) in weak electric fields, that is, electric fields with a voltage of less than 50 V / cm.

Protection against falsification of the object of protection consists in the fact that in a small area of the object of protection (for example, paper) a protective region is formed, for example, a strip that can be invisible to the naked eye, while the protective region contains a protective element containing an insular or granular metal film, which has non-linear electrophysical properties.

Authentication is carried out using a simple electronic device (Figure 3), which checks the non-linearity of the electrophysical properties (eg, conductivity) of the protective region when it is exposed to a weak electric field. The presence (absence) of nonlinear electrophysical properties indicates the authenticity (fake) of the product, while the absence of nonlinear electrophysical properties indicates the fake of the product. Both contact and non-contact control methods are possible with a characteristic control time of less than 0.1-3 sec.

According to a utility model, a single-layer or multilayer island or granular metal film is used as a protective element, which is located on the paper substrate of the security itself (for example, in the case of a banknote) or on a specially created thin dielectric substrate (for example, lavsan) embedded in object of protection. The outer surface of the metal film is protected from weathering and premature aging by dielectric coating. Figure 1 shows the structure of the product protection means based on a single-layer island metal film, where 1 is a paper or dielectric substrate, 2 is an island metal film, 3 is a protective dielectric film.

To verify the authenticity of the object of protection (for example, a banknote), the conductivity of the aforementioned film is measured at at least two different values of a constant or alternating weak electric field with an intensity of F <50 V / cm applied to it. Detected sign of the authenticity of a valuable product ("label") is the nonlinear conductivity of the film (Figure 2). This means that with an increase in the applied electric field, for example, by a factor of two, the conductivity of the film increases by a certain amount, determined by the parameters of the film and controlled during its manufacture.

High-quality protection of objects of protection is determined, firstly, by the uniqueness of the properties of island metal films, in which a significant change in conductivity is observed under the influence of a weak electric field. It is known that a change in conductivity under the influence of an electric field in various materials, for example, in semiconductors, is observed at an electric field F >> 1000 V / cm. In island films, a significant change in conductivity is observed in much weaker electric fields F = 10–50 V / cm. (Figure 2).

Secondly, protection is ensured by the uniqueness of the technological process of creating island and granular metal films. Indeed, islands should have dimensions of the order of 10 nm and tunnel conductivity between them should be realized at room temperature, which is the main reason for the nonlinear electrophysical properties of these films. For this, in the process of creating films, it is necessary to strictly observe the technological parameters, which are the know-how of the process and can neither be defined nor reproduced by the “artisanal production method” without the necessary equipment and qualified personnel. In particular, it is necessary to strictly observe the temperature regime of film growth, providing a given growth rate, etc. On the other hand, in modern factories it is not difficult to carry out this technological process by various methods: using high-frequency sputtering of metal targets, thermal sputtering of metals or using the creation of granular metal films. The listed technologies are well mastered and guarantee low cost and reliability in mass production of protective products for valuable products.

An example of creating a means of protection of a valuable product is a structure implemented on the basis of a single-layer nano-island metal film (Figure 1). Thin islet or granular metal films (2) of ordinary metals, for example Ti, W; or from ferromagnetic metals, for example Co, Fe; or from metallic non-magnetic alloys, for example, WRe, NiCr; or from metal magnetic alloys, for example, FeNi, FeCo, are grown by RF sputtering in argon on a dielectric substrate (1). After spraying, each of the metal structures is closed with a thin protective layer of a dielectric (Al ₂ O ₃ , d = 20 Ǻ). The thickness of metal films varies from 7 Ǻ to 30 Ǻ depending on the properties of the dielectric substrate. Figure 2 shows the dependences of the relative differential conductivity of metal films on the electric field applied to the sample (curve 1 — Ti; 2 — FeNi; 3 — Co; 4 — W). The differential conductivity in%, plotted along the vertical axis of Figure 2, is an indicator of the uniqueness of the properties of this film as a “label” for protecting securities, such dependencies, under normal conditions, are not achievable in conventional materials.

As noted, to verify the authenticity of a valuable product by the presence of nonlinear effects in the film, the conductivity of the film is measured at various values of the applied constant or alternating electric field. Figure 3 presents a circuit diagram of a measuring device (detector). Metal electrodes (2-5) are pressed (brought up) to the structure (1), which makes it possible to create ohmic (capacitive) contacts. A low-frequency (up to 100 kHz) or pulsed voltage is applied to electrodes 2 and 5, the voltage amplitude at electrode 5 should be several (for example, 10) times greater than at electrode 2, the maximum electric field in the film should not exceed 50 V / cm. The limitation of the electric field is due to the unique properties of island films to change their electrophysical properties in weak electric fields. Electrodes 3 and 4 through the same load resistance 6 are grounded. From the load resistances 6, a voltage proportional to the current is supplied to amplifiers 7 and 8, and the gain of amplifier 7 is 10 times greater than the gain of amplifier 8. Then, the signals from the amplifiers go to adder 9. If the structure has nonlinear effects, the signals from the outputs of amplifiers 7 and 8 in absolute value will differ, and the signal Uc will be present at the output of the adder, which indicates the authenticity of the product. If the structure does not have nonlinear properties, the signals from the outputs of amplifiers 7 and 8 will be equal in absolute value and at the output of the adder, the signal Uc will be zero, which is evidence of a fake product.

It is possible to detect non-linear effects in the film using a constant voltage applied to the electrodes, in this case the protective region with the film should move relative to the electrodes. In the case when the electrodes will be in contact with the film, or located near it, pulse signals will be emitted at the load resistances, and the duration of these signals t will be determined by the speed of movement of the valuable product relative to the electrodes (v) and the dimensions of the film in the direction of movement of the valuable product (d) ( t = v * d). The duration of the interaction of the detector with the film may be less than 10-3 seconds.

Claims (4)

1. A security element for verifying the authenticity of the object of protection, including a substrate and a metallized layer, characterized in that said metallized layer is a single-layer or multilayer island metallized layer or a granular metal layer having a non-linear dependence of electrophysical properties when exposed to a weak constant or an alternating electric field, and further comprising a protective dielectric layer deposited over said metallized layer, while the detected sign of the authenticity of the object of protection is the nonlinear conductivity of the protective element, which is determined by measuring the conductivity of the protective element at two different amplitudes of the mentioned electric field applied to the protective element. 2. The protective element according to claim 1, characterized in that the said weak constant or alternating electric field is a constant or alternating electric field with an intensity of less than 50 V / cm, respectively. 3. The protective element according to any one of claims 1 or 2, characterized in that in the said single-layer or multilayer islet metallized layer or layer of granular metal, the islands or granules of said metallized layer are ordinary and ferromagnetic metals. 4. The protective element according to any one of claims 1 or 2, characterized in that in the said single-layer or multilayer islet metallized layer or layer of granular metal, the islands or granules in said metallized layer are metallic magnetic or non-magnetic alloys.