PL187652B1 - Optically active diffraction-type protective element and apparatus for testing such elements - Google Patents

Abstract

1. A diffractive-optically active security element having a supporting layer or supporting foil in the form of a discontinuous, metalized layer with electrically conductive segments and/or with partially metallic, band zones and with demetallized zones or with demetalized segments, arranged - at various places in the document, characterized in that electrically conductive segments (28, 29, 30, 31, 32), and or partially metallic, conductive zones (2, 7), and/or metalized lines (21), and /or metallized layers (24), have a characteristic differing electrical conductivity constituting encoded information. Fig. 1 PL PL PL PL PL PL PL

Description

The subject of the invention is an optically active security element for marking documents, especially banknotes.

Documents with diffractive-optically active security elements, in particular holograms, are known and are inspected by an expensive optical checking technique. The document to be checked must be placed very precisely so that the entire checking process takes a long time.

EP 330 733 A1 describes security features on documents having metallized layers, including luminescent substances, holograms and reflective elements. These layers are separated by non-metallic layers and are optically readable in mechanical checking devices.

DE 195 12 921 A1 describes a banknote checking device. The device has optical and magnetic sensors and strip sensors for checking the characteristics of banknotes passing through the device. Counterfeit and damaged banknotes will be rejected. The device has electrodes for identifying conductive structural features and runs at speeds of 500 to 1800 pcs.

DE 44 05 860 A1 describes a method for checking metallized characteristics on banknotes and securities. The method consists in measuring the electromagnetic field of a banknote placed between the pairs of two electrodes, comparing this field with a pattern and sorting the notes on this basis.

Patent US 4,255,652 describes a device for checking recognition features of documents with electrically conductive regions. The charge is transferred to one of the electrically conductive areas by means of a first capacitive element placed over the document to be checked over its entire width. During the further transport of the test document, the charged, electrically conductive area is introduced under the second capacitive element, by means of which the charge is discharged.

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The computational and decoding circuitry generates a conventional signal. The device and the principle of checking documents used come from relatively large, electrically conductive areas, extending across the entire width of the inspected documents, because the amount of cargo transported in these areas is greatly reduced. Simultaneous checking of multiple conductive areas is as impossible as determining their geometrical shape and size, especially a drawing with fine, fine detail.

EP 0 097 570 describes a device for testing the dielectric properties of sheet materials in which the material to be tested passes between the electrode pairs. Changing the dielectric properties causes a voltage change at the receiving electrodes. The signals are amplified and processed individually.

In this device, which is based on the study of the dielectric properties of the sheet material, especially watermarks, all capacitors are simultaneously energized at the oscillator frequency, as a result of which coupling can occur between adjacent channels. If, on the other hand, to avoid this disadvantage, a larger capacitor spacing is chosen, the achievable geometrical recognition is reduced. Hence, only thick structures can be read. In order to tackle the vibration problems in the capacitor receiving facings, only one relatively low switching frequency is allowed, so that the checking speed is kept within low limits. Also, for design reasons, such a device cannot be used in high-speed machining machines.

EP 0 338 478 describes a combined process for printing and forming a hologram, the reflective material being applied either to the hologram only or to the surrounding material. The material outside the hologram is removed by etching or, in order not to damage the base layer, it is left on the base layer.

DE 27 47 156 describes a method and an inspection device for authenticating holographically secured identification cards. The instrument reproduces the OVD for visual inspection. This method is not suitable for quick, efficient and personnel-independent testing.

Patent EP 0 042 946 describes a device for reproducing read patterns which are then checked with lasers, mirror and lens systems as well as a photo detector. The cost of using the described method is very high. The outlay can be even greater if unsorted material is to be checked. To avoid presorting, a multiple layout of the authentication system would be needed.

As is known from US 5,248,544 and US 5,388,862, optically variable security elements have metal layers in the shape of so-called holograms and security fibers, the metal layers in the holograms being reflective and the X-ray security fibers cloudy. As a result of the overlapping metallized and demetallized areas in the beam or meander pattern, bright patterns are perceived, which are phase shifted when overexposed.

The aim of the invention is to eliminate the drawbacks described in the prior art and to develop diffractive-optically active security elements, especially OVDs, holograms or kinegrams, which provide better security and can be checked quickly, independently of personnel and with little effort in the inspection device. the identity of the documents arranged for example on a banknote counting machine.

A diffraction-optically active security element according to the invention, having a carrier layer or a carrier foil in the form of a discontinuous, metallized layer with electrically conductive segments and / or with partially metallic, streaked zones and with demetallised zones and / or with demetallized segments distributed at different points in the document , characterized in that the electrically conductive segments and / or partially metallic conductive zones and / or metallized lines and / or metallized layers have a characteristic differing electrical conductivity constituting coded information.

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The electrically conductive segments and / or partially metallic conductive zones and / or metallized lines and / or metallized layers are preferably arranged at different levels.

The distance between the electrically conductive segments and / or partially metallic conductive zones and / or metallized lines and / or metallized layers is preferably at least 0.1 mm.

The electrically conductive segments and / or partially metallic conductive zones and / or metallized lines and / or metallized layers are preferably interrupted by at least one vertical non-metallized zone.

The diffraction-optically active elements consist, among others, of a metallized layer, which is an electrically conductive layer, and its electrical conductivity changes according to the thickness of this layer. The diffractive-optically active element according to the invention has a discontinuous metallizing layer and / or partially metallized layers which form the targeted encoding of the information. The coding form is represented by geometric figures, in particular lines, lattice lines, arcs and / or circles, which are arranged regularly or irregularly. The partially metallized layer which is located above the carrier layer comprises a plurality of demetallized segments. The discontinuous metallized layer has segments with different, characteristic electrical conductivities.

The diffractive-optically active elements according to the invention can be checked by machine in a device having a capacitive scanner and transmitting and receiving electrodes. The device is arranged in the document processing machine in such a way that optical or mechanical sensors in conventional document processing machines activate the document authentication device. The control of the individual transmitting electrodes with electricity takes place in a time-varying manner by means of control electronic devices with a switching frequency in the kHz range. The control electronics have as the main components a multiplexer, an oscillator for powering the transmitting electrodes and an oscillator for controlling the multiplexer.

The energy of each controlled transmitting electrode is capacitively coupled with the receiving electrode. If the document to be inspected is not electrically conductive, no energy transfer occurs between the controlled transmitting electrode and the receiving electrode. The signal waveform to the receiving electrode is converted into the corresponding image signal. The signal image depends on the metallized structure. If the diffractive-optically active elements have a discontinuous metallizing layer, then multiple segments of the metallizing layer have different electrical conductivities. Computing electronic devices connected to the receiving electrode compare the signal image of the test document with the corresponding reference signals. Computing electronic devices have an amplifier connected to a comparator demodulator which in turn is connected to a microprocessor. In the microprocessor's memory, apart from its software, reference images are encoded, which, depending on the security elements to be checked, are compared with the image signal of the examined document. As the scanner travels the full width of the document, each electrically conductive feature is registered by the device. Comparison with reference images gives a classification signal. Accordingly, for example, a document recognized as a counterfeit can be sorted out, with the checking device stopped. In order to reduce the interference effects, the sensor carrier is bonded to a board on which control and computing electronics are placed. The entire checking device is inside the document processing machine so that the space requirement is relatively small. In document processing machines, the transmitting and receiving electrodes are positioned above or below the documents in such a way that correct reading of the features is guaranteed. This takes place, for example, by means of strips or in the area of the turning devices, so that the document is pressed against the transmitting and receiving electrodes during transport. The document inspection apparatus has a longitudinal transmitting electrode disposed parallel to a series of adjacent receiving electrodes. In this case, the received signals are created by the mux. The device used in handheld devices has a scanner and suitable means for transporting documents.

An embodiment of the invention is shown in the drawing and in which Fig. 1 shows a schematic view of an OVD of a document with meandering demetallised layers; Fig. 2 is a schematic representation of an OVD document with banded demetallised layers; Fig. 3 is a schematic view of the document OVD with banded demetallized layers; figs 4 - schematic OVD document with streaked demetallizos \ vyns; Fig. 5 is a schematic view of an OVD document with multiple security features, gig. 6 - block circuit of the security element checking device according to the invention; Fig. 7 shows a security device checking scanner according to the invention with a plurality of transmitting and one receiving electrode, gig. 8 - scanner as in fig. 7 but with one transmitting electrode and multiple receiving electrodes, fig. 9 - scanner with gig 7 with multiple transmitting and receiving electrodes; Fig. 10 is a side view of the proof-of-document scanner; Fig. 11 is a schematic section of an OVD with non-metallized segments; Fig. 12 is a voltage-time diagram of the calculation signal; Fig. 13 is a schematic section of an OVD with a discontinuous metallization layer and a gig. 14 - voltage-time diagram of the calculation signal.

The exemplary embodiments shown in FIGS. 1 to 5 each show documents with security elements according to the invention and a schematic representation of a scanner for checking these security elements.

At the gig 1 shows schematically the structure of an OVD with a metallized layer 2. The metallized layer 2 has a non-metallic zone 3. In the plan view, the non-metallic zone 3 has the form of a meander. The width of the meandering non-metallic zone 3 is thereby greater than the smallest spacing between two electrodes. The capacitive scanner consists of a plurality of transmitting electrodes 5 placed next to each other and a parallel receiving electrode 6. Figure 2 shows schematically the structure of an OVD in which metallized banded streams 7 and non-metallized banded zones 8 are alternately placed parallel to each other. In the plan view, the metallized and non-metallic strip streams 7, 8 run parallel or perpendicular to the transport direction of the documents. The latter case is illustrated in Fig. 3. The distance between two zones of equal electrical conductivity is 0.1 to 1.0 mm. The widths of the zones with the same electrical conductivity are variable.

The combination of the features of the examples from gig. 2 and 3 are shown in Fig. 4. Parallel to the transport direction of the documents, alternating metallized banded zones 7 and demetallized banded zones 8. The metallized zones 7 are interrupted by a non-metallized zone 9 that runs vertically thereto.

Figure 5 shows a document with multiple OVD's. The targeted combination of diffractive-optically active security elements creates a further coding. This increases the certainty of control.

Figures 6 to 9 show a circuit block arrangement as well as various embodiments of a capacitive scanner 4 used to check security features according to the invention.

Figure 6 shows a circuit block of a checking device consisting of a capacitive scanner 4, a demultiplexer 10, an oscillator 11 for powering the transmitting electrodes, and an oscillator 12 for controlling the demultiplexer. Computing electronics mainly consist of an amplifier 13, a demodulator 14, a comparator 15, and a microprocessor 16. The transmitting and receiving electrodes are embedded in the sensor carrier. They form a scanner 4 that works capacitively across the entire width of the document input. The strip-shaped receiving electrode extends transversely to the document input direction. The transmitting electrodes are placed parallel to the receiving electrode. The distance between the transmitting and receiving electrodes is determined by the electrically conductive security elements that are typical of the respective documents. By aligning a plurality of transmitting electrodes, it is possible that the longitudinal axis of the capacitive scanner 4 can simultaneously record a plurality of electrically conductive features. The effectiveness of such a system depends on the number of transmitting electrodes used.

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In this embodiment, the device reads the number of dots per mm ² , i.e. in both the longitudinal and transverse directions. The smallest distance between adjacent transmitting electrodes is limited by mutual capacitive interference coupling. In order to prevent this and to reduce the interference effects of the adjacent transmitting electrodes, they are successively controlled by the multiplexer 10. Due to the arrangement of the transmitting electrodes, the documents are checked in a neutral position across their entire width. This means that there is no need to pre-sort more documents on the document handling machine.

Figure 7 shows a schematic view of a scanner 4 with a plurality of transmitting electrodes 5 and one receiving electrode 5. Control and processing are performed according to the circuit block arrangement shown in Figure 6.

Figure 8 shows a schematic view of an embodiment of a capacitive scanner with one transmitting electrode 17 and a plurality of receiving electrodes 18. In contrast to the circuit block arrangement of Figure 6, the transmitting electrode 17 is controlled by an oscillator. The signals of the receiving electrodes 18 are processed with a multiplexer. The electronic processing device consists of a demodulator, comparator, microprocessor with memory and filters for suppressing extraneous and interfering signals, and is comparable to the circuit block circuit of Fig. 6.

Figure 9 shows a schematic view of a further embodiment of a capacitive scanner with a plurality of transmitting electrodes 19 and a plurality of receiving electrodes 20. These are alternately arranged in a row.

Figure 10 shows a schematic view of a capacitive scanner and inspected document in a side view. The security feature 1 has metallized lines 21 and an electrically insulating carrier foil 22.

Figure 11 shows a section of a security feature with a support layer 23 and a partially metallized layer 24. The partially metallized layer 24 has a plurality of insulating segments 25. In Fig. 12 the associated processing signal is shown in a voltage-time diagram.

Figure 13 shows a schematic section of an OVD with a support layer 26 and a discontinuous metal layer 27. Discontinuous metal layer 27 has segments 28, 29, 30, 31, 32 of different electrical conductivity. In Fig. 14, the associated processing signal is shown in a voltage-time diagram.

On the basis of specific embodiments according to the invention, the structure of the security elements and the device for checking such elements are explained. The present invention is not limited only to the details described in the embodiments, as changes and modifications are possible. In the described device for checking security features according to the invention, in addition to the diffractive-optically active security elements, also other electrically conductive features can be detected. The targeted combination of diffractive and optically active security elements with other electrically conductive features enables further coding. By means of the described testing device, it is also possible to identify further electrically conductive testing features, such as for example security fibers or coding made with electrically conductive paint.

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Publishing Department of the UP RP. Circulation of 50 copies

Price PLN 2.00.

Claims (4)

Patent claims A diffraction-optically active security element having a carrier layer or a carrier film in the form of a discontinuous, metallized layer with electrically conductive segments and / or with partially metallic, streaked zones and with demetallised zones or with demetallized segments distributed at different points in the document, characterized by that the electrically conductive segments (28, 29, 30, 31, 32) and or the partially metallic conductive zones (2, 7) and / or the metallized lines (21) and / or the metallized layers (24) have a distinctive characteristic of electrical conductivity representing the coded information. 2. The security element according to claim The process of claim 1, characterized in that the electrically conductive segments (28, 29, 30, 31, 32), and / or partially metallic, conductive zones (2, 7), and / or metallized lines (21), and / or metallized layers (24 ) are located at different levels. 3. The security element according to claim A method as claimed in claim 1, characterized in that the distance between the electrically conductive segments (28, 29, 30, 31, 32) and / or partially metallic conductive zones (2, 7) and / or metallized lines (21) and / or metallized layers (24) is at least 0.1 mm. 4. An element according to claim The process of claim 1, characterized in that the electrically conductive segments (28, 29, 30, 31, 32), and or partially metallic conductive zones (2, 7), and / or metallized lines (21), and / or metallized layers (24) , are interrupted by at least one vertical non-metallized zone (9).