JP2001524235A - Use of a document inspection method with a diffractive optically effective security layer - Google Patents

Abstract

SUMMARY The present invention relates to the use and method of document inspection. To date, documents having a diffractive optically effective security layer, especially holograms, have been inspected with expensive optical inspection equipment. The entire inspection process takes a very long time and these inspection processes cannot be used on high-speed processors. Quick testability is another security step in the measurement of the diffractive optically effective safety layer as a certification mark. The diffractive optically effective layer has areas of discontinuous and / or partial metal layers and / or metal layers of different planes. Various measurement methods for determining electrical conductivity are known. In fact, non-contact, capacitive measurement methods have proven to be beneficial.

Description

DETAILED DESCRIPTION OF THE INVENTION Use of a document inspection method with a diffractive optically effective security layer   The invention relates to the use of a document inspection method.   To date, documents with diffractive optically effective security layers, especially holograms, It has been inspected by expensive optical inspection equipment. In these procedures, Had to be placed very accurately. Is the whole inspection process long? Therefore, these inspection procedures could not be used on high-speed processors. For example, It is not possible to check banknotes with a program certificate with a banknote counter . Because, banknotes are 500 to 1500 or more per minute Because it passes by. Holographically protected identification card for counterfeit inspection A method and a device are disclosed by German Patent No. 2,747,156. Holog The ram is reproduced and a visual check is performed. This method is fast and efficient Not suitable for general, non-independent testing. Laser, mirror and lens The system and the device that generates the scanning pattern to be inspected by the photoelectric detector are No. 0042946. In this case, the financial costs are also Very high. This cost is renewed if the inspection object is inspected without pre-classification. To increase. Counterfeit inspection systems must be deployed several times to avoid pre-classification. I have to.   It is an object of the present invention to eliminate the disadvantages of the prior art and to provide a diffractive optically effective security layer, Use holograms in documents, and do not rely on individuals and And an inspection method capable of quickly inspecting the document. The device is Document inspection apparatus, a cash processor, and a document having a diffractive optically effective safety layer. It is intended for use in a manual inspection unit of a ment.   The problem to be solved is solved by the features described in the characterizing part of claim 1.   Holograms and other times to protect certificates and other certificates and banknotes from forgery Optically effective safety layers are now being used more and more widely. Quick inspection capability is Another safety step in the evaluation of the diffractive optically effective safety layer as a witness . The diffractive optically effective layer comprises, inter alia, a metal layer. This metal layer has conductivity . The electrical conductivity varies with the thickness of the layer. The diffractive optically active layer is It has metal layers and / or partial metal layers and / or metal layer regions on different planes. Various measurement methods for determining electrical conductivity are known. In fact, a non-contact capacitive meter Measurement methods have proven useful. This document security inspection method Capacitive coupling between transmitter and receiver and energy transfer between transmitter and receiver The conductive safety material Used by bridging the magnetic field. The downstream electronic measurement system Is compared with the associated reference signal. The comparison is a classification signal for reprocessing. Provide an issue. Therefore, documents detected as counterfeit can be Classified by stopping. The signal image is composed of the metal layer of the diffractive optically effective layer. Depends on the structure. If the diffractive optically effective layer has a discontinuous metal layer, Some parts have different electrical conductivity. In practice, these different conductivities are This has an effect on the signal image.   Inspection reliability combines electrical conductivity testing with other certifications that are diffractive optically active layers. By doing so, it is further increased. Discontinuous and / or partial metal layers And / or additional certification of non-metallic parts in the area between different planar metal layers The application of the mark allows the simultaneous inspection of these certification marks having electrical conductivity. With the electronic measuring system, the authentication signal of the other sensors for the authentication decision is the conductivity Logically coupled to the measurement sensor. Diffraction optics at the output of the electronic measurement system The signal that classifies the effective layers is available for reprocessing. This additional certification Can be fluorescent, phosphorescent, light absorbing, or have different magnetic properties. It has different properties from its environment depending on its gender. Therefore, optical or magnetic Sensors are used. To reduce detection and measurement errors, the use of sensor carriers Preferred No. This sensor carrier contains all the sensors needed to detect the certification mark. You. This minimizes the distance between the sensors and ensures that the sensors are always defined It becomes possible to arrange in a different position. To avoid interference effects, the sensor carrier Is securely connected to the mounting plate holding the electronic measurement system. Full examination The inspection device is located in the processing machine, so that additional No expensive costs are required.   The features of the invention reside in the claims and beneficial patentable implementations for which protection is claimed. Several individual or individual connections in the form of subordinate connections representing an example Will be apparent from the detailed description and drawings. The invention relates to the accompanying This will be explained in more detail with reference to an embodiment represented by the drawings. Here And   FIG. 1 is a schematic sectional view of a processing machine having an inspection device.   FIG. 2a is a schematic sectional view of a hologram having a non-metallic part.   FIG. 2b is a voltage-time diagram of the measurement signal.   FIG. 3a is a schematic cross-sectional view of a hologram having a discontinuous metal layer.   FIG. 3b is a voltage-time diagram of the measurement signal.   FIG. 4a is a schematic sectional view of a hologram having a UV certification mark.   FIG. 4b is a voltage-time diagram of the measurement signal of the electrical conductivity test.   FIG. 4c is a voltage-time diagram of the measurement signal of the UV sensor.   In the inspection method according to the present invention, an appropriate sensor is provided at an appropriate position of the banknote counter. Is done. The electrical conductivity detection sensor may be configured such that the sensor detects the banknote regardless of the banknote position. Is designed to be able to inspect Optical or mechanical sensors are used for banknotes And provides a reference signal for the timing of the inspection device 4. simultaneous Next, the sensor for forgery inspection of the hologram is activated. Banknote beginning to end By recording the time window up to The position of the hologram of the banknote can be determined.   FIG. 1 shows how the inspection device 4 is arranged on the banknote transport path. . The banknote counting machine includes a supply wheel 1, a transport wheel 2, a banknote guiding device 3, and an inspection device 4. And   FIG. 2 a shows a hologram having a carrier layer 11 and a partial metal layer 12. FIG. 2 shows a schematic sectional view. Partial metal layer 12 comprises some non-metallic parts 13 I can. FIG. 2b shows the relevant measurement signals in a voltage-time diagram.   FIG. 3a is a schematic diagram of a hologram having a carrier layer 11 and a discontinuous metal layer 14. FIG. The discontinuous metal layer 14 has portions 15 having different electrical conductivities. , 16,1 7, 18, and 19 are included.   FIG. 3b shows the relevant measurement signals in a voltage-time diagram.   FIG. 4a is a schematic diagram of a hologram having a carrier layer 11 and a discontinuous metal layer 20. FIG. The discontinuous metal layer 20, as well as additional certification marks, Includes minute 21. These certification targets are fluorescent paint 22, which is excited by detection with UV light. State and is detected by the photodetector. Additional certification marks in non-metallic part 21 Is preferably located at FIG. 4b shows a capacitive motion sensor for testing electrical conductivity. , The relevant measurement signals are shown in a voltage-time diagram. FIG. 4c is a voltage-time diagram. 3 shows the response of the measurement signal of the photodetector at the time of FIG.   In the present invention, inspection of a document having a diffractive optically effective security layer is an example. It was explained in connection with. However, the invention is limited to the detailed description of the embodiments. Instead, it is understood that other embodiments and improvements are claimed within the scope of the claims. Should.

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Claims (1)

[Claims] 1. Capacitive coupling between transmitter and receiver with conductive safety material and transmitter and receiver Using a document inspection method with energy transfer to and from a container,   Discontinuous metal layers (14) or partial metal layers (12, 20) or different planes Document counterfeit inspection with diffractive optically effective security layer with metal layer area Document inspection method characterized in that electrical conductivity is measured and evaluated for Use of law. 2. Diffraction with discontinuous metal layers (14) and partial metal layers (12, 20) For the counterfeit inspection of a document having an optically effective security layer, The use of the method according to claim 1, wherein the rate is measured and evaluated. 3. Diffractive optics having discontinuous metal layers (14) and regions of differently planar metal layers For the counterfeit inspection of a document having an effective security layer, the electrical conductivity is Use according to claim 1, characterized in that it is measured and evaluated. 4. Circuits with partial metal layers (12, 20) and areas of different planar metal layers For the counterfeit inspection of a document having an optically effective security layer, The use of the method according to claim 1, wherein the electrical power is measured and evaluated. 5. Discontinuous metal layers (14) and partial metal layers (12, 20) and different planes Forgery of a document having a diffractive optically effective security layer having a surface metal layer area The electrical conductivity is measured and evaluated for inspection. Use of the method of claim 1. 6. Discontinuous metal layer (14) and / or partial metal layer (12, 20) and / or Or additional applicable certification in non-metallic parts, in the area between metal layers on different planes 6. One or several claims according to claim 1, including said inspection of the mark. Use of the method described in section. 7. Claims characterized by including an inspection of the fluorescent properties of the additional applicable certification mark Use of a method according to item 6. 8. Including inspection of phosphorescent properties of additional applicable certification marks Use of the method according to claim 6. 9. A contract, characterized by including an inspection of the light absorption properties of the additional applicable certification mark. Use of the method of claim 6. 10. Including inspection of magnetic properties different from the environment of additional applicable certification marks. Use of the method according to claim 6, characterized in that: 11. 2. The method according to claim 1, wherein the diffractive optically effective safety layer is a hologram. Use of the method according to one or more of 1 to 10. 12. High-speed processors with speeds of up to 2000 documents per minute Hologram inspection Use of the method according to one or more of claims 1 to 11, characterized in that: 13. 2. The method according to claim 1, further comprising inspecting a hologram of the manual unit. Use of the method according to one or several of the methods 12. 14． Capacitive coupling between transmitter and receiver by said conductive safety material, and transmission For document inspection using energy transfer between a receiver and a receiver And   The document to be inspected has a diffractive optically effective security layer, said security layer being discontinuous. Metal layer (14) and / or partial metal layer (12, 20) and / or different planes The document is guided so that the document is Passes through the electronic sensor system at a determined speed,   Energy is transferred from one or several transmitting electrodes to one or several receiving electrodes via a metal layer Capacitively converted,   The signal is available at the receiving electrode or the electrode and the signal is Magnified by the system and compared to a reference signal,   The classification signal of the document is further output at the output of the electronic measurement system. Available for the journey A document inspection method. 15. Documents with a diffractive optically effective security layer are: 15. The inspection according to claim 14, wherein the inspection is performed in at least two different inspection directions. the method of. 16. The classification signal is tested by another sensor before the electronic measurement system. System is logically combined with the certification signal of the additionally applicable certification mark,   The combined signal for classifying the document is then processed for further processing. 2. The method of claim 1, wherein the output is available at an output of an electronic measurement system. 4. The method according to 4.