WO2004001684A1

WO2004001684A1 - Recognition of foreign objects on or in banknotes

Info

Publication number: WO2004001684A1
Application number: PCT/EP2003/006325
Authority: WO
Inventors: Jürgen Schützmann; Jan Domke
Original assignee: Giesecke & Devrient Gmbh
Priority date: 2002-06-19
Filing date: 2003-06-16
Publication date: 2003-12-31
Also published as: AU2003246439A1; DE10227354A1

Abstract

The invention relates to a device and a corresponding method for recognizing foreign objects, particularly adhesive tape, on or in banknotes (1), comprising at least one unit (6) which irradiates a banknote (1) that is to be analyzed with electromagnetic rays (2), at least one detector (4) which detects the rays (3) reflected or transmitted by the banknote (1), and an evaluation unit (5) which recognizes foreign objects (10) located on or in the banknote (1) based on the detected rays (3). In order to increase reliability concerning the recognition of foreign objects, the wavelength of the rays (2, 3) lies within the medium infrared (MIR) spectrum, in which differences in the transmission behavior and reflection behavior between banknote areas (21) with and without adhesive tape (10) are clearly visible. Said differences are particularly great at wavelengths ranging between 5.5 and 6 µm, especially between 5.7 and 5.8 µm such that a high sensitivity to detection is obtained even for thin strips of adhesive tape.

Description

Detection of foreign objects on or in banknotes

8. The invention relates to a method and a corresponding device for recognizing foreign objects, in particular adhesive strips, on or in banknotes according to the preamble of claims 1 and 8.

When machine processing banknotes in commercial or central banks, the banknotes are checked, among other things, with regard to their suitability for further use in payment transactions. An important decision criterion here is the presence of undesired foreign objects on or in the banknotes. Such undesired objects are generally objects which are not part of a finished banknote and only appear on or into the banknote during circulation. or be introduced. Frequently, these are adhesive strips or similar adhesive objects that are glued to the banknote in particular for repair purposes. Such banknotes are generally considered to be no longer suitable for further use and must be recognized, sorted out and, if necessary, destroyed during machine processing.

Commercial adhesive strips generally consist of a thin carrier layer which is provided with an adhesive layer. Depending on the manufacturer and type of adhesive tape, the backing layer is made of plastics, e.g. Polypropylene (PP), polyvinyl chloride (PVC), polyethylene terephthalate (PET), polyethylene (PE) or cellulose acetate. The adhesive layer usually contains acrylate, modified acrylate or rubber.

To detect undesired objects on banknotes in banknote processing machines according to the prior art, methods are used, among other things, in which the light reflected from a banknote to be checked or the visually visible light transmitted through the banknote is detected. Statements about the presence of foreign objects on the banknote are derived from the detected light. However, this method provides insufficiently accurate results, particularly when detecting thin or transparent adhesive strips, since the reflection and transmission properties in the area of the adhesive strip usually do not differ sufficiently clearly from the other areas of the banknote without adhesive strips.

In other methods, the bank notes to be examined are subjected to ultrasound and the thickness of the bank note is calculated from the sound component reflected or transmitted by the bank note. These methods are also only suitable to a limited extent for the detection of adhesive strips on banknotes, since the commercially used adhesive films which are frequently used have a very small thickness in relation to the paper thickness of the banknote. The differences in the reflected or transmitted sound in areas with and without adhesive strips are correspondingly small, so that in particular thin adhesive strips cannot be detected with sufficient reliability.

It is an object of the invention to provide a method and a corresponding device for more reliably recognizing foreign objects, in particular adhesive strips, on or in banknotes.

This object is achieved in the method and the device according to claims 1 and 8, respectively, in that the wavelength of the radiation in the middle infrared (MIR) is between 2.5 μm and 25 μm.

The invention is based on the idea of adhesive strips on banknotes by measuring the reflected from the banknote and / or by Banknote transmitted middle infrared radiation (MIR radiation) with wavelengths between 2.5 μm and 25 μm.

By using MIR radiation, adhesive strips can be detected with high reliability, since differences between individual areas of the bank note with and without adhesive strips clearly emerge in this spectral range. This means that even very thin adhesive strips with typical thicknesses between 15 μm and 50 μm can be recognized with high reliability.

The wavelength of the radiation used is preferably between 3 μm and 12 μm in order to be able to detect the different transmission or reflection behavior of the banknote in regions with and without adhesive strips even more reliably. Particularly large differences can be detected at wavelengths between 5.5 μm and 6 μm, preferably between 5.7 μm and 5.8 μm.

The invention is explained in more detail below with reference to figures. Show it:

Fig. 1 shows an embodiment of the device according to the invention and

Fig. 2 shows the transmission behavior of a banknote at locations with and without adhesive strips.

Fig. 1 shows an embodiment of the device according to the invention. A bank note 1 is conveyed through a suitable transport device (not shown) in the transport direction 20 to an irradiation device 6. The irradiation device 6 sends electromagnetic radiation lung 2, which meets the bank note 1 in the area of point 21. A detector 4 arranged opposite the radiation device 6 detects the radiation 3 transmitted through the bank note 1 and generates a signal 15 corresponding to the radiation 3 detected in each case, which signal 15 is forwarded to an evaluation device 5.

By transporting the bank note 1 past the irradiation device 6 and the detector 4, the radiation transmitted at different locations 21 of the bank note 1 is detected. Places 21 on the bank note 1 with an adhesive strip 10 show a different transmission behavior than places 21 without an adhesive strip.

By recording the radiation 3 several times at regular or irregular time intervals during the transport of the banknote 1, a so-called trace of measured values is obtained, i.e. a large number of individual measurements lying on a straight line at different points 21.

According to the invention, the wavelengths of the radiation 2 or 3 emitted by the irradiation device 6 and / or of the detector 4 are in the mid-infrared (MIR), i.e. between 2.5 μm and 25 μm. In this spectral range, differences in the transmission behavior between the individual areas of the bank note 1 with and without adhesive strips 10 are clearly evident. The differences in the transmission behavior at wavelengths of radiation 2 or 3 between 3 μm and 12 μm are particularly clear. Even greater differences can be detected at wavelengths between 5.5 μm and 6 μm, preferably between 5.7 μm and 5.8 μm.

The corresponding signals 15 of the MIR radiation 3 detected at different points 21 of the bank note 1 are recorded in the evaluation device 5. compared to each other. Statements about the presence of foreign objects, in particular adhesive strips 10, on the banknote 1 are derived from the comparison. The ratio or difference of signals 15 detected at different points 21 of the bank note 1 is preferably formed, which signals 15 are then used to identify adhesive strips.

The irradiation device 6 comprises a radiation source 7, which emits thermal radiation 8 in the MIR. A Nernst pin or a Globar pin is preferably used as the radiation source 7.

A Nernst pencil is a rod a few centimeters long and a few millimeters thick made of zirconium oxide with additions of yttrium oxide and oxides of other rare earths. The normal operating temperature is around 1900 K. Because of this high operating temperature and the corresponding spectral energy distribution, the Nernst pen is particularly suitable as a radiation source in the mid-infrared.

A Globar pin is a silicon carbide rod with typical diameters of about 6 to 8 mm. The operating temperature is around 1500 K, which results in a lower radiation intensity in the radiation maximum.

Depending on the application, ceramic light sources heated with a metallic conductor can also be used as radiation source 7. A heating wire made of platinum or a platinum alloy is wound around a ceramic rod. This wire helix is covered with a sintered layer of aluminum oxide, thorium oxide, zirconium silicate or a similar material. surrounding material. Coils made of chrome-nickel or tungsten wire are particularly suitable for the short-wave spectral range.

The radiation source 7 is preferably surrounded by a casing 9 with an opening 12. The sheath 9 shields the radiation 8 emitted by the radiation source 7, as a result of which undesired heating of an excessively large area on the bank note 1 but also from neighboring other devices is prevented. Only the radiation 2 provided for irradiation of a specific area of the bank note 1 can emerge from the casing 9 through the opening 12.

In the illustrated embodiment, an aperture 11 is also provided in the area of the opening 12, which is provided for further spatial limitation of the radiation 2 striking the bank note 1. By choosing a specific shape and size of the aperture opening, the shape and size of the area at point 21 on bank note 1 can be set. The diaphragm 11 is preferably slit-shaped, as a result of which a rectangular area on the bank note 1 is irradiated.

In the example shown, a filter 13, e.g. an interference filter is provided. The filter 13 is only permeable in a narrow spectral range, preferably between 5.5 μm and 6 μm, in particular between 5.7 μm and 5.8 μm, so that only the spectral component relevant for the measurement - and thus a comparatively small one spectral portion of the thermal radiation 8 emitted by the radiation source 7 - on the

Banknote 1 hits. This prevents undesired heating of the bank note 1 by spectral components that are not required for the measurement. This is particularly advantageous in cases in which banknotes are prolonged due to banknote jams or a stoppage of the banknote transport Exposed to radiation for a long time, since here a relatively broadband thermal radiation would lead to strong heating and thus to damage or even destruction of the banknote.

Because of the high operating temperatures of the radiation sources 7 described in more detail above, a cooling device (not shown) for cooling the radiation device can preferably be provided in the area of the casing 9.

The detector 4 is preferably designed as a line detector with a plurality of detector elements, so-called pixels, arranged in a row. In the example shown, the detector line runs perpendicular to the plane of the drawing and thus perpendicular to the transport direction 20 and extends over the entire width of the banknote 1. By successive detection of the radiation 3 transmitted at different locations 21 by the banknote 1 during transport, the banknote becomes 1 receive an image in the middle infrared, which is evaluated in the evaluation device 5 for the detection of adhesive strips 10 by suitable image analysis methods.

In analogy to the line detector described above, the detector 4 can also be designed as a two-dimensional area detector, preferably in the size of the area of the bank note 1. In this case, the entire area of the bank note 1 is irradiated and the radiation passing through the bank note 1 is detected by the area detector. In this way, a very rapid detection of the radiation transmitted in the MIR is achieved over the entire bank note 1. As described above, the captured image can be evaluated in the evaluation device 5 to derive statements about any adhesive strips 10 that are present. Thermal detectors or quantum detectors are used as detectors 4 or detector elements.

Thermal detectors have a sensitivity that is independent of the wavelength. Bolometers, which measure the change in resistance due to heating, or pyroelectric detectors, which consist of a radiation-sensitive capacitor, such as e.g. DTGS (deuterated triglycine sulfate doped with alanine), or sintered ceramics, e.g. PZT (lead zirconate titanate). The favorable price and the robust construction are advantageous.

Quantum detectors are very fast and sensitive, which makes them particularly suitable for applications of the invention in banknote checking systems with high transport speeds. The sensitivity of quantum detectors depends on the wavelength. The working principle is based on the external photoelectric effect. Quantum detectors based on CdHgTe ('MCT detector ¹ , Mercury Cadmium Telluride) are preferably used, since they have a very high response speed and sensitivity.

In the exemplary embodiment of FIG. 1 described above, the radiation 3 transmitted by the bank note 1 is detected and used to identify adhesive strips 10. In the sense of the invention it is also possible, as an alternative or in addition to the transmitted radiation, to detect the radiation reflected by the baric note 1 and to use it for the detection of adhesive strips 10. In this case, a corresponding detector (not shown) is arranged on the side of the irradiation device 6 and can be designed to detect the radiation and / or diffusely reflected, ie remitted, radiation reflected by the bank note 1. For example, an integrating sphere, a so-called Ulbricht sphere, can be provided to detect the diffuse reflection. Otherwise, the above statements apply analogously in connection with the detection and evaluation of transmitted radiation 3 for reflected radiation.

2 shows the spectral transmission behavior of a banknote at a point without and a point with adhesive strips B or B + S in a partial region of the middle infrared. The intensity T of the radiation 3 transmitted by the bank note is plotted here over the wavelength λ of the radiation 2 or 3. The intensity T can be a measure of the actual, i.e. absolute, intensity of the radiation transmitted through the banknote or else by the size derived from it, e.g. a variable normalized to the transmission in a certain spectral range.

In the example shown, the difference in light transmitted through the spot on the bill without adhesive strips B intensity T occurs clearly the light transmitted through the place on the banknote with tape B + S intensity T in the WEL ^• wavelength region a forward and is in the wavelength range b most pronounced. Depending on the types of banknotes and adhesive tape types to be checked, the wavelength ranges a and b can, in principle, be between 2.5 μm and 25 μm in the entire middle infrared range.

The area a is preferably between 5.5 μm and 6 μm and the area b is between 5.7 μm and 5.8 μm. In these wavelength ranges, particularly large differences in the transmission behavior are detected for a large number of different banknote types and common types of adhesive tape, which means that even very thin adhesive tapes with typical thicknesses between - lo ¬

15 μm and 50 μm can be detected with high reliability.

As has already been explained in connection with the exemplary embodiment described in FIG. 1, the radiation 3 transmitted by the banknote 1 to be checked in the wavelength ranges a or b is detected by the detector 4 and used for the detection of adhesive strips 10. The measured absolute intensity of the radiation 3 is preferably used as a measure of the transmitted radiation. Alternatively, a variable derived from the intensity of the radiation 3 can also be used, e.g. the intensity of the radiation normalized to the transmission in other spectral ranges 3.

The invention is particularly suitable for the detection of adhesive films .on ^'banknotes from paper or cotton. But also adhesive strips on with

Plastic-coated banknotes made of paper or cotton, so-called paper / polymer banknotes, can be recognized with a high degree of reliability since, despite the plastic coating, significant differences in the transmission behavior between areas with and without adhesive strips are detected in the wavelength ranges mentioned.

The invention is also suitable for the detection of adhesive strips on plastic banknotes, so-called polymer banknotes. In this application, a wavelength range in the MIR is selected in which both the polymer banknotes and the adhesive strips to be detected have a low, but non-zero transmittance. In particular, a strong absorption band is chosen, in which, however, neither the polymer banknotes nor the adhesive strips completely absorb the radiation passing through. In this wavelength range the transmitted radiation is then heavily dependent on the thickness, so that adhesive strips on polymer banknotes can be detected with great sensitivity due to the associated differences in thickness. In these applications, preferred wavelength ranges are between 2.7 μm and 3.6 μm, in particular between 2.7 μm and 3.0 μm or between 3.3 μm and 3.6 μm. In these wavelength ranges, the thickness dependence of the transmitted radiation is particularly pronounced and the detection of adhesive strips is particularly reliable.

Claims

Patent claims

1. A method for recognizing foreign objects, in particular adhesive strips, on or in banknotes (1) with the following steps: - irradiation of a banknote (1) to be examined with electromagnetic radiation (2),

Detection of the radiation (3) reflected by the banknote (1) and / or transmitted by the banknote (1) and detection of foreign objects (10) located on or in the banknote (1) on the basis of the detected radiation (3), characterized in that the wavelength (λ) of the radiation (2, 3) in the middle infrared (MIR) is between 2.5 μm and 25 μm.

2. The method according to claim 1, characterized in that the wavelength (λ) of the radiation (2, 3) is between 3 microns and 12 microns.

3. The method according to any one of claims 1 or 2, characterized in that the wavelength (λ) of the radiation (2, 3) between 5.5 microns and 6 microns (a), in particular between 5.7 microns and 5.8 microns (b).

4. The method according to any one of claims 1 to 3, characterized in that the reflected from the banknote (1) and / or transmitted by the banknote (1) radiation (3) at several different locations (21), in particular along one or several tracks, the banknote (1) is detected.

5. The method according to claim 4, characterized in that the detection of foreign objects (10) located on or in the bank note (1) takes place on the basis of the radiation (3) detected at the different locations (21) of the bank note (1) ,

6. The method according to any one of claims 4 to 5, characterized in that the detection of foreign objects (10) located on or in the bank note (1) by comparing the radiation (1) detected at the different locations (21) of the bank note (1) 3) is done.

7. The method according to any one of claims 4 to 6, characterized in that the detection of foreign objects (10) located on or in the banknote (1) by forming the ratio and / or the difference from the at different points (21) Banknote (1 detected radiation (3) takes place.

8. Device for recognizing foreign objects, in particular adhesive strips, on or in banknotes (1) comprising: at least one irradiation device (6) for irradiating a banknote (1) to be examined with electromagnetic radiation (2), at least one detector (4) for detection the radiation (3) reflected by the banknote (1) and / or transmitted by the banknote (1) and an evaluation device (5) for recognizing foreign objects (10) located on or in the banknote (1) on the basis of the detected

Radiation (3), characterized in that the wavelength (λ) of the radiation (2, 3) in the middle infrared (MIR) is between 2.5 μm and 25 μm.

9. The device according to claim 8, characterized in that the wavelength (λ) of the radiation (2, 3) is between 3 microns and 12 microns.

10. Device according to one of claims 8 to 9, characterized in that the wavelength (λ) of the radiation (2, 3) between 5.5 microns and 6 microns (a), in particular between 5.7 microns and 5.8 microns (b).

11. Device according to one of claims 8 to 10, characterized in that the irradiation device (6) at least one radiation source (7), in particular a Nernst pin and / or a globar pin, for the emission of radiation (8) in the middle infrared (MIR) includes.

12. The device according to one of claims 8 to 11, characterized in that the irradiation device (6) has at least one casing (9) with an opening (12), the radiation (8) emitted by the radiation source (7) from the casing ( 9) is shielded and can only emerge from the casing (9) through the opening (12).

13. The device according to one of claims 8 to 12, characterized in that between the radiation source (7) and the banknote (1) has a, in particular gap-shaped, diaphragm (11) for spatial limitation of the radiation incident on the banknote (1) ) is provided.

14. The apparatus according to claim 13, characterized in that the diaphragm (11) is arranged in the region or in the opening (12) of the casing (9).

15. The device according to one of claims 8 to 14, characterized in that between the radiation source (7) and the banknote (1) at least one filter (13), in particular an interference filter, is provided, which is only for radiation in the detection of Foreign objects (10) used wavelength range (a or b), in particular between

5.5 μm and 6 μm or 5.7 μm and 5.8 μm, is permeable.

16. The apparatus according to claim 15, characterized in that the filter (13) in the region or in the opening (12) of the casing (9) is arranged.

17. Device according to one of claims 8 to 16, characterized in that the detector (4) is designed as a bolometer, pyroelectric detector or quantum detector.

18. Device according to one of claims 8 to 17, characterized in that the detector (4) is designed as a position-resolving line detector or area detector.