JP4746449B2 - Paper sheet inspection device - Google Patents

Description

  The present invention relates to a paper sheet inspection apparatus for inspecting a paper sheet or the like to which a hologram is attached.

  A diffractive optical change element (hereinafter referred to as diffractive OVD) typified by a hologram is an element that has been processed to cause a light diffraction phenomenon on its surface, and is brilliant due to the diffraction / interference phenomenon of light due to the diffraction pattern. It has a pattern that emits color. Since the hologram has optical characteristics different from those of normal printing, it is used as a security thread for paper sheets such as gift certificates and securities, and is realized for the purpose of determining authenticity.

Various inspection devices for inspecting paper sheets are used for the purpose of quality control of paper sheets with such holograms. For example, an inspection apparatus that irradiates the surface of an inspection medium with laser light and inspects the reflected diffraction image using a light receiving sensor, or an apparatus that inspects an inspection medium that moves using line illumination has been put into practical use. (For example, Patent Documents 1, 2, and 3).
JP 2004-150885 A JP 2002-221494 A JP 2002-221696 A

  However, in the conventional inspection apparatus using laser light, there is a problem that conditions for observing the inspection medium with the inspection medium stationary are severe, and that information collection and discrimination processing take time. An inspection apparatus that inspects a moving medium has a problem that fluttering of the inspection medium adversely affects the inspection result.

  Also, paper and other securities such as securities will be chipped and chipped during the distribution process, resulting in “defects” due to chipping and peeling, and “fatigue” in which the surface characteristics of scratches and wrinkles deteriorate and the original optical characteristics of the hologram are lost. there is a possibility. In an apparatus for automatically inspecting these paper sheets, it is required to inspect the authenticity (genuine and fake) and the damaged state. However, an apparatus for inspecting such a hologram defect or exhaustion is not provided.

  The present invention has been made in view of the above points, and an object thereof is to provide a paper sheet inspection apparatus capable of stably detecting the authenticity and damage of a paper sheet with a hologram attached thereto.

In order to achieve the above object, a paper sheet inspection apparatus according to an aspect of the present invention is a paper sheet inspection apparatus that inspects a paper sheet provided with a hologram having a diffraction pattern of a desired shape formed on a metal foil. A light source device for irradiating illumination light from a predetermined direction for obtaining diffracted light from the hologram, a first light receiving unit for receiving diffracted light from the hologram, and the hologram A second light-receiving unit that receives the transmitted light that has been irradiated and transmitted through the paper sheet, and the authenticity of the hologram is determined from the diffracted light received by the first light-receiving unit, and is received by the second light-receiving unit. And a discrimination processing device for discriminating a defect of the metal foil of the hologram from the transmitted light.

  According to the above configuration, it is possible to provide a paper sheet inspection apparatus capable of stably detecting the authenticity and damage of a paper sheet with a hologram.

Hereinafter, a paper sheet inspection apparatus according to an embodiment of the present invention will be described in detail with reference to the drawings.
As shown in FIGS. 1 and 2, the paper sheet inspection apparatus according to the first embodiment of the present invention holds a paper sheet 12 such as a securities with a hologram 10 to be inspected. 14, a light source device 16 that irradiates a paper sheet with illumination light for inspection, a first light receiving sensor 18 that receives reflected light from the hologram 10, and a second light receiving sensor 20 that receives transmitted light that has passed through the paper sheet. It has.

  The hologram 10 has, for example, a circular metal foil 10a attached to a paper sheet 12, and a desired shape formed on the metal foil, for example, a diffraction pattern (diffraction grating) 10b of “A”. When visible light is irradiated from a predetermined angle, the hologram 10 reflects diffracted light corresponding to the diffraction pattern 10b and displays a rainbow feature pattern.

  The holding mechanism 14 includes, for example, a plurality of rollers 22 and a belt (not shown), and holds the paper sheet 12 at a predetermined position in a state where a tension is applied, that is, in a tensioned state without slack.

  The light source device 16 includes a spot illuminator that irradiates spot illumination light to an illumination area 34 that includes the hologram 10 and is larger than the hologram. The spot illuminator is constituted by, for example, an incandescent light source, and irradiates illumination light in a wide wavelength region including wavelengths from a visible light wavelength region to a near infrared wavelength region. The light source device 16 is disposed at a predetermined angular position with respect to the paper sheet 12, and irradiates the hologram with illumination light having directivity optimized so that a diffraction image can be obtained by the diffraction pattern 10b of the target hologram 10. .

  The first light receiving sensor 18 functioning as a first light receiving unit is provided on the same surface side as the light source device 16 with respect to the paper sheet 12 and is disposed at a position for receiving diffracted light from the hologram 10. The first light receiving sensor 18 includes an imaging lens 19 and receives reflected light imaged by the imaging lens. As the first light receiving sensor 18, a point photo sensor, a monochrome CCD sensor, a color CCD sensor, or the like can be used.

  The second light receiving sensor 20 that functions as a second light receiving unit is provided on the opposite side of the light source device 16 with respect to the paper sheet 12 and receives a transmitted light that has passed through the paper sheet 12 from the periphery of the hologram 10. It is arranged. The second light receiving sensor 20 includes an imaging lens 21 and receives transmitted light imaged by the imaging lens. As the second light receiving sensor 20, a point photo sensor, a monochrome CCD sensor, a color CCD sensor, or the like can be used.

  As shown in FIG. 3, the paper sheet inspection apparatus performs arithmetic processing on the detection data detected by the first light receiving sensor 18 to extract features, compares it with reference data stored in the determination reference memory 26, and generates a hologram. The first discrimination processing circuit 28 for discriminating the authenticity of 10 and the detection data detected by the second light receiving sensor 20 are arithmetically processed to extract features, and are compared with the reference data stored in the determination reference memory 26, and the hologram and A second determination processing circuit 30 for determining whether the paper sheet 12 is damaged or missing, a light source driver 32 for driving the light source device 16, and a control unit 36 for controlling the operation of the entire device. The first and second discrimination processing circuits function as a discrimination processing device.

Next, the inspection operation of the paper sheet inspection apparatus configured as described above will be described.
Conditions under which diffracted light appears from the hologram 10 to be inspected are determined by the direction and pitch of the diffraction grating of the hologram. As shown in FIG. 4, the irradiation light from the light source device 16 illuminates the hologram 10 at an incident angle θ1 optimized in a direction B orthogonal to the diffraction grating 10 b of the hologram 10. Thereby, specularly reflected light appears at an angle θ1 from the diffraction grating 10b. Diffracted light is observed between the incident angle and the regular reflection light angle.

  Assuming that the illumination light is spot illumination having an illumination region 34 slightly larger than the dimension of the hologram 10 to be inspected, here, the dimension of the metal foil 10a, the illumination light is incident on the hologram 10 as shown in FIG. Since the angle varies depending on the position of the hologram, the wavelengths of the diffracted beams λ2, λ3, and λ4 are shifted. As a result, when a color CCD sensor is used as the first light receiving sensor 18, an image received by the first light receiving sensor is obtained as an iridescent image having different wavelengths depending on the position. The first discrimination processing circuit 28 performs arithmetic processing on the detection data detected by the first light receiving sensor 18 to extract features as a two-dimensional image, compares it with reference data stored in the determination reference memory 26, and compares the hologram 10 Determine the authenticity of

  Of the illumination light irradiated on the illumination area 34 of the paper sheet 12, the light hitting the hologram 10 is shielded by the metal foil 10a and hardly transmits the paper sheet. The light hitting the periphery of the hologram 10 passes through the paper sheet 12 and is received by the second light receiving sensor 20. Compared with the transmitted light that passes through the paper sheet 12, the light that is shielded by the metal foil 10a as the non-transmissive light region is extremely small, and therefore information on the metal foil can be obtained from this non-transmissive region. The second discrimination processing circuit 30 performs arithmetic processing on the detection data detected by the second light receiving sensor 20 to extract a feature as a one-dimensional or two-dimensional image and compares it with reference data stored in the determination reference memory 26. . Thereby, the second determination processing circuit 30 determines whether the hologram 10 is damaged or missing.

  As described above, the paper sheet inspection apparatus illuminates the optimized spot illumination light on the hologram 10 attached to the paper sheet 12, and detects the diffracted light information from the hologram, thereby improving the authenticity of the hologram. Can be inspected. The above-mentioned diffracted light is not observed unless a specific hologram such as a genuine diffraction grating pattern or pitch is completely matched in a forgery hologram medium intentionally pasted for similar purposes or a counterfeit hologram medium. Thereby, effective authentication can be performed. Even when the same hologram is repeatedly manufactured without intending forgery, it is possible to inspect whether the quality and characteristics of the hologram are stable.

At the same time, by detecting the transmitted light information transmitted through the paper sheet, it is possible to inspect the metal foil used in the hologram for defects or damage. Rainbow holograms, which can observe rainbow-colored stripes when white light is applied to the surface, have conditions that make it difficult to transmit light because of the principle that light reflected by a metal foil reproduces an image. By utilizing this characteristic and detecting the transmitted light information from the hologram with the same inspection device, it is possible to inspect the metal foil for damage or loss.
Accordingly, it is possible to provide a paper sheet inspection apparatus capable of stably detecting the authenticity and damage of a paper sheet with a hologram attached thereto.

  By using spot illumination light as the inspection light emitted from the light source device, illumination optimized for the characteristics of the diffraction grating of the hologram can be realized. When diffuse illumination or large area illumination is used, light having a direction other than that of optimum illumination exists. The risk of obtaining iridescent features increases as these lights are adapted to different diffraction gratings. It is desirable that the illumination light required from this viewpoint is the minimum necessary light optimized for the inspection object. A spot illuminator is an illumination suitable for this purpose.

  Even when a photodiode or the like is used as the first light receiving sensor, information on the diffracted light of the hologram can be detected. However, obtaining a two-dimensional image information enables a higher-performance authentication. As for the second light receiving sensor for detecting the transmitted light that passes through the paper sheet, a sensor for detecting one-dimensional data such as a photodiode and an image sensor such as a CCD sensor for obtaining two-dimensional image information can be used. Then, the image sensor becomes effective. Further, when a color image sensor which is a two-dimensional image sensor, for example, a color CCD sensor, is used as the first and second light receiving sensors, the discrimination performance can be further improved.

  As the light source device, white illumination or spot illumination having a wide wavelength range characteristic such as an incandescent light source can be used to maximize the rainbow feature of the rainbow hologram to be inspected. At the same time, iridescent features can be obtained stably even when the hologram surface is tilted or has some irregularities. Since the appearance of the rainbow feature varies depending on the conditions, it is possible to obtain stable performance by making a determination based on evaluation criteria such as the presence / absence of the feature and the frequency of the feature.

  When using a light source device that includes heat rays, such as an incandescent light source, inspection of damage and defects is achieved by reducing the influence of the printed ground pattern around the hologram by transmitting and receiving light in the near-infrared wavelength region. It is possible to improve performance and is effective.

Next explained is the second embodiment of the invention.
In the first embodiment described above, the hologram is inspected while the paper sheet 12 is stationary. However, according to the second embodiment, as shown in FIG. 12 is provided along a direction C parallel to the paper surface. The transport mechanism includes a plurality of transport rollers 40 that transport the paper sheet 12 while sandwiching the paper sheet 12, a transport belt (not shown), and the like.

  According to this inspection apparatus, while transporting the paper sheet 12 by the transport mechanism, the illumination light is irradiated from the light source device 16 to the illumination area 34 including the hologram 10, and the reflected light is detected by the first light receiving sensor 18, The transmitted light that has passed through the paper sheet is detected by the second light receiving sensor 20.

  In the second embodiment, other configurations are the same as those of the first embodiment described above, and the same reference numerals are given to the same portions, and detailed description thereof is omitted. Also in the second embodiment, the same operational effects as in the first embodiment can be obtained. In addition, the sheet can be inspected while being conveyed, and can be developed for various uses.

Next explained is the third embodiment of the invention.
As shown in FIGS. 7 and 8, according to the second embodiment, the paper sheet inspection apparatus includes two illuminators as the light source device 16. That is, the light source device 16 includes a spot illuminator 16a and a transmissive illuminator 16b that emits transmissive illumination light.

  The spot illuminator 16a irradiates the illumination area 34a where the hologram 10 is provided with spot illumination light. The spot illuminator 16a is configured as a light source that emits illumination light in the visible light wavelength region. The spot illuminator 16a is disposed at a predetermined angular position with respect to the paper sheet 12, and irradiates the hologram with illumination light having directivity optimized so that a diffraction image can be obtained by the diffraction pattern 10b of the hologram 10. .

  The transmission illuminator 16b irradiates the illumination light for transmission to the illumination area 34b including the hologram 10 and larger than the hologram. The transmission illuminator 16b is configured as a light source that emits illumination light in the near-infrared wavelength region. In the third embodiment, other configurations are the same as those of the first embodiment described above, and the same reference numerals are given to the same portions, and detailed description thereof is omitted.

  According to the third embodiment, the same operational effects as those of the first embodiment can be obtained. In addition, the light source device is configured by an illuminator that illuminates illumination light in a wavelength region that is reflected by a hologram, and an illuminator that illuminates illumination light in a wavelength region that is transmitted through a paper sheet. It is possible to set an optimum function suitable for detection. That is, the spot illuminator 16a can have the same spot diameter as that of the hologram 10, thereby increasing the intensity and uniformity of the illumination light and improving the detection accuracy. Further, the irradiation light wavelength of the transmission illuminator 16b is set to a wavelength region different from the irradiation light wavelength of the spot illuminator 16a, thereby preventing mutual interference. By setting the illumination light of the transmission illuminator 16b in the near-infrared wavelength region, it is possible to reduce the influence of the printed background pattern of the paper sheet, and to ensure that the illumination light can be transmitted through the paper sheet.

Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. In addition, various inventions can be formed by appropriately combining a plurality of components disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined.
For example, the first and second light receiving sensors may be line sensors. The spot shape of the light source device is not limited to a circle but may be any other shape.

FIG. 1 is a perspective view showing a paper sheet inspection apparatus according to a first embodiment of the present invention. FIG. 2 is a side view schematically showing the paper sheet inspection apparatus. FIG. 3 is a block diagram showing the overall configuration of the paper sheet inspection apparatus. FIG. 4 is a diagram showing diffracted light and reflected light of a hologram. FIG. 5 is a diagram showing diffracted light of a hologram by spot illumination light. FIG. 6 is a perspective view showing a paper sheet inspection apparatus according to the second embodiment of the present invention. FIG. 7 is a perspective view showing a paper sheet inspection apparatus according to a third embodiment of the present invention. FIG. 8 is a side view schematically showing the paper sheet inspection apparatus according to the third embodiment.

Explanation of symbols

10 ... Hologram, 12 ... Paper sheets, 16 ... Light source device,
18 ... 1st light receiving sensor, 20 ... 2nd light receiving sensor, 26 ... Judgment reference memory,
28 ... 1st determination processing circuit, 30 ... 2nd determination processing circuit

Claims (10)

A paper sheet inspection apparatus for inspecting a paper sheet provided with a hologram having a diffraction pattern of a desired shape formed on a metal foil ,
A light source device that irradiates the hologram of the paper sheet with illumination light from a predetermined direction to obtain diffracted light from the hologram;
A first light receiving unit for receiving diffracted light from the hologram;
A second light receiving unit that receives transmitted light that has been irradiated onto the hologram and transmitted through the paper;
A discrimination processing device for discriminating the authenticity of the hologram from the diffracted light received by the first light-receiving unit and discriminating a defect of the metal foil of the hologram from the transmitted light received by the second light-receiving unit;
Paper sheet inspection device equipped with.   2. The paper sheet inspection apparatus according to claim 1, wherein the light source device includes a spot illuminator that includes the hologram and irradiates spot illumination light on a region larger than the hologram. 3.   The sheet processing apparatus according to claim 2, wherein the light source device includes an illuminator that irradiates illumination light including a wavelength region from a visible light wavelength region to a near infrared wavelength region. A paper sheet inspection apparatus for inspecting a paper sheet provided with a hologram having a diffraction pattern of a desired shape formed on a metal foil,
A spot illuminator that irradiates the hologram of the paper sheet with a spot illumination light from a predetermined direction to obtain diffracted light from the hologram;
A first light receiving unit for receiving diffracted light from the hologram;
A transmission illuminator that includes the hologram and irradiates transmission illumination light to an area larger than the hologram;
A second light receiving unit that receives transmitted light that has been irradiated onto the hologram and transmitted through the paper;
A discrimination processing device for discriminating the authenticity of the hologram from the diffracted light received by the first light-receiving unit and discriminating a defect of the metal foil of the hologram from the transmitted light received by the second light-receiving unit;
Paper sheet inspection device equipped with .   The paper sheet according to claim 4, wherein the spot illuminator is an illuminator that irradiates illumination light in a visible light wavelength range, and the transmission illuminator is an illuminator that irradiates illumination light in a near-infrared wavelength region. Processing equipment.   6. The paper sheet processing apparatus according to claim 1, wherein at least one of the first and second light receiving units includes a detector that detects a one-dimensional image.   6. The paper sheet processing apparatus according to claim 1, wherein at least one of the first and second light receiving units includes a detector that detects a two-dimensional image.   The paper sheet processing apparatus according to any one of claims 1 to 5, wherein at least one of the first and second light receiving units includes a detector that detects a color image. The transmission illuminator irradiates the hologram with illumination light from an oblique direction, and the second light receiving unit is arranged to receive transmission light from a direction orthogonal to the paper sheet. 4. The paper sheet processing apparatus according to 4. The paper sheet processing apparatus according to any one of claims 4 to 9, wherein a light emission wavelength of the transmission illuminator is set to a wavelength region different from a light emission wavelength of the spot illuminator.

Images