JP2001307170A - Fluorescent thread detector of paper sheets - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fluorescent thread detector of paper sheets capable of detecting a fluorescent thread simply and surely. SOLUTION: The fluorescent thread detector of paper sheets 10 irradiates the fluorescent threads S provided at a paper money 2 with ultraviolet rays by an ultraviolet LED 12 to detect the fluorescence emitted from the thread S by a photo sensor 16. In front of the sensor 16 within a casing 11, an infrared cut filter 17 and a condenser 18 with a long wavelength transmission filter function are provided. In cooperation with these filter 17 and the condenser 18, a fluorescent transmission wavelength band including only the fluorescent wavelength peak of the red fluorescent thread of the smallest fluorescent quantity among respective fluorescent wavelength peaks of red, yellow green and blue fluorescent thread being the object of detection is formed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fluorescent thread detecting device for a paper sheet for detecting a fluorescent thread for security provided on a paper sheet such as a bill, a voucher, and a security.

[0002]

2. Description of the Related Art As a conventional thread detecting apparatus for paper sheets, there is, for example, JP-A-10-511784. The paper thread detecting apparatus described in this publication reads a security thread used for banknotes and other securities. This thread is a metal magnetic thread in which each segment is coded so as to indicate a digital value, and the magnetic thread is configured to be read by a magnetic head.

[0003]

However, the above-described conventional thread detecting device is a device which focuses on the magnetic property of the thread and reads the coded magnetism, and focuses on the fluorescent property of the thread. Not something. As a method for identifying the presence or absence of a thread, image recognition using a CCD camera may be considered. However, an apparatus for realizing this method is expensive, and furthermore, the fluorescent component contained in the thread is determined. For this purpose, there is a problem that complicated image processing must be performed.

An object of the present invention is to provide a fluorescent thread detecting device for paper sheets, which can easily and reliably detect the fluorescent thread.

[0005]

SUMMARY OF THE INVENTION The present invention relates to a fluorescent thread detecting apparatus for a paper sheet for detecting a fluorescent thread provided on the paper sheet. A light-emitting element that emits ultraviolet light toward the light-receiving element, a light-receiving element that is housed in the housing, and detects fluorescence emitted from the fluorescent thread by the irradiation of the ultraviolet light, and a light-receiving element that is housed in front of the light-receiving element in the housing and enters the light-receiving element. An infrared cut filter that cuts out the infrared component of the light, and a light that is accommodated in front of the light receiving element in the housing and that is incident on the light receiving element and that has a predetermined wavelength band or more including the fluorescence wavelength peak of the fluorescent thread. A long-wavelength transmission filter for transmitting light is provided, and in cooperation with the infrared cut filter and the long-wavelength transmission filter, the fluorescence amount among the fluorescence wavelength peaks of a plurality of types of fluorescent threads to be detected is reduced. It is characterized in that the formation of the fluorescent transmission wavelength band that includes only the fluorescence wavelength peak of also small fluorescent threads.

By providing the infrared cut filter and the long wavelength transmission filter in this way, it is possible to distinguish not only the fluorescent thread having the smallest amount of fluorescent light but also other fluorescent threads having a large amount of fluorescent light among a plurality of types of fluorescent threads. Becomes That is, the above-mentioned fluorescence transmission wavelength band is formed so as to include only the fluorescence wavelength peak of the fluorescence thread having the smallest fluorescence amount among the respective fluorescence wavelength peaks of the plurality of types of fluorescence threads, so that the other fluorescence threads having the larger fluorescence amount In the detection of the fluorescent sled, the fluorescent level at the foot of the fluorescent wavelength band deviating from the fluorescent wavelength peak of the fluorescent sled may be detected. However, the fluorescence thread has a fluorescence spectral characteristic that the larger the fluorescence wavelength band including the fluorescence wavelength peak, the larger the amount of fluorescence. Therefore, a fluorescent thread having a large amount of fluorescence has a wider fluorescent wavelength band than a fluorescent thread having a small amount of fluorescent light, so that a relatively high amount of fluorescent energy can be obtained even at the bottom of the fluorescent wavelength band. This makes it possible to easily and reliably detect a plurality of types of fluorescent threads. At this time, since the fluorescence transmission wavelength band is formed based on the fluorescent thread having the smallest fluorescence amount, the fluorescent thread having the smallest fluorescence amount can be clearly distinguished from the fluorescent thread.

[0007] Preferably, the infrared cut filter is a filter for cutting a wavelength of about 650 nm or more, and the long wavelength transmission filter is a filter for transmitting a wavelength of about 600 nm or more. There are various types of fluorescence such as red, yellow-green, and blue. Among them, the fluorescence wavelength peak of the red fluorescence thread having the smallest fluorescence amount is 620 to 630 n.
m. Therefore, by configuring the infrared cut filter and the long-wavelength transmission filter as described above, the fluorescence transmission wavelength band is approximately 600 to 650 nm, so that the red fluorescence thread can be clearly distinguished and the yellow-green or blue-colored thread can be distinguished. The determination of the fluorescent thread can be performed reliably.

Preferably, the apparatus further includes a condenser lens housed in the housing in front of the light receiving element, for condensing the fluorescence emitted from the fluorescent thread and guiding the fluorescence to the light receiving element. This allows
Irrespective of the interval between the housing and the bill, a constant reading resolution can always be maintained, which is advantageous for flapping of the bill.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A preferred embodiment of a fluorescent thread detecting apparatus for paper sheets according to the present invention will be described below in detail with reference to the drawings.

FIG. 1 is an enlarged sectional view showing a main part of a sheet inspection apparatus having one embodiment of a fluorescent thread detecting device according to the present invention. The inspection target of the paper sheet inspection device 1 is a bill 2 which is an example of a paper sheet (see FIG. 2).
Specifically, it is a U.S. dollar banknote, an ink country peso banknote, or the like. A fluorescent thread S for security having a width of about 2 mm is printed on such a bill 2. The fluorescent thread S is formed as a metal thin film, and contains a substance that emits fluorescent light.

The paper sheet inspection apparatus 1 for inspecting such a bill 2 has a linear transport path 5 formed so as to be sandwiched between upper and lower guide plates 3 and 4. This transport path 5
Are transported in the middle of the paper money, and the transport rollers 6 and 7 reliably transport the banknote 2 toward the discharge side. A bill recognizing device (not shown) for identifying a denomination is provided in the middle of the transport path 5.

Although not shown, the inside of the bill recognition device illuminates the surface of the bill 2 with a light source such as an LED.
It has a structure in which light reflected from the bill 2 is captured by a CCD camera. Then, the image captured by the camera is compared with known image data, and the denomination of the banknote 2 is determined. However, in recent years, due to the high precision of color copying, it has been difficult to determine the authenticity of the banknote 2 only by image recognition.

Therefore, the fluorescent thread detecting device 10 is arranged on the upstream side of the bill recognizing device (not shown). The fluorescent thread detecting device 10 has a housing 11,
1 accommodates, for example, two sets of ultraviolet LEDs 12 (only one set is shown in FIG. 1), which are light-emitting elements that emit ultraviolet light toward the transport path 5 of the bill 2. L used here
The ED 12 is an ultraviolet lamp containing a visible light component. And the reason for adopting LED12 as the light source is:
This is because even if the housing 11 is small, the housing space may be small, the variation in luminance is small, and the light fluctuation over time is small.

A window 13 for extracting light to the outside is provided on the lower surface of the housing 11, and a dustproof glass plate 14 is fitted into the window 13 with an adhesive or the like. As the dustproof glass plate 14, quartz glass having an extremely high ultraviolet transmittance is used. Dustproof glass plate 14 and UV LE
An ultraviolet transmission filter 15 is disposed between the filter and D12.
This ultraviolet filter 15 is located on the optical axis G of the ultraviolet LED 12. The light emitted from the ultraviolet LED 12 passes through the ultraviolet transmission filter 15, so that an ultraviolet component (for example, about 200 to 400 nm) is removed from the dustproof glass plate 1.
4, and is discharged to the transport path 5. Then, the ultraviolet light is irradiated on the fluorescent thread S of the banknote 2 that has been sent to a position directly below the dustproof glass plate 14 through the transport path 5.

In a space A formed by the light shielding wall P of the housing 11, a photosensor 16 which is a light receiving element for detecting fluorescence excited by the fluorescent thread S by irradiation of ultraviolet rays is accommodated. This photo sensor 16
Outputs an electric signal (current signal) corresponding to the level of the fluorescence emitted from the fluorescent thread S.

In the housing 11, between the dust-proof glass plate 14 and the photo sensor 16, an infrared cut filter 1 is provided.
7 are arranged. The reason for employing the infrared cut filter 17 has been clarified in various experiments that an infrared wavelength component is present in addition to the fluorescent light excited from the fluorescent thread S, so that the determination of the fluorescent component of the fluorescent thread S is clear. This is because it is necessary to remove even a slight infrared component in order to perform the above.

In the housing 11, between the dustproof glass plate 14 and the infrared cut filter 17, a condenser lens 18 that collects the fluorescence emitted from the fluorescent thread S and guides the fluorescence to the photosensor 16 is disposed. . This condenser lens 1
Numeral 8 is made up of a plastic lot lens or the like as shown in FIGS. 1 and 3 so that only the fluorescent light excited by the fluorescent thread S is incident on the photosensor 16.
By narrowing down the fluorescent light by such a condensing lens 18, the window 13 (the dust-proof glass plate 14) and the bill 2
A constant width can always be read irrespective of the interval between the two. Therefore, when the banknote 2 is conveyed, even if the banknote 2 flaps, it is possible to maintain substantially the same reading resolution as in the state without flapping. At this time, it is preferable to position the ultraviolet LED 12 so that the amount of light increases as the bill 2 moves away from the ultraviolet LED 12 by utilizing the light emitting directivity characteristics of the LED. In this case, regardless of the interval between the ultraviolet LED 12 and the bill 2, a constant output voltage is always obtained as the amount of the fluorescent component received from the fluorescent thread S. For this reason, when the bill 2 is conveyed,
Even when the fluttering occurs, it is possible to obtain a signal substantially the same as in the state without fluttering.

Such a condensing lens 18 has a long wavelength transmission filter function of transmitting light of a predetermined fluorescence wavelength band or more including the fluorescence wavelength peak of the fluorescence thread S among the light incident on the photo sensor 16. ing.

Here, there are various types of fluorescent light excited by ultraviolet rays, such as red, yellow-green, and blue. The fluorescent wavelength band differs depending on the fluorescent color, and the amount of fluorescent light changes accordingly. Specifically, the larger the fluorescence wavelength band, the larger the amount of fluorescence.

By the way, bill 2 as shown in FIG.
A fluorescent thread S having a different fluorescent color may be provided for each denomination. As an example, FIG. 4 shows the fluorescence spectral characteristics of the respective fluorescent threads S when the red, yellow-green, and blue fluorescent threads S are provided on the banknote 2. 4A shows a red fluorescent thread, FIG. 4B shows a yellow-green fluorescent thread, and FIG. 4C shows a blue fluorescent thread. As can be seen from this figure, among the red, yellow-green, and blue fluorescent threads, the fluorescent wavelength band of the red fluorescent thread having a fluorescent wavelength peak of about 620 to 630 nm is the narrowest, and accordingly, the amount of fluorescence is the smallest. small.

Light collection with the above long wavelength transmission filter function
The lens 18 and the infrared cut filter 17 are
In cooperation, each fluorescent wavelength of red, yellow-green, and blue fluorescent threads
Peak P₁~ P_ThreeRed fluorescence with the smallest fluorescence
Thread fluorescence peak P ₁Fluorescence transmission wavelength including only
A band F is formed. More specifically,
Filter 17 cuts a wavelength of about 650 nm or more.
Filter with long wavelength transmission filter function
The lens 18 is a lens that transmits a wavelength of about 600 nm or more.
It is a filter. Thereby, the fluorescence transmission wavelength band F becomes 6
It becomes 00-650 nm.

By forming the fluorescence transmission wavelength band F in accordance with the red fluorescent thread having the smallest amount of fluorescence in this way, it is possible to clearly determine the red fluorescent thread. In addition, here, in consideration of the fact that the red fluorescence is adjacent to the infrared wavelength spectrum, approximately 65
Wavelengths of 0 nm or more are cut.

Furthermore, not only the red fluorescent thread,
It is also possible to distinguish between yellow-green and blue fluorescent threads. For example, in the detection of yellow-green fluorescent threads, as shown in FIG. 4 (b), the fluorescence level of the foot of the fluorescence wavelength band deviated from the fluorescence wavelength peak P ₂ of the fluorescent thread is detected. However, the fluorescent wavelength band of the yellow-green fluorescent thread is sufficiently wider than the fluorescent wavelength band of the red fluorescent thread, and the amount of fluorescence increases accordingly. For this reason, relatively high fluorescence energy can be obtained even at the bottom of the fluorescence wavelength band, whereby the presence or absence of a fluorescent thread can be detected easily and reliably. The same applies to the blue fluorescent thread.

Further, since the ultraviolet component of the light incident on the light receiving element is reliably removed by the condenser lens 18 having a long wavelength transmission filter function, the ultraviolet light reflected on the surface of the bill 7 is converted into noise as noise. It is possible to avoid erroneous detection due to the incidence on the light incident on the light source 16.

Here, the condenser lens 18 having a long wavelength transmission filter function is provided between the dustproof glass plate 14 and the infrared cut filter 17, but the long wavelength transmission filter and the condenser lens are composed of separate members. May be. Further, instead of the condenser lens, a slit plate having a slit hole may be provided, and the fluorescence may be narrowed down by the slit hole.

Returning to FIG. 1, a printed circuit board 21 is provided on the upper surface of the housing 11, and the printed circuit board 21 is provided with an amplifier circuit for converting an output current from the photosensor 16 into a voltage and amplifying it. ing. An output monitoring photosensor 22 for monitoring the output of the ultraviolet LED 12 is attached to the inner surface of the printed board 21. An external connector 23 is connected to the upper surface of the printed circuit board 21 so that an output signal of the amplifier circuit is output to the external connector 2.
The data is sent to an external discriminating means via 3 and authenticity judgment or denomination discrimination is performed.

The present invention is not limited to the embodiment described above. For example, paper sheets applied to the present invention are not limited to banknotes, but may be slips or securities.

[0028]

According to the present invention, the cooperation of the infrared cut filter and the long-wavelength transmission filter allows the fluorescent thread having the smallest amount of fluorescence among the fluorescent wavelength peaks of a plurality of types of fluorescent threads to be detected. Since the fluorescence transmission wavelength band including only the fluorescence wavelength peak is formed, the fluorescence thread can be easily and reliably detected.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view showing one embodiment of a fluorescent thread detecting device according to the present invention.

FIG. 2 is a diagram showing typical banknotes as representatives.

FIG. 3 is a bottom view of the fluorescent thread detecting device shown in FIG. 1;

4 is a diagram showing red, yellow-green, and blue fluorescence spectral characteristics corresponding to the types of the fluorescent threads shown in FIG. 2;

[Explanation of symbols]

7: banknotes (sheets), 10: fluorescent thread detection device, 1
DESCRIPTION OF SYMBOLS 1 ... Housing, 12 ... Ultraviolet LED (light emitting element), 16 ... Photosensor (light receiving element), 17 ... Infrared cut filter, 18 ... Condenser lens with long wavelength transmission filter function (long wavelength transmission filter, condenser lens) , S ... fluorescent thread.

Claims (3)

[Claims] 1. A fluorescent thread detecting device for a paper sheet for detecting a fluorescent thread provided on the paper sheet, wherein the fluorescent thread detecting apparatus is housed in a casing and irradiates the fluorescent thread of the paper sheet with ultraviolet light. A light-emitting element, a light-receiving element that is housed in the housing, and detects fluorescence emitted from the fluorescent thread by the irradiation of the ultraviolet light, and a light-receiving element that is housed in front of the light-receiving element in the housing and is incident on the light-receiving element. An infrared cut filter that cuts out the infrared component of the light, and a predetermined wavelength band that is housed in front of the light receiving element in the housing and includes a fluorescent wavelength peak of the fluorescent thread among light incident on the light receiving element. A long-wavelength transmission filter that transmits the above light, and a plurality of types of the fluorescent threads to be detected are cooperated by the infrared cut filter and the long-wavelength transmission filter. Of the fluorescence wavelength peak of de fluorescence thread detecting apparatus of the paper sheet, characterized in that the formation of the fluorescent transmission wavelength band that includes only the fluorescence wavelength peak of the fluorescence amount is the smallest fluorescent threads. 2. The infrared cut filter according to claim 1, wherein the infrared cut filter is substantially 650.
The fluorescence thread detecting device for paper sheets according to claim 1, wherein the filter is a filter that cuts a wavelength of at least nm, and the long wavelength transmission filter is a filter that transmits a wavelength of at least approximately 600 nm. 3. The light-receiving device according to claim 1, further comprising a condenser lens that is housed in front of the light-receiving element in the housing and condenses the fluorescence emitted from the fluorescent thread and guides the fluorescence to the light-receiving element. 3. The fluorescence thread detecting device for paper sheets according to 2.