JP3799498B2 - Information recording medium provided with information that can be identified under transmitted X-rays - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an information recording medium including banknotes, stamps, stamps, stamps, stock certificates, bonds, gift certificates, admission tickets, registration cards, membership cards, rights certificates, immigration cards, and passports.
[0002]
[Prior art]
In order to prevent counterfeiting of precious printed matter such as banknotes so far, for example, paper is used for cleaning, security threads or fluorescent fibers that emit light under ultraviolet light, printing is used for micro characters, and special latent images that appear when tilted obliquely. An image pattern, fluorescent printing that emits light under ultraviolet light, or elaborate coloring patterns, fine lines, portraits, and the like were applied to various kinds of precious printed matter, and the effectiveness against counterfeiting was maintained. Recently, however, counterfeiting of printed matter using color copiers and printer output using a personal computer has become more frequent, making counterfeiting of precious printed matter more difficult and making it easy for anyone to determine authenticity. Therefore, in combination with the forgery prevention technology, OVD and metal foil with optical changes are attached (for example, British 20 pound ticket, German 100 mark ticket, etc.).
[0003]
[Problems to be solved by the invention]
This metal layer made of OVD and metal foil is effective for color copying and forgery by printer output, but for the part to which the metal layer is applied, it prevents the OVD image change and the recognition of the color and brightness of the metal foil. In order to avoid this problem, it has been difficult to provide other anti-counterfeiting technology in the same region to which the metal layer has been applied. However, precious printed matter such as banknotes has high security by providing a plurality of anti-counterfeiting techniques, not only one, in one area in order to enhance the anti-counterfeiting effect in a limited narrow area. Furthermore, their effectiveness increases further when they are related to each other.
[0004]
[Means for Solving the Problems]
Therefore, in the present invention, first information that is hidden by the metal layer and cannot be recognized in a normal visual state (visible light) is given to the same region under the metal layer. This first information is information that can be recognized under transmitted X-rays. By giving this first information, in addition to OVD image information in the metal layer, information on the color and brightness of the metal foil, New information can be given. In the present invention, the second information recognizable under the transmission X-ray is also given to the opposite side of the same region covered with the metal layer, so that one composite image under the transmission X-ray is obtained. It is assumed that (third information) can be recognized. This makes it possible to obtain a more complicated forgery prevention effect in the same predetermined region. In addition, by confirming the presence or absence of correlation between the composite information appearing under the transmitted X-rays and the information on the metal layer, it is possible to easily and reliably determine the authenticity, thereby realizing an information recording medium that is extremely difficult to forge. .
[0005]
In order to solve the above problems, the present invention prints a base material and an ink having an X-ray transmittance of α% (where α is a constant) on a predetermined region on one surface of the base material. In order to conceal the presence of the first information and the presence of the first information, an X-ray transmittance covering the predetermined region from the one surface is β% (where α <β; β is X-ray transmittance is γ% (where γ <β; γ is a constant) in the nonmagnetic metal layer of the constant and the region corresponding to the predetermined region on the other surface of the base material. )) And the third information obtained by synthesizing the first information and the second information under transmitted X-rays, and the base material The X-ray transmittance of the metal layer is higher than α% which is the X-ray transmittance of the first information and γ% which is the X-ray transmittance of the second information, and the X-ray transmittance of the metal layer is the base information. By higher than X-ray transmission factor of said third information under transmitted X-ray is to provide an information recording medium characterized by comprising a recognizable.
[0006]
Furthermore, in order to solve the above-mentioned problems, the present invention provides an ink having an X-ray transmittance of α% (where α is a constant) in a predetermined region of the base material and one surface of the base material. In order to conceal the presence of the first information printed in step 1 and the first information, the X-ray transmittance covering the predetermined region from the one surface is β% (where α <β; β is a constant) and a region corresponding to the predetermined region on the other surface of the base material has an X-ray transmittance of γ% (where γ <β; γ is a constant). The second information printed with ink, the third information obtained by combining the first information and the second information under transmitted X-rays, and the metal layer. The X-ray transmittance of the base material is α% which is the X-ray transmittance of the first information and γ which is the X-ray transmittance of the second information. Higher than the X-ray transmittance of the metal layer is higher than the X-ray transmittance of the base material, so that the third information is recognized under a predetermined viewing condition that is not based on the transmitted X-ray. Information recording characterized in that the fourth information can be recognized, the third information can be recognized under transmitted X-rays, and the fourth information cannot be recognized. Provide media.
[0007]
The first information, the second information, and the third information by the printing ink that can be recognized as a transmitted X-ray image are recorded as machine-readable code information using a barcode or a two-dimensional code. It is good also as composition which has.
[0008]
The ink having the X-ray transmittance of α% and the ink having the X-ray transmittance of γ% are magnetic inks, and the magnetic data of the third information is the magnetic data of the first information and the second information. It may be configured as magnetic data obtained by combining the magnetic data.
[0009]
The first information and the second information may be printed using a colored or transparent ink containing an element having a lower X-ray transmittance than the metal layer and the substrate.
[0010]
Furthermore, in order to solve the above-mentioned problems, the present invention provides a base material having an X-ray transmittance of α% (where α is a constant), and the base material and X in a predetermined region of the base material. X for covering the predetermined region from one surface of the base material in order to conceal the presence of the first information and the first information recorded by using a gap so as to have different line transmittances X-ray transmittance in a nonmagnetic metal layer having a line transmittance of β% (where α <β; β is a constant) and a region corresponding to the predetermined region on the other surface of the substrate. Is composed of the second information printed with ink of γ% (where γ <β; γ is a constant) and the first information and the second information under transmitted X-rays. The X-ray transmittance of the base material is higher than γ%, which is the X-ray transmittance of the second information, so that the transmitted X-ray An information recording medium characterized in that the third information can be recognized.
[0011]
Furthermore, in order to solve the above-mentioned problems, the present invention provides a base material having an X-ray transmittance of α% (where α is a constant), and the base material and X in a predetermined region of the base material. X for covering the predetermined region from one surface of the base material in order to conceal the presence of the first information and the first information recorded by using a gap so as to have different line transmittances X-ray transmittance in a nonmagnetic metal layer having a line transmittance of β% (where α <β; β is a constant) and a region corresponding to the predetermined region on the other surface of the substrate. Is composed of the second information printed with ink of γ% (where γ <β; γ is a constant) and the first information and the second information under transmitted X-rays. Third information obtained in this manner and fourth information recorded on the metal layer, and the X-ray transmittance of the base material is more than γ% which is the X-ray transmittance of the second information. The third information becomes unrecognizable under a predetermined viewing condition that is not under transmitted X-rays, and the fourth information is recognizable under transmitted X-rays. An information recording medium is provided in which the third information can be recognized and the fourth information cannot be recognized.
[0012]
Furthermore, in order to solve the above-mentioned problems, the present invention provides a base material having an X-ray transmittance of α% (where α is a constant), and the base material and X in a predetermined region of the base material. X for covering the predetermined area from one surface of the substrate in order to conceal the presence of the first information recorded using micro-perforation so as to have different line transmittances and the presence of the first information X-ray transmittance in a nonmagnetic metal layer having a line transmittance of β% (where α <β; β is a constant) and a region corresponding to the predetermined region on the other surface of the substrate. Is composed of the second information printed with ink of γ% (where γ <β; γ is a constant) and the first information and the second information under transmitted X-rays. The X-ray transmittance of the base material is higher than γ%, which is the X-ray transmittance of the second information, so that the transmitted X-ray An information recording medium characterized in that the third information can be recognized.
[0013]
Furthermore, in order to solve the above-mentioned problems, the present invention provides a base material having an X-ray transmittance of α% (where α is a constant), and the base material and X in a predetermined region of the base material. X for covering the predetermined area from one surface of the substrate in order to conceal the presence of the first information recorded using micro-perforation so as to have different line transmittances and the presence of the first information X-ray transmittance in a nonmagnetic metal layer having a line transmittance of β% (where α <β; β is a constant) and a region corresponding to the predetermined region on the other surface of the substrate. Is composed of the second information printed with ink of γ% (where γ <β; γ is a constant) and the first information and the second information under transmitted X-rays. Third information obtained in this manner and fourth information recorded on the metal layer, and the X-ray transmittance of the base material is more than γ% which is the X-ray transmittance of the second information. The third information becomes unrecognizable under a predetermined viewing condition that is not under transmitted X-rays, and the fourth information is recognizable under transmitted X-rays. An information recording medium is provided in which the third information can be recognized and the fourth information cannot be recognized.
[0014]
As the configuration in which the first information, the second information, and the third information by the insertion or the fine perforation are machine-readable code information and are recorded using a barcode or a two-dimensional code. Also good.
[0015]
In order to conceal the presence of the first information between the base information and the first information by the printing ink, an ink having higher X-ray transmittance than the base material, the printing ink and the metal layer is used. It is good also as a structure by which the concealment image line is printed.
[0016]
In order to conceal the presence of the first information by the printing ink on the surface opposite to the surface on which the metal layer is provided on both surfaces of the base material, the X-ray transmittance is the base material, the printing ink and the above It is good also as a structure by which the concealment image line is printed using the ink higher than a metal layer.
Further, in order to conceal the presence of the first information by the clearance or the fine perforation on the surface opposite to the surface on which the metal layer is provided on both surfaces of the base material, the X-ray transmittance is the base material. And it is good also as a structure by which the concealment image line is printed using the ink higher than the said metal layer.
[0017]
In order to conceal the presence of the first information between the metal layer and the first information by the printing ink, an X-ray transmittance higher than that of the base material, the printing ink and the metal layer is used. It is good also as a structure by which the concealment image line is printed.
Further, in order to conceal the presence of the first information between the metal layer and the first information by the penetration or the fine perforation, the X-ray transmittance is higher than that of the base material and the metal layer. A concealed image line may be printed using high ink.
[0018]
The second information recorded on the metal layer may be OVD image information, the brightness of the metal foil, or information printed on the metal foil with colorless fluorescent ink.
[0019]
The material of the metal layer that covers the first information by the printing ink, the scoring, or the fine perforations may be composed of, for example, nonmagnetic metal aluminum.
[0020]
The transmitted X-rays used in the present invention may utilize soft X-rays.
[0021]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of an information recording medium according to the present invention will be described based on examples with reference to the drawings.
[0022]
(Example 1)
FIG. 1 is a diagram for explaining Example 1 of an information recording medium according to the present invention. In FIG. 1A, this information recording medium 1 has a base material 2 made of paper, and the first information 3 is recorded in a predetermined region R on one surface of the base material 2. Yes. Specifically, the first information 3 is information printed with ink having an X-ray transmittance of α% (where α is a constant), and the specific mode is printed with ink. Various types of codes, characters, marks, numbers, etc., for example, a regular triangle figure as shown in FIG.
[0023]
In order to conceal the first information 3, the predetermined region R in which the first information 3 is recorded has an X-ray transmittance of β% (where α <β; β is a constant). For example, it is covered with a metal layer 4 made of a material such as aluminum. Furthermore, the second information 5 is recorded in a predetermined region R on the other surface (back surface) corresponding to the predetermined region R on the one surface (front surface) of the substrate 2. Specifically, the second information 5 is information printed with ink having an X-ray transmittance of γ% (where γ <β; γ is a constant), for example, as shown in FIG. As shown, the figure is an inverted equilateral triangle.
[0024]
Here, X-rays such as soft X-rays are transmitted through the information recording medium 1. Then, the first information 3 and the second information 5 indicate that the X-ray transmittances α% and γ% of the inks are the metal layer 4 (β%) and the substrate 2 (where the X-ray transmittance is The first information and the second information <the base material <the metal layer are configured to be lower than the first information and the second information by the printing ink.) The third information 6 obtained by combining the information 3 and the second information 5 can be recognized as an X-ray transmission image. Here, as shown in FIG. 1D, a star-shaped figure in which regular triangles and inverted triangles are combined appears as an X-ray transmission image.
In the first embodiment, in the same region to which the metal layer is applied, in addition to the metal layer, the third information 6 in which the first information 3 and the second information 5 by the printing ink applied under the metal layer are combined. Can be compared and verified with authentic information to determine authenticity.
[0025]
The first information 3 is printed with ink having an X-ray transmittance of α%, and the second information 5 is printed with ink having an X-ray transmittance of γ%. The configuration of the third information 6 which is the combined information of the information 3 and the second information 5 has various aspects such as codes, characters, marks, numbers, etc. in addition to the graphic.
[0026]
A configuration in which the first information 3, the second information 5, and the third information 6 are machine-readable code information will be described. FIG. 2A shows a configuration in which the first information 3 is recorded in the region R using the barcode 7. FIG. 2B shows a configuration in which the second information 5 is recorded in the region R using a barcode 7 ′. The barcode 7 and barcode 7 ′ are printed with inks having X-ray transmittances of α% and γ%, respectively. Therefore, when X-rays are transmitted through the information recording medium, as shown in FIG. 2C, a bar code 8 that is the third information 6 appears as combined information of the first information 3 and the second information 5, The third information can be visually or optically read, and compared with a genuine code and verified, thereby making it possible to determine authenticity.
[0027]
FIG. 3A shows a configuration in which the first information 3 is recorded in a matrix using the two-dimensional code 9. FIG. 3B shows a configuration in which the second information 5 is recorded in a matrix using the two-dimensional code 10. The elements 11 and 12 of the two-dimensional code of the first information and the second information are printed with ink having X-ray transmittances of α% and γ%, respectively.
[0028]
Therefore, when X-rays are transmitted through the information recording medium 1, the two-dimensional code is synthesized as the third information 6 in which the first information 3 and the second information 5 are synthesized as shown in FIG. Information, that is, a composite two-dimensional code 13 of the two-dimensional code 9 and the two-dimensional code 10 appears, and the composite two-dimensional code 13 is visually or optically read, and compared with a genuine code to verify the authenticity. It becomes possible. According to such a synthesized two-dimensional code, a larger amount of information can be given, and the effect of authenticity determination and forgery prevention is enhanced.
[0029]
FIG. 4 shows that the bar of the bar code 14 that gives the first information 3 and the bar of the bar code 15 that gives the second information 5 have an X-ray transmittance of α% and γ%, respectively, and a magnetic flux density. A configuration is shown in which each bar is printed with a predetermined ink. 4A shows the barcode 14 of the first information 3 and the magnetic flux density for each bar, and FIG. 4B shows the barcode 15 of the second information 5 and the magnetic flux density for each bar. .
[0030]
In authenticity determination, the information recording medium 1 to which such information is given is read by an X-ray transmission image, and the magnetic flux density for each bar is read by a magnetic sensor. As a result, as shown in FIG. 4C, a bar code 16 of all digits which is the third information 6 obtained by combining the first information 3 and the second information 5 is obtained, and for each bar. Data of magnetic flux density obtained by adding the magnetic flux density is obtained. Such synthetic bar code 16 and synthetic magnetic flux density data are compared and verified with authentic data for authenticity determination.
[0031]
With such an information recording medium configuration, information on a predetermined magnetic flux density for each bar can be given in addition to the presence / absence of each bar constituting the bar code. Since the image and the magnetic sensor can check the information of the combined barcode and the combined magnetic flux density for each bar, it is possible to reliably determine authenticity, and the effect of preventing forgery is extremely large.
[0032]
Next, the ink in the first information 3 will be described. As a specific example, the first information 3 is a colored ink having a color tone different from the color tone of the substrate 2 and is printed using a colored ink containing an element having an X-ray transmittance lower than that of the metal layer and the substrate. It is the composition which is. Moreover, the 1st information 3 is good also as a structure printed using the transparent ink containing the element whose X-ray transmittance is lower than a metal layer and a base material.
[0033]
Next, the ink in the second information 5 will be described. As a specific example, the second information 5 is a colored ink having a color tone different from the color tone of the base material 2 and is printed using a colored ink containing an element having an X-ray transmittance lower than that of the metal layer and the base material. It is the structure which is done. Moreover, the 2nd information 5 is good also as a structure printed using the transparent ink containing the element whose X-ray transmittance is lower than a metal layer and a base material.
[0034]
As described above, when the first information 3 or the second information 5 is printed using a colored or transparent ink containing an element having an X-ray transmittance lower than that of the metal layer and the base material, for example, aluminum is used. The first information 3 covered with the metal layer as the material and the second information 5 printed on the back side thereof are more X-ray transmittance than the base material 2 and the metal layer 4 under transmitted X-rays. Therefore, the third information 6 that is the combined information of the first information 3 and the second information 5 can be recognized as an X-ray transmission image, and authenticity determination is possible. Here, when the first information 3 is printed using a transparent ink, the first information 3 cannot be recognized even if the metal layer 4 is peeled off. When printed with transparent ink, the design becomes unrecognizable. In this case, for the first time under transmitted X-rays, the first information 3 using the transparent ink, the second information 5 and the third information 6 that is the combined information thereof can be recognized, so that the anti-counterfeit effect is achieved. Get higher.
[0035]
(Example 2)
FIG. 5 is a diagram showing Example 2 of the information recording medium according to the present invention. In this embodiment, the base material 2, the first information 3, the second information 5, and the third information that is the first and second composite information recorded on one surface and the other surface of the base material 2. 6 is exactly the same as in the first embodiment. In the information recording medium 17 of the second embodiment, the fourth information 18 is recorded on the metal layer 4. However, the third information = the fourth information, or the third information ≠ the fourth information.
[0036]
By the way, the fourth information 18 is recorded in a state in which it cannot be read under transmission X-rays. The fourth information 18 can be recognized under a predetermined viewing condition that is not based on transmitted X-rays. For example, the predetermined visual recognition condition of the fourth information 18 may be a configuration using colorless fluorescent ink that emits light when irradiated with ultraviolet rays, or a configuration or brightness of an OVD that can recognize image information in observation under visible light. It is good also as a structure of the metal foil which can recognize the color.
Thus, by utilizing the information of the metal layer, not only can a plurality of techniques be applied to the same region, but also the information can be correlated.
[0037]
Since the information recording medium 17 of Example 2 is configured as described above, the third information 6 cannot be recognized under a predetermined viewing condition that is not based on transmitted X-rays. The formed fourth information 18 can be recognized, and the third information 6 can be recognized and the fourth information 18 cannot be recognized under transmitted X-rays. The fourth information 18 has a specific correlation with the third information 6 in advance (for example, it is the same or not the same, but has an alphabetical relationship, correlates with a bright color, etc.). The information may be recorded as such information, and at the time of authenticity determination, the presence / absence of a specific correlation may be confirmed to determine the authenticity.
[0038]
Example 3
FIG. 6 is a diagram for explaining Example 3 of the information recording medium according to the present invention. 6A, the information recording medium 19 of Example 3 has a base material 20 made of paper having an X-ray transmittance of α% (where α is a constant), and this base material. First information 21, for example, a triangular mark is recorded in a predetermined area R that is a part of 20 using a gap as shown in FIG.
[0039]
In order to conceal the presence of the first information 21, the X-ray transmittance is β% (provided that the first information 21 on one surface of the base material 20 is recorded). α <β; β is a constant), and is covered with a metal layer 4 made of a material such as aluminum. Further, the X-ray transmittance is γ% (where γ <α, γ <β; γ) in the predetermined region R on the other surface (back surface) of the base material 20 corresponding to the predetermined region R on the one surface. Is a constant)), the second information 22 printed with ink, for example, an inverted triangle mark is recorded as shown in FIG.
[0040]
The first information 21 is recorded using a penetration, and the X-ray transmittance of this penetration is different from that of the ground that is not a penetration of the base material 20, so that the X-ray transmission reaction is different. Since the metal layer 4 covering the first information 21 by the penetration has a higher X-ray transmittance than the base material 20, if soft X-rays are transmitted through the information recording medium 19 of Example 3, for example, The first information 21 recorded using the insert can be recognized as an X-ray transmission image. Further, since the X-ray transmittance of the second information 22 by the printing ink is lower than that of the base material 20 and the metal layer 4, the X-ray transmittance is the same as the first information 21 by the penetration under the transmitted X-ray. It can be recognized as a line transmission image. As a result, as shown in FIG. 6 (d), it is possible to recognize a star-shaped mark obtained by synthesizing the triangle and the inverted triangle which are the third information 23 obtained by synthesizing the first information 21 and the second information 22. Become.
In Example 3, in the same region to which the metal layer was applied, in addition to the metal layer, the first information 21 by the squeezing performed under the metal layer and the second information 22 by the printing ink were synthesized. By reading the information 23 of No. 3, it is possible to perform authenticity determination by comparing and collating with the authentic information. In Example 3, since the first information and the second information are given by different methods, the effect of preventing forgery is further high.
[0041]
The first information 21 is recorded on the base material 20 using the penetration, and the second information 22 is recorded on the back surface of the base material by printing with ink having an X-ray transmittance of γ%. The configuration of the third information 23 that is the configuration and combination information may be characters, marks, numbers, or machine-readable code information.
[0042]
As shown in FIG. 7A, the first information 21 is recorded on the base material 20 with, for example, a bar code 24 using a gap, and as shown in FIG. 7B, the second information 21 is recorded. Reference numeral 22 denotes a configuration in which a barcode 24 'is printed on the back surface of the substrate 20 with ink having an X-ray transmittance of γ%.
[0043]
When, for example, soft X-rays are transmitted through the information recording body, as shown in FIG. 7C, a bar code 24 that is the first information 21 and a bar code 24 ′ that is the second information 22 are combined. The combined barcode 25 can be recognized as an X-ray transmission image as the information 23 of FIG. 3, and it is possible to determine authenticity by reading this visually or optically and collating it with a genuine barcode.
[0044]
FIG. 8 shows that machine-readable code information is recorded in a matrix form as a two-dimensional code 26 by, for example, insertion into the base material 20 as shown in FIG. 8A. As shown in FIG. 2, a configuration in which the two-dimensional code 27 is printed on the back surface of the base material 20 with ink having an X-ray transmittance of γ% is shown.
[0045]
In authenticity determination, the information recording medium 19 is transmitted through X-rays, and as shown in FIG. 8C, the first information 21 is a two-dimensional code 26 and the second information 22 is 2 The synthesized two-dimensional code 28, which is the third information 23 obtained by synthesizing the three-dimensional code 27, can be identified as an X-ray transmission image, and this can be identified visually or optically and verified with an authentic code. It becomes possible. In this way, when information is provided by two-dimensional codes to the ink and ink, and these synthetic two-dimensional codes are used for authenticity determination, a larger amount of information can be provided, and the authenticity determination effect and The anti-counterfeiting effect is further enhanced.
[0046]
Next, the ink in the second information 22 will be described. As a specific example, the second information 22 is a colored ink having a color tone different from the color tone of the base material 20 and is printed using a colored ink containing an element having an X-ray transmittance lower than that of the metal layer and the base material. It is the structure which is done. Moreover, the 2nd information 22 is good also as a structure printed using the transparent ink containing the element whose X-ray transmittance is lower than a metal layer and a base material.
[0047]
As described above, when the second information 22 is printed using a colored or transparent ink containing an element having a lower X-ray transmittance than the metal layer and the base material, the second information 22 is the base material. Since the X-ray transmittance is lower than that of the metal layer 4 and the metal layer 4, second information 22 that can be recognized by an X-ray transmission image is given in addition to the first information 21 by the penetration under the transmission X-ray. It becomes possible to do. In the third embodiment, since the third information can be recognized as composite information obtained by different information application methods, such as the first information by the insertion and the second information by the printing ink, the forgery prevention effect is high.
[0048]
(Example 4)
FIG. 9 is a diagram showing Example 4 of the information recording medium according to the present invention. The information recording medium 29 of this Example 4 is the base material 20, the first information 21 recorded on the part of the base material 20 using a scratch, and the back surface of the base material 20 with ink having a transmittance γ%. The printed second information 22 and the third information 23, which is the combined information of the first information and the second information, are exactly the same as in the third embodiment. In the information recording medium 29 of Example 4, fourth information 30 is recorded on the metal layer 4. However, the third information = the fourth information, or the third information ≠ the fourth information.
[0049]
By the way, the fourth information 30 cannot be read even if X-rays are transmitted, and the predetermined viewing condition may be, for example, a configuration using colorless fluorescent ink that emits light when irradiated with ultraviolet rays, or In observation under visible light, a configuration of OVD that can recognize image information or a configuration of metal foil that can recognize a bright color may be used.
Thus, by utilizing the information of the metal layer, not only can a plurality of techniques be applied to the same region, but also the information can be correlated.
[0050]
Since the information recording medium 29 of Example 4 is configured as described above, the third information 23 becomes unrecognizable under a predetermined viewing condition that is not based on transmitted X-rays. The formed fourth information 30 can be recognized, and the third information 23 can be recognized and the fourth information 30 cannot be recognized under transmitted X-rays.
[0051]
The fourth information 30 has a specific correlation with the third information 23 in advance (for example, it is the same or not the same, but has an alphabetical relationship, correlates with a bright color, etc.). The information may be recorded as such information, and at the time of authenticity determination, the presence or absence of a specific correlation may be confirmed to determine the authenticity.
[0052]
(Example 5)
FIG. 10 is a diagram for explaining an embodiment 5 of the information recording medium according to the present invention. 10A, the information recording medium 31 has a base material 20 made of paper having an X-ray transmittance of α% (where α is a constant). The first information 32, for example, a triangular dot mark as shown in FIG. 10B is used for fine drilling (irradiating a laser to drill the base material; the same applies hereinafter) in a predetermined region R that is a part. Is recorded.
[0053]
In order to conceal the presence of the first information 32, the X-ray transmittance is β% (provided that the first information 32 on one surface of the base material 20 is recorded in the predetermined region R). α <β; β is a constant), and the metal layer 4 of a material such as aluminum is coated. Further, the X-ray transmittance is γ% (where γ <α, γ <β; γ) in the predetermined region R on the other surface (back surface) of the base material 20 corresponding to the predetermined region R on the one surface. Is a constant.) Second information 33 printed with ink of, for example, an inverted triangle mark as shown in FIG. 10C is recorded.
[0054]
Since the first information 32 is recorded using micro-perforation, the X-ray transmittance of this micro-perforated portion is higher in X-ray transmission reaction than other portions of the base material 20 without micro-perforation. . Further, since the metal layer 4 has a higher X-ray transmittance than the base material 20, for example, when X-rays such as soft X-rays are transmitted through the information recording body 31 of Example 5, recording was performed using fine perforations. The first information 32 can be recognized as an X-ray transmission image having a different X-ray transmission response depending on the presence / absence of fine perforations. Furthermore, since the X-ray transmittance of the second information 33 is lower than that of the base material 20 and the metal layer 4, an X-ray transmission image can be recognized under the transmitted X-rays as in the first information 32. As a result, it is possible to recognize a hexagonal point mark obtained by combining the triangular point and the inverted triangular point, which is the third information 34 in which the first information 32 and the second information 33 are combined. In Example 5, in the same region where the metal layer was applied, in addition to the metal layer, the first information 32 by the fine perforations provided under the metal layer and the second information 33 by the printing ink were synthesized. By reading the third information 34, authenticity determination can be performed by comparing and collating with the authentic information. In Example 5, since the first information and the second information are given by different methods, the effect of preventing forgery is further high.
[0055]
The first information 32 is recorded on the base material 20 using fine perforations, and the second information 33 is recorded on the back surface of the base material by printing with ink having an X-ray transmittance of γ%. The configuration and the configuration of the combined third information 34 may be characters, marks, numbers, or machine-readable code information.
[0056]
In FIG. 11, the machine-readable code information is recorded as a first information 32 in the form of a matrix by fine perforation on the base material, and the second information 33 is also recorded on the back surface of the base material 20. As shown, the two-dimensional code 36 is printed with ink having an X-ray transmittance of γ%.
[0057]
When the information recording medium 31 is confirmed under transmission X-rays for authenticity determination, the two-dimensional code 35 as the first information 32 and the two-dimensional code 36 as the second information 33 are synthesized. The synthesized two-dimensional code 37 that is the third information 34 can be recognized as a transmitted X-ray image, and this can be identified visually by reading it visually or optically and collating it with a genuine code. As described above, if information is provided by a two-dimensional code by fine perforation and ink, and this synthetic two-dimensional code is used for authenticity determination, a larger amount of information can be provided, and the authenticity determination effect and counterfeiting can be achieved. The prevention effect is further enhanced.
[0058]
Next, the ink in the second information 33 will be described. As a specific example, the second information 33 is a colored ink having a color tone different from the color tone of the base material 20, and a colored ink containing an element having an X-ray transmittance lower than that of the metal layer 4 and the base material 20 is used. The configuration is printed. The second information 33 may be printed using a transparent ink containing an element having a lower X-ray transmittance than the metal layer 4 and the base material 20.
[0059]
Thus, when the second information 33 is configured to be printed using a colored or transparent ink containing an element having a lower X-ray transmittance than the metal layer 4 and the substrate 20, the second information 33 is Since the X-ray transmittance is lower than that of the base material 20 or the metal layer 4, the second information 33 that can be recognized by the X-ray transmission image in addition to the first information 32 by the fine perforation under the transmission X-ray. Can be given. In the fifth embodiment, since the third information can be recognized as the combined information obtained by different information application methods, such as the first information by fine perforation and the second information by printing ink, the forgery prevention effect is high.
[0060]
(Example 6)
FIG. 12 is a diagram showing Example 6 of the information recording medium according to the present invention. In Example 6, the base material 20, the first information 32 recorded by fine perforation on a part of the base material 20, and the second information printed on the back surface of the base material 20 with ink having a transmittance γ%. 33 and the third information 34, which is the combined information of the first information and the second information, are exactly the same as in the fifth embodiment. In the information recording medium 37 ′ of Example 6, the fourth information 38 is recorded on the metal layer 4. However, the third information = the fourth information, or the third information ≠ the fourth information.
[0061]
By the way, the fourth information 38 is recorded in a state in which it cannot be read even if X-rays are transmitted. For example, the fourth information 38 may be configured with a colorless fluorescent ink that emits light when irradiated with ultraviolet rays as a viewing condition, or an OVD configuration or a bright color that allows information to be visually observed by observation under visible light. It is good also as a structure of the metal foil which can be recognized.
Thus, by utilizing the information of the metal layer, it is possible not only to give a plurality of techniques to the same region but also to correlate information.
[0062]
Since the information recording medium 37 ′ of the sixth embodiment is configured as described above, the third information 34 cannot be recognized under a predetermined viewing condition that is not based on transmitted X-rays, and the metal layer 4 The fourth information 38 formed in the above can be recognized, and the third information 34 can be recognized and the fourth information 38 cannot be recognized under transmitted X-rays.
[0063]
The fourth information 38 has a specific correlation with the third information 34 in advance (for example, it is the same or not the same, but has an alphabetical relationship, correlates with a bright color, etc.). The information may be recorded as such information, and at the time of authenticity determination, the presence or absence of a specific correlation may be confirmed to determine the authenticity.
[0064]
As mentioned above, although Examples 1-6 of the information recording medium concerning the present invention were explained, the modification which attached the concealment picture line for improving a forgery prevention effect further to the information recording medium of Examples 1-6 is as follows. explain.
Here, a concealing example for the first information 3 will be described in order to prevent the first information 3 concealed by the metal layer from being visible through the metal layer or the base material.
[0065]
(Modification of Examples 1 and 2)
FIG. 13 is a diagram illustrating a modification of the first embodiment. In all of the modifications shown in FIGS. 13A to 13E, the first information 3 concealed by the metal layer cannot be recognized from the back surface through the base material on the information recording medium 1 of the first embodiment. In addition, a concealed image line is provided so that it cannot be recognized through the metal layer.
In addition, although it becomes a modification of Example 2 by providing the 3rd information 18 (FIG. 5) to the metal layer 4 of Fig.13 (a)-(e), the description is abbreviate | omitted.
[0066]
As the hidden image lines, there are a first hidden image line 39 and a second hidden image line 40 in which the background pattern is printed densely or solidly, and these hidden image lines 39 and 40 are the first information. 3. The X-ray transmittance is higher than that of the second information 5, the base material 2, and the metal layer 4. Therefore, the identification of the first information 3, the second information 5, and the third information 6 that is a combination of the first information and the second information under transmitted X-rays is not hindered. At this time, the first concealment image line 39 and the second concealment image line 40 have a condition that the X-ray transmittance is higher than that of the first information 3, the second information 5, the base material 2, and the metal layer 4. The configuration is such that printing is performed using ink having the same X-ray transmittance, and the concealed image line described in the claims of the present invention is configured similarly.
[0067]
FIGS. 13A and 13B respectively show the first information 3 through the base material 2 from the opposite surface (back surface) of the metal layer 4 of the base material 2 in the information recording medium of Example 1. The first concealed image line 39 is printed on the predetermined region R of the base material 2 so that the image cannot be formed.
[0068]
FIG. 13A shows a configuration in which the first concealed image line 39 is printed on the region R on the surface of the substrate 2 and then the first information 3 is printed. FIG. In this configuration, the first hidden image line 39 is printed on the region R on the back surface of the substrate 2.
[0069]
FIGS. 13 (c), (d) and (e) show the top of the first information 3 so that the first information 3 cannot be seen through the metal layer or when the metal layer is peeled off. The second concealed image line 40 is printed. Here, there is a complicated one combined with FIGS. 13 (a) and 13 (b).
[0070]
FIG. 13C shows a configuration in which the second hidden image line 40 is printed on the region R from the top of the first information 3. In FIG. 13D, the first concealed image line 39 is printed on the region R on the back surface of the substrate 2 and the second concealed image line 40 is printed on the region R from the first information 3. The first information 3 can be concealed more effectively from the upper and lower surfaces. In FIG. 13E, the first concealed image line 39 is printed on the region R on the surface of the substrate 2 and the second concealed image line 40 is printed on the region R from the first information 3. The first information 2 can be more effectively concealed from the upper and lower surfaces.
[0071]
(Modification of Examples 3 to 6)
FIG. 14 is a diagram illustrating a modification of the third to sixth embodiments. 14 (a) to 14 (c), the first information, that is, the clearance (Examples 3 and 4) and the fine perforation (implementation) are all recorded on the information recording media of Examples 3 to 6. A configuration in which a concealment image line for concealing the first information is provided so that Examples 5 and 6) cannot be visually observed through the base material 20 or the metal layer 4. As the hidden image line, the first hidden image line 39 and the second hidden image line 40 which are exactly the same as the hidden image line used in FIG. 13 are used. In FIGS. 14A to 14C, description of the fourth information 30 of the fourth embodiment and the fourth information 38 of the sixth embodiment is omitted.
[0072]
FIG. 14A shows a configuration in which the first concealment image line 39 is printed on the region R on the back surface of the base material 20, and FIG. 14B shows the configuration on the region R on the surface of the base material 20. In this configuration, the second hidden image line 40 is printed. FIG. 14C shows a case where the first concealed image line 39 is printed on the region R on the back surface of the base material 20, and the first information 21 and 32 (in the case of Examples 3 and 4) on the surface of the base material 20. 21 and in the case of Examples 5 and 6, the second concealment image line 40 is printed on the region R from above, and the first information 21 and 32 can be concealed more effectively from the upper and lower sides. A possible configuration is shown.
[0073]
FIG. 15 shows an example of a concealed image line. First information (information by printing ink in Examples 1 and 2, information by squeezing in Examples 3 and 4, information by micro-perforation in Examples 5 and 6) ) Is hidden by a finely printed copy-forgery-inhibited pattern line 41. Further, the concealed image line may be obtained by solid printing.
[0074]
Although the embodiments of the present invention have been described based on the embodiments with reference to the drawings, the present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the technical matters described in the claims. Needless to say, there is an embodiment.
For example, plastic or synthetic resin may be used as the substrate. In this case, information can be given by changing the thickness of the base material to provide a difference in the X-ray transmittance. Further, as in the case of paper, information may be given by printing with printing ink or fine drilling by laser drilling.
[0075]
【The invention's effect】
As described above, the information recording medium according to the present invention can provide a plurality of information in the same area, and is limited in particular because information obtained by combining the front and back surfaces can be obtained under transmitted X-rays. For precious printed matter such as banknotes having a small area, the effect of preventing forgery can be further enhanced. When the first information is inserted and fine perforations are used, the anti-counterfeiting effect is enhanced because the application method is different from the second information using printing ink. Furthermore, by correlating both information of the metal layer and information recognizable under transmission X-rays, not only a plurality of techniques are given in the same area, but also a more complicated one.
Because the first information under the metal layer is confirmed under transmitted X-rays, the transmitted X-ray equipment is only in special places such as airports and research institutes. It is.
As a result, an information recording medium that is extremely difficult to counterfeit is realized.
[Brief description of the drawings]
FIG. 1 is a diagram for explaining Example 1 of an information recording medium according to the present invention.
FIG. 2 is a diagram for explaining a main part of Embodiment 1 of the information recording medium according to the present invention.
FIG. 3 is a diagram for explaining a main part of Embodiment 1 of the information recording medium according to the present invention.
FIG. 4 is a diagram for explaining a main part of Embodiment 1 of the information recording medium according to the present invention.
FIG. 5 is a diagram for explaining Example 2 of the information recording medium according to the present invention.
FIG. 6 is a diagram for explaining Example 3 of the information recording medium according to the present invention.
FIG. 7 is a diagram for explaining a main part of Embodiment 3 of an information recording medium according to the present invention.
FIG. 8 is a diagram for explaining a main part of Embodiment 3 of the information recording medium according to the present invention.
FIG. 9 is a diagram for explaining Example 4 of the information recording medium according to the present invention.
FIG. 10 is a diagram for explaining Example 5 of the information recording medium according to the present invention.
FIG. 11 is a diagram for explaining a main part of Embodiment 5 of the information recording medium according to the present invention.
FIG. 12 is a diagram for explaining Example 6 of the information recording medium according to the present invention.
FIG. 13 is a diagram for explaining a modification of the first and second embodiments of the information recording medium according to the present invention.
FIG. 14 is a diagram for explaining a modification of Embodiments 3 to 6 of the information recording medium according to the present invention.
FIG. 15 is a diagram illustrating a hidden image line according to a modification.
[Explanation of symbols]
1, 17, 19, 29, 31, 37 'information recording medium
2, 20 Base material
3, 21, 32 First information
4 Metal layers
5, 22, 33 Second information
6, 23, 34 Third information (synthesis information)
7, 7 ', 8, 14, 15, 16, 24, 24', 25 Barcode
9, 10, 13, 26, 27, 28, 35, 36, 37 Two-dimensional code
11, 12 Predetermined code (two-dimensional code)
18, 30, 38 Fourth information
39 First Hidden Painting Line
40 Second concealed drawing line
41 Line pattern line

Claims (19)

A substrate;
First information printed with an ink having an X-ray transmittance of α% (where α is a constant) in a predetermined region on one surface of the substrate;
In order to conceal the presence of the first information, the non-magnetic material has an X-ray transmittance of β% (where α <β; β is a constant) covering the predetermined region from the one surface. A metal layer,
Second information printed with ink having an X-ray transmittance of γ% (where γ <β; γ is a constant) in a region corresponding to the predetermined region on the other surface of the substrate. When,
Third information obtained by combining the first information and the second information under transmitted X-rays,
The X-ray transmittance of the base material is higher than α% which is the X-ray transmittance of the first information and γ% which is the X-ray transmittance of the second information, and the X-ray transmittance of the metal layer. Is higher than the X-ray transmittance of the base material. A substrate;
First information printed with an ink having an X-ray transmittance of α% (where α is a constant) in a predetermined region on one surface of the substrate;
In order to conceal the presence of the first information, the non-magnetic material has an X-ray transmittance of β% (where α <β; β is a constant) covering the predetermined region from the one surface. A metal layer,
Second information printed with ink having an X-ray transmittance of γ% (where γ <β; γ is a constant) in a region corresponding to the predetermined region on the other surface of the substrate. When,
Third information obtained by combining the first information and the second information under transmitted X-rays;
Fourth information recorded on the metal layer,
The X-ray transmittance of the base material is higher than α% which is the X-ray transmittance of the first information and γ% which is the X-ray transmittance of the second information, and the X-ray transmittance of the metal layer. Is higher than the X-ray transmittance of the base material. The information recording medium according to claim 1, wherein the first information, the second information, and the third information are machine-readable code information. 4. The information recording medium according to claim 3, wherein the machine-readable code information is recorded using a bar code. The information recording medium according to claim 4, wherein the ink having an X-ray transmittance of α% and the ink having an X-ray transmittance of γ% are magnetic inks. 6. The information according to claim 5, wherein the magnetic data of the third information is magnetic data obtained by combining the magnetic data of the first information and the magnetic data of the second information. recoding media. The information recording medium according to claim 3, wherein the machine-readable code information is recorded using a two-dimensional code. A base material having an X-ray transmittance of α% (where α is a constant);
First information given to the predetermined region of the base material using a gap so that the X-ray transmittance is different from that of the base material;
In order to conceal the presence of the first information, the X-ray transmittance covering the predetermined region from one surface of the substrate is β% (where α <β; β is a constant). A non-magnetic metal layer;
Second information printed with ink having an X-ray transmittance of γ% (where γ <β; γ is a constant) in a region corresponding to the predetermined region on the other surface of the substrate. When,
Third information obtained by combining the first information and the second information under transmitted X-rays,
An information recording medium, wherein the X-ray transmittance of the substrate is higher than γ% which is the X-ray transmittance of the second information. A base material having an X-ray transmittance of α% (where α is a constant);
First information given to the predetermined region of the base material using a gap so that the X-ray transmittance is different from that of the base material;
In order to conceal the presence of the first information, the X-ray transmittance covering the predetermined region from one surface of the substrate is β% (where α <β; β is a constant). A non-magnetic metal layer;
Second information printed with ink having an X-ray transmittance of γ% (where γ <β; γ is a constant) in a region corresponding to the predetermined region on the other surface of the substrate. When,
Third information obtained by combining the first information and the second information under transmitted X-rays;
Fourth information recorded on the metal layer,
An information recording medium, wherein the X-ray transmittance of the substrate is higher than γ% which is the X-ray transmittance of the second information. A base material having an X-ray transmittance of α% (where α is a constant) and a predetermined region of the base material provided with a fine perforation so that the X-ray transmittance is different from that of the base material. 1 information and
In order to conceal the presence of the first information, the X-ray transmittance covering the predetermined region from one surface of the substrate is β% (where α <β; β is a constant). A non-magnetic metal layer;
Second information printed with ink having an X-ray transmittance of γ% (where γ <β; γ is a constant) in a region corresponding to the predetermined region on the other surface of the substrate. When,
Third information obtained by combining the first information and the second information under transmitted X-rays,
An information recording medium, wherein the X-ray transmittance of the substrate is higher than γ% which is the X-ray transmittance of the second information. A base material having an X-ray transmittance of α% (where α is a constant) and a predetermined region of the base material provided with a fine perforation so that the X-ray transmittance is different from that of the base material. 1 information and
In order to conceal the presence of the first information, the X-ray transmittance covering the predetermined region from one surface of the substrate is β% (where α <β; β is a constant). A non-magnetic metal layer;
Second information printed with ink having an X-ray transmittance of γ% (where γ <β; γ is a constant) in a region corresponding to the predetermined region on the other surface of the substrate. When,
Third information obtained by combining the first information and the second information under transmitted X-rays;
Fourth information recorded on the metal layer,
An information recording medium, wherein the X-ray transmittance of the substrate is higher than γ% which is the X-ray transmittance of the second information. 12. The information recording medium according to claim 8, 9, 10, or 11, wherein the first information, the second information, and the third information are machine-readable code information. 13. The information recording medium according to claim 12, wherein the machine-readable code information is recorded using a bar code. 13. The information recording medium according to claim 12, wherein the machine-readable code information is recorded using a two-dimensional code. In order to conceal the presence of the first information between the base material and the first information, the X-ray transmittance is higher than the X-ray transmittance of the base material by δ% (where α <δ , Β <δ, γ <δ; δ is a constant), and a concealing image line is printed using the ink of claim 1, 2, 3, 4, 5, 6 or 7 The information recording medium according to any one of the above. In order to conceal the presence of the first information on the surface opposite to the surface on which the metal layer is provided on both surfaces of the substrate, the X-ray transmittance is higher than the X-ray transmittance of the substrate. 2. A concealment image line is printed using% ink (where α <δ, β <δ, γ <δ; δ is a constant). The information recording medium according to any one of 5, 6, or 7. In order to conceal the presence of the first information on the surface opposite to the surface on which the metal layer is provided on both surfaces of the substrate, the X-ray transmittance is δ% (where α <δ, β <δ , Γ <δ; δ is a constant.) A concealed image line is printed using an ink of claim 8, 15, 10, 11, 12, 13, or 14. Information recording media. In order to conceal the presence of the first information between the metal layer and the first information, the X-ray transmittance is higher than the X-ray transmittance of the substrate by δ% (where α <δ , Β <δ, γ <δ; δ is a constant), and a concealing image line is printed using the ink of claim 1, 2, 3, 4, 5, 6, 7, The information recording medium according to any one of 15 and 16. In order to conceal the presence of the first information between the metal layer and the first information, the X-ray transmittance is δ% (where α <δ, β <δ, γ <δ; δ is The information recording medium according to any one of claims 8, 9, 10, 11, 12, 13, 14 and 17, wherein a concealed image line is printed using an ink of a constant.

Images