JP4344799B2 - Authenticity discriminator - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a true / false discrimination forming body applied to valuable printed matter that needs to be prevented from forgery and tampering such as banknotes, passports, securities, cards, and stamps.
[0002]
[Prior art]
Due to the nature of precious printed matter such as banknotes, passports, securities, cards, and stamps, they are required to be difficult to forge or alter. As a preventive measure, it is known to form numbers or the like on a substrate of these valuable printed materials by a plurality of perforations. There is also known a technique for performing authenticity determination by allowing a latent image to be visually recognized by tilting and observing a substrate having a plurality of perforations.
[0003]
The former is used for Swiss banknotes, and the numbers are expressed by perforations. In addition, the hole diameter is characterized in that the pattern formed by the naked eye cannot be seen in the reflective state, and the safety mark is composed of a plurality of holes that form a pattern on the document surface that is visible in the transparent state. A safekeeping document provided with a safety mark for preventing this is disclosed (for example, see Patent Document 1).
[0004]
[Patent Document 1]
JP 2000-501036 A (2nd page, Fig. 1-2)
[0005]
The latter is a true / false discriminating body having a base material and having a large number of fine perforations that are formed on the base material and form a background portion and an information portion consisting of a specific pattern that are difficult to see. A true / false discrimination formed body characterized in that the perforations forming the background portion and the perforations forming the information portion are formed so that at least one of the shape, size and arrangement direction of the perforations is different. (For example, refer to Patent Document 2).
[0006]
[Patent Document 2]
JP 2000-233561 (2nd page, Fig. 1-2)
[0007]
Also, a micro-perforated card having a card base with a large number of micro-perforations formed in a specific pattern to give information, the micro-perforations being applied to the card base by a laser processing machine A perforation formed by penetrating at a specific inclination angle, and projecting light from one side of the fine perforation card to the fine perforation card at the same angle as the specific inclination angle, thereby forming the fine perforation. A micro-perforated card is disclosed in which the above information is checked by transmitting the card (for example, see Patent Document 3).
[0008]
[Patent Document 3]
JP 2002-160477 (second page, FIG. 1)
[0009]
In addition, it is conceivable that an image is viewed three-dimensionally by binocular parallax by forming an image with perforations penetrating at different angles.
[0010]
[Problems to be solved by the invention]
In general, the above prior art generally forms numbers or the like on the base material by perforation, makes the base material different in the shape of some perforations, or opens a part of the perforations obliquely with respect to the base material. The latent image was visually recognized when observed by tilting with light. The Japanese translation of PCT publication No. 2000-501036 only forms numbers and the like by perforation, and it is simple and has room for improvement as a forgery prevention technique. Japanese Patent Laid-Open No. 2000-233561 has a configuration in which the information part is concealed in the perforation group by combining the information part and the background part. If the depth is not deepened, the latent image may not appear clearly, and it is difficult to form a plurality of latent images. Japanese Patent Laid-Open No. 2002-160477 discloses a base image in which a perforation group including a plurality of perforations is provided on a base material, and a partial image of the perforation group is opened obliquely with respect to the base material to form a latent image. It is easy to construct a mass production line that can irradiate a laser beam vertically and automatically convey the substrate in the horizontal direction. Forming oblique perforations in the base material has a complicated processing machine configuration and is difficult to manufacture. In addition, it is conceivable that the image is viewed three-dimensionally by binocular parallax by forming an image with perforations penetrating at different angles. Could not get.
[0011]
From the above, the present invention aims to solve the above-mentioned problems, and is an image comprising a group of perforations formed by perforations that do not penetrate the base material and a group of perforations formed by perforations that penetrate the base material. When observing with transmitted light, the individual perforation positions of the perforation group penetrating through the substrate forming the image are arranged corresponding to the individual perforation positions of the perforation group not penetrating the substrate, It has been found that the appearance of a clear second image, the appearance or disappearance of a second image that differs from multiple directions, and the appearance of a clear three-dimensional second image appear depending on the viewing angle. Therefore, the present invention proposes a true / false discrimination forming body having a high authenticity discrimination effect and an effect of preventing falsification and duplication.
[0012]
In addition, an image of the second base material including a first base material having a perforation group formed by perforation penetrating through and a second base material having an image of the perforation group formed by perforation penetrating through the second base material. The individual drilling positions of the perforated group to be formed are observed when transmitted light is observed by sequentially laminating them so as to be arranged corresponding to the individual perforated positions of the perforated group of the first substrate. It has been found that the appearance of a clear second image, the appearance or disappearance of a second image that differs from multiple directions, and the appearance of a clear three-dimensional second image appear depending on the angle. Therefore, the present invention proposes a true / false discrimination forming body having a high authenticity discrimination effect and an effect of preventing falsification and duplication.
[0013]
[Means for Solving the Problems]
The present invention provides at least two images of a perforation group formed by perforation not penetrating the base material and a perforation group formed by perforation penetrating the base material, and penetrates the base material forming the at least two images An individual perforation position of the perforation group to be formed is a true / false discrimination forming body arranged corresponding to each perforation position of the perforation group not penetrating the base material, and forms the at least two images. The individual perforation diameter of the perforation group that passes through the substrate is smaller than the individual perforation diameter of the perforation group that does not penetrate the substrate, and the individual perforation group that penetrates the base material that forms the at least two images. The perforations are arranged so as to overlap individual perforations of a group of perforations that do not penetrate the substrate (in this case, overlapping means that part or all of them overlap), and the base that forms the at least two images Pierce the material The individual perforation positions of the perforation group to be arranged are arranged at a specific direction and a specific distance from the reference with reference to the center position of the individual perforations of the perforation group not penetrating the substrate, and the specific direction is the respective image. A true / false discriminating body characterized in that the direction is different for each. When this authenticity determination formed body is observed with tilted transmitted light, a plurality of images corresponding to a plurality of observation angles are visually recognized.
[0014]
Further, the present invention provides at least one image consisting of a perforation group formed by perforations that do not penetrate the base material, a perforation group for the right eye and a perforation group for the left eye formed by perforations that penetrate the base material, The individual perforation positions of the right eye perforation group and the left eye perforation group penetrating the base material forming the at least one image are the individual perforation positions of the perforation group not penetrating the base material. Correspondingly arranged authenticity forming bodies, the diameters of the right eye perforation group and the left eye perforation group penetrating the base material forming the at least one image are as follows: A perforation group for the right eye and a perforation group for the left eye that are smaller than the individual perforation diameter of the perforation group that does not penetrate the base material and that penetrate the base material that forms the at least one image. Each perforation is a group of perforations that do not penetrate the substrate. (The overlapping in this case means that part or all of them overlap), and the right eye perforation group and the left eye perforation group form a pair, and the true When the false discrimination formation is observed with transmitted light from a specific distance, the at least one image is viewed three-dimensionally.
[0015]
Further, the present invention is the second substrate comprising a first base material having a perforation group formed by penetrating through holes and a second base material having at least two images consisting of the perforation group formed by penetrating through holes. The individual perforation positions of the perforation group forming the at least two images on the base material of the substrate are sequentially stacked so as to correspond to the individual perforation positions of the perforation group of the first base material. An individual perforation diameter of the perforation group that forms the at least two images on the second base material is a true / false discrimination formed by the individual perforation group on the first base material. And each of the perforations in the perforation group forming the at least two images on the second substrate overlaps the individual perforations in the perforation group on the first substrate. (In this case, overlapping means part or all Are arranged in such a way that the individual perforation positions of the perforation group forming the at least two images on the second substrate are the individual perforations of the perforation group on the first substrate. A true / false discriminating body characterized in that it is arranged at a specific direction and a specific distance from the center position of the perforation as a reference, and the specific direction is a different direction for each second image. . When this authenticity determination formed body is observed with tilted transmitted light, a plurality of images corresponding to a plurality of observation angles are visually recognized.
[0016]
The present invention also includes a first base material having a perforation group formed by non-penetrating perforations, and at least one image composed of a right eye perforation group and a left eye perforation group formed by through perforations. Each of the perforation positions of the right eye perforation group and the left eye perforation group that form at least one image of the second base material, which is formed of the second base material, is the first base. A true / false discrimination forming body that is sequentially laminated so as to correspond to each perforation position of the perforation group in the material, and forms the at least one image on the second base material. The individual perforation diameters of the right eye perforation group and the left eye perforation group are smaller than the individual perforation diameters of the perforation group in the first base material, and the second base The right eye perforation for forming the at least one image on the material And the individual perforations of the left eye perforation group overlap the individual perforations of the perforation group that do not penetrate the first substrate (overlap in this case means that part or all of them overlap) Furthermore, the right eye perforation group and the left eye perforation group form a pair, and when the authenticity determination formed body is observed with transmitted light from a specific distance, the at least one image is three-dimensional. It is a true / false discrimination formation characterized by being visually recognized.
[0017]
Further, the present invention is the authenticity determination formed body, wherein the non-penetrating perforations and the penetrating perforations are formed in at least one of a right angle with respect to the substrate and an oblique shape at a specific angle. .
[0018]
Further, the present invention is the authenticity determination formed body in which the perforations that do not penetrate and the perforation pitches of the perforations that penetrate are arranged at equal pitches.
[0019]
Further, the present invention is the true / false discrimination formed body characterized in that the diameter of the perforation not penetrating and the penetrating perforation is 50 μm to 1000 μm.
[0020]
In addition, the present invention is the authenticity determination formed body, wherein the perforation not penetrating and the shape of the penetrating perforation are at least one of a circular shape, a polygonal shape, and a special shape.
[0021]
In addition, in the present invention, the degree of overlap between the non-penetrating perforations and the penetrating perforations according to the present invention is a true / false discrimination formation characterized in that the through-piercing perforations are contained or arranged with respect to the non-penetrating perforations.
[0022]
Further, in the authenticity determination formed body according to the present invention, the perforation that does not penetrate and the perforation that penetrates have a shape in which the diameter of the perforation decreases in the depth direction.
[0023]
The image according to the present invention is at least one of a character, a number, a symbol, and a pattern.
[0024]
In addition, the present invention is a true / false discrimination formed body provided with perforations for camouflaging an image composed of a perforation group formed by perforations penetrating the substrate.
[0025]
In addition, the present invention is a true / false discrimination formed body provided with perforations for camouflaging an image composed of a group of perforations formed by perforations penetrating the second base material.
[0026]
An explanatory diagram of the specific direction and the specific distance described above is shown in FIG. Here, the specific direction is a direction in which the perforation (3c) is formed with respect to the center position (P) of the perforation (3a). The specific distance is a distance at which the perforation (3c) is formed with respect to the center position (P) of the perforation (3a).
[0027]
DETAILED DESCRIPTION OF THE INVENTION
An embodiment of the authenticity determination forming body according to the present invention will be described with reference to the drawings. The true / false discrimination formed body of the present invention is characterized in that a first image comprising a perforation group formed by perforation not penetrating a two-dimensionally arranged base material formed on the base material and a two-dimensional shape formed on the base material. A second image comprising a group of perforations formed by perforations penetrating through the arrayed substrate is provided, and the individual perforation positions of the group of perforations penetrating the substrate forming the second image form a first image. The appearance or disappearance of a clear second image when tilted in a certain direction from the vertical direction and observed with transmitted light by disposing it corresponding to the individual perforation positions of the perforation group not penetrating the substrate to be A stereoscopic second image appears. In addition, a first image composed of a group of perforations formed by perforation penetrating the first base material formed on the first base material and a two-dimensional array formed on the second base material Providing a second image comprising a perforation group formed by perforations penetrating through the second substrate, and the individual perforation positions of the perforation group penetrating the second substrate forming the second image are: By sequentially laminating the first substrate and the second substrate so as to correspond to the individual drilling positions of the drilling group that penetrates the first substrate forming one image, When observed with transmitted light after tilting from a certain direction, a clear second image appears or disappears, and a stereoscopic second image appears.
[0028]
FIG. 1 shows a view in which a first image (2a) is formed on a substrate (1a) by perforation (3a) and a cross-sectional view taken along line AA ′. As shown in FIG. 1, the perforations (3a) need to be formed at a certain depth or a depth determined in plural without penetrating the substrate. FIG. 2 shows a view in which only the second image (2c) is formed on the substrate (1a) by perforation (3c) and a cross-sectional view taken along line AA ′. As shown in FIG. 2, the perforation (3c) needs to penetrate the substrate. The authenticity determination formed body (4a) on which the first image (2a) formed by the perforation (3a) shown in FIGS. 1 and 2 and the second image (2c) formed by the perforation (3c) are applied, and The AA ′ sectional views are shown in FIGS. 3 and 4. As shown in FIG. 3 and FIG. 4, the perforations (3c) that penetrate the base material (1a) need to be regularly arranged so as to overlap the perforations (3a) that do not penetrate the base material (1a). . In this case, the perforation (3c) that penetrates the base material (1a) is inherent to the perforation (3a) that does not penetrate the base material (1a), and is on the left side with respect to the center position of the perforation (3a). Although it is regularly arranged, the effect of the present invention can be obtained even if it is arranged on the right, upper, lower or the like. That is, the position of the perforation (3c) that penetrates the base material (1a) is arranged at a specific direction and a specific distance from the center position of the perforation (3a) that does not penetrate the base material (1a), and penetrates the base material (1a). The perforation (3c) which penetrates the base material (1a) may be provided in the perforation (3a) which is not performed.
[0029]
FIG. 5 shows a view when the authenticity determination formed body (4a) is observed with transmitted light from a direction perpendicular to the substrate. As shown in FIG. 5, when the authenticity determination formed body (4a) is observed with transmitted light from a direction perpendicular to the base material, the observer forms the perforation (3a) that does not penetrate the base material (1a). Since the first image (2a) is the same color as the base material, it is difficult to visually recognize the first image (2a). Further, since the amount of light transmitted through the perforation (3c) that penetrates the base material (1a) is strongly recognized, the second image (2c) by the perforation (3c) that penetrates the base material (1a) is visually recognized. Will do. When the true / false discrimination formed body (4a) is observed with reflected light, the first image (2a) formed by the perforations (3a) not penetrating the base material (1a) is the same color as the base material, The second image (2c) cannot be viewed because it is difficult to recognize the transmitted light transmitted through the perforations (3c) penetrating the substrate (1a).
[0030]
FIGS. 6A and 6B are diagrams when the authenticity determination formed body (4a) is observed with transmitted light from the X1 direction or the X2 direction shown in FIG. FIG. 6A is a view when observed from the X1 direction. In this case, from the X1 direction, since the light transmitted through the perforation (3c) that penetrates the base material (1a) and the perforation (3a) that does not penetrate the base material can be recognized, the perforation that penetrates the base material (1a). The second image (2c) according to (3c) can be seen (in this case the number 1). FIG. 6B is a diagram when observed from the X2 direction. In this case, from the X2 direction, light transmitted through the perforations (3c) penetrating the base material (1a) and the perforations (3a) not penetrating the base material (1a) can hardly be recognized. The second image (2c) due to the perforation (3c) penetrating through can not be visually recognized.
[0031]
Regarding the observable direction of the second image, as shown in FIG. 7, the arrangement position of the perforations (3c) penetrating through the base material (1a) arranged in the perforations (3a) not penetrating the base material (1a). Depends on. That is, as shown in the AA ′ cross-sectional view of FIG. 7, the perforations (3c) that penetrate the base material (1a) are regularly formed on the Y1 side with respect to the perforations (3a) that do not penetrate the base material (1a). Can be observed from the X0 direction with transmitted light or the X1 direction with transmitted light, and when arranged regularly on the Y2 side, it can be observed with the transmitted light in the X0 direction or transmitted light. It can be observed from the X2 direction.
[0032]
Next, FIG. 9 shows the authenticity determination formed body (4b) in which images can be visually recognized in different patterns from different directions with transmitted light. First, as shown in FIG. 8, the base material is provided with a first image (2a) formed by perforations (3a) that do not penetrate the base material. In order to cause different second images to appear from different directions as shown in FIGS. 9A to 9E, the second image (2c1) and the second image (2c2) as shown in FIG. ), The second image (2c3) and the second image (2c4) are combined to form the second image (2c) by the perforations (3c) penetrating the substrate (1a). The perforations (3c) penetrating the base material (1a) constituting the second image (2c) provided on the base material (1a) are regularly formed in the perforations (3a) not perforating the base material (1a). Need to be placed in. That is, the position of the perforation (3c) that penetrates the substrate (1a) that forms the second image (2c1), the second image (2c2), the second image (2c3), and the second image (2c4) May be arranged at specific distances in different directions from the center position of the perforation (3a) that does not penetrate the substrate (1a).
[0033]
Regarding the observation direction, when the perforations (3c) penetrating the substrate (1a) are regularly arranged at the Y1 position with respect to the perforations (3a) as shown in FIG. 8 (in this case, the image 2c1). It is necessary to observe from the X1, X3, or X4 direction with transmitted light, and when arranged regularly at the Y2 position (in this case, the image 2c2), observe from the X2, X3, or X4 direction with transmitted light. If it is regularly arranged at the Y3 position (in this case, the image 2c3), it is necessary to observe the transmitted light from the X1, X2 or X3 direction, and it is regularly arranged at the Y4 position. (In this case, the image 2c4), it is necessary to observe from the X1, X2 or X4 direction with transmitted light.
[0034]
Therefore, the authenticity determination formed body (4b) provided with the image (2c) by perforation penetrating through the base material (1a) is observed with transmitted light from the vertical direction as shown in FIG. 9 (a). In this case, when the image (2c1), the image (2c2), the image (2c3), and the image (2c4) are simultaneously viewed and tilted in the X1 direction shown in FIG. 8 as shown in FIG. , Image (2c1) regularly arranged on Y1 (1 in this case), image (2c3) regularly arranged on Y3 (3 in this case), and image regularly arranged on Y4 side (3) 2c4) (in this case 4) is visually recognized, and as shown in FIG. 9 (c), in the case of observing by tilting in the X2 direction shown in FIG. 8, the image (2c2) regularly arranged in Y2 (in this case) 2), images regularly arranged in Y3 (2c3) and Y4 regularly arranged When the observed image (2c4) is viewed and tilted in the X3 direction shown in FIG. 8 as shown in FIG. 9D, the image (2c1) regularly arranged in Y1 and the rule in Y2 When the image (2c2) and the image (2c3) regularly arranged on the Y3 side are visually recognized and tilted in the X4 direction shown in FIG. 8 as shown in FIG. The image (2c1) regularly arranged on Y1, the image (2c2) regularly arranged on Y2, and the image (2c4) regularly arranged on Y4 are visually recognized. Further, for example, when the observation angle from the X1 direction is deepened, only the image (2c1) regularly arranged in Y1 (in this case, 1) is observed. The same applies to the X2, X3, and X4 directions.
[0035]
The authenticity determination forming body (4b) combines the four images to form the second image, but may combine the four or more images to form the second image. The four images of the image (2c1), the image (2c2), the image (2c3), and the image (2c4) are regularly arranged vertically and horizontally with respect to the perforation (3a), but regularly in an oblique direction. In this case, it is also possible to make a plurality of images appear by combining the perforations regularly arranged vertically and horizontally with the perforations arranged obliquely. The four images of the image (2c1), the image (2c2), the image (2c3), and the image (2c4) are all different from each other. However, even if the same image is used, it is different from the same image. You may combine images.
[0036]
As described above, when the authenticity determination formed bodies (4a) and (4b) are put together, the image by the perforation penetrating the base material is composed of the perforations obtained by synthesizing n different images to form the second image of n1. The perforations that constitute the second image of n2, n3, n4,... Are arranged with regularity so that the perforations that do constitute the first image by the perforations that do not penetrate the substrate. For the perforations constituting the first image by the perforations that do not penetrate the base material, it is necessary to arrange them with regularity so as to be inherent to the perforations that do not penetrate the base material, except for the region where the second image of n1 is provided. There is.
[0037]
FIG. 10 shows a diagram in which the first image (2a) is formed on the substrate (1a) by perforation (3a) and a cross-sectional view taken along line AA ′. As shown in FIG. 10, the perforations (3a) need to be formed at a certain depth or a plurality of depths without penetrating the substrate. FIG. 11 shows a view in which only the second image (2c) is formed on the base material (1a) by perforation (3c) and its AA ′ cross-sectional view. As shown in FIG. 11, the perforations (3c) need to penetrate the substrate. The authenticity determination formed body (4a) on which the first image (2a) formed by the perforation (3a) shown in FIGS. 10 and 11 and the second image (2c) formed by the perforation (3c) are applied, and The AA ′ sectional views are shown in FIGS. 12 and 13. As shown in FIGS. 12 and 13, the perforations (3c) penetrating the substrate (1a) need to be regularly arranged so as to contact the perforations (3a) not penetrating the substrate (1a). . In this case, the perforation (3c) that penetrates the base material (1a) circumscribes the perforation (3a) that does not penetrate the base material (1a), and regularly on the left side with respect to the center position of the perforation (3a). Although it is arranged, the effect of the present invention can be obtained even if it is arranged in the right part, upper part or lower part. That is, the position of the perforation (3c) that penetrates the base material (1a) is arranged at a specific direction and a specific distance from the center position of the perforation (3a) that does not penetrate the base material (1a), and penetrates the base material (1a). The perforation (3c) to be made only needs to circumscribe the perforation (3a) that does not penetrate the substrate (1a). In the drawings, the first image (2a) and the second image (2c) are described with different designs, but the same design may be used.
[0038]
FIG. 14 shows a view when the authenticity determination formed body (4c) is observed with transmitted light from a direction perpendicular to the substrate. When the authenticity determination formed body (4c) is observed with transmitted light from a direction perpendicular to the base material, the observer views the first image (2a) formed by the perforations (3a) that do not penetrate the base material (1a). ) Is the same color as the base material, so it is difficult to see. Further, since the amount of light transmitted through the perforation (3c) that penetrates the base material (1a) is strongly recognized, the second image (2c) by the perforation (3c) that penetrates the base material (1a) is visually recognized. Will do. When the true / false discrimination formed body (4c) is observed with reflected light, the first image (2a) formed by the perforations (3a) not penetrating the base material (1a) is the same color as the base material, The second image (2c) cannot be viewed because it is difficult to recognize the transmitted light transmitted through the perforations (3c) penetrating the substrate (1a).
[0039]
FIGS. 15A, 15B, 15C, and 15D show the true / false discrimination formed body 4c when observed from the X1, X2, X3, or X4 directions shown in FIG. The figure is shown. FIG. 15A is a diagram when observed from the X1 direction. In this case, from the X1 direction, since the light transmitted through the perforation (3c) that penetrates the base material (1a) and the perforation (3a) that does not penetrate the base material can be recognized, the perforation that penetrates the base material (1a). The second image (2c) according to (3c) can be seen (in this case the number 1). FIGS. 15B, 15C, and 15D are views when observed from the X2, X3, and X4 directions. In this case, since the light transmitted through the perforation (3c) penetrating the base material (1a) and the perforation (3a) not penetrating the base material (1a) can hardly be recognized, the perforation penetrating the base material (1a) ( The second image (2c) according to 3c) cannot be visually recognized.
[0040]
The direction in which the second image can be observed depends on the positions of the perforations (3a) that do not penetrate the base material (1a) and the perforations (3c) that penetrate the base material (1a) as shown in FIG. That is, as shown in the AA ′ cross-sectional view of FIG. 16, the second image (2c) is formed on the perforations (3a) that do not penetrate the base material (1a) constituting the first image (2a). When the perforations (3c) penetrating the constituting substrate (1a) are regularly arranged on the Y1 side, it is necessary to observe from the X0 direction with transmitted light or the X1 direction with transmitted light, and Y2 When regularly arranged on the side, it is necessary to observe from the X0 direction with transmitted light or from the X2 direction with transmitted light.
[0041]
Next, FIG. 18 shows the authenticity determination formed body (4d) in which images can be visually recognized in different patterns from different directions with transmitted light. First, as shown in FIG. 17, the substrate is provided with a first image (2a) formed by perforations (3a) that do not penetrate the substrate. In order to make different second images appear from different directions as shown in FIG. 18A to FIG. 18E, the second image (2c1) and the second image (2c2) as shown in FIG. ), The second image (2c3) and the second image (2c4) are combined to form the second image (2c) by the perforations (3c) penetrating the substrate (1a). The through-holes (3c) constituting the second image (2c) provided on the substrate (1a) must be regularly arranged outside the perforations (3a) that do not perforate the substrate (1a). There is. That is, the position of the perforation (3c) that penetrates the substrate (1a) that forms the second image (2c1), the second image (2c2), the second image (2c3), and the second image (2c4) May be arranged at specific distances in different directions from the center position of the perforation (3a) that does not penetrate the substrate (1a).
[0042]
Regarding the observation direction, when the perforations (3c) penetrating the substrate (1a) are regularly arranged at the Y1 position with respect to the perforations (3a) as shown in FIG. 17 (in this case, the image 2c1). , It is necessary to observe from the X1 direction with transmitted light, and when arranged regularly at the Y2 position (in this case, the image 2c2), it is necessary to observe from the X2 direction with transmitted light, and the Y3 position Is regularly arranged (in this case, image 2c3), it is necessary to observe from the X3 direction with transmitted light, and when regularly arranged at Y4 position (in this case, image 2c4), It is necessary to observe from the X4 direction with transmitted light.
[0043]
Therefore, the authenticity determination formed body (4b) provided with the image (2c) by the perforation penetrating the base material (1a) is observed with transmitted light from the vertical direction as shown in FIG. 18 (a). In this case, when the image (2c1), the image (2c2), the image (2c3), and the image (2c4) are viewed at the same time and observed from the X1 direction shown in FIG. 17, as shown in FIG. When the image (2c1) regularly arranged in Y1 (1 in this case) is visually recognized and viewed from the X2 direction shown in FIG. 17, as shown in FIG. 18C, the image is regularly arranged in Y2. The arranged image (2c2) (2 in this case) is visually recognized, and as shown in FIG. 18 (d), when observing from the X3 direction shown in FIG. 17, the image is regularly arranged on the Y3 side. (2c3) is visually recognized and shown in FIG. 17 as shown in FIG. X4 when viewing from the direction are regularly arranged image Y4 (2c4) is visually recognized.
[0044]
The authenticity determination forming body (4d) combines the four images to form the second image, but may combine the four or more images to form the second image. The four images of the image (2c1), the image (2c2), the image (2c3), and the image (2c4) are regularly arranged vertically and horizontally with respect to the perforation (3a), but regularly in an oblique direction. In this case, it is also possible to make a plurality of images appear by combining the perforations regularly arranged vertically and horizontally with the perforations arranged obliquely. The four images of the image (2c1), the image (2c2), the image (2c3), and the image (2c4) are all different from each other. However, even if the same image is used, it is different from the same image. You may combine images.
[0045]
As described above, when the authenticity determination formed bodies (4c) and (4d) are put together, the image by the perforation penetrating the base material is composed of the perforations obtained by synthesizing n different images, and the perforations constituting the image of n1. , With respect to the perforations constituting the image by the perforations that do not penetrate the base material, the perforations constituting the images of n2, n3, n4... It is necessary to arrange with regularity so as to circumscribe the perforations constituting the image by the perforations that do not penetrate the substrate, except for the region where the n1 image is provided.
[0046]
Next, a case where a three-dimensional image can be visually recognized when observed with transmitted light from a direction perpendicular to the substrate will be described. In order to make a three-dimensional image visible when observed with transmitted light from a direction perpendicular to the substrate, it is necessary to provide regularity in the arrangement of the perforations penetrating the substrate. As shown in FIG. 19, the pair of second images (2c1, 2c2) by the perforation (3c) penetrating the base material does not penetrate the base material so as to be inherent in the perforation (3a) not penetrating the base material. It is necessary to provide symmetry with respect to the center position of the perforation (3a), such as right and left and up and down. Furthermore, the positions where the pair of second images (2c1, 2c2) by the perforations (3c) penetrating the base material need to be arranged in consideration of the binocular parallax of the observer. This is manifested by a parallax barrier effect in which the direction of transmitted light that is visible is limited by the perforations (3a) and perforations (3c). Here, the parallax barrier uses a phenomenon in which the line-of-sight angle passing through the barrier opening differs depending on the left and right eyes.For example, two images are cut into two vertically elongated images, This is a phenomenon in which images are viewed three-dimensionally by arranging barriers having openings in front of alternately arranged images.
[0047]
A pair of images (2c1, 2c2) from a perforation (3c) that penetrates the substrate is symmetrical to the perforation (3a) that does not penetrate the substrate, as is inherent in the perforation (3a) that does not penetrate the substrate. The true / false discrimination formed body (4e) provided is a perforation that does not penetrate the base material in the left eye of the observer when observed with transmitted light from the direction perpendicular to the base material as shown in FIG. The image (2c1) by the perforation (3c) provided on the right side of (3a) is visually recognized, and the observer's right eye is provided on the left side of the perforation (3a) that does not penetrate the base material. By visually recognizing the image (2c2) by the perforation (3c) penetrating the base material, the second image by the perforation penetrating the base material is viewed three-dimensionally.
[0048]
Further, another example in which a three-dimensional image can be visually recognized when observed with transmitted light from a direction perpendicular to the base material will be described. In order to make a three-dimensional image visible when observed with transmitted light from a direction perpendicular to the substrate, it is necessary to provide regularity in the arrangement of the perforations penetrating the substrate. As shown in FIG. 21, the pair of second images (2c1, 2c2) by the perforation (3c) penetrating the base material does not penetrate the base material so as to circumscribe the perforation (3a) not penetrating the base material. It is necessary to provide symmetry with respect to the center position of the perforation (3a), such as right and left and up and down. Furthermore, the positions where the pair of second images (2c1, 2c2) by the perforations (3c) penetrating the base material need to be arranged in consideration of the binocular parallax of the observer.
[0049]
A pair of images (2c1, 2c2) from a perforation (3c) penetrating the substrate is symmetrical to the perforation (3a) not penetrating the substrate so as to circumscribe the perforation (3a) not penetrating the substrate The true / false discrimination formed body (4f) provided is a perforation that does not penetrate the base material in the left eye of the observer when observed with transmitted light from a direction perpendicular to the base material as shown in FIG. The image (2c1) by the perforation (3c) provided on the right side of (3a) is visually recognized, and the observer's right eye is provided on the left side of the perforation (3a) that does not penetrate the base material. By visually recognizing the image (2c2) by the perforation (3c) penetrating the base material, the second image by the perforation penetrating the base material is viewed three-dimensionally.
[0050]
FIG. 23 shows an explanation of the internal and external circumstance described in the above-described authenticity determination formed body (4a, 4b, 4c, 4d, 4e, 4f). The inherent here is as shown in FIGS. 23 (a) and 23 (b). In FIG. 23 (a), a perforation 3c is included in the perforation 3a. In this case, it is sufficient that the perforations 3c are disposed in the perforations 3a as shown in FIG. Further, the perforations (3c) that form the second image are preferably arranged within the radius (S) of the perforations (3a) that form the first image. The circumscribing referred to here is as shown in FIG. In FIG. 23C, the perforation 3c circumscribes the perforation 3a. That is, the relationship between the perforations (3a) for forming the first image and the perforations (3c) for forming the second image is that the perforations (3c) need to be formed at positions other than the center position of the perforations (3a). In addition, the perforation (3a) and the perforation (3c) must be partially or entirely overlapped.
[0051]
The authenticity discrimination formed body (4a, 4b, 4e) described above is formed on one base material. However, the present invention is not limited to this, and the effects of the present invention are also achieved by the following configuration. be able to. As shown in FIGS. 24A to 24C, a two-layer structure in which a first base material 11a and a second base material 11b are provided may be used. In this case, the first image and the second image use perforations that penetrate the substrate. FIG. 24 (a) shows the same effect as the authenticity discrimination formed body (4a), and the first base material (11a) has perforations (3a) penetrating the base material constituting the first image (2a). It is the structure which provided and the perforation (3c) which penetrates the base material which comprises a 2nd image (2c) in the 2nd base material (11b). FIG. 24 (b) shows the same effect as the authenticity determination formed body (4b), and a perforation (3a) penetrating the base material constituting the first image (2a) is formed in the first base material (11a). It is the structure which provided and the perforation (3c) which penetrates the base material which comprises a 2nd image (2c) in the 2nd base material (11b). FIG. 24 (c) shows the same effect as the authenticity determination formed body (4e), and a perforation (3a) penetrating the base material constituting the first image (2a) is formed in the first base material (11a). It is the structure which provided and the perforation (3c) which penetrates the base material which comprises a 2nd image (2c) in the 2nd base material (11b). The first substrate (11a) and the second substrate (11b) are bonded with an adhesive or the like. However, when the true / false discrimination formed body (4a, 4b, 4e) is formed in a two-layer structure, the perforation that penetrates the second base material needs to have a smaller diameter than the perforation that penetrates the first base material. There is.
[0052]
For example, in the case where the substrate is a true / false discrimination formed body (4 g) which is a two-layer laminate, a case where an arbitrary image is lost is shown. The first base material (11a) of the base material used the first image (2a) by the through-holes shown in FIG. 25, and the second base material (11b) of the base material was shown in FIG. A second image (2c1, 2c2) with a penetrating hole is used. FIG. 27 shows a laminate obtained by laminating these two base materials with high accuracy. When the transmitted light is observed from the direction perpendicular to the base material, all the second images (2c1, 2c2) by the perforations penetrating the second base material can be visually recognized, and the transmitted light in the X1 direction is observed. Then, only the second image (2c1) regularly arranged in Y1 can be visually recognized, and when the transmitted light in the X2 direction is observed, only the second image (2c2) regularly arranged in Y2 can be visually recognized. .
[0053]
The authenticity determination formation body (4g) combines two images to form a second image, but may combine four or more images to form a second image. The two second images (2c1, 2c2) shown in FIG. 27 are regularly arranged on the left and right with respect to the perforation (3c1) of the first base material, but regularly in the vertical and diagonal directions. In this case, a plurality of images can be made to appear by combining perforations that are regularly arranged in the up, down, left, and right directions. It is also possible to combine the second image (2c1 and 2c2) with the same image and view a three-dimensional image by taking a distance in the left-right direction and a different image in the vertical direction.
[0054]
The perforation of the present invention can be applied with a laser perforation apparatus or the like, and the shape is preferably 50 to 500 μm. The shape of the perforations is related to the thickness and the resolution and the number of images to be expressed. Naturally, in order to express a high-resolution image in a specific area, it is necessary to make a hole having as small a shape as possible, but if it is several tens of μm or less, it is difficult to create the hole. In addition, when a large-shaped perforation is used, an image that can be expressed becomes rough.
[0055]
The authenticity determination formed body of the present invention can give gradation expression to the first image and the second image, and the perforation is a perforation that penetrates (a perforation that penetrates the first substrate of the laminate). Excluding), at least one of density, size, and arrangement may be changed.
[0056]
When the perforations forming the second image of the present invention are inherent in the perforations forming the first image, the diameter of the perforations forming the second image is equal to the diameter of the perforations forming the first image. A size of 10 to 30% is preferable.
[0057]
The substrate used in the present invention is not particularly limited, and paper sheets, films, plastics and the like can be used. Further, the thickness of the substrate is not particularly limited, but is preferably about 0.12 mm to 1.0 mm.
[0058]
The shape of the perforation of the present invention is not particularly limited, and it is necessary to form at least one of a circular shape, a polygonal shape, and a special shape. By using polygonal or specially shaped perforations, the anti-counterfeiting effect is improved because it becomes difficult to be duplicated.
[0059]
The perforations forming the first image and the perforations forming the second image of the present invention can be formed in at least one of a right angle and a specific angle with respect to the substrate. When it is formed obliquely at a specific angle, it becomes difficult to replicate, so the forgery prevention effect is improved. When the oblique angle is deepened at a specific angle, the observation angle at which the latent image is visually recognized becomes somewhat deeper.
[0060]
By forming the perforations of the present invention with at least one shape having the same perforation diameter and a smaller perforation diameter in the depth direction, the anti-counterfeiting effect is improved because the perforation according to the present invention is less likely to be duplicated.
[0061]
When the second image of the present invention is at least one of a character, a number, a symbol, and a picture, the authenticity determination effect is improved when the image is observed with an inclination with transmitted light. Further, the first image and the second image may have the same design.
[0062]
By providing the perforations for camouflaging the second image formed by the perforations formed by the perforations penetrating the substrate of the present invention, it is possible to prevent the second image from being visually recognized. The camouflage perforation is shown in FIG.
[0063]
In the authenticity determination formed body of the present invention, any different color tone can be visually recognized by stacking color filters (for example, three colors) that transmit light on the authenticity determination formed body.
[0064]
FIG. 28 shows a case where the perforations forming the first image and the second image of the present invention are formed obliquely at a specific angle with respect to the substrate. FIG. 28A shows a configuration showing the same configuration as the authenticity determination formed body (4a) except for the angle of perforation. FIG. 28 (b) shows a configuration showing the same configuration as the authenticity discrimination formed body (4b) except for the perforation angle. FIG. 20 (c) shows a configuration showing the same configuration as the authenticity determination formed body (4e) except for the angle of perforation. In FIGS. 28A and 28B, unlike the true / false discrimination formations (4a, 4b), the second image cannot be observed when observed with transmitted light from the vertical direction, but is observed with an inclination. In some cases, a second image is observed. The effect of FIG. 28C is different from the authenticity determination formed body (4e), and the first image cannot be observed when observed with transmitted light from the vertical direction, but the second image is observed when observed with an inclination. Observed in three dimensions. FIG. 29 shows a case where the perforation of the present invention is formed so that the diameter of the perforation becomes smaller in the depth direction. FIG. 29 shows an example of a truncated cone.
[0065]
FIG. 30 shows a conceptually simple arrangement of the authenticity determination formation bodies (4a, 4b, 4c, 4d, 4e, 4f) in the above configuration.
[0066]
【Example】
EXAMPLES Hereinafter, although this invention is demonstrated further in detail using an Example, the content of this invention is not limited to the range of these Examples.
[0067]
Example 1
Prepare a sheet of paper with a thickness of about 0.15 mm, and drill holes with a diameter of 0.4 mm on this paper at a constant depth without penetrating the paper by a laser processing machine in a grid pattern at regular intervals of 0.8 mm. A first image (A) was applied (see FIG. 31). Further, the paper is perforated with a diameter of 0.1 mm at a constant interval of 0.8 mm through this paper by a laser processing machine, and four different second images (B1), second images (B2), second The image (B3) and the second image (B4) were applied (see FIG. 31). At this time, the perforations of the first image (A) formed on the paper are arranged in a regular manner so as to form the second images formed on the paper, and the perforations of the first image (A). , The perforations forming the second image (B1) are regularly arranged on the right side (90 ° when the upper side is 0 °) to form the second image (B2) The perforations are regularly arranged on the right side (270 ° when the upper side is 0 °), and the perforations forming the second image (B3) are on the right side (0 ° when the upper side is 0 °). Regularly arranged, the perforations forming the second image (B4) are regularly arranged on the right side (180 ° when the upper side is 0 °) to create a true / false discrimination formed body (C1) (See FIG. 31). When this authenticity determination formed body (C1) is observed with transmitted light, the second image (B1), the second image (B2), and the second image are viewed from the vertical direction as shown in FIG. The image (B3) and the second image (B4) are all visible, and when viewed from the X1 direction, the second image (B2) disappears and is observed from the X2 direction as shown in FIG. In this case, the second image (B1) disappears as shown in FIG. 32 (c), and when viewed from the Y1 direction, the second image (B4) disappears as shown in FIG. 32 (d), When observed from the Y2 direction, the second image (B3) disappears as shown in FIG.
[0068]
(Example 2)
Prepare a sheet of paper with a thickness of about 0.15 mm, and drill holes with a diameter of 0.4 mm on this paper at a constant depth without penetrating the paper by a laser processing machine in a grid pattern at regular intervals of 0.8 mm. A first image (A) was applied (see FIG. 33). Further, the paper is perforated with a diameter of 0.1 mm at a constant interval of 0.8 mm through this paper by a laser processing machine, and four different second images (B1), second images (B2), second The image (B3) and the image (B) on which the second image (B4) is formed were applied (see FIG. 33). At this time, perforations for forming the second image (B) applied to the paper are regularly arranged in contact with the perforations of the first image (A) applied to the paper, and the first image (A ), The perforations forming the second image (B1) are regularly arranged on the right side (90 ° when the upper side is 0 °) to form the second image (B2) Are arranged regularly on the right side (270 ° when the upper side is 0 °), and the perforations forming the second image (B3) are on the right side (0 ° when the upper side is 0 °). ) Regularly and the perforations forming the second image (B4) are regularly arranged on the right side (180 ° when the upper side is 0 °), and the true / false discrimination formed body (C1 ) Was created (see FIG. 33). When the authenticity determination formed body (C1) is observed with transmitted light, the second image (B1), the second image (B2), and the second image are viewed from the vertical direction as shown in FIG. When viewed from the X1 direction, only the second image (B1) can be viewed and viewed from the X2 direction as shown in FIG. 34 (b). In this case, only the second image (B2) is visible as shown in FIG. 34 (c), and when viewed from the Y1 direction, only the second image (B3) is shown in FIG. 34 (d). When viewing from the Y2 direction, only the second image (B4) is visible as shown in FIG. 34 (e).
[0069]
(Example 3)
Prepare a sheet of paper with a thickness of about 0.3 mm, and drill holes with a diameter of 0.4 mm on this paper at a constant depth without penetrating the paper in a grid pattern at regular intervals of 0.8 mm. A first image (A) was applied (see FIG. 35). In addition, a pair of second images (B1, B2) in which perforations having a diameter of 0.08 mm were penetrated through the paper by a laser processing machine at a constant interval of 0.8 mm were applied (see FIG. 35). At this time, in the perforations of the first image (A) made on the paper, the perforations forming the pair of second images (B1, B2) made on the paper are inherently arranged and regularly arranged. A true / false discriminating body (C3) was created by regularly arranging the left and right 0.04 mm from the center of the perforation in image (A) (see FIG. 35). As shown in FIG. 36, when this true / false discrimination formed body (C3) is observed from a distance of about 300 mm away from the vertical direction with respect to the base material, the left eye and the right eye respectively Since the second image (B1) and the second image (B2) can be seen, a three-dimensional image can be visually recognized in the first image (A).
[0070]
(Example 4)
Prepare a sheet of paper with a thickness of about 0.45 mm. On this paper, punches with a diameter of 0.1 mm are formed at a constant depth without penetrating the paper with a laser processing machine in a grid pattern at regular intervals of 0.8 mm. A first image (A) was applied (see FIG. 37). In addition, a pair of second images (B1, B2) in which perforations having a diameter of 0.08 mm were penetrated through the paper by a laser processing machine at a constant interval of 0.8 mm were applied (see FIG. 37). At this time, in the perforations of the first image (A) made on the paper, the perforations forming a pair of second images (B1, B2) made on the paper are regularly arranged so as to circumscribe, A true / false discrimination formed body (C4) was prepared (see FIG. 37). As shown in FIG. 38, when this true / false discrimination formed body (C4) is observed from a distance of about 300 mm away from the substrate in a direction perpendicular to the base material, the left eye and the right eye respectively Since the second image (B1) and the second image (B2) can be seen, a three-dimensional image can be visually recognized in the first image (A).
[0071]
Although the present invention has been described based on the embodiment of the present invention, the present invention is not limited to this embodiment, and various other implementations are possible within the scope of the technical idea described in the claims. Possible forms.
[0072]
【The invention's effect】
An image comprising a perforation group formed by perforation not penetrating the base material and a perforation group formed by perforation penetrating the base material is provided, and the individual perforation positions of the perforation group penetrating the base material forming the image are By locating corresponding to the individual perforation positions of the perforation group not penetrating through, the appearance of a clear second image, the appearance of a second image different from multiple directions, depending on the observation angle when observed with transmitted light Or, since the disappearance and the appearance of the stereoscopic two-dimensional image are made, it can become a true / false discriminating body having a high authenticity discrimination effect, falsification, and anti-duplication effect, such as banknotes, passports, passports, cards, etc. It can be applied to valuable printed matter that needs to prevent counterfeiting, copying, and tampering.
[0073]
In addition, an image of the second base material including a first base material having a perforation group formed by perforation penetrating through and a second base material having an image of the perforation group formed by perforation penetrating through the second base material. The individual drilling positions of the perforated group to be formed are observed when transmitted light is observed by sequentially laminating them so as to be arranged corresponding to the individual perforated positions of the perforated group of the first substrate. Depending on the angle, the appearance of a clear second image, the appearance or disappearance of a second image that differs from multiple directions, and the appearance of a stereoscopic second image can occur. It can be an effective authenticity determination forming body, and can be applied to valuable printed materials that need to prevent counterfeiting, copying, and falsification of banknotes, passports, passports, cards, and the like.
[0074]
In design, the second image can appear in a plurality of different observation directions, and anyone can determine authenticity on the spot without using an authenticity determination device or the like. In addition, when the device is counterfeited or tampered with, the positional relationship between the perforation penetrating the base material and the perforation not penetrating the base material, or the perforation penetrating the first base material and penetrating the second base material It is necessary to faithfully reproduce the positional relationship of the perforations, and it is very difficult to reproduce not only the fine perforations themselves but also their arrangement.
[0075]
The true / false discrimination formed body of the present invention can be manufactured even in an apparatus that constitutes a mass production line that irradiates a laser vertically and automatically conveys the base material in the horizontal direction without forming oblique perforations in the base material. Since a latent image can be formed, it can be produced without using a complicated processing machine.
[0076]
[Brief description of the drawings]
FIG. 1 is a diagram in which a first image (2a) is formed on a base material (1a) by perforation (3a) and a sectional view taken along line AA ′.
FIG. 2 is a diagram in which a second image (2c) is formed on a substrate (1a) by perforation (3c) and a cross-sectional view taken along line AA ′.
FIG. 3 is a cross-sectional view of authenticity determination formed body (4a) and its AA ′.
FIG. 4 is a diagram showing the direction of transmitted light of the authenticity discrimination formed body (4a).
FIG. 5 is a diagram showing a case where a true / false discrimination formed body (4a) is observed with transmitted light from a vertical direction.
FIG. 6 is a view when observed with transmitted light at a different angle with respect to the authenticity determination formed body (4a).
FIG. 7 is an explanatory diagram of directions that can be observed.
FIG. 8 shows a first image (2a) formed with a perforation (3a) that does not penetrate, a second image (2c1), a second image (2c2), a second image formed with a perforation (3c) that penetrates It is a figure which shows the authenticity determination formation body (4b) which provided four images, the image (2c3) and the 2nd image (2c4).
FIG. 9 is a view of the true / false discrimination formed body (4b) observed with transmitted light from the vertical direction shown in FIG. 8 with transmitted light and tilted in the X1, X2, X3, and X4 directions.
FIG. 10 is a diagram in which a first image (2a) is formed on a substrate (1a) by perforation (3a) and a cross-sectional view taken along line AA ′.
FIG. 11 is a view in which a second image (2c) is formed on a base material (1a) by perforation (3c) and a sectional view taken along line AA ′.
FIG. 12 is a cross-sectional view of authenticity determination formed body (4c) and its AA ′.
FIG. 13 is a diagram showing the direction of transmitted light of the authenticity determination formed body (4c).
FIG. 14 is a diagram showing a case where the authenticity determination formed body (4c) is observed with transmitted light from the vertical direction.
15 is a view when the authenticity determination formed body (4c) is observed with transmitted light from the X1, X2, X3, and X4 directions shown in FIG. 12. FIG.
FIG. 16 is an explanatory diagram of directions that can be observed;
FIG. 17 shows a first image (2a) formed with a perforation (3a) that does not penetrate, a second image (2c1), a second image (2c2), a second image formed with a perforation (3c) that penetrates It is a figure which shows the authenticity determination formation body (4d) which provided four images, the image (2c3) and the 2nd image (2c4).
18 is a view of the true / false discrimination formed body (4d) observed with transmitted light from the vertical direction shown in FIG. 17 with transmitted light and tilted in the X1, X2, X3, and X4 directions.
FIG. 19 is a true / false discrimination formed body provided with a first image (2a) formed by a perforation (3a) not penetrating and a pair of second images (2c1, 2c2) formed by a perforation (3c) penetrating. It is a figure which shows (4e) and its AA 'sectional drawing.
FIG. 20 is a diagram illustrating the principle by which a stereoscopic image of a true / false discrimination formed body (4e) is visually recognized.
FIG. 21 is a true / false discrimination formed body provided with a first image (2a) formed by a perforation (3a) not penetrating and a pair of second images (2c1, 2c2) formed by a perforation (3c) penetrating. It is a figure which shows (4e) and its AA 'sectional drawing.
FIG. 22 is a diagram illustrating the principle by which a stereoscopic image of a true / false discrimination formed body (4e) is visually recognized.
FIG. 23 is an explanatory diagram of internal and circumscribed aspects of the present invention.
FIG. 24 is a view showing a two-layer structure in which a first base material (11a) and a second base material (11b) are provided.
FIG. 25 is a diagram in which the first image (2a) is formed on the first base material (11a) by perforation (3c).
FIG. 26 is a diagram in which a second image (2c) is formed on the second base material (11b) by perforation (3c).
FIG. 27 is a true / false discrimination formed body (4g) in which a first base material (11a) and a second base material (11b) are laminated.
FIG. 28 is a diagram showing a case where the substrate is formed obliquely at a specific angle with respect to the substrate.
FIG. 29 is a diagram when the diameter of the perforation of the present invention becomes smaller in the depth direction.
FIG. 30 is a diagram conceptually and simply organizing authenticity determination formation bodies (4a, 4b, 4c, 4d, 4e, and 4f).
FIG. 31 shows a first image (A) made by punching that does not penetrate paper, a second image (B1), second image (B2), and second image (B3) made by punching that penetrates paper. ) And the second image (B4) are true / false discrimination formation bodies (C1).
32 is a view showing a case where the authenticity discrimination formed body (C1) is observed with transmitted light from the direction shown in FIG. 24. FIG.
FIG. 33 shows a first image (A) made by punching that does not penetrate paper, a second image (B1), second image (B2), and second image (B3) made by punching that penetrates paper. ) And a second image (B4) showing a true / false discrimination formed body (C2).
34 is a diagram showing a case where the authenticity determination formed body (C1) is observed with transmitted light from the direction shown in FIG. 26. FIG.
FIG. 35 shows a true / false discrimination formed body (C3) composed of a first image (A) made by perforation not penetrating paper and a pair of second images (B1, B2) made by perforation penetrating paper. FIG.
FIG. 36 is a diagram showing an observation direction in which a stereoscopic image is visually recognized by a true / false discrimination formed body (C3).
FIG. 37 shows a true / false discrimination formed body (C3) composed of a first image (A) made by perforation not penetrating paper and a pair of second images (B1, B2) made by perforation penetrating paper. FIG.
FIG. 38 is a diagram showing an observation direction in which a stereoscopic image is visually recognized by a true / false discrimination formed body (C4).
FIG. 39 shows a camouflage perforation of the present invention.
FIG. 40 is a view of a specific direction referred to in the present invention.
[Explanation of symbols]
1a Base material
2a First image
2c, 2c1, 2c2, 2c3, 2c4 second image
3a Drilling that does not penetrate the substrate
3c, 3c1, 3c2, 3c3, 3c4 perforations through the substrate
4a, 4b, 4c, 4d, 4e, 4f, 4g Authenticity discriminator
A First image
B, B1, B2, B3, B4 Second image
C1, C2, C3, C4 Authenticity discriminator
11a First base material
11b Second base material
S Camouflage perforation

Claims (8)

A perforation group formed by perforations formed by perforations not penetrating the base material and a perforation group formed by perforations formed by perforations penetrating the base material, and the perforation group penetrating the base material forming the at least two images Each of the perforation positions is a true / false discrimination formed body arranged corresponding to each perforation position of a perforation group that does not penetrate the substrate,
An individual perforation diameter of a perforation group penetrating the base material forming the at least two images is smaller than an individual perforation diameter of a perforation group not penetrating the base material, and forms the at least two images. The individual perforations of the group of perforations that penetrate the substrate are arranged to overlap the individual perforations of the perforations that do not penetrate the substrate;
The individual perforation position of the perforation group that penetrates the base material forming the at least two images is based on the center position of the individual perforation group of the perforation group that does not penetrate the base material, and a specific direction and a specific distance from the reference. And the specific direction is a different direction for each image. Providing at least one image comprising a perforation group formed by perforation not penetrating the base material, a perforation group for right eye and a perforation group for left eye formed by perforation penetrating the base material, and the at least one image is The individual perforation positions of the right eye perforation group and the left eye perforation group penetrating the base material to be formed are arranged corresponding to the individual perforation positions of the perforation group not penetrating the base material. A true / false discriminator, wherein the diameter of each of the right eye perforation group and the left eye perforation group that penetrates the base material forming the at least one image penetrates the base material. Each of the right eye perforation group and the left eye perforation group penetrating through the base material forming the at least one image is smaller than the individual perforation diameter of the perforation group Overlapping individual perforations in a group of perforations that do not penetrate the substrate Is urchin disposed further perforations for perforations and the left eye for the right eye becomes a pair,
The true / false discrimination formed body is characterized in that the at least one image is viewed three-dimensionally when the true / false discrimination formed body is observed with transmitted light from a specific distance. The first substrate having a perforated group formed by penetrating through and a second substrate having at least two images composed of the perforated group formed by penetrating through, the second substrate having the second base Authenticity discrimination formed by sequentially laminating the individual perforation positions of the perforation group forming at least two images so as to correspond to the individual perforation positions of the perforation group included in the first substrate. A formed body,
An individual perforation diameter of the perforation group forming the at least two images on the second base material is smaller than an individual perforation diameter of the perforation group on the first base material, and the second The perforations of the perforations that form the at least two images on the substrate of the first substrate are arranged to overlap the perforations of the perforations of the first substrate;
An individual perforation position of the perforation group forming the at least two images on the second base material is based on a center position of the individual perforation group of the perforation group on the first base material. An authenticity determination formation body, which is arranged at a specific direction and a specific distance, and wherein the specific direction is a direction different for each second image. From a first base material having a perforation group formed by non-penetrating perforations, and a second base material having at least one image consisting of a right eye perforation group and a left eye perforation group formed by perforating holes The individual perforation positions of the right eye perforation group and the left eye perforation group forming at least one image on the second base material are the perforation group on the first base material. A true / false discrimination formed by sequentially stacking so as to correspond to the individual perforation positions,
The individual perforation diameters of the right eye perforation group and the left eye perforation group forming the at least one image on the second base material are the same as those of the perforation group on the first base material. Individual perforations of the right eye perforation group and the left eye perforation group that are smaller than individual perforation diameters and that form the at least one image on the second substrate are the first perforation group, Are arranged so as to overlap the individual perforations of the perforation group that does not penetrate the base material, and the perforation group for the right eye and the perforation group for the left eye are paired,
The true / false discrimination formed body is characterized in that the at least one image is viewed three-dimensionally when the true / false discrimination formed body is observed with transmitted light from a specific distance. 5. The authenticity according to claim 1, wherein the non-penetrating perforations and the penetrating perforations are formed by at least one of a right angle with respect to the substrate and an oblique shape at a specific angle. Discriminant formation. The authenticity determination formed body according to claim 1, 2, 3, 4, or 5, wherein the perforation not penetrating and the perforation pitch of the through perforation are arranged at equal pitches. The true / false discrimination formed body according to claim 1, 2, 3, 4, 5, or 6, wherein the diameter of the perforation not penetrating and the diameter of the penetrating perforation is 50 µm to 1000 µm.         8. The authenticity determination formed body according to claim 1, wherein the perforation not penetrating and the shape of the penetrating perforation are circular.

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