JP6065409B2 - Anti-counterfeit medium, anti-counterfeit sticker, anti-counterfeit transfer foil and verification method - Google Patents

Description

  The present invention relates to an anti-counterfeit medium that can be used for various articles.

  Anti-counterfeiting technology is used for various articles. For example, a bank note, a bond, a gift certificate, a check such as a check, or a securities. It is also used for various certificates such as credit cards, ID cards, official documents, and important documents. Recently, it has been applied to various products and their packaging materials to ensure that the products are authentic. Needless to say, anti-counterfeiting measures for these articles are inspected, and if proper anti-counterfeiting measures are taken, it is determined that the article is genuine, and if anti-counterfeiting measures are not applied or anti-counterfeiting measures are inappropriate Is determined to be a non-authentic article.

  Such anti-counterfeiting means is generally divided into an overt technique and a covert technique.

  First, overt technology is a technology that anyone can recognize as anti-counterfeiting technology, and can determine its authenticity. As this overt technique, for example, a color or pattern changes depending on the viewing angle like a diffractive structure like a hologram, or an effect that the color changes depending on the viewing angle like a spiral structure of cholesteric liquid crystal, so-called cholesteric color Examples include observing known phenomena.

  In the method shown in Patent Document 1, both of these diffractive structures and cholesteric color using a cholesteric and absorbing layer are provided. With such an object, the phenomenon cannot be reproduced by simple printing or color copying, and anyone can recognize its existence without requiring a special detector or skilled ability for authenticity determination. For this reason, for example, when a general consumer purchases a product, it can be determined whether or not the product is genuine. On the other hand, since its existence is obvious for a malicious person, it is easily targeted as a forgery or counterfeit object. For example, many forgeries have already been forged due to the improvement of technical capabilities of counterfeiting groups, and there are many products that can achieve similar color and pattern changes despite being poor products. In addition, a film close to a cholesteric color whose color changes depending on the viewing angle can be easily realized by a multilayer film used for high-grade packaging. And by combining these technologies, it is possible to make things that look the same.

  In addition, the covert technique is a technique that cannot be recognized unless there is a special detector or skill. For example, the effect of changing the appearance by applying a special filter can be exemplified. Patent Document 2 proposes a medium in which a retardation film is arranged in a pattern on a part of a light reflection film. Although this medium cannot recognize the existence of the retardation film itself, when the polarizing film is stacked on the retardation film as a detector and the polarizing film is rotated in the plane, the phase difference is accompanied with the rotation. Since the brightness changes in the shape of the film, if such a phenomenon can be observed, it can be determined that the article is genuine, and if it cannot be observed, it can be determined that the article is a non-genuine counterfeit or forged product. As described above, the anti-counterfeiting means using the covert technology cannot be recognized without a special detector or skill. For this reason, for example, it is difficult for general consumers to make a decision at the store, but since it is not clear to a malicious person, it is difficult to grasp it as an object of forgery or forgery. .

  From the above, it is considered preferable that the anti-counterfeit medium has a plurality of the above-mentioned overt techniques and covert techniques.

  In addition, such media are often used in designs that allow the user's logo or product name to be recognized by the user, and therefore have a high degree of freedom in design and design. Preferably it is.

Japanese Patent No. 4778445 JP 2006-142599 A

  Among the background technologies described so far, cholesteric is a very useful anti-counterfeiting technology. As described above, not only has both the overt technology that changes color depending on the viewing angle and the covert technology that can discriminate the reflection of circularly polarized light by overlapping circularly polarizing filters, but cholesteric has many color shifting materials. Among them, the color change is particularly large, the appearance is vivid, and the design is excellent, but as mentioned above, it is possible to make the same appearance by using the multilayer film There is.

  Therefore, in the present invention, it is difficult to create a medium that looks similar to the above, while having the effect of changing the color depending on the viewing angle, and by observing a specific appearance change with a filter. Provided is a medium that enables authenticity determination.

That is, the first embodiment of the present invention shows the minimum configuration of the present invention, and includes a polarization color shift layer that produces a color shift effect in which the color reflected changes depending on the viewing angle, and the polarization color shift layer. An absorbing layer that absorbs at least the transmitted visible light wavelength; and a shaping layer having an inclined surface on which the polarizing color shift layer is disposed, and an angle of a valley formed by adjacent inclined surfaces is 90 degrees. This is a medium for preventing forgery.

The second embodiment of the present invention shows another minimum configuration of the present invention, and a polarization color shift layer that produces a color shift effect in which the reflected color changes depending on the viewing angle, and the polarization color shift layer. An absorptive layer that absorbs at least visible light wavelengths transmitted through the surface, an inclined surface on which the polarizing color shift layer is disposed, and a shaping layer having an angle of 45 degrees formed by a surface adjacent to the inclined surface, These are anti-counterfeit media characterized by comprising:

The third embodiment of the present invention shows one of the forms of the present invention. In the forgery prevention medium of the first embodiment , one of the inclined surfaces adjacent to each other is formed with respect to the surface of the medium. An anti-counterfeit medium characterized in that the angle is 45 degrees.

The fourth embodiment of the present invention shows one of the embodiments of the present invention. In the forgery prevention medium of the second embodiment , the angle of the inclined surface with the surface of the medium is 45 degrees. The anti-counterfeit medium is characterized in that the angle between the surface adjacent to the inclined surface and the surface of the medium is 90 degrees.

The fifth embodiment of the present invention shows one of the embodiments of the present invention, and is adjacent to the inclined surface on which the polarization color shift layer is arranged in the forgery prevention medium of the second or fourth embodiment. The anti-counterfeit medium is characterized in that a reflective layer is provided on the surface.

The sixth embodiment of the present invention shows one of the embodiments of the present invention. In the forgery prevention medium of the fourth embodiment , the polarization color shift is performed on the surface having the smaller angle with the surface of the medium. The anti-counterfeit medium is characterized in that a reflective layer is provided on the surface having the larger angle between the layer and the surface of the medium.

A seventh embodiment of the present invention shows one of the embodiments of the present invention. In the anti-counterfeit medium according to any one of the first to sixth embodiments , the polarization color shift layer includes: An anti-counterfeit medium characterized by being provided only on a surface inclined with respect to the surface.

The eighth embodiment of the present invention defines the configuration of the present invention in more detail. In the anti-counterfeit medium according to any one of the first to seventh embodiments , the polarization color shift layer includes a cholesteric liquid crystal. This is a medium for preventing forgery.

The ninth embodiment of the present invention shows one of the forms of the present invention. In the forgery prevention medium of any one of the first to eighth embodiments , the forgery prevention medium is patterned on the same plane. An anti-counterfeit medium characterized by being arranged.

A tenth embodiment of the present invention includes the anti-counterfeit medium according to any one of the first to ninth embodiments , and an adhesive is provided on a surface opposite to the observation surface of the medium. It is a forgery prevention sticker.

An eleventh embodiment of the present invention includes an anti-counterfeit medium according to any one of the first to ninth embodiments , and a support that can be separated by separating the anti-counterfeit medium is provided on the observation surface of the anti-counterfeit medium. A forgery-preventing transfer foil, which is provided so as to be in contact with each other, and is provided with an adhesive layer on a surface opposite to the support.

In the twelfth embodiment of the present invention, any one of the anti-counterfeit media of the first to ninth embodiments , the anti-counterfeit sticker of the tenth embodiment , or the anti-counterfeit transfer foil of the eleventh embodiment is transferred to an article. Verification method for judging the authenticity of an article by visually observing one or more types of circularly polarized latent images by observing the observation surface through a circularly polarizing filter and confirming the presence or absence of the latent images. It is.

  As described above, according to the anti-counterfeit medium of the present invention, the polarization color shift layer, the absorption layer, and the reflection layer are inclined from the surface of the medium by the shaping layer, so that a color different from that of the normal polarization color shift layer is obtained. Since it shows a change, it is possible to develop different colors in a pattern on the same plane, and the reflected light in a specific direction of one part reflects circularly polarized light opposite to the other part. When observing through a polarizing film, it is possible to judge at a glance that it is true when a characteristic color development or color change can be observed, and that it is non-authentic when it cannot be observed due to the effect of developing a circularly polarized latent image. In addition, it is possible to determine that an object that has a similar visual effect but does not have a circularly polarized latent image by a circularly polarizing filter is not authentic, and an object that can be observed is authentic.

It is sectional drawing of the forgery prevention medium which illustrated the layer structure. It is sectional drawing of the forgery prevention medium explaining the effect by a multiple observation viewpoint. It is sectional drawing of the forgery prevention medium in which the polarization color shift layer was formed only in the structure bottom part. It is sectional drawing of the forgery prevention medium in which the polarization color shift layer was formed only in the structure top part. It is sectional drawing of the forgery prevention medium in which the angle | corner which a structure bottom part makes is 90 degree | times. It is a forgery prevention medium bird's-eye view explaining the viewpoint from which an effect differs. It is an overhead view of an orthogonal type T character pattern forgery prevention medium. It is a bird's-eye view of an orthogonal T character pattern forgery prevention medium. It is an overhead view of the T character pattern forgery prevention medium which changed the angle gradually. It is sectional drawing of the saw-type reflective medium with a reflective layer which illustrated the layer structure. It is sectional drawing of the saw-type reflective medium with a reflecting layer explaining the effect by a multiple observation viewpoint. It is sectional drawing of the saw-type reflective medium with a reflective layer explaining the effect from the viewpoint J. It is sectional drawing of the saw-type reflective medium with a reflective layer explaining the effect from the viewpoint K. It is sectional drawing of the saw-type reflective medium with a reflecting layer explaining the effect from the viewpoint L. It is sectional drawing of the saw-type reflective medium with a reflective layer explaining the effect between each observation viewpoint. It is a bird's-eye view of the saw-type reflective medium with a reflective layer explaining the viewpoint from which an effect differs. It is an overhead view with a latent image of the latent image medium which has a T character pattern latent image. It is sectional drawing of the latent image medium which has a T character pattern latent image. It is an overhead view with a latent image of a two-image latent image medium having two types of latent images. It is sectional drawing explaining the production method of the medium which has a reflection layer. It is sectional drawing which illustrates the layer structure of the medium from which an observation viewpoint becomes from the shaping layer side. FIG. 6 is a cross-sectional view of a medium showing another method for forming a layer of the medium.

  FIG. 1 shows an example of a layer structure of an anti-counterfeit medium 10 according to the present invention, which includes a polarization color shift layer 101, an absorption layer 102, and a shaping layer 103 as the minimum constituent elements. An absorption layer 102 is formed on the back side of the polarization color shift layer 101 when viewed from the viewing direction. The polarization color shift layer 101 is formed on the shaping layer 103 that also serves as a base material via the absorption layer 102. Since the polarization color shift layer 101 is inclined as viewed from the direction of observing the medium, the upper surface portion of the shaping layer 103 on which the polarization color shift layer 101 is disposed is on the surface of the shaping layer 103 (or the back surface of the medium). In contrast, it has an inclination. Further, the polarization color shift layer 101 is arranged in an inclined state with an angle of less than 45 degrees with respect to the front surface (or the medium back surface) of the shaping layer 103. That is, in FIG. 1, a steep wall having an angle of 90 degrees formed from the medium surface and a gently inclined surface having an angle of 45 degrees formed from the medium surface are adjacent to each other.

  The polarization color shift layer 101 changes its color depending on the viewing angle and reflects right-handed or left-handed circularly polarized light. The polarization color shift layer 101 is ideally formed using cholesteric liquid crystal, but even if a reflective polarizing plate, a retardation layer, a multilayer film, or the like can be used, the same effect can be obtained. Good.

  When a cholesteric liquid crystal is used for the polarization color shift layer 101, the helical molecular structure of the cholesteric liquid crystal periodically changes the refractive index of light along the helical axis. Since the light of the corresponding wavelength is selectively reflected, a color shift effect in which the color changes depending on the viewing angle is produced, and the reflected light becomes right-handed circularly polarized light or left-handed circularly polarized light. The pitch of the twisted structure of the cholesteric liquid crystal can be controlled by the amount of the chiral agent added to the cholesteric liquid crystal. Therefore, a desired reflection color can be created.

  The absorption layer 102 is a black layer that uniformly absorbs at least visible light wavelengths. This is a layer for making the reflected light more prominent by absorbing the component transmitted through the polarization color shift layer 101 and making the so-called cholesteric color more colored. Therefore, the absorption layer 102 is disposed on the back side of the polarization color shift layer 101 in principle when viewed from the observation direction.

  The shaping layer 103 is a layer or a substrate for giving the polarization color shift layer 101 an inclination when viewed from the observation direction. As the shaping layer 103, a plastic material may be used, or a fibrous material such as paper may be used. In particular, when the shaping layer 103 is transparent, it is possible to observe not only from the polarization color shift layer 101 side but also from the shaping layer 103 side.

  In the anti-counterfeit medium 10 shown in the cross-sectional view of FIG. 1, a shaping layer 103, an absorption layer 102, and a polarization color shift layer 101 are laminated in this order. The shaping layer 103 also serves as a base material for the anti-counterfeit medium 10, but the cross-sectional shape of the base material of the anti-counterfeit medium 10 is a saw shape. The anti-counterfeit medium 10 is created by pressing a saw-shaped mold (not shown) from the polarizing color shift layer 101 side of the medium in which the shaping layer 103, the absorbing layer 102, and the polarizing color shift layer 101 are laminated in this order. be able to. Moreover, you may heat the metal mold | die as needed.

  Here, when a cholesteric liquid crystal having an acrylate terminal is used as a material of the polarization color shift layer 101, liquid crystal molecules are aligned, and then cured by irradiation with ultraviolet rays from a UV (ultraviolet) lamp. When the mold is pressed, the polarization color shift layer 101 is cut off because the surface area is increased, and as shown in FIG. 1, it does not remain on the wall surface perpendicular to the bottom surface of the shaping layer 103, but increases on the inclined surface side. Part will remain.

  Since the polarization color shift layer 101 formed in this way is already at an angle when observed from the front of the medium, it is shorter than the reflected light when the polarization color shift layer 101 is observed alone from the front. The reflected light of the wavelength can be observed.

  Further, when the medium is tilted and the angle of the tilted polarized color shift layer 101 is observed from the front side, the same color as the reflected light when the polarized color shift layer 101 is observed from the front alone, that is, observed from the front of the medium. Observe the color of the longer wavelength than the reflected light that can be observed, and the observer will observe a different color shift phenomenon that changes from short wavelength to long wavelength by tilting. .

  The saw shape is a state in which the cross-sectional shape of the medium is as shown in FIG. 1, and more specifically, a steep wall with an angle of 90 degrees from the medium surface and the medium surface. This is a state where the inclinations of 45 degrees are adjacent to each other. However, the angle formed by the wall from the medium surface may be less than 90 degrees in processing. In this case, the angle formed by the inclined medium surface is made steeper than 45 degrees. Further, it is important that the angle formed by the concave and convex valleys created by these wall surfaces and the inclined surface is 45 degrees.

  However, in reality, when the medium as shown in FIG. 1 is observed from the front, the reflected light is very dark unless the relationship between the incident light and the angle of the reflected light to be observed is adjusted correctly. There is a drawback that it is difficult to observe a simple color.

  Therefore, as shown in FIG. 2, the cross-sectional shape of the medium is an isosceles triangle whose apex is a valley or a mountain, and the angle formed by adjacent slopes or the angle formed from the medium surface has an inclination of 45 degrees Structure. The angle formed by the slope from the medium surface is 45 degrees.

  With this concavo-convex structure, as seen from the A viewpoint 201 shown in FIG. 2, the observation from the front of the medium is caused by two reflections by a pair of adjacent polarized color shift layers 101, thereby observing with extremely bright reflected light. Is possible. In addition, the angle formed by the valley portions of the adjacent inclined surfaces is 90 degrees, but here, 90 degrees when the angle formed from the medium surface of the inclined surface is 90 degrees is a case where the above function is achieved. It may be about 90 degrees including, and is not limited to 90 degrees in a strict sense.

  Further, at the B viewpoint 202 and the C viewpoint 203 when the medium 10 is tilted, the reflected light from the polarization color shift layer 101 has a longer wavelength than the A viewpoint 201 and observes a behavior different from that of a normal cholesteric color. It will be.

  When the medium 10 having this structure is formed by a method of pressing a mold as in the case described with reference to FIG. 1, it is not exactly as shown in FIG. 2, but as shown in FIG. 3 and FIG. The color shift layer 101 tends to remain in only a part of the inclination.

  However, the remaining shape of the polarization color shift layer 101 is left only in the valley portion of the structure as shown in FIG. 3 or only in the mountain portion of the structure as shown in FIG. As shown in FIGS. 3 and 4, the light reflection trajectory is basically the same as that in FIG. 2, and the observation angle is oblique from the front of the medium 10. When tilted toward, a color shift phenomenon from the short wavelength side to the long wavelength side can be confirmed.

  2, 3, and 4, the phenomenon of reflecting the short wavelength color at the time of observation from the front of the medium 10 by causing reflection twice by the polarization color shift layer 101 is the structure of the structure. If the angle formed by the inclined surfaces at both ends constituting the valley portion is 90 degrees, it can be expressed. Therefore, if the inclined surfaces on both sides constituting the valley portion of the structure at the A viewpoint 201 as shown in FIG. 5 are both 45 degrees from the surface of the medium 10, the angle formed by both inclined surfaces is 90 degrees. A short wavelength color develops when observed from the front.

  If the inclined surfaces on both sides constituting the valley portion of the structure at the D viewpoint 501 are 30 degrees and 60 degrees, the angle formed by both inclinations is 90 degrees, and a short wavelength color appears when the angle is 15 degrees from the front of the medium. . Further, if the inclinations on both sides constituting the valley portion of the structure at the E viewpoint 502 are 15 degrees and 75 degrees, a short wavelength color appears when the inclination is inclined 30 degrees from the front of the medium.

  Until now, the color change depending on the observation angle has been described using only the cross-sectional views, but different colors appear depending on the direction of observing the medium.

FIG. 6 is a bird's-eye view of the medium 10 having a structure in which the cross-sectional shape of FIG. 2 is extended in a uniaxial direction. In this case, the viewpoint F601 corresponds to the A viewpoint 201 in FIG. 2, and the viewpoint G602 and the viewpoint H603 correspond to the B viewpoint 202 and the C viewpoint 203 in FIG. 2, respectively. The viewpoint I604 is a line of sight as seen from the back in FIG. At this viewpoint I604, even if the angle from the front of the medium is steep, a color shift to the long wavelength side does not occur, and the original color change of the cholesteric can be observed. Therefore, the viewpoint I604 observes a shorter wavelength color than the viewpoint F601. For example, when a cholesteric liquid crystal that reflects red when viewed from the front and green when viewed from an oblique direction is used as the polarization color shift layer 101, yellow is used for the viewpoint F601, red is used for the viewpoint G602 and the viewpoint H603, and the viewpoint I604 is used. The green color can be observed.

  From these facts, it is possible to create a pattern by arranging the structure as shown in FIG. 6 as one cell and arranging it in the plane while partially rotating the direction by 90 degrees. For example, in FIG. 7, a portion 701 in which the structure of the square medium is horizontally oriented is formed to be a “T” character, and the other peripheral portions 702 are 90 degrees different from the “T” character. It is arranged vertically. When this medium is observed from the front of the medium serving as the viewpoint F601, although it depends on the light source, in principle, it can be confirmed as a short wavelength color having the same color as a whole.

  Further, FIG. 8 is a bird's-eye view of the medium of FIG. 7 tilted and observed from an oblique direction. The portion 701 whose structure is horizontal can observe a long wavelength color, and the surrounding portion 702 is observed from the viewpoint F601 which is the front of the medium. As a result, a shorter wavelength color can be confirmed. By tilting the medium in this way, the color difference between the portion 701 where the structure is oriented horizontally and the peripheral portion 702 is increased, and the pattern can be visually recognized more clearly. Of course, when the medium is rotated 90 degrees, the colors are reversed.

  In FIG. 9, the portion 701 in which the structure is horizontal is arranged so as to be a “T” character, and the other portions are arranged by changing the angle little by little by using the structure as shown in FIG. 6 as one cell. The portion other than the portion 701 where the structure is horizontally oriented gradually changes in color from a short wavelength to a long wavelength as it spreads from the center to the left and right. Further, it can be observed that the color gradually changes by rotating the medium.

  In the medium described so far, the inclined surface portion is entirely composed only of the polarization color shift layer 101 and the absorption layer 102, and the circle reflected by the polarization color shift layer 101 is observed from any angle. Polarization is in the same direction. For this reason, when observing through a circularly polarizing filter that transmits circularly polarized light in the direction opposite to the reflected light, the entire medium looks black and when viewed through a circularly polarizing filter that transmits circularly polarized light in the same direction as the reflected light, The same hue as when there is no filter can be observed.

  FIG. 10 shows a sectional view of the saw-type reflective medium 11 in which the wall portion of the structure of FIG. 1 is a reflective layer 111 like a mirror. Here, in particular, the angle formed by the inclined medium surface is 45 degrees, and the angle formed by the wall portion from the medium surface is 90 degrees.

  The behavior of light reflection at each viewpoint of such a medium is as shown in FIG. First, a viewpoint J121 in FIG. 11 is a viewpoint in which the medium surface is viewed from a position perpendicular to the medium surface. Here, as shown in FIG. 12, the light emitted from the light source 224 becomes incident light 225 incident on the polarization color shift layer 101 of the inclined portion at an angle of 45 degrees. Only the circularly polarized light having a specific wavelength is reflected. Here, circularly polarized light having a shorter wavelength is reflected. The reflected light 226 is incident on the reflecting layer 111 perpendicularly and reflected. At this time, the phase is inverted by 180 degrees.

  If the polarization color shift layer 101 here reflects right-handed polarized light, the reverse reflection light 227 reflected by the reflective layer 111 is left-handed polarized light. Thus, the circularly polarized light whose rotation direction is reversed is incident again on the polarization color shift layer 101 at an angle of 45 degrees. However, since the rotation direction is reversed, the circular polarization light is transmitted through the polarization color shift layer 101 and absorbed by the absorption layer 102. Therefore, it becomes almost black.

  However, since slight reflection occurs on the surface of the polarization color shift layer 101, the light is very weak light, but is circularly polarized light opposite to that reflected by the polarization color shift layer 101, and the wavelength component is relatively low. The light on the short wavelength side is radiated in the direction perpendicular to the medium surface as the minute reflected light 228.

  A viewpoint K122 in FIG. 11 is a viewpoint in which the reflective layer 111 on the wall of the saw-shaped structure is viewed from an angle of 45 degrees formed from the medium surface. Here, as shown in FIG. 13, the light emitted from the light source 224 first becomes incident light 231 incident on the reflective layer 111 at an angle of 45 degrees. The reflected light 232 reflected here enters the polarization color shift layer 101 perpendicularly.

  Next, the circularly polarized light 233 having a specific wavelength reflected perpendicularly from the polarization color shift layer 101 is incident on the reflection layer 111 again at an angle of 45 degrees and is reflected in the direction of an angle of 45 degrees formed from the medium surface. Is inverted by 180 degrees, so that the polarized color shift layer 101 becomes circularly polarized light and reversed circularly polarized light 234 opposite to the reflected light. Here, the wavelength of the reversed circularly polarized light 234 finally extracted is light on a relatively long wavelength side.

  A viewpoint L123 in FIG. 11 is a viewpoint when viewing the polarization color shift layer 101 inclined from an angle of 45 degrees formed from the medium surface. As shown in FIG. 14, this is an extremely simple vertical reflection of the polarization color shift layer 101, and the light emitted from the light source 224 is perpendicularly incident on the polarization color shift layer 101 as incident light 241. This light is reflected as reflected light 242 in the vertical direction. At this time, the reflected light 242 is circularly polarized light, and the rotational direction of the circularly polarized light is circularly polarized light in the direction reflected by the normal polarization color shift layer 101.

  These three viewpoints shown in FIG. 11 appear to be mixed depending on the viewing angle. Specifically, the viewpoint K122 is seen in the α section 131 in FIG. 15 where the angle formed from the medium surface is 45 degrees or less and the reflective layer 111 on the saw-shaped structure wall is viewed.

  Next, in the β section 132 in which the angle formed from the medium surface is 45 degrees to 90 degrees and the wall of the saw structure is viewed, the viewpoint K122 and the viewpoint J121 are seen mixed. The smaller the angle formed from the medium surface in this section, the stronger the element of the viewpoint K122, and the larger the angle formed, the stronger the element of the viewpoint J121. That is, the smaller the formed angle, the brighter, and the larger the formed angle, the darker.

  Subsequently, in the γ section 133 in which the angle formed from the medium surface is 90 degrees or less and the polarization color shift layer 101 is inclined, the reflection layer 111 cannot be seen, so the viewpoint L123 is seen. As the angle formed decreases from 90 degrees to 45 degrees, the reflected light shifts from a short wavelength to a long wavelength. When the formed angle becomes 45 degrees or less, the reflected light shifts again from the long wavelength to the short wavelength.

  In addition to the viewpoints J121, K122, and L123 that have been described using the cross-sectional views so far, there is a viewpoint M124 that looks at the near side from the back as shown in FIG. This viewpoint M124 can observe the original color change of the cholesteric like the viewpoint I604. The reflected light at this viewpoint M124 is circularly polarized light, and this circularly polarized light reflects both right-handed and left-handed polarized light.

  The light directly reflected on the polarization color shift layer 101 becomes circularly polarized light in the direction normally reflected by the polarization color shift layer 101, but the light reflected on the reflection layer 111 after being reflected on the polarization color shift layer 101 is polarized. The color shift layer 101 is reversed circularly polarized light in the reverse direction to the normal reflection direction. Both of these lights will be observed almost equally.

  Here, since the viewpoint K122 and the viewpoint L123 are formed at an angle of 90 degrees formed by the reflective layer 111 from the medium surface, the appearance and the color change with respect to the angle are the same, but the turning direction of the reflected circularly polarized light is Since this is reversed, a circularly polarized latent image can be formed by disposing the pattern while partially reversing the direction.

  FIG. 17 is a top view of the latent image medium 12 arranged in a pattern while changing the direction of the saw-shaped reflection medium 11. The latent image portion 301 in which the portion where the inclination of the saw-shaped reflective medium 11 is directed upward in FIG. 17 is arranged in a “T” character pattern and the surrounding portion 302 are inclined downward in FIG.

  FIG. 18 is a cross-sectional view taken along the cutting plane 300 in FIG. 17 and shows a saw-shaped state. Such a latent image medium 12 is a square color shift medium, and the “T” character pattern is very difficult to see and looks like a solid pattern that changes color. There is no difference in color change between the latent image portion 301 and the surrounding portion 302 depending on the observation angle.

  However, since the turning directions of the reflected circularly polarized light are reversed, when the latent image medium 12 is observed through a circularly polarizing filter that shields right-handed or left-handed circularly polarized light, one side is black and the other side is normal. Since it is visible, the “T” character pattern can be viewed as a latent image.

  In FIG. 17, the pattern in which the direction of the saw-shaped latent image medium 11 is rotated by 180 degrees is arranged, but an orthogonal pattern in which the direction is rotated by 90 degrees and 270 degrees may be arranged. The latent image expressed by the 90/270 degree pattern cannot be observed when the latent image expressed by the 0/180 degree pattern is observed. Therefore, it is possible to prepare two types of latent images as shown in FIG.

  FIG. 19 shows a pattern A303 of the saw-shaped reflective medium 11 with the inclination direction oriented in the Y-axis minus direction, the pattern B304 arranged in the “T” character pattern with the inclination direction oriented in the Y-axis plus direction, A two-image latent image medium 13 in which a pattern C305 arranged in an elliptical pattern with the direction directed in the X-axis minus direction and a pattern D306 arranged in a “P” character pattern with the inclination direction directed in the X-axis plus direction are formed. It is.

  When this is observed toward the plus direction of the X axis, it only looks like an ellipse pattern in which the pattern C305 and the pattern D306 are combined as shown in FIG. One reflects long wavelength light and the other reflects short wavelength light. In this state, when observed through a circularly polarizing filter that shields right-handed or left-handed circularly polarized light, the pattern D306 appears as a latent image, but the pattern A303 does not appear.

  When the observation direction is rotated by 90 degrees and observed through the circular polarization filter in the positive direction of the Y axis, the pattern A303 appears this time and the pattern D306 becomes invisible.

  Heretofore, the saw-shaped reflection medium 11 has been exemplified and described with respect to a saw-shaped pattern having inclination angles of 45 degrees and 90 degrees from the medium surface, but the angle between adjacent inclinations is 90 degrees. In the saw-type reflective medium 11, as shown in FIG. 5, which explains that there is a pattern other than 45 degrees from the medium surface if the angle formed between adjacent patterns is maintained at 90 degrees. However, if the angle formed by the adjacent inclinations is 45 degrees, for example, the pattern formed by the 60-degree and 75-degree inclinations adjacent to the medium surface, or the 55-degree and 80-degree inclinations are adjacent. Patterns are also possible.

  Although the angle has been defined by specific numerical values so far, in actual processing, shrinkage due to hot-press embossing of the mold occurs, and the angle slightly blurs, but if there is a slight difference, the present invention The effect of.

  Next, a specific method for creating the present invention will be described. Essential elements constituting the forgery prevention medium 10 are a polarization color shift layer 101, an absorption layer 102, and a shaping layer 103.

  Here, the shaping layer 103 may be a plastic material or a fiber material such as paper, but has a good shaping property by pressing the mold while applying heat as necessary. A material that has a shape and retains the shape after shaping is desirable. Specifically, polyethylene terephthalate, polyethylene naphthalate, polypropylene, polyethylene, polymethyl methacrylate, polystyrene, nylon, polycarbonate, acrylic, triacetyl cellulose, and the like are considered. Since these are particularly transparent, they can also be used in a configuration that is observed from the back side. Preferably, amorphous polyethylene terephthalate, which is amorphous polyethylene terephthalate, can be considered as a material whose elastic modulus decreases at a relatively low temperature.

  The absorption layer 102 needs to absorb at least visible light wavelengths. When forming this, for example, there is a method of forming a film by printing a printing smear ink in which a carbon black pigment is dispersed in a binder such as a polymer resin, by a gravure printing method, a screen printing method, an offset printing method, or the like. . Further, instead of the carbon black pigment, an organic black pigment typified by aniline black, perylene black or the like, or an inorganic black containing chromium, manganese, iron, cobalt, copper, etc., titanium black or the like may be used. Good. At this time, it is preferable that the binder used has good adhesion to the shaping layer 103. Depending on the content of the black pigment, the film thickness is generally from about 0.3 μm to about 30 μm.

  The polarization color shift layer 101 needs to change the wavelength of reflected light depending on the viewing angle, and the reflected light must be circularly polarized. A reflective polarizer such as a wire grid polarizer and a multilayer film may be used, but a cholesteric liquid crystal is preferable because it can be formed in one layer.

  Cholesteric liquid crystals selectively reflect light with a wavelength corresponding to the pitch of the twisted structure because the refractive index of light periodically varies along the helical axis of cholesteric liquid crystals having a helical molecular structure. . Therefore, it is possible to create a desired reflection color by controlling the pitch of the twisted structure. Then, by aligning these cholesteric liquid crystals, the respective molecules are uniformly arranged in layers, and the reflected lights are strengthened to reflect the color light as a whole.

  By disposing a black absorption layer having absorption in the visible light region on the back surface, the transmitted light is absorbed and the reflected light is more emphasized, so that color light called a so-called cholesteric color can be confirmed.

  Since the aligned cholesteric liquid crystal molecules have a helical structure, the reflected light is right-handed circularly polarized light or left-handed circularly polarized light. For this reason, the reflected light can be blocked by placing an appropriate circularly polarizing filter on the cholesteric liquid crystal layer.

The cholesteric liquid crystal can be aligned by forming a layer on the alignment film. That is, it is possible to align by forming an alignment film on the substrate and forming a cholesteric liquid crystal layer on the alignment film. As this alignment film, a film obtained by rubbing a coating film of polyvinyl alcohol or polyimide can be used. Rubbing is possible using, for example, cotton or velvet. Moreover, it can also be made to orient in the direction of the shearing force by apply | coating, applying a shearing force. Or after forming a cholesteric liquid crystal layer, it can also align by applying a shearing force. Further, the formed cholesteric liquid crystal layer can be oriented by irradiating polarized laser light, or applying electrolysis or a magnetic field.
This cholesteric liquid crystal layer is formed by applying a liquid crystal solution in which a liquid crystal substance having a nematic structure or a smectic structure, a chiral substance, a photopolymerizable polyfunctional compound and a polymerization initiator are mixed, and irradiating the coating film with ultraviolet rays. Can be formed. At this time, the chiral material bonds the liquid crystal materials to form the helical structure. Further, the photopolymerizable polyfunctional compounds are polymerized and cured to fix the cholesteric liquid crystal.

  In place of the liquid crystal material and the chiral material, an optical isomer liquid crystal material having an asymmetric carbon atom in the molecule is used, and the optical isomer liquid crystal material, the photopolymerizable polyfunctional compound, and the polymerization initiator are mixed. It is also possible to form a cholesteric liquid crystal layer by coating and irradiating with ultraviolet rays.

  In addition, the liquid crystal solution can be directly applied onto a substrate to form a cholesteric liquid crystal layer, or after forming a cholesteric liquid crystal layer on another support, an adhesive is used to form the substrate. The cholesteric liquid crystal layer may be formed on the substrate by bonding or transferring using a method such as laminating.

  Next, as the photopolymerizable polyfunctional compound, a polymerizable functional group, a polycondensable functional group, or a monomer or oligomer having two or more functional groups effective for polyaddition in the molecule can be used.

  In addition to this photopolymerizable polyfunctional compound, a monofunctional monomer or oligomer can be used in combination. Examples of the radical photopolymerizable polyfunctional monomer include trimethylolpropane triacrylate, 1,6-hexanediol diacrylate, pentaerythritol tetraacrylate, pentaerythritol triacrylate, dipentaerythritol hexaacrylate, and the like.

  Examples of the radical photopolymerizable polyfunctional oligomer include polyurethane polyacrylate, epoxy resin polyacrylate, acrylic polyol polyacrylate, and the like.

  Examples of the radical photopolymerizable monofunctional monomer include alkyl (C1 to C18) (meth) acrylate, benzyl (meth) acrylate, cyclohexyl (meth) acrylate, alkylene (C2 to C4) glycol (meth) acrylate, In alkoxy (C1-C10) alkyl (C2-C4) (meth) acrylate, polyalkylene (C2-C4) glycol (meth) acrylate, alkoxy (C2-C10) polyalkylene (C2-C4) glycol (meth) acrylate, etc. Can be mentioned.

  Moreover, an aromatic epoxy compound, an alicyclic epoxy compound, and a glycidyl ester compound can be used.

  A three-dimensional cross-linkable liquid crystal polyorganosiloxane can also be used.

  Subsequently, as the polymerization initiator, a radical photopolymerization initiator or a cationic photopolymerization initiator can be used. In addition to these photopolymerization initiators, a sensitizer and a peroxide can be used in combination. As the radical photopolymerization initiator, known ones such as acetophenone series such as α-hydroxyacetophenone series and α-aminoacetophenone series, benzoin ether series, benzyl ketal series, α-dicarbonyl series, α-acyl oxime ester series, etc. Specifically, α-aminoacetophenone, acetophenone diethyl ketal, benzyldimethyl ketal, α-hydroxycyclohexyl phenyl ketone, 2-hydroxy-2-methylphenylpropanone, benzophenone, Michler's ketone, isopropylthioxanthone, benzophenone and N-methyl The combined use with diethanolamine etc. are mentioned.

  Conventionally known cationic photopolymerization initiators can be used without particular limitation, and more preferably, known cationic sensitizers and peroxides can be used in combination as appropriate. For example, allyl iodonium salt-α-hydroxyacetophenone, triallylsulfonium salt, metallocene compound-peroxide combined system, metallocene compound-thioxanthone combined system, metallocene compound-anthracene combined system, and the like.

And as a coating apparatus utilized when apply | coating the liquid crystal solution which mixed these liquid crystal substance, a chiral substance, a photopolymerizable polyfunctional compound, and a polymerization initiator, a comma coater, a micro gravure coater offset, etc. can be used. The thickness may be 0.5 to 20 μm. Preferably it is 2-10 micrometers.

  The cholesteric liquid crystal formed in this way may be directly formed on the absorption layer 102 as long as it can be formed by direct alignment on the absorption layer 102 and can obtain an adhesive force. When difficult, after forming on another base material, after laminating | stacking on the absorption layer 102 on both sides of an adhesive agent, you may form by peeling another base material.

  The anti-counterfeit medium 10 can be formed by pressing a mold from the polarization color shift layer 101 side of the polarization color shift layer 101, the absorption layer 102, and the shaping layer 103 thus formed. When the mold is heated as necessary, the formability may be improved. The pressure can be about 10 to 300 kgf / cm ^ 2.

  The layers may be laminated in the order of the shaping layer 103, the absorption layer 102, and the polarization color shift layer 101 as described above, or the shaping layer 103, the polarization color shift layer 101, and the absorption layer 102. May be laminated in the order of. In the latter case, the shaping layer 103 is required to be transparent and have no phase difference, and the observation is performed from the shaping layer 103 side.

  The stacking order may be the absorption layer 102, the shaping layer 103, and the polarization color shift layer 101. In this case, as shown in FIGS. 5, 12, and 13, in the configuration using two or more reflections, the effect of the absorption layer 102 is weakened, and the color development of the cholesteric color is deteriorated. Therefore, the absorbing layer 102 and the polarization color shift layer 101 are preferably provided in contact with each other as much as possible.

  The saw-type reflection medium 11 is a medium in which a part of the forgery prevention medium 10 is a reflection layer.

  As a method for partially providing the reflective layer, a method in which a metal is obliquely vacuum-deposited after the anti-counterfeit medium 10 is formed is considered. In a vacuum with a high degree of vacuum and a sufficient mean free process, the straightness of molecules during vapor deposition can be improved.

  As for the type of metal, aluminum, silver, nickel, iron, cobalt, zinc, titanium, manganese, platinum, palladium, lead, copper, gold, or alloys thereof, and refraction typified by magnesium fluoride and zinc sulfide. Multi-layer deposition of materials with different rates can be considered, but as a material with high processing suitability, economical efficiency, high reflectivity, and metallic luster with no wavelength selectivity for reflected light, deposition of aluminum alone is possible. preferable.

  As another method, as shown in FIG. 21, the reflection layer 311 is patterned on the polarization color shift layer 101 of the forgery prevention medium 10 in which the shaping layer 103, the absorption layer 102, and the polarization color shift layer 101 are laminated. A method may be considered in which a reflective portion is partially provided by forming and pressing the mold 312 in alignment with the pattern. In this case, the material of the reflective layer 311 may be aluminum paste ink or silver paste ink in which fine aluminum pieces or fine silver pieces are dispersed in a binder. As the binder, a material having high elasticity that is easily stretched by heat pressure is suitable. This ink is patterned by a gravure printing method, an offset printing method, a silk screen printing method, or the like.

  As another method, as shown in FIG. 22, a transparent material is used for the shaping layer 103, and the anti-counterfeit medium 10 in which the shaping layer 103, the polarization color shift layer 101, and the absorption layer 102 are laminated in this order is used. After forming the structure by pressing the mold from the 102 side, the reflective color layer 313 is formed with a film thickness sufficient to fill the structure, so that when viewed from the shaping layer 103 side, the polarization color shift layer 101 and the absorption layer A portion without 102 can be observed as the reflective layer 313.

  As a material for the reflective layer 313, like the above-described reflective layer 311, a metal paste ink in which fine metallic pieces having a metallic luster are dispersed as a pigment in a binder is desirable. Since elasticity is unnecessary, various binders such as an oxidation polymerization type, a two-component curing type, a thermosetting type, and a UV curing type can be used.

  In addition, as a layer forming method, printing methods such as micro gravure coating, direct gravure coating, offset coating, flexographic coating, silk screen coating, and die coating can be considered. In addition to the printing method, a thin film may be formed on the entire surface by a dry coating method such as a vacuum deposition method, a sputtering method, or an ion plating method, or a method such as wet plating using a solution in which a metal is dissolved is also considered. It is done.

A protective layer may be provided on the structure. By doing so, it is possible not only to suppress the structural destruction due to scratching and the disappearance of the effect accompanying it, but also to suppress the copying of the structure due to transfer. When it is provided on the observation surface side, the material needs to be transparent and have no phase difference. A method of coating, drying and curing a transparent binder using a printing method,
A method of laminating an unstretched film is conceivable. When the structural surface is on the side opposite to the observation surface, it does not have to be a transparent material.

In the case of the configuration shown in FIG. 22, the reflective layer 311 also serves as the protective layer referred to here.
The observation surfaces of the tenth and eleventh embodiments of the present invention indicate the same surfaces as the observation surfaces described here.

  In the present invention described so far, in principle, the side where the polarization color shift layer 101 can be seen is the front side, and the opposite side of the absorption layer 102 is the back side. Actually, an adhesive is formed on the back surface to make a sticker or transfer foil, and this adhesive is used by sticking it on an article to be prevented from forgery.

  When determining the authenticity, the determination is performed by observing a desired color change or confirming whether a latent image appears by using a circular polarization filter.

  In the case of a sticker configuration, an adhesive is used as the adhesive on the back surface, and a release paper such as a silicon separator is attached.

  Examples of the pressure-sensitive adhesive include vinyl chloride-vinyl acetate copolymer, polyester-based polyamide, acrylic-based, butyl rubber-based, natural rubber-based, silicon-based, polyisobutyl-based pressure-sensitive adhesive alone, alkyl methacrylate, vinyl ester, Aggregating components such as acrylonitrile, styrene, vinyl monomers, unsaturated carboxylic acids, hydroxy group-containing monomers, modifying components such as acrylonitrile, polymerization initiators, plasticizers, curing agents, curing accelerators, antioxidants What added the additive of these etc. as needed can be used. For the formation, a gravure printing method, an offset printing method, a screen printing method, or the like can be used. Moreover, you may provide so that it may stick together by roll lamination using the adhesive member in which both surfaces were comprised with the film separator.

  In the case of the transfer foil configuration, a peeling support substrate is required. However, in the configuration of FIG. 21, for example, the shaping layer 103 can also be used as the peeling support substrate to obtain a transfer foil.

  The polarizing color shift layer 101 is formed on the shaping layer 103. At this time, the shaping layer 103 that is not sufficiently adhered to the polarizing color shift layer 101 is used.

  For example, when a UV curable cholesteric liquid crystal having an acrylate end is used for the polarization color shift layer 101, the shaping layer 103 may be stretched polyethylene terephthalate.

  Subsequently, after forming the absorption layer 102 and providing a structure using a mold, a reflective layer 313 is formed, and an adhesive is further applied by a printing method or the like.

  The transfer foil prepared in this manner is stacked so that the adhesive is in contact with a transfer medium such as paper, and after applying heat pressure from the shaping layer 103 side, the shaping layer 103 that also serves as a peeling support substrate is peeled off. The transfer is performed.

  Note that the adhesive on the back surface has a small tack. The material varies depending on the object to be applied, but for example, when transferring to paper, for example, aliphatic hydrocarbon resin, alicyclic hydrocarbon resin, aromatic hydrocarbon resin, α-pinene and / or β -Hot melt adhesives such as terpene resin, rosin resin, hydrogenated rosin resin, styrene resin, coumarone / indene resin, etc., containing pinene as a component, with addition of carnauba wax as required Use.

  When affixing, for example, heat and pressure of about 120 to 180 degrees are applied.

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes designs and the like that do not depart from the spirit of the present invention.

  Examples of the present invention will be described below.

  A stretched polyethylene naphthalate film with a thickness of 16 μm is coated with a wire bar using a cholesteric ink having the following composition, adjusted to a thickness of 3 μm after drying and curing, and dried at 80 ° C. for 1 minute. After that, the polarizing color shift layer 101 was obtained by irradiating with 500 mJ with a high pressure mercury lamp and curing.

<Cholesteric ink composition>
Nematic liquid crystal (Paliocolor LC242) [manufactured by BASF] 30 parts by weight Chiral agent (Paliocolor LC756) [manufactured by BASF] 1.5 parts by weight Polymerization initiator (Irgacure 184) [manufactured by BASF] 1.5 parts by weight Solvent (Methyl ethyl ketone) 67 parts by weight Subsequently, a 30 μm-thick amorphous polyethylene terephthalate film was applied with a wire bar using a laminate ink having the following composition, adjusted to have a film thickness after drying and curing of 3 μm. Then, after drying at 50 ° C. for 3 minutes, using a pressure of 50 kgf / cm ² and a temperature of 100 ° C., the laminate layer and the polarizing color shift layer 101 were laminated at 24 ° C. at 24 ° C. After performing time aging, the stretched polyethylene naphthalate film was peeled off.

<Laminate ink composition>
Polyol (Takelac A977) [Mitsui Chemicals Co., Ltd.] 27 parts by weight Isocyanate (Takenate A92) [Mitsui Chemicals Co., Ltd.] 3 parts by weight Solvent (ethyl acetate) 70 parts by weight Subsequently, the polarizing color shift layer 101 was subjected to the following composition. About the resulting Sumi ink, what was adjusted so that the film thickness after drying and curing would be 3 μm was applied using a wire bar and dried at 50 ° C. for 3 minutes.

<Sumi ink composition>
NEWLP Super R92 Black [Toyo Ink Manufacturing Co., Ltd.] 90 parts by weight NEWLP Super Curing Agent [Toyo Ink Manufacturing Co., Ltd.] 10 parts by weight Subsequently, the mold heated to 130 ° C. was pressured 250 kgf / cm ^2.
The structure was formed by pressing for 1 second. The mold has a saw-tooth shape with a cross-sectional shape of a right triangle and angles of inclination of 45 degrees and 90 degrees, and the length of the inclination is 50 μm.

  The saw shape is partially different in direction, and has a pattern shape as shown in FIG.

  When the two-image latent image medium 13 obtained by forming 1000 angstroms of aluminum on the structure surface by sputtering using nitrogen was observed, the color was partially changed by tilting the medium, and 90 ° The color was reversed every time it was rotated. Further, when the same observation was performed using a circular polarizing filter, the effect that two different types of latent images appeared and disappeared each time the image was rotated 90 degrees was confirmed.

The anti-counterfeit medium of the present invention is affixed to various certificates such as banknotes, bonds, gift certificates, checks, securities, credit cards, ID cards, official documents, important documents, or various products and their packaging materials, By being transcribed, it is possible to ensure that the product is authentic. Other you can see the effect of the pattern color change seemingly, the only person latent image with a limited by circular polarizing filter, know the existence, by confirming it to spot a counterfeit product even if it is forged by the present invention Will be able to.

DESCRIPTION OF SYMBOLS 10 ... Anti-counterfeit medium 101 ... Polarization color shift layer 102 ... Absorption layer 103 ... Shape-forming layer 201 ... A viewpoint 202 ... B viewpoint 203 ... C viewpoint 501 ... D viewpoint 502 ... E viewpoint 601 ... viewpoint F
602 ... Viewpoint G
603 .. Viewpoint H
604 ... Viewpoint I
Reference numeral 701: A portion where the structure is horizontally oriented 702: A peripheral portion 901: A portion arranged while changing the angle little by little 11: A saw-shaped latent image medium 111 ... A reflective layer 121 ... A viewpoint J
122 ... viewpoint K
123 ... viewpoint L
124 ... Viewpoint M
224 ... Light source 225 ... Incident light 226 ... Reflected light 227 ... Reverse reflected light 228 ... Minute reflected light 231 ... Incident light 232 ... Reflected light 233 ... Circularly polarized light 234 ... Reverse circularly polarized light 241 ... Incident light 242 ... Reflected light 131 ... α section 132 ... β section 133 ... γ section 12 ... Latent image medium 301 ... Latent image portion 302 ... Surrounding part 13 ... Two-image latent image medium 303 ... Pattern A
304 ... Pattern B
305 ... Pattern C
306 ... Pattern D
311 ... Reflective layer 312 ... Mold 313 ... Reflective layer

Claims (9)

A polarized color shift layer that produces a color shift effect in which the reflected color changes depending on the viewing angle;
An absorption layer that absorbs at least visible light wavelengths transmitted through the polarization color shift layer;
A shaping layer having an angle of 45 degrees between the inclined surface on which the polarizing color shift layer is disposed and a surface adjacent to the inclined surface;
An anti-counterfeit medium, comprising: a reflective layer provided on a surface adjacent to an inclined surface on which the polarization color shift layer is disposed . In the anti-counterfeit medium according to claim 1 ,
An anti-counterfeit medium characterized in that an angle formed between the inclined surface and the surface of the medium is 45 degrees, and an angle formed between a surface adjacent to the inclined surface and the surface of the medium is 90 degrees. In the anti-counterfeit medium according to claim 2 ,
An anti-counterfeit medium, wherein a polarizing color shift layer is provided on a surface having a smaller angle with the surface of the medium, and a reflective layer is provided on a surface having a larger angle with the surface of the medium. In the anti-counterfeit medium according to any one of claims 1 to 3 ,
The anti-counterfeit medium, wherein the polarization color shift layer is provided only on a surface inclined with respect to the surface of the medium. In the anti-counterfeit medium according to any one of claims 1 to 4 ,
The anti-counterfeit medium, wherein the polarization color shift layer is a cholesteric liquid crystal. In the anti-counterfeit medium according to any one of claims 1 to 5 ,
An anti-counterfeit medium, wherein the anti-counterfeit medium is arranged in a pattern on the same plane. An anti-counterfeit sticker comprising the anti-counterfeit medium according to any one of claims 1 to 6 , wherein an adhesive is provided on a surface opposite to the observation surface of the medium. A support that includes the anti-counterfeit medium according to any one of claims 1 to 6 and that can be separated by separating the anti-counterfeit medium so as to be in contact with an observation surface of the anti-counterfeit medium. An anti-counterfeit transfer foil characterized in that an adhesive layer is provided on the surface opposite to the body. The medium for preventing forgery according to claims 1 to claim 6, of the article in a state where the transfer of the one in the article of forgery-preventing transfer foil according to anti-counterfeit sticker or claim 8 according to claim 7, circularly polarized light A verification method in which one or more kinds of circularly polarized latent images are visually recognized by observing an observation surface through a filter, and the authenticity of the article is determined by checking the presence or absence of the latent images.

Images