JPH07329469A - Forgery prevention sheet - Google Patents

Abstract

PURPOSE:To prevent a structure having the same area and shape as an authentication structure from being formed from a used forgery prevention sheet, by a method in which, in the case a section whose area and shape are substantially the same as those of a formation predetermined section is specified from a non-formation predetermined section, the structure of the specified non-formation predetermined section is made different from the structure of the formation predetermined section. CONSTITUTION:In a part corresponding to the formation predetermined section 12 of an authentication structure formation layer 14, a mosaic-like relief- diffraction-grating with lines in different directions or at different intervals is formed as an authentication structure. In a non-formation predetermined section 13, a light-scattering structure obtained by a mat processing, etc., is formed; however, the reflecting layer 15 of the part 19 corresponding to the letters 'VOID' is removed. In the relief of the part from which the reflecting layer 15 is removed, a bonding layer 16 made of a material having the same refractive power as the material of the authentication structure formation layer 14 is embedded. Because it is very difficult to remove the bonding layer 16 and reproduce the relief, this is very useful to prevent forgery.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a forgery prevention sheet having an authentication structure provided to prevent forgery of cash vouchers, securities, cards and other documents.

[0002]

2. Description of the Related Art In recent years, copying performance has been remarkably improved by color copying of copying machines. The copy is of high quality and almost invisible to the naked eye as compared with the original of the copy. Along with this, banknotes, cash vouchers, etc. are being copied and used more fraudulently. In order to prevent such forgery, various anti-counterfeiting methods have been conventionally proposed.

For example, there is one disclosed in Japanese Patent Laid-Open No. 59-88780. This is one in which a light diffraction pattern such as a hologram or a diffraction grating is provided on the surface of an important document. Holograms and diffraction gratings cannot be copied by general copiers, and can only be created using a dedicated expensive machine.In addition, the optical diffraction pattern already provided on important documents can be peeled off to create other documents. Even if it is attempted to replace it, it is difficult to replace it because the light diffraction pattern itself is too thin to support itself. Therefore, since it is difficult to obtain a light diffraction pattern having a predetermined image to be attached to the surface of the important document, the authenticity of the important document provided with the light diffraction pattern is guaranteed.

There is also one disclosed in JP-A-61-272772. This is a transparent layer having a refractive index different from that of the material of the relief layer, instead of the conventional opaque reflecting layer made of a simple metal such as aluminum instead of the reflection layer provided on the relief surface such as a hologram or a diffraction grating. The metal compound is provided as a reflective layer. By making the reflective layer transparent, the display section can be provided below the hologram or diffraction grating, and the display section can be provided as described above.
For the same reason as in the case of 9-88780, the authenticity of the important document can be assured, and the rewriting of the display portion is made difficult, so that the forgery and alteration of the important document can be prevented.

[0005]

As described in the above two examples,
When forming holograms or diffraction gratings on important documents,
As a general method, there are a case of hot stamping using a transfer sheet and a case of labeler using a label. Here, a process of transferring the hologram area 8 transferred from the transfer sheet 1 to the card 2 will be described with reference to FIG. The unused transfer sheet 1 supplied from the supply roll 4 passes through the roll 6 and the roll 7, and the used transfer sheet is wound around the winding roll 5. When the area 8 is between the roll 6 and the roll 7,
The area 8 is heated and pressed by the thermal iron 3 to activate the adhesive layer and transferred to the card 2. Roll 6 and roll 7
Is a set of rolls for making the transfer sheet 1 and the card 2 in close contact with each other and applying a tension required for the transfer to the transfer sheet 1. The transfer sheet 1 and the card 2 are transferred in the direction of the arrow, and if the transfer speeds of the transfer sheet 1 and the card 2 are different, air is not transferred during transfer due to a decrease in adhesion between the transfer sheet 1 and the card 2. The transfer sheet 1 and the card 2 are transported at the same speed because scratches are generated on the surface of the card 2 due to entanglement and rubbing between the surface of the transfer sheet 1 and the surface of the card 2.

By the way, when the transfer sheet 1 and the card 2 are transported at the same speed, as shown in FIG. 2, the distance L between the adjacent transfer regions 8 of the transfer sheet 1 is the length of the card 2 in the transport direction. As described above, a region having the same area and the same shape as the region 8 having the authentication structure can be obtained from the used transfer sheet 1. Therefore, a structure obtained from the used transfer sheet 1 may be formed on the counterfeit card, and the used transfer sheet 1 also needs to be managed. However, the place where the authentication structure is transferred from the transfer sheet 1 to the card 2 spreads widely, and the larger the number, the more difficult it is to manage the used transfer sheet. In addition, labels are in the same situation as transfer sheets.

The present invention has been made in order to solve the above problems, and provides an anti-counterfeit sheet in which a structure of a predetermined shape having the same predetermined area as the authentication structure cannot be obtained from a used sheet. It is intended to be provided.

[0008]

In order to achieve the above object, the anti-counterfeit sheet according to the present invention includes an authentication structure forming layer provided with an authentication structure for authenticating the authenticity of an object to be formed. The anti-counterfeit sheet,
At least the formation planned region where the authentication structure forming layer is formed on the formation target, and the non-formation planned region where the authentication structure formation layer is not formed on the formation target, wherein the formation planned region is the authentication structure. In a predetermined area including a predetermined area, the non-formation planned area is a wider area than the formation planned area, when the predetermined shape of the predetermined area is specified from the non-formation planned area, The structure of the designated non-formation area is different from the structure of the formation area.

The authentication structure forming layer may be laminated on a support having releasability with respect to the authentication structure forming layer to form a transfer sheet.

The authentication structure forming layer may be laminated on the release sheet via an adhesive to form a label.

The authentication structure may be provided as an uneven pattern on the surface of the authentication structure forming layer.

The authentication structure may be a structure that diffracts light.

The difference between the structure of the planned formation area and the structure of the non-formed area may depend on whether or not the authentication structure is formed in the authentication structure forming layer.

The portion of the authentication structure forming layer where the authentication structure is not formed may be a light scattering structure.

The difference between the structure of the planned formation region and the structure of the non-formation region is that the uneven pattern on the surface of the authentication structure forming layer is filled with a material having a refractive index substantially the same as the refractive index of the material of the authentication structure forming layer. It depends on whether or not it is used.

The difference between the structure of the planned formation region and the structure of the non-formation region may depend on whether or not the reflection layer is formed on the surface of the authentication structure forming layer.

The difference between the structure of the area to be formed and the structure of the area not to be formed may be due to the difference in color.

[0018]

In the anti-counterfeit sheet according to the present invention, when a region having a shape substantially the same as the formation-scheduled region is designated from the non-formation-scheduled region, the designated structure of the non-formation-scheduled region is the formation-scheduled region. Since the structure is different from that of the region, it is impossible to obtain a structure having the same area as the authentication structure from the used forgery prevention sheet.

[0019]

Embodiments of the anti-counterfeit sheet according to the present invention will be described below with reference to the drawings. FIG. 3 is a top view of the first embodiment of the forgery prevention sheet according to the present invention. The forgery prevention sheet 11 is in the form of a transfer sheet, and the forgery prevention sheet 11 has a region 12 to be formed on the adherend and a region 13 to be not formed. An authentication structure is formed in the area to be formed 12, and a non-formation area 13 is provided with a "VOI" in order to prevent reuse of a used transfer sheet.
The letter "D" is formed.

FIG. 4 is a cross-sectional view taken along the line AA of FIG. 3, and the support 18 may be a sheet-like material having excellent heat resistance and weather resistance such as a synthetic resin film such as polyethylene terephthalate. It is desirable to coat the surface with a silicone resin or a melamine resin so as to have releasability from the protective layer 17 and improve the transferability.
Further, by coating a curable silicone oil or the like on the surface of the support 18 opposite to the side on which the protective layer 17 is coated, and providing a releasable heat-resistant slip layer, the fusion of the thermal head can be prevented. It is possible to prevent blocking during winding or winding.

The protective layer 17 protects the authentication structure forming layer 14 from scratches due to external force, and is made of synthetic resin such as acrylic resin having excellent heat resistance and weather resistance. In consideration of transfer suitability, it is necessary to make the adhesive force between the protective layer 17 and the authentication structure forming layer 14 larger than the adhesive force between the support 18 and the protective layer 17. When the adhesive force between the support 18 and the protective layer 17 is larger, it is desirable to provide a release layer made of a thermoplastic resin or wax between the support 18 and the protective layer 17.

The authentication structure only needs to change at least one of wavelength, amplitude and phase of light incident on the authentication structure. For example, it may be a pigment or a dye that selectively absorbs a part of the wavelength of incident light and reflects another wavelength,
Further, it may be one that converts the wavelength of incident light, such as a phosphor, and it is desirable that these are formed in a pattern from the viewpoint of preventing forgery. Further, an optical diffractive structure, such as a hologram or a diffraction grating, which causes a phase difference between adjacent incident lights to interfere with each other is desirable from the viewpoint of difficulty of production and duplication. As the hologram, an amplitude hologram, a phase hologram, a plane hologram, a volume hologram, an image hologram, a Fresnel hologram, a Fraunhofer hologram or the like can be used, but if a hologram capable of reproducing white light such as a rainbow hologram or a Lippmann hologram is used, It is desirable because the certification structure can be visually verified. Also, a barcode or the like can be recorded as a subject and can be read by a machine. Further, in the case of a plane hologram, by using a relief hologram, mass productivity can be improved. As the diffraction grating, it is possible to use a holographic diffraction grating in which interference fringes of two light beams of coherent light are recorded, a diffraction grating in which a grating is directly drawn on a photoresist by an electron beam drawing device or the like. Directly drawn diffraction gratings are desirable because of the image precision and the difficulty of optical copying. As for the morphology, the relief structure is desirable as well as the hologram. Furthermore, a line-shaped concavo-convex pattern may be used as the authentication structure because it cannot be copied by a copying machine.

In the case of a pattern image formed by printing, the authentication structure forming layer 14 is made of a known binder mixed with a pigment, a dye, or a phosphor, a relief hologram, or a line-shaped uneven pattern made of a thermoplastic resin. , Thermosetting resin,
If it is a material capable of forming a well-known concavo-convex structure such as an electron beam curable resin and an ultraviolet curable resin, and a Lippmann hologram,
Materials such as photopolymer and dichromated gelatin, and photosensitive materials such as silver salt can be used for other holograms.

The reflective layer 15 is a layer for reflecting incident light and is reflective in the authentication structure itself, and can be omitted in the case of a pattern image by printing or a Lippmann hologram, for example. As a specific material, use a material such as aluminum, tin, or gold that reflects metal by an alloy or an alloy, or a metal compound such as zinc sulfide or titanium oxide that is transparent due to reflection based on the difference in refractive index. You can It is preferable to use the transparent reflection layer because the authentication structure can be formed on desired image information and the rewriting of the image information can be made difficult.

When the anti-counterfeit sheet is in the form of a transfer sheet, the adhesive layer 16 is preferably a heat-sealing agent, which is used by coating a mixture of vinyl chloride, vinyl acetate, acrylic resin and the like as appropriate. When the anti-counterfeit sheet is in the form of a label, it is possible to use a so-called adhesive which adheres only by pressure. Further, as the adhesive layer 16, a dye-receptive adhesive layer can be obtained by using a polyolefin resin such as polypropylene that can be dyed with a sublimable dye or a vinyl chloride / vinyl acetate copolymer. When the adhesive layer 16 is a dye receiving adhesive layer,
A full-color image such as a photograph of a face is taken with a thermal head by using a thermal transfer sheet described in JP-A-62-297184 and provided with yellow, magenta, cyan, and optionally black dye layers. Can be formed on the adhesive layer, and the authentication structure can be transferred to the adherend for each of the formed full-color images. In order to prevent the dye layer and the dye-receptive adhesive layer from being fused by heat when forming a full-color image with a thermal head,
When a dye-receptive adhesive layer is coated and formed, a release agent such as silicone oil is mixed, and the release agent bleeds out by drying after coating. It is desirable that the agent be applied.

In the first embodiment shown in FIG. 4, these layers are sequentially laminated. Relief diffraction gratings having different lattice directions or different grating intervals are formed in a mosaic pattern as an authentication structure in a portion corresponding to the formation planned region 12 of the authentication structure forming layer 14, and in a portion corresponding to the non-formation planned region 13. A light-scattering structure is formed by matting. Also, the part 19 corresponding to the character "VOID"
The reflective layer of is removed. As described above, by using the light diffractive structure including the relief diffraction grating as the authentication structure, the function as the authentication structure is sufficiently exhibited due to the difficulty of producing and copying the diffraction structure. Also,
By making the portion corresponding to the non-formation planned area 13 a light scattering structure, it becomes clear that this portion is the non-formation planned area 13, but instead of providing the light scattering structure, the authentication structure forming layer 14 is provided. It is desirable that the mosaic diffraction grating is uniformly provided in the planned formation region 12 and the planned non-formation region 13 and only the reflective layer 15 in the planned non-formation region 13 is removed, because the number of steps can be reduced. Furthermore, by removing a part of the reflective layer 15 in the non-formation planned area 13, it becomes clear that this portion is the non-formation planned area 13.
Furthermore, the removal of the reflection layer 15 in the non-formation planned area 13 may be performed not only in the portion corresponding to the character "VOID" but also in almost the entire non-formation planned area 13.
The relief of the portion from which 5 is removed is the authentication structure forming layer 14
Since it is filled with the adhesive layer 16 made of a material having substantially the same refractive index as that of the above-mentioned material, there is no difference in the optical path of incident light as in the case where there is no relief, and there is no difference in the refractive index due to the relief surface. There is also no reflection based. Moreover, since it is difficult to remove the adhesive layer 16 and reproduce the relief, it is very useful for preventing forgery. In addition to the adhesive layer, a layer dedicated to the relief layer may be provided as a layer for filling the relief.

Next, the manufacturing method of the first embodiment will be described. As the support 18, a polyethylene terephthalate film having a thickness of 25 μm and having a release treatment applied is used, and a transparent acrylic resin is coated on the film to a thickness of 1 μm by an appropriate means such as a bar coater for protection. This is layer 17. Then, an ultraviolet curable resin containing a mixture of a transparent melamine resin and an acrylic resin as a main component is applied on the protective layer 17 to a thickness of 2 μm and dried,
Create the material to be embossed. On the other hand, on the photoresist surface of the glass plate coated with electron beam photoresist, each grating is directly drawn by an electron beam drawing device to form a mosaic diffraction grating, which is the area where the light diffraction structure is to be formed. , And draw each point directly with an electron beam drawing device,
By providing an uneven surface, a light-scattering structure is provided in a non-formation planned area, and development is performed to prepare an original plate. After depositing a conductive metal on this original plate, nickel is plated to form a stamper. Using this stamper, the surface of the ultraviolet curable resin of the material to be embossed is embossed and irradiated with ultraviolet rays to cure the resin to form the authentication structure forming layer 14.
Here, a water-soluble resin composed of a mixture of polyvinyl alcohol resin and silicon oxide is silk screen printed to a thickness of about 1 μm on the surface of the authentication structure forming layer 14 to form the above-mentioned “VOID”. Further, aluminum is vacuum-deposited to a thickness of about 300Å to form the reflection layer 15, and then the water-soluble resin is dissolved by washing with water to remove the water-soluble resin and the reflection layer 19 at a portion corresponding thereto. Then, a mixture of vinyl chloride and vinyl acetate is coated to a thickness of about 2 μm to form the adhesive layer 16 to prepare a transfer sheet.

FIG. 5 is a schematic sectional view of a second embodiment of the forgery prevention sheet of the present invention, which is a case where a Lippmann hologram is used as an authentication structure. Area to be formed 12
As shown in the figure, the Lippmann hologram provided in 1 is such that the interference fringes are sufficiently swollen, and when reproduced with white light, the image is reproduced with light in the red wavelength region. On the other hand, the Lippmann hologram provided in the non-formation planned region 13 is insufficient in swelling and reproduces an image with light in the blue wavelength region. In this way, the planned formation region 12 and the non-formation planned region 13 have different colors, so that they can be clearly distinguished from each other.

Next, the manufacturing method of the second embodiment will be described. 66% by weight of polyvinyl acetate as a binder polymer, 17% by weight of phenol ethoxy acrylate as a monomer, ethoxylated bisphenol-A diacrylate as a binder polymer, 10.22% by weight of tetraethylene glycol diheptanoate as a plasticizer under red light. 1,1'-biimidazole as photoinitiator, 2,
2'-bis [O-chlorophenyl] -4,4 ', 5
Prepare 3.7% by weight of 5'-tetraphenyl, stir until it is completely dissolved in 97% by weight of dichloromethane and 3% by weight of 2-propanol (22% by weight of total solute), and mix while mixing. To the solvent and then cyclopentanone, 2,5-bis [(2,3,6,7-tetrahydro-1H, 5H-benzo [i, j] quinolidine-1
-Yl) methylene]-) sensitizer 0.08% by weight
Was added to prepare a sensitizer, which was coated on a transparent film 28 of polyethylene terephthalate having a thickness of 50 μm by gravure coating and then dried to prepare a photopolymer / photosensitive swollen film. Then, one of the two light beams split from the argon ion laser is
The object light from the subject and the other as reference light are made to interfere on this photopolymer film, and after recording the interference fringes, the monomer in this photosensitive material is fixed by irradiation with 50 mJ of ultraviolet light, I got a type hologram.
Further, the photosensitive swelling film is overlapped with a mask having an opening at a portion corresponding to the non-formation planned region 13, and 100 mJ of ultraviolet light is irradiated from the side of the mask to form the non-formation of the photosensitive swelling film. Only the monomer in the portion corresponding to the area 13 was fixed. The photopolymer film and the photosensitive material surface of the photosensitive swelling film are brought into close contact with each other, and processed in an atmosphere of 120 ° C. in a circulation oven for 1 hour to form a portion of the photosensitive swelling film corresponding to the area 13 to be formed. By migrating the penetrating monomer into the interference fringes of the hologram, the interference fringes of the part corresponding to the planned formation region 12 are swollen and the interval is widened, while the monomer of the part corresponding to the non-formation planned region 13 is already fixed. Therefore, the interference fringes in this part were not swollen.
After that, 100 mJ of ultraviolet light is irradiated to fix the monomers in the interference fringes to form the authentication structure forming layer 24, and then a mixture of vinyl chloride and vinyl acetate is coated to a thickness of about 2 μm, and the adhesive layer 26 is formed. To form a transfer sheet.

FIG. 6 is a schematic sectional view of a forgery prevention sheet according to a third embodiment of the present invention, in which a base material 37, an authentication structure forming layer 34, a reflecting layer 35, an adhesive 36 and a release sheet 38 are provided. The layers are sequentially laminated and punched into the shape of the planned formation region 12. It is to be noted that a relief hologram is used as the authentication structure, and the colored layer 39 is formed in the non-formation planned region 13 in the case of a label. In the case of a label, as in the case of the above-mentioned transfer sheet, the non-formation planned region 13 is the formation planned region 1 due to the structure of the labeler as the label sticking machine.
In many cases, it is more widely provided than in No. 2, and even in the case of hand-pasting, the label can be efficiently attached to an object to be formed such as a card or passport.
In many cases, 3 is widely set, and the same problem as in the case of the transfer sheet occurs.

The relief hologram provided in the area 12 to be formed is based on a two-step method generally called a rainbow hologram. Since the interference fringes with the reference light are recorded, it is possible to create an object image with a white light source. Therefore, the authenticity of the formed object can be visually confirmed, which is preferable as an authentication structure.

The colored layer 39 is formed by appropriately printing an ink in which a pigment, a dye and the like are mixed in a binder in a desired pattern. In this example, as shown in FIG.
The characters "OID" are printed. The print layer 3
Regarding the position where 9 is formed, in this embodiment, the reflection layer 35 is formed.
Although provided between the adhesive layer 36 and the adhesive 36, the surface of the base material 37, the layer between the base material 37 and the authentication structure forming layer 34, the authentication structure forming layer 3
4 and the reflective layer 35, between the reflective layer 35 and the adhesive layer 36, on the surface of the adhesive layer 36, and further in each layer, etc., at appropriate places. However, if it is provided on the relief hologram surface of the authentication structure forming layer 34 in order to prevent it from being used by a counterfeiter by erasing the print layer 39, the relief hologram itself is damaged when the colored layer 39 is erased. It is preferable because it ends up. In addition, the coloring layer 39
If the colored layer 39 is provided adjacent to the reflective layer 35, the colored layer 39 is damaged when the colored layer 39 is erased, and it can be seen at a glance whether the colored layer 39 is erased.

Next, the manufacturing method of the third embodiment will be described. A transparent polyethylene terephthalate film having a thickness of 25 μm is used as the support 18, and a transparent UV-curable urethane acrylate resin is coated on the film to a thickness of 2 μm by an appropriate means such as a bar coater to make the rainbow hologram uneven. The plates recorded as the surface are overlapped and the urethane acrylate resin is irradiated with ultraviolet rays to be cured to form the authentication structure forming layer 34.
The characters “VOID” are printed by silk screen printing on the relief hologram surface of the authentication structure forming layer 34 corresponding to the non-formation planned area 13 to form the colored layer 39. Further, titanium oxide is vapor-deposited on the relief hologram surface of the authentication structure forming layer 34 to a thickness of about 500Å,
The reflection layer 35 is used. On the other hand, the release sheet 38 has a thickness of 1
A polyethylene terephthalate film having a thickness of 00 μm is prepared, and the surface of the film is coated with an adhesive agent having a thickness of 20 μm from a mixture of an acrylic resin and a vinyl acetate resin.
The surface of the pressure-sensitive adhesive 36 of the release sheet 38 is overlapped with the surface of the reflective layer 35 of the authentication structure forming layer 34 described above to form the planned region 1
Half-cut into the shape of 2 to create a label-shaped forgery prevention sheet.

Although the embodiments of the forgery prevention sheet of the present invention have been described above, the present invention is not limited to these and various modifications can be made. For example, for removal of the reflection layer, instead of using a water-soluble resin, a reflection layer is provided on the entire surface of the planned formation region 12 and the non-formation planned region 13 to form an anti-counterfeit sheet, and then an appropriate heating means such as a thermal head is used. The reflective layer may be removed by heating and breaking the reflective layer with.

[0035]

According to the anti-counterfeit sheet according to the present invention, when a region having a shape substantially the same as the planned formation region is designated from the non-formation planned region, the designated structure of the non-formation planned region is the above-mentioned. Since the structure of the area to be formed is different, it is not possible to obtain a structure with the same area as the authentication structure from the used anti-counterfeit sheet. There is no need to strictly manage the seat.

[Brief description of drawings]

FIG. 1 is a diagram for explaining a current transfer process.

FIG. 2 is a diagram for explaining a region where an authentication structure is formed on a transfer sheet.

FIG. 3 is a top view of the first embodiment according to the present invention.

FIG. 4 is a sectional view taken along line AA of the first embodiment shown in FIG.

FIG. 5 is a sectional view of a second embodiment according to the present invention.

FIG. 6 is a sectional view of a third embodiment according to the present invention.

[Explanation of symbols]

 11, 21, 31 Anti-counterfeit sheet 12 Area to be formed 13 Area to be not formed 14, 24, 34 Authentication structure forming layer 15, 35 Reflective layer 16, 26 Adhesive layer 17 Protective layer 18, 28 Support 36 Adhesive 37 Base material 38 Release Sheet 39 Coloring Layer 40 Notch

Claims (10)

[Claims] 1. A forgery prevention sheet including an authentication structure forming layer provided with an authentication structure for authenticating the authenticity of an object to be formed, wherein at least the authentication structure forming layer is the object to be formed. An area to be formed on the body,
The authentication structure forming layer is composed of a non-formation planned region that is not formed on the formation target, the formation planned region is a region having a predetermined area and a predetermined shape including the authentication structure, and the non-formation planned region is the When a region having a predetermined shape and having a predetermined area is specified from the non-formation planned region, the structure of the designated non-formation planned region is different from the structure of the formation planned region. An anti-counterfeit sheet characterized by that. 2. The forgery according to claim 1, wherein the authentication structure forming layer is laminated on a support having releasability with respect to the authentication structure forming layer to form a transfer sheet. Prevention sheet. 3. The anti-counterfeit sheet according to claim 1, wherein the authentication structure forming layer is laminated on a release sheet via an adhesive to form a label. 4. The forgery prevention sheet according to claim 1, wherein the authentication structure is provided on the surface of the authentication structure forming layer as an uneven pattern. 5. The forgery prevention sheet according to claim 1, wherein the authentication structure is a structure that diffracts light. 6. The structure according to claim 1, wherein the difference between the structure of the formation planned area and the structure of the non-formation planned area is whether or not the authentication structure is formed in the authentication structure forming layer. The anti-counterfeit sheet according to item 1. 7. The forgery prevention sheet according to claim 6, wherein a portion of the authentication structure forming layer where the authentication structure is not formed is a light scattering structure. 8. The difference between the structure of the area to be formed and the structure of the area not to be formed is that the unevenness pattern on the surface of the authentication structure forming layer is substantially the same as the refractive index of the material of the authentication structure forming layer. The anti-counterfeit sheet according to any one of claims 1 to 4, wherein the anti-counterfeit sheet depends on whether or not the sheet is filled with the material. 9. The difference between the structure of the planned formation region and the structure of the non-formation planned region depends on whether or not a reflection layer is formed on the surface of the authentication structure forming layer. The anti-counterfeit sheet described in. 10. The forgery prevention sheet according to claim 1, wherein the difference between the structure of the planned formation region and the structure of the non-formation planned region is due to a difference in color.