JP2013080099A - Forgery-preventive display body and information printed matter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a forgery-preventive display body solving such problems that holograms give similar impression on an observer and, even when there is a little change in observation conditions, exerting little color change on a reproduction image.SOLUTION: A forgery-preventive display body comprises a plurality of pixels, and the pixels constituting two images of a reflection image and a transmission image comprise an asperity structure part, a print part, and a flat part. The area of protruded parts or recessed parts disposed on the asperity structure area of the pixels and an area to be printed on the print area are determined on the basis of contrasting density of the reflection image and transmission image of the display body. The pixel comprises either of: an asperity structure area in which a plurality of protruded parts protruding from a metal thin film layer to the asperity structure forming layer, or a plurality of recessed parts recessed from the asperity structure forming layer towards the metal thin film layer are randomly or periodically disposed at center-to-center spacing less than a wavelength of visible light and that has optical transparency function; the print area; only the asperity structure area; and the only print area.

Description

  The present invention relates to an image display body that is used for anti-counterfeiting and changes its appearance depending on viewing conditions, and in particular, an anti-counterfeit display body in which the brightness and color diagram of an image changes depending on the angle of illumination light, the viewing direction, etc. And information printed matter.

  In recent years, it has a visual effect different from ordinary printed materials for the purpose of preventing counterfeiting of securities such as gift certificates and checks, cards such as credit cards, cash cards, ID cards, and certificates such as passports and licenses. The display body is provided in the form of a transfer foil, a sticker, or the like, which is attached to the surface of a certificate such as the securities or a card, and is crimped. Also, the distribution of counterfeit goods has become a social problem for articles other than securities and certificates, and there are increasing opportunities to apply similar anti-counterfeiting techniques to such articles.

  Examples of anti-counterfeiting technologies include micro characters, special light-emitting inks, watermarks, diffraction gratings, and holograms. This forgery prevention technology can be roughly divided into two. One is a technique for determining authenticity using a simple device, a measuring device, or the like. The other is a technique that can easily determine authenticity with the naked eye.

  In recent years, a security device has been developed in which various fine structures can be produced by an electron beam drawing apparatus (EB apparatus) and visually differentiated from similar techniques. The most common security device is a surface relief type rainbow hologram. Rainbow holograms have a more complex structure than ordinary printed materials, and are difficult to manufacture unless they are a specific vendor with high microfabrication technology. A large-scale replication device is required for replication. This makes it difficult to replicate easily. For this reason, it is difficult to produce counterfeit products (Non-Patent Document 1).

  In addition, when illuminated with illumination light, it is reproduced with light close to a single wavelength, so it can be observed in bright and vivid colors corresponding to the seven colors of the rainbow, and the color and image pattern change when the observation conditions change The way you look. For this reason, the difference from other members can be easily discriminated visually.

  For these reasons, the rainbow hologram is excellent for visual security applications and has been widely used as an image display for preventing counterfeiting. However, in the rainbow hologram, the color of the reproduced image changes greatly even if the observation condition changes slightly, so it is difficult to identify the difference in the color of the image. For this reason, even a rainbow hologram in which different images are recorded has a problem that it is easy to give an impression similar to an observer, and it is difficult to discriminate a difference in recorded images between holograms.

  In general, in order to emit diffracted light, a periodic structure is required, and as a result, a rainbow color can be seen (Patent Document 1).

In order to solve such a problem, it is possible to change the period (d _x ; d _y ) of the relief structure and change the lattice angle and the structure depth between the background surface of the pattern surface section and the pattern element. Proposed. However, only the reflected light with a fine structure is controlled, and it is easy to give an impression similar to observers between holograms (Patent Document 2).

JP-A-2-72320 JP-T-2005-518956

“Principles of Holography”, Optronics, p. By Hari Haran

  An object of the present invention is to provide a security element that cannot be duplicated by a copying machine and that cannot be duplicated by a holography method, and that achieves an inexpensive optical change. The display is observed with transmitted light and reflected light. By displaying different images at the same time, the problem that the holograms give a similar impression to the viewer is passed, and the forgery prevention display body with little color change of the reproduced image even if there is a slight change in the viewing conditions Is to provide.

As means for solving the above-mentioned problems, the invention according to claim 1 includes a light-transmitting base material, a concavo-convex structure forming layer provided on one surface of the base material, and the concavo-convex structure. And a metal thin film layer covering the forming layer, and on the base material surface opposite to the base material surface on which the concavo-convex structure forming layer is provided, between the base material and the concavo-convex structure forming layer, or A forgery prevention display body configured to include a printing layer between the concavo-convex structure forming layer and the metal thin film layer, displaying an image depending on the presence or absence of the concavo-convex structure forming layer and the presence or absence of the printing layer,
The image includes a transmission image and a reflection image, and each of the transmission image and the reflection image includes a plurality of pixels.
When the portion having the concavo-convex structure forming layer is the concavo-convex structure portion, the portion having the printing layer is the printing portion, and the portion where neither the concavo-convex structure forming layer nor the printing layer is present is the flat portion, the printing portion depends on the color. A light-reflecting portion that reflects light, and the concavo-convex structure portion is a convex portion or a concave portion provided in the concavo-convex structure forming layer, the convex portion or the concave portion arranged at a center-to-center distance less than a visible wavelength. And has a light transmitting portion that reflects light without reflecting light based on the convex portion or the concave portion, and the flat portion has a light source light reflecting portion that reflects light source light based on the metal thin film layer. Composed of
Among the plurality of pixels, at least some of the pixels have at least two types of portions, that is, a concavo-convex structure portion and a printing portion or a flat portion.
This is an anti-counterfeit display body characterized by the above.

  According to a second aspect of the present invention, the inverted image of the reflected image is included in a transmissive image, the bright portion of the reflected image is composed of an uneven structure region, and the dark portion other than the inverted image on the transmissive image is a printed region. It is comprised by these, The forgery prevention display body of Claim 1 characterized by the above-mentioned.

  The invention according to claim 3 is the forgery prevention display body according to claim 1 or 2, characterized in that the area of the concavo-convex structure region and the printing region occupying the pixel is substantially the same. is there.

  The invention according to claim 4 is characterized in that the shade of the image is binary, and the presence or absence of the uneven structure region and the print region of the pixel is determined according to the shade. 4. A forgery prevention display body according to any one of items 3 to 3.

  The invention according to claim 5 is the forgery-preventing display body according to any one of claims 1 to 4, wherein the uneven structure region and the printing region have substantially the same chromaticity. .

In the invention according to claim 6, the center-to-center distance of the plurality of convex portions or concave portions is 100 nm or more and less than 500 nm, and the height or depth of the plurality of convex portions or concave portions is 100 nm or more and 50.
It is less than 0 nm, It is a forgery prevention display body as described in any one of Claims 1-5 characterized by the above-mentioned.

  The invention according to claim 7 is characterized in that the film thickness on the flat surface of the metal thin film layer is not less than 50 nm and not more than 100 nm, and the counterfeit prevention display body according to any one of claims 1 to 6 It is.

  The invention according to claim 8 is characterized in that the plurality of pixels are two-dimensionally arranged, and the shape of the convex part or the concave part is rectangular. It is a forgery prevention display body as described in an item.

  The invention according to claim 9 is the forgery prevention display body according to any one of claims 1 to 8, wherein a length of one side of the pixel is 145 μm or less.

  The invention according to claim 10 is an information printed material comprising a light-transmitting printed material substrate, and the information printed material has a partial area on the surface of the information printed material according to any one of claims 1 to 9. An information printed matter comprising an anti-counterfeit display.

  According to invention of Claim 1, this display body has the uneven | corrugated structure area | region which has a light-transmitting function, and the printing area | region. The concavo-convex structure region having a light transmitting function is a low reflection region, and is displayed in black or dark gray when illuminating light from the observation direction and observing the display body (reflection observation). Further, when the display body is observed by illuminating light from the direction opposite to the observation direction (transmission observation), the transmitted light can be observed. On the other hand, when the print area is reflected and observed, the printed color can be perceived. However, transmitted light cannot be confirmed even through transmission observation. Moreover, when the reflection observation is performed in a portion where there is no concavo-convex structure region or printing region, the illumination light is regularly reflected by the metal thin film layer, so that the color of the illumination light is observed. In other words, by providing the concavo-convex structure region and the print region for each pixel, the image recognized in the reflection observation can be made different from the image recognized in the transmission observation.

  According to the invention of claim 2, the reverse image of the reflection image is included in the transmission image, the bright portion of the reflection image is configured by the uneven structure region, and the dark portion other than the reverse image on the transmission image is configured by the print region. Thus, the correspondence between the two images, the uneven structure area, and the installation location of the print area are clarified.

  According to the invention of claim 3, since the area of the concavo-convex structure in the pixel and the area of printing are substantially the same, it is possible to invert the image observed in the reflection observation and the transmission observation. is there.

  According to the invention of claim 4, the shade of the image is binary. By being binary, the distinction between images observed in reflection observation and transmission observation can be made clearer.

  According to the invention of claim 5, the display colors of the concavo-convex structure region and the print region are substantially the same. By being substantially the same, it is possible to make it indistinguishable when the concavo-convex structure region and the print region are observed by reflection.

  According to invention of Claim 6, the center-to-center distance of a some convex part or a recessed part is 100 nm or more and less than 500 nm, and the height or depth of a some convex part or a recessed part is 100 nm or more and less than 500 nm. By molding under the above conditions, it is possible to exhibit a highly effective low reflection function.

According to invention of Claim 7, the film thickness in the flat surface of a metal thin film layer is 50 to 100 nm.
It is as follows. By forming the metal thin film layer under these conditions, it is possible to maximize the difference in transmittance between the flat surface and the uneven structure region.

  According to the invention of claim 8, the pixels are two-dimensionally arranged and the shape is rectangular. The rectangular shape improves image handling.

  According to the invention of claim 9, the length of one side of the pixel is preferably 145 μm or less. By orderly arranging pixels having a side length of 145 μm or less, it is possible to prevent the pixel shape from being recognized when the display body is observed with the naked eye.

  According to invention of Claim 10, it becomes possible to give the high anti-counterfeit effect to the conventional articles | goods by bonding or combining the display body of this invention to printed matter, a card | curd, and other articles | goods.

Schematic of the display body of the present invention. The figure which showed the II cross section of the display body shown in FIG. Sectional drawing which showed an example of the structure employable as the display body shown in FIG. The perspective view which showed the convex structure of the low reflection area | region 20 of FIG. The top view which showed the convex structure of FIG. The perspective view which showed an example of the form employable as the convex structure of the low reflection area | region 20 of FIG. The top view which showed the convex structure of FIG. Sectional drawing which shows an example of a metal thin film layer. The figure which expanded the dotted-line area | region A of FIG. The figure which showed the difference at the time of the observation of the reflected light and the observation of the transmitted light by the occupation area of the low reflection area and the printing area. An image obtained when the display body 10 is observed from the observer side with a light source incident on the display body. An image obtained when a light source is incident on the display body 10 from the opposite side of the observer and observed.

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the drawings. FIG. 1 of the present invention is a schematic diagram showing an embodiment of the display body of the present invention. 2 is a cross-sectional view taken along the line II of the display shown in FIG. 9 which is an enlarged view of the dotted line area A of FIG.

  The concavo-convex structure portion 20 in FIG. 2 is obtained by embossing a concavo-convex structure forming layer 101 in which the convex structure 200 is laminated on the light transmissive substrate 100 from a mold having the convex structure 200. Although 101 is formed as a concave structure, the observer sees it as a convex structure 200 in order to observe from the light-transmitting substrate 100 side.

  The display body 10 includes a laminate of a light transmissive layer 11 (light transmissive substrate 100 and concavo-convex structure forming layer 101), a printed layer 103, and a metal thin film layer 102. In this example, the light transmissive layer 11 includes a light transmissive substrate 100 and a concavo-convex structure forming layer 101, and a concavo-convex structure 200 is formed on the concavo-convex structure forming layer 101. In the example shown in FIG. 2, the printed layer 103 side is the front side (observer side), and the metal thin film layer side is the back side. In FIG. 2, the printing layer 103 is shown on the light transmission layer 11, but may be formed between the light transmission layer 11 and the metal thin film layer 102 as shown in FIG.

The light transmissive substrate 100 is formed of a film or sheet that can be handled by itself. As a material of the light transmissive substrate 100, for example, polyethylene terephthalate (PET), polycarbonate (PC), or the like can be used.

  The concavo-convex structure forming layer 101 is a layer formed on the light transmissive substrate 100, and the convex structure 200 is formed on the surface of the concavo-convex structure forming layer 101. As a method of forming the convex structure 200 on the concavo-convex structure forming layer 101, for example, a resin is applied on the light-transmitting substrate 100 to form the concavo-convex structure forming layer 101, and the resin is applied while pressing a stamper on this layer. A curing method can be used, and as the resin applied on the light-transmitting substrate 100, a light-transmitting thermoplastic resin, thermosetting resin, photocurable resin, or the like can be used. .

  The material of the metal thin film layer 102 is not particularly limited, but it is preferable to use a metal material such as aluminum that exhibits a high reflectance with respect to visible light. The film thickness of the metal thin film layer is preferably about 50 to 100 nm from the viewpoint of optical characteristics. As a method of laminating the reflective layer, a thin film can be formed with high accuracy by following the relief structure by a vapor deposition method such as a vacuum deposition method and a sputtering method.

  The printing layer 103 displays images such as characters, pictures, symbols, etc., and has a property of not transmitting light. Depending on the printing method of the printing layer 103, various printing inks such as offset ink, letterpress ink, and gravure ink can be used. Ink is used. Inks used for printing can be classified by composition such as resin-type ink, oil-based ink, water-based ink, and classification by drying method such as oxidation polymerization type ink, osmosis drying type ink, evaporation drying type ink, ultraviolet curable ink etc. It is appropriately selected according to the type of substrate and the printing method.

  In addition, toner made by attaching colored particles such as graphite and pigment to plastic particles with charging properties can be transferred to a substrate such as polyethylene terephthalate (PET) film or paper using static electricity, and then heated and fixed. A technique for forming the printing layer 103 is also common.

  The display body 10 can further include other layers such as an adhesive layer and an adhesive layer. In this case, it is desirable to form the adhesive layer and the adhesive layer so as to cover the metal thin film layer 102. The adhesive layer and the adhesive layer are light transmissive. When the display body 10 includes both the light transmission layer 11 and the metal thin film layer 102, the shape of the surface of the metal thin film layer 102 is usually substantially equal to the shape of the interface between the light transmission layer 11 and the metal thin film layer 102. Therefore, when the adhesive layer or the adhesive layer is provided as described above, it is possible to prevent the surface of the metal thin film layer 102 from being exposed. Therefore, it is possible to make it difficult to copy the uneven structure for the purpose of counterfeiting.

  Next, the uneven structure portion 20 formed on the uneven structure forming layer 101 will be described. The concavo-convex structure portion 20 has a plurality of convex structures 200 protruding from the metal thin film layer 102 toward the concavo-convex structure forming layer 101, or a plurality of concave structures recessed from the concavo-convex structure forming layer 101 toward the metal thin film layer 102. They are arranged randomly or periodically with a center distance D of 500 nm.

  Moreover, the height of the convex structure 200 or the depth of the concave structure is 100 nm to 500 nm. In the future, for the sake of simplification of explanation, the explanation will be made with a special focus on the convex structure 200, but the convex structure 200 may be replaced with a concave structure. 4 and 5 are a perspective view and a plan view in which the convex structures 200 are randomly arranged at a center-to-center distance D less than the wavelength of visible light. 6 and 7 are a perspective view and a plan view in which the convex structures 200 are periodically arranged in parallel with the X axis and the Y axis. The above shows an example in which typical convex structures 200 are arranged, and they may be arranged in parallel with a straight line where the X axis and the Y axis intersect at an angle of 45 degrees.

The convex structure 200 typically has a tapered shape. Examples of the tapered shape include a semi-spindle shape, a cone shape such as a cone and a pyramid, and a truncated cone shape such as a truncated cone and a truncated pyramid. The side surface of the convex structure 200 may be configured only by an inclined surface or may be stepped. The tapered shape of the convex structure 200 is useful for reducing the reflectance of light incident on the concave-convex structure portion 20 as will be described later. When the convex structure 200 is formed using a stamper, the taper shape facilitates removal of the hardened concavo-convex structure forming layer 101 from the stamper and contributes to improvement in productivity.

  As described above, the convex structure 200 is suitable for a tapered shape. When such a structure is adopted, if the center-to-center distance DD1 is sufficiently short, the concavo-convex structure portion 20 has a refractive index that continuously changes in the Z direction. Can be regarded as having Therefore, the reflectance is small no matter what angle is observed.

  Therefore, the portion corresponding to the concavo-convex structure portion 20 in the display body 10 appears, for example, black or dark gray when reflected from the normal direction. Here, the reflection observation refers to a case where light is generally applied to the surface of the display body from a light source disposed above, and the state of the display body surface is observed by reflected light from the display body surface.

  Here, “black” is a wavelength range of 400 nm to 700 nm when the portion of the display body 10 corresponding to the concavo-convex structure region 20 is irradiated with light from the normal direction and the intensity of specular reflection light is measured. This means that the reflectance is 10% or less for all the light components within, and “dark gray” means that the portion corresponding to the concavo-convex structure region 20 in the display body 10 is irradiated with light from the normal direction. When the intensity of the reflected light is measured, it means that the reflectance is about 25% or less for all the light components whose wavelength is in the range of 400 nm to 700 nm which is the wavelength of visible light.

  As described above, the concavo-convex structure portion 20 displays black or dark gray when reflected from the front, that is, from the transmissive substrate 100 side. Therefore, a portion of the display body 10 corresponding to the concavo-convex structure region 20 looks like, for example, a black or dark gray print layer 103 when reflected from the front.

It is preferable that the display colors of the printing unit 21 and the concavo-convex structure unit 20 are substantially the same. Here, the display colors being substantially the same indicate that the color difference ΔE ^* _ab between the concavo-convex structure portion 20 and the printing portion 21 is a value within 13 or less. The above value is called class C tolerance and indicates a degree corresponding to the color difference between the color charts of the JIS standard color chart (JIS S6016), and is judged to be the same color. The color difference ΔE ^* _ab is obtained by measuring L ^* , a ^* , b ^* , which are parameters expressing the color of an object with a spectrocolorimeter or the like, for the display colors of the concavo-convex structure portion 20 and the printing portion 21, The differences ΔL ^* , Δa ^* , Δb ^* of the printing unit 21 are calculated, and the color difference ΔE ^* _ab is obtained from Equation 1.

(Formula 1)
The center distance DD1 of the convex structure 200 is 100 nm to 500 nm. In general, as the distance DD1 between the centers of the convex structures 200 decreases, the brightness and saturation decrease, enabling a black display, and the brightness increases as the distance between the centers DD1 increases. The structure is perceived as gray. Further, the higher the height of the convex structure 200 is, the more black display becomes possible. As the height is reduced, the luminance increases and is perceived as dark gray. Typically, it is desirable that the height of the convex structure 200 be at least half of the center distances D and D1.

Specifically, when the center-to-center distances D and D1 are 500 nm, dark gray can be displayed by setting the height of the convex structure 200 to 250 nm or more, and more than 500 nm that is larger than the center-to-center distance DD1. By making the height of, black display becomes possible. However, if the center distances D and D1 are shortened or the height of the convex part is high, it becomes difficult to form the convex structure 200. Therefore, the center distances D and D1 are 100 nm or more and the height is 500 nm or less. . Further, when the center distance D1 is increased or the height of the convex structure 200 is reduced, it becomes difficult to display black or dark gray. Therefore, the center distances D and D1 are 500 nm or less, and the height of the convex structure 200 is 100 nm or more. Yes.

  When the convex structures 200 are periodically arranged as shown in FIG. 6, it also functions as a diffraction grating. Typical diffracted light is first-order diffracted light, and the emission angle β of the first-order diffracted light can be calculated from Equation 2.

(Formula 2)
In Equation 2, d represents the distance between the concave or convex portions, and λ represents the wavelengths of incident light and diffracted light. Α represents an incident angle. As is apparent from Equation 2, the emission angle β of the first-order diffracted light changes according to the wavelength λ. That is, the concavo-convex structure region composed of convex portions (or concave portions) has a function as a spectroscope. Therefore, if the observation angle when observing the concavo-convex structure region formed of the convex structure 200 when the illumination light is white light, the color perceived by the observer changes.

  However, when the center-to-center distance D1 is set to less than 200 nm from Equation 2, the function of emitting the first-order diffracted light cannot be obtained. Therefore, in order to add a diffracted light function, it is necessary to arrange the convex structures 200 periodically and to set the center distance D1 to 200 nm or more.

  Next, transmission observation will be described. Here, the transmission observation generally refers to a case where light is irradiated from the light source arranged on the back surface of the display body to the back surface of the display body, and the state of the display body surface is observed by transmitted light from the display body surface. As described above, the metal thin film layer 102 preferably has a thickness of 50 nm to 100 nm or less on a flat surface. An example of the metal thin film layer 102 is shown in FIG. The metal thin film layer 102 shown in FIG. 8 has a flat portion 22 formed with a layer thickness T1 by a vapor deposition method, and the side surface portion of the convex structure 200 is formed with a layer thickness T2 that is relatively thinner than the layer thickness T1. Has been. If the height of the convex structure 200 is high, the layer thickness T2 becomes thinner. As a specific example, when T1 is 60 μm, T2 is 30 μm. Therefore, the concavo-convex structure region 20 provided with the convex structure 200 is easier to transmit light than the flat portion 22. When the layer thickness is 50 nm or less, the reflectance of the flat surface is 80% or less.

  In addition, when the layer thickness is 100 nm or more, T2 becomes thick, so that it is difficult to transmit light. From the above, the metal thin film layer has a thickness of 50 nm to 100 nm or less on a flat surface. That is, when the metal thin film layer 102 is observed through the concavo-convex structure portion 20 having a thickness of 50 to 100 nm, the transmitted light can be observed. Further, since the flat portion 22 is reflected by the metal thin film layer 102, the transmitted light cannot be observed. Furthermore, since the printing layer 103 described above is an ink that does not transmit light, the transmitted light cannot be observed even in the printing region 21.

  Next, the pixels constituting the display body surface will be described. The surface of the display body is divided into a plurality of pixels, and the pixels are composed of the concavo-convex structure portion 20, the printing portion 21, the flat portion 22, or a combination of the three. As an example, FIG. 9 shows an enlarged view of a dotted area A of the display body 10 of FIG. A dotted line area B in FIG. 9 indicates one pixel. In the description of FIG. 9, the shape of the pixel is rectangular, but it may be circular or polygonal. Further, although the pixels are arranged in an orderly manner in FIG. 9, they may be arranged in a honeycomb structure or the like. The vertical line portion in FIG. 9 is the uneven structure portion 20, and the black portion indicates the printing portion 21.

Moreover, although the concavo-convex structure part 20 and the printing part 21 are shown in a rectangular shape, they may be circular or polygonal. The pixel size is preferably within 145 μm. When the observer observes the state of the image display body at a position 500 mm away from his / her own eye, the resolution of a human eye with a visual acuity of 1.0 is generally 1 minute. A structure of 145 μm or less cannot be decomposed. Therefore, when the length of the long side of the pixel is 145 μm or less, the pixels cannot be decomposed. Therefore, by setting the length of the long side of the pixel to 145 μm or less, it is possible to provide an image display body that displays a higher quality image.

  In FIG. 10, the pixel (a) composed only of the concavo-convex structure portion 20 is reflected and observed (a1) and transmitted (a2), and the pixel (b) composed only of the printing portion 21 is reflected and observed (b1) and transmitted (b2). ), A reflection observation (c1) and a transmission observation (c2) are shown for the pixel (c) composed only of the flat portion 22. Moreover, the case where reflection observation (d1)-(g1) and permeation | transmission observation (d2)-(g2) are shown about the pixel (d)-(g) comprised by the uneven | corrugated structure part 20, the printing part 21, and the plane part 22 is shown. The vertical line portions of (a) to (g) indicate the concavo-convex structure portion 20, and the black portion indicates the printing portion 21. A hatched portion 300 indicates a dark portion (black, dark gray), and a dot coating portion 301 indicates a bright portion. As shown in FIG. 10, the images displayed in the reflection observation and the transmission observation differ depending on the area ratio of the uneven structure portion 20, the printing portion 21, and the flat portion 22 occupying the pixel.

  Next, a display image design method will be briefly described. When the two images are images A and B, the images A and B are created so that the inverted image of the image A is included in the image B. The bright portion of the image A is configured by a concavo-convex structure region (the concavo-convex structure region indicates a concavo-convex structure portion and a flat portion or a concavo-convex structure portion). At this time, the bright portion may maintain gradation. When the gradation is maintained, the area of the concavo-convex structure portion of the pixel constituting the bright portion of the image A is controlled according to the gradation. Further, a dark area other than the reverse image of the image A on the image B is configured by a print area (a print area indicates a print part and a flat part or a print part). By setting the uneven structure area and the print area in this way, different images can be displayed during reflection observation and transmission observation.

  FIG. 11 shows an example in which a display body is manufactured by arranging pixels as described above while considering an image that can be observed by reflection observation and an image that can be observed by transmission observation. FIG. 11 shows an image displayed when the display body 10 is reflected and observed. The letter “P” is made of the concavo-convex structure portion 20. Therefore, since the reflectance is low as described above, it is displayed in black or dark gray in reflection observation. In the flat portion 22, the light source color is displayed because the reflectance is high. The region 24 for displaying the background of the letter T is composed of the concave-convex structure portion 20, the printing portion 21, the flat portion 22, or a combination of the three or two regions. Is displayed.

  Next, an example of an image displayed when the display body 10 is observed through transmission is shown in FIG. Since the letter “P” is the concavo-convex structure region 20 as described above, the thickness of the metal thin film layer 102 is smaller than that of the flat portion 22, so that the transmitted light 306 can be observed. The flat portion 22 cannot observe the transmitted light 306 because the light from the light source 302 is reflected by the metal thin film layer. In the region 23 for displaying the letter T, the pixels are arranged so that the light reflected by the metal thin film layer and the transmitted light 306 display the letter “T” with respect to the incident light 304 from the light source. “T” can be observed. The region 24 that displays the background of the letter T blocks light.

  In the present invention, since the diffracted light is not used, it does not look like a rainbow color, and the color change of the reproduced image becomes large with a slight change in the observation condition, which is a problem when using the conventional rainbow hologram. There was no such thing. It was possible to provide a forgery prevention display body and an information printed matter in which a reproduced image hardly changes.

DESCRIPTION OF SYMBOLS 10 ... Display body 11 ... Light transmission layer 20 ... Uneven structure part 21 ... Printing part 22 ... Flat part 23 ... Area | region 24 which displays the character T ... Background of the character T Display region 100 ··· Transparent substrate 101 ··· Concavity and convexity formation layer 102 ·· Metal thin film layer 103 ·· Print layer 200 ·· Convex structure 300 ·· Low lightness portion 301 ·· High lightness portion 302 ..Light source 303 ..observation position 304 ..incident light 305 ..reflected light 306 ..transmitted light D1 .. convex structure center distance T1... Layer thickness T2.

Claims (10)

A light-transmitting base material; a concavo-convex structure forming layer provided on one surface of the base material; and a metal thin film layer covering the concavo-convex structure forming layer. On the base material surface opposite to the base material surface formed, between the base material and the concavo-convex structure forming layer, or between the concavo-convex structure forming layer and the metal thin film layer, is configured with a printing layer, An anti-counterfeit display for displaying an image depending on the presence or absence of a concavo-convex structure forming layer and the presence or absence of a printed layer
The image includes a transmission image and a reflection image, and each of the transmission image and the reflection image includes a plurality of pixels.
When the portion having the concavo-convex structure forming layer is the concavo-convex structure portion, the portion having the printing layer is the printing portion, and the portion where neither the concavo-convex structure forming layer nor the printing layer is present is the flat portion, the printing portion depends on the color. A light-reflecting portion that reflects light, and the concavo-convex structure portion is a convex portion or a concave portion provided in the concavo-convex structure forming layer, the convex portion or the concave portion arranged at a center-to-center distance less than a visible wavelength. And has a light transmitting portion that reflects light without reflecting light based on the convex portion or the concave portion, and the flat portion has a light source light reflecting portion that reflects light source light based on the metal thin film layer. Configured
Among the plurality of pixels, at least some of the pixels have at least two types of portions, that is, a concavo-convex structure portion and a printing portion or a flat portion.
An anti-counterfeit display body characterized by that.   The reverse image of the reflection image is included in a transmission image, a bright portion of the reflection image is configured by a concavo-convex structure region, and a dark portion other than the reverse image on the transmission image is configured by a print region. Item 2. An anti-counterfeit display body according to Item 1.   The counterfeit prevention display body according to claim 1 or 2, wherein an area of the concavo-convex structure region and the printing region occupying the pixel is substantially the same.   The forgery prevention according to any one of claims 1 to 3, wherein the shade of the image is binary, and the presence or absence of the uneven structure region and the print region of the pixel is determined according to the shade. Display body.   The forgery prevention display body according to any one of claims 1 to 4, wherein the uneven structure region and the printing region have substantially the same chromaticity.   The distance between centers of the plurality of convex portions or concave portions is 100 nm or more and less than 500 nm, and the height or depth of the plurality of convex portions or concave portions is 100 nm or more and less than 500 nm. The forgery prevention display body as described in any one of Claims.   The forgery prevention display body according to any one of claims 1 to 6, wherein a film thickness on a flat surface of the metal thin film layer is 50 nm or more and 100 nm or less.   The forgery-preventing display body according to any one of claims 1 to 7, wherein the plurality of pixels are two-dimensionally arranged, and a convex portion or a concave portion has a rectangular shape.   The counterfeit prevention display body according to any one of claims 1 to 8, wherein a length of one side of the pixel is 145 µm or less.   It is the information printed matter which consists of printed matter base material which has a light transmittance, Comprising: The forgery prevention display body of any one of Claims 1-9 was provided in the one part area | region of the information printed matter surface, Printed information.