JP5141159B2 - Security device, verification method thereof, and printed matter - Google Patents

Description

  The present invention relates to a security device, a verification method thereof, and a printed matter that can easily perform authenticity determination by using the characteristics of a latent image confirmed by using a polarizer.

  Conventionally, there are various techniques using a latent image for preventing forgery. For example, there are a method in which hidden characters or the like are inserted using gaps between the pitches of the lines, and the hidden characters appear by hiding the lines, and a method in which characters appear when the angle is changed by intaglio printing. However, when these methods are looked closely, a latent image can be seen.

  In addition, there is a method in which a latent image is formed by partially changing the pitch or angle of halftone dots and lines, and an image appears by overlaying a halftone dot or line of transparent film regularly arranged on the latent image. . However, this method has a problem that a complex image cannot be formed.

  In addition, as a method of forming a latent image by using special ink, reversible thermochromic ink (thermochromic ink) that reversibly develops or discolors by applying heat and returns to its original state when left for a while. There was a method. However, these methods have problems in terms of ink resistance.

  Similarly, as a method using a special ink, a method using a photochromic ink that develops a color when irradiated with ultraviolet rays, a method using a fluorescent ink that emits light when irradiated with ultraviolet rays, and a latent image using an ink that absorbs infrared light. And a layer for transmitting infrared light without transmitting visible light is provided on the latent image. However, these methods require a large-scale device for displaying a latent image.

  In recent years, a method using liquid crystal has been proposed for forming a latent image. In this method, a latent image is formed by imparting orientation to a part of the liquid crystal, and the latent image can be visually recognized by using a polarizer.

In Patent Document 1, it is proposed that a liquid crystal is oriented on a fine structure, solidified, and then adhered to a reflective layer to be used for security purposes.
JP 2003-251643 A

  However, the substance that forms the fine structure proposed in the above method is impermeable or has poor adhesion to the liquid crystal polymer even if it is permeable. There is a need to.

  In that case, since the inverted structure of the fine structure remains in the liquid crystal polymer peeled from the substance that forms the fine structure, there is a problem that the structure can be visually recognized even without a verification device such as a polarizer. .

In order to solve the above-described problems, a security device according to claim 1 of the present invention is configured to be incident on a reflective layer that reflects incident light while maintaining polarization, and is formed on the reflective layer. An intermediate layer that transmits light while maintaining polarization, a latent image forming layer formed on the intermediate layer, and a protective layer formed on the latent image forming layer and protecting the latent image forming layer Including an uneven pattern on the surface of the intermediate layer or the protective layer on the side in contact with the latent image forming layer, the latent image forming layer including liquid crystal molecules aligned along the uneven pattern, and a polarizer. A security device that forms a latent image that can be visually recognized when used, wherein at least one of the reflective layer and the intermediate layer has a scattering property to scatter light, and the latent image forming layer is visible. Of ordinary and extraordinary light The minimum rate and n _min, when the maximum value was n _max, the normal light and the abnormal light in the visible region of the intermediate layer or the protective layer in contact with the surface of the latent image formation layer to which the concave-convex pattern is formed The refractive index is n _min −0.2 or more and n _max +0.2 or less.

  The security device according to claim 2 of the present invention is characterized in that the reflective layer is formed by forming a metal thin film on the surface of a base material on which fine irregularities are formed.

  In the security device according to claim 3 of the present invention, the base material is a polyethylene terephthalate film.

  The security device according to claim 4 of the present invention is characterized in that the reflective layer is composed of a single-layer or multilayer dielectric film in which minute irregularities are formed.

  Moreover, the security device according to claim 5 of the present invention is characterized in that the intermediate layer contains a filler.

  In the security device according to claim 6 of the present invention, one or more of the concave / convex patterns are provided, and the concave / convex pattern extends along a direction in which a concave portion and a convex portion extending linearly intersect with the extending direction. The angle formed by the longitudinal direction of the concave portion and the convex portion with respect to a reference line extending on a plane on which the latent image forming layer extends is defined as a pattern angle of the concave / convex pattern. In this case, the concave and convex pattern angles are substantially the same in the entire concave / convex pattern.

  In the security device according to claim 7 of the present invention, at least two of the concave / convex patterns are provided, and the concave / convex pattern extends along a direction in which a concave portion and a convex portion extending linearly intersect with the extending direction. The angle formed by the longitudinal direction of the concave portion and the convex portion with respect to a reference line extending on a plane on which the latent image forming layer extends is defined as a pattern angle of the concave / convex pattern. In this case, the pattern angles of the two concavo-convex patterns are different from each other.

  The security device according to claim 8 of the present invention is characterized in that the pitch of the recesses is 0.1 μm or more and 10 μm or less, and the depth of the recesses is 0.1 μm or more and 1 μm or less.

  The security device according to claim 9 of the present invention is characterized in that the uneven pattern is a diffraction grating or a unidirectional diffusion pattern.

  Further, in the security device according to claim 10 of the present invention, at least two uneven patterns are provided, and the film thicknesses of the portions where the two uneven patterns are formed in the latent image forming layer are substantially equal to each other. It is characterized by.

  Further, in the security device according to claim 11 of the present invention, at least two of the uneven patterns are provided, and the film thicknesses of the portions where the two uneven patterns are formed in the latent image forming layer are different from each other. Features.

  In the security device according to a twelfth aspect of the present invention, the liquid crystal molecules are photopolymerizable nematic liquid crystal molecules, the liquid crystal molecules are aligned along the concavo-convex pattern, and are fixed to the concavo-convex pattern by polymerization. It is characterized by that.

  A security device according to claim 13 of the present invention is characterized in that a polarizer layer is formed on the protective layer, and the polarizer is composed of the polarizer layer.

  The security device according to claim 14 of the present invention is characterized in that the protective layer transmits the incident light while maintaining the polarization property of the incident light.

  Moreover, the verification method of the security device which concerns on Claim 15 of this invention uses the security device in any one of Claims 1-14, and is polarized from the direction inclined with respect to the virtual plane where the said security device extends. The authenticity determination is performed by confirming a latent image that appears when observing through a child.

  A security device verification method according to claim 16 of the present invention uses the security device according to any one of claims 1 to 14, and is polarized from a direction inclined with respect to a virtual plane in which the security device extends. The latent image that appears when observing through the child is confirmed, and the color change of the latent image that occurs when the security device is rotated around a virtual axis that is orthogonal to the virtual plane while maintaining the state. It is characterized in that authenticity is determined by checking.

  Moreover, the printing part which concerns on Claim 17 of this invention is equipped with the security device in any one of Claims 1-14, It is characterized by the above-mentioned.

  In the present invention, the orientation direction of the liquid crystal molecules can be controlled by designing the direction of the concavo-convex pattern to be different for each region. By controlling the refractive index of the layer in contact with the surface having the reversal pattern in the latent image forming layer, it is possible to form a latent image having high design properties and high concealability without using a verifier. is there.

  Hereinafter, the security device of the present invention will be described based on examples.

FIG. 1 shows a typical configuration of the present invention.
An intermediate layer 2 is formed on the reflective layer 1, a latent image forming layer 3 is formed thereon, and a protective layer 4 is formed thereon. At this time, the surface of the latent image forming layer 3 on which the reverse pattern exists is at the interface with the protective layer 4. Note that the reverse pattern is formed by aligning and fixing liquid crystal molecules on the concavo-convex pattern of the latent image forming layer 3 as described later.

  FIG. 2 shows another typical configuration of the present invention. An intermediate layer 2 is formed on the reflective layer 1, a latent image forming layer 3 is formed thereon, a protective layer 4 is formed thereon, and a polarizing layer 5 is further formed thereon. At this time, the surface of the latent image forming layer 3 on which the reverse pattern exists is at the interface with the protective layer 4.

The reflective layer 1 maintains the polarization of light incident on the interface, in other words, reflects the light without disturbing the polarization.
In this example, the structure of the reflective layer 1 is a metal reflective film having minute irregularities, and a characteristic of imparting scattering properties to incident light is given. That is, the reflection layer 1 is provided by imparting scattering properties to the metal reflection film that does not disturb the deflection by minute unevenness. Thereby, the reflective layer 1 has a scattering property to scatter light.
Such a scattering metal reflection layer can be obtained, for example, by forming a thin film of a metal such as aluminum on a minute surface uneven structure by vapor deposition or sputtering. As an example, it is produced by vapor-depositing aluminum on a base material whose surface has been roughened.

  Examples of metals that form such a scattering metal reflective layer include aluminum, platinum, gold, silver, copper, titanium, bismuth, germanium, indium, tin, and the like.

  In addition, examples of the base material on which the surface is roughened include films of polyethylene terephthalate (hereinafter referred to as PET), triacetyl cellulose, polycarbonate, polyester, polyacetate, polystyrene, epoxy resin, and the like.

  In particular, PET is excellent as a base material because it is excellent in mechanical strength, dimensional stability, solvent resistance, processability, and is relatively inexpensive. However, since it has optical anisotropy, it cannot be used for a security device that utilizes polarized light and allows light to pass through the substrate. However, in this embodiment, since the metal thin film is formed on the base material, light does not pass through the base material, so that it can be used.

  The reflective layer 1 may be a single-layer or multilayer dielectric film having minute irregularities. That is, in this case, the reflective layer 2 is provided by imparting scattering properties to a single or multi-layer dielectric film that does not disturb polarization by minute unevenness.

  Such a scattering dielectric layer can be obtained, for example, by depositing a high refractive index material such as zinc sulfide and a low refractive index material such as magnesium fluoride on a minute surface uneven structure.

  The intermediate layer 2 is formed between the reflective layer 1 and the latent image forming layer 3 and improves the adhesion between the reflective layer 1 and the latent image forming layer 3.

  Examples of the material forming the intermediate layer 2 are acrylic, urethane, epoxy resin, vinyl chloride, styrene, cellulose, polyacetate, polyamide, polyimide, polyolefin, polycarbonate, polystyrene. , Polyether-based, polyester-based, phenol-based, and melamine-based resins, and the like, and it is desirable to select in consideration of adhesiveness with the reflective layer 1 and the latent image forming layer 3.

  Further, when it is not possible to select a material having good adhesion to the reflective layer 1 and the latent image forming layer 3 with a single material, it is possible to use a material having good adhesion to the reflective layer 1 on the reflective layer 1 side. The layer A made of a material having good adhesion to the latent image forming layer 3 is formed on the latent image forming layer 3 side, and the layers A and B are further formed according to the adhesion between the layers A and B. By providing a layer in between, adhesion can be improved.

  Further, in this example, the reflective layer 1 is made of a metal reflective film having minute unevenness to give a property of imparting scattering to incident light. However, by adding a filler to the intermediate layer 2 Can give the same effect. In this case, the intermediate layer 2 has a scattering property to scatter light.

  At this time, as an example of the filler contained in the intermediate layer 2, an inorganic material such as silica can be used.

The latent image forming layer 3 is formed by being oriented and fixed along the concavo-convex pattern. At this time, the liquid crystal molecules are aligned so that the major axis direction of the liquid crystal molecules and the groove direction of the concavo-convex pattern are the same direction. Due to the orientation of the liquid crystal molecules, an image that can be observed only through a polarizer, in other words, the inversion pattern is formed.
In other words, the latent image forming layer 3 includes liquid crystal molecules aligned along the concavo-convex pattern, and forms a latent image that can be visually recognized by using a polarizer.
If it demonstrates in detail, the said uneven | corrugated pattern will be formed by alternately arranging the recessed part and convex part which are extended linearly along the direction which cross | intersects those extending directions.

Such a concavo-convex pattern for aligning liquid crystal molecules may have a periodic structure like a diffraction grating, or may be random to some extent like a unidirectional diffusion pattern.
However, the unidirectional diffusion pattern is a structure in which the longitudinal direction of the concavo-convex structure is arranged in one direction on average even though the longitudinal direction is somewhat random.
In addition, regarding the grooves of the concavo-convex pattern, the pitch is 0.1 to 10 μm and the depth is 0.05 to 1 μm.

  As a method for forming the concavo-convex pattern, there are a method of recording a hologram pattern by a two-beam interference method, a method of drawing a diffraction grating pattern by an electron beam, a method of forming a diffraction grating pattern by cutting tools, and the like.

  The concavo-convex pattern formed in this way is produced on a metal plate by electroforming, for example, and a concavo-convex pattern can be reproduced in large quantities by producing an original plate and transferring the pattern from the original plate to a thermoplastic resin by an embossing method. Further, instead of transferring to the thermoplastic resin by an embossing molding method, the pattern may be transferred by a molding method using an ultraviolet curable resin.

As a method for manufacturing the security device shown in FIG. 1, there is a manufacturing method including the following steps.
First, a latent image forming layer material containing liquid crystal molecules is applied on the concavo-convex pattern and cured.
Next, the latent image forming layer is peeled off from the concavo-convex pattern, and a protective layer is laminated on the surface of the latent image forming layer having a reverse pattern and cured.
Next, an intermediate layer and a reflective layer are sequentially laminated on the surface of the latent image forming layer having no reversal pattern (on the surface opposite to the surface on which the protective layer is laminated), and cured to form a security device. Is done.

Another manufacturing method includes the following steps.
First, a latent image forming layer containing liquid crystal molecules, an intermediate layer, and a reflective layer are sequentially laminated on a concavo-convex pattern and cured.
Next, the security device is also formed by peeling the laminate consisting of the latent image forming layer, the intermediate layer, and the reflective layer from the concavo-convex pattern, laminating a protective layer on the reverse pattern on the surface of the latent image forming layer, and curing it. Is possible.

  In addition, the liquid crystal molecules contained in the latent image forming layer 3 are highly fluid and easy to align, and can be cured while maintaining the alignment by light irradiation. A liquid crystal molecule is desirable.

  When the film thickness of the latent image forming layer 3 changes due to the birefringence of the liquid crystal molecules contained in the latent image forming layer 3, the phase difference given to the transmitted light changes. Different colors are observed.

  When it is desired to provide the latent image forming layer 3 with regions having different film thicknesses, for example, when forming an uneven pattern by embossing, for example, by providing regions with different depths to the embossed plate, regions having different film thicknesses are formed. It becomes possible to obtain.

  Further, in this example, the surface on the latent image forming layer 3 where the reverse pattern (uneven pattern) exists is at the interface with the protective layer 4, but the reverse pattern (uneven pattern) on the latent image forming layer 3 exists. Even when the surface is at the interface with the intermediate layer, the same effect can be obtained.

There is a manufacturing method including the following steps as a method for manufacturing a security device in the case of having an uneven pattern at the interface with the intermediate layer.
A latent image forming layer material containing liquid crystal molecules is applied on the concavo-convex pattern and cured.
Next, the latent image forming layer is peeled from the concavo-convex pattern, and an intermediate layer and a reflective layer are sequentially laminated on the surface of the latent image forming layer having a reversal pattern and cured.
Next, a protective layer is laminated on the surface of the latent image forming layer having no reversal pattern and cured.

  By manufacturing in this way, even when the adhesion between the layer having the concavo-convex pattern and the latent image forming layer is poor, the latent image forming layer is adhered to the layer having the concavo-convex pattern by peeling off the latent image forming layer. It is possible to select a material with good properties (intermediate layer or protective layer), and a security device with good adhesion strength can be formed.

  The protective layer 4 is formed on the latent image forming layer 3 to protect the latent image forming layer 3 from deterioration and improve the durability of the security device. In this example, the reverse pattern of the latent image forming layer 3 is provided. Is difficult to see in the absence of a verifier such as a polarizer.

At this time, the closer the refractive index values of the latent image forming layer 3 and the protective layer 4 are, the more difficult it is to recognize the reverse pattern formed on the latent image forming layer 3 without the verifier.
The conditions under which it is difficult to visually recognize the reverse pattern formed on the latent image forming layer 3 without the verifier are as follows.
That is, when the minimum value of the refractive index of normal light and extraordinary light in the visible region of the latent image forming layer 3 is n _min and the maximum value is n _max , the reflective layer 1 or the intermediate layer 2 scatters the incident light. The refractive index of normal light and extraordinary light in the visible region of the reflective layer 1 or the intermediate layer 2 becomes “n _min −0.2 or more and n _max +0.2 or less” by combining with the effect of imparting the property.
Therefore, when the reverse pattern in the latent image forming layer 3 is present at the interface with the protective layer 4, the refractive index of the protective layer 4 is preferably included in the above range.

In this example, since the reversal pattern in the latent image forming layer 3 exists at the interface with the protective layer 4, it is desirable that the refractive index of the protective layer 4 be included in the above range. Is present at the interface with the intermediate layer 2, the refractive index of the protective layer 4 is not limited, and the refractive index range of the intermediate layer 2 is “n _min −0.2 or more and n _max +0.2 or less”. In the case of the range, the reversal pattern formed on the latent image forming layer 3 is difficult to visually recognize in combination with the effect that the reflection layer 1 or the intermediate layer 2 imparts the scattering property to the incident light. Become. Therefore, in this case, it is desirable that the range of the refractive index of the intermediate layer 2 be included in the above range.

  Examples of the material for forming the protective layer 4 include acrylic, urethane, epoxy resin, vinyl chloride, styrene, cellulose, polyacetate, polyamide, polyimide, polyolefin, polycarbonate, polystyrene. , Polyether-based, polyester-based, phenol-based, and melamine-based resins, and the like, and it is desirable to select in consideration of adhesion to the latent image forming layer 3 and required properties.

FIG. 7 shows the results of using various materials having different refractive indexes for the protective layer 4 in this configuration.
The minimum value n _min −0.25 in the refractive index of normal light and extraordinary light in the visible region of the latent image forming layer 3 and the maximum value n _max +0 in the refractive index of normal light and extraordinary light in the visible region of the latent image forming layer 3. When a material having a refractive index of .25 was used as the protective layer 4, the structure of the reversal pattern formed in the latent image forming layer 3 was confirmed.

Further, the minimum value n _min −0.2 in the refractive index of normal light and extraordinary light in the visible region of the latent image forming layer 3 and the maximum value in the refractive index of normal light and extraordinary light in the visible region of the latent image forming layer 3. When a material of n _max +0.2 is used as the protective layer 4, it is possible to recognize the presence of the region in the region where the reversal pattern is formed in the latent image forming layer 3, but the structure of the reversal pattern is confirmed. It became difficult.

Further, the minimum value n _min −0.1 in the refractive index of normal light and extraordinary light in the visible region of the latent image forming layer 3 and the maximum value in the refractive index of normal light and extraordinary light in the visible region of the latent image forming layer 3. When a material of n _max +0.1 was used as the protective layer 4, it was difficult to recognize the region where the reversal pattern formed in the latent image forming layer 3 was formed.

Therefore, in order to make it difficult to recognize the reversal pattern of the latent image forming layer 3, the refractive index of normal light and extraordinary light in the visible region of the layer in contact with the surface having the reversal pattern of the latent image forming layer 3 is determined. The range is preferably “n _min −0.2 or more and n _max +0.2 or less”, and more preferably “n _min −0.1 or more and n _max +0.1 or less”.

  As an embodiment of the verification method of the present invention, FIG. 3 shows an embodiment relating to the latent image forming layer 3 having a configuration in which regions 6a and 6b oriented in the 0 ° and 90 ° directions are arranged.

An image is confirmed through the polarizer 7 and a color change is observed when the security device of the present invention is tilted for observation. That is, the authenticity determination is performed by confirming a latent image that appears when the security device is observed through the polarizer 7 from a direction inclined with respect to the virtual plane in which the security device extends.
The latent image observed at this time has a unique color. This is because the effect derived from the anisotropy of liquid crystal molecules, which is hard to be observed normally, in the latent image forming layer 3 appears remarkably when the reflection layer 1 is observed at an angle.

  Specifically, when viewed from the front through the polarizer 7, the regions 6a and 6b can be observed as latent images, and then when the security device is tilted and observed, for example, 6a is red and 6b is green. Each looks different. At this time, the transmission axis of the polarizer 7 is set to a 45 ° direction.

  FIG. 4 shows another embodiment of the verification method of the present invention. At this time, the configuration of the security device is the same as that shown in FIG.

An image is confirmed through the polarizer 7, a color change when the security device of the present invention is tilted and observed, and a color change when rotated horizontally is observed.
In other words, the latent image that appears when observing through the polarizer 7 from the direction inclined with respect to the virtual plane in which the security device of the present invention extends is confirmed, and the security device is attached to the virtual device while maintaining the state. The authenticity is determined by confirming the color change of the latent image that occurs when the image is rotated about a virtual axis orthogonal to the plane.
The image observed at this time has a unique color, and changes in color when rotated. This is because rotating the security device of the present invention produces the same effect as rotating the alignment direction of the liquid crystal molecules. Since the observed color is derived from the alignment direction of the liquid crystal molecules, the observed color changes when the alignment direction is different.

Specifically, the colors observed at this time are those in which 6a before rotation is red and 6b is green, but after 90 ° rotation, 6a is green and 6b is red.
This is because rotating the security device by 90 ° produces the same effect as rotating the alignment direction of the liquid crystal molecules contained in the latent image forming layer 3 by 90 °.

  Further, these observed colors can be controlled by the alignment direction and film thickness of the liquid crystal molecules contained in the latent image forming layer 3, the transmission axis direction of the polarizer 7, and the like.

  Further, when the polarizer 7 is configured as the polarizing layer 5 in advance, the same effect can be obtained.

FIG. 5 shows a layer structure which is one embodiment of the security device. A latent image forming layer 3 is formed on the intermediate layer 2 formed on the reflective layer 1. Further, the latent image forming layer 3 is formed with two regions having the same film thickness in which liquid crystal molecules are aligned by a concavo-convex pattern having pattern angles of 0 ° and 90 °, respectively.
If it demonstrates in detail, the uneven | corrugated pattern will be formed by arranging the recessed part and convex part which are extended linearly alternately along the direction which cross | intersects those extension directions. The pattern angle refers to an angle formed by the longitudinal direction of the concave portion and the convex portion with respect to a reference line extending on a plane on which the latent image forming layer 3 extends. And the pattern angle of the said recessed part and a convex part is substantially the same in the whole uneven | corrugated pattern.

  At this time, when the security device is observed through the polarizer 7 and tilted, a difference in color resulting from a difference in the alignment direction of the liquid crystal is observed in two regions having different pattern angles.

  FIG. 6 shows a layer configuration which is one embodiment of the present security device. A latent image forming layer 3 is formed on the intermediate layer 2 formed on the reflective layer 1. Further, the latent image forming layer 3 is formed with two regions having different film thicknesses in which liquid crystal molecules are aligned by an uneven pattern having a pattern angle of 90 °.

  At this time, when the security device is observed through the polarizer 7 and tilted, it is derived from the fact that the thickness of the liquid crystal contained in the latent image forming layer is different in two regions where the thickness of the latent image forming layer 3 is different. A color difference is observed.

Here, the difference in color resulting from the difference in film thickness of the liquid crystal will be described.
This is because the phase difference caused by the birefringence of the liquid crystal depends on the film thickness and wavelength,
It is clear from the following formula.
Re = Δnd
(Δn = ne−no)
I = I ₀ sin ² (2θ) sin ² (Reπ / λ)
Re: phase difference Δn: birefringence d: liquid crystal film thickness ne: ordinary light refractive index no: extraordinary light refractive index I: incident light intensity I ₀ : transmitted light intensity θ: liquid crystal alignment direction and polarizing plate transmission Axis angle λ: wavelength

  5 and 6, only one of the alignment direction and the film thickness of the liquid crystal molecules included in the latent image forming layer 3 is different. Is possible.

  As the liquid crystal material, a photopolymerization type nematic liquid crystal is desirable. After applying and orienting on the concavo-convex pattern, the orientation can be fixed by exposing with an ultraviolet lamp or the like.

  In addition, printed matter that requires security, such as securities, banknotes, identification cards, credit cards, etc. equipped with the security device of the present invention has a visual effect different from normal printing and prevents counterfeiting due to copying, etc. The authentication can be performed by the security device verification function of the present invention.

  The best mode for carrying out the present invention has been described above with reference to the accompanying drawings, but the present invention is not limited to this configuration. Various modifications and modifications can be conceived within the scope of the invented technical idea of the claims, and these also belong to the technical scope of the present invention.

It is the schematic of the layer structure in the Example of this security device. It is the schematic of the layer structure in the Example of this security device. It is the schematic of the verification method of this security device. It is the schematic of the verification method of this security device. It is the schematic of the layer structure in the Example of this security device. It is the schematic of the layer structure in the Example of this security device. It is explanatory drawing which shows whether the refractive index and pattern recognition in the layer which contact | connects a reverse pattern are possible.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Reflective layer, 2 ... Intermediate layer, 3 ... Latent image forming layer, 4 ... Protective layer, 5 ... Polarizing layer, 6a, 6b ... Reverse pattern, 7 ... Polarizer.

Claims (17)

A reflective layer that reflects incident light while maintaining polarization;
An intermediate layer formed on the reflective layer and transmitting incident light while maintaining the polarization;
A latent image forming layer formed on the intermediate layer;
A protective layer formed on the latent image forming layer and protecting the latent image forming layer,
It has a concavo-convex pattern on the surface of the intermediate layer or the protective layer on the side in contact with the latent image forming layer,
The latent image forming layer includes a liquid crystal molecule aligned along the uneven pattern, and is a security device that forms a latent image that can be visually recognized by using a polarizer,
At least one of the reflective layer and the intermediate layer has a scattering property to scatter light,
When the minimum value of the refractive index of normal light and extraordinary light in the visible region of the latent image forming layer is n _min and the maximum value is n _max , the latent image forming layer is in contact with the surface of the latent image forming layer on which the uneven pattern is formed. The refractive index of normal light and extraordinary light in the visible region of the intermediate layer or the protective layer is n _min −0.2 or more and n _max +0.2 or less,
A security device characterized by that. The reflective layer is formed by forming a metal thin film on the surface of the base material on which fine irregularities are formed.
The security device according to claim 1. The substrate is a polyethylene terephthalate film;
The security device according to claim 2. The reflective layer is composed of a single-layer or multilayer dielectric film in which minute irregularities are formed,
The security device according to claim 1. The intermediate layer contains a filler;
The security device according to any one of claims 1 to 4. One or more of the concave and convex patterns are provided;
The concavo-convex pattern is formed by alternately arranging concave and convex portions extending linearly along a direction intersecting the extending direction,
When the angle formed by the longitudinal direction of the concave and convex portions with respect to a reference line extending on the plane on which the latent image forming layer extends is the pattern angle of the concave and convex pattern, the entire concave and convex pattern The pattern angles of the concave and convex portions are substantially the same,
The security device according to any one of claims 1 to 5. At least two uneven patterns are provided,
The concavo-convex pattern is formed by alternately arranging concave and convex portions extending linearly along a direction intersecting the extending direction,
When the angle formed by the longitudinal direction of the concave portion and the convex portion with respect to a reference line extending on a plane on which the latent image forming layer extends is a pattern angle of the concave / convex pattern, the pattern of the two concave / convex patterns The angles are different from each other,
The security device according to any one of claims 1 to 5. The pitch of the recesses is 0.1 μm or more and 10 μm or less, and the depth of the recesses is 0.1 μm or more and 1 μm or less.
The security device according to any one of claims 1 to 7. The uneven pattern is a diffraction grating or a unidirectional diffusion pattern,
The security device according to any one of claims 1 to 8. At least two uneven patterns are provided,
Of the latent image forming layer, the thicknesses of the portions where the two concavo-convex patterns are formed are substantially equal to each other.
The security device according to any one of claims 1 to 9. At least two uneven patterns are provided,
Of the latent image forming layer, the thicknesses of the portions where the two concavo-convex patterns are formed are different from each other.
The security device according to any one of claims 1 to 9. The liquid crystal molecule is a photopolymerizable nematic liquid crystal molecule,
The liquid crystal molecules are aligned along the concavo-convex pattern and fixed to the concavo-convex pattern by polymerization.
The security device according to claim 1, wherein: A polarizer layer is formed on the protective layer,
The polarizer is composed of the polarizer layer,
The security device according to any one of claims 1 to 12.   The security device according to claim 1, wherein the protective layer transmits the incident light while maintaining polarization. A security device according to any one of claims 1 to 14 is used to confirm the latent image that appears when observing through a polarizer from a direction inclined with respect to a virtual plane in which the security device extends. Make a false decision,
And a security device verification method. Using the security device according to any one of claims 1 to 14, confirming a latent image that appears when observing through a polarizer from a direction inclined with respect to a virtual plane in which the security device extends, and The authenticity determination is performed by checking the color change of the latent image that occurs when the security device is rotated around a virtual axis orthogonal to the virtual plane while maintaining the state.
And a security device verification method. The security device according to claim 1.
Printed matter characterized by that.

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