JP2018013706A - Display medium, article attached with the display medium, and display method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a display medium in which display of optical image information can be varied as desired even when the display is observed from the same view field or observed from the top side and the back side.SOLUTION: The display medium includes an image display part and a power supply part for supplying electric power to the image display part. The image display part includes: a light control element layer capable of controlling reflection and transmission of light by a voltage; and a diffraction structure layer where optical image information is recorded. The diffraction structure layer is disposed on the top and back surfaces of the light control element layer; and the power supply part is connected to the light control element layer. Otherwise, the display medium includes the plurality of laminated image display parts, and the power supply part for supplying electric power to the image display parts. Each image display part includes: the light control element layer capable of controlling reflection and transmission of light by a voltage; and the diffraction structure layer where the optical image information is recorded. The diffraction structure layer is disposed at least one of the top and back surfaces of the light control element layer; and the power supply part is connected to the light control element layer.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a display medium having a diffractive structure layer on which optical image information is recorded.

  In recent years, it is possible to easily determine the authenticity at a glance by attaching it to an article (forgery prevention object), and since it is easy to handle, diffractive structures on which diffraction grating patterns are recorded are widely used as a forgery prevention means. It is used. Examples of the diffractive structure employed as such anti-counterfeiting means include a peelable layer having a releasability on a substrate, a diffractive structure forming layer having a diffraction grating formed thereon, a reflective layer having a metallic luster, and an adhesive layer. There is a structure in which a diffraction structure is formed into a transfer foil by laminating sequentially (see, for example, Patent Document 1).

  In addition, some transparent diffraction gratings that are positioned below the reflective layer by forming a transparent metal vapor-deposited thin film or an inorganic compound thin film on the reflective layer can be visually observed through the diffraction grating. (For example, refer to Patent Document 2).

  However, since these diffractive structures used in the prior art are all formed in a predetermined pattern of a vapor-deposited thin film or a transparent metal thin film having a metallic luster, the diffractive structure The only visual change was a change in pattern or color due to a change in viewing angle previously recorded in the diffraction structure. That is, in order to obtain a diffracted light pattern which is an optical visual effect by the diffractive structure, the reflection layer in contact with the diffractive structure layer is laminated on the entire surface or in an arbitrary shape in a pattern, so that the transmission density of the reflection layer or The reflection density was constant without changing. Furthermore, in the reflective layer made of a conventional transparent metal thin film, the visibility of the image by printing or the like located in the lower layer and the visibility of the diffracted light pattern are in a trade-off relationship from the relationship between the reflected light and the transmitted light, respectively. It was necessary to compromise on the compatibility of visibility.

  In addition, there are also two types of diffractive structures that are bonded together so that different patterns can be observed on the front and back sides (see, for example, Patent Document 3).

  On the other hand, in recent years, in order to reduce energy consumption, development of light control glass aiming at improvement of heat insulation by a light shielding effect is progressing. The light control glass can be realized by forming a light control mirror element in which a thin film material is combined on the glass so that optical characteristics can be arbitrarily controlled. It can be formed not only on but also on a plastic film that can be folded. (See, for example, Patent Document 4, Non-Patent Document 1, etc.) The applications of these light control mirror elements are currently limited to electronic display devices such as automobile and building window glass, liquid crystal displays, etc. It is not applied to the use of.

JP-A-61-190369 Japanese Patent Publication No. 1-54709 JP 2009-134094 A JP 2014-112183 A

Adv. Mater. 2012, 24, OP122-OP126, S. Araki et al.

  In view of the above, the present invention uses a display medium capable of arbitrarily changing the display of recorded optical image information during observation from the same field of view or during both front and back observations, and the same. An object is to provide an image display method.

The first aspect of the present invention is:
(A) an image display unit;
(B) a power supply unit for supplying power to the image display unit;
A display medium comprising:
The image display unit is
(A-1) a light control element layer capable of controlling reflection and transmission of light by voltage;
(A-2) a diffractive structure layer in which optical image information is recorded,
The diffractive structure layer is provided on both front and back surfaces of the light control element layer,
The power supply unit is connected to the light control element layer;
This is a display medium characterized by the above.

The second aspect of the present invention is:
(A) a plurality of stacked image display units;
(B) a power supply unit for supplying power to the plurality of image display units;
A display medium comprising:
Each of the image display units
(A-1) a light control element layer capable of controlling reflection and transmission of light by voltage;
(A-2) a diffractive structure layer in which optical image information is recorded,
The diffractive structure layer is provided on at least one of the front and back surfaces of the light control element layer;
The power supply unit is connected to each of the light control element layers,
This is a display medium characterized by the above.

    Another aspect of the present invention is an article to which the display medium of the first aspect or the second aspect of the present invention is attached.

    Further, according to a further aspect of the present invention, by using the display medium of the first aspect or the second aspect of the present invention and changing the voltage from the power supply unit to the dimming element layer, the diffraction structure layer is previously formed. This is a method for displaying recorded optical image information.

(First embodiment of the present invention)
In the first aspect of the present invention, the diffractive structure layers on which optical image information is recorded are provided on both the front and back surfaces of the light control element layer that controls the reflection and transmission of light by voltage.

  For this reason, when the light control element layer is in a certain power supply state (for example, a power supply state), the image observed from the front side and the image observed from the back side are different from each other. An image can be displayed. On the other hand, when the power supply state is different (for example, the power non-supply state), the light control element layer is transparent and the optical image information recorded on the diffractive structures on both the front and back sides is hardly visible, The opposite side of the observation surface can be seen through.

(Second embodiment of the present invention)
In the second aspect of the present invention, there are two or more image display units each including a diffractive structure layer in which optical image information is recorded, and a dimming element layer that controls reflection and transmission of light with voltage. It is configured by stacking. For this reason, it is possible to provide more various optical image information than the first aspect of the present invention.

  In a more preferred embodiment of the second aspect of the present invention, it is also possible to display optical image information of any combination by controlling the power supply to the light control element layer of each image display unit. It becomes.

  For example, in a more preferable embodiment in which power is independently supplied to a plurality of light control element layers, an image that can be viewed from the same field of view can be changed in various ways with a plurality of patterns. .

  Further, as a more preferable embodiment, one embodiment in which optical image information is aligned between any two or more diffractive structure layers; or the light control element layer controls reflection and transmission of light by voltage. One embodiment can be given that has a controllable partial region of constant shape and a residual uncontrollable partial region. In these embodiments, due to a change in the power supply pattern to the light control element layer, only a part of the optical image information is changed before and after the visible optical image information is switched to express movement and change. Display is possible, and different optical image information can be displayed on the front and back sides.

(Other aspects of the present invention)
Furthermore, in another aspect of the present invention, an article having the display medium of the present invention attached thereto or the display medium of the present invention is used to change the voltage from the power supply unit to the dimming element layer in advance to the diffraction structure layer. A method of displaying recorded optical image information is provided, and can be used in the fields of authentication, anti-counterfeiting, decoration, toys, learning materials, and the like, for example, without being limited thereto.

It is the schematic showing the structure of the display medium 1 (one embodiment of the 1st aspect of this invention). In the display medium 1 (one embodiment of the first aspect of the present invention), when the dimming element layer 14 is in a transparent state (14a), it is a plan view observed from the front side surface and the back side surface. In the display medium 1 (one embodiment of the first aspect of the present invention), when the dimming element layer 14 is in a mirror state (14b), it is a plan view observed from an observation angle with a front side surface. In the display medium 1 (one embodiment of the first aspect of the present invention), when the light control element layer 14 is in a mirror state (14b), it is a plan view observed from an observation angle with a back side surface. In display medium 1 (one embodiment of the 1st mode of the present invention), it is a schematic diagram showing the state of light in case light control element layer 14 is in a transparent state (14a). In display medium 1 (one embodiment of the 1st mode of the present invention), it is a schematic diagram showing the state of light in case light control element layer 14 is in a mirror surface state (14b). It is the schematic showing the structure of the display medium 2 (one embodiment of the 2nd aspect of this invention). In the display medium 2 (one embodiment of the second aspect of the present invention), when both the light control element layers 15 and 16 are in a transparent state (15a and 16a), the plane is observed from the front side surface and the back side surface. FIG. In display medium 2 (one embodiment of the 2nd mode of the present invention), it is a top view observed from the back side, when light control element layer 16 is a mirror surface state (16b). In display medium 2 (one embodiment of the 2nd mode of the present invention), it is a schematic diagram showing the state of light in case light control element layers 15 and 16 are both transparent (15a and 16a). In display medium 2 (one embodiment of the 2nd mode of the present invention), it is a schematic diagram showing the state of light in case light control element layers 15 and 16 are both specular states (15b and 16b). In the display medium 2 (one embodiment of the second aspect of the present invention), the light state when the dimming element layer 15 is in the transparent state (15a) and the dimming element layer 16 is in the specular state (16b). FIG. In the display medium 2 (one embodiment of the second aspect of the present invention), the light state when the light control element layer 15 is in the mirror state (15b) and the light control element layer 16 is in the transparent state (16a) is shown. It is a schematic diagram representing It is the schematic showing the structure of the display medium 3 (one embodiment of the 2nd aspect of this invention). In the display medium 3 (one embodiment of the second aspect of the present invention), a part of the light control element layer 15 is in a mirror state and the other part is in a transparent state (15c), and the light control element layer 16 is in a mirror state ( 16b) is an example of a plan view observed (19b) from an observation angle having a front side surface in the case of 16b) (see FIG. 20). In the display medium 3 (one embodiment of the second aspect of the present invention), the light control element layer 15 is in the transparent state (15a) and the light control element layer 16 is in the mirror surface state (16b) (see FIG. 21). FIG. 9 is a plan view observed (19b) from an observation angle having a front side surface. In the display medium 3 (one embodiment of the second aspect of the present invention), a part of the light control element layer 15 is in a mirror state, the other part is in a transparent state (15c), and the light control element layer 16 is in a transparent state ( It is the top view observed (19a, 19b) from the observation angle with a front side surface in the case of 16a) (see FIG. 22). In the display medium 3 (one embodiment of the second aspect of the present invention), a part of the light control element layer 15 is in a mirror state, the other part is in a transparent state (15c), and the light control element layer 16 is in a transparent state ( It is the top view observed (20a, 20b) from the observation angle which has a back side surface in the case of 16a) (refer FIG. 22). In display medium 3 (one embodiment of the 2nd mode of the present invention), it is a schematic diagram showing a light state in case light control element layers 15 and 16 are both in a transparent state (15a and 16a). In the display medium 3 (one embodiment of the second aspect of the present invention), a part of the light control element layer 15 is a mirror surface and the other part is transparent (15c), and the light control element layer 16 is a mirror surface state (16b). It is the schematic showing the state of the light in case of. In the display medium 3 (one embodiment of the second aspect of the present invention), the light state when the light control element layer 15 is in the transparent state (15a) and the light control element layer 16 is in the specular state (16b) is shown. FIG. In the display medium 3 (one embodiment of the second aspect of the present invention), a part of the light control element layer 15 is a mirror surface and the other part is transparent (15c), and the light control element layer 16 is transparent (16a It is the schematic showing the state of the light in case of. The display medium 1 (one embodiment of the first aspect of the present invention) is provided on a product support 42 and includes a cover member 43 (see FIG. 24), and the light control element layer 14 is in a mirror state (14b). It is a top view from an observation angle with a front side of article 50 concerning Example 1 when there is (refer to Drawing 6). It is sectional drawing at the time of cut | disconnecting the article | item 50 of FIG. 23 by the XXV line. The display medium 2 (one embodiment of the second aspect of the present invention) is provided on the product support 42 and provided with a cover member 43 (see FIG. 26), and the light control element layer 15 is adjusted in a transparent state (15a). It is a top view seen from the observation angle with the front side of the article | item 51 which concerns on Example 2 when the optical element layer 16 is a mirror surface state (16b) (refer FIG. 12). It is sectional drawing at the time of cut | disconnecting the article | item 51 of FIG. 25 by the XXVII line. The display medium 3 (one embodiment of the second aspect of the present invention) is provided on the product support 42 and includes a cover member 43 (see FIG. 28), and a part of the light control element layer 15 is a mirror surface. Is a plan view seen from an observation angle with the front side of the article 52 according to Example 3 when the portion is in a transparent state (15c) and the dimming element layer 16 is in a mirror state (16b) (see FIG. 20). is there. It is sectional drawing at the time of cut | disconnecting the articles | goods 52 of FIG. 27 with the XXIX line.

  DESCRIPTION OF EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

  The following embodiment is merely an example of the present invention, and those skilled in the art can change the design as appropriate.

[I. Basic Components Common to Aspects of the Present Invention]
FIG. 1 is a schematic diagram showing a configuration of a display medium 1 which is an embodiment belonging to the first aspect of the present invention.

  7 and 14 are schematic views showing the configurations of the display medium 2 and the display medium 3, which are different embodiments belonging to the second aspect of the present invention.

(Diffraction structure layer)
The diffractive structure layers (10, 11) are light transmissive members each having a diffractive structure (12, 13).

  As will be described later, when the light control element layer is in the mirror state (14b, 15b, 16b), diffracted light is generated by the incidence of light on the diffractive structure (12, 13) in which the optical image information is recorded. The diffracted light displays an image that can be stereoscopically viewed in 2D or 3D.

  The optical image information recorded on the diffractive structure (12, 13) may be singular or plural. When there are a plurality of optical image information to be recorded, the display medium of the present invention arbitrarily changes an image that can be viewed during observation from the same field of view by controlling the light control element layers (14, 15, 16) described later. can do.

  Here, in the present invention, “optical image information” refers to 2D or 3D visually recognizable image information displayed by diffracted light generated when light enters the diffractive structure (12, 13). . In detail, it is composed of patterns, characters, and visually recognizable patterns including color changes.

  In the present invention, “image” refers to information that can be recognized visually, and includes characters, patterns, colors, and shapes in addition to pictorial images such as illustrations. Furthermore, the image of the present invention is not limited to the image displayed by the diffracted light, but also includes an image formed on a print layer, which will be described later, and the color of each component.

  The diffractive structure layers (10, 11) and diffractive structures (12, 13) of the present invention can be formed by materials and forming methods known in the art.

  As a material for forming the diffractive structure layers (10, 11) of the present invention, a thermoplastic resin, a thermosetting resin, an ultraviolet ray, an electron beam curable resin, or the like, which is preferably a light transmitting material, can be used. For example, acrylic resins include acrylic resins, epoxy resins, cellulose resins, vinyl resins, and the like. Examples of thermosetting resins that can be used include urethane resins, melamine resins, and phenol resins that are crosslinked by adding polyisocyanate as a crosslinking agent to acrylic polyols or polyester polyols having reactive hydroxyl groups. Further, as the ultraviolet ray or electron beam curable resin, epoxy (meth) acryl, urethane (meth) acrylate, or the like can be used. With these materials as main materials, the diffractive structure layers (10, 11) can be formed by a known coating method such as a gravure printing method or a micro gravure method.

  As a method for recording optical image information on the diffractive structure layers (10, 11), a method well known in the art can be used. For example, although not limited to these, the diffractive structure (12, 13) which is a fine concavo-convex structure may be formed directly on the diffractive structure layer (10, 11) or obtained by coherent light. A photographic material on which the diffracted light of the obtained image is recorded may be incorporated in the diffractive structure layer (10, 11).

  When optical image information is recorded using the diffractive structure (12, 13), it is preferable to use a relief plate to form the diffractive structure (12 and 13) which is a fine concavo-convex structure. In the relief plate, first, the surface of the electron beam curable resin is irradiated with an electron beam, exposed in a desired pattern, and then developed to produce a master plate. Subsequently, the surface of the master plate is electroplated. It is produced by forming a metal film by the method and replicating the concave / convex pattern of the master plate. A diffraction structure having a fine concavo-convex structure can be obtained by thermocompression bonding the relief plate to the material for forming the diffractive structure (10, 11) or by curing the relief plate in close contact with an uncured curable resin. (12, 13) is formed.

(Dimmer element layer)
The light control element layers (14, 15, 16) of the present invention control light transmission and reflection by voltage, for example, change from a transparent state (14a, 15a, 16a) to a specular state (14b, 15b, 16b). be able to. Therefore, the control method is not limited as long as transmission and reflection of light can be controlled by voltage. For example, an electrochromic type that is electrically switched and a gaschromic type that is switched by an ambient gas can be used. From the viewpoint of convenience and safety, an electrochromic type is preferable, and an all-solid electrochromic dimming mirror in which the entire layer is made of solid instead of liquid or gas is more preferable.

  The electrochromic light control mirror may have a structure known in the art, for example, a light control mirror layer / catalyst layer / electrolyte layer / ion accumulation layer / conductive layer laminated in this order, or a light control mirror A layer laminated in the order of layer / catalyst layer / buffer layer / electrolyte layer / ion accumulation layer / conductive layer can be used.

  Gaschromic and electrochromic dimming mirror layers include rare earth metals such as yttrium and lanthanum, hydrides of rare earth metals and magnesium alloys, magnesium and transition metal alloys, and magnesium and nickel alloys. However, an alloy of magnesium and nickel can be preferably used as the material of the light control element in the electrochromic light control mirror.

  The catalyst layer material is palladium or platinum, the electrolyte layer material is tantalum oxide or zirconium oxide, the ion storage layer is tungsten oxide, the transparent conductive film is indium oxide, tin oxide, or oxide. Zinc and the like can be used respectively. Any thin film can be applied to a known method for obtaining a desired thickness, such as a vacuum evaporation method or a sputtering method, but is not particularly limited to these layer structures, materials, and manufacturing methods.

  Depending on the material configuration, some may become a mirror surface when a voltage is applied in a certain direction (+), while others may become transparent. Furthermore, after applying a voltage in a certain direction to make it mirror or transparent, it is sufficient to turn off the power to switch between mirror / transparent, or transparent / mirror, and voltage is applied in the opposite direction (-). Some things have to be done. In the invention of this aspect, any of these material configurations may be used.

  The light control element layers (14, 15, 16) of the present invention may be adjacent to the diffractive structure portion in one embodiment of the present invention, and may be a diffractive structure layer as long as they do not prevent light transmission. A transparent layer (not shown) such as an adhesive layer may be optionally inserted between (10, 11). Further, a printing layer (not shown) may be incorporated. However, from the viewpoint of the brightness of the optical image obtained by reflection, the light control element layer and the diffractive structure (12, 13) are adjacent as much as possible, or any transparent layer and diffractive structure layer (10, 11) to be inserted. It is preferable that the difference in refractive index with

  The light control element layer (14, 15, 16) of the present invention may be capable of controlling the transmission and reflection of light by an external voltage in the entire light control element layer, but at least one light control element layer of the present invention is It may have a controllable partial region having a certain shape (patterned), and the remaining partial region may be an uncontrollable region (for example, the light control element layer 15 of the display medium 3 of Example 3).

  Alternatively, the controllable partial region may be formed of a plurality of regions, and in this case, the controllable region may not necessarily be included.

(Power supply unit)
The power supply unit 17 of the present invention is connected to the light control element layers 14 to 16 at the connection part 18, and controls the transmission and reflection of light of the light control element layers (14, 15, 16) as the voltage changes. For example, the mirror surface state and the transparent state can be switched.

  The power supply unit 17 only needs to be able to apply a voltage sufficient to change the light transmission / reflection state of the light control element layer (14, 15, 16). For example, the power supply unit 17 is connected to external power. For example, an antenna part that can generate an alternating current by an external electromagnetic wave, a solar battery, and a paper battery can be used. That is, the connection with the light control element layer includes not only a wired connection but also a wireless connection.

  When a voltage is applied in a certain direction (+) from the power supply unit 17 to the dimming element layer (14, 15, 16), the dimming element layer (14, 15, 16) is in a certain state, for example, a mirror surface state ( 14b, 15b, 16b), the diffracted light generated through the diffractive structure (12, 13) is reflected, and the optical image information recorded in the diffractive structure (12, 13) is displayed by the diffracted light. (See FIG. 3, FIG. 4, FIG. 15, FIG. 16 etc.). On the other hand, when no voltage is applied from the power supply unit 17 to the dimming element layer (14, 15, 16), or when a voltage is applied in the opposite direction (-), the dimming element layer (14, 15, 16) is applied. ) Is another state, for example, a transparent state (14a, 15a, 16a), and light is transmitted (see FIGS. 5, 10, and 19).

  Further, when the antenna unit is built in the power supply unit 17, for example, when the display medium (1, 2, 3) of the present invention is brought close to a device that emits electromagnetic waves or magnetic fluxes, it is adjusted even in a non-contact state. A voltage is applied to the optical element layers (14 to 16), and an image of the diffractive structure (12, 13) can be displayed. The antenna unit receives an electromagnetic wave or magnetic flux from the outside and generates an alternating current. The antenna unit rectifies the alternating current generated by the antenna 31 and converts it into direct current. And an IC chip 32 (FIGS. 23 to 28).

  As the material of the antenna 31, a known conductive metal material such as copper, silver, or aluminum can be used. The IC chip 32 has a rectifying function and a constant voltage holding function, and further includes a plurality of light control element layers. In some cases, it has a function of controlling the power supply of the individual light control element layers, and a thinner and smaller one can be suitably used.

  As a method for manufacturing the antenna 31, for example, a layer made of a resin material is formed in advance as an antenna base layer, a metal thin film is formed on the resin layer, and then a masking agent having a desired antenna shape is formed on the metal thin film. Then, an unnecessary metal thin film is dissolved and removed by using an etching method. Finally, the mask agent is removed to produce the antenna 31, and the IC chip 32 can be connected and fixed thereto.

  As another method, a light control element layer and a diffractive structure layer are formed in advance on the resin layer, and the light control element layer and the IC chip 32 are laminated, and then the IC chip. The antenna 31 may be manufactured by applying a conductive ink containing conductive metal particles by a screen printing method or a gravure printing method so as to be connected to another terminal.

  Furthermore, in one embodiment of the present invention, the power supply unit 17 of the present invention may provide a common set of terminals even when there are a plurality of dimming element layers, or a plurality of dimming element layers may be provided. Each terminal may be provided individually. The latter is more preferable from the viewpoint of various image displays. In addition, the light control element layer may be patterned to have a plurality of controllable partial regions having a fixed shape, and may include a plurality of terminals corresponding to each of the plurality of controllable portions.

  When the power supply unit 17 includes a plurality of terminals, the display medium according to the second aspect of the present invention (for example, the display medium 2 of Example 2) controls the power supply to those terminals corresponding to the display state, The IC chip 32 may be provided with a function for processing it. With such a function, for example, signal patterns of a plurality of dimming element layers (15 and 16) patterned in advance are selected, and a pattern signal of the pattern is transmitted from the outside of the display medium 2. Next, the antenna 31 of the display medium 2 receives the pattern signal together with the driving power for the light control element layers (15 and 16) and sends it to the IC chip 32. The IC chip 32 further processes the signal and supplies the power. The voltage applied to the dimming element layers (15 and 16) from 17 is controlled, and the dimming element portion layers (15 and 16) can individually change the pattern state according to the applied voltage.

[II. Other optional components]
The display media of the present invention, for example, the display media 1 to 3 of Examples 1 to 3, may further include arbitrary components as long as they do not interfere with the above configuration and functions. For example, although constituent elements described below may be provided, those skilled in the art can understand that the present invention is not limited thereto.

(Adhesive member / Adhesive layer)
The adhesive member is used, for example, for sticking the display medium of the present invention, for example, the display media 1 to 3 of Examples 1 to 3 to a base material. The adhesive member may be formed as the adhesive layer 41 on the lowermost layer of the display medium of the present invention, for example, the display media 1 to 3 (see FIGS. 24, 26, and 28). It may be an adhesive transparent cover member 43 to be attached to the material (see FIGS. 24, 26, and 28). A material known in the art can be used for the adhesive member, and depending on the object to be pasted, a pressure-sensitive type or heat-sensitive type adhesive can also be used.

(Product support)
The product support 42 is used as a release paper or a release film for protecting the adhesive surface when the display medium of the present invention, for example, the display media 1 to 3 of Examples 1 to 3 have the above adhesive member. It is. As materials used for the product support 42, release paper obtained by applying a release material to high-quality paper, coated paper, non-woven fabric, etc., vinyl chloride resin, polyester terephthalate resin (commonly known as PET), polyethylene resin, etc. are made into a film. A release film provided with a release layer (release layer) can be used, and when a non-transparent material is used as a base material, when a display medium is applied, a diffraction structure is formed from the opposite surface to which the display medium is applied. It is preferable to drill a base material to form an observation window (for example, the window opening 46) that can be observed.

(Hidden layer)
The concealing layer 44 is a layer for the purpose of concealing the antenna 31 and the IC chip 32 provided in the antenna portion to improve the design (see FIGS. 23 to 28). A known material can be used as long as the interlayer adhesion with the other layer in contact and the concealability are compatible. For example, commercially available white ink for printing or silver ink for concealment can be used.

(Print layer)
The print layer 45 is a layer for visually recognizing the shape of characters, illustrations, patterns, and the like. The print layer 45 can be formed at any position on the display medium of the present invention, for example, the display medium 1 to 3 and any position on the product support 42 in consideration of the decorativeness and / or functionality.

The printed layer 45 has good visual visibility, and good adhesion to the directly contacting layers such as the light control element layers (14 to 16) and the diffractive structure layers (10, 11). As long as there is a known material, a commercially available printing ink can be used. The forming method can also be formed by a known printing method such as a relief printing method, a gravure printing method, an offset printing method, or a screen printing method.

(Brittle part)
The brittle portion (not shown) is easily damaged when the display medium of the present invention attached to the base material, for example, the display media 1 to 3 is peeled off from the base material by a physical or chemical method. It is a part that makes it impossible to replace the.

  For example, a part of the resin layer of the display medium 1 to 3 is provided with an extremely thin part, a flexible resin layer having high elasticity and a flexible part is provided, or a part that is partially broken is provided. By doing so, at least a part of the display medium of the present invention can be made physically brittle. Further, by forming at least one layer constituting the display medium with a material that is easily dissolved in an arbitrary organic solvent that does not dissolve the adhesive layer, a layer that is easily damaged can be provided.

  The brittle portion can be provided in any layer or portion of any embodiment of the invention. For example, in the display medium 2 illustrated in FIG. 7, a brittle portion may be provided between the diffractive structure layer 11 and the dimming element layer 15 or between the diffractive structure layer 11 and the dimming element layer 16. Further, the brittle portion may be patterned in advance so that a specific pattern is generated when it is damaged.

[III. Preferred embodiment]
The display medium of the present invention includes preferred embodiments described below. By having such a structure, it can be used for anti-counterfeiting, decoration, toys, educational materials, and the like.

[III-1: Basic configuration of the first aspect of the present invention]
The display medium according to the first aspect of the present invention includes an image display unit and a power supply unit 17, and the image display unit is provided with a light control element layer 14 and diffraction provided on both front and back surfaces of the light control element layer. And structural layers (10, 11) (see, for example, FIG. 1).

  As the light control element layer 14, the light control element part layer which is an electrochromic type light control mirror as mentioned above is preferable.

  The power supply unit 17 and the light control element layer 14 are electrically connected, but may be wired connection or wireless connection. In the latter case, the antenna unit as described above can be employed as the power supply unit.

  The power supply unit 17 may be a power supply unit for connecting to external power, a power supply unit that is a solar cell, or a power supply unit that is a paper battery.

As an example of a preferable combination in the display medium of the first aspect of the present invention,
A combination of a diffractive structure layer / a dimming element layer that is an electrochromic dimming mirror / a power supply unit that is a terminal for connecting to external power;
A combination of a diffractive structure layer / a dichromator layer that is an electrochromic dimmer mirror / a power supply unit that is an antenna unit;
A combination of a diffractive structure layer / a dimmer element layer that is an electrochromic dimmer mirror / a power supply unit that is a solar cell;
A diffractive structure layer / a light control element layer that is an electrochromic light control mirror / a power supply unit that is a paper battery, and the like.

  The display medium 1 which is an example of this aspect will be described more specifically. In the first aspect of the present invention, the light reflection of the light control element layer is controlled by controlling the voltage applied to the light control element layer. -The degree of transmission can be changed, whereby the degree of imaging by diffracted light of the optical image information recorded in the diffractive structure layer can be changed. In the examples, as a more preferable embodiment, a case where the light control element layer is in the transparent state 14a and the mirror state 14b is described.

  Furthermore, in the first aspect of the present invention, since the diffractive structure layers (10 and 11) are formed on both the front and back surfaces of the light control element layer, it is possible to form images by diffracted light on both the front and back surfaces of the display medium. In addition, by recording different optical image information between the diffractive structure layers 10 and 11, different images can be formed by diffracted light on both the front and back surfaces of the display medium.

  Further, the dimming element layer may have one or a plurality of controllable partial regions having a certain shape in which light reflection and transmission can be controlled by voltage. For example, the whole light control element layer may be comprised by the several controllable partial area | region which can control reflection and transmission of light mutually independently with a voltage. Or the whole light control element layer may be comprised from the 1 or several controllable partial area | region which can control reflection and permeation | transmission of light mutually independently with a voltage, and a non-controllable partial area | region. Here, the uncontrollable partial region may be, for example, a transparent state or a mirror state (a state in which image formation by reflected light can be expected). By adopting such a configuration, it is possible to form more various images using diffracted light.

[III-2: Basic configuration of the second aspect of the present invention]
The display medium according to the second aspect of the present invention includes a plurality of stacked image display units, and a power supply unit 17 for supplying power to each of the image display units. A light control element layer (15, 16) whose reflection and transmission can be controlled by voltage, and a diffraction structure layer (10, 11) provided on at least one of the front and back surfaces of the light control element layer Prepare.

  As the light control element layers (15, 16), the light control element layer which is an electrochromic light control mirror as described above is preferable.

  The power supply unit 17 and the light control element layers (15, 16) are electrically connected, but may be wired connection or wireless connection. In the latter case, the antenna unit as described above can be employed as the power supply unit.

  The power supply unit 17 may be a power supply unit for connecting to external power, a power supply unit that is a solar cell, or a power supply unit that is a paper battery.

As an example of a preferable combination in the display medium of the second aspect of the present invention,
A combination of a plurality of diffractive structure layers / a plurality of light control element layers / a plurality of power supply units;
A combination of a plurality of diffractive structure layers / a plurality of light control element layers patterned in advance with controllable partial regions / a plurality of power supply units;
A combination of a plurality of diffractive structure layers / a plurality of light control element layers / patterned controllable partial regions in a matrix;
A plurality of diffractive structure layers / a plurality of light control element layers in which controllable partial regions are patterned in a matrix / a pattern signal generator in the state of a selected light control element layer / an external signal receiver for receiving a pattern signal / IC chip for processing received signal / a combination of power supply units whose voltage changes depending on the signal from the IC chip.

  Since the display medium according to the second aspect of the present invention includes two or more light control element layers, it is expected to form a wider variety of images by diffracted light than the first aspect of the present invention. it can.

  In the display medium 2 which is an example of this aspect, an embodiment in which two image display units are stacked and thus includes two dimming element layers (15, 16) is illustrated. Moreover, in this Example, the example provided with two diffractive structure layers (10, 11) in total, one for each light control element layer is shown.

  Among the plurality of image display units, a plurality of methods of stacking two adjacent image display units can be considered. However, it is preferable that at least one diffractive structure part is interposed between the light control elements in the two image display parts adjacent to each other from the viewpoint of enabling various displays as much as possible. In the display medium 2 which is an embodiment of this aspect, the diffractive structure layers and the light control element layers are alternately stacked, and one diffractive structure part is interposed between the light control elements in the two adjacent image display parts. doing.

  As will be described in detail in Examples, in the display medium 2, if the voltages of the two image display units are independently controlled as a preferred embodiment, various images can be switched and observed from the front and back surfaces, respectively. In this display medium 2, regarding the positional relationship of the diffractive structures (12, 13), the reflected light of the diffractive structure 12 passes through the diffractive structure portion 10 made of a translucent material and exits outside (front side). The diffraction structure 13 exemplifies an embodiment in which the reflected light passes through the light control element portion 16 and exits outside (back side) while being in the position. Reflecting this difference, in this display medium 2, when viewed from the front side, the mirror surface is not observed, but when viewed from the back side, it may become a mirror surface by controlling the voltage (FIG. 9). FIG. 11 and FIG. 12).

  In addition, the at least one light control element layer of the present aspect may have one or a plurality of controllable partial regions having a certain shape in which light reflection and transmission can be controlled by voltage. For example, the entire light control element layer may be configured by a plurality of controllable partial regions in which light reflection and transmission can be controlled independently of each other with a voltage. Alternatively, the entire light control element layer may be composed of one or a plurality of controllable partial regions and non-controllable partial regions in which the reflection and transmission of light can be controlled independently of each other with a voltage. Here, the uncontrollable partial region may be, for example, a transparent state or a mirror state (a state in which image formation by reflected light can be expected). By adopting such a configuration, it is possible to form more various images using diffracted light.

[III-3: Combination of Basic Aspects of the Present Invention and Arbitrary Components]
As an example of the combination of the first or second basic aspect of the present invention and an arbitrary component,
-Combination of diffraction structure layer / light control element layer / power supply unit / adhesive member;
A combination of diffractive structure layer / light control element layer / power supply unit / adhesive layer;
A combination of a diffractive structure layer / a light control element layer / a power supply unit / a cover member;
A combination of diffractive structure layer / light control element layer / power supply unit / adhesive member / product support;
A combination of diffractive structure layer / light control element layer / power supply unit / adhesive layer / product support;
A combination of diffractive structure layer / light control element layer / power supply unit / cover member / product support;
A combination of a diffractive structure layer / a light control element layer / a power supply unit / a concealing layer;
A combination of a diffractive structure layer / a light control element layer / a power supply unit that is an antenna unit / a concealment layer;
-Combination of diffractive structure layer / light control element layer / power supply unit / printing layer;
A combination of a diffractive structure layer / a light control element layer / a power supply unit / a printed layer formed under the light control element layer;
A combination of the diffractive structure layer / the light control element layer / the power supply unit / the printed layer formed on the diffractive structure layer;
A combination of printed layers formed between the diffractive structure layer / the light control element layer / the power supply part / the diffractive structure layer / the light control element part;
A combination of diffraction structure layer / light control element layer / power supply unit / printing layer / adhesive member;
A combination of diffractive structure layer / light control element layer / power supply unit / printing layer / adhesive layer;
A combination of diffractive structure layer / light control element layer / power supply unit / printing layer / cover member;
A combination of diffraction structure layer / light control element layer / power supply unit / printing layer / adhesive member / product support;
A combination of diffractive structure layer / light control element layer / power supply unit / printing layer / adhesive layer / product support;
A combination of diffraction structure layer / light control element layer / power supply unit / printing layer / cover member / product support;
A combination of a diffractive structure layer / a light control element layer / a power supply unit (any layer or part becomes brittle);
A combination of a diffractive structure layer / a light control element layer / a power supply unit (any layer or part is physically brittle);
-Diffraction structure layer / light control element layer / power supply part (any layer or part becomes chemically brittle);
A combination of a power supply unit (the power supply unit becomes brittle) that is a diffractive structure layer / light control element layer / antenna unit,
Etc.

  Here, the above example is representatively exemplified by using the first aspect of the present invention, but the second aspect of the present invention is described in the above example by, for example, a diffractive structure layer and a light control element layer. The power supply unit may be read as a plurality of diffraction structure layers, a plurality of light control element layers, and a plurality of power supply units, respectively.

[III-4: Other embodiment of the present invention]
In one embodiment of the present invention, the display medium of the present invention can be attached to an article. The embodiment of the present invention in this aspect is an article to which the display medium is attached.

  Furthermore, in another embodiment of the present invention, optical image information recorded in advance in the diffractive structure layer is displayed by using the display medium of the present invention and changing the voltage from the power supply unit to the light control element layer. Provide a way to make it happen.

  In one embodiment of the present invention, the present invention may be a display medium for authentication and anti-counterfeiting, a display medium for decoration, a display medium for toys, or a display medium for learning materials.

Hereinafter, the present invention and effects will be described using specific examples, but the examples do not limit the scope of application of the present invention.
Example 1
A display medium 1 according to an embodiment belonging to the first aspect of the present invention was produced as follows.

A polyethylene terephthalate (PET) plate having a thickness of 250 μm was used as a support for production. On one side of this support for production, ink composed of the following composition was applied and dried by a gravure printing method to form a release layer having a thickness of 0.5 μm.
"Release layer ink composition"
Polyamideimide resin 19.5 parts by weight Polyethylene powder 0.5 parts by weight Dimethylacetamide 30.0 parts by weight Toluene 50.0 parts by weight

Next, an ink comprising the following composition is applied and dried on the release layer by a gravure printing method, and a diffractive structure layer 10 having a film thickness of 1.5 μm is laminated. 3) was pressed against the diffractive structure layer while applying heat and pressure to form a desired diffractive structure 12 in the diffractive structure layer 10. This produced the front side diffractive structure layer on the production support.
"Diffraction structure layer ink composition"
Acrylic resin 18.0 parts by weight Silane coupling agent 2.0 parts by weight Methyl ethyl ketone 80.0 parts by weight

  Furthermore, a peeling layer and a diffractive structure layer 11 are laminated on another production support in the same manner as described above, and the diffractive structure that causes the diffracted light pattern of the cherry blossom pattern (see FIG. 4) to appear on the diffractive structure layer 11. 13 was formed, and a diffractive structure transfer foil for the back side surface was produced.

  Next, an alloy of magnesium and nickel was formed with a film thickness of 100 nm on the front-side diffraction structure layer 10 by a sputtering method, and the light control mirror layer in the light control element layer 14 was laminated.

Next, a water-soluble mask ink composed of the following composition is applied and dried on the portion to be an electrode of the light control mirror layer by a gravure printing method to form a first mask printing layer having a thickness of 5 μm, Palladium was formed with a film thickness of 100 nm by a sputtering method, and the catalyst layer in the light control element layer 14 was laminated.
"Water-soluble mask ink composition"
Water-soluble inorganic salt 13.0 parts by weight Hydrophilic inorganic filler 2.0 parts by weight Isopropyl alcohol 10.0 parts by weight Water 75.0 parts by weight

  Next, tantalum oxide was formed to a thickness of 100 nm by a sputtering method, and the electrolyte layer in the light control element layer 14 was laminated.

  Next, tungsten oxide was formed to a thickness of 100 nm by a sputtering method, and an ion storage layer in the light control element layer 14 was laminated.

  Next, a mixture of indium oxide and tin oxide (ITO) was formed to a thickness of 100 nm by a sputtering method, and the conductive layer in the light control element layer 14 was laminated. Next, a part of the conductive film layer is a part different from the first mask print layer, and the same composition as the first mask print layer is applied and dried to the other electrode part by the same method. Then, the second mask printing layer was formed with a film thickness of 5 μm.

Next, an adhesion auxiliary layer composed of the following composition was applied and dried by a gravure printing method, and an adhesion auxiliary layer having a thickness of 3 μm was laminated.
"Ink composition for adhesion auxiliary layer"
Vinyl chloride vinyl acetate copolymer resin 15.0 parts by weight Acrylic resin 10.0 parts by weight Methyl ethyl ketone 45.0 parts by weight Toluene 30.0 parts by weight

Next, the first mask print layer and the second mask print layer were removed by washing with water, and parts of the catalyst layer and the conductive film layer were exposed to form electrodes. The IC chip 32 is connected to this electrode, and the antenna for the printed antenna made of the following composition is applied to the desired antenna shape by screen printing so that the end of the antenna 31 is connected to the IC chip 32. The antenna 31 was formed by drying, and the power supply unit 17 was obtained.
"Ink composition for printed antenna"
Silver 80.0 parts by weight Diethylene glycol monoethyl ether acetate 20.0 parts by weight

Next, a white hiding ink composed of the following composition was applied and dried by a gravure printing method so that the power supply unit 17 was hidden from the front side surface, and a hiding layer 44 having a thickness of 2 μm was laminated.
"White hiding ink composition"
Ink binder 10.0 parts by weight White pigment 5.0 parts by weight Titanium oxide 20.0 parts by weight Ethyl acetate 65.0 parts by weight

  Next, the back side diffractive structure transfer foil having the release layer and the diffractive structure layer 11 is bonded onto the adhesion auxiliary layer while being heated by a dry laminating method, and then diffracted for the back side. The production support for the structure transfer foil was peeled together with the release layer. This obtained the light control element layer 14 provided with the diffraction structure on both front and back surfaces.

Next, an adhesive layer ink composed of the following composition is applied and dried by a gravure printing method so as to cover the entire back side including the diffractive structure layer 11, the power supply unit 17, and the concealing layer 44, and adhesion with a film thickness of 5 μm is performed. Layer 41 was laminated. Next, polyethylene was laminated on one side of kraft paper (thickness: about 100 μm), and a silicon-treated separator was temporarily adhered to the adhesive layer.
"Ink composition for adhesive layer"
Acrylic adhesive 30.0 parts by weight Ethyl acetate 50.0 parts by weight Toluene 20.0 parts by weight

  Thereafter, the separator is peeled off from the product support 42 that has been previously opened, and the window opening 46 and the diffractive structure layer 11 on the back side of the display medium are aligned to be pasted on the product support 42, and finally manufactured. The PET plate as the support for the substrate was peeled off together with the release layer to produce an article 50 to which the display medium 1 was attached (FIGS. 23 and 24).

  In the state where the power is not supplied, the light control element layer 14 is in a transparent state 14a as shown in FIG. 5 and light is transmitted through the article 50 thus obtained, and the opposite side of the light control element layer 14a is transparent as shown in FIG. Observed.

  Further, when a voltage of +5 V is applied to the dimming element layer 14 close to the AC magnetic field generator for power supply, the entire dimming element layer 14 becomes a mirror surface state 14b as shown in FIG. When the light is incident on the diffractive structure layer 10 on the front side, the diffracted light 19b appears along with the reflected light, and the diffracted light 19b composed of the image of the morning glory and the goldfish as shown in FIG. 3 can be observed at a certain observation angle. Furthermore, when the article 50 is turned over and brought closer to the AC magnetic field generator for supplying power again, and a voltage of +5 V is applied to the light control element layer 14, the light control element layer as a whole is in a mirror state 14b as in the case of the front side surface. Therefore, when light is incident on the diffractive structure layer 11 on the back side surface, the diffracted light 20b is also manifested together with the reflected light, and the diffracted light 20b composed of the cherry blossom image as shown in FIG. 4 can be observed at a certain observation angle. did it.

  Further, when a voltage of −5 V was applied to the light control element layer 12, the entire light control element layer 14 that was a mirror surface was changed to the transparent state 14a and returned to the state of FIG. 5, and the diffracted light images 19b and 20b disappeared.

(Example 2)
A display medium 2 according to an embodiment belonging to the second aspect of the present invention was produced as follows.

A PET plate having a thickness of 250 μm was used as a production support. On one side of this product support, ink comprising the following composition was applied and dried by a gravure printing method to form a release layer having a thickness of 0.5 μm.
"Release layer ink composition"
Polyamideimide resin 19.5 parts by weight Polyethylene powder 0.5 parts by weight Dimethylacetamide 30.0 parts by weight Toluene 50.0 parts by weight

Next, an ink comprising the following composition is applied and dried on the release layer by a gravure printing method, and a diffractive structure layer 10 having a film thickness of 1.5 μm is laminated. The relief plate for expressing the diffracted light pattern (see 3) was pressed against the diffractive structure layer 10 while applying hot pressure to form the desired diffractive structure 12 on the diffractive structure layer 10.
"Diffraction structure layer ink composition"
Acrylic resin 18.0 parts by weight Silane coupling agent 2.0 parts by weight Methyl ethyl ketone 80.0 parts by weight

  Next, an alloy of magnesium and nickel was formed to a thickness of 100 nm on the diffractive structure layer 10 by sputtering, and the light control mirror layer in the light control element layer 15 was laminated.

Next, a water-soluble mask ink composed of the following composition is applied and dried on the portion to be an electrode of the light control mirror layer by a gravure printing method to form a first mask printing layer having a thickness of 5 μm, Palladium was formed with a film thickness of 100 nm by a sputtering method, and the catalyst layer in the light control element layer 15 was laminated.
"Water-soluble mask ink composition"
Water-soluble inorganic salt 13.0 parts by weight Hydrophilic inorganic filler 2.0 parts by weight Isopropyl alcohol 10.0 parts by weight Water 75.0 parts by weight

  Next, aluminum was formed to a thickness of 100 nm by a sputtering method, and the buffer layer in the light control element layer 15 was laminated.

  Next, tantalum oxide was formed to a thickness of 100 nm by sputtering, and the solid electrolyte layer in the light control element layer 15 was laminated.

  Next, tungsten oxide was formed to a thickness of 100 nm by a sputtering method, and an ion storage layer in the light control element layer 15 was laminated.

  Next, ITO was laminated with a film thickness of 100 nm by a sputtering method to form a conductive layer in the light control element layer 15.

  Next, a part of the conductive film layer is a part different from the first mask print layer, and the same composition as the first mask print layer is applied and dried to the other electrode part by the same method. Then, the second mask printing layer was formed with a film thickness of 5 μm.

  Next, an adhesion auxiliary layer made of the following composition was applied and dried on the front side display portion by a gravure printing method, and an adhesion auxiliary layer having a thickness of 3 μm was laminated.

"Ink composition for adhesion auxiliary layer"
Vinyl chloride vinyl acetate copolymer resin 15.0 parts by weight Acrylic resin 10.0 parts by weight Methyl ethyl ketone 45.0 parts by weight Toluene 30.0 parts by weight

  Next, the first mask print layer and the second mask print layer are removed by washing with water, and an electrode is created by exposing a part of the catalyst layer and the conductive film layer to form a front side display section. .

Next, the pattern of the relief plate is changed to a cherry blossom (see FIG. 4), the manufacturing support is changed to a 125 μm PET film, and the back side display unit is changed by the same manufacturing method as the front side display unit. Next, after the front side display part and the back side display part are bonded by applying pressure while applying heat by a dry laminating method, the support for manufacturing on the back side display part side is attached together with the release layer. It peeled.

Next, the IC chip 32 is connected using the exposed electrode as the connecting portion 18, and the printed antenna ink composed of the following composition is screen-printed so that the end of the antenna 31 is connected to the IC chip 32. The antenna 31 was formed by coating and drying into a desired antenna shape, and the power supply unit 17 was obtained.
"Ink composition for printed antenna"
Silver 80.0 parts by weight Diethylene glycol monoethyl ether acetate 20.0 parts by weight

Next, a white hiding ink composed of the following composition was applied and dried by a gravure printing method so that the power supply unit 17 was hidden from the front side surface, and a hiding layer 44 having a thickness of 2 μm was laminated.
"White hiding ink composition"
Ink binder 10.0 parts by weight White pigment 5.0 parts by weight Titanium oxide 20.0 parts by weight Ethyl acetate 65.0 parts by weight

  Next, an adhesive layer ink composed of the following composition is applied and dried by the gravure printing method so as to cover the entire back side surface including the light control element layer 16, the power supply unit 17, and the masking layer 44, and the film thickness is 5 μm. The adhesive layer 41 was laminated. Next, polyethylene was laminated on one side of kraft paper (thickness: about 100 μm), and a silicon-treated separator was temporarily adhered to the adhesive layer.

  Thereafter, the separator is peeled off from the product support 42 that has been previously opened, and the window opening 46 and the diffractive structure layer 11 on the back side of the display medium are aligned to be pasted on the product support 42, and finally manufactured. It peeled with the peeling layer from the PET board | substrate which is a support body, and produced the article 51 to which the display medium 2 was affixed (refer FIG. 25, FIG. 26).

  In the article 51 thus obtained, in a state where no power is supplied, the light control element layers 15 and 16 are in a transparent state as shown in FIG. 10 and light is transmitted, and the opposite side of the light control element layers 15 and 16 is shown in FIG. It was observed through.

  Next, when a voltage of +5 V is applied to both the dimming element portions 15 and 16 close to the AC magnetic field generator for power supply, the entire surfaces of the dimming element layers 15 and 16 are in a mirror state (15b) as shown in FIG. 16b) When light is incident on the diffractive structure layer 10 on the front side surface, the diffracted light appears at a certain angle together with the reflected light, and the diffracted light composed of the image of the morning glory and goldfish as shown in FIG. 3 can be observed. It was. At this time, on the back side surface, the light control element layer 16 in the mirror surface state blocks light from entering the diffractive structure layer 11 so that diffracted light does not appear, and only reflected light to the mirror surface as shown in FIG. I was able to observe.

  Next, close to the AC magnetic field generator, a signal for controlling the magnetic field for power supply and the power supply pattern to the light control element layer is transmitted to the antenna part of the article 51, so that the light control element layer 15 on the front side surface When a voltage of -5V is applied and a voltage of + 5V is applied to the dimming element layer 16 on the back side surface, the dimming element layer 15 returns to the transparent state, and the dimming element layer 16 becomes a mirror surface, as shown in FIG. When light enters the diffractive structure layer 10 on the front side surface, the light passes through the diffractive structure layer 10 and the light control element layer 15 as they are, and reaches the diffractive structure layer 11. Is expressed. The reflected light and diffracted light pass through the transparent light control element layer 15 and the diffractive structure layer 10 again, and at a certain observation angle, observe the diffracted light comprising an image obtained by inverting the image of the cherry blossom in FIG. Moreover, from another angle, it has been possible to observe diffracted light composed of morning glory and goldfish images as shown in FIG. At this time, the incident light was blocked by the light control element layer 16 on the back side, and the diffracted light did not appear on the back side surface, and only the reflected light to the mirror surface as shown in FIG. 9 could be observed.

  Next, close to the AC magnetic field generator for power supply, this time, when a voltage of −5 V is applied to the back side dimming element layer 16 and a voltage of +5 V is applied to the dimming element layer 15 on the front side, The dimming element layer 16 on the surface changes to transparent, the dimming element layer 15 becomes a mirror surface, and the state shown in FIG. 13 is obtained. When light enters the diffractive structure layer 10 on the front side surface, the dimming element layer 15 reflects the reflected light. Diffracted light was expressed, and diffracted light consisting of images of morning glory and goldfish as shown in FIG. 3 could be observed. At this time, since the light control element layer 16 is transparent on the back side surface, the incident light to the back side surface passes through the light control element layer 16 and the diffractive structure layer 11 and the back side surface of the light control element layer 15. 4 and again passes through the diffractive structure layer 11 and the dimming element layer 16. At this time, the diffraction structure layer 11 twice at the time of incidence and at the time of reflection, the diffraction that is the image of the cherry blossom in FIG. Since light is generated, a plurality of diffracted light appears at slightly shifted positions due to the distance between the diffractive structure 13 and the light control element layer 15 and reflection due to the difference in refractive index between the interfaces of the passing layers. However, actually, the cherry blossom image in FIG. 4 could be observed on the back side, although the visibility was slightly lowered.

(Example 3)
A display medium 3 according to another embodiment belonging to the second aspect of the present invention was produced as follows.

A PET plate having a thickness of 250 μm was used as a production support. On one side of this support for production, ink composed of the following composition was applied and dried by a gravure printing method to form a release layer having a thickness of 0.5 μm.
"Release layer ink composition"
Polyamideimide resin 19.5 parts by weight Polyethylene powder 0.5 parts by weight Dimethylacetamide 30.0 parts by weight Toluene 50.0 parts by weight

Next, an ink composed of the following composition is applied and dried on the release layer by a gravure printing method, and a diffractive structure layer 10 having a film thickness of 1.5 μm is laminated. 17), the relief plate for expressing the diffracted light pattern was pressed against the diffractive structure layer 10 while applying hot pressure to form a desired diffractive structure 12 on the diffractive structure layer 10.
"Diffraction structure layer ink composition"
Acrylic resin 18.0 parts by weight Silane coupling agent 2.0 parts by weight Methyl ethyl ketone 80.0 parts by weight

Next, an alloy of magnesium and nickel was formed with a thickness of 100 nm on the diffractive structure layer 10 by sputtering, and an unprocessed dimming mirror layer in the dimming element layer 15 was laminated. Further, a photoresist ink having the following composition is applied and dried by a gravure printing method to form a photoresist layer having a thickness of 6 μm, and an exposure mask plate having a pattern corresponding to the geometric pattern of the diffraction structure 12 After the photoresist layer was covered with this exposure mask, the exposure light beam was irradiated to the photoresist layer through the exposure mask for 120 seconds. The exposed photoresist layer is removed by etching to remove unnecessary magnesium and nickel alloy film, and the remaining mask layer is removed by a plasma ashing device using a chemical reaction between oxygen gas and ultraviolet rays to obtain a desired shape. An etched shape processing light control mirror layer was formed.
"Ink composition for photoresist"
Photoresist 25.0 parts by weight Methyl ethyl ketone 75.0 parts by weight

Next, a water-soluble mask ink composed of the following composition was applied and dried on the portion to be an electrode of the shape processing light control mirror layer by a gravure printing method to form a first mask printing layer having a thickness of 5 μm. Then, palladium was formed with a film thickness of 100 nm by a sputtering method, and the catalyst layer in the light control element layer 15 was laminated.
"Water-soluble mask ink composition"
Water-soluble inorganic salt 13.0 parts by weight Hydrophilic inorganic filler 2.0 parts by weight Isopropyl alcohol 10.0 parts by weight Water 75.0 parts by weight

  Next, aluminum was formed to a thickness of 100 nm by a sputtering method, and the buffer layer in the light control element layer 15 was laminated.

  Next, tantalum oxide was formed to a thickness of 100 nm by sputtering, and the solid electrolyte layer in the light control element layer 15 was laminated.

  Next, tungsten oxide was formed to a thickness of 100 nm by a sputtering method, and an ion storage layer in the light control element layer 15 was laminated.

  Next, ITO was laminated with a film thickness of 100 nm by a sputtering method to form a conductive layer in the light control element layer 15. Next, a part of the conductive film layer is a part different from the first mask print layer, and the same composition as the first mask print layer is applied and dried to the other electrode part by the same method. Then, the second mask printing layer was formed with a film thickness of 5 μm.

  Next, an adhesion auxiliary layer made of the following composition was applied and dried on the front side display portion by a gravure printing method, and an adhesion auxiliary layer having a thickness of 3 μm was laminated.

"Ink composition for adhesion auxiliary layer"
Vinyl chloride vinyl acetate copolymer resin 15.0 parts by weight Acrylic resin 10.0 parts by weight Methyl ethyl ketone 45.0 parts by weight Toluene 30.0 parts by weight

  Next, the first mask print layer and the second mask print layer are removed by washing with water, and an electrode is created by exposing a part of the catalyst layer and the conductive film layer to form a front side display section. . Here, the light control element layer 15 included in the display unit for the front side surface includes a controllable partial region including the shape processing light control mirror layer and an uncontrollable partial region including no shape processing light control mirror layer. .

  Subsequently, the display part for back side surfaces was created with the manufacturing method similar to the display part for front side surfaces. But it differs from the manufacturing method of the display part for front side surfaces by the point of the following (i)-(iii).

  (I) The relief pattern has been changed to another geometric pattern or character pattern (see FIG. 16) designed to be a new pattern in combination with the geometric pattern on the surface.

  (Ii) Further, the production support was changed to a 125 μm PET film.

  (Iii) Further, the shape processing light control mirror layer is changed to an unprocessed light control mirror layer. Here, since the non-processed light control mirror layer is used for the light control element layer 16 contained in this display part for back side surfaces, the whole light control element layer 16 is a controllable area | region.

  Next, the front side display part and the back side display part were bonded together by applying pressure while applying heat by a dry laminating method, and then the support for manufacturing on the back side display part side was peeled off together with the release layer. .

The printed antenna ink made of the following composition is screen-printed so that the IC chip 32 is connected using the exposed electrode as the connection portion 18 and the end of the antenna 31 is connected to the IC chip 32. The antenna 31 was formed by applying and drying into a desired antenna shape, and the power supply unit 17 was obtained.
"Ink composition for printed antenna"
Silver 80.0 parts by weight Diethylene glycol monoethyl ether acetate 20.0 parts by weight

Next, a white hiding ink composed of the following composition was applied and dried by a gravure printing method so that the power supply unit 17 was hidden from the front side surface, and a hiding layer 44 having a thickness of 2 μm was laminated.
"White hiding ink composition"
Ink binder 10.0 parts by weight White pigment 5.0 parts by weight Titanium oxide 20.0 parts by weight Ethyl acetate 65.0 parts by weight

  Next, an adhesive layer ink composed of the following composition is applied and dried by a gravure printing method so as to cover the entire back side surface including the light control element layer 16, the power supply unit 17, and the concealing layer 44, and the film thickness is 5 μm. The adhesive layer 41 was laminated. Next, polyethylene was laminated on one side of kraft paper (thickness: about 100 μm), and a silicon-treated separator was temporarily adhered to the adhesive layer.

  Thereafter, the separator is peeled off from the product support 42 that has been previously opened, and the product is attached to the product support 42 while aligning the position of the window opening and the diffractive structure layer 11 on the back side of the display medium. It peeled with the peeling layer from the PET board which is a support body, and produced the articles | goods 52 with which the display medium 3 was affixed (refer FIG. 27, FIG. 28).

  In the article 52 thus obtained, in a state where no electric power is supplied, the light control element layers 15 and 16 are in a transparent state as shown in FIG. 19 and light is transmitted, and the opposite side of the light control element layers 15 and 16 is shown in FIG. It was observed through.

  Next, when a voltage of +5 V is applied to both the light control element layers 15 and 16 close to the AC magnetic field generator for power supply, the light control element layer 15 is formed in an arbitrary pattern in advance. The layer becomes a mirror surface, and the portion without the light control mirror layer becomes transparent (see 15c, FIG. 20). On the other hand, the entire surface of the light control element layer 16 is in a mirror state 16b, and when light enters the diffractive structure layer 10 on the front side surface, the mirror surface portion of the light control element layer 15 reflects the diffracted light having a geometric pattern at a certain angle along with the reflected light. In the transparent portion of the light control element layer 15, the incident light reaches the lower diffraction structure layer 11, is reflected by the light control element layer 16, and the diffracted light by the diffraction structure 13 is expressed and light control is performed again. The light passes through the element layer 15 and the diffraction structure layer 10 and returns to the front side surface. Further, in this example, as one embodiment, the diffracted light images of the diffractive structures 12 and 13 are recorded so as to appear at the same angle, and further aligned, so that at a certain observation angle, as shown in FIG. I was able to observe various geometric patterns.

  On the other hand, at this time, on the back side, the light incident on the diffractive structure layer 11 is blocked by the light control element layer 16 in the mirror state, so that diffracted light does not appear, and only reflected light as shown in FIG. 9 can be observed. .

  Next, close to the AC magnetic field generator, a signal for controlling the magnetic field for power supply and the power supply pattern to the dimming element layer is transmitted to the antenna part of the article 52, so that the dimming element layer 15 on the front side surface Applies a voltage of -5V, and when a voltage of + 5V is applied to the light control element layer 16 on the back side surface, the light control element layer 15 becomes transparent 15a as a whole, and the light control element layer 16 becomes a mirror surface 16b. It will be in the state of FIG. For this reason, when light is incident on the diffractive structure layer 10 on the front side surface, the light passes through the diffractive structure layer 10 and the light control element layer 15 and reaches the diffractive structure layer 11. Diffracted light due to is expressed. The diffracted light by the diffractive structure 13 should pass through the transparent light control element layer 15 and the diffractive structure layer 10 again to give an image as shown in FIG. However, since the diffracted light images of the diffractive structures 12 and 13 are recorded so as to appear at the same angle, and further aligned, diffraction caused by light transmitted through the diffractive structure 12 at the time of incidence and after reflection. The light and the diffracted light expressed by the diffractive structure 13 were combined as two diffracted light images from the front side, and could be observed as an image as shown in FIG. However, the image by the diffractive structure 13 was observed in a state where the luminance was lower than that of the image by the diffractive structure 12 because reflection due to the difference in refractive index occurred at the interface between the light control element layer 15 in the transparent state and the other layer. Further, at this time, the incident light is blocked on the back side because the light control element layer 16 is a mirror surface, so that diffracted light does not appear, and only the reflected light from the mirror surface as shown in FIG. 9 can be observed.

  Next, close to the AC magnetic field generator for power supply, this time, when +5 V is applied to the light control element layer 15 on the front side and -5 V is applied to the light control element 16 on the back side, The optical element layer 16 becomes transparent, and only the light control mirror layer formed in the geometric pattern of the light control element layer 15 becomes a mirror surface to be in the state of FIG. 22, and light enters the diffractive structure layer 10 on the front side surface. In the mirror surface portion, diffracted light composed of an image having a geometric pattern as shown in FIG. 17, which is diffracted light by the diffractive structure 12 together with reflected light in the light control element layer 15, can be observed. In the transparent portion, incident light remains as it is. All layers were transmitted, and the other side of the light control element layers 15 and 16 was observed through. At this time, since the light control element layer 16 is transparent on the back side surface, the incident light to the back side surface passes through the light control element layer 16 and the diffractive structure layer 11 and the back side surface of the light control element layer 15. And is transmitted through the diffractive structure layer 11 and the light control element layer 16 again. At this time, diffracted light is generated twice in the diffractive structure layer 11 at the time of incidence and at the time of reflection, but it depends on the distance between the diffractive structure 13 and the light control element layer 15 and the refractive index difference between the interfaces of the passing layers. A plurality of diffracted lights appear at slightly shifted positions due to reflection or the like. However, in practice, the geometrical pattern image of FIG. 18 could be observed on the back side surface with a slight reduction in visibility.

  Here, the following Table 1 (display medium 1) shows how the light control element layers of the display media 1 to 3 in Examples 1 to 3 look according to the combination of the mirror surface state and the transparent state. Table 2 (display medium 2) and Table 3 (display medium 3) show.

Here, * 1 in Table 2 indicates the following notes.
* 1: Two images with different observation angles As described above, the display medium of the present invention can display the recorded optical image information arbitrarily during observation from the same field of view and observation of the front and back sides. It was possible to change to.

1 Display medium 1 which is one embodiment of the first aspect of the present invention
2 Display medium 2 according to an embodiment of the second aspect of the present invention
3 Display medium 3 which is another embodiment of the second aspect of the present invention
10 Diffraction structure layer 1 (front side)
11 Diffraction structure layer 2 (back side)
12 Diffraction Structure 13 of Diffraction Structure Layer 1 Diffraction Structure 14 of Diffraction Structure Layer 2 Light Control Element Layer 14a Light Control Element Layer 14b in Transparent State Light Control Element Layer 15 in Mirror Surface State Light Control Element Layer 1 (Front Side)
15a Light-control element layer 1 in a transparent state
15b Light control element layer 1 in mirror state
15c Light control element layer 1 with a part of mirror surface
16 Light control element layer 2 (back side)
16a Transparent light control element layer 2
16b Dimming element layer 2 in mirror state
17 Power supply unit 18 Connection unit 19a Transmitted light 19b observed on the front side Optical image information 20a observed on the front side Transmitted light 20b observed on the back side Optical image information 20c observed on the back side Back side Reflected light 31 observed at 32 Antenna 32 IC chip 41 Adhesive layer 42 Product support body 43 Cover member 44 Concealing layer 45 Print layer 46 Window opening 50 Article 51 with display medium 1 attached Article 52 with display medium 2 attached Article with display medium 3 attached

Claims (7)

(A) an image display unit;
(B) a power supply unit for supplying power to the image display unit;
A display medium comprising:
The image display unit is
(A-1) a light control element layer capable of controlling reflection and transmission of light by voltage;
(A-2) a diffractive structure layer in which optical image information is recorded,
The diffractive structure layer is provided on both front and back surfaces of the light control element layer,
The power supply unit is connected to the light control element layer;
A display medium characterized by that. (A) a plurality of stacked image display units;
(B) a power supply unit for supplying power to the plurality of image display units;
A display medium comprising:
Each of the image display units
(A-1) a light control element layer capable of controlling reflection and transmission of light by voltage;
(A-2) a diffractive structure layer in which optical image information is recorded,
The diffractive structure layer is provided on at least one of the front and back surfaces of the light control element layer;
The power supply unit is connected to each of the light control element layers,
A display medium characterized by that.   The display medium according to claim 2, wherein the power supply unit can independently supply power to a light control element layer of each of the image display units.   The display medium according to claim 1, wherein the optical image information is aligned between at least two diffractive structure layers.   The at least one light-modulating element layer has a controllable partial region having a certain shape capable of controlling reflection and transmission of light with voltage, and a remaining uncontrollable partial region. 5. The display medium according to any one of 4.   An article to which the display medium according to any one of claims 1 to 5 is attached. Optical image information recorded in advance in the diffractive structure layer by using the display medium according to any one of claims 1 to 5 and changing a voltage from the power supply unit to the dimming element layer. How to display.