JP5359250B2 - Method for manufacturing patch transfer medium - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a patch transfer medium having a composite cholesteric liquid crystal layer and a hologram which can easily transfer a patch onto a body to be transferred, has abrasion resistance and solvent resistance for protecting a medium surface even when repeatedly used many times and further can easily perform authenticity determination. <P>SOLUTION: The patch transfer medium is constituted of (1) a transfer material and (2) a support material. The transfer material includes a transparent base material and, on one surface of the transparent base material, a first cholesteric liquid crystal layer, a retardation layer, a second cholesteric liquid crystal layer, a hologram forming layer and an adhesive layer. The support material includes a support base material and a peelable resin layer provided thereon. A transfer part of the transfer material is subjected to half cut processing to obtain the patch and the patch is laminated on a peelable resin layer surface of the support material so as to be peelable. Further the composite cholesteric liquid crystal layer has a polarizing property. <P>COPYRIGHT: (C)2010,JPO&amp;INPIT

Description

The present invention relates to a method for producing a patch transfer medium, and more specifically, after transfer, in addition to durability such as scratch resistance and solvent resistance, has a cholesteric liquid crystal composite excellent in design and security, and further has a hologram. The present invention relates to a method for manufacturing a patch transfer medium capable of transferring a patch with good transferability. The patch transfer medium manufactured by the method for manufacturing a patch transfer medium is used by accurately transferring to a desired portion of an article having various shapes that require a forgery prevention function (hereinafter referred to as a transfer target). “Patch” means when only a part of the transfer material provided on the support substrate is half-cut through the releasable resin layer, and only the half-cut part is transferred. This “transcription part”. Furthermore, an image that needs to be transferred to a transfer target is provided on the adhesive layer of the patch transfer medium by any one of the hot-melt transfer method, the thermal sublimation transfer method, and the ink-jet method, and this transfer provides high positional accuracy. Manufacture of anti-counterfeit medium (referred to a patch transfer medium transferred to a non-transfer body) and patch transfer medium used for proving the authenticity of the formed image with high durability by forming on the transfer target It is about the method .

  In the present specification, “ratio”, “part”, “%” and the like indicating the composition are based on mass unless otherwise specified, and the “/” mark indicates that they are integrally laminated. “PET” is an abbreviation, synonym, functional expression, common name, or industry term for “polyethylene terephthalate” and “extrusion coating” is “EC”.

The Lord applications of the patch transfer medium manufactured by the manufacturing method of the patch transfer medium (Lord use) the present invention, anti-counterfeiting fields, specifically, such as a credit card, when used being forged, Items that may cause damage to cardholders or card companies, driver's licenses, employee ID cards, membership cards, ID cards, entrance examination cards, passports, banknotes, gift certificates, point cards, stock certificates, securities There are lottery tickets, horse tickets, bankbooks, boarding tickets, pass tickets, air tickets, admission tickets for various events, play tickets, prepaid cards for transportation and various telephones. All of these are information records that hold information of economic or social value, identity identification, etc., and can identify the authenticity of the record itself for the purpose of preventing damage caused by forgery. Although it is desired to have a function, among these, the information is a visual image, and the present invention is applied to a case where it is particularly desired to have a function of proving the authenticity of the visual image. Further, the present invention is applied to those in which it is desired to improve the durability of the visual image, that is, scratch resistance, solvent resistance, and the like.

In addition to the uses described above, expensive products such as luxury watches, luxury leather products, precious metal products, jewelry, etc., often referred to as luxury brand products, or storage boxes for these expensive products And cases can also be forged. In addition, mass-produced products of famous brands, such as audio products, electrical appliances, etc., or tags that are hung on them are also subject to forgery.

Furthermore, a storage body in which music software, video software, computer software, game software, or the like, which is a copyrighted work, or cases thereof can also be forged. In addition, it is desirable that products such as printer toner, paper, and the like in which supplies to be replaced are limited to genuine materials have a function of identifying their authenticity for the purpose of preventing damage caused by forgery. In particular, it is suitable for a case where the form is complicated or too large to be easily formed by a normal transfer method.
It is also suitable for those in which a visual image is formed on these materials and the authenticity of the visual image needs to be proved.

(Background Art) Conventionally, a medium for the above-mentioned use, for example, a medium for certifying a right or qualification for which a certain amount of money has been paid (called prepaid) is increasing. Since the medium has a certain economic value and effect, individual information such as the validity period, section, name, and age is falsified, and it is constantly falsified, altered, and illegally used. It has been proposed to improve security.
It is also known to transfer a hologram to a medium using a hologram transfer foil having high security as well as excellent aesthetics and design. A hologram transfer foil is basically provided with a release layer or a release layer and a protective layer, a hologram forming layer, a hologram effect layer, and an adhesive layer on a base film, and faces a transfer area of a transfer material such as a card. Then, the base film is peeled off after the adhesion, and the hologram forming layer is transferred onto the surface of a transfer material such as a card.
The hologram transfer foil is difficult to counterfeit or counterfeit the hologram forming layer, so that counterfeiting and counterfeiting of the article to be transferred is effectively prevented. Prevention property and alteration prevention property have been required.

  On the other hand, in a medium for the above-mentioned use, for example, an ID card, images such as letters, numbers, and facial photographs are formed on the surface of the medium. In recent years, these images are often formed by a transfer method by thermal transfer or sublimation transfer using a so-called melt transfer type or sublimation transfer type ink ribbon. The transfer method is a thermal transfer sheet in which a colored transfer layer is formed on a base sheet, and is heated in an image form from the back by a thermal head or the like, and the above-described colored transfer layer is thermally transferred to the surface of the thermal transfer image receiving sheet. An image is formed. This thermal transfer method is roughly classified into a sublimation transfer type and a thermal melt transfer type depending on the configuration of the colored transfer layer. Both types can form full-color images.For example, yellow, magenta, and cyan, if necessary, black or three-color thermal transfer sheets are prepared, and the surface of the same thermal transfer image-receiving sheet has each color. The images are superimposed and thermally transferred to form a full color image.

With the development of various hardware and software related to multimedia, this thermal transfer method has become a full-color hard copy system for analog images such as digital images and video such as still images by computer graphics, satellite communications, and CDROM and others. That market is expanding.
The specific application of the thermal transfer image receiving sheet by this thermal transfer method is diverse. Typical examples include printing proofs, image output, CAD / CAM design and design output, various medical analytical instruments such as CT scans and endoscopic cameras, measuring instrument output applications and instant As an alternative to photos, output of ID cards, ID cards, credit cards, other face photos on cards, etc., as well as composite photos and amusement photos at amusement facilities such as amusement parks, game centers, museums, and aquariums Etc.

(Prior art)
With the diversification of applications as described above, an image is obtained by transferring a dye by using a thermal transfer sheet having a dye layer on the receiving layer, which is an intermediate transfer medium in which the receiving layer is detachably provided on the substrate. A method is proposed in which the intermediate transfer recording medium is formed and then the intermediate transfer recording medium is heated to transfer the receptor layer onto the transfer medium. (For example, see Patent Document 1)
In particular, when an image is formed with a sublimation transfer type thermal transfer sheet, a gradation image such as a facial photograph can be accurately formed, but unlike an image with a normal printing ink, weather resistance, friction resistance, There are weaknesses that lack durability such as chemical properties. As a solution, a protective layer thermal transfer film having a thermal transfer resin layer is superimposed on the thermal transfer image, and the thermal transfer resin layer having transparency is transferred using a thermal head, a heating roll, or the like, and the protective layer is formed on the image. Has been made to form.

Since the protective layer described above needs to be partially transferred at the time of transfer by a thermal head or a heat roll, it needs to have a foil cutting property. In this case, since the protective layer has to be a resin film having a thickness of about several microns, durability such as tough scratch resistance and chemical resistance cannot be provided. In addition, the protective layer formed on the intermediate transfer recording medium cannot be provided with sufficient durability such as scratch resistance and chemical resistance from the viewpoint of foil breakage.
The ink jet system is to print (image formation) by ejecting full-color toner to the print target portion by an electrostatic method by an ink jet printer, and has an advantage of not contacting the print target portion, but to the print target portion. Therefore, it is necessary to say that the durability of the printing (image) is extremely low.

  In addition, a sheet base material provided with a resin layer and a transparent sheet provided with a receiving layer are laminated, a half cut treatment is performed on the transparent sheet portion including the receiving layer, and a hologram forming layer is laminated on the transparent sheet, In a method for producing an intermediate transfer recording medium that peels between a resin layer and a transparent sheet, a receiving layer is applied on the raw material on which the hologram forming layer is laminated on the transparent sheet, and then the receiving layer of the transparent sheet is provided. Half-cut processing position by pasting the opposite surface to the sheet surface and the sheet base material on which the registration mark is formed in advance at the position corresponding to each screen unit through the resin layer, and then reading the registration mark It is described that the alignment and half-cut processing are performed. Using the intermediate transfer recording medium in this document, it is excellent in various durability of thermal transfer images even under severe usage conditions, and the protective layer (transparent sheet) is half-cut on the image, so it is accurate It is described that it can be easily transferred and that a hologram image is formed on a transparent sheet, so that it is excellent in falsification and anti-counterfeiting of a transferred object on which a thermal transfer image is formed. . (Hologram patch transfer medium. For example, see Patent Document 2)

  However, in recent years, forgery of the hologram itself has become more advanced, and authenticity determination by merely visually determining that there is a hologram image cannot clearly determine whether or not the hologram is genuinely manufactured. It is difficult to eliminate. In addition, when the authenticity is determined, for example, under the lighting of a financial institution or department store, the lighting itself is often unsuitable for hologram reproduction (wavelength uniformity and phase alignment). In many cases, it is scattered light with many wavelengths mixed together, such as fluorescent lamps that gently scatter light in the eyes.) Only the visual judgment of the hologram is the basis for authenticity judgment. It had the disadvantage that it was no longer sufficient.

JP-A-62-238791 JP 2002-274060 A

Accordingly, the present invention has been made to solve such problems. The purpose is to protect an image formed by thermal transfer or the like on a forgery prevention medium such as a card or the like manufactured by the patch transfer medium manufacturing method (referred to as a transfer target in the present invention) or formed by thermal transfer or the like. A highly durable patch having an image is transferred and formed, and the durability of the image is excellent even under harsh conditions, and the patch can be easily transferred onto the transfer target with high positional accuracy. The transferred medium is accurately transferred to the desired position.) In the transferred medium, the composite cholesteric liquid crystal, which is excellent in terms of security that the authenticity can be easily and accurately determined by a simple determination method, and further the hologram A patch transfer medium is provided. That is, it provides a method for producing a patch transfer medium that has durability when the medium is used, and that can protect the surface of the medium even when used repeatedly many times and can accurately determine its authenticity by simple means.

In order to solve the above-mentioned problems, a first aspect of the method for producing a patch transfer medium of the present invention is such that a transfer material is releasably supported as a transfer portion on a support material, and the support material is a support base material and a release property. Ri Do from the resin layer, the transfer material is a transparent substrate, prepared first cholesteric liquid crystal layer, the retardation layer, the manufacturing method of the patch transfer medium of a second cholesteric liquid crystal layer and the adhesive layer, the (1) a transparent substrate And (2) the first cholesteric liquid crystal layer composition is printed on one surface of the transparent substrate by a printing method and dried, and then a PET film is laminated and irradiated with ultraviolet rays. A first cholesteric liquid crystal layer forming step for forming the first cholesteric liquid crystal layer; and (3) an ultraviolet ray that is applied to the surface of the PET film by a coating method using a polymerizable nematic liquid crystal solution and dried. A phase difference layer forming step of forming a nematic liquid crystal layer by irradiating a line and using the two-layered laminate of the PET film and the nematic liquid crystal layer as the phase difference layer; and (4-1) the surface of the phase difference layer. In addition, a second cholesteric liquid crystal layer is formed by gravure printing using a second polymerizable cholesteric liquid crystal solution different from the first cholesteric liquid crystal layer composition, and is irradiated with ultraviolet rays after printing and drying. And (5) an adhesive layer forming step that becomes the transfer material by applying an adhesive layer composition to the surface of the second cholesteric liquid crystal layer by a coating method and drying to form an adhesive layer; ) Separately, a supporting base material preparing step of preparing the supporting base material, and (7) a peelable resin layer composition that is coated on the surface of the supporting base material and dried to form the peelable resin layer. Resin layer forming step and (8) the the surface of the release resin layer, and a lamination step to laminate the surface of the transparent substrate of the transfer material by a dry lamination method, (9) portion of the half-cut of the laminate the transfer material And a half-cut step for forming a patch. A method for manufacturing a patch transfer medium is provided. The patch transfer medium manufactured by the manufacturing method of the patch transfer medium, position置精degree better patch is transferred.
A second aspect of the method for manufacturing a patch transfer medium according to the present invention is the method for manufacturing a patch transfer medium according to claim 1 , wherein between the step (4-1) and the step (5), (4-2) A method of manufacturing a patch transfer medium , comprising: a hologram forming layer forming step of forming a hologram forming layer on the surface of the second cholesteric liquid crystal layer . In addition to the effect of the first aspect, the patch including visual judgment of the hologram is transferred by the patch transfer medium manufactured by the method for manufacturing the patch transfer medium.

A third aspect of the method for manufacturing a patch transfer medium according to the present invention is the method for manufacturing a patch transfer medium according to claim 1 , wherein (10) the adhesion is performed following the step (9). the plane of the layer, the hot-melt transfer system, a step of forming an image in one of the thermal sublimation transfer system or ink jet system, a manufacturing method of the patch transfer medium, characterized in that it comprises a are provided. According to a third aspect of the method for producing a patch transfer medium of the present invention, in addition to the effect according to any one of the first and second aspects, the adhesive layer has a receptivity capable of forming an image. In addition, after an image is formed in advance , the image is transferred to a transfer medium.

By patch transfer, a patch holding this image is formed at a predetermined position on the non-transfer body. This image is, for example, characters, numbers, face photos, etc. formed on the surface of the ID card. For the purpose of authentication of the ID card, the characters and numbers are optically automatically read and the face photo is determined. Therefore, the position accuracy is required to be high. Furthermore, it becomes possible to selectively cover only a specific part to be authenticated, and the effect of preventing forgery can be enhanced.
Furthermore, due to the flexibility and portability of the patch transfer medium, there is an advantage that it can be easily transferred even if the transfer target has a three-dimensional shape or is large and difficult to handle.
In the first to third aspects of the patch transfer medium of the present invention, after this patch transfer, the ID card is repeatedly rubbed by a gate terminal or the like for several to several tens of years, or the physicality caused by the holder carrying it. The first cholesteric liquid crystal layer, the retardation layer, and the second cholesteric liquid crystal layer (hereinafter referred to as a composite cholesteric liquid crystal layer) And the transparent base material having excellent durability in contact with the hologram forming layer. Furthermore, the durability of the cholesteric liquid crystal layer can be further increased by using a polymer dispersed liquid crystal or an encapsulated liquid crystal.
For this reason, the transparent substrate has a thickness of 2.5 μm to 50 μm, and the cholesteric liquid crystal layer itself uses a resin having excellent durability. Therefore, in a normal spot transfer method, the transparent substrate is transferred to a desired shape. It is difficult. Further, the spot transfer system is likely to be subjected to high temperature and high pressure conditions because the transfer portion is broken into a desired shape, and it is assumed that the cholesteric liquid crystal layer is damaged.

Therefore, using a support material in which a peelable resin layer is provided on a support substrate, the transfer part of the transfer material is subjected to a half-cut treatment to make a patch, and then a laminate transfer method capable of transferring at a relatively low pressure, -It can be transferred to a transfer medium using a spot transfer system with low pressure.
These low-temperature and low-pressure transfer conditions are important in terms of reducing or preventing the deformation and color tone of the image formed on the adhesive layer, and further the damage to the cholesteric liquid crystal layer. In particular, since the cholesteric liquid crystal layer itself is broken by half-cutting, it is preferable to encapsulate the liquid crystal and form a film even when the cholesteric liquid crystal layer itself is broken and further used.
Further, since this image formation is usually carried out continuously using the above-described method, it is necessary to carry a composite cholesteric liquid crystal layer, a hologram forming layer and an adhesive layer in a roll shape by the transparent substrate.
On this roll-shaped transparent substrate, in order to accurately perform half-cut processing and image formation with high accuracy, a mark for displaying the position on the substrate is required. A position display mark is inserted, and half-cut processing is performed while detecting this mark. Furthermore, the patch transfer is performed while detecting the position display mark and aligning it with a desired position of the transfer target.
Therefore, it is preferable that the position display mark is a half-cut region different from the image so that the position display mark is not transferred to the transfer medium during transfer. Alternatively, it is also preferable to simplify the half-cut process by using a specific part in the image for position display.

As described above, the composite cholesteric liquid crystal or hologram can be transferred to a predetermined position on the transfer target with a predetermined size and shape at the same time and with a precise position. It becomes possible to synchronize the shape of the cholesteric liquid crystal layer and the hologram design, and a more advanced forgery prevention effect can be brought out.
For example, the ID number and the composite cholesteric liquid crystal layer transmit specific incident light (polarizability, wavelength), synchronize with the shielding effect, and the hologram design that covers the face part of the face photograph and part of the ID number The present invention can be applied to tuning and further to authenticity determination using this automatic recognition device.
Since the composite cholesteric liquid crystal layer has the effect of selecting the light reflected by itself, it has anti-counterfeiting properties by changing the color of the reflected light depending on the viewing angle, but in addition to this, it has right or left circular polarization. Therefore, authenticity determination using a circularly polarizing plate is possible. Using this function, authenticity can be easily confirmed even by visual observation. Of course, in the automatic reading device, by setting the polarizing plate in a predetermined pattern, only a predetermined portion of the image can be extracted and read to check the authenticity.

Cholesteric liquid crystals have a property of selectively reflecting (selective reflection) light having a specific wavelength. Light of this wavelength is called “selective reflected light”, and this specific wavelength is called “center wavelength”.
The cholesteric liquid crystal layer of the present invention is a “composite cholesteric liquid crystal” (see FIGS. 1A and 1B), and there are two cholesteric liquid crystal layers sandwiching a retardation layer. The “retardation layer” is a layer in which “circular polarization” is reversed when light passes through this layer. For example, if right circularly polarized light and left circularly polarized light are incident on the first cholesteric liquid crystal layer at the same time, only the right circularly polarized light is selectively reflected by the first cholesteric liquid crystal layer. The left circularly polarized light that is light is allowed to pass through. Therefore, at this stage, the pattern shape of the first cholesteric liquid crystal layer can be confirmed by observation using a circularly polarized light judgment plate.
The remaining light is incident on the next phase retardation layer, and when passing through this layer, a phase shift occurs, and the light is incident on the second cholesteric liquid crystal layer in a state of being shifted from the left circularly polarized light to the right circularly polarized light again. To do. When a cholesteric liquid crystal having the same properties as the first liquid crystal layer is used as the second cholesteric liquid crystal layer, the right circularly polarized light (having the same center wavelength) is selectively reflected.

This light enters the retardation layer again, shifts from right circularly polarized light to left circularly polarized light, passes through the first cholesteric liquid crystal layer as it is, and is observed as second reflected light from the observation side. be able to. That is, “right-circularly polarized light” returns from the first layer as reflected light, and from the second layer through the retardation layer and the first layer, the “left circle” having the same wavelength (center wavelength). "Polarized light" returns as reflected light.
Therefore, on the observation side, when the “polarizing plate that passes only the right circularly polarized light” is observed, a “first layer pattern” (the shape formed on the transfer medium) is observed, and “the polarized light that passes only the left circularly polarized light” When observed using a “plate”, the “second layer pattern” (the shape formed on the transfer medium) can be seen.
Actually, since the “second layer pattern” is a pattern that cannot be discriminated from the observer side, it can be used as “hidden information” for preventing counterfeiting.

In addition, when the wavelength of the selectively reflected light of the second cholesteric liquid crystal layer is different from that of the first liquid crystal layer (the center wavelength is different), right and left circular polarizations that pass through the first liquid crystal layer as they are are obtained. Each of the light is inverted by the retardation layer, but in this state, only the right circularly polarized portion is selectively reflected by the second liquid crystal layer, and also returns to the viewer side with left circular polarization.
At this time, the observer can observe the hidden pattern of the second liquid crystal layer in the same manner as described above, but this time, the wavelength is observed differently (observation of light having a different central wavelength).
That is, when the selective wavelength is varied, in the observation without using the polarizing plate, light of two kinds of wavelengths are mixed and observed as a third color tone. If the first is blue and the second is red, the third color tone is yellow.
When the third light is observed through the “right circularly polarizing plate” or the “left circularly polarizing plate”, it is clear that the color separation is performed again.
It is possible to change the color tone that can be extracted by the pattern of the first liquid crystal layer, the pattern of the second liquid crystal layer, and the third pattern which is the overlapping portion.
Furthermore, if a colored pattern is inserted between these layers, a more complicated color reproduction is obtained.

As described above, it is possible to create a complex color reproduction effect by inserting a phase difference layer, and it can be used for judgment of anti-counterfeiting, making it difficult for counterfeiters to read and high anti-counterfeiting. The forgery prevention medium which has the property can be provided.
In the portion without the retardation layer, the first liquid crystal layer and the second liquid crystal layer are in direct contact with each other, so that the interface is disturbed and the color tone and the reflection angle are disturbed.
In any case, it appears from the appearance that only one layer of cholesteric liquid crystal is formed. However, since the second cholesteric liquid crystal is actually provided below the cholesteric liquid crystal, a unique anti-counterfeit function is exhibited.

According to the method for producing a patch transfer medium of the present invention, (1) a transparent substrate, a first cholesteric liquid crystal layer, a retardation layer, a second cholesteric liquid crystal layer and an adhesive layer on one surface of the transparent substrate, or A transfer material comprising a first cholesteric liquid crystal layer, a retardation layer, a second cholesteric liquid crystal layer, a hologram forming layer, and an adhesive layer; and (2) a support material provided with a peelable resin layer on a support substrate. The transfer portion of the material is subjected to a half-cut process to form a patch, and the patch transfer medium on which the patch is peelably laminated on the surface of the releasable resin layer of the support material, and the adhesive layer of the transfer material are heat-melt transfer There is provided a method for producing a patch transfer medium , which has a receptivity for forming an image by any one of a method, a thermal sublimation transfer method, and an ink jet method.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1A is a cross-sectional view of a composite cholesteric liquid crystal layer.
FIG. 1B is a diagram illustrating the function of the composite cholesteric liquid crystal layer.
FIG. 2 is a cross-sectional view of the patch transfer medium manufactured by the method for manufacturing a patch transfer medium of the present invention.
FIG. 3 is a cross-sectional view of an anti-counterfeit medium transferred using the patch transfer medium manufactured by the patch transfer medium manufacturing method of the present invention. (An image is formed in advance on the transfer medium.)
FIG. 4 is a cross-sectional view of a forgery prevention medium transferred using a patch transfer medium manufactured by the method for manufacturing a patch transfer medium of the present invention (an image is formed in advance on the patch transfer medium).
FIG. 5 is a cross-sectional view showing another example of a patch transfer medium manufactured by the method for manufacturing a patch transfer medium of the present invention.
FIG. 6 is a cross-sectional view of an anti-counterfeit medium showing still another example transferred using the patch transfer medium manufactured by the method for manufacturing a patch transfer medium of the present invention (image formation on a transfer medium).
FIG. 7 is a cross-sectional view of an anti-counterfeit medium showing still another example transferred using the patch transfer medium manufactured by the method for manufacturing a patch transfer medium of the present invention (image formation on the patch transfer medium).

(Patch Transfer Medium) As shown in FIG. 2 or FIG. 5, the patch transfer medium 20 manufactured by the method for manufacturing a patch transfer medium of the present invention allows the patch 21 to be peeled off to the surface of the peelable resin layer 33 of the support material 30. Are stacked. The patch 21 is a patch formed by half-cutting the transfer portion of the transfer material 10. The transfer material 10 includes (1) a transparent base material 11, a first cholesteric liquid crystal layer 14, a retardation layer 17, a second cholesteric liquid crystal layer 15 and an adhesive layer, or a first layer on one surface of the transparent base material 11. The support material 30 includes a cholesteric liquid crystal layer 14, a retardation layer 17, a second cholesteric liquid crystal layer 15, a hologram forming layer 18, and an adhesive layer 19.
(Anti-Counterfeit Medium) An anti-counterfeit medium 100 transferred using the patch transfer medium 20 manufactured by the method for manufacturing a patch transfer medium of the present invention is shown in FIG. 3, FIG. 4, FIG. 6, or FIG. Using the patch transfer medium 20 of the present invention, the patch 21 in the form of a patch obtained by half-cutting the transfer portion of the transfer material 10 is peeled off from the support material 30 and transferred to the transfer object 101. . The patch 21 is a transparent substrate 11, a first cholesteric liquid crystal layer 14, a retardation layer 17, a second cholesteric liquid crystal layer 15 and an adhesive layer, or a first cholesteric liquid crystal layer 14, a retardation layer 17, a second cholesteric liquid crystal layer 15. The hologram forming layer 18 and the adhesive layer 19 are included.

The patch transfer medium 20 can achieve the following effects.
(1) When the patch 21 is transferred from the patch transfer medium 20 to the transfer target 101, the patch 21 is half-cut, so that it can be easily peeled off from the support material 30 and transferred with good transferability. it can.
That is, when normal spot transfer is performed, transfer is performed under high temperature, high pressure, and long time transfer conditions in the transfer process in order to accurately reproduce the spot shape. For example, 200 degrees or more, 5 tons / cm ² or more, 5 seconds or more. In particular, by increasing the pressure, the end of the spot shape is finished to be clean and free from protrusions and jaggedness. Further, in order to finish this end portion more neatly, it is desirable that the breaking strength of the portion to be transferred is small, and in the case of a normal resin layer, it is set to several μm or less.
However, in order for the cholesteric liquid crystal layer to exhibit its function, 1.5 μm or more is required. Therefore, transfer by the spot transfer process described above is difficult, and half-cut processing as in the present invention is required.
Furthermore, since the layer to which the hologram forming layer is added becomes more difficult to break, the half-cut treatment of the present invention is essential.

(2) Furthermore, in this half-cut treatment, the above-described high temperature and high pressure are not required, and 50 to 150 degrees, 0.1 to 1 ton / cm ² , and 70 to 100 degrees, 0.5 Tons to 1 ton / cm ² is preferred.
If it is 50 degrees or less and 0.1 ton / cm ² or less, the adhesive force cannot be secured, and if it is 150 degrees or more and 1 ton / cm ² or more, the cholesteric liquid crystal layer is damaged. Among these, stable adhesion and transfer with little damage to the cholesteric liquid crystal layer can be performed under the conditions of 70 to 100 degrees and 0.5 to 1 ton / cm ² .
Further, in order to increase the durability of the cholesteric liquid crystal layer, when the film strength of the resin layer to be used is increased or encapsulated, spot transfer becomes more difficult, and half-cut processing is preferable.

(Hologram forming layer)
As the hologram forming layer 18, a known hologram forming layer can be used, but in order to make use of the color tone change of the light selective reflection layer as described above, a material having visible light permeability is preferable. For example, the hologram forming layer 18 can be produced by forming fine irregularities of a relief hologram on one side of a layer made of a transparent resin material. As the transparent resin material for constituting the hologram forming layer 18, various resin materials such as various thermosetting resins, thermoplastic resins, and ionizing radiation curable resins can be selected. Examples of the thermosetting resin include unsaturated polyester resins, acrylic urethane resins, epoxy-modified acrylic resins, epoxy-modified unsaturated polyester resins, alkyd resins, and phenol resins. Examples of the thermoplastic resin include acrylate resin, acrylamide resin, nitrocellulose resin, and polystyrene resin. These resins can be used alone or as two or more types of copolymers. In addition, these resins may be used alone or in combination of two or more types of isocyanate resins, metal soaps such as cobalt naphthenate and zinc naphthenate, benzoyl peroxide, peroxides such as methyl ethyl ketone peroxide, benzophenone, acetophenone, anthraquinone, naphthoquinone, A heat or ultraviolet curing agent such as azobisisobutyronitrile or diphenyl sulfide may be blended. Examples of the ionizing radiation curable resin include epoxy acrylate, urethane acrylate, and acrylic-modified polyester. Other monofunctional or polyfunctional monomers, oligomers and the like can be conjugated to such ionizing radiation curable resins for the purpose of adjusting the cross-linking structure and viscosity.

  The hologram forming layer 18 can also be directly formed by developing a photosensitive resin material by performing interference exposure of the hologram. However, a relief hologram produced in advance or a duplicate thereof, or a plating mold thereof is duplicated. Molding can also be performed by using it as a mold and pressing the mold surface against the resin material. When a thermosetting resin or ionizing radiation curable resin is used, it is cured by heating or irradiation with ionizing radiation while the uncured resin is kept in close contact with the mold surface, and the cured transparent film is peeled off after curing. The fine irregularities of the relief hologram can be formed on one side of the layer made of the resin material. In the present invention, the hologram forming layer 18 includes a diffraction grating forming layer having a diffraction grating formed into a pattern by a similar method. Further, a combination of the hologram forming layer and the diffraction grating forming layer is also included.

The ionizing radiation curable resin is preferably (1) an isocyanate having three or more isocyanate groups in the molecule, and (2) at least one hydroxyl group and at least two (meth) acryloyloxy groups in the molecule. Preferably using an ionizing radiation curable resin containing a polyfunctional (meth) acrylate having, or (3) a urethane (meth) acrylate oligomer which is a reaction product of a polyhydric alcohol having at least two hydroxyl groups in the molecule. May contain polyethylene wax, applied, dried, and cured with ionizing radiation to form an ionizing radiation curable resin.

  The ionizing radiation curable resin containing the urethane (meth) acrylate oligomer is disclosed in a cured product of an ionizing radiation curable resin containing a urethane (meth) acrylate oligomer, specifically, JP-A-2001-329031. The photocurable resin etc. which can be illustrated. Specifically, MHX405 varnish (product name of ionizing radiation curable resin, manufactured by The Inktec Co., Ltd.) can be exemplified.

  (Formation of Hologram Formation Layer) The formation of the hologram formation layer 18 is based on the above ionizing radiation curable resin, added with a photopolymerization initiator, a plasticizer, a stabilizer, a surfactant, etc., and dispersed or dissolved in a solvent. Then, it may be applied by a known coating method such as roll coating, gravure coating, comma coating, die coating and the like, dried and reacted (cured) with ionizing radiation after shaping the hologram (relief). The thickness of the hologram forming layer 18 is usually about 1 to 10 μm, preferably 2 to 5 μm.

(Hologram) Next, on the surface of the hologram forming layer 18, predetermined fine unevenness (relief structure) such as a hologram that exhibits a light diffraction effect is formed and cured. A hologram is a recording of interference fringes due to the interference of light between object light and reference light in an uneven relief shape, such as a laser reproduction hologram such as a Fresnel hologram, a white light reproduction hologram such as a rainbow hologram, There are color holograms utilizing the above principle, computer generated holograms (CGH), holographic diffraction gratings and the like.

A relief shape is formed (also referred to as replication) on the surface of the hologram forming layer 18. Hologram shaping can be formed by a known method. For example, when recording diffraction gratings or interference fringes of holograms as reliefs of surface irregularities, a master on which the diffraction gratings or interference fringes are recorded in irregularities is pressed. The concave / convex pattern of the original can be duplicated by using it as a mold (referred to as a stamper) and by superimposing the original on the resin layer and heat-pressing both of them with an appropriate means such as a heating roll.
Using this method, a similar relief shape can be formed in the cholesteric liquid crystal layer. In this case, the hologram forming layer is unnecessary, and when the light incident on the cholesteric liquid crystal layer is reflected at the interface between the cholesteric liquid crystal layer and the adhesive layer, the interface itself has the relief shape. The reflection itself at the interface creates the hologram effect.
Therefore, when the light is reflected at this interface, the reflected light has not yet appeared on the cholesteric liquid crystal layer, that is, part of the light reflected within the cholesteric liquid crystal layer. (When the cholesteric liquid crystal layer reflects right circularly polarized light, the light forming the hologram also has right circular polarization.

On the other hand, when a hologram forming layer is provided, the light incident on the cholesteric liquid crystal layer once passes through the cholesteric liquid crystal layer, and then the hologram forming layer formed in contact with the layer also When passing, it is reflected at the interface (relief shape) between the hologram forming layer and the adhesive layer. Therefore, when the cholesteric liquid crystal layer reflects right circularly polarized light with respect to a specific wavelength, the light forming this hologram has left circularly polarized light.
By utilizing these differences in circular polarization properties and confirming with a right or left circularly polarizing plate when observing the anti-counterfeit medium, the authenticity can be authenticated by a simple method.

Further, the hologram pattern formed on the hologram forming layer 18 may be single or plural. The hologram forming layer 18 is irradiated with ionizing radiation during or after embossing with a stamper to cure the ionizing radiation curable resin. The ionizing radiation curable resin becomes an ionizing radiation curable resin (fine irregularities = relief structure = hologram) when it is cured (reacted) by irradiation with ionizing radiation such as ultraviolet rays or electron beams after the relief is formed. Since this method can be shaped at a relatively low temperature and low pressure, damage to the cholesteric liquid crystal layer can be reduced.
Further, the hologram relief or hologram forming layer may be provided on the observation side with respect to the cholesteric liquid crystal layer. In this case, the light forming the hologram is not affected by the polarization of the cholesteric liquid crystal layer. Further, a transparent film may be provided between the cholesteric liquid crystal layer and the hologram forming layer.

A transparent reflective layer may be added to the hologram forming layer 18 in order to increase its reflectivity. Since the transparent reflection layer is provided on the transparent reflection layer on the relief surface of the hologram forming layer 18 provided with a predetermined relief structure, the relief reflection and / or diffraction effect is enhanced. It is not particularly limited as long as it is high or low. The transparent reflective layer is a transparent reflective layer formed by a vacuum thin film method or the like. As a transparent reflective layer, since the optical refractive index is different from that of the hologram forming layer 18 in a substantially colorless and transparent hue, it is possible to visually recognize the glitter of a hologram or the like even though there is no metallic luster, A transparent hologram can be produced. For example, there are a thin film having a higher refractive index than the hologram forming layer 18 and a thin film having a lower refractive index. Examples of the former include ZnS, TiO ₂ , Al ₂ O ₃ , Sb ₂ S ₃ , SiO, and SnO. ₂ and ITO. Examples of the latter include LiF, MgF ₂ and AlF ₃ . Preferably, it is a metal oxide or nitride, specifically, Be, Mg, Ca, Cr, Mn, Cu, Ag, Al, Sn, In, Te, Fe, Co, Zn, Ge, Pb, Cd , Bi, Se, Ga, Rb, Sb, Pb, Ni, Sr, Ba, La, Ce, Au, and other oxides or nitrides, and the like can be exemplified by a mixture of two or more thereof. Also, a general light-reflective metal thin film such as aluminum can be used when it has a thickness of 200 mm or less. The transparent metal compound is formed by vapor deposition, sputtering, ion plating, CVD, etc. on the relief surface of the hologram forming layer 18 so as to have a thickness of about 10 to 2000 nm, preferably 20 to 1000 nm, like the metal thin film. It may be provided by a vacuum thin film method or the like.

Moreover, the forgery prevention medium 100 can have the following effects.
(1) The outermost surface of the anti-counterfeit medium 100 is the transparent base material 11 of the patch 21, and the transparent base material 11 is once formed with high strength for a film. It has excellent durability such as scratch resistance and solvent resistance, and can protect the surface of the medium more firmly than a conventional protective layer made of a resin applied. The transparent substrate 11 is preferably a biaxially stretched film, but more preferably a film having no phase difference in order to confirm the circular polarization property of the cholesteric liquid crystal layer with a circularly polarizing plate.
(2) In particular, the information printing layer 10 is the outermost surface in the transfer target on which an image on which information is printed by any one of the hot melt transfer method, the thermal sublimation transfer method, and the ink jet method is formed. The patch 21 having a high durability film on the surface of the image forming layer 102 protects the image of the image forming layer 102 even under harsh use conditions. Can be protected.

(3) Since the patch 21 including the composite cholesteric liquid crystal layer and the hologram forming layer is transferred with high positional accuracy in the anti-counterfeit medium 100, information such as an image provided in advance on the transfer target 101, The image formed on the patch 21 can be combined with the image, and the image formed on the patch 21 is observed using a polarizing plate so that only the image formed on the patch 21 is blocked or transmitted. Thus, it is possible to confirm the authenticity and further improve the anti-counterfeiting property. Of course, the same effect can be obtained when optically automatically reading.

(Transfer Material) The transfer material 10 has a transparent base material 11, a first cholesteric liquid crystal layer 14, a retardation layer 17, a second cholesteric liquid crystal layer 15 and an adhesive layer on one surface of the transparent base material 11, or a first cholesteric material. The liquid crystal layer 14, the retardation layer 17, the second cholesteric liquid crystal layer 15, the hologram forming layer 18, and the adhesive layer 19 are included.
(Transparent base material) The transparent base material 11 functions as a protective layer in a form in which 11 parts of the transparent base material are cut and covers at least the part including the image forming layer 102 with the half-cut portion as a boundary. . Various materials can be applied depending on the application as long as they have transparency and durability such as weather resistance, friction resistance, and chemical resistance. For example, polyester resins such as polyethylene terephthalate and polyethylene naphthalate, polyamide resins, vinyl resins such as polyvinyl chloride, acrylic resins, imide resins, engineering resins such as polyarylate, polycarbonate, cyclic polyolefin resins, cellophane Examples thereof include cellulosic films. The transparent substrate 11 may be a copolymer resin containing these resins as a main component, a mixture (including an alloy), or a laminate including a plurality of layers. In particular, a TAC film (triacetylcellulose) is excellent in optical characteristics (no retardation) and is suitable.

  The transparent substrate 11 may be a stretched or unstretched film, but is preferably a film stretched in a uniaxial direction or a biaxial direction for the purpose of improving strength. A thickness of about 2.5 to 50 μm is usually applicable, but 2.5 to 25 μm is preferable. Prior to application, the transparent substrate 11 is subjected to easy adhesion treatment such as corona discharge treatment, plasma treatment, primer (also called an anchor coat, adhesion promoter, or easy adhesive) application treatment, alkali treatment, etc. May be. Moreover, you may add additives, such as a filler, a plasticizer, a coloring agent, and an antistatic agent, as needed. A biaxially stretched polyethylene terephthalate film is preferably used because of its good heat resistance and mechanical strength.

(Cholesteric liquid crystal layer)
The cholesteric liquid crystal layers 14 and 15 have light selective reflectivity that reflects either left circularly polarized light or right circularly polarized light with respect to incident light from the observation side. Also, by applying these in combination, the determination method can be complicated, and a more sophisticated authenticity identifier can be obtained.
Cholesteric liquid crystals include cholesterol halides, monocarboxylic acid cholesterol esters, monocarboxylic acid sitosterol esters, benzoic acid derivative cholestanol esters, dibasic acid dicholesteryl esters, main chain liquid crystal polymer compounds, side chain liquid crystal polymers Examples thereof include molecular compounds and rigid main chain type liquid crystal polymer compounds.

  More specifically, for example, cholesteryl chloride, cholesteryl acetate, cholesteryl nonanoate, methyl carbonate, ethyl cholesterol, cholesteryl p-methoxybenzoate, sitosteroyl benzoate, sitosteroyl p-methyl benzoate, cholestanyl benzoate, 10, 12- Docosadiin dicarboxylic acid dicholesteryl ester, 8,12-eicosadicarboxylic acid dicholesteryl ester, 10,12-pentacosadiin dicarboxylic acid dicholesteryl ester, dodecadicarboxylic acid dicholesteryl ester, 12,14-hexacosadiin dicarboxylic acid Dicholesteryl ester, 4- (7-cholesteryloxycarbonylheptyloxy) phenoxyoctanoic acid cholesteryl ester, L-glu Min acid -γ- benzyl / L-glutamate -γ- dodecyl copolymers and the like.

  Further, cholesteryl formate, cholesteryl acetate, cholesteryl propionate, cholesteryl butyrate, cholesteryl pentanate, cholesteryl hexanate, cholesteryl heptanoate, cholesteryl octanate, cholesteryl nonanoate, cholesteryl decanate, cholesteryl decanate (cholesteryl laurate) Cholesteryl myristate, cholesteryl palmitate, cholesteryl stearate, cholesteryl oleate, cholesteryl oleyl carbonate, cholesteryl linoleate, cholesteryl 12-hydroxystearate, cholesteryl mercaptan, cholesterol chloride, cholesteryl fluoride, cholesteryl bromide, cholesteryl iodide, etc. Can be mentioned.

Preferably, a mixture of three kinds of alkyl cholesterol (for example, cholesterol nanoate) and cholesteryl halide (for example, cholesterol chloride) cholesteryl oleyl carbonate is used, and these three types of liquid crystals are used so as to be used at room temperature. Is common.
In addition, it is not limited to the compound shown here, Moreover, these cholesteric liquid crystal compounds can be used 1 type or in mixture of 2 or more types.

  As a liquid crystal compound in which a chiral compound is added to a nematic liquid crystal compound, 4-substituted benzoic acid 4′-substituted phenyl ester, 4-substituted cyclohexanecarboxylic acid 4′-substituted phenyl ester, 4-substituted cyclohexane Carboxylic acid 4′-substituted biphenyl ester, 4- (4-substituted cyclohexanecarbonyloxy) benzoic acid 4′-substituted phenyl ester, 4- (4-substituted cyclohexyl) benzoic acid 4′-substituted phenyl ester, 4- (4- Substituted cyclohexyl) benzoic acid 4'-substituted cyclohexyl ester, 4-substituted 4'-substituted biphenyl, 4-substituted phenyl 4'-substituted cyclohexane, 4'-substituted cyclohexane, 2- (4-substituted phenyl) -5-substituted pyridine Etc. are used.

Particularly preferably, a liquid crystal compound having a cyano group or a fluorine atom at least at one end of the molecule is used, and various suitable chiral agents are added to these liquid crystal compounds. As the chiral compound, “CB-15”, “C-15” (manufactured by BDH), “CM-21”, “CM-22”, “CM-19”, “CM-20”, “CM” (Above, manufactured by Chisso Corporation), "S1082", "S-811", "R-811" (above, manufactured by Merck & Co., Inc.), and the like.
Furthermore, a three-dimensionally crosslinkable liquid crystalline polymerizable monomer molecule or polymerizable oligomer molecule can be used. A layer containing cholesteric liquid crystal molecules can be obtained by adding an arbitrary chiral agent to a predetermined polymerizable monomer molecule or polymerizable oligomer molecule.
Examples of the three-dimensionally crosslinkable monomer molecule include a mixture of a liquid crystal monomer and a chiral compound as disclosed in, for example, JP-A-7-258638 and JP-T-10-508882. As a more specific example, for example, liquid crystalline monomers represented by the following general chemical formulas (1) to (11) can be used. In the case of the liquid crystalline monomer represented by the general chemical formula (11), X is preferably an integer in the range of 2 to 5.

Moreover, as a chiral agent, a chiral agent as shown, for example by the following general chemical formula (12)-(14) can be used. In the case of the chiral agent represented by the general chemical formulas (12) and (13), X is preferably an integer in the range of 2 to 12, and the general chemical formula (1
In the case of the chiral agent represented by 4), X is preferably an integer in the range of 2-5.

When oligomer molecules are used, a cyclic organopolysiloxane compound having a cholesteric phase as disclosed in, for example, JP-A-57-165480 can be used. For example, a cholesteric liquid crystal layer can be obtained by adding about several to 10% of a chiral agent to polymerizable monomer molecules or polymerizable oligomer molecules. The cholesteric liquid crystal layer can be formed as a layer having a substantially uniform thickness, but can also be a pattern layer in which a pattern is formed depending on the presence or absence of the layer or a difference in thickness. The pattern layer can be formed using various printing methods.

Further, a cholesteric liquid crystal having no cholesterol group in which a group having an asymmetric carbon is introduced into a terminal group of a nematic liquid crystal obtained by organic synthesis, or a mixed liquid crystal in which a Schiff nematic liquid crystal is added to a cholesterol derivative is also used. Furthermore, halogen substitution products and esterified products of natural cholesterol (cholesteryl benzoate, cholesteryl chloride, cholesteryl oleate, cholesteryl nonanoate, and the like are also suitable.
As a method of providing these cholesteric liquid crystals, it can be formed by dissolving a cholesteric liquid crystal material in an appropriate solvent, applying it by various printing methods, and drying it. At this time, an ultraviolet-polymerizable composition is prepared using a polymerizable cholesteric liquid crystal, and the obtained ultraviolet-polymerizable composition is applied by various printing methods, and after drying, it is polymerized by irradiation with ultraviolet rays. You can also.
Alternatively, the liquid crystal may be formed using an ink encapsulated with a resin film such as gelatin. The encapsulated product is excellent not only in workability during production but also in physical properties (toughness, wear resistance, heat resistance, etc.) and particularly suitable in terms of hygiene.

The shapes and thicknesses of the cholesteric liquid crystal layers 14 and 15 need to be appropriately optimized depending on the purpose of use of the authenticity identifier. While maintaining the selective reflectivity and the polarization property, the thickness corresponding to each of the thicknesses, ie, 1.5 μm to 50 μm, is optimal. If it is 1 μm or less, its selective reflectivity and polarization are insufficient, and if it is 50 μm or more, half-cut processing becomes difficult and the protrusion on the transfer target 101 after patch transfer becomes large. This may cause troubles such as catching and peeling during use.
When the cholesteric liquid crystal layers 14 and 15 are provided, an alignment treatment such as providing the following alignment film may be performed in advance. Any alignment film may be used as long as it can be generally used as an alignment film, such as polyvinyl alcohol resin (PVA) or polyimide resin. For the alignment film, a solvent solution of these resins is applied to the surface of the layers forming the cholesteric liquid crystal layers 14 and 15 by an appropriate application method, dried, and then rubbed with a cloth, a brush, or the like. Form.

(Phase difference layer) The phase difference layer 17 laminated | stacked between the two cholesteric liquid crystal layers is a layer which birefrings incident light, produces a phase which changes with polarization directions, and provides a phase difference. Birefringence is a phenomenon that occurs because the refractive index of a medium is not uniform depending on the polarization direction, and the phase difference σ of light transmitted through such a medium is given by σ = 2π (ne−no) d / λ. It is known. Here, ne is the extraordinary ray refractive index, no is the ordinary ray refractive index, d is the thickness of the medium, and λ is the wavelength of the light. That is, for a medium having a certain thickness d, the phase difference σ depends on the wavelength λ of light. When the right circularly polarized light having the wavelength λ = 2 (ne−no) d is incident on the phase difference layer 2, the phase difference σ = π (that is, ½ wavelength) is given while transmitting the right circularly polarized light. Therefore, the incident right circularly polarized light is converted into left circularly polarized light and emitted, and the incident left circularly polarized light is converted into right circularly polarized light and emitted. Such a retardation layer 2 can be composed of a nematic liquid crystal layer, or a nematic liquid crystal layer and a transparent substrate film, as described later, in addition to the transparent substrate film being composed of a stretched plastic film.
The retardation layer 17 can be composed of, for example, nematic liquid crystal, and can be formed by various printing methods using an ink composition containing nematic liquid crystal, preferably an ink composition comprising a solvent solution of nematic liquid crystal. In addition to being used alone, it is laminated on the surface of the transparent base film having orientation or laminated on the surface of the base film via an orientation film. In addition, if a transparent base film is also a stretched plastic film, it can become a phase difference layer, and a layer obtained by laminating the phase difference layer 2 on such a transparent base film, or an alignment film on the transparent base film. A layer in which the retardation layer 17 is laminated can function as the retardation layer 17 as a whole.
As a method of laminating the transparent base material 11 and the composite cholesteric liquid crystal layer including the retardation layer, a method of laminating each film by using an ultraviolet curable resin and bonding and laminating by ultraviolet curing is formed. It is desirable because it has excellent interface properties (a mirror surface with less unevenness).

(Adhesive layer) As the adhesive layer 19, a heat-sensitive adhesive that melts or softens when heated and exhibits an adhesive effect can be applied. Specifically, a vinyl chloride resin, a vinyl acetate resin, or vinyl chloride. Examples thereof include vinyl acetate copolymer resins, acrylic resins, and polyester resins.
(Adhesive adhesive layer) The adhesive layer 19 is preferably an adhesive adhesive layer having both adhesiveness and thermal adhesiveness. As the adhesive adhesive layer, an acrylic resin or rubber resin having adhesiveness and thermal adhesiveness, or a mixture of an adhesive resin and a thermal adhesive resin can be applied.
Examples of the adhesive resin include vinyl acetate resin, vinyl acetate butyrate resin, chloroprene rubber, isoprene rubber, and urethane resin.
The material resin is dissolved or dispersed in a solvent, an additive such as a pigment is added as appropriate, and the layer is applied and dried by a known method such as roll coating, gravure coating, or comma coating, and a layer having a thickness of 1 to 30 μm Get. When the surface of the transfer target 101 is as smooth as a film sheet, a thickness of 1 to 5 μm is suitable, but it is preferably 3 μm or more on the image forming surface. On the contrary, when the surface of the transfer target 101 has a surface roughness of 30 μm or more like paper or cloth, the thickness of the adhesive layer 19 is 5 μm to 30 μm, and further, 20 μm to A thickness of 30 μm is preferred. In particular, in the case of an adhesive adhesive layer, a thicker one is desirable because the resin in a portion other than the image forming portion enters the transfer target 101.
However, having a transparent base material as a patch does not require the adhesive layer 19 to enter the transfer target 101 and exhibits sufficient durability only by partial adhesion. .

(Support Material) The support material 30 is provided with a peelable resin layer 33 on a support base material 31.
(Supporting base material) The supporting base material 31 is not particularly limited. For example, condenser paper, glassine paper, sulfuric acid paper, high-size paper, synthetic paper (polyolefin-based, polystyrene-based), high-quality paper, coated paper , Synthetic resin or emulsion-impregnated paper, polyester resins such as polyethylene terephthalate, polybutylene terephthalate, polyethylene naphthalate, polyamide resins, vinyl resins such as polyvinyl chloride, acrylic resins, imide resins, polyarylate, etc. Examples include engineering resins, polycarbonates, cyclic polyolefin resins, and cellulose films such as cellophane. When the peelable resin layer 33 described later is provided on the support base 31, the surface of the support base 31 may be subjected to corona discharge treatment or a primer layer may be provided in order to improve adhesion.

The support material 30 preferably has a thickness of 10 μm to 100 μm. If the sheet base material is too thin, the so-called stiffness of the obtained patch transfer medium 20 is lost, and it cannot be conveyed by a thermal transfer printer, or the patch transfer medium 20 is curled or wrinkled. Occur. On the other hand, if the support material 30 is too thick, the resulting patch transfer medium 20 becomes too thick, and the force to drive and drive the thermal transfer printer becomes too great, causing the thermal transfer printer to fail or not be transported normally.
(Peelable resin layer) The peelable resin layer 33 is formed of a pressure-sensitive adhesive layer, a simple adhesive layer, or an extrusion coating (EC) layer.

The pressure-sensitive adhesive layer is a conventionally known solvent-based or water-based pressure-sensitive adhesive, such as vinyl acetate resin, acrylic resin, vinyl acetate-acrylic copolymer, vinyl acetate-vinyl chloride copolymer, ethylene-vinyl acetate copolymer. Examples thereof include rubber resins such as coalescence, polyurethane resin, natural rubber, and chloroprene rubber. The coating amount of the pressure-sensitive adhesive layer is generally about 8 to 30 g / m ² (solid content), and is applied and dried by a conventionally known method such as gravure coating, roll coating, comma coating, and the like. To form an adhesive layer. Further, the adhesive strength of the pressure-sensitive adhesive layer is the peel strength between the transparent substrate 11 and the pressure-sensitive adhesive layer, and is desirably in the range of about 5 to 1,000 g in a 180 ° peeling method in accordance with JIS Z0237. It is preferable to select and use the kind of adhesive and the coating amount as described above so that the peel strength is within the above range when the adhesive layer is formed on the support substrate 31. Moreover, in order to provide an adhesive layer on the support base material 31 and to laminate the transparent base material 11 and the adhesive layer, methods such as dry lamination and hot melt lamination of the adhesive layer can be employed.

  For the simple adhesive layer, latex of acrylic resin such as styrene-butadiene copolymer rubber (SBR), acrylonitrile-butadiene copolymer rubber (NBR) or polyacrylate, rubber resin, waxes and a mixture thereof are used. Then, it may be formed on the support substrate 31 by a conventionally known coating method, and the transparent substrate 11 and the simple adhesive layer may be laminated by dry lamination while heating. And the simple adhesive layer after peeling the transparent base material 11 and the support base material 31 falls in adhesiveness, and the transparent base material 11 and the support base material 31 cannot be bonded together again. When such a simple adhesive layer is used, a primer layer may be provided between the support base 31 and the simple adhesive layer.

Further, as the peelable resin layer 33, an EC layer may be provided on the support base 31. The thermoplastic resin forming the EC layer does not essentially adhere to the transparent substrate 11 and is not particularly limited as long as the resin has EC processing characteristics. On the other hand, a polyolefin-based resin having no essential adhesiveness and excellent workability is particularly preferable. Specifically, LDPE, MDPE, HDPE, PP resin, etc. can be used.
Using a mat roll as the cooling roll for EC processing of these resins, the mat surface is transferred to the surface of the EC layer to make the irregular shape opaque, and the polyolefin resin is calcium carbonate, titanium oxide, etc. The white pigment may be kneaded and made opaque.
The EC layer may be a single layer or a plurality of layers. The peel strength from the transparent substrate 11 can be adjusted by the processing temperature and the resin type during EC processing. In this way, the EC layer is formed on the support substrate 31 simultaneously with EC processing, and the support substrate 31 and the transparent substrate 11 may be laminated via the EC layer by so-called EC lamination.

(Heat resistant slipping layer) In the patch transfer medium 20, a heat resistant slipping layer may be provided on the surface opposite to the peelable resin layer 33 surface of the support base 31 as required.
Since retransfer to the transfer target 101 using the patch transfer medium 20 uses a thermal transfer printer such as a thermal head or a heat roll, a heat resistant slipping layer is provided to prevent adverse effects such as sticking and wrinkles due to the heat. Also good. The resin for forming the heat-resistant slipping layer may be any conventionally known resin such as polyvinyl butyral resin, polyvinyl acetoacetal resin, acrylic resin, cellulose resin, aromatic polyamide resin, polyimide resin, polycarbonate resin, etc. Is mentioned.
The slipperiness-imparting agent that is added to or overcoated the heat-resistant slipping layer is, for example, a layer composed of a polyalcohol polymer compound, a polyisocyanate compound, and a phosphate ester compound, and a filler may be further added. preferable. The heat resistant slipping layer is prepared by dissolving or dispersing the above-described resin, slipperiness-imparting agent, and filler with an appropriate solvent, and, for example, gravure printing or screen printing on the back surface of the support substrate 31. It may be formed by applying and drying with the like.

(Patch) The patch transfer medium 20 has a patch 21 laminated on the surface of a support material 30 in a peelable manner. The patch 21 is in the form of a patch by half-cutting the transfer portion of the transfer material 10 composed of the transparent base material 11 / composite cholesteric liquid crystal layer or hologram forming layer 18 / adhesive layer 19, and the support base material 31 / peelable resin layer 33. It is laminated | stacked on the support material 30 which consists of so that peeling is possible.
(Half cut) As a half-cut treatment method, a method of moving the upper die up and down by inserting the patch transfer medium 20 in a stacked state before cutting between the upper die attached with the cutter blade and the pedestal, or cylinder type There is no particular limitation as long as it is a method capable of half-cutting, such as a rotary cutter method or a heat treatment method using a laser processing means.
It is not necessary to remove the patch 21 portion and the other portions. However, as shown in the cross section of the patch transfer medium 20 shown in FIG. 1, only the patch 21 portion is half-cut and the other portions are peeled off in advance. It is preferable to keep it (referring to those skilled in the art as scrap removal). When the patch 21 is transferred to the transfer target, the transparent substrate 11 is not cut at the half-cut portion and can be transferred reliably.

In general, half-cutting is performed by continuously cutting around the patch 21 in units of one round, and by partially providing uncut (no cut) parts such as four corners or perforated parts. It is possible to prevent troubles in which the half-cut portion is peeled off during handling such as during transfer of the thermal transfer printer. In addition, at least one part of the support material 30 is not cut and is made continuous. If the cutting depth is too deep in the half-cut processing, the support base material 31 is cut, and the printer is cut at the half-cut processing section during printer conveyance, which easily causes a conveyance trouble.
Although it does not specifically limit as a shape of the patch 21, For example, a rectangle, an ellipse, a round shape, a donut shape etc. can be illustrated. The half-cut patch 21 portion may be smaller than the entire size of the transfer target body, and the patch 21 portion may be partially removed from the transfer body. Furthermore, the entire width of the patch transfer medium 20 may be wider than the width of the surface to which the transfer target is transferred.
(Patch Transfer Medium) The patch transfer medium 20 of the present invention has a transparent base material 11 / composite cholesteric liquid crystal layer or hologram forming layer 18 / adhesive layer 19 on the surface of a support material 30 comprising a support base material 31 / peelable resin layer 33. A patch 21 obtained by half-cutting the transfer portion of the transfer material 10 is laminated so as to be peelable.

(Anti-Counterfeit Medium) An anti-counterfeit medium 100 transferred using the patch transfer medium 20 manufactured by the method for manufacturing a patch transfer medium of the present invention is a transfer material using the patch transfer medium 20 as shown in FIG. The patch 21 formed into a patch shape by half-cutting the 30 transfer portions is peeled off from the support material 30 and transferred to the transfer target 101. The patch 21 includes a transparent substrate 11, a composite cholesteric liquid crystal layer, a hologram forming layer 18, and an adhesive layer 19.
(Transfer method) As a transfer method for transferring to a transfer object, a known transfer method may be used. For example, hot stamping by hot stamping (foil stamping), transfer by a hot roll, thermal printer using a thermal head (thermal printing head). A known method such as a thermal transfer printer can be applied. Further, it may be transferred by heating in accordance with the shape of the patch 21. However, transfer is possible at a lower temperature, lower pressure, and shorter time than usual. For this reason, the load on the transfer medium is also small.
Furthermore, only the predetermined part of the non-transfer body is matched to the hologram design and transferred so as to cover (covering only the specific image part where the anti-counterfeit effect is desired), so that the right or left circular polarization of the cholesteric liquid crystal layer, A high anti-counterfeiting effect can be obtained by the light transmission / shielding effect through the right or left circularly polarizing plate that can confirm the effect.

This effect is further enhanced by causing the above-described difference between the predetermined portion of the image forming portion and the other portions by accurately transferring and forming the predetermined image forming portion by the patch transfer method.
(Transfer To be Transferred) The transfer target 101 is not particularly limited, for example, natural fiber paper, coated paper, tracing paper, plastic film that is not deformed by heat during transfer, glass, metal, ceramics, wood, cloth, etc. Any one of them may be used, and it may be appropriately selected depending on the application. Further, at least a part of the medium of the transfer target 101 may be subjected to image, coloring, printing, or other decoration.

(Image Forming Layer) The image on the transfer target 101 is not particularly limited, but images such as letters, numbers, and facial photographs are formed. As a method of forming an image on the transfer target 101, any one of a heat melting transfer method, a heat sublimation transfer method, and an ink jet method is preferable.
The image forming layer 102 to be an image is printed on the transfer target 101 with a thermal transfer printer or an ink jet printer, and the patch 21 is subsequently applied to the surface of the image forming layer 102 using the forgery prevention medium 100 by an in-line method in the same planter. Can be transferred. When the image forming layer 102 is provided on the transfer target 101, a receiving layer (a layer having improved image forming properties) may be provided as necessary in order to improve the adhesion and fixing properties of printing.
Although the image forming layer 102 provided on the surface of the transfer target 101 lacks durability, the patch 21 is transferred and the image is protected, thereby being excellent in various durability and excellent in heat resistance and light resistance. The forgery prevention medium 100 is excellent in security.
In this way, the forgery prevention medium 100 using the patch transfer medium 20 forms an image on a medium such as a card (transfer object), particularly a transfer object, and a highly durable patch (protective layer) on the image. The thermal transfer image is excellent in various durability even under severe use conditions, and the patch can be easily and accurately transferred onto the image by the patch (protective layer). In addition, it has excellent security and durability during use, that is, a hard coat property, and in addition to scratch resistance and solvent resistance to protect the surface of the medium even when used repeatedly, heat resistance and It has a composite cholesteric liquid crystal layer and a hologram forming layer with excellent light resistance.

(Durability) Since it can protect the surface of the medium and protect it from mechanical and chemical damage over a long period of time even after repeated use, it can be used for gas station cards and construction site cards used in extremely harsh environments, and It can also be suitably used for an entrance / exit card that has no expiration date or that repeatedly enters and exits many security-controlled rooms such as entrance / exit cards, point cards, and financial institutions.
In addition, the weather resistance test measured according to JIS-B-7753 (Sunshine carbon arc lamp type light resistance and weather resistance tester) compares the color change of the printed matter after irradiation for 500 hours with that before irradiation. As a result of visual evaluation, there was no significant change even after 500 hours.
In this way, the foil can be easily transferred to a medium (transfer object) such as a card, and the transferred medium has excellent security and durability during use, that is, hard coat properties. Even when used repeatedly many times, it has a composite cholesteric liquid crystal layer and a hologram forming layer excellent in heat resistance and light resistance in addition to scratch resistance and solvent resistance for protecting the surface of the medium.

EXAMPLES Hereinafter, although an Example and a comparative example demonstrate this invention further in detail, it is not limited to this. In addition, except a solvent, each composition of each layer is a mass part of solid content conversion.
Example 1
Using a PET (polyethylene terephthalate) film having a thickness of 25 μm as the transparent substrate 11, the following cholesteric liquid crystal layer composition (A) is printed on one surface of the substrate 11 by screen printing, and the thickness after drying Immediately after coating and drying at 60 ° C. so that the thickness is 2.2 μm, a 38 μm thick PET film is laminated and irradiated with ultraviolet rays so that the first cholesteric liquid crystal layer 14 is sandwiched between the PET films. Formed.
・ <Polymerizable cholesteric liquid crystal composition (A)>
20 parts by mass of polymerizable nematic liquid crystal (manufactured by BASF Corp., trade name: “Paliocolor LC242”)
1 part by mass of chiral agent (manufactured by BASF Corp., trade name: “Palio Color LC756”)
Ultraviolet polymerization initiator 1 part by weight Toluene 78 parts by weight Gravure coating is performed on a PET film having a thickness of 38 μm using a polymerizable nematic liquid crystal solution, dried, and then irradiated with ultraviolet rays to obtain a thickness of 1.0 μm. The nematic liquid crystal layer was formed.
The two-layer laminate portion of the PET film / nematic liquid crystal layer having a thickness of 38 μm becomes the retardation layer 17.
・ <Polymerizable nematic liquid crystal composition>
Nematic liquid crystal BASF "Palio Color LC242" 15 parts by weight UV polymerization initiator 0.8 part by weight Toluene 42.1 parts by weight Cyclohexanone 42.1 parts by weight This two-layer laminate of PET film / nematic liquid crystal layer with a thickness of 38 μm The phase difference layer 17 is formed.

On this retardation layer 17, gravure printing is performed using another polymerizable cholesteric liquid crystal solution (B), dried, and then irradiated with ultraviolet rays, whereby a cholesteric liquid crystal layer having a thickness of 2.2 μm ( B) was formed on the entire surface to form a second cholesteric liquid crystal layer 15.
・ <Polymerizable cholesteric liquid crystal composition (B)>
24 parts by mass of polymerizable nematic liquid crystal (manufactured by BASF Corp., trade name: “Paliocolor LC242”)
1 part by mass of chiral agent (manufactured by BASF Corp., trade name: “Palio Color LC756”)
Ultraviolet polymerization initiator 1 part by mass Toluene 74 parts by mass The second cholesteric liquid crystal layer of the composite cholesteric liquid crystal layer having a laminated structure of the obtained transparent substrate 11 / first cholesteric liquid crystal layer 14 / retardation layer 17 / second cholesteric liquid crystal layer 15 On the liquid crystal layer 15 side, the following adhesive layer composition was applied with a gravure coater so that the coating amount after drying was 3 μm, and dried at 60 ° C. to form the adhesive layer 19, and transparent substrate 11 A transfer material 10 having a layer structure of / first cholesteric liquid crystal layer 14 / retardation layer 17 / second cholesteric liquid crystal layer 15 / adhesive layer 18 was obtained.
・ <Adhesive layer composition>
Urethane resin 20 parts Acrylic resin 10 parts Solvent (methyl ethyl ketone: toluene = 1: 1) 70 parts

Separately, a PET film having a thickness of 38 μm was used as the support 31, and the support 31 and the previously produced transfer material 10 were laminated. The following peelable resin layer composition is applied to the surface of the support 31 so that the coating amount after drying is 3 μm and dried at 70 ° C., and then the transparent substrate 11 surface of the transfer material 10 is pressurized. A laminate was obtained by the dry lamination method.
・ <Peelable resin layer composition (simple adhesive layer type)>
Acrylic resin latex (manufactured by Nippon Zeon Co., Ltd., LX874) 30 parts Solvent (water: isopropyl alcohol = 1: 1) 70 parts Rectangle cutter blade with rounded corners on the transfer material 10 part to the above laminated product A half-cut process was performed by a press method of an upper mold and a pedestal to which a patch was attached, and scrap removal was performed to obtain a patch transfer medium 20 of Example 1 in a continuous winding shape in which patches were peeled and stacked. Using a credit card specification card made of polyvinyl chloride as the transfer target 101, a sublimation type thermal transfer sheet (Dai Nippon Printing Co., Ltd., yellow, magenta, cyan) is applied to the surface of the transfer target 101. Using a standard ribbon, an image (image forming layer 102) was formed by printing a face photograph, name and ID number of 10 digits as specific information at a predetermined position with a 600 dpi thermal transfer printer. The surface of the adhesive layer 18 of the patch transfer medium 20 is overlapped on the image surface with a card printer CX330 made by DNP so that the hologram image overlaps with a predetermined position of the face photograph with high positional accuracy. The anti-counterfeit medium 100 transferred using the patch transfer medium 20 manufactured by the patch transfer medium manufacturing method of Example 1 was obtained. At this time, the face photograph was observed together with the composite cholesteric liquid crystal, and further exhibited a color tone change peculiar to the cholesteric liquid crystal, and was excellent in design. When the obtained anti-counterfeit medium 100 was viewed at a different angle from the first cholesteric liquid crystal layer 14 side, the effect of changing the color of the cholesteric liquid crystal layer could be confirmed. Further, when the right circularly polarizing plate is superimposed on the first cholesteric liquid crystal layer 14 side of this authenticity determination medium, the whole appears colored green, and when the left circularly polarizing plate is overlapped except for the right circularly polarizing plate, the whole Was colored red, and it was easy to prove that this anti-counterfeit medium was genuine.

(Example 2) On the second cholesteric liquid crystal layer 15 side of the composite cholesteric liquid crystal layer having a laminated structure of transparent substrate 11 / first cholesteric liquid crystal layer 14 / retardation layer 17 / second cholesteric liquid crystal layer 15 of Example 1. Applying a transparent ultraviolet curable resin composition, irradiating with ultraviolet rays while keeping the mold surface of the reproduction mold of the hologram (having a forgery prevention design of the same size as the photo size provided on the face photograph) in contact, A hologram relief was formed by curing the transparent ultraviolet curable resin composition, and a transparent reflective thin film 40 nm made of TiO 2 was provided thereon by a vacuum deposition method to form the hologram forming layer 18. As a result, a hologram forming layer having a thickness of 2 μm was formed. Except for this, the patch transfer medium 20 manufactured by the patch transfer medium manufacturing method of Example 2 was obtained in the same manner as Example 1. At this time, the face photograph was observed together with the hologram image, showed a color tone change peculiar to the cholesteric liquid crystal, and was excellent in design. When the obtained anti-counterfeit medium 100 was viewed at a different angle from the first cholesteric liquid crystal layer 14 side, the effect of changing the color of the cholesteric liquid crystal layer could be confirmed. Further, when the right circularly polarizing plate is superimposed on the first cholesteric liquid crystal layer 14 side of this authenticity determination medium, the whole appears colored green, and when the left circularly polarizing plate is overlapped except for the right circularly polarizing plate, the whole Was colored red, and it was easy to prove that this anti-counterfeit medium was genuine.

(Reference Example 1) As the adhesive composition, the following adhesive layer composition having image-forming properties was used to form the adhesive layer 19,
・ <Adhesive layer composition having image-forming properties>
Vinyl chloride / vinyl acetate copolymer resin 30 parts Solvent (Methyl ethyl ketone: Toluene = 1: 1) 70 parts and aligned so that the patch overlaps only in the face photo position and the latter half of the ID number, and the adhesive layer 19 has an ID Example 2 except that the five-digit number was printed and that the patch was partially transferred after high-precision alignment so as to be connected to the five-digit ID number already formed on the card. Reference Example 1 was obtained in the same manner as above. At this time, the hologram on the face photograph is the same as in Example 2, and the ID number is observed as 10 digits with high positional accuracy, and is optically obtained using a light source having a wavelength different from the main wavelengths of the first and second cholesteric liquid crystals. When automatic automatic reading was performed, optical automatic recognition was possible as a 10-digit number. In addition, the composite cholesteric liquid crystal layer portion showed a color tone change peculiar to the cholesteric liquid crystal similar to that in Example 2, was excellent in design, and was easy to determine authenticity with two types of circularly polarizing plates.

Reference Example 2 Reference Example 2 was obtained in the same manner as in Example 3 except that an image was formed with a hot melt transfer printer SIS MSP40 (manufactured by Sun Graphic). Although the effect as a forgery prevention medium was the same as that of Reference Example 1 , it was excellent in automatic ID number recognition.
Reference Example 3 Reference Example 3 was obtained in the same manner as in Example 4 except that an image was formed with an inkjet printer (Canon iPF9000). The effect as a forgery prevention medium was the same as in Example 4.

(Reference Example 4) As an adhesive layer composition,
・ <Adhesive layer composition (adhesive adhesive layer)>
Vinyl chloride / vinyl acetate copolymer resin 30 parts Vinyl acetate resin 30 parts Solvent (methyl ethyl ketone: toluene = 1: 1) 40 parts were used, and an image was formed with an inkjet printer (Canon iPF9000), Reference Example 4 was obtained in the same manner as Reference Example 3 . Since the adhesive layer has tackiness, the toner has excellent fixability and a clear image can be obtained. Further, due to the adhesiveness, the transfer to the transfer target 101 could be performed at low temperature and low pressure (50 degrees, 0.1 ton / cm 2). The effect of the anti-counterfeit medium was the same as in Reference Example 3 , but damage to the composite cholesteric liquid crystal layer was less than in Reference Example 3 .

(Reference Example 5) On the opposite side of the support 31 from the surface on which the peelable resin layer composition was formed, the following hard coat layer composition was applied and dried at 70 ° C. so that the coating amount after drying was 3 μm. Except that, Reference Example 5 was obtained in the same manner as Example 1.
・ <Hard coat layer composition>
MHX405 varnish (manufactured by The Inktec Co., Ltd.) 25 parts methacrylate oligomer (manufactured by Nippon Synthetic Chemical Co., Ltd., trade name: Purple Light 6630B) 5 parts photopolymerization initiator (manufactured by Ciba, trade name: Irgacure 907) 0.9 part solvent (acetic acid Ethyl: methyl isobutyl ketone = 1: 1) With the 70 parts hard coat layer, the card printer could print smoothly. Other effects were the same as in Example 1.
Reference Example 6 Reference Example 6 was obtained in the same manner as Reference Example 1 except that 5 digits of ID number was printed on the retardation layer instead of 5 digits of ID number printed on the adhesive layer 19. The design and authenticity determination effects were the same as in Reference Example 1. However, when the automatic recognition operation was performed using the left circularly polarizing plate with the main wavelength of the second cholesteric liquid crystal layer as the light source, a 10-digit ID number was used. Was able to recognize.

(Comparative Example 1)
Using a credit card specification card made of polyvinyl chloride as the transfer target 101, a sublimation type thermal transfer sheet (Dai Nippon Printing Co., Ltd., yellow, magenta, cyan) is applied to the surface of the transfer target 101. Comparative Example 1 is a card in which a face photograph, a name and an ID number of 5 digits, which are unique information, are printed at a predetermined position with a 600 dpi thermal transfer printer using a standard ribbon) and an image is still formed.
(Comparative Example 2)
Comparative Example 2 was obtained in the same manner as Comparative Example 1 except that the transfer sheet had a hologram forming layer and was transferred onto a facial photograph.
Comparative Example 2 is superior in anti-counterfeiting properties than Comparative Example 1 in that it can observe a hologram image, and also has excellent durability because it has a transparent substrate on the outermost surface. However, since only the hologram image is visually confirmed, there remains anxiety as to whether or not it is authentic.
(Comparative Example 3)
Comparative Example 3 was obtained in the same manner as in Example 1 except that the retardation layer and the second cholesteric liquid crystal layer were not provided.
A certain amount of anti-counterfeiting effect was obtained due to the design and unique color tone of cholesteric liquid crystal, but the function of this cholesteric liquid crystal can be easily analyzed from the observation side, so it is easy for counterfeiters with a predetermined knowledge Seemed to be able to forge.

(Evaluation test) Evaluation was carried out by transferring to a transfer medium and evaluating the transferability, the hardness of the surface after transfer, scratch properties, and light resistance.
(Evaluation Results) The patch transfer media 20 obtained in Examples 1 and 2, Reference Examples 1 to 6 and Comparative Example 3 had good peelability during transfer and could be transferred normally. When the pencil hardness test was measured according to JIS-K-5400, it had a hardness of 2H or more, and showed sufficient durability. In addition, regarding light resistance, measurement is performed according to JIS-B-7773 (Sunshine carbon arc lamp type light resistance and weather resistance tester), and the change in color of the image after irradiation for 500 hours is compared with that before irradiation. And visually evaluated. In the patch transfer media 20 obtained in Examples 1 and 2, Reference Examples 1 to 6 , and Comparative Example 3 , there was no significant change and the light resistance was good. However, in Comparative Examples 1 and 2, it was HB or less in the pencil hardness test, and in the light resistance test, fading was observed, which was somewhat poor.
(Authenticity Evaluation) The anti-counterfeit medium 100 obtained in Examples 1 and 2 and Reference Examples 1 to 6 is a design property of the cholesteric liquid crystal layer and confirmation of polarization characteristics by a combination of the hologram forming layer and the cholesteric liquid crystal layer. Thus, the authenticity was sufficiently confirmed. However, Comparative Examples 1 and 2 only confirmed the image by visual observation, and anxiety remained about authenticity. Moreover, it was thought that the comparative example 3 can be easily counterfeited if it is a forger who has predetermined knowledge.

1A is a cross-sectional view of a composite cholesteric liquid crystal layer, FIG. 1B is a diagram showing the function of the composite cholesteric liquid crystal layer, and FIG. 2 is manufactured by the method for manufacturing a patch transfer medium of the present invention. 2 is a cross-sectional view of a patch transfer medium.
FIG. 3 is a cross-sectional view of an anti-counterfeit medium transferred using the patch transfer medium manufactured by the patch transfer medium manufacturing method of the present invention. (An image is formed in advance on the transfer medium.)
FIG. 4 is a cross-sectional view of a forgery prevention medium transferred using a patch transfer medium manufactured by the method for manufacturing a patch transfer medium of the present invention (an image is formed in advance on the patch transfer medium).
FIG. 5 is a cross-sectional view showing another example of a patch transfer medium manufactured by the method for manufacturing a patch transfer medium of the present invention.
FIG. 6 is a cross-sectional view of an anti-counterfeit medium showing still another example transferred using the patch transfer medium manufactured by the method for manufacturing a patch transfer medium of the present invention (image formation on a transfer medium).
FIG. 7 is a cross-sectional view of an anti-counterfeit medium showing still another example transferred using the patch transfer medium manufactured by the method for manufacturing a patch transfer medium of the present invention (image formation on the patch transfer medium).

Explanation of symbols

1: Composite cholesteric liquid crystal layer 10: Transfer material 11: Base material 14: First cholesteric liquid crystal layer 15: Second cholesteric liquid crystal layer 17: Retardation layer 18: Hologram forming layer 19: Adhesive layer 20: Patch transfer medium 21: Patch 30: Support material 31: Support substrate 33: Peelable resin layer 100: Anti-counterfeit medium 101: Transfer object 102: Image forming layer

Claims (3)

The transfer material is detachably supported as a transfer part on the support material ,
Said support member is Ri Do from the supporting substrate and the release resin layer,
In the method for producing a patch transfer medium , wherein the transfer material comprises a transparent substrate, a first cholesteric liquid crystal layer, a retardation layer, a second cholesteric liquid crystal layer, and an adhesive layer.
(1) a transparent substrate preparation step of preparing a transparent substrate;
(2) The first cholesteric liquid crystal layer composition is printed on one surface of the transparent substrate by a printing method and dried, and then a PET film is laminated and irradiated with ultraviolet rays to form the first cholesteric liquid crystal layer. First cholesteric liquid crystal layer forming step,
(3) The surface of the PET film is coated with a polymerizable nematic liquid crystal solution by a coating method and dried, and then irradiated with ultraviolet rays to form a nematic liquid crystal layer. The PET film and the nematic liquid crystal layer are two layers. A retardation layer forming step using the laminate as the retardation layer;
(4-1) On the surface of the retardation layer, gravure printing is performed using a second polymerizable cholesteric liquid crystal solution different from the first cholesteric liquid crystal layer composition, and after printing and drying, irradiation with ultraviolet rays is performed. A second cholesteric liquid crystal layer forming step for forming two cholesteric liquid crystal layers;
(5) An adhesive layer forming step that becomes the transfer material by applying an adhesive layer composition by a coating method on the surface of the second cholesteric liquid crystal layer and drying to form an adhesive layer;
(6) Separately, a supporting base material preparing step of preparing the supporting base material,
(7) A peelable resin layer forming step of coating the peelable resin layer composition on the surface of the support substrate and drying to form the peelable resin layer;
(8) On the surface of the peelable resin layer, a laminating step in which the surface of the transparent base material of the transfer material is laminated by a dry lamination method;
(9) A method of manufacturing a patch transfer medium , comprising: a half-cut step of half-cutting a portion of the transfer material of the laminated product into a patch. A method for producing a patch transfer medium according to claim 1 ,
Between the step (4-1) and the step (5),
(4-2) A method of manufacturing a patch transfer medium , comprising: a hologram forming layer forming step of forming a hologram forming layer on the surface of the second cholesteric liquid crystal layer . A method for producing a patch transfer medium according to claim 1 or 2 ,
A patch transfer medium comprising , following the step (9), (10) forming an image on the surface of the adhesive layer by any one of a hot melt transfer method, a heat sublimation transfer method, and an ink jet method. Manufacturing method .

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