JP2020082354A - Thermosensitive transfer medium and information recording body - Google Patents

Abstract

To provide a thermosensitive transfer medium capable of providing a latent image by ink containing a brilliant pigment and an information recording body on which a latent image is provided by the thermosensitive transfer medium.SOLUTION: There is provided a thermosensitive transfer medium obtained by successively providing one or more thermal transfer ink layers C, M and Y containing a dye and at least two functional thermal transfer ink layers P1 and P2 composed of functional ink containing a brilliant pigment on one surface of a support, wherein the functional thermal transfer ink layers have a functional thermal transfer ink layer A composed of functional ink A containing a brilliant pigment A and a functional thermal transfer ink layer B composed of functional ink B containing a brilliant pigment B, the functional thermal transfer ink layer A and the functional thermal transfer ink layer B have the same interference color and the functional thermal transfer ink layer A and the functional thermal transfer ink layer B have haze values which are different from each other.SELECTED DRAWING: Figure 1

Description

The present invention relates to a thermal transfer medium for producing an information recording medium such as a personal authentication medium represented by a passport or an ID card, an information recording medium using the same, and a display method thereof.

Conventionally, security and design are added to printed matter in which characters and patterns are printed by various methods, especially personal authentication media such as passports and ID cards, as well as information recording bodies that require security such as credit cards and passbooks. In order to do so, an image having a special visual effect is provided, and it is said that there are effects such as forgery, falsification and forgery prevention, and proof of authenticity.

Various methods for providing an image have been proposed, one of which is a thermal transfer recording method using a thermal transfer medium such as an ink ribbon. The thermal transfer recording method includes a direct transfer method in which ink is directly transferred from a thermal transfer medium to an information recording medium, and an indirect method in which ink is temporarily transferred from the thermal transfer medium to an intermediate transfer foil and then retransferred from the intermediate transfer foil to the information recording medium. There is a transfer method, which is widely used according to each characteristic.

As a method for providing an image having a special visual effect, for example, Patent Document 1 discloses a method of forming a latent image using fluorescent ink, and Patent Document 2 discloses a pattern combining a diffraction grating and a light scattering pattern. And the method of forming an image with a thermal transfer ink containing a pearl pigment that emits interference light, respectively.

The latent image formed by the fluorescent ink of Patent Document 1 is formed by printing a colorless fluorescent ink containing a fluorescent substance on a card using a conventional printing technique such as offset to form a latent image. It is suitable for providing a common latent image on the card, and it is good for identifying whether the card base material is genuine, but in order to be able to determine whether the displayed content of the issued card is genuine, It was not realistic because it was necessary to make a printing plate for each.

Patent Document 2 proposes a method of printing individual information by using a diffraction grating such as a hologram as a thermal transfer foil. In addition, an indirect transfer method is used to provide an optically variable element such as a hologram between transfer layers of the intermediate transfer foil, and the effect of providing an anti-counterfeit property is achieved. However, in general, it is relatively easy to obtain hologram transfer foils, so the anti-counterfeiting effect is also limited, and it is possible to substitute a seemingly similar effect. However, there was also the problem that it was difficult to make a genuine/counterfeit judgment by visual observation except for a professional engineer.

Further, Patent Document 3 discloses a printing method for forming a second image using a pearl pigment and a method for forming an image in the form of a thermal transfer ribbon. However, the pearl pigment (brightening pigment) is It is used for various kinds of cosmetic boxes, wrapping paper, etc., and it is generally easily available, and there is a problem that it is easy to copy if it has a simple pattern.

Registered utility model No. 3029273 JP-A-2000-263910 JP, 2004-142445, A

The present invention provides a heat-sensitive transfer medium capable of forming a latent image with an ink containing a glitter pigment (pearl pigment), and an information recording medium provided with a latent image on the heat-sensitive transfer medium. The latent image can be provided in a special pattern with the ink containing, and the displayed image can be changed when the interference color is exhibited by the bright pigment and when the interference color disappears, and the duplication is difficult. An object of the present invention is to provide a heat-sensitive transfer medium and an information recording body that can obtain high security.

In order to solve the above problems, the invention according to claim 1 of the present invention is
One or more thermal transfer ink layers containing a dye and at least two functional thermal transfer ink layers consisting of a functional ink containing a bright pigment are provided on one surface of the support in a frame-sequential manner.
The functional thermal transfer ink layer has a functional thermal transfer ink layer A made of the functional ink A containing the bright pigment A and a functional thermal transfer ink layer B made of the functional ink B containing the bright pigment B. Then
The functional thermal transfer ink layer A and the functional thermal transfer ink layer B have the same interference color,
The thermal transfer medium is characterized in that the functional thermal transfer ink layer A and the functional thermal transfer ink layer B have different haze values from each other.

The invention according to claim 2 of the present invention is
The haze value of the functional thermal transfer ink layer A is 1% or more and less than 3%, and the haze value of the functional thermal transfer ink layer B is 3% or more and less than 6%. It is a thermal transfer medium.

The invention according to claim 3 of the present invention is
On the substrate,
One or more thermal transfer ink layers containing a dye,
At least the functional thermal transfer ink layer A made of the functional ink A containing the bright pigment A and the functional thermal transfer ink layer B made of the functional ink B containing the bright pigment B are thermally transferred,
The functional thermal transfer ink layer A and the functional thermal transfer ink layer B have the same interference color, the functional thermal transfer ink layer A and the functional thermal transfer ink layer B have different haze values, and the overlay layer Is an information recording body in which
At least one image forming portion on which a predetermined display image is formed using the functional ink A and the functional ink B is provided, and the image forming portion has the functionality when viewed from a predetermined observation angle. The information recording medium is characterized in that the same interference color exhibited by the thermal transfer ink layer A and the functional thermal transfer ink layer B is visible, and the interference color disappears when the observation angle is changed.

The invention according to claim 4 of the present invention is
The haze value of the functional thermal transfer ink layer A is 1% or more and less than 3%, and the haze value of the functional thermal transfer ink layer B is 3% or more and less than 6%. It is an information recording body.

The invention according to claim 5 of the present invention is
The image forming unit forms a predetermined display image using at least two types of cell patterns, that is, a cell pattern A formed of the functional ink A and a cell pattern B formed of the functional ink B. The information recording medium according to claim 3 or 4, wherein

The invention according to claim 6 of the present invention is
A cell pattern C formed by core dots α formed of the functional ink A, and peripheral dots β formed of the functional ink B adjacent to the core dots α and having the same area as the core dots α, ,
A cell pattern D formed by a core dot β formed of the functional ink B and a peripheral dot α formed of the functional ink A adjacent to the core dot β and having the same area as the core dot β. The information recording body according to claim 3 or 4, wherein a predetermined display image is formed by using at least two types of cell patterns.

The invention according to claim 7 of the present invention is
The functional ink of the core dots α of the cell pattern C and the core dots β of the cell pattern D is obtained by stacking a convex lens array having the same pitch as the cell patterns are arranged on the information recording medium according to claim 6. The cell pattern display method is characterized by displaying only the background color of.

According to the first aspect of the present invention, there is provided a thermal transfer medium in which a functional thermal transfer ink layer is formed by the functional ink A and the functional ink B each containing a different bright pigment, The functional thermal transfer ink layer A made of the ink A and the functional thermal transfer ink layer B made of the functional ink B exhibit the same interference color and have different haze values, so that they are transferred to a recording medium or the like requiring security. When a display image is formed, when viewed from an angle at which an interference color is produced due to the action of the bright pigment, even if patterns such as characters and images of the functional ink A and the functional ink B are provided as the display image, they are the same. Because of the interference color, it cannot be seen as a pattern of characters or images. On the other hand, when viewed from a different angle, the color of the part that becomes the base due to the disappearance of the interference color, that is, the base color, looks different due to the different haze values of the functional thermal transfer ink layer A and the functional thermal transfer ink layer B, It is possible to make a pattern such as a predetermined character or image stand out as a display image. That is, a thermal transfer medium can be obtained which can be made into a latent image or a visible image depending on the viewing angle of the recording medium and can be viewed differently to provide security.

According to the second aspect of the present invention, it is possible to obtain the heat-sensitive transfer medium in which the difference in the appearance of the base color when the interference color disappears can be suitably obtained.

According to the third aspect of the invention, the image forming portions formed by using the functional ink A and the functional ink B are the same when viewed from an angle at which an interference color is produced by the action of the bright pigment. When viewed from different angles, the interference color disappears and the underlying color is visible. Therefore, the appearance of the underlying color depends on the difference in the haze value between the functional thermal transfer ink layer A and the functional thermal transfer ink layer B. However, an information recording body can be obtained in which the formed predetermined display image appears to stand out. In other words, a latent image or a visible image can be formed depending on the viewing angle of the recording medium, and the information recording body having security can be obtained by allowing different appearances depending on the viewing angle.

Further, according to the invention described in claim 4, it is possible to obtain the information recording medium in which the difference in the appearance of the base color when the interference color disappears can be suitably obtained.

According to the invention of claim 5, the angle at which the image forming portion is formed by the cell pattern A formed of the functional ink A and the cell pattern B formed of the functional ink B, and the interference color disappears. When viewed from above, the cell pattern A and the cell pattern B have different appearances, so that an information recording body in which a predetermined display image appears to be visible can be obtained.

According to the invention of claim 6, the image forming unit forms a predetermined image using two cell patterns in which core dots and peripheral dots having equal areas having different haze values are combined. With normal visual inspection, the two types of cell patterns cannot be distinguished because the interference color and the background color look the same, and characters and symbols are recorded as an image formed on the cell pattern in a latent image state. Thus, an information recording body can be obtained in which characters and symbols can be recorded as secret information, and an image formed by using the convex lens array can be viewed as a visible image.

According to the invention described in claim 7, the characters and symbols recorded as a latent image in the cell pattern in the image forming body according to claim 6 are magnified and displayed only by the convex lens array in the nucleus dot portion. Since the appearance of the color of the base portion is different, it is possible to display the latent image in a mode that can be easily visually confirmed.

It is a figure which shows the example of the thermal transfer medium of this invention. 1 is a schematic configuration diagram of an example of an indirect thermal transfer printer. It is a figure which shows the example of a form of the cell pattern A and the cell pattern B. It is a figure which shows the example of the image formed by the cell pattern A and the cell pattern B. FIG. 6 is a diagram illustrating how an image forming portion formed with a cell pattern A and a cell pattern B looks. It is the figure which planarly viewed one form of the information recording body of this invention. It is sectional drawing of one form of the information recording body of this invention. It is a figure which shows the example of a form of the cell pattern C and the cell pattern D. It is a figure which shows the example of the image formed by the cell pattern C and the cell pattern D. It is the top view and sectional view of the example of form of a convex lens array. It is a top view of the state where the convex lens array was piled up on the image pattern formed by the cell pattern C and the cell pattern D. FIG. 7 is a schematic diagram of how a convex lens array looks when it is superimposed on an image pattern formed by a cell pattern C and a cell pattern D. It is the figure which planarly viewed the 2nd form of the information recording body of this invention. It is sectional drawing of the 2nd form of the information recording body of this invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The present invention is not limited to the embodiments described below. In addition, the same members and the like are denoted by the same reference numerals, and the description thereof may be omitted.

FIG. 1 is a diagram showing an example of the thermal transfer medium of the present invention. The heat-sensitive transfer medium 1 is composed of one surface of a base film 2 on which a normal heat-transfer ink layer of three colors of cyan (C), magenta (M), and yellow (Y) is sequentially provided. A thermal transfer ink layer of functional ink A (P1) and functional ink B (P2) is provided. Here, the functional ink A contains a bright pigment A having a haze value of 1 or more and less than 3 when the functional thermal transfer ink layer A is formed, and the functional ink B when the functional thermal transfer ink layer B is formed. The bright pigment B having a haze value of 3 or more and less than 6 is included. Further, the functional thermal transfer ink layer A and the functional thermal transfer ink layer B exhibit the same interference color. In this way, all the thermal transfer ink layers are provided on the same substrate film, and a single ink ribbon can be obtained, which is easy to handle and does not complicate the configuration of the printer.

If necessary, a black (Bk) ink layer may be provided, and a release layer may be provided between the base film and the thermal transfer ink layer on the other surface of the base film, that is, the surface contacting the thermal head. Each coat layer may be provided. When used in the indirect thermal transfer system, an adhesive layer may be further provided for adhering to the information recording body at the time of retransfer. Providing a sensor mark for detecting the position of each ink layer is known and can be appropriately adopted.

As the bright pigment A used for the functional thermal transfer ink layer A, for example, synthetic mica (synthetic glass) coated with titanium oxide (TiO ₂ ) in a film thickness of 0.5 μm or more and 3 μm or less can be used. The haze value of the thermal transfer ink layer A is 1% or more and less than 3%. As the bright pigment B used in the functional thermal transfer ink layer B, natural mica coated with titanium oxide to a film thickness of 0.5 μm or more and 3 μm or less can be used, and the haze value of the functional thermal transfer ink layer B is 3% or more 6 It is less than %. In any case, iron oxide (FeO, Fe ₂ O ₃ ) or the like can be further coated on the outside of titanium oxide. Therefore, the color of the background of the portion to which the functional thermal transfer ink layer B is transferred is inferior in transparency to the color of the background of the portion to which the functional thermal transfer ink layer A is transferred, and a difference in appearance can be created. ..

As the pigment used in the cyan (C), magenta (M), and yellow (Y) ink layers, various known pigments can be used. Specific examples include phthalimide yellow, benzimidazolone orange, sulfoamide yellow, azo dyes such as benzimidazolone yellow, phthalocyanine pigments, diketopyrrolopyrrole, quinophthalone, isoindolinone, and diaminodianthraquinone. It is not limited to these.

As the base film 2, for example, a plastic sheet such as polyethylene terephthalate (PET), polypropylene (PP), polycarbonate (PC), polymethylmethacrylate (PMMA), polyethylene (PE) is preferably used. The thickness of the base film 2 is generally about 1 to 100 μm, but the thickness is preferably thin in order to improve transferability, and particularly preferably about 1 to 10 μm.

In the case of the thermal transfer recording system, there are a direct transfer recording system in which an image is directly transferred to an information recording medium and an indirect transfer recording system in which an image once transferred and recorded on an intermediate transfer medium is retransferred to the information recording medium. The thermal transfer medium 1 can be applied to either of them. FIG. 2 shows an example in which the thermal transfer medium 1 is used in an indirect thermal transfer printer.

The printer 100 is composed of a primary transfer section which is composed of a thermal head 101 and a platen roller 102 as a main member, and a secondary transfer section whose main members are a heat roller 107 and a conveyance roller 108. In the primary transfer portion, the thermal transfer medium 1 and the intermediate transfer medium 201 unwound from the unwinding rolls 103 and 105 pass between the thermal head 101 and the platen roller 102, respectively, and the thermal transfer medium 1 is transferred to the take-up roll 104. Then, the intermediate transfer medium 201 is conveyed to the secondary transfer portion.

As the intermediate transfer medium, a resin film such as polyethylene terephthalate can be used, and a release layer and an image receiving layer can be formed in this order and used as a laminate. Examples of the material for the image-receiving layer include thermoplastic resins such as a polypropylene resin, a polyethylene terephthalate resin, a polyacetal resin, and a polyester resin.

At the time of primary transfer, the thermal head 101 and the platen roller 102 are pressed against each other, and thermal transfer recording of each color is performed from the thermal transfer ink layer of each color of the thermal transfer medium 1 to the intermediate transfer medium 201 in a frame sequential manner according to image information. . The intermediate transfer medium 201 is reciprocally moved by the number of colors to be recorded (five colors in this example), and the color is superimposed on a predetermined portion. The order of color superposition is not particularly limited, but in the case of the thermal transfer medium 1 of FIG. 1, cyan (C), magenta (M), yellow (Y), functional ink A (P1), functional ink B ( P2), and so on.

After the completion of the primary transfer, the intermediate transfer medium 201 on which the predetermined image recording is performed is conveyed to the secondary transfer section. The intermediate transfer medium 201 is conveyed while being pressed and held between the heat roller 107 and the conveying roller 108 together with the recording medium 109 serving as an information recording body which is conveyed by a conveying mechanism (not shown), and is recorded at the primary transfer portion. The image is transferred to the recording medium 109 by heat and pressure, and the secondary transfer is completed. The intermediate transfer medium 201 after the secondary transfer is wound up by the winding roll 106 or rewound by a predetermined amount for the primary transfer of the next image.

An information recording medium of the present invention in which a pattern such as characters and images is formed as a display image by using the thermal transfer medium 1 and a functional ink containing a bright pigment will be described. FIG. 3 is a diagram showing a form example of a cell pattern A11 formed by thermally transferring the functional ink A from the thermal transfer medium 1 and a cell pattern B12 formed by thermally transferring the functional ink B. The cell pattern A11 and the cell pattern B12 are composed of one or a plurality of dots thermally transferred by a thermal head which is a recording head.

As described above, the functional ink A contains the bright pigment A, the functional thermal transfer ink layer A has a haze value of 1% or more and less than 3%, and the functional ink B contains the bright pigment B. The thermal transfer ink layer B has a haze value of 3% or more and less than 6% and exhibits the same interference color. FIG. 3 is a diagram viewed from the angle at which the interference color disappears, and different haze values give different appearances. The cell pattern A11 formed by thermally transferring the functional ink A of the functional thermal transfer ink layer A having a small haze value has higher transparency, and the functional ink B is thermally transferred from the functional thermal transfer ink layer B having a large haze value. The cell pattern B12 thus formed has poor transparency and looks more cloudy.

FIG. 4 shows an example in which the cell pattern A and the cell pattern B are combined and appropriately arranged to form a cell matrix. Similarly, it can be formed by thermal transfer from the thermal transfer medium 1. FIG. 4A shows the cell matrix 10 viewed from the angle at which the cell pattern A11 and the cell pattern B12 disappear the interference color. As shown in FIG. 3, the cell pattern A11 and the cell pattern B12 have different haze values and thus have different appearances. Therefore, here, the pattern (OK character) by the cell pattern B12 appears as a display image and appears. There is.

FIG. 4B shows the cell matrix 10 viewed from the angle at which the cell patterns A11 and B12 exhibit interference colors. Since both cell patterns exhibit the same interference color, the cell patterns A and B are almost uniform and can be seen on the surface 13 of the same color (for example, green), and the cell matrix 10 cannot see a specific pattern.

FIG. 5 shows an example of an image pattern actually provided on an information recording body such as a card. In the image pattern 20, a cell matrix in which a cell pattern A11 and a cell pattern B12 similar to the cell matrix 10 are combined is formed in the central portion, and a normal image 21 surrounds the periphery. The normal method of forming the image 21 may be, in addition to normal printing, an optical element such as a hologram, or normal pearl printing, and is not particularly limited. From the thermal transfer medium 1, cyan (C), magenta (M), You may transfer and form the normal thermal transfer ink of three colors of yellow (Y).

FIG. 5A shows the image pattern 20 viewed from an angle at which the cell pattern A11 and the cell pattern B12 do not exhibit interference colors. In the center portion, as in the cell matrix 10 of FIG. The characters are visible as a display image.

FIG. 5B shows the image pattern 20 viewed from the angle at which the cell pattern A11 and the cell pattern B12 exhibit interference colors, and the central portion has substantially the same color as the cell matrix 10 of FIG. 4B. A specific display image cannot be seen in the image pattern 20 while the image is visible on the (for example, green) surface 13.

FIG. 6 shows an example in which the same material as the image pattern 20 is provided as an image forming portion on the surface of the information recording body by using the thermal transfer medium 1. The information recording body 30 is a card-shaped medium, on the surface of which a second image forming portion 32 including normal characters and a face photograph is formed, and on another portion, a first image forming portion equivalent to the image pattern 20. 31 is formed. In the first image forming unit 31, as described above, when a predetermined display image appears to stand out depending on the viewing angle (FIG. 6A) and when a substantially uniform interference color is seen (FIG. 6B). However, it becomes a mode in which it looks switched. The second image forming section 32 may be formed by a method such as ordinary printing, but the ordinary thermal transfer inks of three colors of cyan (C), magenta (M) and yellow (Y) of the thermal transfer medium 1 are used. Can also be formed by transfer.

FIG. 7 shows a cross section of the information recording body 30 of FIG. The information recording body 30 has a second image forming portion 32 and a first image forming portion 31 formed on a base material 35 with an adhesive layer 34 interposed therebetween. In the first image forming unit 31, the cell pattern A11 and the cell pattern B12 are appropriately arranged so that a predetermined display image can be displayed. Also, the overlay 33 is formed as a protective layer. Here, the information recording medium 30 is an example recorded by the indirect thermal transfer recording system, and the overlay 33 is a medium on which the image receiving layer of the intermediate transfer medium is transferred.

In the second image forming unit 32, here, dots 36 formed by transferring the normal thermal transfer inks of three colors of cyan (C), magenta (M), and yellow (Y) of the thermal transfer medium 1 are formed. Has been done.

The material of the base material 35 is not particularly limited, but for example, paper such as natural paper and synthetic paper, polyethylene terephthalate resin (PET), polyvinyl chloride resin (PVC), thermosetting polyester resin, polycarbonate resin, It may be a synthetic resin such as polymethacryl resin and polystyrene resin, glass, ceramics such as pottery and porcelain, or a metal material such as a single metal and an alloy.

As a result, the information recording body 30 has a characteristic that the pearly luster which is an interference color due to the glittering pigment and the display image with a pattern that emerges due to a unique difference in appearance due to the difference in haze value are switched depending on the viewing angle. Since it has a display effect, the effect of preventing forgery and forgery is enhanced, and the recording material can be improved in security. Moreover, an image forming portion having such a unique effect can be formed by thermal transfer recording from one thermal transfer medium, and can be efficiently formed. Further, it is possible to record different information for each information recording medium, and it is possible to provide a forgery prevention medium having a higher forgery prevention effect.

FIG. 8 shows a second example of the cell pattern formed by thermally transferring the functional ink from the thermal transfer medium 1. The core dot α411 formed of the functional ink A and the core dot α411 adjacent to the core dot α411 are formed. , A cell pattern C41 having the same area as the core dot α411 and composed of peripheral dots β412 formed of the functional ink B, a core dot β421 formed of the functional ink B, and a core dot β421 adjacent to the core dot β421. The cell patterns D42 are shown, each of which is composed of a peripheral dot β422 formed of the functional ink A having the same area as the dot β421. Note that, here, the aspect is shown from the angle at which the interference color disappears, but when viewed from the angle at which the interference color is exhibited, the core dot and the peripheral dot show the same interference color (for example, green). Therefore, both the cell pattern C41 and the cell pattern D42 look almost uniform in color.

FIG. 9 shows an example of a cell matrix in which the cell pattern C41 and the cell pattern D42 are combined and arranged at equal pitches to form letters, numbers, symbols and the like. In the cell matrix 50 of FIG. 9, the cell pattern C41 is "ground", and the character pattern "123" is formed by the cell pattern D42. In addition, here, a mode is shown as viewed from the angle at which the interference color disappears.

In FIG. 9, the cell matrix 50 is shown in a large size for the sake of easy understanding, but when the areas of the cell pattern C and the cell pattern D are sufficiently small, the difference in the appearance due to the difference in the haze value is discriminated by normal visual inspection. This is impossible, and it is difficult to distinguish the core dot from the peripheral dot. Further, since the core dot α411 and the peripheral dot β412, and the core dot β421 and the peripheral dot β422 have the same area, the cell pattern C and the cell pattern D cannot be distinguished. As a result, the character pattern of "123" becomes a latent image by normal visual observation, and the cell matrix 50 portion appears to have a substantially uniform color. Here, the area being sufficiently small means that the length of one side is 0.25 to 1 mm or less.

To make the cell matrix 50 of FIG. 9 visible, a fly-eye convex lens array 60 as shown in FIG. 10 is used. As can be seen from the sectional view taken along the line YY′ shown in FIG. 10B, the convex lens array 60 is one in which the convex lenses 61 are two-dimensionally arranged at equal pitches on the transparent substrate portion 62, and the pitch is It is the same as the pitch of the cell matrix 50. When this convex lens array 60 is overlapped with the image pattern 70 in which the cell matrix 50 is formed in the central portion of the image pattern similar to the image pattern 20 exemplified in the above-described embodiment, the cell pattern D42 is formed as shown in FIG. The core dot β formed by the functional ink B can be seen, and the core dot α formed by the functional ink A can be made visible in the cell pattern C portion, which is a latent image by normal visual inspection. The character pattern "123" can be visually recognized.

This is a case where the focus of the convex lens 61 is aligned with the nuclear dot α411 formed with the functional ink A and the nuclear dot β421 formed with the functional ink B, as schematically shown in FIG. Only the portions of the nuclear dots α411 and the nuclear dots β421 are enlarged by the convex lens 61, and the portions of the peripheral dots α412 and the peripheral dots β422 become difficult to see, so that the portions having different haze values and different appearances are enlarged. The character pattern (“123” in this case) which has been a latent image can be visually recognized.

At this time, if the shape of the nucleus dot is easily enlarged, for example, if the shape is a square such as the nucleus dot α411 and the nucleus dot β421 shown in FIG. 8, the convex lens 61 can be easily focused when the convex lens array 60 is overlapped. The shape of the nucleus dot is not limited to a square shape, and may be any shape that facilitates focusing, such as a circle, an ellipse, or a polygon other than a square.

FIG. 13 shows an example in which the same material as the image pattern 70 is provided on the surface of the information recording body by using the thermal transfer medium 1 as an image forming portion. The information recording body 80 is a card-like medium, on the surface of which a second image forming portion 82 composed of ordinary characters and a face photograph is formed, and on another portion, a first image forming portion equivalent to the image pattern 70. 81 is formed. The first image forming unit 81 normally does not see a pattern or the like as shown in FIG. 13A, but by overlapping the convex lens array 60 as shown in FIG. 13B, a display image (here, “ 123”) appears in a floating manner. The second image forming portion 82 may be formed by a method such as normal printing, but the normal thermal transfer inks of three colors of cyan (C), magenta (M), and yellow (Y) of the thermal transfer medium 1 are used. Can also be formed by transfer.

FIG. 14 shows a cross section of the information recording medium 80 of FIG. 13(b) taken along the line ZZ'. The information recording body 80 has a second image forming portion 82 and a first image forming portion 81 formed on a base material 85 with an adhesive layer 84 interposed therebetween. In the first image forming unit 81, the cell pattern C41 and the cell pattern D42 are appropriately arranged so that a predetermined display image can be displayed. In addition, the overlay 83 is formed as a protective layer. Here, the information recording medium 80 is an example recorded by the indirect thermal transfer recording system, and the overlay 83 is a medium on which the image receiving layer of the intermediate transfer medium is transferred.

As a result, when the information recording body 80 is normally viewed, no special image or a display image such as a character is visible in the first image forming portion 81, but by overlapping the convex lens array 60, the functional thermal transfer ink layer is formed. It has a characteristic display effect that a display image formed by a difference in the appearance due to the difference in haze value appears, and a recording body with improved security against forgery and forgery can be obtained. .. Moreover, an image forming portion having such a unique effect can be formed by thermal transfer recording from one thermal transfer medium 1, and can be efficiently formed. Further, it is possible to record different information for each information recording medium, and it is possible to provide a forgery prevention medium having a higher forgery prevention effect.

As described above, according to the heat-sensitive transfer medium and the information recording medium of the present invention, a display image having a unique visual effect of a difference in appearance due to a difference in haze value of the functional heat-transfer ink layer containing a bright pigment. Can be formed with a fine cell pattern as a latent image pattern, and not only is it difficult to forge, but the latent image pattern is not visible in the normal state, and the latent image pattern itself is easily provided. It is also possible to reduce the trigger for inducing forgery or falsification, and to obtain a high anti-counterfeiting effect.

The present invention will be specifically described below with reference to specific examples.
<Example 1>
・Coating a base film with a functional ink A using a bright pigment in which synthetic mica is coated with titanium oxide (TiO ₂ ) and a functional ink B using a bright pigment in which natural mica is coated with titanium oxide. An indirect thermal transfer printer was used to combine the manufactured thermal transfer medium with a square cell pattern A and a cell pattern B each having a size of 1 mm on a PVC card, and an image pattern was formed so as to have a character shape of "OK".
-At this time, the film thickness of titanium oxide with which synthetic mica and natural mica were coated was made the same.
The haze value of the functional thermal transfer ink layer A was 2%, and the haze value of the functional thermal transfer ink layer B was 4%.
-When the PVC card was viewed from the normal direction, the character "OK" was visually recognized due to the difference in haze value.
When the PVC card was tilted so that the interference color was visible, the cell pattern A and the cell pattern B exhibited the same interference color, and the image pattern disappeared.
As described above, the image pattern capable of being recorded on demand as individual information by thermal transfer recording can be provided so as to be switchable between a latent image and a visible image.

<Comparative Example 1>
-Two kinds of transparent inks were applied to the part to which the functional ink was transferred in Example 1. A filler was added to one side of the transparent ink so that the haze value was different so that the haze value became 5.
-In the same manner as in Example 1, an image pattern having a character shape of "OK" was formed on the PVC card.
-When the PVC card was viewed from the normal direction, the character "OK" was visually recognized due to the difference in haze value.
-Even when the PVC card was tilted, the interference color was not visible because it was not a bright pigment, and a latent image could not be formed.

<Example 2>
Using the same thermal transfer medium as in Example 1, a square cell pattern C and a cell pattern D each having a size of 1 mm are combined on a PVC card by a printer of an indirect thermal transfer system, and an image pattern is formed so as to have a character shape of "OK". Formed.
-When the PVC card was viewed from the normal direction, the image pattern was not visible.
・When the PVC card was tilted so that the interference color could be seen, the interference color was seen almost uniformly.
When the 1 mm pitch convex lens arrays were overlapped, a difference in appearance occurred due to a difference in haze value, and the character "OK" was visually recognized.

<Comparative example 2>
-One kind of general-purpose pearl ink was applied to the part to which the functional ink was transferred in Example 1 to prepare it.
-Almost uniform interference color was seen when viewed from the angle at which interference color was exhibited.
-Even when the same convex lens array as in Example 2 was stacked, no image pattern appeared.

1... Thermal transfer medium 2... Base film 10... Cell matrix 11... Cell pattern A
12... Cell pattern B
13... Same-color surfaces 20, 70... Image pattern 21... Normal image 30, 80... Information recording body 31, 81... First image forming portion 32, 82... 2 image forming portions 33, 83... overlays 34, 84... adhesive layers 35, 85... base material 36... dots 41... cell pattern C
411... Nuclear dot α
412 ... peripheral dot β
42... Cell pattern D
421... Nuclear dot β
422... peripheral dot α
50... Cell matrix 60... Convex lens array 61... Convex lens 62... Transparent substrate 100... Printer

Claims (7)

One or more thermal transfer ink layers containing a dye and at least two functional thermal transfer ink layers consisting of a functional ink containing a bright pigment are provided on one surface of the support in a frame-sequential manner.
The functional thermal transfer ink layer has a functional thermal transfer ink layer A made of the functional ink A containing the bright pigment A and a functional thermal transfer ink layer B made of the functional ink B containing the bright pigment B. Then
The functional thermal transfer ink layer A and the functional thermal transfer ink layer B have the same interference color,
A thermal transfer medium, wherein the functional thermal transfer ink layer A and the functional thermal transfer ink layer B have different haze values. The haze value of the functional thermal transfer ink layer A is 1% or more and less than 3%, and the haze value of the functional thermal transfer ink layer B is 3% or more and less than 6%. Thermal transfer medium. On the substrate,
One or more thermal transfer ink layers containing a dye,
At least the functional thermal transfer ink layer A made of the functional ink A containing the bright pigment A and the functional thermal transfer ink layer B made of the functional ink B containing the bright pigment B are thermally transferred,
The functional thermal transfer ink layer A and the functional thermal transfer ink layer B have the same interference color, the functional thermal transfer ink layer A and the functional thermal transfer ink layer B have different haze values, and the overlay layer Is an information recording body in which
At least one image forming portion on which a predetermined display image is formed using the functional ink A and the functional ink B is provided, and the image forming portion has the functionality when viewed from a predetermined observation angle. An information recording medium characterized in that the same interference color exhibited by the thermal transfer ink layer A and the functional thermal transfer ink layer B is visible, and the interference color disappears when the observation angle is changed. The haze value of the functional thermal transfer ink layer A is 1% or more and less than 3%, and the haze value of the functional thermal transfer ink layer B is 3% or more and less than 6%. Information recording body. The image forming unit forms a predetermined display image using at least two types of cell patterns, that is, a cell pattern A formed of the functional ink A and a cell pattern B formed of the functional ink B. The information recording medium according to claim 3 or 4, wherein A cell pattern C formed by core dots α formed of the functional ink A, and peripheral dots β formed of the functional ink B adjacent to the core dots α and having the same area as the core dots α, ,
A cell pattern D formed by a core dot β formed of the functional ink B and a peripheral dot α formed of the functional ink A adjacent to the core dot β and having the same area as the core dot β. The information recording medium according to claim 3 or 4, wherein a predetermined display image is formed by using at least two types of cell patterns. The functional ink of the core dots α of the cell pattern C and the core dots β of the cell pattern D is obtained by stacking a convex lens array having the same pitch as the cell patterns are arranged on the information recording medium according to claim 6. A cell pattern display method characterized by displaying only the background color of.