JP2011212952A - Dye sublimation thermal transfer method and information leakage preventing system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a dye sublimation thermal transfer method for making reading of only transfer marks on a used dye sublimation thermal transfer ink ribbon difficult, and to provide an information leakage preventing system.SOLUTION: The dye sublimation thermal transfer method includes: (i) a step for preparing a body to be transferred for recording a two-dimensional pattern (A) to be recorded; (ii) a step for preparing a ribbon that is a dye sublimation thermal transfer ribbon, which has a base material, a non-transferrable reading preventing layer, and a sublimation-transferrable color-material layer, and that is provided with a color-material layer and a reading preventing layer having a disturbance pattern (B) containing elements similar to those of the two-dimensional pattern (A) recorded on the body to be transferred; (iii) a step for preparing information of the two-dimensional pattern (A) to be recorded on the body to be transferred; and (iv) a step for executing dye sublimation thermal transfer of the pattern (A) to the body to be transferred on the basis of the information of the two-dimensional pattern (A) by using the dye sublimation thermal transfer ribbon.

Description

  The present invention relates to a sublimation thermal transfer method and an information leakage prevention system.

2. Description of the Related Art Conventionally, thermal transfer recording media have been used in computers, facsimiles, ID photographs, and the like to output characters, figures, face photographs, and the like on a transfer medium such as plain paper or image receiving paper. In general, the thermal transfer recording medium includes a melt type thermal transfer sheet in which a transferable wax ink layer is provided on a base film such as a polyester film, and a sublimation type thermal transfer ribbon in which a dye ink layer such as cyan, magenta and yellow is provided on the base film.
In the melt-type thermal transfer system, heat is applied to the sheet from the base film side of the melt-type thermal transfer sheet by a thermal head, and the heated portion of the wax ink layer is transferred to the transfer target (melt-type thermal transfer), resulting in area gradation To transfer (output) characters and figures.
On the other hand, in the sublimation type thermal transfer method, heat is applied to the thermal transfer ribbon from the base film side by the thermal head, and each dye ink layer such as cyan, magenta and yellow is transferred to the transfer target in proportion to the heat of the thermal head (sublimation). Mold thermal transfer), and transfer (output) figures, face photos, etc. according to density gradation.

The melt-type thermal transfer method is suitable for transfer of applications that require high contrast such as characters because it outputs in area gradation.
On the other hand, the sublimation type thermal transfer system is suitable for transferring images such as face photographs and landscape photographs that require high color reproducibility because the sublimation type thermal transfer system outputs in accordance with the density gradation of each dye ink such as cyan, magenta and yellow.

  When characters and images are transferred to a transfer medium using the above thermal transfer recording medium, the characters and image portions of the wax ink layer and dye ink layer are transferred to the transfer medium. In the wax ink layer and the dye ink layer, a transfer mark from which the characters and image portions are missing remains. When creating confidential documents such as contract documents, patent application documents, and know-how documents, the contents of the confidential documents are recorded as transfer marks on the used thermal transfer recording media, so there is sufficient care for disposal. There was a problem of being required.

Patent Document 1 proposes a thermal transfer printer provided with a means for thermally transferring reverse data to a used ribbon for the purpose of a thermal transfer printer that can erase a residual inverted image on a used ink ribbon.
However, in order to adopt this method, it may be necessary to modify the ink ribbon transport method or the printing method, and the load on the existing system is heavy. For this reason, there has been a demand for a method that provides a high information leakage prevention effect with simpler means.

  On the other hand, in Patent Document 2, a thermal transfer sheet in which a heat-meltable ink layer is provided on one surface of a base film via a mat layer for the purpose of a thermal transfer sheet that does not cause leakage of secrets after use. Has been proposed to be provided in the same color layer as the ink layer and in a pattern.

  However, since the thermal transfer sheet described in Patent Document 2 is a heat-melting type, it is difficult to read white characters on a used thermal transfer sheet in printing with area gradation of characters or the like, but a sublimation thermal transfer ribbon In this case, the concentration of the dye layer (colored layer) must be sufficiently high, and personal information such as face photographs, figures and landscapes can be observed under the reflected light of fluorescent lamps and sunlight or under the transmitted light of these lights. There has been a problem that it is difficult to obtain sufficient readability such as the above.

JP-A-3-211077 JP 2009-012445 A

  The present invention has been made to solve the above problems, and an object thereof is to provide a sublimation thermal transfer method and an information leakage prevention system in which it is difficult to read a transfer trace of a used sublimation thermal transfer ink ribbon. .

  As a result of intensive studies by the present inventors, the face contour of a desired facial photograph recorded by sublimation thermal transfer, the similar shape, size, density gradation, etc. of eyes, nose, mouth, eyebrows, ears, hairstyle, etc. By performing transfer of the desired facial photograph using a sublimation type thermal transfer ribbon provided with a non-transferable read prevention layer having a disturbing pattern containing elements and a colorant layer (dye ink layer) having transferability, The used ribbon has a color material layer having a transfer mark of a facial photograph and a read prevention layer having a disturbing pattern including elements similar to the facial photograph, and the disturbing pattern is combined with the facial photograph as one pattern. Therefore, even under reflected or transmitted light, it is difficult to determine which part of the read pattern is the face photograph recorded on the transferred object. Rukoto becomes difficult, it found that the resulting effect of excellent information leakage prevention, thereby completing the present invention.

That is, the sublimation type thermal transfer method according to the present invention comprises (i) a step of preparing a transfer body for recording a two-dimensional density gradation pattern (A) recorded by sublimation type thermal transfer and visually recognized,
(Ii) a sublimation type thermal transfer ribbon having at least a base material, a read-preventing layer having non-transferability, and a color material layer having sublimation transferability,
A reading prevention layer having a two-dimensional density gradation disturbing pattern (B) containing elements similar to the two-dimensional density gradation pattern (A) to be recorded on the transferred material is provided on at least one surface side of the substrate,
A step of preparing a sublimation type thermal transfer ribbon in which the color material layer is provided on the surface of the substrate opposite to the surface on which the read prevention layer is provided or on the surface of the read prevention layer on the side opposite to the substrate. ,
(Iii) a step of preparing information of a two-dimensional density gradation pattern (A) to be recorded on the transfer object;
(Iv) A step of thermally transferring the two-dimensional density gradation pattern (A) by the sublimation method based on the information of the two-dimensional density gradation pattern (A) using the sublimation type thermal transfer ribbon on the transfer object. , Including.

  The non-transferable read prevention layer is a two-dimensional density scale including elements similar to the two-dimensional density gradation pattern (A) (hereinafter sometimes simply referred to as “two-dimensional pattern A”) recorded on the transfer medium. A sublimation thermal transfer ribbon (hereinafter sometimes simply referred to as “ribbon”) provided with the read prevention layer has a tonal disturbance pattern (B) (hereinafter sometimes simply referred to as “disturbance pattern B”). When the thermal transfer is performed by the sublimation type method, the read prevention layer remains on the ribbon even after the sublimation type thermal transfer, and the transfer trace of the two-dimensional pattern A and the disturbance pattern B are overlapped on the used ribbon. Since they are combined and read as one pattern, it is difficult to read only the transfer trace of the two-dimensional pattern A from the used ribbon.

  In the sublimation thermal transfer method according to the present invention, the two-dimensional density gradation pattern (A) includes a human face image having an elliptical minor axis a and an elliptical major axis b, and the two-dimensional density gradation disturbing pattern (B). A pseudo face contour ellipse having an elliptical minor axis a ′ and an elliptical major axis b ′, where a ′ is 0.5a to 1.5a, and b ′ is 0.5b to 1.5b. It is preferable from the point of view that the readability of the two-dimensional pattern A is improved.

  In the sublimation thermal transfer method according to the present invention, the aspect ratio b / a of the human face image and the aspect ratio b ′ / a ′ of the pseudo face contour ellipse are 1.2 to 2.0. This is preferable from the viewpoint of improving the readability of A.

In the sublimation thermal transfer method according to the present invention, when the maximum transmission density of the read prevention layer is D _1max and the transmission density of the color material layer is D ₂ , the D _1max is 0.8D _{2 to} 1.2D. ₂ is preferable from the viewpoint of improving the readability of the two-dimensional pattern A.
In the present invention, the transmission density means a value determined by trade name X-Rite 361T (measurement aperture diameter 1 mm) manufactured by Sakata Inx Engineering Co., Ltd.

  In the sublimation thermal transfer method according to the present invention, it is preferable that the pseudo face contour ellipse includes pseudo eyes having a diameter C of a / 15 to a / 5 from the viewpoint of improving the readability of the two-dimensional pattern A.

Sublimation thermal transfer method according to the present invention, the maximum value D _1max of transmission density of the read-preventing _layer, the pseudo face contour ellipse portion of the transmission density of D _fave, when the transmission density of the pseudo first portion was D _e The D _1max , D _fave and D _e preferably satisfy the following formulas (1) and (2) from the viewpoint of improving the _{readability of} the two-dimensional pattern A.
_{0.5D 1max} ≦ D _fave ≦ 0.9D _1max (1)
_{D e} <D _fave ··· formula (2)
Note that the transmission density _Dfave of the pseudo face contour ellipse part means the transmission density of a part other than the pseudo eyes in the pseudo face outline ellipse. The transmission density _De of the pseudo eye part means the transmission density of the pseudo eye part. The same applies to the information leakage prevention system described later.

Sublimation thermal transfer method according to the present invention, the D _e is greater than 0, and it is preferable from the viewpoint of enhancing the reading prevention of two-dimensional pattern A or less 0.2D _1max.

An information leakage prevention system according to the present invention comprises: (I) a transferred object for recording a two-dimensional density gradation pattern (A) recorded by sublimation thermal transfer and visually recognized;
(II) recording information synthesizing means having means for synthesizing information of the two-dimensional density gradation pattern (A) and means for thermally transferring information of the synthesized two-dimensional density gradation pattern (A) by a sublimation method;
(III) a sublimation type thermal transfer ribbon having at least a base material, a non-transferable read prevention layer and a color material layer having sublimation transferability,
The reading prevention layer has a two-dimensional density gradation disturbing pattern (B) including elements similar to the two-dimensional density gradation pattern (A) recorded on the transferred body,
At least one side of the base material has the read prevention layer,
It has the color material layer on one side of the base material, on the side opposite to the side having the read prevention layer of the base material, or on the side opposite to the base material of the read prevention layer. It is characterized by.

  Similar to the above-described sublimation type thermal transfer method, by using a sublimation type thermal transfer ribbon provided with a read prevention layer having a disturbance pattern B, the used ribbon after recording using the above system is a two-dimensional pattern A. It is difficult to read only the transfer trace of the information leakage prevention system, and the information leakage prevention system according to the present invention has an excellent information leakage prevention function.

  In the information leakage prevention system according to the present invention, the two-dimensional density gradation pattern (A) includes a human face image having an elliptical minor axis a and an elliptical major axis b, and the two-dimensional density gradation disturbing pattern (B) A pseudo face contour ellipse having an elliptical minor axis a ′ and an elliptical major axis b ′, where a ′ is 0.5a to 1.5a, and b ′ is 0.5b to 1.5b. It is preferable that it is included from the viewpoint of improving the readability of the two-dimensional pattern A.

  In the information leakage prevention system according to the present invention, the aspect ratio b / a of the person's face image and the aspect ratio b ′ / a ′ of the pseudo face contour ellipse are 1.2 to 2.0. This is preferable from the viewpoint of improving the readability of A.

In the information leakage prevention system according to the present invention, when the maximum transmission density of the reading prevention layer is D _1max and the transmission density of the color material layer is D ₂ , the D _1max is 0.8D _{2 to} 1.2D. ₂ is preferable from the viewpoint of improving the readability of the two-dimensional pattern A.

  In the information leakage prevention system according to the present invention, it is preferable that the false face contour ellipse includes a false eye having a diameter C of a / 15 to a / 5 from the viewpoint of improving the readability of the two-dimensional pattern A.

Information leakage prevention system according to the present invention, the maximum value D _1max of transmission density of the read-preventing _layer, the pseudo face contour ellipse portion of the transmission density of D _fave, when the transmission density of the pseudo first portion was D _e The D _1max , D _fave and D _e preferably satisfy the following formulas (1) and (2) from the viewpoint of improving the _{readability of} the two-dimensional pattern A.
_{0.5D 1max} ≦ D _fave ≦ 0.9D _1max (1)
_{D e} <D _fave ··· formula (2)

Information leakage prevention system according to the present invention, the D _e is greater than 0, and it is preferable from the viewpoint of enhancing the reading prevention of two-dimensional pattern A or less 0.2D _1max.

  In the sublimation type thermal transfer method and the information leakage prevention system according to the present invention, since there is a disturbance pattern B including an element similar to the two-dimensional pattern A recorded on the transfer object, a ribbon provided with the read prevention layer is used. When the thermal transfer is performed by the sublimation type method, the read prevention layer remains on the ribbon even after the sublimation type thermal transfer, and the transfer trace of the two-dimensional pattern A and the disturbance pattern B are overlapped on the used ribbon, and the two patterns are combined. Therefore, it is difficult to read only the transfer trace of the two-dimensional pattern A from the used ribbon.

FIG. 1 is a schematic view showing an example of a layer structure of a sublimation thermal transfer ribbon used in the sublimation thermal transfer method according to the present invention. FIG. 2 is a schematic view showing another example of the layer structure of the sublimation thermal transfer ribbon used in the sublimation thermal transfer method according to the present invention. FIG. 3 is a schematic diagram showing an example of a transfer trace after use of a conventional sublimation type thermal transfer ribbon without a reading prevention layer and an image of its transmission observation. FIG. 4 is a schematic diagram showing an example of a transfer trace after use of a sublimation thermal transfer ribbon having no density gradation and an image of transmission observation thereof. FIG. 5 is a schematic view showing an example of a transfer trace after use of the sublimation type thermal transfer ribbon according to the present invention and an image of its transmission observation. FIG. 6 shows an example of an image of transmission observation of a transfer trace after using a conventional sublimation type thermal transfer ribbon in which a color material layer capable of developing three colors of yellow, magenta or cyan after thermal transfer is formed surface-sequentially. It is the shown schematic diagram. FIG. 7 is a cross-sectional view schematically showing an example of a transfer trace after use of the conventional sublimation type thermal transfer ribbon of FIG. 6 and an image observed by transmission observation thereof. FIG. 8 shows a case where the sublimation type thermal transfer method of the present invention is performed using the sublimation type thermal transfer ribbon of the present invention in which color material layers capable of developing three colors of yellow, magenta, and cyan are formed in the surface order after the thermal transfer. It is the schematic diagram which showed an example of the image of permeation | transmission observation of the transfer trace after. FIG. 9 is a schematic diagram showing an example of transmission observation image of the sublimation thermal transfer ribbon used in Example 1. FIG. 10 is a schematic diagram showing an example of transmission observation image of the sublimation thermal transfer ribbon used in Example 2. FIG. 11 is a schematic diagram illustrating an example of transmission observation image of the sublimation thermal transfer ribbon used in Comparative Example 1.

  Hereinafter, a sublimation thermal transfer method according to the present invention will be described first, and then an information leakage prevention system according to the present invention will be described.

(Sublimation type thermal transfer method)
The sublimation type thermal transfer method according to the present invention comprises: (i) a step of preparing a transfer medium for recording a two-dimensional density gradation pattern (A) recorded by sublimation type thermal transfer and visually recognized;
(Ii) a sublimation type thermal transfer ribbon having at least a base material, a read-preventing layer having non-transferability, and a color material layer having sublimation transferability,
A reading prevention layer having a two-dimensional density gradation disturbing pattern (B) containing elements similar to the two-dimensional density gradation pattern (A) to be recorded on the transferred material is provided on at least one surface side of the substrate,
A step of preparing a sublimation type thermal transfer ribbon in which the color material layer is provided on the surface of the substrate opposite to the surface on which the read prevention layer is provided or on the surface of the read prevention layer on the side opposite to the substrate. ,
(Iii) a step of preparing information of a two-dimensional density gradation pattern (A) to be recorded on the transfer object;
(Iv) A step of thermally transferring the two-dimensional density gradation pattern (A) by the sublimation method based on the information of the two-dimensional density gradation pattern (A) using the sublimation type thermal transfer ribbon on the transfer object. , Including.

  Since the non-transferable read prevention layer has a disturbance pattern B including elements similar to the two-dimensional pattern A recorded on the transfer target, thermal transfer is performed by a sublimation method using a ribbon provided with the read prevention layer. Since the read prevention layer remains on the ribbon even after the sublimation thermal transfer, the transfer trace of the two-dimensional pattern A and the disturbance pattern B are overlapped on the used ribbon, and the two patterns are combined and read as one pattern. Thus, it is difficult to read only the transfer trace of the two-dimensional pattern A from the used ribbon.

The steps (i) to (iv) of the sublimation type thermal transfer method according to the present invention will be described.
In the steps (i) and (ii), a transfer target and a sublimation thermal transfer ribbon described later are prepared.
In the step (iii), information on the two-dimensional pattern A to be recorded on the transfer target is prepared. As will be described later, the information of the two-dimensional pattern A is information of a person's face, upper body, or whole body recorded in the case where an ID photo, an ID card, a credit card, and a driver's license are transferred. If the photo mount other than the ID photo is a transfer object, the landscape or figure may be information of the two-dimensional pattern A.
In the step (iv), a two-dimensional pattern A is thermally transferred by a sublimation type method based on information of the two-dimensional pattern A using a sublimation type thermal transfer ribbon as a transfer target. As the thermal transfer method, a conventionally known sublimation thermal transfer method described in JP 2008-132771 A can be used. Specifically, for example, the color material layer of the ribbon is superposed on the information recording surface of the base material and heated by a thermal head according to the information of the two-dimensional pattern A to sublimate the color material of the color material layer. (Transfer) to record the information of the two-dimensional pattern A on the substrate.

  Hereinafter, the transfer target and the sublimation thermal transfer ribbon used in the sublimation thermal transfer method according to the present invention will be described.

(Transfer material)
The transfer target is a base material that receives a color material sublimated from a color material layer of a sublimation thermal transfer ribbon, which will be described later, and displays a two-dimensional pattern A such as a face photograph or a figure.
The transfer target is not particularly limited, and, for example, an identification card, an ID card, a credit card, a driver's license, other cards, or a photo mount can be preferably used.
Examples of the material for the transfer target include paper such as synthetic paper (polyolefin-based, polystyrene-based, etc.), high-quality paper, and various plastics such as polyolefin, polystyrene, polycarbonate, polyethylene terephthalate, polyvinyl chloride or polymethacrylate. Sheets can be used. In addition, a white opaque sheet formed by adding a white pigment or a filler to these plastic sheets or a sheet having fine voids (microvoids) inside the substrate can be used, and is not particularly limited.

  In addition, when a sublimable color material capable of forming a chelate is used as a color material included in a color material layer of a sublimation type thermal transfer ribbon described later, a metal ion capable of forming a chelate with the sublimable color material is used for a transfer target. It is preferable that an image receiving layer containing the containing compound is provided. As such an image receiving layer, for example, an image receiving layer described in [0047] and [0048] of JP-A-2006-007507 may be used. Moreover, as a metal ion containing compound contained in an image receiving layer, the metal complex of [0048]-[0050] description of Unexamined-Japanese-Patent No. 2006-007507 is mentioned, for example.

(Two-dimensional density gradation pattern (A))
The two-dimensional pattern A is a two-dimensional pattern in which a sublimation color material of a color material layer, which will be described later, is transferred to a transfer medium by a sublimation thermal transfer method and is expressed by density gradation. When the transferred object is a photo card of ID photo, ID card, credit card or driver's license, the two-dimensional pattern A is usually the face, upper body or whole body of the person to be recorded on the transferred object. Includes a unique image of the person. When the transfer target is a photo mount other than the ID photo, the two-dimensional pattern A can be a landscape or a figure. In addition, even when the transfer object is a photo mount or ID card of the above ID photo, the two-dimensional pattern A is not related to a person such as a person's face or upper body, but also a landscape, background, figure, etc. May be included.

  When the two-dimensional pattern A is a person's face photograph, the face outline, skin, eyes, mouth, nose, ears, eyebrows, hairstyle, etc. are usually included as the elements, and these elements have different colors and colors depending on the type and part. The density is different and it is difficult to reproduce with the melt type thermal transfer method, but vivid color reproduction is possible with the sublimation type thermal transfer method, and the sublimation type thermal transfer method is suitable as a method for recording such a two-dimensional pattern A.

(Sublimation type thermal transfer ribbon)
The sublimation type thermal transfer ribbon used in the sublimation type thermal transfer method according to the present invention is a sublimation type thermal transfer ribbon having at least a base material, a read prevention layer having non-transferability and a color material layer having sublimation transferability,
A reading prevention layer having a two-dimensional density gradation disturbing pattern (B) containing elements similar to the two-dimensional density gradation pattern (A) to be recorded on the transferred material is provided on at least one surface side of the substrate,
The color material layer is provided on the surface of the substrate opposite to the surface on which the read prevention layer is provided, or on the surface of the read prevention layer opposite to the substrate.

FIG. 1 is a schematic view showing an example of a layer structure of a sublimation thermal transfer ribbon used in the sublimation thermal transfer method according to the present invention.
In FIG. 1, the sublimation thermal transfer ribbon 1 is provided with a read prevention layer 20 on one surface side of a base material 10, and a color material layer 30 is provided on a surface opposite to the surface having the read prevention layer 20 of the base material 10. It has been.
FIG. 2 is a schematic view showing another example of the layer structure of the sublimation thermal transfer ribbon used in the sublimation thermal transfer method according to the present invention.
In FIG. 2, the sublimation thermal transfer ribbon 1 is provided with a read prevention layer 20 on one surface side of the substrate 10, and the color material on the surface of the read prevention layer 20 opposite to the substrate 10, that is, on the read prevention layer 20. A layer 30 is provided.

  Hereinafter, the base material, the read prevention layer, and the color material layer, which are essential components of the sublimation thermal transfer ribbon, will be described.

(Base material)
The base material of the sublimation type thermal transfer ribbon is not particularly limited, and a conventionally known base material of a sublimation type thermal transfer recording medium can be used. Examples thereof include fine paper, polyethylene terephthalate (PET), polyethylene naphthalate, polyacrylate, polycarbonate, polyurethane, polyimide, and polyetherimide. Of these, a PET substrate is preferred.

  The thickness of the substrate is not particularly limited, and can be set to the thickness of a conventionally known thermal transfer recording medium. 5-100 micrometers is preferable from the point of the conveyance property in a printer.

(Read prevention layer)
The reading prevention layer has a non-transfer property and has a two-dimensional density gradation disturbance pattern (B) including elements similar to the two-dimensional density gradation pattern (A) recorded on the transfer target.
By having this read-preventing layer, in the used ribbon after the thermal transfer by the sublimation method using the ribbon, the transfer trace of the two-dimensional pattern A of the color material layer and the disturbance pattern B described later overlap. Since both patterns exist and are read as one pattern, it is difficult to read only the transfer trace of the two-dimensional pattern A from the used ribbon.

FIG. 3 is a view schematically showing an example of a transfer trace of a conventional sublimation type thermal transfer ribbon without a reading prevention layer and an image observed by observation of the transmission trace. 3 and FIGS. 4 and 5 to be described later, the transfer mark and the disturbance pattern B are shown in a square shape for the sake of simplicity of explanation.
FIG. 3A shows a cross-sectional view of a used sublimation type thermal transfer ribbon. There is no reading prevention layer, and there is a color material layer 30 directly on one side of the substrate 10, and the color material layer is transferred to the color material layer. The trace 40 remains.
FIG. 3B shows a plan view of an image observed by transmission observation of the ribbon of FIG. 3A and shows that the pattern 50 is observed.
3A and 3B, the transfer mark 40 and the observed pattern 50 are the same. With a conventional ribbon without a reading prevention layer, a transfer mark can be read by observing a used ribbon through transmission, and there is a risk of information leakage.

FIG. 4 is a diagram schematically illustrating an example of a transfer trace of a sublimation thermal transfer ribbon having a colored layer having no density gradation and an image observed by observation of the transmission trace.
FIG. 4A shows a cross-sectional view of a used sublimation thermal transfer ribbon, in which a colored layer 60 is provided between the color material layer 30 and the substrate 10, and the colored layer 60 has a concentration. There is no gradation, that is, a uniform density. The same transfer mark 40 as in FIG. 3A remains on the color material layer 30.
FIG. 4B shows a plan view of an image observed by the transmission observation of the ribbon of FIG. 4A, and shows that the pattern 50 is observed.
In FIGS. 4A and 4B, the transfer mark 40 and the observed pattern 50 have different transmission densities due to the presence of the colored layer 60, but the pattern shape is the same. When the ribbon without density gradation is observed through the used ribbon, the transfer mark can be read in the same manner as the ribbon in FIG. 3, and there is a risk of information leakage.

FIG. 5 is a diagram schematically showing an example of a transfer trace of a sublimation type thermal transfer ribbon having a read prevention layer of the present invention and an image observed by observation of its transmission.
FIG. 5A shows a cross-sectional view of a used sublimation thermal transfer ribbon, in which a read prevention layer 20 is provided between the color material layer 30 and the base material 10. The reading prevention layer has a disturbance pattern B70, and the same transfer mark 40 as that in FIG.
FIG. 5B shows a plan view of an image observed by the transmission observation of the ribbon of FIG. 5A and shows that the pattern 50 is observed.
In FIG. 5B, the transferred trace 40 and the observed pattern 50 have different shapes, and the portion where the transfer trace 40 and the disturbance pattern B70 overlap in the same film thickness direction is the portion where the transmission density is only the transfer trace 40. Is different. Thus, it is difficult to read only the transfer trace 40, that is, the two-dimensional pattern A recorded on the transfer target, from the transmission observation pattern after the use of the ribbon having the read prevention layer, and the sublimation type thermal transfer of the present invention. The ribbon has an excellent information leakage prevention effect.

The thickness of the reading prevention layer may be set as appropriate, and for example, 0.5 to 1.5 g / m ² is preferable from the viewpoint of transferability of the color material.
As the material for the read prevention layer, the same material as the color material layer can be used. Examples of the binder resin include polyester resin, vinyl chloride-vinyl acetate copolymer resin, polyvinyl acetal resin, polyvinyl butyral resin, and cellulose resin. And the like, and polyvinyl acetal resin, polyvinyl butyral resin, and cellulose resin are preferable.

The disturbance pattern B included in the reading prevention layer and including elements similar to the two-dimensional pattern A may be appropriately selected according to the two-dimensional pattern A.
For example, when the two-dimensional pattern A is a human face, the elements include the shape, size, density gradation, etc. of the face contour, skin, eyes, nose, mouth, eyebrows, ears, hair, etc. The disturbance pattern B may include at least one element among them. For example, a disturbance pattern B similar to the shape of the eyes included in the two-dimensional pattern A may be used, or the disturbance pattern B1 similar to the shape and size of the face contour included in the two-dimensional pattern A and the two-dimensional pattern A A disturbance pattern B2 having a shape similar to that of the hairstyle included in the pattern and a similar density gradation may be used together.

  When the two-dimensional pattern A includes a human face image and the face image has an elliptical minor axis a and an elliptical major axis b, the shape of the disturbance pattern B is not particularly limited and may be set as appropriate. a pseudo face contour ellipse having a ′ and an ellipse major axis b ′, where a ′ is 0.5a to 1.5a, and b ′ is 0.5b to 1.5b; The pattern A and the disturbance pattern B, that is, the contour of the face image and the pseudo-face contour ellipse are more similar, and it is preferable that only the transfer trace of the face image, that is, the two-dimensional pattern A is more difficult to read.

  Further, the aspect ratio b / a of the human face image, that is, the value of b ÷ a, and the aspect ratio b ′ / a ′ of the pseudo face contour ellipse, that is, the value of b ′ ÷ a ′ are 1.2 to 2.0. If it is, it becomes more difficult to read only the two-dimensional pattern A, which is preferable. At this time, the aspect ratio b / a of the human face image and the aspect ratio b ′ / a ′ of the pseudo face contour ellipse may be within the range of 1.2 to 2.0, or may be different. And it may be the same.

  In general, since the diameter of the human eye is about 1/10 of the face width, if at least one pseudo eye having a diameter C of a / 15 to a / 5 is included in the pseudo face contour ellipse, Disturbed by pseudo eyes similar to the size of the eyes, it becomes difficult to recognize the transfer trace of the face image, and it is easy for the viewer to feel uncomfortable when viewing the transfer trace, and only the two-dimensional pattern A can be read. It becomes more difficult and preferable. The read prevention layer preferably contains one or more pseudo eyes, and more preferably contains two or more pseudo eyes.

When the maximum value of the transmission density of the read-preventing layer and _{D 1max,} the transmission density of the color material layer and _{D 2,} when the _{D 1max} is 0.8D ₂ ~1.2D _2, and the transmission density of the read prevention layer The difference in the transmission density of the color material layer becomes small, and it becomes more difficult to read only the transfer trace (two-dimensional pattern A).
In addition, the transmission density means a value determined by trade name X-Rite 361T (measurement aperture diameter 1 mm) manufactured by Sakata Inx Engineering Co., Ltd.

When the maximum value of the transmission density of the reading prevention layer is D _1max , the transmission density of the pseudo face contour ellipse part is D _fave , and the transmission density of the pseudo eye part is D _e , the D _1max , D _fave and D _e are as follows: When the expressions (1) and (2) are satisfied, the density gradation of the two-dimensional pattern A of the face image is similar to the density gradation of the disturbance pattern B, and it becomes more difficult to read only the transfer trace (two-dimensional pattern A). preferable.
_{0.5D 1max} ≦ D _fave ≦ 0.9D _1max (1)
_{D e} <D _fave ··· formula (2)
Note that the transmission density _Dfave of the pseudo face contour ellipse part means the transmission density of a part other than the pseudo eyes in the pseudo face outline ellipse. The transmission density _De of the pseudo eye part means the transmission density of the pseudo eye part. The same applies to the information leakage prevention system described later.

Further, D _e is greater than zero, and if it is less 0.2D _1max, transmission density of the pseudo-th portion becomes closer to the transmission density of the eyes of the face image, and more the distinction between the eye and the pseudo-th face image It is difficult to read, and it is difficult to read only the two-dimensional pattern A, which is preferable.

(Color material layer)
The color material layer of the present invention has sublimation transfer properties and contains at least a color material and a binder component.
The color materials contained in the color material layer may be used singly or in combination of two or more.
The thickness of the color material layer may be appropriately adjusted and is not particularly limited, but is preferably 0.5 to 2.0 g / m ² .
Hereinafter, the color material and the binder component of the color material layer will be described in order.

(Color material)
The color material used for the heat sublimable color material layer is not particularly limited, and yellow, magenta, cyan, and the like used for heat transfer ribbons of a conventionally known sublimation type heat transfer method can be used. Examples of yellow color materials include hollon brilliant yellow 6GL, PTY-52, and Macrolex Yellow 6G. Examples of magenta color materials include MS Red G, Macrolex Red Violet R, Ceres Red HBSL, and Resolin Red F3BS. Examples of cyan color materials include Kayaset Blue 714, Waxoline Blue AP-FW, Holon Brilliant Blue SR, MS Blue 100, and the like.

Alternatively, a reaction type color material that develops a target color by reacting a compound in the color material layer with a compound in the layer (image receiving layer) that receives the compound on the transferred material side by thermal transfer may be used. good. As such a reaction type method, a sublimation colorant is used as a compound to be contained in a color material layer, a metal ion-containing compound is used as a compound to be contained in an image receiving layer, and these are reacted after heat transfer to be sublimable. Examples include a post-chelation method in which a target color is developed by forming a colorant-metal ion-containing compound complex. The color formed by the post-chelation method has an advantage that even if it is left for a long time at high temperature and high humidity, the colorant is not easily faded or smudged and has excellent light resistance.
Examples of such a sublimable colorant include cyan dyes such as naphthoquinone, anthraquinone and azomethine, and magenta such as anthraquinone, azo and azomethine described in JP-A-2006-007507. Yellow pigments such as pigments and methine pigments, azo pigments, quinophthalone pigments and antisothiazole pigments can be used. In addition, compounds represented by the general formula: X1-N = N-X2-G described in [0091] of JP-A-2006-007507 can also be preferably used. In this general formula, X1 represents a group of atoms necessary for completing an aromatic carbocyclic or heterocyclic ring in which at least one ring is composed of 5 to 7 atoms, and is bonded to an azo bond. At least one of the adjacent positions of the carbon atom is a carbon atom substituted with a nitrogen atom or a chelating group. X2 represents an aromatic heterocyclic ring or an aromatic carbocyclic ring in which at least one ring is composed of 5 to 7 atoms. G represents a chelating group.
When the color to be formed is a single color, any of the yellow dye, magenta dye and cyan dye may be used. Further, two or more of the above three types of dyes may be used in combination depending on the color tone to be formed. Furthermore, other sublimable coloring materials may be included.

(Binder component)
As the binder component for dissolving or dispersing the color material, a binder component of a color material layer of a conventionally known sublimation thermal transfer ribbon can be used. For example, ethyl cellulose, hydroxyethyl cellulose, hydroxypropyl cellulose, methyl cellulose, cellulose acetate, vinegar Examples thereof include cellulose derivatives such as cellulose butyrate, vinyl resins such as polyvinyl alcohol, polyvinyl acetate, polyvinyl butyral, polyvinyl acetal, polyvinyl pyrrolidone, and polyacrylamide, and polyesters. Among these, cellulose derivatives, polyvinyl acetals, and polyesters are preferable from the viewpoint of heat resistance and color material transferability.

  In addition to the above-mentioned color materials, the color material layer is added with known additives such as polyethylene wax fine particles conventionally used for providing printability and transferability, such as anti-blocking agents, lubricants and antistatic agents. be able to.

  A solvent may be used to dissolve or disperse the binder component, and known solvents can be used. For example, hydrocarbon solvents such as toluene and n-hexane, alcohol solvents such as methanol and isopropyl alcohol, ketone solvents such as acetone, methyl ethyl ketone and methyl isobutyl ketone, and ester solvents such as methyl acetate and ethylene glycol monoethyl acetate Examples of the solvent include ether solvents such as ethylene glycol monomethyl ether and ethylene glycol monoethyl ether.

In a preferred embodiment of the sublimation type thermal transfer method of the present invention, even when a color material layer capable of developing three colors of yellow, magenta, or cyan is formed in the surface sequence as the color material layer after thermal transfer, high reading is performed. Preventive properties can be demonstrated.
As such a form, three colors of yellow, magenta, and cyan may be formed in the order of frames. In general, a sublimation type thermal transfer ribbon has a color material layer that can develop three colors of yellow, magenta, and cyan after thermal transfer in a surface sequential manner. For example, when a facial photograph of a person is transferred, There is a possibility that the color material layers of the respective colors are overlapped and synthesized based on the position of the eyes, and the reproduction processing is performed. In contrast, since the sublimation thermal transfer ribbon of the present invention has the above-described read prevention layer, even if the color material layers of each color are superimposed and synthesized, the two-dimensional pattern A and the disturbance pattern B are combined to form one Since it is read as a pattern, it is difficult to read only the transfer trace of the two-dimensional pattern A from the used ribbon.
The surface sequence refers to a state in which color material layers capable of developing three colors of yellow, magenta, and cyan are sequentially formed after thermal transfer, and the order of arrangement of these three color material layers in one repeating unit. May be appropriately selected from among six ways.
The color material layer may include a black layer in addition to the color material layer.

FIG. 6 shows an example of an image of transmission observation of a transfer mark after using a conventional sublimation type thermal transfer ribbon in which color material layers capable of developing three colors of yellow, magenta, and cyan are formed in a surface sequence after thermal transfer. It is a schematic diagram.
A ribbon in which a color material layer 31 capable of developing yellow after thermal transfer, a color material layer 32 capable of developing magenta after thermal transfer, and a color material layer 33 capable of developing cyan after thermal transfer are formed in a surface sequential manner is thermally transferred. Image transfer marks 41 and 42 remain on the ribbon after transfer.
Although it may be difficult to read a face image with each of these colors alone, the transfer trace 43 can be read more clearly by superimposing these images on the basis of the transfer trace 41, which is an eye portion having a large transmission density difference from the color material layer. End up.

FIG. 7 is a cross-sectional view schematically showing an example of a transfer trace after use of the conventional sublimation type thermal transfer ribbon of FIG. 6 and an image observed by transmission observation thereof.
The color material layers 31 to 33 are superposed on the basis of the transfer mark 41.

FIG. 8 shows a case where the sublimation type thermal transfer method of the present invention was performed using the sublimation type thermal transfer ribbon of the present invention in which the color material layers capable of developing three colors of yellow, magenta, and cyan were formed in the surface order after the thermal transfer. It is the schematic diagram which showed an example of the image of the transmission observation of the subsequent transcription | transfer trace.
It is difficult to mix the disturbing pattern B70 and the transfer trace 41 and superimpose only the transfer trace 41, and the pattern 50 that can be read becomes complicated and unpleasant, and it is difficult to read only the transfer trace.

  When color material layers capable of developing three colors of yellow, magenta, and cyan are formed in the surface order after thermal transfer, the read prevention layer positioned in the film thickness direction of each color material layer has each color as shown in FIG. In this case, a common disturbance pattern B may be used, or a different disturbance pattern B corresponding to each color material layer may be used.

(Other layers)
The sublimation thermal transfer ribbon of the present invention may be provided with a conventionally known heat-resistant slipping layer as needed in addition to the reading preventing layer and the color material layer.
The heat-resistant slip layer is provided to prevent problems caused by thermal head heat during thermal transfer such as sticking and printing wrinkles. When providing a heat-resistant slip layer, the side opposite to the color material layer of the sublimation thermal transfer ribbon Provided on the surface. For example, in the case of FIG. 1, it is provided on the read prevention layer 20, and in the case of FIG. 2, it is provided on the surface of the substrate 10 opposite to the read prevention layer.

(Formation method of sublimation thermal transfer ribbon)
As a method for forming a sublimation type thermal transfer ribbon used in the present invention, a conventionally known method for forming a thermal transfer sheet or a thermal transfer recording medium can be used. For example, a base material is prepared, the read prevention layer or the color material layer is formed on one side of the base material, and then the color material layer or the read prevention layer is formed on the read prevention layer or the color material layer. A method is mentioned. These color material layer and reading prevention layer can be formed by a conventionally known forming method.
For example, in the formation of the color material layer, the composition is prepared using the color material and the binder component, which are essential components constituting the color material layer, and a solvent as necessary. The composition is prepared by, for example, dissolving or dispersing the coloring material and the binder component using a ball mill or a basket mill.
The composition thus obtained is applied to a substrate or a surface to be coated using a coating apparatus such as a gravure coater or a roll coater, and the colorant layer is formed by removing the solvent by drying.
The reading prevention layer and other layers may be formed in the same manner.

(Information leakage prevention system)
An information leakage prevention system according to the present invention comprises: (I) a transferred object for recording a two-dimensional density gradation pattern (A) recorded by sublimation thermal transfer and visually recognized;
(II) recording information synthesizing means having means for synthesizing information of the two-dimensional density gradation pattern (A) and means for thermally transferring information of the synthesized two-dimensional density gradation pattern (A) by a sublimation method;
(III) a sublimation type thermal transfer ribbon having at least a base material, a non-transferable read prevention layer and a color material layer having sublimation transferability,
The reading prevention layer has a two-dimensional density gradation disturbing pattern (B) including elements similar to the two-dimensional density gradation pattern (A) recorded on the transferred body,
At least one side of the base material has the read prevention layer,
It has the color material layer on one side of the base material, on the side opposite to the side having the read prevention layer of the base material, or on the side opposite to the base material of the read prevention layer. It is characterized by.

  Similar to the above-described sublimation type thermal transfer method, by using a sublimation type thermal transfer ribbon provided with a read prevention layer having a disturbance pattern B, the used ribbon after recording using the above system is a two-dimensional pattern A. Therefore, it is difficult to read only the transfer trace, and it has an excellent information leakage prevention function.

Since the two-dimensional density gradation pattern (A) (I) and the transfer target in (I) have been described in the sublimation type thermal transfer ribbon, description thereof is omitted here.
The means for synthesizing the information of the two-dimensional pattern A in (II) is, for example, a program used for digital printing (on-demand printing) for synthesizing and correcting a photo, and a CPU or computer for executing the program.
A means for thermally transferring the information of the synthesized two-dimensional density gradation pattern (A) by a sublimation type method is, for example, a sublimation type thermal transfer printer including a roller and a thermal head.
The recorded information synthesizing means having these is, for example, an ID photographic apparatus, or a multi-function machine having both a computer as the synthesizing means and a sublimation type thermal transfer printer (for example, Dainippon Printing Co., Ltd .: sublimation type printer, trade name) NL-2000).
Since the sublimation type thermal transfer ribbon (III) has been described in the sublimation type thermal transfer ribbon, description thereof is omitted here.
In the sublimation type thermal transfer ribbon, the pseudo face contour ellipse and the pseudo eye, the transmission density of the read prevention layer and the color material layer, and the formulas (1) and (2) which are satisfied are the same as those described in the sublimation type thermal transfer ribbon. is there.

(Sublimation type thermal transfer ribbon for ID photos)
As another example of the embodiment of the sublimation type thermal transfer ribbon used in the sublimation type thermal transfer method and information leakage prevention system according to the present invention, there is a sublimation type thermal transfer ribbon for ID photographs. The ID photo sublimation type thermal transfer ribbon is an ID photo sublimation type thermal transfer ribbon having at least a substrate, a read-preventing layer having non-transferability, and a color material layer having sublimation transfer property,
On at least one surface side of the substrate, it has a read prevention layer having a two-dimensional density gradation pattern (B ′),
The color material layer is provided on the one surface side of the substrate and on the surface opposite to the surface having the read prevention layer of the substrate or on the surface of the read prevention layer opposite to the substrate.
In addition, the ID photo here includes a photo for a driver's license, ID card, passport, credit card, etc., as well as a photo for identity verification, in addition to the ID photo including a general photo. It is a concept.

  This ID photo sublimation thermal transfer ribbon (hereinafter, sometimes simply referred to as “ID photo ribbon”) has a non-transferable read prevention layer having a two-dimensional pattern B ′. In the ID photo ribbon, the reading prevention layer remains on the ID photo ribbon after use, and the transfer trace of the used ID photo ribbon and the two-dimensional pattern B ′ are overlapped, and the transfer trace and the two-dimensional pattern B ′ are combined. Therefore, it is difficult to read only the transfer mark from the used ID photo ribbon, and an excellent information leakage prevention effect is obtained.

A face image of a person output to a general ID photo or ID card has an elliptical minor axis of 1.0 to 3.0 cm and an elliptical major axis of 1.5 to 5.0 cm, and an aspect ratio (elliptical major axis / elliptical minor axis). ) Is 1.2 to 2.0, the two-dimensional pattern B ′ has an elliptical minor axis of 1.0 to 3.0 cm and an elliptical major axis of 1.5 to 5.0 cm, The pseudo-contour face ellipse of the ID photo ribbon with an aspect ratio (ellipse major axis / elliptical minor axis) of 1.2 to 2.0 prevents reading of only the transfer mark from the used ID photo ribbon. It is preferable from the point of increasing.
Similarly, since the diameter of the eye included in the face image of a person output to a general ID photo or ID card is 1 to 5 mm, the two-dimensional pattern B ′ has a similar diameter of 1 to 5 mm. It is preferable to include a false eye that is 5 mm from the viewpoint of enhancing the readability of only the transfer mark from the used ID photograph ribbon.
Similarly, in the ID photo ribbon, the maximum value D _1max of the transmission density of the reading prevention layer, the transmission density D ₂ of the color material layer, the transmission density D _fave of the pseudo contour face ellipse of the ID photo ribbon, and the ID photo transmission density D _e pseudo first part of the use ribbon, satisfy the relationship mentioned in sublimation thermal transfer ribbon, from the viewpoint of enhancing the reading prevention of transcription only traces from used certification photograph ribbon.

  Hereinafter, the present invention will be described more specifically with reference to examples. These descriptions do not limit the present invention.

Example 1
A composition for a color material layer, a composition for a reading prevention layer, and a composition for a heat resistant slipping layer having the following compositions were prepared.
(Cyan color material layer composition)
・ C. I. Solvent Blue 63: 3.5 parts by mass-Polyvinyl acetal resin (trade name ESREC KS-5 manufactured by Sekisui Chemical Co., Ltd.): 3.5 parts by mass-Toluene: 46.5 parts by mass-Methyl ethyl ketone: 46.5 parts by mass Part (Composition for cyan read prevention layer)
-Kayaset Blue 714 (disperse dye): 3.5 parts by mass-Polyester resin (trade name Vironal MD-1500, solid content ratio of Toyobo Co., Ltd.): 3.5 parts by mass-Water: 46.5 parts by mass Isopropyl alcohol: 46.5 parts by mass (composition for heat resistant slipping layer)
Polyvinyl butyral resin (trade name S-REC BX-1 manufactured by Sekisui Chemical Co., Ltd.): 13.6 parts by mass Polyisocyanate curing agent (trade name Takenate D218 manufactured by Takeda Pharmaceutical Co., Ltd.): 0.6 mass Parts ・ Phosphate ester (trade name Prisurf A208S manufactured by Daiichi Kogyo Seiyaku Co., Ltd.): 0.8 parts by mass. Methyl ethyl ketone: 42.5 parts by mass. Toluene: 42.5 parts by mass.

As a substrate, a polyethylene terephthalate substrate having a thickness of 6 μm was prepared.
On one side of the substrate, the prepared composition for heat-resistant slip layer is applied with a gravure coater so that the thickness after drying is 1.0 g / m ² and dried at 100 ° C. A layer was formed.
Next, on the other surface side of the base material, the prepared composition for reading prevention layer is applied with a gravure coater using a printing plate having a pattern of disturbance pattern B, dried at 100 ° C., and disturbance pattern B is formed. An anti-reading layer was formed. The coating amount of the portion having D _1max after drying was 0.8 g / m ² .
Next, the color material layer composition prepared on the read prevention layer is applied with a gravure coater so that the thickness after drying is 1.0 g / m ² and dried at 100 ° C. The sublimation type thermal transfer ribbon was formed.
FIG. 9 shows an image observed by the transmitted light of the sublimation thermal transfer ribbon produced in Example 1.
Table 1 shows the dimensions of the disturbance pattern B.

(Printing method)
Printing was performed using a sublimation transfer printer (trade name SELPHY CP710) manufactured by Canon Inc. As the sublimation type thermal transfer ribbon, one in which the cyan sublimation type thermal transfer ribbon prepared as described above was attached to the cyan portion of the sublimation type thermal transfer ribbon for SELPHY CP710 was used. As the image receiving paper, the sublimation type thermal transfer image receiving paper for SELPHY CP710 was used.

(Evaluation of readability of used ribbon)
The cyan portion of the sublimation thermal transfer ribbon after the face image is printed using the sublimation thermal transfer ribbon with the cyan sublimation thermal transfer ribbon attached is visually observed using transmitted light from a fluorescent lamp to prevent reading. Was evaluated according to the following criteria. The evaluation results are shown in Table 1.
○: It is not possible to determine what image was printed. Δ: Although it was possible to determine that a face image was printed, it was not possible to determine what kind of person it was.
X: The printed face image can be discriminated, and what kind of person it is can be discriminated.

(Example 2)
In Example 1, a sublimation type thermal transfer ribbon was produced in the same manner as in Example 1 except that the disturbance pattern B of the read prevention layer was changed as shown in FIG. 10 with respect to the image observed by the transmitted light of the sublimation type thermal transfer ribbon. did.
In the same manner as in Example 1, the reading prevention property of the sublimation thermal transfer ribbon after the face image was printed was evaluated.
Table 1 also shows the dimensions of the disturbance pattern B of Example 2 and the evaluation results of readability.

(Comparative Example 1)
In Example 1, the reading prevention layer was replaced with a layer having no density gradation (that is, no disturbance pattern B), and the image observed by the transmitted light of the sublimation thermal transfer ribbon was changed to that shown in FIG. In the same manner as in Example 1, a sublimation thermal transfer ribbon was produced.
In the same manner as in Example 1, the reading prevention property of the sublimation thermal transfer ribbon after the face image was printed was evaluated.
Table 1 also shows the evaluation results of the readability of Comparative Example 1.

(Summary of results)
In Examples 1 and 2, it was impossible to determine what kind of person it was from the used ribbon with good readability.
However, in Comparative Example 1 using the ribbon without the disturbance pattern B, it was possible to determine what kind of person it was from the used ribbon.

DESCRIPTION OF SYMBOLS 1 Sublimation type thermal transfer ribbon 2 Used sublimation type thermal transfer ribbon 10 Base material 20 Reading prevention layer 30 Color material layer 31 Color material layer 32 capable of developing yellow after thermal transfer 32 Color material layer 33 capable of developing magenta after thermal transfer 33 Cyan after thermal transfer Color material layer 34 capable of developing the color material layer 40, 41, 42 superimposed trace 50 pattern 60 colored layer 70 without density gradation Two-dimensional density gradation disturbance pattern B

Claims (14)

(I) a step of preparing a transfer medium for recording a two-dimensional density gradation pattern (A) recorded by sublimation thermal transfer and visually recognized;
(Ii) a sublimation type thermal transfer ribbon having at least a base material, a read-preventing layer having non-transferability, and a color material layer having sublimation transferability,
A reading prevention layer having a two-dimensional density gradation disturbing pattern (B) containing elements similar to the two-dimensional density gradation pattern (A) to be recorded on the transferred material is provided on at least one surface side of the substrate,
A step of preparing a sublimation type thermal transfer ribbon in which the color material layer is provided on the surface of the substrate opposite to the surface on which the read prevention layer is provided or on the surface of the read prevention layer on the side opposite to the substrate. ,
(Iii) a step of preparing information of a two-dimensional density gradation pattern (A) to be recorded on the transfer object;
(Iv) A step of thermally transferring the two-dimensional density gradation pattern (A) by the sublimation method based on the information of the two-dimensional density gradation pattern (A) using the sublimation type thermal transfer ribbon on the transfer object. And a sublimation thermal transfer method.   The two-dimensional density gradation pattern (A) includes a human face image having an elliptical minor axis a and an elliptical major axis b, and the two-dimensional density gradation pattern (B) includes an elliptical minor axis a ′ and an elliptical major axis. A pseudo-face contour ellipse having b ', wherein a' is between 0.5a and 1.5a, and where b 'is between 0.5b and 1.5b, is included. 1. A sublimation thermal transfer method according to 1.   3. The sublimation thermal transfer according to claim 2, wherein an aspect ratio b / a of the face image of the person and an aspect ratio b ′ / a ′ of the pseudo face contour ellipse are 1.2 to 2.0. Method. Maximum value _{D 1max} of transmission density of the read-preventing layer, when the transmission density of the coloring material layer was _{D 2,} characterized in that the _{D 1max} is 0.8D ₂ ~1.2D _2, wherein Item 4. The sublimation thermal transfer method according to any one of Items 1 to 3.   The sublimation thermal transfer method according to any one of claims 2 to 4, wherein the pseudo face contour ellipse includes pseudo eyes having a diameter C of a / 15 to a / 5. When the maximum value of the transmission density of the reading prevention layer is D _1max , the transmission density of the pseudo face contour ellipse part is D _fave , and the transmission density of the pseudo eye part is D _e , the D _1max , D _fave and D _e Satisfies the following formulas (1) and (2), the sublimation type thermal transfer method according to claim 5.
_{0.5D 1max} ≦ D _fave ≦ 0.9D _1max (1)
_{D e} <D _fave ··· formula (2) Wherein _{D e} is greater than zero, _and wherein the at _{0.2D 1max} less, sublimation type thermal transfer method according to claim 6. (I) a transfer target for recording a two-dimensional density gradation pattern (A) recorded by sublimation thermal transfer and visually recognized;
(II) Recording information synthesizing means having means for synthesizing the information of the two-dimensional density gradation pattern (A) and means for thermally transferring the information of the synthesized two-dimensional density gradation pattern (A) by a sublimation method ,
(III) a sublimation type thermal transfer ribbon having at least a base material, a read-preventing layer having non-transferability, and a color material layer having sublimation transferability,
The reading prevention layer has a two-dimensional density gradation disturbing pattern (B) including elements similar to the two-dimensional density gradation pattern (A) recorded on the transferred body,
At least one side of the base material has the read prevention layer,
It has the color material layer on one side of the base material, on the side opposite to the side having the read prevention layer of the base material, or on the side opposite to the base material of the read prevention layer. An information leakage prevention system characterized by   The two-dimensional density gradation pattern (A) includes a human face image having an elliptical minor axis a and an elliptical major axis b, and the two-dimensional density gradation pattern (B) includes an elliptical minor axis a ′ and an elliptical major axis. A pseudo-face contour ellipse having b ', wherein a' is between 0.5a and 1.5a, and where b 'is between 0.5b and 1.5b, is included. 8. The information leakage prevention system according to 8.   The information leakage prevention according to claim 9, wherein an aspect ratio b / a of the face image of the person and an aspect ratio b '/ a' of the pseudo face contour ellipse are 1.2 to 2.0. system. Maximum value _{D 1max} of transmission density of the read-preventing layer, when the transmission density of the coloring material layer was _{D 2,} characterized in that the _{D 1max} is 0.8D ₂ ~1.2D _2, wherein Item 11. The information leakage prevention system according to any one of Items 8 to 10.   The information leakage prevention system according to any one of claims 9 to 11, wherein the pseudo face contour ellipse includes pseudo eyes having a diameter C of a / 15 to a / 5. When the maximum value of the transmission density of the reading prevention layer is D _1max , the transmission density of the pseudo face contour ellipse part is D _fave , and the transmission density of the pseudo eye part is D _e , the D _1max , D _fave and D _e Satisfies the following formulas (1) and (2), the information leakage prevention system according to claim 12.
_{0.5D 1max} ≦ D _fave ≦ 0.9D _1max (1)
_{D e} <D _fave ··· formula (2) Wherein _{D e} is greater than zero, and _to equal to or less than _{0.2D 1max,} information leakage prevention system according to claim 13.