JP2011152652A - Security printing method and security printer - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To form characters or patterns made of points or line shapes unresolvable in a photogravure orinting, as variable information on a ribbon to improve security by making it difficult to achieve confirmation by visual observation for forgery prevention in thermal transfer printing using an ink ribbon and a thermal head. <P>SOLUTION: Micro characters or the like difficult to be confirmed by visual observation are printed beforehand on an infrared absorbing ink ribbon by laser, or a black image formed using an ink ribbon not absorbing in an infrared region is made a base or concealed not to be discriminated in a visible region so as to provide further security, or an image is formed on a transfer film and then transferred onto a printed body together with an image receiving layer to form the image receiving layer on the printed image, thus preventing a falsification. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a thermal transfer printing method and apparatus using an ink ribbon and a thermal head used for image formation such as a facial photograph on a card or passport, and relates to a security printing method and a security printer for preventing forgery and alteration.

  For cards and passports, many anti-tampering technologies are included for their intended use. In a thermal transfer printing apparatus, an image is formed by thermal transfer to an intermediate transfer medium rather than directly transferring and printing on the transfer target, and then the image formed on the intermediate transfer medium is heated and pressed to be transferred to the transfer target. Since the image is transferred and the transferred image is formed not over the surface but over the intermediate transfer medium, it is difficult to forge (Patent Document 1).

  In a printing method in which heat transfer is performed using a thermal transfer ribbon, the first print pattern data printed using the first special ink and the second print pattern data printed using the second special ink, Proposals have been made to discriminate using discriminating waves having different wavelengths after printing so that the portions overlap. Since printing is performed by a thermal head, fine printing cannot be performed. Moreover, since special ink is used, it is complicated and expensive (Patent Document 2).

  Fine information such as micro characters is used as a means for preventing counterfeiting and alteration of securities such as cards and passports, and is also considered as a forgery prevention method in thermal transfer printing.

  The ink ribbon is part coated with cyan, magenta, yellow, and black ink coatings in the longitudinal direction by gravure printing on the base film, and is used to print fine white letters. Although it is possible, the gravure version has poor resolution and has not yet been miniaturized to prevent counterfeiting. In the gravure printing method, since the printing plate is used, only fixed information is used and variable information cannot be printed.

JP 11-77959 A JP 2005-149417 A

  Print for thermal transfer printing using a thermal head and a ribbon with dot or line shape patterns and variable information characters that cannot be resolved with the conventional gravure method, which makes it difficult to visually check and improve security. A method and printer are provided.

  As a means for solving the above-mentioned problems, it is possible to print micro characters or the like that are difficult to visually confirm on the infrared absorbing ink ribbon in advance with a laser, or ink that does not absorb in the infrared region so that it cannot be distinguished in the visible region. By providing a black image formed using a ribbon as a base or concealing it, further providing security, or by forming an image on a transfer film and then transferring it together with an image receiving layer onto a printing medium The image receiving layer is formed on the printed image to prevent falsification.

  The invention according to claim 1 is a printing method in which a position based on image information is heated with respect to an ink ribbon in which ink is applied on a substrate, and image information is thermally transferred and printed. This is a quality printing method characterized in that an infrared laser is used for the ink of the ink ribbon, the ink is printed and evaporated in dots or lines, and then thermal transfer printing is performed.

  According to a second aspect of the present invention, a position based on image information is heated to an ink ribbon in which carbon ink and cyan, magenta, and yellow ink are part-coated on a base material, and the image information is thermally transferred. In the printing method for printing, before the thermal transfer printing, the carbon ink of the ink ribbon is ink-printed in dots or lines by using an infrared laser, and the carbon ink which is thermal transfer-printed in the subsequent thermal transfer printing process And a black portion composed of cyan, magenta and yellow inks and an image composed of cyan, magenta and yellow inks by thermal transfer printing so as to overlap the printing portion.

  According to a third aspect of the present invention, a position based on image information is heated on an ink ribbon in which carbon ink and cyan, magenta, and yellow ink are part-coated on a substrate, and the image information is subjected to thermal transfer printing. In this printing method, before the thermal transfer printing, the ink is printed and evaporated in a dot or line shape using an infrared laser on the carbon ink portion of the ink ribbon, and in the subsequent thermal transfer printing process, cyan, magenta A thermal printing method characterized in that an image composed of yellow ink and a black portion composed of cyan, magenta and yellow ink are subjected to thermal transfer printing, and then the thermal printing is performed so that the printed portions of the black portion carbon ink overlap. is there.

  Further, the invention according to claim 4 is directed to a transfer film in which a thin film image-receiving layer is laminated by heating a position based on image information with respect to an ink ribbon having ink applied on a substrate. In a printing method in which image information is thermally transferred and printed, and then the image information is transferred to the transfer medium together with the image receiving layer by heat pressing with a heat roller, an infrared laser is applied to the ink ribbon ink before the thermal transfer printing. Is used to print and evaporate ink in a dot or line shape, and then heat transfer printing is performed on the transfer medium together with the image receiving layer by thermal transfer printing to form an image.

  According to a fifth aspect of the present invention, there is provided a thin film-like film by heating a position based on image information to an ink ribbon in which carbon ink and cyan, magenta, and yellow ink are part-coated on a substrate. In a printing method in which thermal transfer printing is performed on a transfer film in which an image receiving layer is laminated and image information is transferred to the transfer medium together with the image receiving layer, before the thermal transfer printing, the carbon ink content of the ink ribbon is divided. A black part made of cyan, magenta, and yellow ink is used to print and evaporate the ink in a dot or line shape using an infrared laser and overlap the carbon print part of the transferred image in the subsequent thermal transfer printing process. , And images of cyan, magenta, and yellow inks are printed by thermal transfer, and then the thermal transfer image is placed on the transfer medium. And transferring by thermocompression bonding a Curie tee printing method characterized by forming an image.

According to a sixth aspect of the invention, a thin film is obtained by heating a position based on image information on an ink ribbon in which carbon ink and cyan, magenta, and yellow ink are part-coated on a substrate using a thermal head. In a printing method in which thermal transfer printing is performed on a transfer film on which a film-like image receiving layer is formed and then image information is transferred to the transfer medium together with the image receiving layer, before the thermal transfer printing, the carbon ink of the ink ribbon The ink is printed and evaporated in a dot or line shape using an infrared laser, and in the subsequent thermal transfer printing process, an image composed of cyan, magenta, yellow ink and a transferred image composed of cyan, magenta, yellow ink Heat transfer printing so that the black part of the paper overlaps the printed part of the carbon ink, and then on the transfer medium It was transferred by heat pressing a Curie tee printing method characterized by forming an image.

  In addition, the invention according to claim 7 includes a supply means for supplying an ink ribbon coated with ink on a substrate, an infrared laser for printing and evaporating ink in a dot or line shape on the ink portion, and image information. A thermal printer having a thermal transfer printing unit provided with a thermal head for performing thermal transfer printing by heating a base position.

  The invention according to claim 8 is characterized in that a carbon ink and a supply means for supplying an ink ribbon in which cyan, magenta, and yellow inks are part-coated on a substrate, and a carbon ink portion in a dot or line shape. Infrared laser for printing and evaporating the ink, heating the position based on the image information and forming the image made of carbon ink and black image made of cyan, magenta, yellow so as to overlap the image of carbon ink, and cyan, magenta, A thermal printer having a thermal transfer printing unit equipped with a thermal head for forming an image made of yellow ink.

  The invention according to claim 9 is characterized in that a carbon ink and a supply means for supplying an ink ribbon in which cyan, magenta and yellow inks are part-coated on a substrate, and a dot or linear shape on the carbon ink portion. Infrared laser for printing and evaporating ink in the shape, image formation consisting of cyan, magenta and yellow ink by heating the position based on image information, and the ink ribbon so as to overlap with black image consisting of cyan, magenta and yellow And a thermal transfer printing unit equipped with a thermal head for forming an image made of carbon ink.

  According to a tenth aspect of the present invention, there is provided a supply means for supplying an ink ribbon coated with an ink on a substrate, and an infrared laser for printing and evaporating the ink in a dot or line shape on the carbon ink of the ink ribbon. A thermal transfer printing means having a thermal head for performing thermal transfer printing by heating a position based on image information on a transfer film in which a thin film-like image receiving layer is laminated, a transfer film supplying means, and a thermal transfer image A security printer comprising: a heat roller that transfers an image onto a transfer medium together with a layer to form an image; and a transfer unit that includes a pressure-bonding table.

  The invention described in claim 11 is a supply means for supplying an ink ribbon coated with ink on a substrate, and an infrared laser for printing and evaporating the ink in a dot or line shape on the carbon ink of the ink ribbon. A thermal transfer printing means having a thermal head for performing thermal transfer printing by heating a position based on image information on a transfer film in which a thin film-like image receiving layer is laminated, a transfer film supplying means, and a thermal transfer image A security printer comprising: a heat roller that transfers an image onto a transfer medium together with a layer to form an image; and a transfer unit that includes a pressure-bonding table.

  The invention according to claim 12 is characterized in that a carbon ink and a supply means for supplying an ink ribbon in which cyan, magenta and yellow inks are part-coated on a substrate, and a carbon ink on the ink ribbon, Infrared laser that prints and evaporates ink in the shape of the shape, and image formation consisting of cyan, magenta, and yellow inks by heating the position based on the image information on the transfer film on which the thin film-like image receiving layer is laminated. , Heat transfer printing means with a thermal head that forms an image by heating carbon ink so as to overlap with a black image composed of magenta and yellow, transfer film supply means, and transfer the thermal transfer image together with the image receiving layer onto a transfer medium And a transfer means having a heat roller for forming an image and a compression table. A tee printer.

  The invention according to claim 13 is the security printer according to any one of claims 7 to 12, wherein the infrared laser is a YAG laser or a YVO4 laser.

  In the thermal transfer printing method using an ink ribbon and a thermal head, which is used for image formation such as facial photos to cards and passports that need to be counterfeited or tampered with, fine dots and lines that were impossible in the past, Printing information that gives security such as micro characters can be printed by using a laser beam, and the printing information can be concealed with cyan, magenta, and yellow inks. Further, since the printing information can be printed before the thermal transfer printing, it is possible to print the unique information for each medium. Therefore, it is possible to provide a security printing method and a security printer that can further improve security.

Schematic explaining an example of an embodiment of a security printing method and a security printer according to the present invention Schematic explaining an example of an embodiment of a security printing method and a security printer for transferring a thermal transfer image according to the present invention onto an object to be printed (5) together with an image receiving layer (17) and forming an image. Schematic illustrating an example of an embodiment of an ink ribbon (2) that is part-coated with carbon (13) and cyan (10), magenta (11), and yellow (12) inks according to the present invention. An example of an embodiment in which carbon ink in which a print evaporation portion (16) by an infrared laser (1) is formed on a black portion on which an image composed of cyan, magenta, and yellow ink according to the present invention is thermally transferred is printed. Schematic explained An embodiment in which a carbon ink (13) in which a print evaporation portion (16) is formed by an infrared laser (1) according to the present invention is subjected to thermal transfer printing, and a black portion of an image composed of cyan, magenta, and yellow inks is subjected to thermal transfer printing. Schematic explaining the example A print evaporation portion (1) is formed on the black portion obtained by thermal transfer printing an image made of cyan, magenta, and yellow ink on the transfer film on which the thin film image-receiving layer (17) according to the present invention is laminated. 16) Schematic illustrating an example of an embodiment in which carbon ink (13) formed is subjected to thermal transfer printing On the transfer film (4) on which the thin film-like image receiving layer (17) according to the present invention is laminated, carbon ink (13) having a print evaporation portion (16) formed by an infrared laser (1) is subjected to thermal transfer printing. Schematic illustrating an example of an embodiment in which a black portion of an image composed of cyan (10), magenta (11), and yellow (12) inks is subjected to thermal transfer printing. The conceptual diagram which showed the reflectance of visible region (14) of each ink of carbon ink, cyan, magenta, and yellow which concerns on this invention, and infrared region (15) The conceptual diagram which showed the absorption characteristic of the visible region (14) of a black part which consists of carbon ink which concerns on this invention, and cyan, magenta, and yellow ink, and an infrared region (15) Photograph in which micro characters having a line width of 30 μm and a character height of 250 μm are printed and evaporated on an ink ribbon (2) coated with the carbon ink (13) according to the present invention using an infrared laser (1). A character having a character height of 2500 μm is formed using an ink ribbon (2) coated with carbon ink (13) obtained by printing and evaporating micro characters having a line width of 30 μm and a character height of 250 μm using an infrared laser according to the present invention. Photo printed with thermal head (3)

A security printing method and a security printer according to the present invention will be described with reference to the drawings. FIG. 1 is a schematic diagram illustrating a security printing method and a security printer. An infrared laser (2) is applied to a roll-shaped ink ribbon (2) supplied from a take-up reel (8) and stored in a take-up reel (9). According to 1), a method and an apparatus for irradiating a fine pattern and evaporating the ink portion after printing and heating the position based on the image information by the thermal head (3) to thermally transfer and print the image information on the transfer object (5) Show.

  FIG. 2 shows that a roll-shaped ink ribbon (2) supplied from the take-up reel (8) and stored in the take-up reel (9) is irradiated with a fine pattern by an infrared laser (1), and the ink portion is printed and evaporated. After that, the position based on the image information is heated by the thermal head (3), the image information is subjected to thermal transfer printing on the transfer film (4) on which the image receiving layer (17) is formed, and the thermal transfer image is heated. (6) shows a method and an apparatus for transferring onto the transfer medium (7) together with the image receiving layer (17) by thermocompression bonding.

  The step of irradiating a point or line shape pattern or variable information with the infrared laser 1 and printing and evaporating the ink portion is performed immediately before the thermal transfer printing of the image information. It is easy to print the corresponding information, but it is also possible to print dot or line shape patterns and variable information when manufacturing the ink ribbon, and the ink ribbon can be secured.

  FIG. 3 shows an example of a roll-shaped ink ribbon (2), in which ink coating liquids of cyan (10), magenta (11), yellow (12), and black (13) are repeated in the surface direction in the longitudinal direction. Part coat.

  As the ribbon base material, a material having excellent heat resistance and strength that is not softened and deformed by heat pressure at the time of thermal transfer printing is used. Specifically, synthetic resin films made of polyethylene terephthalate, polyethylene naphthalate, polypropylene, cellophane, acetate, polycarbonate, polysulfone, polyimide, polyvinyl alcohol, aromatic polyamide, aramid, polystyrene, etc. are used alone or in combination. be able to.

  In thermal transfer printing, the thermal head (3) is often used as a heating means. However, a heat-resistant slip layer may be provided on the side opposite to the ink-coated surface so that the thermal head (3) is not fused. It also functions as an ink blocking prevention layer.

  The ink is supported by an arbitrary binder resin with pigments and dyes exhibiting the hues of cyan, magenta, yellow, and black, and the binder includes ethyl cellulose, hydroxyethyl cellulose, ethyl hydroxy cellulose, hydroxypropyl cellulose, methyl cellulose, Examples thereof include cellulose resins such as cellulose acetate, vinyl resins such as polyvinyl alcohol, polyvinyl acetate, polyvinyl butyral, polyvinyl pyrrolidone, and polyacrylamide, polyester resins, and styrene-unfavorable tolyl copolymer resins and phenoxy resins. Of these, polyvinyl acetal, polyvinyl butyral, styrene-acrylonitrile copolymer resin, and phenoxy resin are preferably used.

Conventionally known pigments and dyes can be used as the colorant. Examples of yellow dyes include azo dyes, disazo dyes, methine dyes, styryl dyes, and pyridone / azo dyes. Examples of magenta dyes include azo dyes, anthraquinone dyes, styryl dyes, and heterocyclic azo dyes. Examples of cyan dyes include indoaniline dyes, anthraquinone dyes, naphthoquinone dyes, heterocyclic azo dyes, and yellows include Kayaset Yellow AG, Kayaset Yellow TDN, PYT52, Plast Yellow 8040, and Holon Brilliant Yellow S6GLPI, etc., magenta (as Kayaset Red B, Kayaset Red 130, Celeste Red 7B, Macrolex Red Violet R, etc., as cyan, Kayaset Blue 714, Ceres Blue GN, MS Blue 50, etc. Examples thereof include carbon black.

  The color material and the binder resin are kneaded with an organic solvent to form an ink, and additives can be added as necessary.

  Conventionally known methods such as roll coating method, screen printing method, spraying method, etc. that are usually used for thin film formation can be used as the ink application method. For this, a forming method capable of different coating such as a gravure coating method and a slot coating method is suitable.

  As the infrared laser (8) for printing and evaporating the pigment ink in a point having a width of 40 μm or less or a linear shape, a gas laser, a semiconductor laser, a YAG laser or a YVO4 laser can be used. The semiconductor laser is 820 nm and the beam diameter is 200 μm. It can be narrowed down to the rank.

  With YAG laser or YVO4 laser, it is possible to narrow down to 1064 nm and a beam diameter of 10 μm or less, and printing of 10 μm is also possible. Infrared light having absorption in the carbon ink (13) can be used at wavelengths other than 1064 nm.

  In the method shown in FIG. 2, the thermal transfer image is transferred onto the transfer target medium (7) together with the image receiving layer (17) by thermocompression bonding with a heat roll (6), but the transfer film substrate and the image receiving layer (17) are transferred. If a release layer (18) is provided between them, transfer to the transfer medium (7) becomes easy.

  Examples of the binder resin used for the release layer (18) include butyral resin, polyester resin, acrylic resin, polyvinyl chloride resin, vinyl chloride-vinyl acetate copolymer resin, ethylene-vinyl acetate copolymer resin, polyamide resin, and styrene. 1 type or 2 or more types of mixtures from thermosetting resins, such as thermoplastic resins, such as styrene-butadiene copolymer resin, these crosslinked products, phenol resin melamine resin, unsaturated polyester resin, alkyd resin, polyimide resin, and epoxy resin Can be appropriately selected and used.

  The resin used for the image receiving layer (17) is preferably a thermoplastic resin having a Tg (glass transition temperature) of 50 to 120 ° C. in order to adhere to the transfer medium by heat from a thermal head or the like. When Tg is 50 ° C. or lower, the ink ribbon has poor storability and the strength and durability of the image after printing are weak, and image smearing tends to occur. Further, if the temperature is 120 ° C. or higher, printing cannot be performed under normal printing conditions, and the load on the thermal head (3) and the like is undesirably increased for printing. As such a binder resin, one or more kinds of polyester resin, acrylic resin, epoxy resin, polyvinyl chloride resin, vinyl chloride-vinyl acetate copolymer resin and the like can be used in combination. Further, titanium oxide, calcium carbonate, phthalocyanine blue, carbon black, bengara, oil red, aluminum powder, magnetic powder and the like can be appropriately added to the image receiving layer according to the function after transfer. As addition amount, 1 to 50% is desirable. Also, wax, polyethylene filler, Teflon (registered trademark) filler, zinc stearate or the like may be added in order to improve the abrasion resistance of the transferred image and the cutting at the time of printing.

  FIG. 4 shows a carbon ink (13) in which a print evaporation portion by an infrared laser (1) is formed on a black portion formed by thermal transfer printing so that images of cyan, magenta and yellow inks which are the three primary colors are superimposed. ) Is an example of an embodiment printed by thermal transfer.

Since the black image composed of cyan, magenta, and yellow ink is the background, the minute print evaporation portion (16) by the infrared laser (1) printed on the carbon ink (13) becomes more difficult to recognize.

  FIG. 5 shows a carbon ink (13) on which a print evaporation portion (16) is formed by an infrared laser (1) by thermal transfer printing, and a black portion composed of cyan, magenta, and yellow inks, which are three primary colors, is carbon. An example of an embodiment in which thermal transfer printing is performed so as to overlap with the printing part of FIG. 5 is shown, and the minute print evaporation part (16) by the infrared laser (1) printed on the carbon ink (13) cannot be further recognized.

  FIG. 6 shows a print evaporation portion by an infrared laser on a black portion obtained by thermal transfer printing an image composed of three primary colors of cyan, magenta, and yellow on a transfer film (4) on which an image receiving layer (17) is laminated. The carbon ink on which (16) is formed is subjected to thermal transfer printing.

  FIG. 7 shows a state in which the thermal transfer image on the transfer film (4) obtained in FIG. 6 is transferred to the transfer medium (7) together with the image receiving layer (17), and the image receiving layer is formed on the transferred ink image. (17) Since the release layer (18) is laminated, it contributes to prevention of scratches and tampering.

  FIG. 8 shows the reflectance of the carbon ink according to the invention, which is the three primary colors, and the visible region (14) and infrared region (15) of cyan, magenta, and yellow. The carbon ink is visible to infrared. There is no reflection up to the area, but in the visible area (14) made of cyan, magenta, and yellow ink, the reflection characteristics peculiar to each color are shown, but the infrared area (15) shows the same reflectance. I understand.

  FIG. 9 shows the absorption characteristics in the visible region (14) and the infrared region (15) of the black portion composed of the inks of the three primary colors of the color material, and cyan, magenta and yellow inks. Absorption extends from the visible to the infrared region. On the other hand, it can be seen that the black portion made of cyan, magenta, and yellow ink absorbs the visible region (14), but does not absorb the infrared region (15).

  FIG. 10 shows an ink ribbon (2) coated with carbon ink (13) irradiated with infrared light having a YVO4 laser of 1064 nm and a beam diameter of 10 μm to print and evaporate micro characters having a line width of 30 μm and a character height of 250 μm. It is a photograph and there is a printing evaporation part (16) from which the carbon ink (13) in the irradiation part has been removed.

  FIG. 11 shows a character printed with a height of 2500 μm using an ink ribbon on which a micro character is printed. The micro character consisting of the print evaporation section (16) is printed in the character, and the micro character is visually confirmed. Can not. The micro characters can be confirmed with a magnifying glass and can be used after authenticating.

  An image made of cyan, magenta, and yellow ink was concealed by thermal transfer printing on the image produced in Example 1. Micro characters could not be confirmed using a magnifying glass, but when confirmed in the infrared region using an infrared camera, the carbon ink portion was confirmed to be black and the micro characters were confirmed to be white. Confirmation in the infrared region using an infrared camera The color copy of this was reproduced in black, but the micro characters could not be reproduced even when viewed with the infrared camera, so it could be used for authenticity determination.

An image produced in the same manner as in Example 2 was subjected to thermal transfer printing on the transfer film (4) on which the image receiving layer was formed, and further transferred onto the printing medium (7) together with the image receiving layer (17). Micro characters could not be confirmed using a magnifying glass, but could be confirmed in the infrared region by using an infrared camera. Even if the color copy was viewed with an infrared camera, the micro characters could not be reproduced and it was determined that the copy was made. In addition, since the image receiving layer (17) was present on the surface and the ink was not exposed, the mechanical strength was improved, making forgery more difficult and improving the security.

DESCRIPTION OF SYMBOLS 1 ... Infrared laser 2 ... Ink ribbon 3 ... Thermal head 4 ... Transfer film 5 ... Transfer object 6 ... Heat roller 7 ... Transfer medium 8 ... Unwinding Reel 9 ... take-up reel 10 ... cyan ink 11 ... magenta ink 12 ... yellow ink 13 ... black ink (carbon ink)
14 ... Visible region 15 ... Infrared region 16 ... Print evaporating part 17 by infrared laser ... Image receiving layer 18 ... Release layer 19 ... Transfer film unwinding reel 20 ... Transfer film Take-up reel 21 ... Crimp stand

Claims (13)

  In a printing method in which a position based on image information is heated with respect to an ink ribbon on which ink is applied on a base material, and image information is subjected to thermal transfer printing, an infrared laser is applied to the ink ribbon ink before the thermal transfer printing. A quality printing method comprising: printing and evaporating ink in a dot or line shape, followed by thermal transfer printing.   In a printing method in which a position based on image information is heated with respect to an ink ribbon in which carbon ink and cyan, magenta, and yellow ink are part-coated on a substrate, the image information is thermally transferred and printed. In addition, using an infrared laser to the carbon ink of the ink ribbon, the ink is printed and evaporated in a dot or line shape, and cyan, magenta, so as to overlap with the printed portion of the carbon ink that has been thermal transfer printed in the subsequent thermal transfer printing process. A quality printing method comprising thermal transfer printing a black portion made of yellow ink and an image made of cyan, magenta, and yellow ink.   In a printing method for thermal transfer printing of image information by heating a position based on image information on an ink ribbon in which carbon ink and cyan, magenta, and yellow ink are part-coated on a substrate, before the thermal transfer printing , Using an infrared laser on the carbon ink portion of the ink ribbon, the ink is printed and evaporated in a dot or line shape, and in the subsequent thermal transfer printing process, an image composed of cyan, magenta, yellow ink, and cyan, A quality printing method comprising performing thermal transfer printing on a black portion composed of magenta and yellow inks, and then performing thermal transfer printing so that the printed portions of the black portion carbon ink overlap.   The position based on the image information is heated on the ink ribbon on which the ink is applied on the base material, and the image information is thermally transferred and printed on the transfer film on which the thin film-like image receiving layer is formed, and then the heat roller In a printing method for transferring image information together with the image receiving layer to a transfer medium by thermocompression bonding, before the thermal transfer printing, an ink is applied to the ink ribbon ink by using an infrared laser to form dots or lines. A quality printing method comprising: evaporating a print, and then heat-transfer-printing a thermal transfer image together with an image receiving layer on a transfer medium by thermal transfer printing to form an image.   The position based on the image information is heated on an ink ribbon in which carbon ink and cyan, magenta, and yellow ink are part-coated on the base material, and the thin film image-receiving layer is laminated on the transfer film. In a printing method for performing thermal transfer printing and then transferring image information together with the image receiving layer to a transfer medium, before the thermal transfer printing, an infrared laser is used for the carbon ink content of the ink ribbon, and a dot or line shape is obtained. The ink is printed and evaporated in the shape, and in the subsequent thermal transfer printing process, it consists of the black part composed of cyan, magenta, yellow ink and the cyan, magenta, yellow ink so that it overlaps the carbon printed part of the transferred image. Image transfer is performed by thermal transfer printing, and then the thermal transfer image is transferred onto the transfer medium by thermocompression bonding. Curie tee printing method comprising Rukoto. A transfer film in which a thin film-like image-receiving layer is laminated by heating a position based on image information on an ink ribbon in which carbon ink and cyan, magenta, and yellow ink are part-coated on a substrate using a thermal head In the printing method of performing thermal transfer printing on and then transferring image information together with the image receiving layer to a transfer medium, before the thermal transfer printing, using an infrared laser on the carbon ink of the ink ribbon, a dot or line shape Ink is printed and evaporated in the shape of the image, and in the subsequent thermal transfer printing process, the image of cyan, magenta, yellow ink and the black portion of the transfer image of cyan, magenta, yellow ink overlap with the printed portion of carbon ink. Print on the transfer medium, and then transfer it onto the transfer medium by thermocompression. Curie tee printing method characterized by.   Performs thermal transfer printing by heating the position based on image information and supply means for supplying an ink ribbon coated with ink on a substrate, an infrared laser for printing and evaporating ink in a dot or line shape on the ink portion A thermal printer comprising a thermal transfer printing unit equipped with a thermal head.   Supply means for supplying an ink ribbon that is part-coated with carbon ink and cyan, magenta, and yellow ink on the substrate, an infrared laser that prints and evaporates the ink in a dot or line shape on the carbon ink portion, and image information A thermal head that heats a position based on the image to form an image composed of carbon ink and a black image composed of cyan, magenta, yellow, and an image composed of cyan, magenta, yellow ink so as to overlap the carbon ink image A thermal printer, comprising: a thermal transfer printing means.   A supply means for supplying an ink ribbon in which carbon ink and cyan, magenta, and yellow ink are part-coated on a substrate; an infrared laser that prints and evaporates the ink in a dot or line shape on the carbon ink portion; A thermal head that heats a position based on image information to form an image composed of cyan, magenta, and yellow ink and an image composed of carbon ink of the ink ribbon so as to overlap with a black image composed of cyan, magenta, and yellow. A thermal printer, comprising: a thermal transfer printing means.   A supply means for supplying an ink ribbon coated with ink on a substrate, an infrared laser for printing and evaporating the ink in a dot or line shape on the carbon ink of the ink ribbon, and a thin film image-receiving layer are laminated. A thermal transfer printing unit having a thermal head for performing thermal transfer printing by heating a position based on image information on the transferred transfer film, a transfer film supplying unit, and a thermal transfer image transferred onto a transfer medium together with an image receiving layer. A security printer comprising: a heat roller to be formed; and transfer means having a pressure-bonding table.   Supply means for supplying an ink ribbon that is part-coated with carbon ink and cyan, magenta, and yellow ink on the base material, and an infrared laser that prints and evaporates the ink in a dot or line shape on the carbon ink of the ink ribbon And a black image composed of cyan, magenta and yellow so that the carbon ink image overlaps with the image formation composed of the carbon ink by heating the position based on the image information on the transfer film in which the thin film-like image receiving layer is laminated. And thermal transfer printing means equipped with a thermal head for forming an image made of cyan, magenta, and yellow ink, a transfer film supply means, and a heat roller for transferring the thermal transfer image onto the transfer medium together with the image receiving layer to form an image. Curing pudding characterized by having transfer means provided with a table .   Supply means for supplying an ink ribbon that is part-coated with carbon ink and cyan, magenta, and yellow ink on the base material, and an infrared laser that prints and evaporates the ink in a dot or line shape on the carbon ink of the ink ribbon Then, the position based on the image information is heated on the transfer film on which the thin film-like image receiving layer is laminated to overlap the image formation composed of cyan, magenta, yellow ink and the black image composed of cyan, magenta, yellow. In this way, a thermal transfer printing means equipped with a thermal head for forming an image by heating carbon ink, a supply means for a transfer film, a heat roller and a press stand for transferring a thermal transfer image onto a transfer medium together with an image receiving layer and forming an image. A security printer comprising a transfer means provided.   13. The security printer according to claim 7, wherein the infrared laser is a YAG laser or a YVO4 laser.