JPH0549477B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Technical Field of the Invention The present invention relates to a thermal transfer sheet, and more particularly to a thermal transfer sheet used in combination with a thermal transfer sheet in which thermal printing is performed according to image information using a thermal head or laser. Regarding a sheet and its manufacturing method.

Technical background of the invention and its problems Conventionally, thermosensitive coloring paper has been mainly used to obtain images according to image information using a thermal head or laser. In this heat-sensitive coloring paper, a colorless or light-colored leuco dye provided on a base paper and a color developer are brought into contact with each other by heating to obtain a colored image. As such color developers, phenolic compounds, zinc salicylate derivatives, rosin, etc. are generally used. However, heat-sensitive color paper as described above has the fatal drawback that the color image will fade if stored for a long period of time, and color printing is limited to two colors and has continuous gradation. It was not possible to obtain a color image.

On the other hand, thermal transfer paper in which a heat-fusible wax layer in which pigments are dispersed is provided on a base paper has recently begun to be used. When the thermal transfer paper and the transfer paper are placed one on top of the other and thermal printing is performed from the back side of the thermal transfer paper, the wax layer containing the pigment is transferred onto the transfer paper to obtain an image. According to this printing method,
Durable images can be obtained, and multicolor images can be obtained by printing multiple times using thermal transfer paper containing pigments in the three primary colors, but photographs with essentially continuous gradations cannot be used. It is not possible to obtain such an image.

Incidentally, in recent years, there has been an increasing demand for obtaining photograph-like images directly from electrical signals, and various attempts have been made. One such attempt is a CRT
This is a method of projecting an image onto a silver halide film, but if the silver halide film is an instant film, the running cost increases, and if the silver halide film is a 35mm film, has the disadvantage that it is not instantaneous because it requires development processing after photographing. As another method, an impact ribbon method or an inkjet method has been proposed, but the former has the disadvantage of poor image quality, and the latter requires image processing, making it difficult to easily obtain photographic images. It has the disadvantage of being ugly.

In order to solve these drawbacks, a thermal transfer sheet provided with a sublimable disperse dye layer that has the property of transferring when heated is used in combination with a thermal transfer sheet, and the sublimable disperse dye is transferred onto the thermal transfer sheet while controlling the sublimable disperse dye layer. A method has been proposed to obtain a photograph-like image with gradation by performing a transition. This method is attracting attention because an image having continuous gradation can be obtained from a television signal through simple processing, and the equipment used therein is not complicated. One of the conventional techniques similar to this method is the dry transfer printing method for polyester fibers, which involves dispersing or dissolving dyes such as sublimable disperse dyes in a synthetic resin solution. This paint is applied in a pattern onto thin paper, etc. and dried to form a thermal transfer sheet.The thermal transfer sheet is placed on polyester fibers, which are the heat transfer sheet, and heated in close contact to dye the polyester fibers with disperse dyes. This is a method to obtain an image.

However, when a thermal transfer sheet as described above and a thermal transfer sheet made of polyester fiber are overlapped,
Even if heat is applied to this using a thermal head or the like, a colored image with high density cannot be obtained. One of the reasons for this is that the surface smoothness of the polyester fiber cloth is not good, but it is believed that this is mainly due to the following reasons. In other words, in the normal dry transfer printing method or dry transfer printing method,
The migration of sublimable dyes onto polyester fiber fabrics is
This is because, while heating is carried out over a sufficient period of time, heating using a thermal head or the like is usually extremely short, and as a result, the dye does not transfer sufficiently onto the fiber cloth. By the way, in the dry transfer printing method, dye transfer is achieved by heating at 200°C for about 1 minute, whereas heating with a thermal head is as short as several milliseconds at 400°C.

For this reason, it has been proposed to use dyes with higher sublimability in thermal transfer sheets, and such dyes with higher sublimability include leuco dyes that are colorless or light-colored at room temperature. When these leuco dyes come into contact with acidic substances such as aromatic carboxylic acids, phenolic compounds, and organic sulfonic acids, they undergo lactone ring opening, spiropyran ring opening, or deacylation reactions, resulting in color development.

However, no matter how highly sublimable a dye is used in a thermal transfer sheet, it has not been possible to obtain a practical colored image. This is because even if a clear colored image is temporarily obtained, the image of this invention has extremely poor light resistance and lacks long-term storage stability. It is believed that such poor light resistance of colored images is mainly due to the colored images being oxidized by excited oxygen generated during light irradiation. Generally, methods for improving the light resistance of dyes and pigments by using a UV absorber in combination with dyes and pigments are well known to those who handle dyes and pigments.

However, when printing is performed using a combination of a thermal transfer sheet and a thermal transfer sheet, a sufficient effect cannot be observed simply by including an ultraviolet absorber or an oxygen promoter in the thermal transfer layer. As a result of examining the cause of this, we found that the reason why the effect was not sufficiently recognized was that the dye that migrates from the transfer sheet when heated transfers only to the surface layer of the thermal transfer sheet, so if it is not located at the top of the thermal transfer sheet, it will not be sufficient. It has been found that this is because the ultraviolet absorber, which cannot perform its function, is located at the bottom of the colored image.

As a result of further research based on these facts, the present inventors have found that the above-mentioned drawbacks can be solved at once by using a thermal transfer sheet having a specific configuration, and have completed the present invention. It came to this.

OBJECTIVES AND SUMMARY OF THE INVENTION The present invention aims to solve the drawbacks associated with the prior art, and provides a thermal transfer sheet having a thermal transfer layer containing a heat-transferable dye, and a thermal transfer sheet having a specific configuration. By using these in combination, we aim to achieve the following objectives.

(a) To provide a recording material from which a colored image with continuous gradation like a photograph can be directly obtained from an electrical signal.

(b) Recording materials that can produce highly transparent colored images with high density, excellent light resistance, and clear, high-resolution colored images that do not fade even after long storage periods. to provide.

In order to achieve the above objects, the heat transfer sheet after heat printing according to the present invention is characterized in that an ultraviolet absorber layer is provided on the developer layer on which the colored image is recorded. The ultraviolet absorber layer may be provided as a separate layer on the developer layer, or the ultraviolet absorber layer may be formed as an ultraviolet absorber layer by containing a high concentration of ultraviolet absorber on the top of the developer layer. .

The thermal transfer sheet in which the ultraviolet absorber layer is provided on the developer layer can be formed by the following method.

(a) An ultraviolet absorber layer containing an ultraviolet absorber is provided in advance as a protective layer on the developer layer of the thermal transfer sheet by a coating method such as a roll coating method, a gravure coating method, or a mirror coating method. A sheet to be thermally transferred is thereby formed. The ultraviolet absorber layer needs to be structured so that the dye that migrates from the thermal transfer sheet when heated can pass through it, and for this purpose, it is necessary to provide the ultraviolet absorber layer with a specific binder and a specific thickness. is necessary. By combining the heat transfer sheet and the heat transfer sheet, a color image is formed on the developer layer of the heat transfer sheet, and a color image is formed in the developer layer, and at the same time, an ultraviolet absorber is formed on the developer layer. A thermal transfer sheet provided with this is obtained.

(b) After combining a heat transfer sheet provided with a color developer layer and a heat transfer sheet having a heat transfer layer containing a heat transferable dye, and performing thermal printing to develop a colored image on the color developer layer. , an ultraviolet absorber layer containing an ultraviolet absorber is formed on the developer layer on which the colored image is recorded.

In order to form an ultraviolet absorber layer on the developer layer on which a colored image has been recorded, (a) an ultraviolet absorber having an ultraviolet absorber layer containing an ultraviolet absorber and a binder on the transfer base paper; A transfer sheet is prepared, the transfer sheet is placed on the developer layer, and an ultraviolet absorber layer is formed on the developer layer by heating or the like; A coating composition for an ultraviolet absorber layer containing an ultraviolet absorber and a binder is applied onto the coloring layer by a roll coating method.
The ultraviolet absorber layer may be formed on the developer layer by coating by a coating method such as a gravure coating method or a mirror coating method.

(c) When a heat transfer sheet provided with a color developer layer is combined with a heat transfer sheet having a heat transfer layer containing a heat transferable dye, and a colored image is recorded on the developer layer by heating printing. The ultraviolet absorber is also contained in the thermal transfer layer, and the ultraviolet absorber is thermally transferred to the developer layer along with the dye during heating, so that the ultraviolet absorber is on the top of the developer layer. It is also possible to form a layer of ultraviolet absorber containing a high concentration of ultraviolet absorber.Also, after recording a colored image on the developer layer,
By preparing an ultraviolet absorber transfer sheet containing an ultraviolet absorber, stacking the transfer sheet and a color developer layer and heating them to thermally transfer the ultraviolet absorber onto the developer layer, It is also possible to form an ultraviolet absorbing layer agent containing a high concentration of ultraviolet absorber on the top of the color developer layer.

DETAILED DESCRIPTION OF THE INVENTION Hereinafter, preferred specific examples of the present invention shown in the drawings will be described.

Thermal transfer sheet 1 after thermal printing according to the present invention
In this example, an ultraviolet absorber layer 4 containing an ultraviolet absorber is provided on a color developer layer 3 provided on a base material 2. The ultraviolet absorber layer 4 may be provided as a single layer separately from the color developer layer 3 as shown in FIG. Alternatively, as shown in FIG. 2, the surface of the developer layer 3 may be made into an ultraviolet absorber layer 4 by containing a high concentration of ultraviolet absorber in the uppermost part of the developer layer 3. In addition, in Figures 1 and 2,
5 is a colored image recorded in the color developer layer 3.

In some cases, the thermal transfer sheet may be constructed by providing the ultraviolet absorber layer 4 on the developer layer 3 without using the base material 2. When the color developer layer 3 is provided on the base material 2, the thickness of the color developer layer 3 is 3
The thickness is about 50 μm, preferably about 5 to 15 μm. on the other hand,
When a heat transfer sheet is prepared by providing an ultraviolet absorber layer on the color developer layer 3, the thickness of the color developer layer 3 is 60~60 mm.
It is about 200 μm, preferably about 90 to 150 μm.

In the following description, the thermal transfer sheet having the base material 2 will be mainly explained, but it goes without saying that these descriptions can also be applied to the thermal transfer sheet not having the base material 2.

The base material 2 is preferably one that has excellent smoothness and does not deform due to the heat and pressure applied during printing, and specifically, various synthetic papers,
Silver salt photographic paper, mirror coated paper, calendar coated paper, and various heat-resistant plastic films are used. Among these, synthetic paper and silver salt photographic paper are particularly preferred.

The binder resin that forms the color developer layer 3 has the ability to sufficiently retain the color developer, has good adhesion to the base layer 2, does not fuse with the thermal transfer sheet during thermal printing, and is also able to be used easily from the thermal transfer sheet. It is preferable to use a material that does not prevent the dye from migrating into the interior.
Specifically, polyester resins, modified EVA resins, acrylic resins, maleic anhydride resins,
Urethane resin, polyvinyl alcohol resin,
Vinyl acetate resin, EVA resin, styrene resin, styrene copolymer resin (for example, butadiene-styrene copolymer resin, acrylonitrile-styrene copolymer resin, acrylonitrile-butadiene-styrene copolymer resin, chlorinated polyethylene resin) acrylonitrile-styrene copolymer resin,
methyl methacrylate-butadiene-styrene copolymer resin, methyl methacrylate-styrene copolymer resin, etc.), rubber resin, silicone resin, cellulose resin, natural rosin resin, amino resin, nylon resin, polycarbonate resin, Ethylene-vinyl acetate-vinyl chloride copolymer resin, polymethylpentene resin, ionomer resin, acetal resin, phenol resin, epoxy resin, melamine resin, alkyd resin, etc. can be used.

Among the above-mentioned binders, from the viewpoint of color development, resins with a low glass transition temperature such as Tg of 40°C or less are preferable, and examples of such resins include polyester resins, knitted EVA resins, acrylic resins, and anhydrous resins. Examples include maleic acid resins, urethane resins, salt-vinyl acetate resins, and the like.

As described below, the color developer layer contains a color developer, but depending on the type of color developer, colored substances are likely to be formed during storage or heating. This coloring phenomenon is caused by using resins containing sulfonic acid residues, resins containing carboxylic acid residues, resins containing phosphoric acid residues, or resins with an acid value as the binder resin.
It can be effectively prevented by using more than 100 resins. Among these binder resins,
Particularly preferred are resins containing sulfonic acid residues.

The color developer layer 3 contains a color developer for coloring the dye transferred from the thermal transfer layer of the thermal transfer sheet. Such color developers include heteropolyacids or their salts, zinc salicylate derivatives, aromatic carboxylic acids, phenolic compounds,
Solid acids such as acid clay, organic sulfonic acids, organic phosphoric acids, and resins with high acid values are used.

Heteropolyacid refers to a polyacid formed by the condensation of inorganic acids that has two or more types of central atoms, and specifically includes phosphotungstic acid, phosphomolybdic acid, and phosphomolybdic acid. , phosphovanadic acid, silicon molybdic acid, and the like.

Further, as the heteropolyacid, ammonium salts, alkali metal salts, alkaline earth metal salts, amine salts, alkanolamine salts, etc. of the above-mentioned heteropolyacids can be used.

Although heteropolyacids tend to react with reducing substances to form colored substances, it has been found that color development can be inhibited by treating heteropolyacids with ammonium compounds or amine derivatives. Examples of ammonium compounds for treating heteropolyacids include ammonium hydroxide, ammonium salts such as ammonium hydrochloride, ammonium phosphate, and ammonium acetate, and examples of amine derivatives include primary aliphatic amines and secondary aliphatic amines. , tertiary aliphatic amines, aromatic amines, and salts of the above amines and organic or inorganic acids.

The heteropolyacid can be treated with the ammonium compound or amine derivative as described below.

When the ammonium compound or amine derivative is water-soluble and the binder resin is also water-soluble, the heteropolyacid, ammonium compound or amine derivative, and binder resin may be mixed in an aqueous solution.

In addition, if the ammonium compound or amine derivative is water-soluble and the binder resin is oil-soluble, first dissolve the heteropolyacid in a small amount of alcohol or ketone, and then add the resulting solution to the binder resin. Add to solution. Next, when an aqueous solution of an ammonium compound or an amine derivative is added to the obtained solution and mixed with stirring,
The reaction between the heteropolyacid and the ammonium compound or amine derivative proceeds at the interface, and when the mixture is left to stand, most of the heteropolyacid that has reacted with the ammonium compound or amine derivative is recovered in the binder resin solution.

In addition to these methods, a heteropolyacid may be reacted with an ammonium compound or an amine derivative using an ergelion.

The color developer is contained in the color developer layer in an amount of 1 of the total weight of the color developer layer.
It is used in amounts of ~95% by weight, preferably 20-60% by weight.

In order to provide the color developer layer 3 on the base material 2, a binder resin containing a color developer is applied to the base material by a known coating method such as a roll coating method, a gravure coating method, or a Miyabar coating method. You can apply it on top of 2.
The color developer layer 3 is provided on the base material 2 with a thickness of 0.1 μm to 1 mm, preferably 2 to 20 μm.

A method for forming a thermal transfer sheet in which an ultraviolet absorber layer is provided on a developer layer and a colored image is recorded in the developer layer will be described below.

First, a method for forming a thermal transfer sheet in which the ultraviolet absorber layer 4 shown in FIG. 1 is provided as a separate layer on the developer layer 3 will be described in detail. Such a thermal transfer sheet can be formed mainly by the following two methods.

(a) Before thermal printing, a color developer layer 3 is provided on the base material 2, and then a solution paint composition for the UV absorber layer containing an UV absorber is roll coated onto the developer layer 3. The ultraviolet absorber layer 4 is provided by coating according to a known coating method such as a coating method, a gravure coating method, a mirror coating method, etc., and a thermal transfer sheet 1a before thermal printing is formed (see FIG. 3).

The coating composition for the ultraviolet absorber layer is mainly composed of an ultraviolet absorber and a binder. As the ultraviolet absorber, benzophenone compounds, diphenyl acrylate compounds, benzotriazole compounds, etc. are used.

As the binder for the ultraviolet absorber layer, it is necessary to use a resin that allows the dye that migrates from the thermal transfer sheet to pass through when heated.
Moreover, it is desirable that the resin has properties such as mechanical strength, heat resistance, and solvent resistance, and it is particularly important to select a resin that does not fuse with the heat transfer sheet, especially when heated. It is also important to improve mechanical strength by improving releasability from the thermal transfer sheet or by crosslinking a portion of the resin. The present inventor has found that binder resins for forming a color developer layer are satisfactory in most respects as binder resins that meet these requirements. Tg is 40°C or less), and examples of such resins include polyester resins, modified EVA resins (for example, manufactured by Mitsui Polychemical Co., Ltd., trade name Elvaloy), urethane resins, salt-vinyl acetate resins, and maleic anhydride resins. resin,
Examples include acrylic resin. Alternatively, a resin with high gas permeability, such as a silicone resin, is preferable.

It is also important to control the thickness of the ultraviolet absorber layer 4 from the viewpoint of not blocking the passage of the dye transferred from the thermal transfer sheet, and this thickness depends on the type of binder resin used. Although it varies, it is generally desirable to have a thickness of about 0.1 to 100 μm, preferably 0.5 to 20 μm, particularly preferably 0.5 to 3.0 μm.

UV absorber is 10% of binder resin weight
Hereinafter, it is desirable to add it to the binder resin preferably in an amount of 0.5 to 5%.

A thermal transfer sheet having such a configuration,
A thermal transfer sheet having a thermal transfer layer containing a heat-transferable dye is stacked so that the ultraviolet absorber layer and the thermal transfer layer face each other, and the color developer of the thermal transfer sheet is heated using a heating means such as a thermal head. A colored image is recorded in the layer to obtain a thermal transfer sheet in which an ultraviolet absorber layer is provided on the developer layer and a colored image is recorded in the developer layer.

By providing the ultraviolet absorber layer 4 on the color developer layer 3, it is possible to obtain the effect of improving the long-term storage stability of the colored image, and surprisingly, the obtained colored image becomes clearer. It's also effective. The reason for this is not necessarily clear, but
This is thought to be because the ultraviolet absorber layer 4 has a function of preventing the dye migrating from the thermal transfer layer from being locally localized and developing color. In other words, it is speculated that when a large amount of dye migrates locally, secondary aggregation occurs between the dyes, making it difficult to express the dye's original color and causing a change in hue due to the state of association, resulting in a slight cloudiness. . This is presumed to be because the dye diffuses while passing through the ultraviolet absorbing layer, so the local concentration does not increase enough to cause secondary aggregation of the dye.

In addition to the above roles, the ultraviolet absorber layer 4 also serves as a protective layer for the thermal transfer sheet, and can impart water resistance and solvent resistance to the thermal transfer sheet.

(b) A thermal transfer sheet provided with a color developer layer is combined with a thermal transfer sheet having a heat transfer layer containing a heat transferable dye, and a colored image is recorded on the color developer layer using heating means such as a thermal head. After that, an ultraviolet absorber layer containing an ultraviolet absorber is formed on the developer layer on which the colored image has been recorded, so that the ultraviolet absorber layer is provided on the developer layer and the developer is A thermal transfer sheet having a colored image recorded in the layer is obtained.

The ultraviolet absorber layer can be formed, for example, in the following manner on the developer layer on which a colored image has been recorded.

(a) First, a UV absorber transfer sheet having a UV absorber transfer layer containing a UV absorber and a binder on a transfer base paper is prepared. Next, this ultraviolet absorber transfer sheet and a heat transfer sheet with a color image recorded on the developer layer are placed so that the ultraviolet absorber transfer layer of the ultraviolet absorber transfer sheet and the color developer layer of the heat transfer sheet face each other. The ultraviolet absorber layer is transferred onto the developer layer of the thermal transfer sheet by heating with a hot roll or a thermal head to form an ultraviolet absorber layer on the developer layer. The transfer method using a heated roll has the advantage that it is simple and can use ordinary thermoplastic as the transfer material, but it takes time to heat the roll and keeping it heated all the time is a waste of energy. Another drawback is that the heat generated can affect other parts. On the other hand, the transfer method using a thermal head has the advantage that the adverse effect on the resolution of the colored image can be ignored, although there are restrictions on the transfer materials that can be used. When transferring the ultraviolet absorber layer using a thermal head, the energy applied to the thermal head is:
It is about 0.5 to 3.0 mj/dot. Incidentally, as the transfer material, natural wax, synthetic wax, modified wax, or low melting point synthetic polymer substance can be used.

(b) A coating composition for an ultraviolet absorber layer containing an ultraviolet absorber and a binder is applied by roll coating or gravure coating on the developer layer of the heat transfer sheet on which a colored image is recorded. The ultraviolet absorber layer is formed on the developer layer by coating by a known coating method such as the Myabar coating method. Furthermore, the coating composition for the ultraviolet absorber layer can be applied onto the developer layer by a spray method, or a porous material such as a sponge may be impregnated with the coating composition and then applied onto the developer layer. It is also possible to apply it.

(c) An ultraviolet absorber layer can also be formed on the developer layer using an adhesive film.

According to such a method, in addition to improving the light fastness and long-term storage stability of the colored image obtained, there are the following advantages. First, according to the method described in (a), it is possible to provide a thermal transfer sheet and an ultraviolet absorber transfer sheet on the same base paper. That is, a thermal transfer layer containing a heat-transferable dye and an ultraviolet absorber transfer layer containing an ultraviolet absorber are partially provided for each screen size on the same transfer base paper, and these are combined with a thermal transfer sheet. By sequentially and repeatedly applying heat, it is possible to record a colored image on the developer layer of the thermal transfer sheet and form an ultraviolet absorber layer on the developer layer. At this time, there is no need to add any new auxiliary equipment to the heating device such as a thermal head, and there is an advantage that processing can be performed with the same printer.

Next, according to the methods described in (b) and (c), although it is necessary to coat each sample, the ultraviolet absorber layer can be formed on the developer layer simply and economically. Particularly suitable when the number of samples is small.

Next, a method for forming a thermal transfer sheet in which an ultraviolet absorber layer 4 is provided on the top of a developer layer 3 and a colored image is recorded in the developer layer as shown in FIG. 2 will be described. explain.

A heat transfer sheet provided with a color developer layer and a heat transfer sheet having a heat transfer layer containing a heat-transferable dye are superimposed so that the color developer layer and the heat transfer layer face each other, and heat is applied thereto. When recording a colored image on the developer layer, the heat transfer layer of the thermal transfer sheet contains a UV absorber along with a heat-transferable dye, and when heated, the UV absorber migrates onto the developer layer along with the dye. By letting
A UV absorber layer can be formed on top of the developer layer.

In addition, a heat transfer sheet on which a colored image is recorded on a developer layer and a UV absorber transfer sheet having a separately prepared UV absorber transfer layer containing a UV absorber on a transfer base paper are superimposed. Heat,
By thermally transferring the ultraviolet absorber onto the developer layer, it is also possible to form an ultraviolet absorber layer containing a high concentration of the ultraviolet absorber on the top of the developer layer.

In the developer layer of the thermal transfer sheet according to the present invention,
To improve the long-term shelf life of colored images, non-toxic or low-toxic metal deactivators can be added. Such metal deactivators include:
Examples include organotin stabilizers, specifically di-
Examples include n-octyltin stabilizers, di-n-butyltin stabilizers, dimethyltin stabilizers, malate stabilizers, mercaptide stabilizers, laurate stabilizers, and mixed stabilizers thereof.

Further, an excited oxygen scavenger may also be used in the developer layer for the same purpose, and specifically, dibutyldithiocarbamate metal salt, bisdithiobenzyl metal salt, etc. may be used. Additionally, known rubber or plastic anti-aging agents are also effective in improving the lightfastness of colored images. These metal deactivators, excited oxygen scavengers, anti-aging agents, etc. are used in an amount of 10% by weight or less based on the binder resin for the color developer layer.

Further, in order to prevent the developer layer from fusing with the thermal transfer paper during heating, it is preferable to add curable silicone or non-curable silicone to the developer layer. Note that fusion between the color developer layer and the thermal transfer sheet during heating can be prevented by crosslinking a portion or the entire surface of the binder resin. Crosslinking of the binder resin can be achieved by electron beam irradiation, peroxide addition, and the like.

The thermal transfer sheet as described above is used in combination with a thermal transfer sheet. A typical thermal transfer sheet 6 is constructed by providing a thermal transfer layer 8 on one side of a support 7, as shown in FIG.
When this thermal transfer layer 8 is heated, the dye contained therein is transferred onto the thermal transfer sheet.

The support 7 has the role of holding the thermal transfer layer 8, and since heat is applied during thermal transfer, it is desirable that the support 7 has a mechanical strength that does not cause any trouble in handling even in a heated state. Moreover, in many cases, thermal energy for thermal transfer is applied from the side of the support 7 on which the thermal transfer layer 8 is not provided, so it is desirable that the support 7 also has the property of easily transmitting thermal energy.

Specific examples of such support 7 include condenser paper, glassine paper, parchment paper, highly sized paper, and flexible thin sheets such as plastic film. Of these, condenser paper and polyethylene terephthalate film are often used.Condenser paper is mainly used when heat resistance is important, and polyethylene terephthalate film is used when emphasis is placed on preventing breakage when handled by mechanical devices. Mainly used. The thickness of this support 7 is usually 3 to 50 μm, preferably 5 to 15 μm.
That's about it.

The thermal transfer layer 8 contains a dye that can escape from the thermal transfer layer and transfer to the developer layer of the thermal transfer sheet when heated.

After transferring to the color developer layer of the thermal transfer sheet, such a dye comes into contact with the color developer contained in the color developer layer to develop a color.

The dyes mentioned above include the following types of compounds.

(b) Carbinol-based basic dyes such as the following: diarylmethane type, triarylmethane type, thiazole type, methine type, xanthene type,
Oxazine series, thiazine series, acridine series, azo series, etc.

(b) Leuco dyes Triphenylmethane/phthalide series, phenothiazine series, spirodipyran series, indolinospiropyran series, fluoran series, rhodamine lactam series, lyuco auramine series, etc.

(c) Cationic dye Anthraquinones, azamethines, etc.

The above dye is dispersed in a suitable synthetic resin binder forming a thermal transfer layer and provided on the support 7. As such a synthetic resin binder, it is usually preferable to select one that has high heat resistance and does not hinder dye migration that occurs when heated, and for example, the following are used.

(i) Cellulose resins Ethylcellulose, hydroxyethylcellulose, ethylhydroxycellulose, hydroxypropylcellulose, methylcellulose, cellulose acetate, cellulose acetate butyrate, etc.

(ii) Vinyl resins polyvinyl alcohol, polyvinyl acetate, polyvinyl butyral, polyvinylpyrrolidone,
polyester, polyacrylamide, etc.

Among the above synthetic resin binders, polyvinyl butyral resin or cellulose resin is preferred from the viewpoint of heat resistance.

To provide the thermal transfer layer 8 on the support 7, a dye and a synthetic resin binder are kneaded with a solvent or a diluent to form a coating composition for the thermal transfer layer, and this is applied onto the support 7 by an appropriate printing or coating method. All you have to do is set it up. Note that optional additives may be added to the coating composition for the thermal transfer layer, if necessary.

The basic structure of the thermal transfer sheet is as described above, but when the surface of the support is directly heated by a contact heating means such as a thermal head, the support 7 is heated as shown in FIG. By providing a slippery layer 9 containing a lubricant such as wax or a release agent on the side where the thermal transfer layer is not provided,
It is possible to prevent the heating means such as a thermal head from being fused to the support and to improve the sliding properties.

The thermal transfer sheet may be in the form of a single sheet cut to a required size, continuous or rolled, or may be in the form of a narrow tape.

In addition to thermal heads, heat sources that provide thermal energy include laser light, infrared flash,
A known device such as a thermal pen can be used. Thermal energy can be applied from the thermal transfer sheet side, from the thermal transfer sheet side, or from both sides, but from the viewpoint of effective use of thermal energy, it is best to apply from the thermal transfer sheet side. good. However, it is better to apply thermal energy from the thermal transfer sheet side, because it is possible to control the applied thermal energy to express the gradation of light and shade of the image, or to promote the diffusion of dye on the thermal transfer sheet to create a continuous image. This method is preferable in the sense that the expression of gradation is more reliable, and the advantages of both methods can be enjoyed at the same time in the method of applying thermal energy from both sides.

When a thermal head is used as a heat source for providing thermal energy, the applied thermal energy can be varied continuously or in multiple steps by modulating the voltage or pulse width applied to the thermal head.

When a laser beam is used as a heat source for providing thermal energy, the amount of thermal energy provided can be changed by changing the amount of laser light or the irradiation area. If a dot generator with a built-in acousto-optic element is used, thermal energy can be applied depending on the size of the halftone dot. When using a laser beam, it is best to make sure that the thermal transfer sheet and the thermal transfer sheet are in close contact with each other, and the surface to be irradiated with the laser beam may be colored, for example, black to improve the absorption of the laser beam. good.

When using an infrared flash lamp as a heat source for providing thermal energy, it is best to use a colored layer such as black, similar to when using laser light, or a pattern that continuously expresses the shading of the image, such as black. Alternatively, it may be done through these patterns using halftone dot patterns,
Alternatively, a colored layer such as black on one side and a negative pattern corresponding to the negative of the pattern described above may be combined.

When thermal energy is applied to the interface between the thermal transfer layer and the color developer layer as described above, the amount of dye in the thermal transfer layer is vaporized or melted according to the applied thermal energy, and the color developer layer is heated. It is transferred, accepted, and develops color.

With the above thermal transfer recording, a dye corresponding to the thermal energy is thermally transferred to the receiving layer, and a one-color image can be recorded. By sequentially replacing the black thermal transfer sheet as necessary and performing thermal transfer according to each color,
It is also possible to obtain a color photo-like color image consisting of a combination of colors. Note that instead of using thermal transfer sheets for each color as described above, a single thermal transfer sheet having areas pre-painted in each color is used, and first, for example, a yellow color separation image is thermally transferred using the yellow area. Next, if you use a method that uses, for example, the red area of the thermal transfer sheet, and then repeat the process sequentially to thermally transfer the separated color images of yellow, red, indigo, and if necessary, black, there is no need to replace the thermal transfer sheet. It has the advantage of becoming

Note that the quality of the image obtained can be improved by appropriately adjusting the size of the heat source used to apply thermal energy, the adhesion between the thermal transfer sheet and the thermal transfer sheet, and the thermal energy.

The thermal transfer sheet according to the present invention can be used in combination with a thermal transfer sheet for printing using various thermal printing printers, facsimiles, photo prints using magnetic recording methods, printing from television screens, etc. can.

For example, a received television screen may be stored on a storage medium such as a magnetic tape or magnetic disk.
The signal of each color separation pattern of yellow, red, indigo, and black if necessary is stored, and the signal of each stored color separation pattern is output, and the thermal energy corresponding to this signal is transferred to a thermal head, etc. By applying heat to the stacked body of the thermal transfer sheet and the thermal transfer sheet using the heat source described above and performing thermal transfer for each color sequentially, the television screen can be reproduced as a sheet-like print. When a combination of a thermal transfer sheet and a thermal transfer sheet according to the present invention is used for printing out such a television screen, the thermal transfer sheet usually has a white color developer layer alone or a colorless color developer layer. It is convenient to use a transparent color developer layer lined with a base material such as paper, or a white color developer layer lined with a base material such as paper to obtain a reflective image.

The same thing as above can also be done when using a combination of characters, figures, symbols, colors, etc., or a graphic pattern formed on a CRT screen by computer operation as an original image.
Furthermore, when the original image is a fixed image such as a painting, photograph, or printed matter, or an actual object such as a person, still life, or landscape, the same method as described above can be performed by using an appropriate means such as a video camera as a medium. Furthermore, when creating signals for each color separation pattern from the original image, an electronic plate making machine (color scanner) used for photolithography for printing may be used.

EXAMPLES The present invention will be explained below with reference to Examples, but the present invention is not limited to these Examples.

Example 1 A polyester film with a thickness of 9 μm that was corona-treated on one side was used as a support, and a coating composition for a thermal transfer layer () having the following composition was thoroughly and uniformly ground in a mortar on the corona-treated film surface. , this is 0.24mm so that the thickness when dry is 1μm.
It was coated with a wire bar wrapped with wire of φ and dried with a dryer to obtain a thermal transfer sheet ( ).

Coating composition for thermal transfer layer () CA solvent ⁽¹⁾ 7.5 parts by weight CA varnish ⁽²⁾ 7.5 parts by weight Eisenkathylon Blue 3GLH (manufactured by Hodogaya Chemical Industries) 0.3 parts by weight KOH 0.1 part by weight (1) Toluene: Butyl acetate :Butanol=9:
2:1 mixed solvent (2) 10% by weight of ethyl cellulose resin dissolved in the above CA solvent A thermal transfer sheet () was prepared in the same manner except that a coating composition for a thermal transfer layer () having the following composition was used. Obtained.

Coating composition for thermal transfer layer () CA solvent 7.5 parts CA varnish 7.5 parts by weight Leuco dye TH1109 (manufactured by Hodogaya Chemical Industry)
0.2 parts by weight Add a saturated ammonium sulfate solution to the developer layer coating composition () having the following composition, stir for several minutes to treat phosphotungstic acid with the ammonium compound, then leave to stand, and then separate the upper layer solution. This was applied onto a 100 μm thick synthetic paper as a base material using a #32 wire bar so that the dry film thickness was 5 μm, and then dried in an oven.

Coating composition for developer layer () Modified EVA resin (Elvaloy 741-P) (manufactured by Mitsui Polychemical Co., Ltd.) 2 parts by weight Phosphortungstic acid 0.3 parts by weight Zinc dibutyldithiocarbamate (antiaging agent)
0.01 parts by weight Ethanol 2 parts by weight Methyl ethyl ketone 3 parts by weight Benzene 2 parts by weight Toluene 9 parts by weight Next, on the developer layer of the thermal transfer sheet obtained as above, a coating composition for a protective layer having the following composition was applied. 0.4mmφ so that the film thickness when dry is 1μm
It was applied with a wire bar (#16) wrapped with wire and allowed to dry.

Protective layer coating composition Modified EVA resin (Elvaloy 741-P) (manufactured by Mitsui Polychemicals) 2 parts by weight UV absorber (Tinuvin 328) (manufactured by Ciba Geigy)
0.3 parts by weight Toluene 19 parts by weight Methyl ethyl ketone 2 parts Next, the obtained protective layer was crosslinked by irradiating the entire surface with an electron beam of 10 megalides to obtain a thermal transfer sheet ( ).

When this thermal transfer sheet () and the thermal transfer sheet () were overlapped and printed on this with a thermal printer, a cyan colored image was obtained. When this colored image was subjected to a light fastness test by irradiating it with light from a carbon arc lamp using a Sunshine Weather Meter, the colored image had a light fastness of JIS grade 5 or higher.

Similarly, when the heat transfer sheet () and the heat transfer sheet () were superimposed and a light resistance test was conducted in the same manner as above, the colored image had light resistance of JIS grade 4 or higher.

Example 2 A thermal transfer sheet (2) was obtained in the same manner as in Example 1, except that zinc dibutyldithiocarbamate was not used in the developer layer coating composition (2).

When this thermal transfer sheet () and the thermal transfer sheet () of Example 1 were superimposed and a light fastness test was conducted in the same manner as in Example 1, the colored image was
It had light resistance of JIS grade 3.5 or higher.

[Brief explanation of drawings]

1 and 2 are cross-sectional views of a thermal transfer sheet after a colored image according to the present invention is recorded, and FIG. 3 is a cross-sectional view of a thermal transfer sheet before a colored image is recorded. , 4 and 5 are cross-sectional views of a thermal transfer sheet used in combination with a thermal transfer sheet. DESCRIPTION OF SYMBOLS 1... Thermal transfer sheet, 2... Base material, 3... Color developer layer, 4... Ultraviolet absorber layer, 5... Colored image, 6... Thermal transfer sheet, 7... Support, 8...
Thermal transfer layer.

Claims (1)

[Scope of Claims] 1. By being heated in combination with a thermal transfer sheet having a thermal transfer layer containing a dye that develops color upon contact with a color developer layer containing a color developer and that is heat transferable. In the thermal transfer sheet on which a colored image is recorded on the color developer layer, a color developer layer comprising a binder resin and a color developer is provided on the base material, and an ultraviolet absorber is included on the color developer layer. A thermal transfer sheet characterized by forming an ultraviolet absorber layer. 2. The thermal transfer sheet according to claim 1, wherein the color developer is a heteropolyacid or a salt thereof. 3. The thermal transfer sheet according to claim 1, wherein the binder resin of the color developer layer contains a sulfonic acid residue or a phosphoric acid residue. 4. The thermal transfer sheet according to claim 1, wherein the ultraviolet absorber layer has a thickness of 0.1 to 100 μm. 5. The color developer layer further contains a metal deactivator, an excited oxygen absorber, or an antiaging agent.
A thermal transfer sheet according to claim 1. 6. Prepare a thermal transfer sheet in which a color developer layer consisting of a binder resin and a color developer is provided on a base material, and an ultraviolet absorber layer containing an ultraviolet absorber is formed on the developer layer, A thermal transfer sheet having a thermal transfer layer that develops color upon contact with the color developer layer and contains a heat-transferable dye and the thermal transfer sheet are arranged so that the ultraviolet absorber layer and the thermal transfer layer face each other. A method for producing a thermal transfer sheet in which a colored image is recorded in a developer layer and an ultraviolet absorber layer is formed on the developer layer, the method comprising overlapping the two and then thermally printing. . 7. The method according to claim 6, wherein the color developer is a heteropolyacid or a salt thereof. 8. The method according to claim 6, wherein the binder resin of the color developer layer contains a sulfonic acid residue or a phosphoric acid residue. 9. The method according to claim 6, wherein the ultraviolet absorber layer has a thickness of 0.1 to 100 μm. 10. The method according to claim 6, wherein the color developer layer further contains a metal deactivator, an excited oxygen absorber, or an antiaging agent. 11 A thermal transfer sheet comprising a base material and a color developer layer made of a binder resin and a color developer provided thereon, and a thermal transfer sheet that develops color upon contact with the color developer layer and contains a heat-transferable dye. A thermal transfer sheet having a thermal transfer sheet having a layer is overlaid so that the developer layer and the thermal transfer layer face each other, and then thermal printing is performed to record a colored image in the developer layer of the thermal transfer sheet. Then, this thermal transfer sheet on which a colored image has been recorded and a UV absorber transfer sheet on which a UV absorber transfer layer containing an UV absorber and a binder is formed on a transfer base paper are combined with the color developer. In the color developer layer, the ultraviolet absorber layer is transferred onto the developer layer by overlapping the layer and the ultraviolet absorber transfer layer so that they face each other and heating them. A method for producing a thermal transfer sheet, on which a colored image is recorded, and an ultraviolet absorber layer is formed on the developer layer. 12. The method according to claim 11, wherein the color developer is a heteropolyacid or a salt thereof. 13. The method according to claim 11, wherein the binder resin of the color developer layer contains a sulfonic acid residue or a phosphoric acid residue. 14. The method according to claim 11, wherein the ultraviolet absorber layer has a thickness of 0.1 to 100 μm. 15. The method according to claim 11, wherein the color developer layer further contains a metal deactivator, an excited oxygen absorber, or an antiaging agent. 16 A thermal transfer sheet comprising a heat transfer sheet having a color developer layer made of a binder resin and a color developer provided on a base material, and a heat transferable dye that develops color upon contact with the color developer layer and contains a heat transferable dye. A thermal transfer sheet having a thermal transfer sheet having a layer is overlaid so that the developer layer and the thermal transfer layer face each other, and then thermal printing is performed to record a colored image in the developer layer of the thermal transfer sheet. Then, by applying a coating composition for an ultraviolet absorber layer containing an ultraviolet absorber onto the developer layer on which the colored image has been recorded,
An ultraviolet absorber layer is formed on the developer layer, and a colored image is recorded in the developer layer and an ultraviolet absorber layer is formed on the developer layer. A method of manufacturing a thermal transfer sheet. 17. The method according to claim 16, wherein the color developer is a heteropolyacid or a salt thereof. 18. The method according to claim 16, wherein the binder resin of the color developer layer contains a sulfonic acid residue or a phosphoric acid residue. 19. The method according to claim 16, wherein the ultraviolet absorber layer has a thickness of 0.1 to 100 μm. 20. The method according to claim 16, wherein the color developer layer further contains a metal deactivator, an excited oxygen absorber, or an antiaging agent. 21 A thermal transfer sheet comprising a heat transfer sheet provided with a color developer layer consisting of a binder resin and a color developer on a base material, and a heat transferable dye that develops color upon contact with the color developer layer and which is heat transferable. A thermal transfer sheet having a thermal transfer sheet having a layer is overlaid so that the developer layer and the thermal transfer layer face each other, and then thermal printing is performed to record a colored image in the developer layer of the thermal transfer sheet. Then, this thermal transfer sheet on which a colored image has been recorded and a UV absorber transfer sheet on which a UV absorber transfer layer containing an UV absorber and a binder is formed on a transfer base paper are combined with the color developer. The color developer layer and the UV absorbent transfer layer are layered and heated so that they face each other, and the UV absorber layer is thermally transferred onto the color developer layer. A UV absorber layer containing a high concentration of UV absorber is formed on the top of the color developer layer. A method for producing a thermal transfer sheet formed of 22. The method according to claim 21, wherein the color developer is a heteropolyacid or a salt thereof. 23. The method according to claim 21, wherein the binder resin of the color developer layer contains a sulfonic acid residue or a phosphoric acid residue. the method of. 24. The method according to claim 21, wherein the color developer layer further contains a metal deactivator, an excited oxygen absorber, or an antiaging agent.