JPH06143827A - Thermal transfer recording medium, reproducing method therefor and thermal transfer recording method - Google Patents

Abstract

PURPOSE:To prevent reverse transfer of dye so as to form an excellent color image even by a regenerating thermal transfer recording medium by rapidly supplying dye to used thermal transfer recording medium, and so regenerating it that the quality of the image is not lowered to be repeatedly used many times. CONSTITUTION:A thermal transfer recording medium comprises a dye transport layer 1 made of dye and first medium, and a dye aggregate layer 2 made of dye and second medium. The first medium of the layer 1 has larger diffusion constant of the dye than that of the second medium of the layer 2, and the second medium of the layer 2 has larger saturated solubility of the dye than the medium of the layer 1. The thermal transfer recording medium is regenerated by bringing a dye supply layer of dye supplier into contact with the layer 1, and heating it to diffuse the dyes from the supply layer to the layer 1 and from the layer 1 to the layer 2 to be supplied. Particularly, as a method for preventing reverse transfer of the dye, reactive dispersive dye is used, and active hydrogen compound having a molecular weight of 100-1000 is contained in an image receiving layer of a material to be transferred.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention uses a heating means such as a thermal head or a laser to transfer a heat diffusible dye to an object to be transferred according to an image signal to form a continuous gradation transfer image. A thermal transfer recording medium that enables a thermal transfer recording medium to be repeatedly used by replenishing and reproducing a dye, a method for reproducing such a thermal transfer recording medium, and such a thermal transfer recording medium. Thermal transfer recording method.

[0002]

2. Description of the Related Art Conventionally, an object to be transferred such as a printing paper and a thermal transfer recording medium such as an ink sheet are superposed and heated selectively by a heating means such as a thermal head or a laser according to an image signal. However, a thermal transfer recording method in which a dye is transferred from a thermal transfer recording medium to a transfer target to record an image is widely used. Among them, the so-called sublimation type thermal transfer recording method using a heat diffusible dye such as a sublimation dye as a dye to be transferred is a recording device which can be downsized and easily maintained, and has immediacy.
Moreover, since gradation can be obtained in a recorded image according to heating energy and a high-quality image equivalent to a silver salt color photograph can be obtained, in recent years, a hard copy of an image of a video camera, a television, computer graphics or the like It is attracting attention as a technology.

However, since the thermal transfer recording medium used for such thermal transfer recording is conventionally thrown away, a large amount of waste is generated, which is a problem from the viewpoint of resource saving and environmental protection.

Therefore, it is socially demanded to improve the utilization efficiency of the thermal transfer recording medium by reproducing the used thermal transfer recording medium.

As a method for improving the utilization efficiency of a thermal transfer recording medium, a coloring material layer of a thermal transfer recording medium can be reproduced and repeatedly used, such as a coloring material layer reproducing method or a multi-time coloring material layer construction method. And a method of effectively utilizing the thermal transfer recording medium such as a relative velocity method.

Among them, in the color material layer reproduction method, the heat transfer recording medium used for heat melting type heat transfer recording in which an image is formed by heat melting the color material layer and transferring the color material layer to a transfer object can be repeatedly used. In this method, the thermal transfer recording medium is formed into an endless belt shape, and the color material layer of the thermal transfer recording medium consumed by the transfer is reformed by applying a heat-melting ink (Japanese Patent Publication No. 49-
No. 26245, Japanese Patent Publication No. 59-16932, etc.).

The multi-color material layer construction method is also a method applied to heat-melt type thermal transfer recording, and the color material layer of the ink sheet is
It is formed by impregnating the heat-melting ink into the porous network structure layer so that the ink exudes from the inside to the surface even when the ink on the surface of the ink sheet is consumed. Is enabled (Ozawa, Shimizu, IEICE National Convention, 1236 (1983)).

The relative velocity method is a method for improving the repetitive recording property of an ink sheet by changing the relative velocity of the ink sheet with respect to a transfer target in a thermal transfer recording method using a sublimable dye. Enables single transfer (Taguchi, et al., The Electrophotographic Society of Japan, vol2
4, No3, p17 (1985)).

[0009]

However, among the methods for improving the utilization efficiency of the conventional thermal transfer recording medium, the coloring material layer reproducing method and the multiple times coloring material layer forming method are the thermal transfer methods used for the thermal melting type thermal transfer recording. The present invention relates to a recording medium and does not allow reuse of a thermal transfer recording medium used for sublimation type thermal transfer recording. Also, in these methods,
There is a problem that it is difficult to reform the surface of the color material layer of the thermal transfer recording medium uniformly. Furthermore, in the color material layer recycling method, since the dye is supplied in a wet process, an organic solvent is required, so that the supply mechanism and the maintenance cannot be simplified. In the method, since the dye is not replenished from the outside to the color material layer once formed, there is a problem that the repetitive recording property of the ink sheet is limited to several times, and it is not possible to transfer many times. Therefore, these methods have not been put to practical use.

The relative velocity method relates to a thermal transfer recording medium used for sublimation type thermal transfer recording, but it has a problem that a mechanism for changing the relative velocity between a transfer object and an ink sheet becomes complicated, and this Depending on the method, the repetitive recording property of the ink sheet is limited to several times, and it is not possible to transfer more than that many times. Therefore, the relative velocity method has not been put to practical use.

In general, when a color image is recorded by the thermal transfer recording method, the thermal transfer recording medium is provided with areas of different colors, and the areas of each color are sequentially superposed on the transferred material to record an image. However, in order to enable the thermal transfer recording medium to be used repeatedly a number of times in recording such a color image, the dye of the first color transferred from the thermal transfer recording medium to the transfer target is different from the dye of the first color. At the time of transferring the dyes of two colors, it is a new important issue to prevent reverse transfer from the transferred material to the thermal transfer recording medium.

The present invention is intended to solve such problems of the prior art, and enables a dye to be replenished to a thermal transfer recording medium used for sublimation type thermal transfer recording so that the thermal transfer recording medium can be repeatedly used many times. The purpose is to do.

[0013]

DISCLOSURE OF THE INVENTION The inventors of the present invention relate to a method for reproducing a thermal transfer recording medium using a heat diffusible dye such as a sublimation dye. When a resin having solubility and good diffusibility of the dye is used, the dye is quickly diffused in the color material layer by heating, and a dye composed of a high concentration of dye in such a color material layer. When the supply body is contacted and heated, the dye is transferred from the dye supply body to the color material layer by thermal diffusion, so that the dye of the color material layer consumed by the transfer can be replenished, and the dye concentration of the color material layer can be increased. It has been found that the color material layer can be made uniform, and a method for reproducing a thermal transfer recording medium has been proposed, which comprises heating a dye supplier in contact with the color material layer (Japanese Patent Application No. 4-2.
32711 specification).

However, as a result of further research, the coloring material layer was
By having a two-layer structure of a dye transport layer having excellent dye diffusion properties and a dye aggregation layer that holds the dye at a high concentration and transfers the dye to the transfer target, the consumed dye is replenished more quickly,
Moreover, they have found that the image quality can be further improved, and have completed the thermal transfer recording medium of the present invention and the reproducing method thereof.

Further, in order to prevent the reverse transfer of the dye once transferred from the thermal transfer recording medium to the transfer object, and to form a good color image even when the thermal transfer recording medium is repeatedly used many times. Uses a reactive disperse dye having a specific reactive group as the dye of the thermal transfer recording medium,
It has been found that it is effective to include such a reactive disperse dye and an active hydrogen compound which forms a covalent bond at the time of transfer in the receiving layer of the transferred material, and has completed the thermal transfer recording method of the present invention.

That is, the first aspect of the present invention is a thermal transfer recording medium in which a thermal diffusible dye is transferred to a transferred body by superimposing it on the transferred body and selectively heating it.
It comprises a dye transport layer comprising a dye and a first medium, and a dye aggregation layer comprising a dye and a second medium, the first medium of the dye transport layer being of a dye concentration higher than that of the second medium of the dye aggregation layer. A thermal transfer recording medium is provided which has a high diffusion coefficient and the second medium of the dye aggregation layer has a higher saturated solubility of the dye than the first medium of the dye transport layer.

A second aspect of the present invention is a thermal transfer recording medium in which a thermal diffusible dye is transferred to a transferred body by superimposing it on the transferred body and selectively heating it.
The first medium of the dye transport layer comprises a substrate, a dye supply layer made of a dye, a dye transport layer made of the dye and a first medium, and a dye aggregation layer made of the dye and a second medium. Thermal transfer recording characterized in that the diffusion coefficient of the dye is larger than that of the second medium of the dye aggregation layer, and that the second medium of the dye aggregation layer has a larger saturated solubility of the dye than the first medium of the dye transport layer. Provide media.

Further, the present invention provides a method for reproducing a thermal transfer recording medium according to the first aspect of the present invention, in which a dye supplying layer made of a dye is brought into contact with the dye transport layer of the thermal transfer recording medium according to the first aspect of the present invention. A method for reproducing a thermal transfer recording medium, characterized in that by heating, the dye is diffused from the dye supplier to the dye transport layer of the thermal transfer recording medium to be replenished, and the dye is diffused from the dye transport layer to the dye aggregation layer to be replenished. provide.

As a method of reproducing the thermal transfer recording medium according to the second aspect of the present invention, the thermal transfer recording medium according to the second aspect of the present invention is heated to diffuse the dye from the dye supply layer to the dye transport layer to replenish the dye. Disclosed is a method for reproducing a thermal transfer recording medium, characterized in that a dye is diffused from a layer to a dye aggregation layer and supplied.

Further, according to the present invention, as a thermal transfer recording method capable of forming a color image satisfactorily even when the thermal transfer recording medium is repeatedly used a number of times, the transfer object and the thermal transfer recording medium are superposed, In the thermal transfer recording method of forming an image by transferring a thermal diffusible dye from a thermal transfer recording medium to a transfer target by selective heating, the first thermal transfer recording of the present invention wherein the dye is a reaction dispersible dye as the thermal transfer recording medium. The second thermal transfer recording medium of the present invention, in which the medium or the dye is a reaction dispersible dye, is used, and a transfer target having an image receiving layer containing an active hydrogen compound having a molecular weight of 100 to 1000 is used. A thermal transfer recording method is provided.

The present invention will be described below in detail with reference to the drawings. In each drawing, the same reference numerals represent the same or equivalent constituent elements.

FIG. 1 is a sectional view of an embodiment of the first thermal transfer recording medium of the present invention. As shown in the figure, the thermal transfer recording medium 100 has a structure in which a dye transport layer 1 and a dye aggregation layer 2 are laminated.

Here, the dye transport layer 1 is a layer having a function of supplying the dye to the dye aggregation layer 2, which is consumed during the transfer. In this case, the dye transport layer 1 not only simply supplies the dye to the dye aggregation layer 2 but also has a buffer function for the dye consumed in the dye aggregation layer 2.
It is possible to stably supply the dye in a short time. The dye transport layer 1 also has a function of imparting mechanical strength so that the thermal transfer recording medium can withstand repeated use.

Such a dye transport layer 1 is formed by holding a heat diffusible dye in a medium having a high dye diffusion rate such as a dye diffusible resin, a porous material or a gel material. Here, as the thermal diffusion dye, a dye having a low melting point such as a disperse dye, a leuco dye, an oil-solubilized acid dye, and an oil-solubilized cationic dye, which can be easily thermally transferred to a transfer target is arbitrarily selected. can do. In particular, as the dye, those having a low melting point, having a hydrophobic group such as an alkyl group and a phenyl group in the molecule and exhibiting high compatibility with the image receiving layer of the transferred material are preferable, and further, the diffusion coefficient in the resin is large. Therefore, those having a small molecular weight are preferable. Further, as the dye, a dye that completely fixes the image on the transferred material by forming a covalent bond or an ionic bond with the polymer of the image receiving layer of the transferred material can be used. As such a dye, it is particularly preferable to use a reactive disperse dye that forms a covalent bond with the active hydrogen compound contained in the image-receiving layer of the transferred material. A thermal transfer recording method using a reactive disperse dye as a dye of a thermal transfer recording medium and a transfer target containing an active hydrogen compound in its image receiving layer will be described in detail later. By using the dye, reverse transfer of the dye once transferred to the transfer target is prevented, and a good color image can be obtained even if the thermal transfer recording medium is repeatedly used.

Examples of such reactive disperse dyes include reactive groups of the following formula (1)

[0026]

[Chemical 1] (Wherein, X and Y are each Cl, F, is selected from -OCH ₃ and -N _{(CH 3) 2,} at least one of X and Y in this case is Cl or F), - SO _{2
CH = CH 2, -SO 2 F} , -NH-CO-CHC
_{l 2, -N (C 2 H} 4 Cl) 2, -SO 2 CH 2 CH 2
Cl, -NH-CO-CH = CH 2 or the following formula (2)
Reactive group of

[0027]

[Chemical 2] (In the formula, X, Y and Z are respectively Cl, F and -OCH.
₃ and is selected from -N _{(CH 3) 2,} in this case, X, at least one of Y and Z can be used preferably disperse dyes having a a) Cl or F. As the reactive disperse dye having such a reactive group, those shown in Table 1 can be exemplified.

[0028]

[Table 1] As a medium for the dye transport layer 1 holding the dye as described above, a medium having a dye diffusion coefficient of 1 × 10 ⁻⁶ cm ² / sec or more when the dye transport layer 1 is heated during dye replenishment is used. Further, it is preferable to use a dye having a dye diffusion coefficient of 1 × 10 ⁻⁴ cm ² / sec or more so that the dye replenishment can be completed within a normal transfer time. More specifically, examples of the dye-diffusing resin include silicone resin, polyvinyl chloride containing a large amount of plasticizer, and the like, as the porous material, polyolefin porous body, polytetrafluoroethylene porous body, etc. Can be illustrated.

The thickness of the dye transport layer 1 is 1 μm.
It is preferably not less than m and not more than 1000 μm, more preferably not less than 10 μm and not more than 100 μm. If it is less than 1 μm, the buffer function of the dye transport layer 1 is deteriorated, and the dye cannot be rapidly supplied to the dye aggregation layer 2 at the time of replenishing the dye after transfer, and the same portion of the dye aggregation layer 2 is used again. When performing transfer, a sufficient dye concentration cannot be ensured, and transfer unevenness may occur. Further, if the thickness of the dye transport layer 1 is too thin, the mechanical strength will be insufficient. On the other hand, when the thickness of the dye transport layer 1 exceeds 1000 μm, the distance between the dye aggregating layer 2 and the dye supplying body that supplies the dye to the dye transport layer 1 at the time of replenishing the dye is too large, and the dye transport layer 1 intervenes the dye. Aggregation layer 2
It is difficult to replenish the dye.

There is no particular limitation on the method for holding the dye in the medium in the dye transporting layer 1, and for example, a dye supplier, which will be described later, is brought into contact with a layer formed of the medium in which the dye is not held, It may be heated sufficiently to diffuse the dye from the dye supplier to the medium.

The dye aggregation layer 2 is a layer which comes into contact with the transfer target at the time of transfer and supplies the dye to the transfer target. Therefore, it is desired that the dye aggregation layer 2 has a high dye concentration and a uniform surface dye concentration so that a high-quality image can be formed on the transfer target. Therefore, the dye aggregation layer 2 is formed by using a resin having a high compatibility with the dye and a high solubility of the dye as a medium and holding the dye in the medium. More specifically, it is preferable to use, as the medium of the dye aggregation layer 2, a medium in which the saturated solubility of the dye is 5% by weight or more, and more preferably, the saturated solubility of the dye is 20% by weight.
Use the above. In addition, the medium of the dye aggregation layer 2 is required to have high mechanical strength and heat resistance so that it can withstand repeated transfer, and further, it has affinity and adhesion with the constituent substances of the dye transport layer 1. Good nature,
It is required to be laminated on the dye transport layer 1 without any gap. Examples of such a medium include polyesters, polyvinyl butyral, polyvinyl chlorides, cellulose esters, polystyrenes, polycarbonates, and copolymers thereof. In particular, when a silicone-based resin is used as the resin forming the dye transport layer 1, the dye aggregation layer 2
When a general-purpose resin is used as the medium, the adhesiveness between the dye transport layer 1 and the dye aggregation layer 2 is significantly reduced, so it is preferable to use a resin containing a silicone component such as a silicone-modified polyester resin.

The thickness of the dye aggregation layer 2 is 0.1 μm.
It is preferably not less than 10 μm and more preferably not less than 0.5 μm and not more than 2 μm. If it is less than 0.1 μm, a sufficient amount of dye cannot be secured during transfer, and it becomes difficult to form a transferred image with high sensitivity. On the other hand, if the thickness of the dye aggregation layer 2 exceeds 10 μm, it takes a long time to diffuse the dye, which makes it difficult to quickly replenish the dye.

There is no particular limitation on the method of holding the dye in the medium in the dye aggregation layer 2, and the same method as in the case of holding the dye in the dye transport layer 1 can be used.

As the dye aggregation layer 2, after the layer composed of the resin and the dye as described above is formed, the dye transport layer 1 is further formed.
The surface thereof may be modified in order to improve the affinity and the adhesion with.

Further, in the case where the dye aggregation layer 2 is heated at the time of transfer by using a laser beam as a heat source, a laser beam absorber can be contained. The laser light absorber may be contained in the dye transport layer 1, but is preferably contained mainly in the dye aggregation layer 2. Further, when heating the thermal transfer recording medium during reproduction is performed by energization heating, a resistance heating element such as carbon black or a nichrome wire mesh can be embedded in the dye aggregation layer 2.

2A and 2B are respectively shown in FIG.
FIG. 6 is a cross-sectional view of an embodiment of a dye supplier used to reproduce the thermal transfer recording medium 100 of the present invention as shown in FIG. The dye supply body 200 in FIG. 3A is a plate type in which the dye supply layer 4 is laminated on the base body 3, and the dye supply body 201 in FIG. Of the dye supply layer 4 formed into a stick shape.

The dye supplying bodies 200 and 201 as described above are
Since the dye is supplied to the dye aggregation layer 2 through the dye transport layer 1 of the thermal transfer recording medium 100 described above, the dye supply layer 4 of the dye supply bodies 200 and 201 is the same as the dye used in the thermal transfer recording medium 100. Formed from the same dye.

The dye supply layer 4 may be formed of only the dye, but the shape of the dye supply body is maintained, and the dye supply speed (diffusion speed) of the dye to the dye transport layer 1 of the above-mentioned thermal transfer recording medium is controlled. In order to increase the temperature, a dye may be mixed with a resin binder or a low molecular weight organic compound, if necessary.

The kind of the resin binder and the low molecular weight organic compound is appropriately selected according to the kind of the dye to be used. For example, when a disperse dye is used, the resin binder may be polyester, polyvinyl chloride or acetic acid. Cellulose, nitrocellulose, polyvinyl butyral, polycarbonate and the like can be preferably used. Also,
As the low molecular weight organic compound, a plasticizer such as dibutyl phthalic acid, diethyl phthalic acid or dicyclohexyl phthalate, or an organic solvent such as acetone, toluene, methyl ethyl ketone, ethyl alcohol, methyl alcohol or cyclohexanone can be used.

When a resin binder or a low molecular weight organic compound is used with a dye, the dye is supplied from the dye supply layer 4 to the dye aggregation layer 2 through the dye transport layer 1 of the thermal transfer recording medium by thermal diffusion. As described above, the volume fraction of the dye in the dye supply layer 4 needs to be higher than the volume fraction of the dye in the dye aggregation layer 2. Therefore, generally, the concentration of the resin binder or the low molecular weight organic compound in the dye supply layer 4 is 80% by weight or less, more preferably 1 to 50.
Weight%

As in the dye supplier 200 of FIG. 2A,
When the dye supply layer 4 is provided on the base body 3, the base body 3 has mechanical strength and heat resistance capable of withstanding a large number of transfers, and further has high thermal conductivity in order to improve the thermal efficiency at the time of replenishing the dye. It is preferable to use a polymer compound, a metal, a ceramics, or the like having the above.

3 (a) and 3 (b) respectively show the second
3 is an example of a cross-sectional view of thermal transfer recording media 300 and 301 of the present invention. The thermal transfer recording medium 300 shown in FIG. 2A differs from the thermal transfer recording medium 301 shown in FIG. 2B in that it has a sheet shape, and the thermal transfer recording medium 301 has a roller shape.
Dye supply layer 4 similar to the dye supply body 200 shown in (a)
And a thermal transfer recording medium 1 shown in FIG.
The dye transporting layer 1 and the dye aggregating layer 2 similar to those of No. 00 are laminated.

These thermal transfer recording media 300, 301
Since the dye supply layer 4 for supplying the dye to the dye aggregation layer 2 at the time of reproducing the thermal transfer recording medium is integrated with the dye aggregation layer 2, it is not necessary to use a separate dye supply body at the time of supplying the dye. .

The method of transferring using the thermal transfer recording medium 100 shown in FIG. 1 and the thermal transfer recording media 300 and 301 shown in FIG. 3 can be the same as the conventional thermal transfer recording medium. That is, each thermal transfer recording medium 100, 300, 30
The dye aggregating layer 2 of 1 and the transfer target are superposed, and selective heating according to an image signal is performed by the thermal head to transfer the dye from the dye aggregating layer 2 to the transfer target.

However, when the thermal transfer recording medium is repeatedly reused as in the case of forming a color image, it is particularly necessary to prevent the reverse transfer of the dye once transferred from the thermal transfer recording medium to the transferred material. In this case, as described above, a thermal transfer recording medium using a reactive disperse dye is used, and the transfer target is an image-receiving layer that receives the dye from the thermal transfer recording medium at the time of transfer and has a molecular weight of 100.
The one having an image receiving layer containing ˜1000 active hydrogen compounds, preferably 5 to 50% by weight of the image receiving layer is used. As a result, the reactive group of the reactive disperse dye transferred from the thermal transfer recording medium to the transfer target at the time of transfer and the active hydrogen compound contained in the transfer target form a covalent bond, and the dye receives the image on the transfer target. Since it is fixed in the layer, reverse transfer is prevented. In this case, if the molecular weight of the active hydrogen compound is smaller than the above range, the active hydrogen compound is likely to sublime, which is not preferable, while if it is larger than the above range, it becomes difficult to uniformly disperse it in the image receiving layer. Examples of suitable active hydrogen compounds include those shown in Table 2.

[0046]

[Table 2] As the resin for the image receiving layer in which such an active hydrogen compound is dispersed, for example, cellulose, hydroxyethyl cellulose, alcohol-solubilized nylon or the like can be used. Commercially available products thereof include Toray Industries, Inc., CM
4000, CM8000, manufactured by Teikoku Kagaku KK, resin, etc. can be used.

The thermal transfer recording method of the present invention including the thermal transfer recording medium using the reactive disperse dye and the transfer material containing the active hydrogen compound in the image receiving layer as described above are also included. When thermal transfer recording is performed using a recording medium, the position of the thermal head can be either on the thermal transfer recording medium side or on the transfer target side. When the thermal head is arranged on the thermal transfer recording medium side, heat from the thermal head is transferred to the dye aggregation layer 2 of the thermal transfer recording medium over the dye transport layer 1, so that the thermal efficiency becomes low. Therefore, it is necessary to supply relatively large heating energy from the thermal head. On the other hand, even when the thermal head is arranged on the transfer target side, if the transfer target has a thick base paper, the thermal efficiency is significantly reduced. Therefore, when the thermal head is arranged on the transfer target side, a thin sheet is used as the image receiving layer of the transfer target, a transfer image is formed on this sheet, and then this sheet is laminated on a base paper. Operation is required.

In addition, as a transfer method, laser light can be used as a heat source at the time of transfer. In this case, as described above, it is preferable to add the laser light absorber to the dye aggregation layer 2. Further, it is preferable that a transparent sheet that does not absorb laser light is used as the image receiving layer of the transferred material, and the transferred image is formed by irradiating the sheet with the laser light from the transferred material side.

As a reproducing method for allowing the thermal transfer recording medium of the present invention to be used repeatedly many times, in the case of the thermal transfer recording medium not provided with the dye supply layer 4 like the thermal transfer recording medium 100 shown in FIG. The dye supplying layer 1 is brought into contact with the dye supply body 200 shown in FIG. 2A or the dye supply body 201 shown in FIG. The dye can be supplied to the dye aggregation layer 2 of the thermal transfer recording medium by diffusing the dye through the dye transport layer 1. The thermal transfer recording medium 100 and the dye supplying body 200 or 201 may be in constant contact with each other, or at the time of reproduction, that is, at the time of replenishment of the dye, the dye supplying body 200 is provided near a portion to be reproduced of the thermal transfer recording medium 100. Alternatively, 201 may be contacted.

Further, as shown in FIG. 3 (a) or FIG. 3 (b), the thermal transfer recording mediums 300 and 30 having the dye supplying body.
In the case of 1, the thermal transfer recording media 300, 30 are heated by a heater or the like during or after the transfer.
The dye is supplied from the dye supply layer 4 in 1 to the dye aggregation layer 2 through the dye transport layer 1 by thermal diffusion.

As a heating method at the time of such reproduction, the dye aggregation layer 2 is so adjusted that the dye concentration of the dye aggregation layer 2 becomes high.
It is preferable to arrange the heating means so that a temperature gradient is generated in which the side becomes high temperature and the dye transport layer 1 side becomes low temperature. For this purpose, it is preferable to scan a heating roller on the surface of the dye aggregation layer 2, or a resistance heating element such as carbon black or a nichrome wire mesh may be embedded in the dye aggregation layer 2 in advance and the current is applied to it. Heating or the like is preferable.

The heating for such reproduction can be performed by the heat at the time of transfer, but it is preferably heated separately after the transfer.

[0053]

In general, in the color material layer of the thermal transfer recording medium containing the diffusible dye, the diffusion coefficient of the diffusible dye and the saturation solubility are in a trade-off relationship. That is, in order to enable rapid replenishment of the dye, if the color material layer is configured so that the diffusion coefficient of the dye becomes high, the saturation solubility of the dye becomes low and the quality of the transferred image deteriorates, while the image quality becomes high. Therefore, if the color material layer is configured so that the saturated solubility of the dye becomes high, the diffusion coefficient of the dye becomes low and it becomes difficult to quickly supply the dye.

On the other hand, in the thermal transfer recording medium of the present invention, the portion corresponding to the conventional color material layer is the dye aggregation layer in which the saturated solubility of the dye is increased, and the dye transport layer in which the diffusion coefficient of the dye is increased. Since it has a two-layer structure, it is possible to obtain a high image quality at the time of transfer and to quickly replenish the dye at the time of reproduction after the transfer.

The reproducing method of the thermal transfer recording medium of the present invention is
This is a method of reproducing the thermal transfer recording medium of the present invention having such a two-layer structure. According to this reproducing method, the dye aggregation layer in which the dye concentration is decreased after the transfer is transferred to the high concentration via the dye transport layer. In contact with the dye supply layer consisting of the diffusible dye of
Since it is heated, the dye is rapidly diffused by heat from the dye supply layer to the dye transport layer, and is further maintained at a high concentration in the dye aggregation layer.

Therefore, the dye can be continuously replenished to the dye aggregation layer of the thermal transfer recording medium, and the repeating recording property of the thermal transfer recording medium is not limited to several times, but recording can be performed many times. Further, in this case, since the dye concentration in the dye aggregation layer is rapidly made uniform to a high concentration, the image quality of the thermal transfer recording medium after the dye is replenished does not deteriorate. Further, since the dye replenishment is performed in a dry process, it is possible to simplify the dye replenishment mechanism and the maintenance of the mechanism.

Further, according to the thermal transfer recording method of the present invention, a thermal transfer recording medium in which the dye is a reactive disperse dye is used, and a material to be transferred contains an active hydrogen compound in its image receiving layer. Therefore, the dye transferred from the thermal transfer recording medium to the transferred material at the time of transfer forms a covalent bond with the active hydrogen compound in the image receiving layer of the transferred material and is fixed in the image receiving layer. Therefore, it is possible to prevent reverse transfer of the dye from the transferred material to the thermal transfer recording medium, and it is possible to obtain a good transferred image even when the thermal transfer recording medium is reproduced and repeatedly used to record a color image. Becomes

[0058]

EXAMPLES The present invention will be specifically described below with reference to examples. Needless to say, the present invention is not limited to the embodiments.

Example 1 FIG. 4 is a schematic configuration diagram of an apparatus that performs thermal transfer and reproduction of the thermal transfer recording medium using the thermal transfer recording medium of the present invention.

In the figure, 6 is a thermal head, which has heating elements 6a arranged in a matrix.

Reference numeral 302 denotes a thermal transfer recording medium in which the dye transport layer and the dye aggregating layer are integrated with the dye supply layer, like the thermal transfer recording medium 300 shown in FIG. 3A. The thermal transfer recording medium 302 has an endless ribbon structure and has a yellow transfer portion, a magenta transfer portion, and a cyan transfer portion formed in the running direction. The substrate of the thermal transfer recording medium 302 is made of a PET film having a thickness of 6 μm, the dye supply layer has a thickness of 20 μm, and 10% by weight of dicyclohexyl phthalate is added to the yellow disperse dye, magenta, corresponding to each color transfer portion. An area composed of a disperse dye and a cyan disperse dye is formed. The dye transport layer is composed of a 100 μm thick methylphenyl silicone resin that is in close contact with the dye supply layer. The dye aggregation layer is
It is composed of a polyvinyl butyral resin having a thickness of 2 μm which is in close contact with the dye transport layer. It should be noted that any of these resins constituting the dye transport layer and the dye aggregation layer is used after the dye is sufficiently held in advance.

In the figure, numeral 7 is an image receiving sheet. This image-receiving sheet 7 is formed by using a PET film as a base material and coating a polyester-based image-receiving layer having a thickness of 5 μm on it. The total thickness is 10 μm, and is supplied sequentially from a roll. Reference numeral 8 is a platen roller, and 9 is a heater for supplying dye.

In such an apparatus, thermal transfer was carried out as follows. That is, the thermal transfer recording medium 302 was wound around the platen roller 8, the yellow transfer portion of the thermal transfer recording medium 302 was brought into contact with the image receiving sheet 7, and the thermal head 6 heated from the image receiving sheet 7 side to print. After that, the thermal transfer recording medium 302 was moved, and similarly, recording was sequentially performed on the image receiving sheet 7 at the magenta transfer portion and the cyan transfer portion. Finally, the image receiving sheet 7 was laminated on a mount to obtain a full color image. The optical density of the obtained image-receiving sheet 7 was OD = Yellow, magenta, and cyan on a Macbeth densitometer.
It reached around 2.

After the thermal transfer is completed, in order to reproduce the thermal transfer recording medium 302 in which the surface dye concentration is partially reduced, the thermal transfer recording medium 302 is heated by the dye replenishing heater 9 from the dye aggregating layer side to 10 depending on the required replenishing amount of the dye. Heated ~ 100 ms. As a result, the dye diffused from the dye supplier to the dye aggregation layer via the dye transport layer, and the dye concentration in the dye aggregation layer was recovered.

As a result of repeating such thermal transfer and reproduction operations, the dye concentration on the surface of the thermal transfer recording medium 302 was always kept constant, and the transfer sensitivity did not decrease even after several tens of thermal transfers.

Comparative Example 1 A thermal transfer recording medium similar to that used in Example 1 was used except that it did not have a dye supplier, and the thermal transfer and reproduction operations were repeated. It decreased as the number of repeated transfers increased.

Comparative Example 2 A thermal transfer recording medium similar to that used in Example 1 was used except that it did not have a dye transport layer, and an attempt was made to repeat thermal transfer and regenerating operations. Since the physical strength of the dye cohesive layer that was in direct contact was insufficient, the thermal transfer recording medium was damaged immediately after thermal transfer and could not be used thereafter.

Comparative Example 3 The same thermal transfer recording medium as in Example 1 was used except that it did not have a dye aggregation layer, and the thermal transfer and regenerating operations were repeated to find that the dye was saturated in the dye transport layer. Due to the low solubility, sufficient transfer sensitivity could not be obtained.

Example 2 FIG. 5 is a schematic configuration diagram of an apparatus which performs thermal transfer and reproduction of the thermal transfer recording medium by using the thermal transfer recording medium of a different aspect of the present invention.

Also in the figure, 6 is a thermal head,
The heating elements 6a are arranged in a matrix.

101 is the thermal transfer recording medium 10 shown in FIG.
Like No. 0, it is a thermal transfer recording medium in which a dye transport layer and a dye aggregation layer are formed separately from the dye supplier. Further, this thermal transfer recording medium has an endless ribbon structure in which a yellow transfer portion, a magenta transfer portion and a cyan transfer portion are sequentially formed in the running direction. This thermal transfer recording medium 1
In No. 01, the dye transport layer is composed of a 100 μm thick methylphenyl silicone resin, and a dye aggregation layer composed of a 2 μm thick silicon-modified polyester resin is in close contact therewith. Incidentally, these dye transport layer and dye aggregation layer,
The dye is held in advance by bringing it into contact with the dye supply body and heating.

202Y, 202M and 202C are shown in FIG.
Similar to the dye supply body 201 shown in (b), a cylindrical dye supply body can be in contact with the thermal transfer recording medium 101. These dye supply bodies 202Y, 202M,
202C is formed of a yellow disperse dye, a magenta disperse dye, and a cyan disperse dye, respectively, to which 10% by weight of dicyclohexyl phthalate is added in order to accelerate molding and dye transport.

In the figure, 7 is an image receiving sheet similar to that of the first embodiment, 8 is a platen roller, and 9 is a heater for supplying dye.

Thermal transfer was performed in the same manner as in Example 1 in such an apparatus. As a result, the optical densities of the obtained image-receiving sheets reached around OD = 2 for each of yellow, magenta and cyan by a Macbeth densitometer.

After the thermal transfer is completed, in order to reproduce the thermal transfer recording medium in which the surface dye concentration is partially lowered, the dye transport layers of the respective colors of the thermal transfer recording medium 101 are provided with the corresponding dye supplying bodies 202Y, 202M and 202C. Sequential contact was made, and heating was performed from the dye aggregation layer side by the dye replenishing heater 9 for 10 to 100 milliseconds depending on the required replenishment amount of the dye. As a result, the dye was diffused from the dye supply bodies 202Y, 202M, and 202C to the dye aggregation layer through the dye transport layer, and the dye concentration of the dye aggregation layer was recovered.

As a result of repeating such thermal transfer and reproduction operations, the dye density on the surface of the thermal transfer recording medium 101 was always kept constant, and the transfer sensitivity did not decrease even after several tens of times of thermal transfer.

Embodiment 3 FIG. 6 is a schematic configuration diagram of an apparatus which performs thermal transfer and reproduction of the thermal transfer recording medium by using a thermal transfer recording medium of a different aspect of the present invention.

In the figure, 10 is an in-line multi-semiconductor laser having an emission wavelength of 780 nm. This semiconductor laser outputs laser light having an intensity and a pulse length according to image information.

Reference numeral 102 denotes the thermal transfer recording medium 10 shown in FIG.
Like No. 0, it is a thermal transfer recording medium in which a dye transport layer and a dye aggregation layer are formed separately from the dye supplier. Similar to the thermal transfer recording medium of Example 2, this thermal transfer recording medium 102 also has an endless ribbon structure, in which a yellow transfer portion, a magenta transfer portion, and a cyan transfer portion are sequentially formed in the running direction. The dye transport layer is made of 100 μm thick methylphenylsilicone resin, and the dye aggregation layer is made of 2 μm thick silicon-modified polyester resin. However, 4% by weight of carbon black was added to the dye aggregation layer as a laser light absorber and a conductive substance for electrical heating, and the dye was appropriately cured with isocyanate. The carbon black in the dye aggregating layer does not come out of the system because the dye aggregating layer is appropriately cured by isocyanate.

202Y, 202M, and 202C are dye supply bodies formed of a yellow disperse dye, a magenta disperse dye, a cyan disperse dye, and 10% by weight of dicyclohexyl phthalate, respectively, as in the second embodiment.

Reference numeral 11 denotes an OHP sheet in which a PET film having a thickness of 200 μm is coated with a polyester-based image receiving layer having a thickness of 5 μm. Reference numeral 12 is a transparent platen roller that transmits laser light, 13 is an electrode for electrically heating the dye aggregation layer, and 8 is a platen roller for a thermal transfer recording medium.

In such an apparatus, thermal transfer was carried out as follows. That is, the thermal transfer recording medium 102 was wound around the platen roller 8, while the OHP sheet 11 with the image receiving layer was wound around the transparent platen roller 12. Then
The thermal transfer recording medium 1 is run while irradiating the inline multi-semiconductor laser 10 from the back side of the OHP sheet 11.
The carbon black in the dye aggregation layer at the yellow transfer portion of No. 02 was heated, and the heat disperses the yellow disperse dye to the image receiving layer of the OHP sheet 11. Thereafter, similarly, the transfer was sequentially performed using the magenta transfer portion and the cyan transfer portion of the thermal transfer recording medium 102. The optical density of the OHP sheet 11 after the transfer reached about OD = 2 for each of yellow, magenta, and cyan by a Macbeth densitometer. Further, no damage due to the heat of the laser beam was observed on the surface of the dye aggregation layer.

After the transfer is completed, in order to reproduce the thermal transfer recording medium 102 in which the surface dye concentration is partially lowered, the dye transport layers of the respective colors of the thermal transfer recording medium 102 are respectively provided with the dye supplying bodies 202Y and 202M of the corresponding colors. 202C were sequentially brought into contact with each other, and the electrode 13 was brought into contact with the conductive dye aggregating layer of the thermal transfer recording medium 102 to carry out electric heating. As a result, the temperature of the thermal transfer recording medium 102 becomes 150 ° C. for a short time, the diffusion coefficient of the dye reaches 5 × 10 ⁻⁶ cm ² / sec, and the dye supply from the dye supplier to the dye transport layer is quickly completed. It was

As a result of repeating such thermal transfer and reproduction operations, the dye density on the surface of the thermal transfer recording medium 102 was always kept constant, and the transfer sensitivity did not decrease even after several tens of times of thermal transfer.

Example 4 FIG. 7 is a schematic block diagram of an apparatus in which a thermal transfer recording medium 302 similar to the thermal transfer recording medium used in Example 1 is used to perform thermal transfer and reproduction of the thermal transfer recording medium. . This apparatus is the same as the apparatus used in Example 1 (FIG. 4) except that the dye replenishing heater 9 is provided so as to heat the thermal transfer recording medium 302 from the dye supply layer side when reproducing the thermal transfer recording medium 302. It has the same device configuration.

Thermal transfer was performed in the same manner as in Example 1 using such an apparatus. As a result, the optical densities of the obtained image receiving sheet 7 reached around OD = 2 for each of yellow, magenta and cyan by a Macbeth densitometer.

Further, after the thermal transfer is completed, the thermal transfer recording medium 302 whose surface dye concentration is partially lowered is reproduced, so that the thermal transfer recording medium 302 is adjusted by the dye replenishing heater 9 from the dye supplying layer side according to the required replenishing amount of the dye. For 10 to 100 milliseconds. As a result, the dye diffused from the dye supplier to the dye aggregation layer via the dye transport layer, and the dye concentration in the dye aggregation layer was recovered.

As a result of repeating such thermal transfer and reproduction operations, the dye concentration on the surface of the thermal transfer recording medium 302 was always kept constant, and the transfer sensitivity did not decrease even after several tens of times of thermal transfer.

Example 5 FIG. 8 is a schematic configuration diagram of an apparatus that performs thermal transfer and reproduction of the thermal transfer recording medium by using the same thermal transfer recording medium 101 as that used in Example 2. . This apparatus has substantially the same apparatus configuration as the apparatus used in Example 2 (FIG. 5), but in this apparatus, the dye supplying body 203 used for reproducing the thermal transfer recording medium 302 is used.
Y, 203M, and 203C are yellow disperse dyes, magenta disperse dyes, and cyan disperse dyes, respectively, in the same manner as the dye supplier used in Example 2, and 10% by weight of dicyclohexyl phthalate for accelerating molding and dye transport. It is added and molded into a cylindrical shape, and a nichrome wire mesh serving as a heat source for dye replenishment is further embedded therein. Therefore, the second embodiment shown in FIG.
Unlike the apparatus used in the above, the dye replenishing heater 9 is not provided.

Thermal transfer was carried out in the same manner as in Example 2 using such an apparatus. As a result, the optical densities of the obtained image receiving sheet 7 reached around OD = 2 for each of yellow, magenta and cyan by a Macbeth densitometer.

Further, after the thermal transfer is completed, in order to reproduce the thermal transfer recording medium 302 in which the surface dye concentration is partially lowered, the thermal transfer recording medium 101 is brought into contact with the yellow dye supplying body 203Y and embedded in the dye supplying body. The nichrome wire mesh was used to electrically heat for 10 to 100 milliseconds. As a result, the dye diffused from the dye supplier 203Y to the dye aggregation layer via the dye transport layer, and the dye concentration in the dye aggregation layer was recovered.
The same operation was performed for the magenta dye supplying body 203M and the cyan dye supplying body 203C.

As a result of repeating such thermal transfer and reproduction operations, the dye concentration on the surface of the thermal transfer recording medium 302 was always kept constant, and the transfer sensitivity did not decrease even after several tens of times of thermal transfer.

Example 6 (Preparation of thermal transfer recording medium) Similar to the thermal transfer recording medium 300 shown in FIG. 3A, this is a thermal transfer recording medium in which the dye transport layer and the dye aggregation layer are integrated with the dye supply layer. And has a structure of an endless ribbon, and the dye 1 of the following formula (Procinyl Scarlet GS)

[0094]

[Chemical 3] And a dye 2 of the following formula (Procinyl
Yellow GS).

[0095]

[Chemical 4] A thermal transfer recording medium having a transfer part made of was prepared.

In this case, the substrate was formed from a PET film having a thickness of 6 μm, the dye supply layer had a thickness of 20 μm, and 10% by weight of dicyclohexyl phthalate was added to each color dye corresponding to the transfer portion of each color. Formed from. The dye transport layer was formed of a 10 μm thick methylphenylsilicone resin that was in close contact with the dye supply layer, and the dye aggregation layer was formed of a 2 μm thick polyvinyl butyral resin that was in close contact with the dye transport layer.

(Preparation of Transferred Material)

[0098]

[Chemical 5] 5g, a polyester resin (manufactured by Toyobo Co., Ltd., Byron 600) and 10g of a 1: 1 mixed solvent of methyl ethyl ketone and toluene are mixed, and this is coated on a polyethylene terephthalate film with a wire bar to form a transfer target. Obtained.

(Reverse Transfer Test) A reverse transfer test was carried out as follows, using the obtained thermal transfer recording medium and the material to be transferred using the apparatus used in Example 1 (FIG. 4).

That is, the transfer portion of the dye 1 of the thermal transfer recording medium is brought into contact with the transferred material to perform thermal transfer, and then the thermal transfer recording medium is moved to bring the transferred portion of the dye 2 into contact with the transferred material to perform thermal transfer. Then, the transferred material was laminated on the mount.
Then, the presence or absence of reverse transfer of dye 1 was examined with respect to the aggregation layer of the transfer portion of dye 2 of the thermal transfer recording medium. As a result, dye 1
Reverse transcription was not observed.

Similarly, as a thermal transfer recording medium, as shown in Table 1.
Prepared by using each of the reactive disperse dyes shown in (1) and prepared by incorporating each active hydrogen compound shown in Table 2 into the image-receiving layer as a transferred material and using them for thermal transfer recording. Then, the presence or absence of reverse transcription at that time was examined. in this case,
Thermal transfer recording was performed for all combinations of reactive disperse dyes and active hydrogen compounds, but no reverse transfer was observed in any of them.

Comparative Example 4 As the dye 1 of the thermal transfer recording medium, the following formula was used.

[0103]

[Chemical 6] Disperse dye of

[0104]

[Chemical 7] A thermal transfer recording medium was prepared in the same manner as in Example 6 except that the disperse dye of Example 1 was used. Further, a transfer target was prepared in the same manner as in Example 6 except that the image receiving layer of the transfer target was formed of a polyester resin (Vylon 600 manufactured by Toyobo Co., Ltd.) without containing an active hydrogen compound. And
Using these, a reverse transcription test was conducted in the same manner as in Example 6.

As a result, in the thermal transfer recording medium after the transfer, the dye 1 transferred first was reversely transferred to the dye aggregation layer of the dye 2 transferred next.

[0106]

When the thermal transfer recording medium of the present invention is used and the reproducing method of the present invention is carried out, the sublimation type thermal transfer recording can be repeatedly used many times. In particular, the dye can be quickly replenished during reproduction, and the quality of the transferred image after reproduction can be improved. Further, according to the thermal transfer recording method of the present invention, it is possible to prevent the reverse transfer of the dye once transferred to the transfer target to the thermal transfer recording medium, so that a color image is recorded when the thermal transfer recording medium is reproduced and repeatedly used. Even in this case, a good image can be obtained.

[Brief description of drawings]

FIG. 1 is a sectional view of a thermal transfer recording medium of the present invention.

FIG. 2 is a cross-sectional view of a dye supplier of the present invention.

FIG. 3 is a cross-sectional view of a thermal transfer recording medium according to a different aspect of the present invention.

FIG. 4 is an apparatus configuration diagram in the case of performing thermal transfer and reproduction using the thermal transfer recording medium of the present invention.

FIG. 5 is an apparatus configuration diagram of a different mode when performing thermal transfer and reproduction using the thermal transfer recording medium of the present invention.

FIG. 6 is an apparatus configuration diagram of a different aspect in the case of performing thermal transfer and reproduction using the thermal transfer recording medium of the present invention.

FIG. 7 is an apparatus configuration diagram of a different mode when performing thermal transfer and reproduction using the thermal transfer recording medium of the present invention.

FIG. 8 is an apparatus configuration diagram of a different aspect in the case of thermally transferring and reproducing using the thermal transfer recording medium of the present invention.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 Dye transport layer 2 Dye aggregation layer 3 Substrate 4 Dye supply layer 5 Substrate 6 Thermal head 7 Image receiving sheet 9 Dye replenishing heater 10 In-line multi-semiconductor laser 11 OHP sheet 13 Electric heating electrode 100, 101, 102 Thermal transfer recording medium 200 , 201, 202Y, 202M, 202C, 20
3Y, 203M, 203C Dye supplier 300, 301, 302 Thermal transfer recording medium

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Koichi Kawasaku 6-735 Kita-Shinagawa, Shinagawa-ku, Tokyo Sony Corporation

Claims (16)

[Claims] 1. A thermal transfer recording medium in which a thermal diffusible dye is transferred onto a transferred body by being superposed on the transferred body and selectively heated, wherein the thermal transfer recording medium comprises a dye transport layer comprising a dye and a first medium. And a dye aggregation layer comprising a dye and a second medium, wherein the first medium of the dye transport layer has a larger diffusion coefficient of the dye than the second medium of the dye aggregation layer and the second medium of the dye aggregation layer. The medium is a thermal transfer recording medium characterized in that the saturated solubility of the dye is larger than that of the first medium of the dye transport layer. 2. The diffusion coefficient of the dye in the dye transport layer is
The thermal transfer recording medium according to claim 1, which is heated to 1 × 10 ⁻⁶ cm ² / sec or more by heating. 3. The thermal transfer recording medium according to claim 1, wherein the saturated solubility of the dye in the dye aggregation layer is 5% by weight or more. 4. The thickness of the dye transport layer is 1 μm or more and 1000.
the thickness of the dye aggregation layer is 0.1 μm or more and 1
The thermal transfer recording medium according to claim 1, which has a thickness of 0 μm or less. 5. The thermal transfer recording medium according to claim 1, wherein the dye transport layer comprises a dye-diffusing resin, a porous substance or a gel-like substance which holds a diffusible dye. 6. A thermal transfer recording medium in which a thermal diffusible dye is transferred to a transferred body by being superposed on the transferred body and selectively heated, wherein the thermal transfer recording medium comprises a substrate, a dye supply layer comprising the dye, a dye and a first layer. The first medium of the dye transport layer comprises a dye transport layer composed of one medium and a dye aggregation layer composed of a dye and a second medium. A thermal transfer recording medium having a large diffusion coefficient, and the second medium of the dye aggregation layer has a larger saturated solubility of the dye than the first medium of the dye transport layer. 7. The diffusion coefficient of the dye in the dye transport layer is
The thermal transfer recording medium according to claim 6, wherein the thermal transfer recording medium is heated to 1 × 10 ⁻⁶ cm ² / sec or more. 8. The thermal transfer recording medium according to claim 6, wherein the saturated solubility of the dye in the dye aggregation layer is 5% by weight or more. 9. The dye transport layer has a thickness of 1 μm or more and 1000.
the thickness of the dye aggregation layer is 0.1 μm or more and 1
The thermal transfer recording medium according to claim 6, which has a thickness of 0 μm or less. 10. The thermal transfer recording medium according to claim 6, wherein the dye transport layer comprises a dye-diffusing resin, a porous substance or a gel-like substance which holds a diffusible dye. 11. A dye supply body comprising a dye is brought into contact with the dye transport layer of the thermal transfer recording medium according to claim 1,
A method for reproducing a thermal transfer recording medium, which comprises heating and diffusing the dye from a dye supplier to a dye transporting layer of the thermal transfer recording medium to replenish it, and diffusing the dye from the dye transporting layer to a dye aggregation layer to replenish it. 12. The thermal transfer recording medium according to claim 6 is heated to diffuse and supply the dye from the dye supply layer to the dye transport layer, and to diffuse and supply the dye from the dye transport layer to the dye aggregation layer. A characteristic method for reproducing a thermal transfer recording medium. 13. A thermal transfer recording medium in which a transfer target and a thermal transfer recording medium are superposed, and a thermal diffusible dye is transferred from the thermal transfer recording medium to the transfer target by selective heating to form an image. The thermal transfer recording medium according to claim 1, wherein the dye comprises a reactive disperse dye, and a transfer target having an image receiving layer containing an active hydrogen compound having a molecular weight of 100 to 1000 is used. Recording method. 14. The thermal transfer recording method according to claim 13, wherein the image receiving layer of the transferred material contains an active hydrogen compound in an amount of 5 to 50% by weight of the image receiving layer. 15. A thermal transfer recording medium in which a transfer target and a thermal transfer recording medium are superposed, and a thermal diffusion recording material is transferred from the thermal transfer recording medium to the transfer target by selective heating to form an image. The thermal transfer recording medium according to claim 6, wherein the dye comprises a reactive disperse dye, and a transfer target having an image receiving layer containing an active hydrogen compound having a molecular weight of 100 to 1000 is used. Recording method. 16. The thermal transfer recording method according to claim 15, wherein the image receiving layer of the transferred material contains an active hydrogen compound in an amount of 5 to 50% by weight of the image receiving layer.