JPH0216714B2 - - Google Patents

Description

[Detailed description of the invention]

INDUSTRIAL APPLICATION FIELD The present invention relates to a method for forming and fixing characters and images on image receiving paper using electrical signals, and is particularly applicable to video printers, facsimile machines, copying machines, etc., and is easy to maintain and operate, and has good storage stability. A color hard copy is available. Conventional configurations and their problems In recent years, with the development of office automation, various terminals have been required. Among these, recording devices that convert electrical signals into visible images, so-called printers, are in great demand, but there are few that are satisfactory in terms of performance. Furthermore, when it comes to color printers, inkjet and electrophotographic methods have been proposed and put into practical use, but since they use liquid or powder such as toner, the maintenance and operability of the equipment is complicated and they are extremely expensive. It was hot. Therefore, in recent years, especially video printers have been used, which use an ink sheet with fixed color ink, and transfer the ink to the receiving paper by thermal melting or transfer using a heat source controlled by an electric signal such as a laser or thermal head. A transfer type thermal recording method has been proposed in which an image is formed by sublimation and transfer. The heat-melt transfer recording method uses an ink sheet in which the coloring material is bound with heat-melting wax, and the coloring material is transferred to the image receiving paper along with the wax melted by a heat source, so it is possible to achieve the halftones necessary for the image quality of the image printer. It was difficult to obtain high-resolution images, and it was also difficult to perform high-resolution transfer. In addition, the sublimation/transfer type uses an ink sheet in which a binder binds disperse dyes that are relatively easy to sublimate as coloring materials, and uses a heat source to sublimate and transfer only the dyes to the receiving paper, resulting in high resolution and high gradation. A transcription is obtained. However, when using sublimable dyes, if a dye with a low sublimation temperature is used, it will lack thermal stability after printing, and if a dye with a high sublimation temperature is used, excessive energy will be required for a heat source such as a thermal head. There were problems such as a heavy load being placed on the heat source or a slow recording printing speed. Such problems can be solved by other recording methods using sublimable dyes,
For example, it was also found in the current transfer method, the discharge transfer method, and the like. OBJECTS OF THE INVENTION The purpose of the present invention is to eliminate the above-mentioned conventional drawbacks, and to provide a fixing method that can obtain high-resolution, high-gradation color images with low energy use and has excellent storage stability. That's true. Structure of the Invention The fixing method of the present invention involves forming a recorded image containing a sublimable dye on the porous layer of an image receiving paper provided with a porous layer on one surface of a support, and dissolving a binder in the porous layer. This is constructed by thermo-compression bonding the image receiving paper at a temperature higher than the point, which allows for low energy and
It enables high-speed, high-resolution, high-gradation, color printing with excellent storage stability. Description of Examples In order to effectively dye the image receiving paper with disperse dye,
It is necessary to provide a resin layer with high dyeing effect on the receiving paper side. Polyester, epoxy, nylon, etc., which are compatible with disperse dyes, are used for the resin layer, and it is known that a certain amount of inorganic pigment is dispersed in order to improve the surface smoothness and whiteness of the image-receiving paper. . However, the sublimation temperature of image-receiving paper with a resin layer that has good dyeability for such disperse dyes
When an image was formed using the inventive disperse dye with a low sublimation temperature of 100°C, it was left in a dryer at 50°C for 30 hours, and the characters were so smeared that they became unrecognizable. However, when the fixing method of the present invention is used to fix an image on image-receiving paper using the above-mentioned disperse dye, the image after being left at 50°C for 100 hours shows no change at all compared to the initial image. Nakatsuta. Embodiments of the present invention will be described below with reference to the drawings. Examples Electrifying transfer recording material in which a energizing layer, a semiconducting layer, and a conductive layer are sequentially laminated (Journal of the Institute of Image Electronics Engineers Vol. 11, No. 1, 3-3)
Magenta disperse dye ink with the following composition was applied to the conductive layer side of was applied to a dry film thickness of 1 μm to form an ink layer containing a sublimable dye, thereby obtaining a four-layered electrical transfer medium. As the image-receiving paper, synthetic paper SE-80 (Nisshinbo Co., Ltd.), which is a polyester sheet with a microporous coating on its surface (see the manufacturing method in Patent No. 956091 and Japanese Patent Publication No. 49-25430), was used. The method for manufacturing SE-80 synthetic paper coated with the microporous layer is to coat the surface of a 50 μm polyester film with
A plasticizer such as dibutyl phthalate is oriented in a dimethylformamide solution of styrene plastic.
A fluid composition in which fine inorganic powders such as titanium oxide and clay were suspended was applied to the polyester film, and then passed through hot water adjusted to 90°C for 10 seconds, and then passed through running water. After, 90℃
A gelled microporous layer with a thickness of 30 μm was formed on the surface layer by drying with hot air. A four-layer electrical transfer medium having an ink layer containing the above-mentioned sublimable dye and a composite paper SE-80 with a microporous coating, which is an image receiving paper, were stacked and set as shown in the figure, and an applied voltage of 30 V was applied. , pulse repetition frequency 1.6kHz, needle diameter
50μm recording needle, running speed 20cm/sec, cotton density 10
The image receiving paper SE-
A clear magenta image was obtained on the microporous layer side of No. 80. The electrical transfer method will be briefly explained based on the drawings. As shown in the figure, the energized transfer medium 104 is placed on the image receiving paper 101.
The microporous layer 103 and the ink layer 105 are brought into contact with each other. Electrode needle 109 conductive layer 1
08, and a voltage is applied from a power source 110 to this electrode needle and the conductive layer 106. As a result, current flows through the current-carrying layer as shown in FIG. 111, and the semi-conductive layer 10
Heat one part of 4 (part 112). Due to this heat, the ink layer 105 containing sublimable dye directly below
The sublimable dye sublimes and adheres to the image receiving paper 101. The image was transferred to plain paper (copy paper) and styrene-based coated paper (OK Coat (Oji Paper)) using the same method, and an image similar to that of the image receiving paper SE-80 was obtained. Further, the film was passed through a heated roll adjusted to 120°C at a speed of 5 seconds/sheet. Three different types of image-receiving paper were prepared, one heat-rolled and one untreated after transfer.
It was left in a dryer at ℃ for 100 hours. The results are shown in the table.

[Table] As is clear from the table, not only was it not possible to obtain clear color development using disperse dyes on plain paper (copy paper), but also satisfactory results were not obtained in terms of storage stability. Also, with regular coated paper, there is no problem with initial color development and resolution, but with regard to storage stability,
It showed discoloration similar to that of plain paper, and the bleeding phenomenon was severe enough to make the printed characters unrecognizable. Synthetic paper coated with a porous layer had the same results as regular coated paper without fixing, but by fixing with a hot roll,
It was found that the storage stability was significantly improved. The cause of this is that the binder that binds the porous layer is heated to a temperature higher than its melting point due to thermocompression bonding using hot rolls, and the surface of the binder becomes molten, crushing the surface layer of the porous layer and fixing the sublimable dye. I think that the. If the thermocompression bonding temperature is too high, the molten binder will adhere to the hot roll, etc., and the surface condition of the receiving paper will deteriorate significantly. Therefore, it is preferable to heat at the lowest temperature at which the binder melts. The results were obtained. In the above example, an electric current transfer method was used as a method for forming an image containing a sublimable dye on the image receiving paper, but the present invention is not limited to the electric current transfer method. Any material may be used as long as it has the function of transferring the coloring material. For example, there are thermal transfer methods using a thermal head, discharge transfer methods in which a mask sheet is prepared using discharge breakdown recording and transfer is performed using a flash of light such as xenon, and electrophotography methods using toners containing sublimable dyes. Can be used.
Furthermore, by using paper or a heat-resistant plastic sheet as the support for the image-receiving paper, the precision of overlaying can be improved and a good color image can be obtained. Effects of the Invention As is clear from the above description, the present invention has a recording image containing a sublimable dye in the porous layer of an image receiving paper provided with a porous layer on one surface of a support, and the porous layer Since the image receiving paper is thermocompression bonded at a temperature higher than the melting point of the binder, even if a thermally unstable sublimable dye with a low sublimation temperature is used, it has excellent storage stability. Images with high resolution and high gradation can be obtained. Furthermore, since the sublimation temperature is low, there is no burden on the heat source for sublimation, making it possible to realize a compact and high-speed recording device. Furthermore, by using paper or a heat-resistant plastic sheet as the support for the image-receiving paper, the dimensional accuracy during thermo-compression bonding is improved and a good color image can be obtained.

[Brief explanation of drawings]

The figure is a diagram showing a transfer method in an embodiment of the present invention. 101... Receiving paper, 102... Support, 103
... Porous layer, 104 ... Current transfer medium, 105
... Ink layer, 106 ... Conductive layer, 107 ... Semiconductive layer, 108 ... Current-carrying layer, 109 ... Electrode needle,
110...Power supply, 113,114...Adhered sublimable dye.

Claims (1)

[Scope of Claims] 1. Forming a recorded image containing a sublimable dye on the porous layer of an image-receiving paper having a porous layer provided on one surface of a support,
thermocompression bonding the image receiving paper at a temperature higher than the melting point of the binder of the porous layer to melt the porous layer;
A fixing method comprising fixing the sublimable dye to the image receiving paper. 2. The fixing method according to claim 1, wherein the support is paper or heat-resistant plastic. 3. The fixing method according to claim 1, wherein a sublimable dye is sublimated by a flash of light to form a recorded image on the porous layer. 4. The fixing method according to claim 1, wherein a recorded image is formed on the porous layer by electrical transfer.