JPS63183889A - Accepting sheet for thermal transfer printer - Google Patents

Abstract

PURPOSE:To improve the uniformity of a color recording image in hue and density, by containing at least one pigment-coated layer with predetermined thickness and coating quantity and a sheet-form substrate. CONSTITUTION:In a sublimating thermal transfer accepting sheet, the coating quantity of a pigment-coated layer and the thickness thereof have a significant influence on the manufacture of an accepting sheet in view of a good printing quality and image recording properties and no possibility of heat distortion. Therefore, the coating quantity of pigment is determined to be 30 g/m<2>-80 g/m<2>, and the thickness of the pigment-coated layer is determined to be 30 mum-100 mum. The following is a preferable example of a composition used in the pigment-coated layer: a composition of 100 pts.wt. of a pigment containing 30-100 pts.wt. of a calcined clay, and 10-50 pts.wt. of an adhesive mainly composed of a polymer such as a styrene-butadiene, methyl methacrylate-styrene- butadiene, vinyl acetate, acryl, and starch. As a sheet substrate to form the pigment-coated layer, a paper mainly composed of a wood pulp is preferably used.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a receiving sheet for a thermal transfer printer, particularly for a full-color printer that transfers sharply sublimated ink in a thermal transfer printer using a heat sublimation type ink ribbon. The present invention relates to a receiving sheet capable of printing high-resolution characters and high-fidelity halftone images.

[Prior art and problems to be solved] Recently, the need for color printers has increased, and in particular printers using the dye sublimation thermal transfer method print on a polyester-coated receiving sheet, producing clear color images with a relatively compact device. It has become possible to do this and is attracting attention.

The dye sublimation thermal transfer method is the mainstream for small non-impact printers, and is also often used for small color printers and video printers.

There was a need for a receptor sheet paper that could produce clear images using the sublimation thermal transfer method.

These sublimation thermal transfer printers use an ink sheet consisting of a base material such as film or thin paper and a thermal sublimation dye ink layer. This ink sheet is overlaid with a receiving sheet coated with sublimation dye-dyeable polyester, etc., and the sublimation ink is transferred to the receiving sheet only in required areas by heat from a thermal head, forming an image. however,
In the sublimation type thermal transfer method, the homogeneity and sharpness of the image depend on the uniformity of the base material of the receiving sheet, and the same high level of printed image can be achieved no matter what type of base material the receiving sheet is based on. is not possible.

In a receiving sheet for a sublimation transfer printer, it is known to provide a polyester coating layer on a multilayer synthetic paper made of a mixture of polypropylene and an inorganic pigment in order to obtain good printing.

However, when synthetic paper containing polypropylene as a main component is used, the synthetic paper is thermally deformed by the heat from the print head, causing curls and wrinkles, which significantly deteriorates the quality of the product.

On the other hand, it is difficult to obtain high-resolution characters and images even if a polyester finishing layer is placed on high-quality paper with a high Beck smoothness of 100 seconds or more.A high resolution of 916 bint/wx or higher is required. However, if cellulose fibers are used as the base material, sufficient images cannot be obtained.

An object of the present invention is to provide a receiving sheet that is free from thermal deformation and has good printing and image recording suitability for various thermal transfer printers including those using sublimation ink.

[Means for solving problems]

The present inventors have conducted extensive research into a heat sublimation type thermal transfer receiving sheet that has improved the above-mentioned drawbacks and is capable of stably producing clear recorded images from low density to high density without any density irregularities in the halftone dots. As a result, in the sublimation thermal transfer receiving sheet,
It has been found that in order to provide a receiving sheet that has good printing characteristics 1 and is free from thermal deformation, the coating amount and thickness of the pigment coating layer have a decisive influence.

In other words, the amount of pigment applied is 30 g, 7m” or more, and 80 g.
/m'' or less, and the thickness of the pigment coating layer must be between (to) μm and 100 μm.The type of pigment to be applied and the adhesive used to apply the pigment. has no particularly significant effect on its performance.

Until now, papers coated with pigments on the surface have been known and used for high-grade printing papers, etc., but sublimation transfer is used when the thickness of the pigment coating layer is greater than or equal to 100 μm. It was not yet known that it could be used as a thermal transfer receiving sheet or its base paper to improve transferability. In most ordinary papers, the pigment coating layer has a thickness of 30 g/m or less, and pigment coating layers exceeding 1 μm are rarely seen in general printing paper.

If the amount of pigment coating is less than 30 g/m'', the sharpness, clarity, and uniformity of one image will be poor, and the effect of the pigment coating layer will not be fully demonstrated.If the amount of pigment coating is less than 80 g/m'', .

While the intensity decreases, the effect saturates. The same applies to the thickness of the pigment coating layer; if it is less than 30 μm, a sufficient effect on image sharpness cannot be obtained, and if it is more than 100 μm, the strength will decrease, which is not preferable.

The type of pigment to be applied does not matter. Various known materials can be used. For example, various clays, titanium dioxide, aluminum hydroxide, satin white, talc, calcium sulfite, etc. can be used. In particular, it is preferable to include calcined rays because they are excellent in terms of liquid absorption and homogeneity, and in this case, it is preferable that they are present in an amount of about 30-100% of the pigment components. Particularly preferred are calcined rays with an average particle size of 0.5 to 1.0 μm.

In addition, thermoplastic pigments such as styrene-based copolymers exhibit good properties in terms of uniformity of the coating layer. Plastic pigments have 5-
25 parts by weight, especially 10-. Preferably, it contains 25 parts by weight.

Examples of adhesives used to form the pigment coating layer in the present invention include styrene-butadiene, methyl methacrylate-styrene-butadiene, vinyl acetate, and fc.
3. Copolymer latexes such as acrylic esters can be used alone or in combination.

Preferred compositions of the pigment coating layer include, for example, 100 parts by weight of a pigment containing from 100 parts by weight of calcined resin (9), styrene-butadiene-based, methyl meth, acrylate-styrene-butadiene-based, vinyl acetate-based, or a' Examples include those consisting of 10 to 50 parts of an adhesive whose main component is a polymer such as acrylic or starch.

As the sheet base material on which the pigment coating layer is to be formed, paper whose main component is wood pulp is preferable because it is a thermally stable and inexpensive base material. A sublimation dye-receiving layer or the like containing a polyester resin as a main component can be further provided on the base material as appropriate depending on the needs of the printer system. As a result, it is possible to improve the reproducibility of halftone dots, the hue of overlapping colors, and the reproducibility of density.
Concentration uniformity can be improved.

〔Example〕

Next, the receiving sheet for thermal transfer printers of the present invention will be explained with reference to Examples. Note that parts are parts by weight of solid content.

Example 1 Base paper High quality paper 64 g/m” Kaolin with coating layer (HT clay Engelhardt 7 soil)
50M firing Ray (Ancilex Engelhardt”a) 50 parts SBR latex (JSR069
6 Japan Synthetic Rubber) 20 parts oxidized starch (Oji Ace A
Oji Cornstarch) 5 copies of the above paint on the recording surface 11
c 35 g/m", 20 g/m" coating on the opposite side,
Super calender smoothing treatment. The Bekk smoothness (Ouken method) of the recording surface of the produced paper was 2500 seconds, and the smoothness of the opposite surface was 700 seconds. The thickness of the coating layer on the recording surface was measured from a cross-sectional photograph and was found to be nμm. A receiving paper was prepared by coating the recording surface with a polyester resin (Vylon) at a rate of 5 g/a+.

Example 2 Base paper High-quality paper 64 g/ra" Kaolin with coating layer (UW90 Engelhard) 70 parts Calcined kaolin (Ansilex 93 Engelhard)
) 30 parts acrylic copolymer (Movinyl 963 Hoechst Synthesis) 20 parts polyvinyl alcohol (117K
Japan Synthetic Chemical) 5 parts 50g of the above paint on the recording surface
/m", 20g/rn' was applied to the opposite side and smoothed using a super calender. The resulting paper had a recording surface with a Beck smoothness (Oken type) of 4,500 seconds and an opposite surface with a smoothness of 700 seconds. The thickness of the coating layer (recording surface) was measured from a cross-sectional photograph and was found to be % μm.

5 g of polyester resin (Vylon) on the recording surface, 4'
It was coated to make a receiving paper.

Example 3 Base paper High quality paper 64 g 7 m” Coating layer blended calcium carbonate (N-19 Shiraishi Kogyo)
50 parts kaolin (HT clay Engelhard)
50 parts SBR latex (JSRO696 Japan Synthetic Rubber) 20 parts oxidized starch (Oji Ace A Oji Cornstarch) 5 parts Apply the above paint to the recording surface at 50 g/m
20 g/m was coated on the opposite side of "1" and smoothed using a super calender. The resulting paper had a recording surface smoothness (Ouken style) of 350 seconds and an opposite surface smoothness of 280 seconds. The thickness of the coating layer was measured from a cross-sectional photograph and was found to be 1 μm.

5 g/s of polyester resin (Vylon) on the recording surface
It was coated to make a receiving paper.

Example 4 Base paper High quality paper 64 g/m” Kaolin with coating layer (UW90 Engelhall)'a)
70M.

Silica (Tokusil Tokuyama Soda) 30 parts Acrylic emulsion (Movinyl 952 Hoechst Synthesis) 20 parts Polyvinyl alcohol (117K Nippon Synthesis)
5 parts of the above paint were applied to the recording surface at 50 g/rm'' and the opposite side at 20 g/m', and smoothed using a super calender.

The resulting paper had a recording surface smoothness (Ouken type) of 450 seconds and an opposite surface smoothness of 200 seconds. The thickness of the coating layer was measured from a cross-sectional photograph and was 40 μm.

5 g/m'' of polyester resin (Vylon) on the recording surface
It was coated to make a receiving paper.

Comparative Example 1 Polyester resin (Vylon) was added to the high-quality paper of Example 1 for 5 minutes.
g/m” to prepare a receiving paper.

Comparative Example 2 5g/m of polyester resin (Vylon) on polypropylene synthetic paper (YUBO FPRG80 egg oil synthetic paper)
``It was coated and made into a receiving paper.

Comparative Example 3 Same configuration as Example 1, only recording surface K 15 g/m"
It was coated and smoothed using a super calendar.

The Bekk smoothness of the recording surface of the produced paper was 800 seconds. 5 g/m of polyester resin (Vylon) on the recording surface
``It was coated and made into a receiving paper.

Samples of the above Examples and Comparative Examples were printed using a commercially available dye sublimation type thermal transfer printer, and one image and curl were compared and evaluated. The results are shown in Table 1.

However, ◯ indicates excellent image quality, Δ indicates normal image quality, and X indicates particularly poor image quality.

Table 1□ Example 1 ◎ ○ Q ○Example 2 ・ ○ ○ ○Example 3 0
Δ Δ ○Example 4 0 0 Δ
○Comparative example 1 ○ × X ○Comparative example 2 Q ○ ○ ×Comparative example 3 0
ΔXU Effects of the Invention The thermal transfer receiving sheet of the present invention improves image clarity.

It has excellent gradation and uniformity, making it possible to create compact full-color printers using sublimation transfer methods.

(1 other person)

Claims (1)

[Claims] 1. The thickness is 30 μm or more and 100 μm or less, and the coating amount is 30 μm or more.
A receptor sheet for a thermal transfer printer, comprising at least one pigment coating layer having a pigment coating layer of g/m^3 or more and 80 g/m^3 or less, and a sheet-like base material. 2. The receptor sheet according to claim 1, wherein the pigment coating layer mainly consists of 100 parts by weight of a pigment containing 30-100 parts by weight of calcined clay and 10-50 parts by weight of an adhesive. 3. The receiving sheet according to claim 2, wherein the pigment contains 5 to 25 parts by weight of a particulate polymeric substance. 4. The receiving sheet according to claim 1 or 2, which has a sublimation dye dyed layer containing a polyester resin as a main component. 5. The receiving sheet according to any one of claims 1 to 4, wherein the sheet-like base material is made of paper whose main component is wood pulp.