JP3192847U - Structure of thermal transfer recording sheet - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a structure of a thermal transfer recording sheet which prevents a base material from excessively absorbing a thermal transfer ink and can obtain excellent saturation and gradation. A thermal transfer recording sheet includes a base material 120 and a coating layer 140 having permeation holes 142 installed in the base material. The coating layer contains a coating solution having a mixed composition of an inorganic pigment, a starch derivative, a silicon compound, a cellulose derivative, and a polymer resin. After the solution is applied and dried, permeation pores are formed in the gaps between the granules between the inorganic pigments in the coating layer. The permeation holes limit a part of the heat-sensitive transfer ink 160 that permeates the coating layer and the base material, and the adhesive force of the ink is enhanced. In addition, while maintaining the drying speed of the ink, it is possible to avoid a situation in which the ink to be transferred is insufficient. [Selection diagram] Fig. 3

Description

  The present invention relates to the structure of a thermal transfer recording sheet on which thermal transfer ink is installed.

  As a conventional method for setting a pattern on a textile product, techniques such as halftone printing, dyeing and finishing, and spray coating are commonly used.

  However, in the conventional printing technique described above, the halftone printing method is first performed by plate making, but the printing speed is slow, the halftone expression is poor in color, the textile pattern becomes hard, and immediately after washing with water. Decolorized. Dye finish processing is suitable for orders for large quantities of dyeing, but can only be dyed with a single color, so in recent years, as products have become more individualized, it has been required to efficiently produce a variety of products in small quantities. As a result, dyeing finishing has been stagnant. In addition, plate making is not necessary for spray coating, but the coating layer on the surface of the base material must first be processed and the pattern must be spray-coated on the base material. The work process is complicated and equipment and manufacturing costs are high. .

  In the industry, thermal transfer technology was proposed to improve the above-mentioned disadvantages of the construction method, maintain the original flexibility of the base material (clothing), increase the gradation expression of the color of the pattern, and prevent the pattern from decoloring. . In the conventional thermal transfer, a dye (ink) having thermal characteristics is heated to 200 degrees Celsius to change the dye (ink) from solid to gas. When the vaporized dye (ink) penetrates into the substrate or the fiber of the transferred material and the temperature is lowered, the dye (ink) returns to the original solid and a pattern is formed.

  In addition, thermal transfer dyes (inks) have the advantages of penetrating into the fibers, no stickiness, and excellent breathability of the fabric, being strong against washing, hard to decolorize, difficult to lose color, saturation and vividness Is effectively retained, and details such as gradation and shadow are expressed. Thermal transfer technology is universally applied to printing patterns on clothing substrates.

  As shown in FIGS. 4 and 5, the thermal transfer technology is implemented in a manner that a thermal transfer ink 922 is provided with a pre-designed pattern 920 on a substrate 940 except that it is directly output by an instrument. It is widespread, provides users with various options for personalization at a low price, has a DIY preference, and allows manufacturers to manufacture a wide variety of products at low speeds. However, when the thermal transfer ink 922 is installed on the base material 940, it is easily absorbed by the base material 940, and when the user transfers the pattern 920 of the base material 940 to the base material (not shown), the thermal transfer is performed. Since the ink 922 was excessively absorbed, the thermal transfer ink 922 transferred was insufficient, and the color of the pattern 920 did not become as expected.

  Therefore, the present inventor is considered to be able to improve the above-mentioned drawbacks, and as a result of intensive studies, the inventors have arrived at the proposal of the structure of the thermal transfer recording sheet of the present invention that effectively improves the above-mentioned problems by rational design. It was.

  The present invention has been made in view of such conventional problems. The main object of the present invention is to provide a structure of a thermal transfer recording sheet in order to solve the above-mentioned problems. That is, when the thermal transfer ink is installed on the substrate, it prevents the substrate from excessively absorbing the thermal transfer ink, and when transferring the thermal transfer ink, the thermal transfer ink is insufficient and the saturation and gradation are excellent. Improve the shortcomings such as not.

  In order to solve the above-described problems and achieve the object, the structure of the thermal transfer recording sheet according to the present invention includes a base material and a coating layer that is installed on the base material and has a plurality of penetration holes. It is characterized by.

  In other words, due to the configuration of the above structure, when the thermal transfer ink carrier is used, a part of the thermal transfer ink that permeates the coating layer and the substrate is limited by the permeation holes, and the adhesion of the thermal transfer ink is enhanced. In the conventional thermal transfer ink, the thermal transfer ink is excessively absorbed by the base material when it is directly installed on the base material while the thermal transfer ink is dried. To solve the disadvantages such as lack of color shade of the product.

  According to the present invention, the prior art improves the disadvantages such as inferior saturation and gradation due to the lack of thermal transfer ink.

It is a cross-sectional schematic diagram explaining the structure of the thermal transfer recording sheet which concerns on 1st embodiment of this invention. It is a cross-sectional schematic diagram explaining the structure of the thermal transfer recording sheet which concerns on 1st embodiment of this invention. It is a partial schematic cross-sectional view for explaining the structure of the thermal transfer recording sheet according to the first embodiment of the present invention. It is the schematic of the inclination which shows the structure of the conventional thermal transfer recording sheet. It is a partial schematic cross-sectional view showing the structure of a conventional thermal transfer recording sheet.

Preferred embodiments of the invention will be described with reference to the accompanying drawings. The embodiment described below does not limit the contents of the present invention described in the claims of the utility model registration. In addition, all the configurations described below are not necessarily essential requirements of the present invention.
<First embodiment>

  Hereinafter, the first embodiment will be described with reference to FIGS. The structure of the thermal transfer recording sheet of the present invention includes a base material 120 and a coating layer 140 having a permeation hole 142 installed in the base material 120. Thus, when the thermal transfer ink 160 is installed as a carrier of the above-described structure, only a part of the thermal transfer ink 160 is permeated into the coating layer 140 along the permeation holes 142, and the thermal transfer ink 160 is attached. In addition to enhancing the adhesion, when the conventional thermal transfer ink 160 is installed on the base material 120 while maintaining the drying speed of the thermal transfer ink 160, the thermal transfer ink 160 is excessively absorbed by the base material 120. This solves the shortcomings such as insufficient thermal transfer ink 160 to be transferred and insufficient shade of color of the finished product.

  The coating layer 140 includes a coating solution having a mixed structure of an inorganic pigment, a starch derivative, a silicon compound, a cellulose derivative, and a polymer resin. Due to the particle size of the inorganic pigment, after the solution is applied to the substrate 120 and dried, the permeation holes 142 are formed in the gaps between the inorganic pigments of the coating layer 140, and a part of the thermal transfer ink 160 is formed. It penetrates into the penetration hole. In practice, the inorganic pigment is selected from any one of barium sulfate, potato powder, kaolin, chaco, or zinc pigment, or a combination thereof.

  The starch derivative is selected from powdery derivatives, enzyme-modified starch derivatives, and chemically-modified starch derivatives. The above-mentioned silicon compound is selected from any one of kaolin, mica, bentonite, and copiapolite, or a combination thereof.

  The cellulose derivative is selected from any one of nitrocellulose, acetylcellulose, methylcellulose, carboxymethylcellulose, and ethylcellulose, or a combination thereof.

  Further, the above-mentioned polymer resins are alkyd resins, unsaturated resins, epoxy resins (Epoxy Resins, EP), silicon resins (Silicone Resins, SI), diallyl phthalate resins (Diallyl Phthalate Resins, DAP), Polyvinyl Chloride, H (CH2CHCl) Nh, PVC), polyvinyl alcohol (Polyvinyl Alcohol H [CH2CH (OH)] nH, PVA), polystyrene (Polystyrene, H [CH (C6H5) CH2)] nH, PS), polypropylene (PolyPropylence H [CH (CH3) CH2)] nH, PP), acrylic resin (Acrylic Resins), ABS (Acrylonitrile-butadiene-Styrene, ABS), polyvinyl acetate (Polyvinyl Acetate, PVAC), and polyamide It is selected from any one of (Polyamide, PA) or a combination thereof.

  As described above, following the description of each member of the structure of the thermal transfer recording sheet according to the first preferred embodiment of the present invention, the installation method and the features of use of the present invention will be described below. First, the coating layer 140 is installed on the substrate 120. The installation method is previously formed by applying a mixed solution of inorganic pigment, starch derivative, silicon compound, cellulose derivative and polymer resin in an amount of about 0.1 to 30 μm per square meter and evenly applied to the substrate 120. Is done. The user uses the printing facility to print the thermal transfer ink 160 on the coating layer 140 as a predesigned pattern or character, and a part of the thermal transfer ink 160 passes through the permeation hole 142 of the coating layer 140. Then, the thermal transfer paper having a pattern is formed after being penetrated into the substrate 120 and drying the thermal transfer ink 160 (not shown).

  Thus, when the user transfers the pattern formed of the thermal transfer ink 160 to a predetermined substrate (for example, a textile, not shown), the user sets the thermal transfer paper having the pattern at a predetermined position on the substrate, Heating is performed at about 200 degrees Celsius by a heating facility (not shown), and the thermal transfer ink 160 of the coating layer 140 is gasified and fitted into the surface of the substrate. When removed from the heating facility and cooled, the thermal transfer ink 160 changes from gas to solid and binds to the substrate.

  In the structure of the thermal transfer recording sheet of the present invention, when the thermal transfer ink 160 is installed in the coating layer 140, only a part of the thermal transfer ink 160 is permeated into the coating layer 140 and the substrate 120 through the penetration holes 142. The thermal transfer ink 160 is prevented from being excessively absorbed by the substrate 120, and the thermal transfer ink 160 is sufficiently retained on the other surface of the coating layer 140 with respect to the substrate 120. Even after the thermal transfer ink 160 is heated, it has a sufficient amount of the thermal transfer ink 160 and is coated on the surface of the substrate to ensure the saturation of the finished pattern of the thermal transfer ink 160.

  Note that the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the scope of the present invention.

DESCRIPTION OF SYMBOLS 120 Base material 140 Coating layer 142 Penetration hole 160 Thermal transfer ink 920 Pattern 922 Thermal transfer ink 940 Base material

Claims (7)

In the structure of the thermal transfer recording sheet,
A structure of a heat-sensitive transfer recording sheet, comprising a coating layer provided on the substrate and having a plurality of permeation holes.   2. The structure of a thermal transfer recording sheet according to claim 1, wherein the coating layer includes a mixed structure of calcium carbonate, starch derivative, silicon compound, cellulose derivative, and polymer resin.   2. The structure of a thermal transfer recording sheet according to claim 1, wherein the coating layer includes a mixed structure of barium sulfate, starch derivative, silicon compound, cellulose derivative, and polymer resin.   2. The structure of a thermal transfer recording sheet according to claim 1, wherein the coating layer includes a mixed structure of potato powder, starch derivative, silicon compound, cellulose derivative, and polymer resin.   2. The structure of a thermal transfer recording sheet according to claim 1, wherein the coating layer includes a mixed structure of a zinc pigment, a starch derivative, a silicon compound, a cellulose derivative, and a polymer resin.   2. The structure of a thermal transfer recording sheet according to claim 1, wherein the coating layer includes a mixed structure of an inorganic pigment, a starch derivative, a silicon compound, a cellulose derivative, and a polymer resin.   The silicon compound is selected from any one of kaolin, mica, bentonite, and copiapolite, or a combination thereof, according to any one of claims 2 to 6. The structure of a thermal transfer recording sheet as described in 1.