JPH02175183A - Heat sensitive recording medium - Google Patents

Abstract

PURPOSE:To print a printing part without influence on the color of printing by providing a matlike anchor coating layer on the surface of a magnetic recording layer provided on one side face of a base, and covering it with a thin metal film layer which can be heat sensitive-recorded. CONSTITUTION:This heat sensitive recording medium has a magnetic recording layer 12 provided on one side face of a base 10, a matlike anchor coating layer 14 provided on the other surface, and a thin metal film layer 16 provided thereon. Further, a printing layer 20 is provided thereon through an adhesive layer 18, and a protective layer 22 is provided thereon. The thin metal film 16 is roughed on its surface by the influence of the rough surface state of the primary anchor coating layer 14 to eliminate the glossiness of the surface. Since a light irradiated to the surface of the nonglossy thin metal film 16 is scattered, it does not affect the influence to the printing layer 20 on the thin metal film 16. The surface of the thin metal film 16 is roughed to improve the printing sensitivity of the thin metal film 16. Moreover, since the thin metal film 16 of the part (d1) applied by heat is damaged and the anchor coating layer 14 is exposed, the printing base (D) of the printing surface of the heat sensitive recording medium can be printed.

Description

[Detailed description of the invention] (Industrial application field) The present invention relates to a thermosensitive recording medium.

(Prior Art and its Problems) Conventionally, there are heat-sensitive recording media that use leuco dyes that develop heat-sensitive colors. FIG. 2(a) shows an example of a thermosensitive recording medium using leuco dye. This heat-sensitive recording medium has a heat-sensitive coloring layer 24 containing leuco dye T4 on a substrate lo, a printing layer 20 on the heat-sensitive coloring layer 24, a printing layer 20 on top of that, and then covering the entire surface. A protective layer 22 is provided. When this heat-sensitive recording medium is partially heated, the leuco dye in the heat-applied portion (d2) of the heat-sensitive coloring layer 24 colors and prints, as shown in FIG. 2(b). In this way, Figure 2 (a
) can be used as a prepaid card. However, this thermosensitive recording medium has a drawback in that the leuco dye in the thermosensitive coloring layer 24 deteriorates due to the external environment because the thermosensitive coloring layer 24 is not completely hidden.

There are also heat-sensitive recording media that use metal thin films. FIG. 3(a) shows an example of a heat-sensitive recording medium using a metal thin film. This thermosensitive recording medium has a base 10
A metal thin film 16 is adhered thereon via an adhesive layer 26, and a protective layer 22 is provided on the metal thin film 16. When heat is applied partially to this type of thermosensitive recording medium, as shown in Figure 3 (
As shown in b), the metal thin film 16 in the heated portion (d3) is melted and destroyed, and the adhesive layer 26 is exposed and printed. This type of heat-sensitive recording medium improves the printing sensitivity of the metal thin film, but if the protective layer is made thin, the metal film will corrode and the weather resistance will decrease.If the protective layer is made thicker to improve the weather resistance, There is a drawback that printing sensitivity decreases, causing problems in printing.

Furthermore, there are heat-sensitive recording media that use a metal thin film and print on the metal thin film. However, in this heat-sensitive recording medium, since the metal thin film has gloss, the light reflected by the metal thin film passes through the printing layer from the back side, which affects the color of the print. For this reason, the colors of ink used for printing are limited, and there are restrictions on design. Furthermore, if an attempt is made to thicken the printing layer to hide reflected light so as not to affect printing, the printing sensitivity of the metal thin film will decrease. For this reason, this type of thermosensitive recording medium has the disadvantage that it is not possible to print on printed areas.

The object of the present invention was made in view of the above points, and it is possible to improve the printing sensitivity of metal without thinning the protective layer and the printing layer, and therefore, it is possible to print even on the printed part. An object of the present invention is to provide a heat-sensitive recording medium capable of printing without affecting the color of printing.

(Means for Solving the Problems) The present invention includes a substrate, a magnetic recording layer provided on one surface of the substrate, an anchor coat layer having a matte surface on the magnetic recording layer, and an anchor coat layer having a matte surface on the magnetic recording layer. A heat-sensitive recording medium having a heat-sensitive recordable metal thin film layer on the layer is provided.

(Function) The thermosensitive recording medium of the present invention is provided with an anchor coat layer 14 having a matte surface, and a metal thin film 16 is attached thereon. Therefore, the surface of the metal thin film 16 becomes rough due to the influence of the rough surface condition of the underlying anchor coat layer 14.
As a result, the surface loses its luster. Since the light hitting the surface of the matte metal thin film 16 is scattered,
It does not affect the printing layer 20 above 6. Therefore, the color of the ink used for the printing layer 20 is not limited, and there are no restrictions on the design.

Further, by roughening the surface of the metal thin film 16 with the anchor coat layer 14, the printing sensitivity of the metal thin film 16 is improved.

That is, the metal particles of the metal thin film ball up due to the heat, melt, flow into the four parts of the anchor coat layer 14, and expose the base material. Therefore, protective layer 2
Heat can be sufficiently applied to the metal thin film 16 without making the printed layer 2 and the printed layer 20 thin. Therefore, Fig. 1 (
As shown in b), the metal thin film 16 in the heated portion (dl) is destroyed and the anchor coat layer 14 is exposed. As a result, the printing space (D
) can also be printed.

(Example) Hereinafter, the thermosensitive recording medium of the present invention will be explained with reference to the drawings.

As shown in FIG. 1(a), the thermosensitive recording medium of the present invention is
A magnetic recording layer 12 is provided on one surface of the base 10 . Base 1
Anchor coat layer 14 with a matte surface on the other side of 0
is provided, and a metal thin film layer 16 is provided thereon. Furthermore, a printing layer 20 is provided thereon via an adhesive layer 18, and a protective layer 22 is provided thereon.

Here, the substrate 10 may be any material as long as it has the strength necessary for use as a heat-sensitive recording medium. Further, when printing on the printing surface, the anchor coat layer 14 is provided on one surface of the substrate, and the magnetic recording layer 12 is provided on the other surface of the substrate 10. In addition, when printing on the back side of the mark -1 side, as shown in FIG. 1(c), a magnetic recording layer 12 is provided on the base 10, and an anchor coat layer 14 is provided thereon. Furthermore, the base body 10 may also serve as the magnetic recording layer 12 by using a magnetic material.

Further, for the magnetic recording layer 12, an ordinary magnetic material that can be recorded or read by a magnetic head is used.

Further, the anchor coat layer 14 is an adhesive containing a matting agent that makes the surface of the adhesive matte after hardening. This anchor coat layer 14 is for suppressing or eliminating the gloss of the metal thin film 16 coated on this anchor coat layer 14. The rougher the surface of the anchor coat layer 14, the more the gloss of the metal thin film 16 can be suppressed, but if it is too rough, it will affect the adhesion of the metal thin film 116, so the surface roughness should be in the range of about 1 to 10 μm. It is desirable that An extender pigment is used as the matting agent contained in the adhesive of the anchor coat layer. Examples of such extender pigments include calcium carbonate, barium sulfate, silica, alumina, and clay. The content of the matting agent is determined to be an amount that sufficiently suppresses the gloss of the metal thin film 16 deposited on the anchor coat layer 14, that is, an amount that makes the surface roughness of the anchor coat layer 14 within the range of about 1 to 10 μm. desirable. Here, it is possible to make the base 10 matte without providing the anchor coat layer 14, but since the surface of the magnetic recording layer 12 on the base 10 also becomes rough along the base 10, the magnetic properties will deteriorate. Therefore, the gloss of the metal thin film 16 must be suppressed not by the substrate but by the anchor coat layer 14. Furthermore, the adhesive used for the anchor coat layer 14 may contain ink in addition to the constitutional type U to color the anchor coat layer 14. Such inks include polyester-based inks,
Vinyl-based 5, urethane-based, salt-and-acetate vinyl-based, acrylic polyol-based, salt-and-acetate-vinyl-acrylic-based, Shorikimen-polyester-based, and Shorikimen-acrylic polyol-based 1
Liquid types and two-liquid types in which they are mixed with isocyanate are used.

Furthermore, the metal used for the metal thin film 16 is one that can be easily melted and destroyed by a heat source such as infrared rays. For example, such metals include Cu, Fe5Ga, Ge, Hgs
In1 Li, Mg, Mn.

Mo, Nb, Ni, Os, Pb, Pa, Pt.

Rn, SbS Ses S is Sn, Ta, Te1
Examples include Th, Ti, USVSW, Zn, Zr, compounds thereof, and alloys thereof.

Although the thickness of the metal thin film 16 is not particularly determined, it is set to a thickness that can be easily destroyed by a heat source.

Further, the adhesive used for the anchor coat layer 14 and the adhesive between the metal thin film 16 and the printing layer 20 must be one that does not corrode the metal thin film 16 on which the metal is deposited.

Further, for the printing layer 20, paints, inks, etc. that can be used in normal printing processes can be used.

Further, the protective layer 22 may be made of any material and have any thickness that can protect the metal thin film 16 under normal usage conditions.

A printing test was conducted on the heat-sensitive recording medium thus prepared. In the printing test, the printing energy was 0.5W/
The printing was carried out under printing conditions of dot and dot pitch of 6 lines/-11 lines, and evaluation was made by visual observation of the printing condition of continuous printing and printing in units of dots.

As a result, the thermal recording medium of the example of the present invention was printed by both continuous printing and dot unit printing.

Moreover, the hue of the non-printed area becomes white due to the scattering of light by the anchor coat layer, giving contrast and making the print very easy to see.

(Effects of the Invention) As explained above, the heat-sensitive recording medium of the present invention improves the printing sensitivity of metal without thinning the retaining layer and the printing layer by providing the anchor coat layer with a matte surface. It exhibits the excellent effect of being able to print on the print surface without affecting the color of the print.

Furthermore, improved printing sensitivity enables high-speed printing and also helps extend the life of the thermal head.

[Brief explanation of the drawing]

FIG. 1(a) is a cross-sectional view of a thermosensitive recording medium according to an embodiment of the present invention before heat is applied, and FIG. 1(b) is a cross-sectional view of a thermosensitive recording medium according to an embodiment of the present invention before heat is applied. Later sectional view, Figure 1 (c
) is a cross-sectional view of a heat-sensitive recording medium according to another embodiment of the present invention before heat is applied, and FIGS. 2(a) and 3(a) are cross-sections of a conventional heat-sensitive recording medium before heat is applied. 2(b) and 3(b) are cross-sectional views of a conventional thermosensitive recording medium after being heated. DESCRIPTION OF SYMBOLS 10... Substrate, 12... Magnetic recording layer, 14... Anchor coat layer, 16... Metal thin film, 18.26...
・Young agent layer, 20... Printing layer, 22... Protective layer, 2
4...Thermosensitive coloring layer. Figure (a) Figure (b) Figure (C) Figure (a) Figure (b) Figure (a) Figure (b)

Claims (1)

[Claims] a base; a magnetic recording layer provided on one surface of the base;
A heat-sensitive recording medium comprising: an anchor coat layer having a matte surface on the magnetic recording layer; and a heat-recordable metal thin film layer deposited on the anchor coat layer.