JPH03114870A - Print and discriminating method thereof - Google Patents

Abstract

PURPOSE:To enable printing incapable of being discriminated by the naked eye even in the printing sections of any color by making a print with an ink composed by a magnetic material. CONSTITUTION:A substrate 11 carrying printing information is provided, where the substrate 11 holds a region having characteristics incapable of being visually discriminated by the naked eye, and the region consists of the combination of a section containing nonmagnetic material and a section containing a magnetic material having same visual appearance. That is, a transfer sheet composed of the substrate 11, a peel ply 12, a printing ink layer 13, a magnetic- material printing layer 14 and an adhesive layer 15 is transferred to another substrate 16. Accordingly, a printed matter employing the magnetic material is manufactured thus allowing identification, by a surface magnetic-field detector, of information printed with the magnetic material incapable of being discriminated by the naked eye, and the printed matter can be applicable on anti-forgery, learning or entertainment (for premium).

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to printed matter having printed information that cannot be discerned with the naked eye, and a method for identifying the same.

[Conventional technology]

A device has been invented that consists of a substrate with printing intelligence. This principle uses, for example, changes in capacitance or magnetic reductance as the scanning head moves across the paper, and special inks such as magnetic or metallic inks can be used to provide such changes. . It is also possible to print on a paper substrate by four-color lithography and use the amount of black ink deposited as an operating variable for the detector. That is, it is impossible to distinguish with the naked eye a black printed area resulting from simultaneous printing of yellow + cyan + magenta and a black printed area resulting from printing with black ink. Conventional yellow, cyan, and magenta inks are infrared transparent, and the carbon black in Lidoblack ink has high infrared absorption, so an infrared reflection/absorption detector can easily distinguish the two black prints on infrared reflective paper. can do. A device for performing such identification includes an infrared emitter designed to emit infrared radiation from the tip and an infrared detector designed to respond to the intensity of reflected infrared radiation at the tip. is commercially available. As a perceptible indication in the device, for example, a lamp or a clear tone can be used to identify the device.
No. 0147).

As mentioned above, in conventional four-color lithographic printing technology,
Black can be printed by using a combination of yellow, cyan, and magenta inks, with virtually no black ink, or by using less color ink and more black ink. With careful control, both can be used to produce prints that appear the same color to the naked eye, but look very different to infrared wavelengths. That is, a printed portion that is identified by infrared absorption can be hidden from the naked eye by the presence of another mark that cannot be identified at non-infrared wavelengths. The reason is that the human eye typically has approximately 38
having visible light responsivity in the range 0-750nm, with a peak response in the range 500-600nm; semiconductor infrared emitters and detectors typically have a peak spectral sensitivity in the range 800-11000n; This is because black lithographic ink exhibits absorption properties at this wavelength, while black colors made of yellow, cyan, and magenta inks are transparent to infrared rays.

As an infrared identification device, for example, an audible display is provided by pressing a pen.

One indication in this case may be a visible or olfactory indication.

Low absorption rate for identification - 15 in the printed patch on boat fishing
%, the audible display shows a low tone, the intermediate absorption rate corresponds to a proportion between 15 and 70%,
The audible display indicates a medium tone, and the high absorption rate corresponds to a proportion of black ink of 70% or more, and the audible display indicates a high tone.

[Problem to be solved by the invention]

However, since the conventional techniques described above use black ink, there are restrictions on the color of the ink that can be used. In addition, since the operation of controlling black ink is added,
The disadvantage is that the process is complicated.

Therefore, an object of the present invention is to solve the problems of the conventional products and provide a printed matter and a method for identifying the printed matter that can print in any color in a printed part that cannot be discerned with the naked eye. shall be.

[Means to solve the problem]

Therefore, in the present invention, by producing printed matter printed with ink using a magnetic material, printed information that cannot normally be identified with the naked eye can be identified with a magnetic detector.

An example of a magnetic detector is one that detects the presence or absence of a magnetic field by contacting a part of the sensor at the tip with printed information and displays it with an audible display, or detects a material magnetized by an electric field and displays it with an audible display. There are things to do.

Printed matter printed with ink using magnetic materials uses at least one color of magnetic material ink, which is colored by mixing magnetic material with ordinary printing ink, and ordinary ink of the same color that does not contain magnetic material. Printing is the most preferable in terms of process and cost, but in order to produce clear colors, 1. , a printed circuit board consisting of a multilayer structure is suitable. For example, 1
) Printing ink layer/magnetic material layer/adhesive layer/substrate, 2) printing ink layer/intermediate layer/magnetic material layer/adhesive layer/substrate, etc.

That is, the printed matter of the present invention has a substrate carrying printed information, the substrate carrying an area having a property that is not visually discernible to the naked eye, said area containing a magnetic material that is visually identical on its surface. It is characterized in that it consists of a combination of a region that does not contain magnetic material and a region that contains magnetic material.

In this case, the substrate is printed using letterpress printing, offset printing, gravure printing, screen printing, or dye sublimation thermal transfer printing, or a combination thereof, and is printed with an ink that does not contain magnetic materials. Most typically, it has a section printed with an ink containing a magnetic material and a section printed with an ink containing a magnetic material, with a section printed with an ink that does not contain a magnetic material and a section printed with an ink containing a magnetic material. The printed portions constitute separate layers, and the layer printed with the ink not containing the magnetic material and the layer printed with the ink containing the magnetic material overlap at least in part. is realistic. Preferably, a layer printed with an ink not containing a magnetic material is superimposed on a layer printed with an ink containing a magnetic material. It is also possible to have an intermediate layer between the magnetic material and the ink-printed layer containing the magnetic material.

A method for identifying such printed matter is to visually distinguish between an area that does not contain polar material and an area that contains polar material that are the same on the surface by detecting the surface magnetic field of the printed material. Make it.

[Effect]

Diamagnetism and paramagnetism are properties universally observed in many materials, but the strength of their magnetization is usually extremely weak.

The magnetic material used in the present invention is ferromagnetism (ferromagnetism, ferrimagnetism), that is, to put it simply, it is a material that has the property of being attached to a magnet and has very strong magnetization.

Even if parts printed with ink using or containing such magnetic materials are printed in such a way that they cannot be identified with the naked eye,
Even if it has a layered structure that cannot be discerned with the naked eye, it can be identified by detecting the magnetic field that is generated on the printed surface.

〔Example〕

As explained above, the printed matter of the present invention is printed with ink made of a magnetic material or ink containing such a magnetic material. Such magnetic materials are ferrimagnetic materials that generate spontaneous magnetism because the magnetic atoms occupy two different positions and their magnetic moments are aligned antiparallel; for example, magnetic tape materials. Some γFeze
s, garnet-type ferrite that is transparent and has spontaneous magnetization)
R3F eso12 (R=rare earth element after Sm or Y), or Fe'+ ion and iron group ion M" (
Spinel type ferrite M Fe 204, which is a composite oxide of M=Mn%Fe, Co, Ni, Cu, etc., is used. Further, Fe, Co, Ni, alloys thereof, etc., which are ferromagnetic materials in which the magnetic moments of magnetic atoms are all aligned in parallel, are used.

By the way, for printed matter printed with ink using magnetic materials, printing with magnetic material ink that is colored by mixing magnetic material with ordinary printing ink is most preferable in terms of process and cost, but it is difficult to produce clear colors. For this purpose, a printed circuit board with a multilayer structure is suitable. An example of such a multilayer structure is shown in FIG. In this example, a transfer sheet composed of a substrate 11, a release layer 12, a printing ink layer 13, a magnetic material printing layer 14, and an adhesive layer 15 is transferred to another substrate 16. Further, FIG. 2 shows a substrate 25 made of plastic or the like and transferred in the same manner as in FIG. 1. In this case, the multilayer structure consists of a printing ink layer and one layer from the surface.
Intermediate layer 2, magnetic material printing layer 3, adhesive layer 4, substrate 2
It differs from the one shown in FIG. 1 in that it is made of aluminum and has an intermediate layer made of aluminum or the like interposed therebetween.

Next, specific examples will be shown. A release layer made of polymethyl methacrylate was formed to a thickness of about 1 μm on a 30 μm thick polyester film substrate, and 150 parts of nitrocellulose, 100 parts of incyanate compound, M
IBK) A coating material prepared by dissolving 400 parts of a luene mixed solvent is applied to form a protective layer with a thickness of about 1 μm. On this protective layer, 20 parts of T-Fe*Os 75B1 vinyl chloride-vinyl acetate copolymer, 5 parts of DOP, 1 part of surfactant,
Approximately 15 μm of magnetic paint made by mixing and dispersing 110 parts of solvent
A transfer sheet is prepared by printing and coating the magnetic layer to a thick layer, and then providing a heat-sensitive adhesive layer made of vinyl chloride-vinyl acetate copolymer on top of this magnetic layer. Transfer this transfer sheet to 200μ
Lay it on a vinyl chloride base sheet of m thickness or paper (70 μm thickness) and press it with a pressure plate from above the transfer sheet for 135 minutes.
A pressure of 3-4 kg/cd is applied for about 0°C for 5 seconds.

When the substrate of the transfer sheet is peeled off from the base sheet or paper, the Mn layer, protective layer, and magnetic layer in the heated and pressurized portions are adhered and transferred onto the base sheet or paper. Patterning is performed on this by gravure printing to produce a printed matter. Furthermore, as a result of identifying this magnetic material printed information that cannot be identified with the naked eye using a surface magnetic field detector,
It became clear that the identification was sufficient.

〔Effect of the invention〕

As described above, according to the present invention, by producing printed matter using a magnetic material, it becomes possible to identify printed information made of magnetic material that cannot be identified with the naked eye using a surface magnetic field detector, thereby preventing counterfeiting. For prevention, learning, and entertainment (
Premium version) Can be used as printed matter.

[Brief explanation of drawings]

FIG. 1 is a diagram for explaining an example of a case where a printed matter of the present invention has a multilayer structure using a transfer sheet, and FIG. 2 is a diagram showing a layer structure of another multilayer structure. 11: Substrate, 12: Release layer, 13: Printing ink layer, 14
: Magnetic material printing layer, 15: Adhesive layer, 16: Another substrate, 2
1: Printing ink layer, 22: Intermediate layer, 23: Magnetic material printing layer, 24: Adhesive layer, 25: Substrate ratio Applicant Dai Nippon Printing Co., Ltd.

Claims (6)

[Claims] (1) having a substrate having printed information, the substrate having a region having a property that is not visually discernible to the naked eye, the region being visually identical to a portion of the region that does not contain magnetic material; A printed matter characterized in that it consists of a combination of regions containing magnetic material. (2) In the printed matter according to claim 1, the substrate is printed using any one or a combination of letterpress printing, offset printing, gravure printing, screen printing, or dye sublimation heat-sensitive transfer printing, and is magnetic. The printed material has a portion printed with an ink containing no material and a portion printed with an ink containing a magnetic material. (3) In the printed matter according to claim 2, the part printed with the ink not containing a magnetic material and the part printed with the ink containing the magnetic material constitute separate layers, and the part printed with the ink not containing the magnetic material constitutes separate layers, and The printed material is characterized in that the printed layer and the layer printed with ink containing a magnetic material overlap at least in part. (4) The printed matter according to claim 3, wherein a layer printed with an ink that does not contain a magnetic material is superimposed on a layer printed with an ink that contains a magnetic material. (5) The printed matter according to claim 4, further comprising an intermediate layer between a layer printed with an ink that does not contain a magnetic material and a layer printed with an ink that contains a magnetic material. (6) In the method for identifying a printed matter according to any one of claims 1 to 5, by detecting a surface magnetic field of the printed matter, visually distinguish between a region portion that does not contain magnetic material and a magnetic material that is the same on the surface. The identification method characterized in that the identification method is characterized in that a region portion including a material is identified.