JPH03147884A - Printed matter and recognizing method therefor - Google Patents

Abstract

PURPOSE:To obtain a printing material on which printing unrecognizable by the naked eye can be made by a method wherein an area having characteristics that it cannot be visibly recognized to the naked eye consists of the combination of an area part not containing a transparent, conductive, polymeric material and an area part containing the transparent, conductive, polymeric material, which are visually level with each other. CONSTITUTION:A releasable layer 12 is formed on a substrate 11, and a protective layer 13 is formed on the releasable layer. On the protective layer, a transparent, conductive, polymeric material is applied by printing. Thereafter, on the transparent, conductive, polymeric material, a printing ink layer is provided by printing using an offset printing ink. On the printing ink layer, an adhesive layer 16 is provided to form a transfer sheet. This transfer sheet is lapped over a base sheet or paper, and a pressure is applied on the transfer sheet. The substrate of the transfer sheet is released from the base sheet or paper, whereby a heated and pressurized part of the protective layer and the transparent, conductive, polymeric material is adhesively transferred to the base sheet or paper, and a printed matter is obtained. In addition, the printing information of the transparent, conductive, polymeric material which cannot be recognized by the naked eye is recognized by a surface potential detector. As a result, it can be satisfactorily recognized.

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 reluctance as the scanning head moves across the paper, and special inks such as magnetic or metallic inks can be used to provide such changes. . Furthermore, it is possible to print on the substrate by four-color lithographic printing and use the deposited black ink as an operating variable of the detector. In other words, it is impossible to distinguish with the naked eye the black print area resulting from simultaneous printing of yellow + cyan + magenta and the black print area resulting from printing with black ink. Conventional yellow, cyan, and magenta inks are transparent to infrared rays. Since the carbon black in Lidoblack ink has high infrared absorption, the above two black prints on the infrared reflective paper can be easily distinguished by a red light reflection/absorption detector. A device that performs 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 perceivable display in the device, it can be identified by, for example, billambu or a bright 6F tone.
No. 500147).

As mentioned above, in conventional four-color planographic printing technology,
The black color can be printed 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, it is possible to produce prints that appear the same color to the naked eye, but appear 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
It has visible light responsivity in the range 0-700nm, with a peak response in the range 500-600nm, and semiconductor infrared emitters and detectors typically have a peak spectral sensitivity in the range 800-1000nm. However, at this wavelength, black lithographic ink exhibits absorption properties, 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.

In this case, the display may be a visible or olfactory display.

Low absorption rate in identification - 15 in printed batch on board
%, 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 recall 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, in the conventional technique as described above, since black ink is used, there is a limit to the color of the ink used. In addition, since the operation of controlling the black ink is added, the process becomes difficult. J1).

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 for Solving the Problems] Therefore, in the present invention, by producing a printed matter printed with ink using a transparent conductive polymer material, the printed matter t and Ua, which are normally invisible to the naked eye, can be printed on the surface. As an example of a surface voltage value detector, ammeter, or resistance detector that can be identified by a potential detector, ammeter, or resistance detector, by touching a part of the sensor at the tip to the printed information. Detects surface potential, current, and resistance,
There are some things that are displayed using an audible display.

Printed matter printed with ink using transparent conductive polymer material T4 is made using at least one colored transparent conductive polymer material ink and a normal ink that does not contain a transparent conductive polymer material of the same color. Although the printing method used is the most preferable from the viewpoint of process and cost, multi-layer fM formation is suitable because the ink may cause a decrease in the 4-electroconductivity. for example,()
Transparent 24′irL polymeric material layer/marking ink layer/substrate, 2) Printing ink layer/transparent conductive polymeric material layer/substrate,
The structure is as follows. N? When identifying by detecting R or resistance, it is preferable that the transparent conductive polymer material layer be exposed on the surface, but when identifying by detecting surface potential, this is not necessarily necessary.

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

In this case, the substrate is printed using letterpress printing, offset printing, gravure printing, screen printing, or dye-sublimation heat-sensitive transfer printing, or a combination thereof, and the transparent conductive polymer material 4 is printed on the substrate. Most typically, it has parts printed with ink that does not contain the material, and parts printed with ink that contains the transparent conductive polymer material, and in which case the material does not contain the transparent conductive polymer material. The part printed with the ink and the part printed with the ink containing the transparent conductive polymer material constitute separate layers, and the layer printed with the ink not containing the transparent conductive polymer material and the transparent conductive It is practical to at least partially overlap the layer printed with the ink containing the polymeric material. Then, the layer printed with the ink containing the transparent conductive polymer material is superimposed on the layer printed with the ink not containing the transparent conductive polymer material, or the layer printed with the ink containing the transparent conductive polymer material Preferably, a layer printed with an ink containing no transparent conductive polymer material is superimposed on a layer printed with an ink containing the transparent conductive polymeric material.

A method for identifying such printed matter is to visually identify transparent conductive polymer materials that are the same on the surface by detecting the surface potential, current, or resistance of the printed matter, or two or more of these parameters. A region that does not contain the transparent conductive polymer material and a region that contains the transparent conductive polymer material are distinguished.

[Effect]

An example of a transparent conductive polymer material used in the present invention is a polyacetylene film.

Polyacetylene is a conjugated polymer consisting of C and H, which has the simplest molecular structure among the dehydrated conductive polymers, and there are two types: trans type and trans type. Polyacetylene has various substituents, examples of which are shown in FIG.

Even if the parts printed with ink made of such transparent conductive polymer material or ink containing such transparent conductive polymer material are printed in such a way that they cannot be identified with the naked eye, Even if the layer structure is such that it cannot be distinguished by a layered structure, if a potential is generated on the printed surface by charging, or if a voltage is applied to the back side, for example, the mainstream will pass through, and the resistance will increase in that part. Since it becomes low, it can be identified by detecting its potential, current, and resistance.

[Example] As explained above, the printed matter of the present invention is transparent! Printing is performed using ink made of a conductive polymer material or ink containing such a transparent conductive polymer material. An example of such a transparent conductive polymer material is polyacetylene.

By the way, for printed matter printed with ink using transparent conductive polymer material, printing with colored transparent conductive polymer material ink is most preferable in terms of process and cost, but in order to produce clear colors, printing with colored transparent conductive polymer material ink is most preferable. , a multilayer structure is suitable. An example of such a multilayer configuration is shown in FIG.
A transfer sheet composed of an electrically conductive polymer material printing 71) 4, a printing ink layer 15, and an adhesive [16] is transferred to another substrate 17. Moreover, FIG. 2 is a diagram showing an example in which a transparent conductive polymeric material printing layer is applied on the printing ink layer. A printing ink layer 22 is formed on a substrate 23, and a transparent conductive polymer material printing layer 21 is provided thereon.

Next, as shown in a specific example, a peeling layer made of polymethyl methacrylate was formed to a thickness of 1 μm on a 30 μml polyester film substrate. M.I.
A coating material prepared by dissolving 400 parts of a mixed solvent of BK and toluene is applied to form a protective layer of approximately 1 μm rg-. A transparent conductive polymer material made of trans-type polyacetylene is printed on this protective layer to a thickness of approximately 15 μm, and then printed using offset printing ink on this transparent conductive polymer material layer. An ink layer is formed by printing, and a heat-sensitive adhesive layer made of vinyl chloride-vinyl acetate copolymer is further provided on the printing ink layer to produce a transfer sheet.

This transfer sheet was layered on a 200 μm rtJ vinyl chloride base sheet or paper (70 μm thick), and heated at 135°C for about 0°5 seconds for 3 seconds by applying pressure from above the transfer sheet.
Apply a pressure of ~4 kg/c-. If the substrate of the transfer sheet is peeled off from the base sheet or paper, the heated and pressurized area will be protected. The layer and transparent conductive polymeric material are adhered and transferred onto a base sheet or paper to form a printed matter. Furthermore, as a result of using a surface potential detector to identify the information printed on the transparent conductive polymer material, which cannot be identified with the naked eye, it was revealed that the information could be sufficiently identified.

〔Effect of the invention〕

As described above, according to the present invention, by producing a printed matter using a transparent conductive polymer material, printed information made of the transparent conductive polymer material, which cannot be identified with the naked eye, can be detected by a surface potential detector, It can be identified with a TL flow meter and resistance detector, and can be used as printed matter for counterfeit prevention, educational purposes, and recreational (premium) purposes.

[Brief explanation of the drawing]

Fig. 1 is a diagram for explaining an example of a multilayer structure of the printed matter of the present invention using a transfer sheet, Fig. 2 is a diagram showing another layer structure of a multilayer structure, and Fig. 3 is a diagram of a polyacetylene layer structure. It is a figure for explaining various substitution products. 1): Substrate, 12: Peelable M layer, 13: Protective layer, 14: Transparent conductive polymer material printing layer, 15: Printing ink layer, 16:
Contact layer, 17: Another substrate, 2I: Transparent conductive polymer material printing layer, 22: Printing ink layer, 23: Substrate Applicant: Dai Nippon Printing Co., Ltd.

Claims (6)

[Claims] (1) having a substrate with printed information, the substrate having a region having a property that is visibly indiscernible to the naked eye, the region comprising a transparent conductive polymeric material that is visually identical on its surface; 1. A printed matter comprising a combination of a region containing no transparent conductive polymer material and a region containing a transparent conductive polymer 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 transparent. The printed material has a portion printed with an ink not containing a conductive polymer material and a portion printed with an ink containing a transparent conductive polymer material. (3) In the printed matter according to claim 2, the part printed with the ink not containing the transparent conductive polymer material and the part printed with the ink containing the transparent conductive polymer material constitute separate layers. . The printed material, wherein a layer printed with an ink not containing a transparent conductive polymer material and a layer printed with an ink containing a transparent conductive polymer material overlap at least in part. (4) In the printed matter according to claim 3, a layer printed with an ink containing a transparent conductive polymer material is superimposed on a layer printed with an ink not containing a transparent conductive polymer material. The printed matter is characterized by: (5) In the printed matter according to claim 3, a layer printed with an ink not containing a transparent conductive polymer material is superimposed on a layer printed with an ink containing a transparent conductive polymer material. The printed matter is characterized by: (6) In the method for identifying a printed matter according to any one of claims 1 to 5, by detecting the surface potential, current, or resistance of the printed matter, or two or more parameters thereof, the printed matter can be visually identified. The above-mentioned identification method is characterized in that an area portion not containing a transparent conductive polymer material and an area portion containing a transparent conductive polymer material that are the same on the surface are identified.