JP2007261112A - Forgery preventive printed matter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a forgery preventive printed matter which does not leave any trace on which a security measure is devised, and has no possibility of increasing a cost on printing. <P>SOLUTION: This forgery preventive printed matter 10 has a substrate 11 and a colored pattern printing layer 12 provided on the substrate 11. The colored pattern printing layer 12 comprises an infrared ray-excited visible light fluorescent light emitting material which visually emits fluorescent light excited by infrared rays, and a light transmitting colored material which transmits infrared rays and a fluorescent light emitting visible light at a specified ratio. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a forgery-preventing printed matter having security.

Patent Document 1 discloses a latent image forming member that conceals an invisible infrared-excited fluorescent light-emitting printed pattern with two or more colors of ink so that the presence of the infrared fluorescent printed pattern cannot be visually recognized.
If you print with multiple inks on the infrared fluorescent print pattern, the presence of the infrared fluorescent print pattern will gradually become difficult to see, but no matter how many colors you add, you can see its existence by looking closely. . In addition, as the number of colors increases, the fluorescence emission brightness of the infrared fluorescent printing pattern and the reading rate of the authenticity determination machine decrease and the number of printing steps increases, which may lead to an increase in printing costs. .
JP-A-6-234289

  The subject of this invention is providing the forgery prevention printed matter which does not leave the trace which took the security measure, and does not raise the cost of printing.

The present invention solves the above problems by the following means. In addition, in order to make an understanding easy, although the code | symbol corresponding to the Example of this invention is attached | subjected and demonstrated, it is not limited to this.
Invention of Claim 1 is a forgery prevention printed matter which has a base material (11) and the colored pattern printing layer (12) provided on the said base material (11), Comprising: The said colored pattern printing layer (12) Is an anti-counterfeit printed matter characterized in that it contains an invisible security material that reacts to infrared rays and / or ultraviolet rays.
A second aspect of the present invention is the anti-counterfeit printed matter according to the first aspect, wherein the security material is a material that reacts with infrared rays.
According to a third aspect of the present invention, in the anti-counterfeit printed matter according to the first or second aspect, the security material is an infrared-excited visible-light-fluorescent material that is excited by infrared rays and fluoresces in a visible manner. It is a forgery-proof printed matter.
According to a fourth aspect of the present invention, in the forgery-preventing printed matter according to any one of the first to third aspects, the colored pattern print layer (12) transmits visible light that emits infrared light and / or fluorescence. It is a forgery-preventing printed matter characterized by containing a transparent colored material.
The invention according to claim 5 is the anti-counterfeit printed matter according to any one of claims 1 to 4, wherein the colored pattern printing layer (12) is a first colored ink layer mixed with the security material. (A1, A3, A5) and the second colored ink layer (A2, A4) that is substantially the same color as the first colored ink layer (A1, A3, A5) and does not contain the security material A forgery-preventing printed matter characterized in that a print pattern is formed by a combination of
According to a sixth aspect of the present invention, in the forgery-preventing printed matter according to any one of the first to fourth aspects, the colored pattern print layer (12-2, 12-4) is a machine-readable code. It is a forgery-proof printed matter characterized by being.
The invention of claim 7 is the anti-counterfeit printed matter according to claim 6, wherein the machine-readable code (12-4) includes the first colored ink layer (B1, B3) mixed with the security material; Two kinds of code patterns are formed by combination with the second colored ink layer (B2, B4) which is substantially the same color as the first colored ink layer (B1, B3) and does not contain the security material. It is a forgery-proof printed matter characterized by that.
The invention of claim 8 is the anti-counterfeit printed matter according to any one of claims 1 to 7, wherein the base material (11) is a heat-sensitive self-coloring base material that self-colors by heat. It is a forgery-proof printed matter characterized by.
The invention of claim 9 is the anti-counterfeit printed matter according to claim 8, wherein the colored pattern printing layer (12) is provided on a surface opposite to the heat-sensitive surface of the heat-sensitive self-coloring substrate. It is a forgery-proof printed matter.
According to a tenth aspect of the present invention, in the anti-counterfeit printed matter according to the ninth aspect, the colored pattern printed layer (12) provided on the surface opposite to the heat-sensitive surface is a machine-readable code, and The counterfeit-preventing printed matter is characterized in that the surface is provided with related information associated with the machine-readable code information.

The present invention has the following effects.
(1) By including an invisible security material in the visible colored pattern printing layer, the presence of security can be concealed, and thus a printed matter with excellent anti-counterfeiting properties can be provided. In addition, since the pattern printing layer is colored, management of printing density and printing accuracy can be performed at the manufacturing site in the same manner as conventional printing ink, and printing cost is not increased.
(2) Since the security material is an infrared reaction type, the light source of the authenticity determination device can be an LED or the like, and the cost of the authenticity determination device can be reduced compared to the ultraviolet reaction type.
(3) By making the security material fluorescent, the authenticity can be determined more easily than the absorption type, and the security can be improved.
(4) By including a transparent colored material that transmits visible light that emits infrared rays and / or fluorescent light in the colored pattern printing layer, even if the transparent colored material is mixed in the printing ink, the light source of the authenticity determination machine Since visible light that emits infrared rays and / or fluorescent light is not absorbed, it is possible to prevent a decrease in light emission luminance and light emission efficiency.
(5) By combining the colored ink layer mixed with security material and the colored ink layer of the same color not mixed with security material to form a print pattern, it becomes difficult to realize the presence or absence of security, and the anti-counterfeit effect It can be improved further.
(6) By making the colored pattern printing layer a machine-readable code, it is possible not only to perform authenticity determination based on the presence or absence of security material but also to include information such as a product code. In addition, the security and reliability of the code can be improved.
(7) By combining the colored ink layer mixed with the security material and the colored ink layer of the same color not mixed with the security material to form two types of code patterns, from a portion that appears to be one code at a glance Two kinds of code patterns can be read, and the security can be improved.

  The object of the present invention is to provide an anti-counterfeit printed matter that does not leave a trace of security measures and does not increase the cost of printing. This is realized by including the material to be used.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the drawings.
1A and 1B are diagrams showing Example 1 of a forgery-preventing printed material according to the present invention, in which FIG. 1A is a plan view and FIG. 1B is a cross-sectional view along line BB.
The anti-counterfeit printed matter 10 of Example 1 is an example of a gift certificate, and includes a base material 11 having a display unit 11a such as “gift certificate”, “¥ 1000”, and “ABC Corporation”, an offset, a gravure, and a screen. And a colored pattern printing layer 12 provided on the substrate 11 by a printing method such as thermal transfer or letterpress.
The colored pattern printing layer 12 contains an invisible security material (security ink) that reacts with infrared light and a transparent colored material that transmits visible light that emits infrared light and fluorescence.
The security material is an infrared-excited visible light fluorescent material that is excited by infrared rays and fluoresces in a visible manner. The security material may be an infrared excited infrared fluorescent material, an infrared absorbing material, or the like.

Here, the various materials described above will be described in detail.
(Infrared excited visible fluorescent material, Infrared excited infrared fluorescent material)
Examples of the fluorescent color former include an infrared light emitting fluorescent agent and an ultraviolet light emitting fluorescent agent. Infrared light-emitting fluorescent agents include infrared-visible conversion fluorescent agents that are excited by infrared light and emit visible light, and those that are excited by infrared light (800 nm) and emit light at longer wavelengths (980 to 1020 nm). .
The former infrared-visible conversion fluorescent agent is a phosphor having a very special excitation mechanism, and excites visible light emission by using a plurality of infrared photons with low energy. There are two types of infrared-visible conversion fluorescent agents, one of which can be highly excited by multi-stage excitation in the activator ion and the other by multiple resonance energy transfer from the sensitizer. become. The former type is observed in many host crystals with Er3 + or Ho3 + as an activator, and the latter type is a sensitizer Yb3 + that absorbs infrared rays, and multistage energy transfer causes Er3 +, Tm3 +, For example, HoF3: Yb + Er, YF3: Yb + Tm, BaFCl: Yb + Er, etc. can be used. In addition, although the fluorescent agent is usually expressed by its composition, here, it is divided into a base crystal which is a main component and an activator or a luminescent center dispersed therein, and is shown by a formula connected by (:). . For example, ZnS: Mn indicates that the base crystal is ZnS and the activator is Mn.
Examples of the latter that excites with infrared light (800 nm) and emits light at longer wavelengths (980 to 1020 nm) include, for example, LiNd0.9 Yb0.1 P4 O12, LiBi0.2 Nd0.7 Yb0.1 P4. O12, Nd0.9 Yb0.1 Nd5 (MoO4) 4, NaNd0.9 Yb0.1 P4 O12, Nd0.8 Yb0.2 Na5 (WO4) 4, Nd0.8 Yb0.2 Na5 (Mo0.5 W0.5 O4 ) 4, Ce0.05Gd0.05Nd0.75Yb0.15Na5 (W0.7 Mo0.3 O4) 4, Nd0.9 Yb0.1 Al3 (BO3) 4, Nd0.9 Yb0.1 Al2.7 Cr0.3 (BO3) 4 Nd0.6 Yb0.4 P5 O14, Nd0.8 Yb0.2 K3 (PO4) 2 etc. can be used.

(Infrared absorbing material)
The infrared absorbing material is a substance that absorbs infrared rays, and can be roughly classified into infrared absorbing pigments and infrared absorbing dyes. It can be broadly divided into colorless infrared absorbing pigments that absorb little or no visible light and colored infrared absorbing pigments that have a certain absorption band in the visible region, but the colorless ones are expensive. In order to reduce the manufacturing cost, it is preferable to use a colored infrared absorbing pigment because the concealability of an image pattern formed by infrared absorption is excellent even for colored ones.
As the infrared absorbing pigment, transition metal compounds such as iron, copper, chromium, cobalt, nickel, and complexes can be used. For example, a milory blue pigment that is an iron complex (iron ferricyanide complex) is preferably used. . Moreover, in addition to using said compound independently, 2 or more types can also be mixed and used.
Further, as the infrared absorbing dye, a dye such as polymethine (cyanine dye), phthalocyanine, naphthoquinone, anthraquinone, dithiol, or triphenylmethane can be used.
In terms of light resistance (fading to infrared rays) and the like, infrared absorbing pigments are superior to infrared absorbing dyes, and it is preferable to use inorganic substances such as the above-mentioned metal pigments.

(Transparent colored material)
On the other hand, the transparent colored material is, for example, an infrared transparent colored ink. Specific examples of the infrared transparent pigment used in the infrared transparent colored ink are listed below. As the pigment, it is sufficient that there is no absorption band in the infrared region, and normal process inks such as cyan, magenta, yellow, and black can be used. In the following specific examples, parentheses after the pigment name are C.I. I. The classification of Pigment (Color Index Pigment) is shown.
Among the above infrared transmissive coloring pigments, as yellow pigments, for example, the following can be used. Fast Yellow G (Yellow-1), Fast Yellow 10G (Yellow-3), Disazo Yellow AAA (Yellow-12), Disazo Yellow AAMX (Yellow-13), Disazo Yellow AAOT (Yellow-14), Disazo Yellow AAAA (Yellow) -17), Disazo Yellow HR (Yellow-83).
Among the above infrared transmitting colored pigments, for example, the following can be used as a magenta pigment. Toluidine Red (Red-3), Chlorinated Rose Red (Red-4), Naphthol Carmine FB (Red-5), Naphthol Red M (Red-17), Brilliant Fast Scar Red (Red-22), Naphthol Red (Red) -23), pyrazolone red (Red-38), barium red 2B (Red-48: 1), calcium red 2B (Red-48: 2), strontium red (Red-48: 3), manganese red (Red-48) : 4), Barium Resol Red (Red-49: 1), Lake Red C (Red-53: 1), Brilliant Carmine 6B (Red-57: 1), Pigment Scar Red 3B Lake (Red-60: 1), Lake Bordeaux 10B (Red-63: 1), Anthosine 3B Lake (Red-66), Anthosine 5B Lake (Red-67), Rhodamine 6G Lake (Red-81), Eosin Lake (Red-90), Naphthol Red FGR ( Red-112).
Among the above infrared transmissive colored pigments, as the cyan pigment, for example, the following can be used. Victoria Pure Blue BO Lake (Blue-1), Basic Blue 5B Lake (Blue-3), Basic Blue 6G Lake (Blue-9), Phthalocyanine Blue (α-type, unstable) (Blue-15: 1), Phthalocyanine Blue (Β-type, non-crystalline form) (Blue-15: 3), phthalocyanine blue (β-type, non-crystalline, non-aggregated form) (Blue-15: 4), Fast Sky Blue (Blue-17: 1), Alkaline Blue G toner (Blue-18), alkali blue R toner (Blue-19), peacock blue lake (Blue-24), reflex blue 2G (Blue-56), reflex blue R (Blue-61).
Among the above infrared transmissive colored pigments, for example, the following can be used as a black pigment. Format black (mixed pigment of yellow, magenta and cyan pigments), aniline black (Black-1). Note that black pigments absorb visible light, and thus cannot be used for visible fluorescent materials, but can be used for infrared fluorescent materials.
Among the above infrared transmissive colored pigments, for example, the following can be used as a white pigment (extreme pigment). Zinc white (White-4), titanium oxide (White-6), calcium carbonate (White-18), clay (White-19), barium sulfate (White-21), alumina white (White-24).

As for the content rate of the security material in the printing ink used for the colored pattern printing layer 12, about 10 to 30% is preferable. This is because if the content is less than 10%, the functionality is lowered, and if the content is more than 30%, the printability is lowered.
Further, the content of the transparent colored material in the printing ink is preferably about 0.5 to 20%. This is because if the content is less than 0.5%, printing management is difficult, and if the content is more than 20%, the mixing amount of the infrared reaction material decreases (influences on the printability).

As described above, according to Example 1, the colored pattern printing layer 12 is formed using the printing ink in which the security material and the transparent colored material are mixed, and even if the security material that reacts with infrared rays is invisible, By utilizing the fact that the printed pattern can be recognized by the unevenness, it is possible to improve the anti-counterfeiting property because the trace of the security measure can be hidden even if the presence of the pattern is known.
Moreover, since the colored pattern printing layer 12 is colored, it is possible to manage printing density and printing accuracy as usual at the manufacturing site.
Furthermore, by using an infrared reaction type security material, the light source of the authenticity determination device can be an LED or the like, and the cost of the authenticity determination device can be reduced compared to the ultraviolet reaction type.
Furthermore, since the security material is fluorescent, the authenticity can be determined more easily than the absorption type, and the security can be improved.
On the other hand, the colored pattern printing layer 12 contains a transparent colored material that transmits visible light that emits infrared rays and fluorescent light. Since visible light that emits infrared rays and fluorescent light is not absorbed, it is possible to prevent a decrease in light emission luminance and light emission efficiency.

FIG. 2 is a diagram showing Example 2 of the forgery-preventing printed material according to the present invention.
In addition, the part which fulfill | performs the same function as Example 1 mentioned above attaches | subjects the same code | symbol or the code | symbol unified at the end, and abbreviate | omits duplication description and drawing suitably.
The anti-counterfeit printed matter 10-2 of Example 2 is a barcode that can be read by the colored pattern printing layer 12-2. In the drawing, the colored pattern printing layer 12-2 is displayed with four bars, but actually, it is configured with a number of bars.

  As described above, according to the second embodiment, the color pattern printing layer 12-2 is made a machine-readable barcode, so that not only the authenticity is determined based on the presence or absence of the security material but also the product type, serial number, and manufacturing. Product code information such as date can also be included. In addition, the security and reliability of the code can be improved.

FIG. 3 is a diagram showing Example 3 of the forgery-preventing printed material according to the present invention.
In the forgery prevention printed matter 10-3 of Example 3, a character string “¥ 1000”, which is a part of the display unit 11a, is displayed by the colored pattern printing layer 12-3. The character string “¥ 1000” is divided into five regions: region A1: “¥”, region A2: “1”, region A3: “0”, region A4: “0”, and region A5: “0”. It is divided.
The colored pattern printing layer 12-3 in the areas A1, A3, and A5 is formed of a first colored ink layer mixed with a security material.
On the other hand, the colored pattern printing layer 12-3 in the regions A2 and A4 is formed of a second colored ink layer that is substantially the same color as the first colored ink layer and does not contain a security material.
Therefore, a print pattern of “¥ 1000” is formed by the combination of the regions A1, A3, A5 and the regions A2, A4.

  Thus, according to Example 3, the print pattern is formed by combining the colored ink layer mixed with the security material and the colored ink layer of the same color not mixed with the security material. It becomes hard to be understood and can improve anti-counterfeit effect more.

FIG. 4 is a diagram showing Example 4 of the forgery-preventing printed material according to the present invention.
The anti-counterfeit printed matter 10-4 of the fourth embodiment is of a type in which the second embodiment and the third embodiment are combined.
The colored pattern print layer 12-4 is a barcode as in the second embodiment, and the barcode is divided into regions B1 to B4.
The bar patterns in the areas B1 and B3 are formed by a first colored ink layer mixed with a security material.
On the other hand, the bar patterns in the regions B2 and B4 are formed of a second colored ink layer that is substantially the same color as the first colored ink layer and does not contain a security material.
Therefore, two types of barcode patterns are formed by the regions B1 and B3 and the regions B2 and B4.

  Thus, according to Example 4, the colored ink layer mixed with the security material and the colored ink layer of the same color not mixed with the security material are combined to form two types of barcode patterns in one place. Thus, a normal colored code pattern and a security printing code pattern are mixed, and two types of code patterns can be read from a portion that appears to be one barcode at first glance, thereby further improving security. .

(Modification)
The present invention is not limited to the embodiments described above, and various modifications and changes are possible, and these are also within the equivalent scope of the present invention.
(1) Forgery prevention printed materials are explained in the example of gift certificate, but driver's license, identification card such as passport, securities such as gift certificate, stock certificate, lottery / scratch lottery, credit cash card, game card trading It may be a card, a warranty card, a betting ticket such as a betting ticket or a car ticket.
(2) The security material has been described as an example of a material that reacts with infrared rays, but may be a material that reacts with ultraviolet rays.
(3) Although the machine-readable code has been described as an example of a barcode, it may be a two-dimensional code.

(4) The base material 11 may be thermal paper (thermal self-coloring base material) that self-colors by heat sensitivity. By using self-coloring thermal paper, information can be printed without using supplies (consumables) such as ink ribbons, so that the overall cost can be reduced. Moreover, in the case of thermal paper that self-colors, once recorded information cannot be erased and rewritten with other information, security can be further improved.
Moreover, when the base material 11 is made of thermal paper, it is preferable to provide the colored pattern printing layer 12 on the surface opposite to the thermal surface (thermal surface) of the thermal paper. In this way, there is an effect that more information can be recorded because the area where information can be printed is widened.
Further, the colored pattern printing layer 12 provided on the surface opposite to the thermal surface is a machine-readable code, and the thermal surface has related information (for example, information related to the machine-readable code). It is preferable to provide information such as an amount of money, a refund deadline, and voting details. In this way, falsification of information can be prevented and security can be further improved.

It is a figure which shows Example 1 of the forgery prevention printed matter by this invention. It is a figure which shows Example 2 of the forgery prevention printed matter by this invention. It is a figure which shows Example 3 of the forgery prevention printed matter by this invention. It is a figure which shows Example 4 of the forgery prevention printed matter by this invention.

Explanation of symbols

10, 10-2, 10-3, 10-4 Anti-counterfeit printed matter 11 Base material 11a Display unit 12, 12-2, 12-3, 12-4 Colored pattern printing layer

Claims (10)

A substrate;
A forgery-proof printed matter having a colored pattern printing layer provided on the substrate,
The colored pattern printing layer contains an invisible security material that reacts to infrared rays and / or ultraviolet rays,
Anti-counterfeit printed matter characterized by. In the anti-counterfeit printed matter according to claim 1,
The security material is a material that reacts to infrared rays;
Anti-counterfeit printed matter characterized by. In the anti-counterfeit printed matter according to claim 1 or 2,
The security material is an infrared-excited visible light fluorescent material that is excited by infrared rays and fluoresces in a visible manner;
Anti-counterfeit printed matter characterized by. In the anti-counterfeit printed matter according to any one of claims 1 to 3,
The colored pattern printing layer contains a transparent colored material that transmits visible light that emits infrared rays and / or fluorescence,
Anti-counterfeit printed matter characterized by. In the anti-counterfeit printed matter according to any one of claims 1 to 4,
The colored pattern printing layer is
A first colored ink layer mixed with the security material;
A printing pattern is formed by a combination with the second colored ink layer which is substantially the same color as the first colored ink layer and does not contain the security material,
Anti-counterfeit printed matter characterized by. In the anti-counterfeit printed matter according to any one of claims 1 to 4,
The colored pattern printing layer is a machine-readable code;
Anti-counterfeit printed matter characterized by. In the forgery prevention printed matter according to claim 6,
The machine readable code is:
A first colored ink layer mixed with the security material;
Two kinds of code patterns are formed by a combination with the second colored ink layer which is substantially the same color as the first colored ink layer and does not contain the security material,
Anti-counterfeit printed matter characterized by. In the anti-counterfeit printed matter according to any one of claims 1 to 7,
The substrate is a heat-sensitive self-coloring substrate that self-colors by heat;
Anti-counterfeit printed matter characterized by. The anti-counterfeit printed matter according to claim 8,
The colored pattern printing layer is provided on a surface opposite to the heat-sensitive surface of the heat-sensitive self-coloring substrate;
Anti-counterfeit printed matter characterized by. In the anti-counterfeit printed matter according to claim 9,
The colored pattern printing layer provided on the surface opposite to the heat-sensitive surface is a machine-readable code,
The heat sensitive surface is provided with related information associated with the machine readable code information;
Anti-counterfeit printed matter characterized by.

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