JPS63307996A - Infrared absorption print - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed Description of the Invention] (Technical Field of the Invention) This invention is applicable to barcodes, POS codes, It! This invention relates to an infrared absorbing printed matter used for printed matter that requires hiding properties such as L patterns.

(Technical Background and Problems to be Solved) For this reason, hidden patterns including infrared absorption regions are printed on the surfaces of white and black hidden printed materials such as barcodes, POS codes, and designs. Barcode Ven uses aOO~10G in addition to the 633nm source laser beam.
On-LED light sources are used, and those using the latter are known. If the purpose is only to detect infrared light, a pen with a 70 on cut filter attached to the LED light source can be used. The above-mentioned printed matter uses an infrared absorbing ink containing an infrared absorbing material, and for example, a carbon pigment is used in the Sho ink.

FIG. 5 shows an example of a printed matter on which a hidden pattern is printed, and the figure ([1) shows its x-x.

A cross section is shown.

In the same figure (^), a hidden pattern 40 is printed on the surface of a printed matter 30, which can only be visually seen as a solid achromatic color of the same black or gray color.
As shown in FIG. 8, the hidden pattern 40 includes an area printed with halftone dots using process inks (Y, M, C) 41 and an area printed using infrared absorbing ink 42 made of carbon pigment. It is made up of.

The surface of such a hidden pattern 40 is detected by an infrared sensor (
(not shown), the portion printed with the process ink 41 has a low infrared absorption rate and cannot be detected, but the portion printed with the infrared absorbing ink has a high infrared absorption rate and is easily detected. Therefore, if a barcode is printed using infrared absorbing ink 42, and then printed as a hidden pattern that visually hides the barcode using process ink 41, the barcode information can be retained even though it cannot be visually seen. You can create printed matter.

However, black ink is black in color, and has the disadvantage that when printed as black halftone dots, the color pattern becomes muddy. Furthermore, when white ink is printed on the surface to cover it, there is a drawback that the pattern can be seen through.

(Object of the invention) This invention was made under the above circumstances,
An object of the present invention is to print an image in a hidden pattern on printed matter using a printing ink containing an infrared absorbing pigment, print an ink having a hiding property on the hidden pattern, and further print an image on the hidden pattern. The object of the present invention is to provide an infrared-absorbing printed matter which has excellent hiding properties and can also be used for general printed matter by printing a pattern with common printing ink.

(Means for Solving the Problems) The present invention relates to an infrared absorbing printed matter having a print that can be detected by an infrared sensor. Another invention relates to an infrared-absorbing printed matter having a print that can be detected by an infrared sensor. A printed area is formed using printing inks having different infrared absorption characteristics, and an ink that transmits infrared rays and has a visual hiding property is printed on the upper part of the printed area, and
General printing ink (
This is achieved by the pattern being formed by Y, M, C).

(Operation of the invention) The infrared-absorbing printed matter of the present invention has an image printed on the printed matter in a hidden pattern using an infrared-absorbing ink containing Miloly Blue pigment having infrared absorbing properties, and has a concealing property on the upper part of the hidden pattern. Ink is printed, a pattern is printed on top of the ink using general process ink, and the image is detected by reading the pattern part with an infrared sensor or a reading device in the infrared region or near-infrared region. ing.

(Embodiments of the Invention) The infrared absorbing printed matter of the present invention can be used in any printing method such as offset printing, gravure printing, and silk screen printing. Tables 1 to 20 show the components of infrared absorbing inks that are most compatible with each of the above printing methods, taking cyan ink and green ink as examples.

First, offset ink will be explained.

■Cyan color infrared absorption ink Cyan color infrared absorption ink (Ink 81 to 8) is shown in Table 1.
- Consists of the composition shown in Table 4.

(Unit parts by weight) Table 1 Table 2 Table 3 The cyan inks ^1 to ^ with the above compositions are all blue inks of the same color when visually observed, and have infrared absorption characteristics of 3ai as shown in Figure 'jJ1. The infrared absorption characteristics and color tone in the visible region are adjusted by the difference in the component ratio of cyanine blue and Miloly blue (infrared absorbers).The reason why Miloly blue was used here is that Miloly blue has infrared absorption characteristics. The reason for this is that the cyan inks ^1 to ^3 have three types of characteristics and do not cause a stain on color printed matter.Even when detected by an infrared sensor, the three types of characteristics of these cyan inks ^1 to ^3 can be sufficiently distinguished. , the infrared absorption rate when halftone dots are reproduced shows an absorption rate proportional to the halftone dot area.

Furthermore, the blending of the infrared absorber is not limited to that described above, but may be adjusted as appropriate in the range of 0.5 to 50% depending on the purpose.

■Green infrared absorption ink Green infrared absorption ink (green ink B1~
B2) consists of the compositions shown in Table 1 and Tables 5 to 7.

Table 5 Table 6 Green ink B having the above composition, ~8. are all green ink of the same color visually, and 3f! Infrared absorption characteristics of
(not shown), and its infrared absorption characteristics and color tone in the visible region are adjusted by the difference in the component ratio of cyanine blue and Miloly blue (infrared absorbent). The reason why Miloly Blue was used here is that Miloly Blue has infrared absorption characteristics and does not give a dark color to color printed matter. And such green ink 81~
The three types of characteristics of [l can be sufficiently identified by detection using an infrared sensor. Further, the halftone dot reproduction shows an absorption rate proportional to the halftone dot area. Furthermore, the composition of the infrared absorber is not limited to the above, but is 0.5 to 5
It is adjusted as appropriate within the range of 0t depending on the purpose.

Gravure ink will be explained.

■Cyan infrared absorption ink Cyan infrared absorption ink (inks C1 to C3) is shown in Table 8.
- Consists of the composition shown in Table 1O.

Table 8--1 Table-1 The cyan inks C1 to G3 having the above compositions are all blue inks of the same color when visually observed, and have three types of infrared absorption characteristics (not shown). Its infrared absorption characteristics and color tone in the visible region are adjusted by the difference in the component ratio of cyanine blue and Milory blue (infrared absorbent). The reason why Miloly Blue was used here is that Miloly Blue has infrared absorption characteristics and does not give a dark color to color printed matter. And such cyan ink C1~
C5 can sufficiently identify the characteristics of 3 fl even by detection using an infrared sensor. Further, the halftone dot reproduction shows an absorption rate proportional to the halftone dot area. Further, the composition of the infrared absorber is not limited to the above-mentioned one, but may be appropriately adjusted in the range of 05 to 5 depending on the purpose.

■Green infrared absorption ink Green infrared absorption ink (green ink D, ~D
s) consists of the compositions shown in Tables 11 to 13.

Table 11 Table 12 Table 13 Green inks 01 to D3 with the above compositions were 1.
All are edge inks of the same color, and have three types of infrared absorption characteristics (not shown), and the infrared absorption characteristics and color tone in the visible region are determined by the components of cyanine blue and Miloly blue (infrared absorbent). Adjusted according to the difference in ratio. The reason why Miloly Blue was used here is that Miloly Blue has infrared absorption characteristics and does not give a dark color to color printed matter. And such green ink D, ~D
, detection by an infrared sensor is enough! be able to identify the characteristics of Further, the halftone dot reproduction shows an absorption rate proportional to the halftone dot area. Furthermore, the composition of the infrared absorber is not limited to the above, but is 0.5 to 50.
It is adjusted appropriately within the range of t depending on the purpose.

Silk screen ink will be explained.

Table 1 shows the cyan infrared absorption inks (inks E1 to E3).
It consists of the compositions shown in Tables 4 to 17.

Table 14 Table 15 Table 16 The cyan inks E and ~E with the above compositions are all blue inks of the same color when visually observed, and have infrared absorption characteristics (not shown) of the 3fffi type. The characteristics and color tone in the visible region are adjusted by changing the component ratio of cyanine blue and Miloly blue (infrared absorber). The reason why Miloly Blue was used here is that Miloly Blue has infrared absorption characteristics and does not give a dark color to color printed matter. And such cyan ink E, ~E
3, the three types of characteristics can be sufficiently identified by detection using an infrared sensor.

Furthermore, the infrared absorption rate when halftone dots are reproduced shows an absorption rate proportional to the halftone dot area. Furthermore, the composition of the infrared absorber is
Not limited to the above, 0.5 to 50%
This range shall be adjusted as appropriate depending on the purpose.

■Green infrared absorption ink Green infrared absorption ink (green ink F, ~
rs) has the compositions shown in Tables 17 to 20.

Table 18 Table 19 The green inks F1 to F with the above compositions are all edge inks of the same color when visually observed, and have three types of infrared absorption characteristics (not shown). The color tone in the visible region is adjusted by the difference in the component ratio of cyanine blue and Milory blue (infrared absorber). The reason why Miloly Blue was used here is that Miloly Blue has infrared absorption characteristics and does not give a dark color to color printed matter. Then, such green ink F, -F3
The three main characteristics can be sufficiently distinguished even by detection using an infrared sensor. Furthermore, the infrared absorption rate when halftone dots are reproduced shows an absorption rate proportional to the halftone dot area. Furthermore, the blending of the infrared absorber is not limited to that described above, but may be adjusted as appropriate in the range of 0.5 to 50% depending on the purpose.

Next, examples of printed matter using the indigo inks shown in Tables 1 and 3 will be described.

FIG. 2(A) shows the front side of the printed matter 4 on which the bar code 1 is marked 9j, and FIG. 2 CB) shows its x-x'' section.

The barcode l shown in Figure 2 (^) appears visually as solid cyan ink of the same color, but its structure is as shown in Figure fB), where the barcode l is injected into cyan ink. The positive part 2 of the barcode 1 is printed in cyan ink, and the negative part 3 of the barcode 1 is printed in cyan ink. In such a structure, the surface of the barcode 1 is provided with a light source having at least a wavelength in the infrared region (for example, 70 nm).
00μ or more), and a barcode (not shown) having at least the above-mentioned infrared light-receiving sensitivity is placed on the light-receiving element and moved in the direction of the arrow in Fig. 2 (^). As shown, the cyan ink ^ in the positive part 2 of barcode 1 has a higher infrared absorption rate than the cyan ink ^ 3 in the negative part 3, so the cyan ink ^ 1 is detected and the barcode reader detects it. Barcode data is output from the output.

Next, an example in which the above barcode 1 is applied to a color photographic print will be explained.

FIG. 3 shows a color photographic printed card IO on which barcode 1 is printed and a method of reading barcode 1. In the figure, picture 1 is printed in color on the card IO.
A detecting section 20 on which a barcode 1 is hidden and printed is provided in a part of the necktie 12.

FIG. 4 shows an Barcode is a white ink that is transparent and visually concealable!
Noni! It is printed as a white layer 4 of the cover. On the surface of the white layer 4, black ink 5, which is a mixture of general yellow ink, magenta ink, and cyan ink that transmits infrared light, is printed, and on the surface of the black ink 5, the above-mentioned cyan ink 6 is printed. , the magenta ink 7 is printed on the surface of the cyan ink layer 6, the yellow ink 8 is printed on the surface of the magenta ink 70, and the black ink 5. A part of the tie 12 is expressed by color photo printing using cyan ink 6, magenta ink 7, and yellow ink 8. In addition, the above printing method is offset,
Either gravure or screen printing is acceptable.

In the lower layer of the card IO in Figure 3, the infrared region as described above is installed.
A barcode reader 13 capable of reading data is provided, and the barcode reader 13 is connected to a barcode reading device 14. Inside the barcode reading device 14, there is an 020 unit 15 that analyzes the barcode data 8D read by the barcode reader 13, and a voice synthesis device 16 that synthesizes a predetermined voice using the output signal SD from the CPU unit 15. A speaker 17 connected to a speech synthesizer 16 is provided.

In such a configuration, when the barcode reader 13 is placed on the detection part 20 of the tie 12 printed on the card IO and moved in the direction of the arrow, both the white layer 4 to the yellow ink 8 transmit infrared light. Therefore, the detection unit 20
Barcode 1 printed at the bottom is read and input as barcode data BD to the barcode reading device 14, and then sent to the CP0 circuit 15. The voice synthesizer 16 emits a voice (for example, "tie") from the speaker 17.

Further, the CP port circuit 15 in the barcode reading device 14 is provided with a CD-ROM 21. which stores necktie data in advance.
Reader circuit 22. Image processing device 5 consisting of CRT23
If a slot is provided, the control signal BDI, 501 from the CPU circuit 15 will be sent to the CD-ROM 21. during the above operation. The soda circuit 22 receives image data from the CD-ROM 21.
I is read out and image data GD2 is sent via the reader circuit 22.
is input to the CRT 23, and information on various neckties is displayed.

(Modification of the Invention) In the above embodiment, the infrared absorbing ink is explained using cyan and green printing inks as an example, but other tones of red expressed by a combination of yellow, magenta, and cyan can also be used. It is also possible to create and use a printing ink with external absorption properties.In addition, in the above explanation, microly blue was used as an example due to its infrared absorption properties, but it is also possible to use anthraquinone-based, aminium-based, polymethine-based, cyanine-based, diimonium-based, etc. organic dyes can be used. Also, in the above explanation, barcodes were used as an example, but
The infrared absorbing printed matter of this invention can be widely used for general printed matter such as POS cards and hidden patterns.

(Effects of the Invention) According to the infrared-absorbing printed matter of the present invention, the color tone of the infrared-absorbing ink can only be visually seen to be the same.
This has the advantage that hidden patterns can be easily created. Furthermore, when other patterns are printed on the surface of the infrared absorbing ink using process ink, they do not show through as in the past and have the advantage of extremely high concealability. Furthermore, since the material cost is low, it can be widely used for general printed matter.

[Brief explanation of the drawing]

Figure 1 is a diagram showing the infrared absorption characteristics of the cyan ink used in this invention, Figure 2 (8) is a front view of a printed matter that is an embodiment of this invention, and Figure 2 ([l) is its x-x'
3 is a diagram showing a color photographic print with a barcode printed on it and a method of reading the barcode, FIG. A front view of the printed matter, and FIG. 5 is a sectional view thereof. 1...Barcode, 2...Positive part, 3...
Negative part, 4... White layer, 5... Black ink, 6... Cyan ink, 7... Magenta ink, 8
...Yellow ink, 10...Card, 11...
・Picture, 12... tie, 13... barcode reader, 14... barcode reading device, 15... cp
U section, 16...Speech synthesis device, +7...Speaker, 2 G-...Detection section, 21.CD-ROM. 22...Reader circuit, 23...fRT. Representative Yuzo Yasugata (B) Cha 2 Ougi 4 (/'I) CB) Cha 5 Ward

Claims (5)

[Claims] (1) An infrared absorbing printed matter with a print that can be detected by an infrared sensor, the printed matter having a printed area printed with printing inks having different infrared absorption characteristics. printed matter. (2) The printing area is composed of a first printing area printed with a printing ink having infrared absorption characteristics and a second printing area printed with a general printing ink, and the first printing area and the color tone of the second printing area are visually difficult to distinguish, wherein the printing ink of the first printing area is a printing ink containing an infrared absorbing pigment. Infrared absorbing printed matter as described in Section. (3) The infrared absorbing printed matter according to claim 1, wherein the first printing area is composed of a general printing ink mixed with an infrared absorbing pigment. (4) The first printing area and the second printing area are adjusted so as to visually show the same color, and one of the first and second printing areas has a positive pattern. and the other is a negative pattern, the positive pattern and the negative pattern are printed in a state where they do not overlap but are in contact with each other, and are visually plain. Absorbent print. (5) A printed matter with a print that can be detected by an infrared sensor, wherein the printed matter has a printed area printed with printing ink having different infrared absorption characteristics, and the printed area is formed on the upper part of the printed area. An infrared-absorbing printed matter, characterized in that an ink that transmits infrared rays and has a visual hiding property is printed, and a pattern is formed on the top of the hiding ink using a general printing ink. .