JP2023049613A - printed matter - Google Patents

Abstract

To provide a printed matter on which the reflectance of infrared light makes it easy to read a matrix type symbol but the reflectance of visible light makes it difficult to read it, and which can be produced inexpensively.SOLUTION: A camouflage pattern 8 consisting of light colors and dark colors is formed on a surface of a substrate 2 with an infrared light non-absorbing material, and further, a matrix type symbol 7 consisting of light color cells not absorbing infrared light and dark color cells absorbing infrared light is formed with an infrared light absorbing material so as to overlap the camouflage pattern 8. A printed matter is configured so that the camouflage pattern 8 includes a dot pattern or a checker pattern in a part where a pattern of the matrix type symbol 7 overlaps the camouflage pattern 8.SELECTED DRAWING: Figure 2

Description

The present invention relates to a printed matter on which symbols are formed.

Symbols such as bar codes and QR codes (registered trademark) are printed on various printed materials. For general symbols, reading programs are widely distributed, and the recorded information of the symbols can be read by using a mobile terminal in which the reading program is installed. On the other hand, in order to improve the confidentiality of the symbols, there has been proposed a printed matter in which the symbols formed with an infrared light absorbing material are concealed by a black pattern (black solid pattern) formed with an infrared light non-absorbing material. (For example, Patent Documents 1 and 2). In these printed materials, the entire symbol appears black due to the black-painted pattern, so that it is difficult for a symbol reading program of a mobile terminal to identify the symbol based on the reflection intensity of visible light to read the symbol. On the other hand, a dedicated device that identifies a symbol based on the intensity of reflected infrared light can reliably read the recorded information of the symbol without being obstructed by the black pattern.

Japanese Utility Model Publication No. 04-026922 JP 2013-001077 A

The printed matter of Patent Document 1 has a problem that it cannot sufficiently prevent reading of the matrix-type symbol based on the reflection intensity of visible light. Specifically, in the printed matter of Patent Document 1, a symbol made of an infrared light absorbing material is formed on a black pattern made of an infrared light non-absorbing material. , Even with the same black color, the color and luster are slightly different due to the difference in materials. For this reason, in the printed matter of Patent Document 1, when attempting to read the symbol based on the reflection intensity of visible light with a mobile terminal, etc., the difference in reflection intensity caused by a slight difference in color and glossiness light-dark patterns in symbols may be identified. In such a case, since the matrix-type symbol has an error correction function, even if the light-dark pattern of the symbol is not completely identified, the information recorded in the symbol may be successfully read.

On the other hand, the printed matter of Patent Document 2 tends to be more expensive to manufacture than the printed matter of Patent Document 1. Specifically, in the case of a printed material in which the recorded information of the symbols is different for each sheet, in the configuration of Patent Document 1, only the symbols can be individually formed by the printer after the black pattern is formed by the printer. The configuration of Patent Document 2 is basically necessary to form the black pattern after the symbol is printed, so it is difficult to form the black pattern with a printing machine. If a thermosensitive coloring layer is provided under the black pattern and a symbol can be thermally printed on the thermosensitive coloring layer after the formation of the black pattern, the black pattern can be formed by a printing machine. In this configuration, the cost of the paper is increased by the amount of the thermosensitive coloring layer.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a printed matter that can reliably prevent the matrix type symbol from being read based on the reflection intensity of visible light and that can be manufactured at low cost.

The present invention is a printed material having a symbol formed on a camouflage pattern formed on the surface of a base material, wherein the symbol is made of an infrared light absorbing material that absorbs infrared light. a matrix-type symbol consisting of light-colored cells that do not absorb infrared light and dark-colored cells that absorb infrared light, and the camouflage pattern is a camouflage pattern consisting of light-colored portions and dark-colored portions formed of a material that does not absorb infrared light. and wherein the camouflage pattern includes a dot pattern and/or a checkered pattern in a portion where the camouflage pattern and the symbol overlap.

According to research conducted by the inventors, with such a configuration, reading of symbols based on the reflection intensity of visible light by a mobile terminal or the like can be more reliably prevented than with the configuration of Patent Document 1 above. This is because, in the present invention, the portion where the light color portion of the symbol and the light color portion of the camouflage pattern overlap shows a light color, and the dark color portion of the symbol and the dark color portion of the camouflage pattern show a dark color. When the intensity is measured, the contrast between the light-colored and dark-colored portions of the reflected light becomes high, and the slight difference in the reflected light between the dark-colored portions of the symbol and the dark-colored portions of the camouflage pattern is neglected. This is probably because the dark color portion and the dark color portion of the camouflage pattern are no longer distinguishable. Also, as in the present invention, if the camouflage pattern is a dot pattern or a checkered pattern, even if the entire bright color portion of the symbol does not exhibit black, errors exceeding the error correction capability of the matrix type symbol can easily occur. be able to.
In addition, since the printed matter of the present invention has the symbol formed on the camouflage pattern, it can be manufactured by forming the camouflage pattern on the camouflage pattern with a printer and then forming the symbol on the camouflage pattern with a printer. For this reason, the present invention also has the advantage that it can be manufactured at a lower cost than the configuration of Patent Document 2 above.

It is sufficient that the bright color portion and the dark color portion of the camouflage pattern according to the present invention exhibit bright color and dark color, respectively, in portions that do not overlap the dark color cells of the symbol. However, it is desirable to use a color in which the contrast between the bright color portion and the dark color portion is high. For this reason, the bright color portion according to the present invention is preferably white or a color approximating white, and the dark color portion is preferably black or a color approximating black. In addition, the infrared light absorbing material and the infrared light non-absorbing material according to the present invention are sufficient if they have absorption characteristics and non-absorption characteristics in a specific band of infrared light, and absorption characteristics over the entire infrared region. and non-absorbing properties.

In the present invention, the squares of the checkered pattern and the dots of the dot pattern that make up the camouflage pattern may not have the same size as the cells that make up the matrix symbol. The inventor has found that in a camouflage pattern in which the area of at least the squares or dots is in the range of 1/2 to 6 times the size of the symbol cell, reading of a matrix-type symbol based on the reflection intensity of visible light is better than that of a black pattern. We have confirmed that it is possible to prevent

The area ratio of the bright color portion and the dark color portion in the camouflage pattern according to the present invention is not particularly limited. The inventor has confirmed that at least a camouflage pattern with a dark area ratio of 20 to 80% can more reliably prevent reading of a matrix-type symbol based on the reflection intensity of visible light than a black pattern. .

In the present invention, it is proposed that the camouflage pattern includes a dark fill pattern in a portion where the camouflage pattern and the symbol overlap.

In such a configuration, by including a dark-colored fill pattern in the camouflage pattern in addition to the dot pattern and/or checkered pattern, the distribution of the reflection intensity of visible light at the symbol formation site becomes uneven. It is possible to more reliably prevent the reading of symbols based on the reflection intensity of .

Further, in the present invention, it is proposed that at least the formation portions of the symbol and the camouflage pattern are surface-coated with a transparent laminate film that transmits infrared light.

In such a configuration, the glossiness of the laminate film covering the symbol and the camouflage pattern obscures the difference in gloss between the dark-colored portion of the symbol and the dark-colored portion of the camouflage pattern. It becomes more difficult to distinguish based on the reflected intensity of visible light.

Further, in the present invention, a layer made of a light-colored or transparent infrared light non-absorbing material is formed in the light-colored portion of the camouflage pattern, and a dark-colored infrared light non-absorbent layer is formed in the dark-colored portion of the camouflage pattern. It is proposed that a layer of material is formed.

By forming a layer made of non-infrared light-absorbing material on both the light-colored part and the dark-colored part of the camouflage pattern as in this configuration, the irregularities on the surface of the camouflage pattern are reduced, so that the symbol can be placed on the camouflage pattern. is easily formed, and faintness and loss are less likely to occur during symbol formation.

Further, in the present invention, the camouflage pattern is covered with a transparent covering layer made of a transparent non-infrared light absorbing material, and the entire symbol is formed on the transparent covering layer. is proposed. Here, the transparent coating layer is not limited to being colorless and transparent, and may be colored.

With such a configuration, since the entire symbol is formed on the uniform transparent coating layer, the symbol can be formed more stably than when the symbol is directly formed on the non-homogeneous camouflage pattern.

As described above, according to the present invention, it is possible to inexpensively manufacture a printed matter that can reliably prevent reading of the matrix type symbol based on the reflection intensity of visible light.

1 is a plan view of printed matter 1 of Example 1. FIG. FIG. 7 is an explanatory diagram showing how a QR code 7 is formed; (A) is an explanatory diagram showing a QR code 7 formed on the printed matter 1. FIG. (B) is an explanatory diagram showing a camouflage pattern 8 formed on the printed matter 1. FIG. (C) is an explanatory diagram showing a state in which the QR code 7 and the camouflage pattern 8 are superimposed. (A) is an explanatory diagram showing a QR code 7 according to Example 2; (B) is an explanatory diagram showing a camouflage pattern 8a according to Example 2. FIG. (C) is an explanatory diagram showing a state in which the QR code 7 and the camouflage pattern 8a are superimposed. (A) is an explanatory diagram showing a camouflage pattern 8b according to Example 3. FIG. (B) is an explanatory diagram showing a camouflage pattern 8b according to Example 4. FIG. (C) is an explanatory diagram showing a camouflage pattern 8c of a modified example. 1A is an explanatory diagram showing a cross-sectional structure of a printed matter 1 according to Example 1. FIG. (B) is an explanatory diagram showing a cross-sectional structure of a printed matter 1a according to Example 5. FIG. (C) is an explanatory diagram showing a cross-sectional structure of a printed matter 1b according to Example 6. FIG. (D) is an explanatory diagram showing a cross-sectional structure of a printed matter 1c according to Example 7. FIG. 4 is a chart showing the results of Test 1. FIG.

Embodiments according to the present invention will be described according to the following examples.
In addition, in the following examples, the QR code 7 corresponds to the symbol according to the present invention. Further, the black infrared light absorbing ink corresponds to the infrared light absorbing material according to the invention, and the black infrared light transmitting ink corresponds to the infrared light non-absorbing material according to the invention.

As shown in FIG. 1, the printed matter 1 of this embodiment is a museum admission ticket. In the printed matter 1, character information 4 and 5 for human recognition is formed on the surface of a white base material 2 made of high-quality paper. Among the character information, "xxx museum" is fixed character information 4 that is common to all admission tickets, and "expiration date..." is variable character information 5 that may differ depending on the admission ticket. Also, a QR code 7 is formed on the surface of the printed matter 1 . As shown in FIG. 2, the QR code 7 is formed so as to overlap the camouflage pattern 8. As shown in FIG. A unique number assigned to each admission ticket is recorded in the QR code 7 . That is, a different QR code 7 is formed on each printed matter 1 . Such a printed matter 1, for example, allows the entrance management system to read the QR code 7 at the time of entry, and permits entrance when the entrance management system determines that the unique number recorded in the QR code 7 is valid. It can be used for purposes such as

As shown in FIG. 3A, the QR code 7 is formed by arranging square cells vertically and horizontally. The cells are composed of bright cells and dark cells, and information is recorded by a pattern of bright cells and dark cells. Square-shaped finder patterns 10 for detecting the position of the QR code 7 are formed at the three corners of the QR code 7 . A certain range of blank portion 11 (quiet zone) is provided around the QR code 7 . Note that the QR code 7 is created in accordance with the existing standard (JIS X 0510) for points not mentioned in the text.

Such a QR code 7 is formed with black infrared light absorbing ink. Specifically, the QR code 7 is formed by solidly printing black infrared light absorbing ink only on the dark color cells. That is, when such a QR code 7 is directly formed on the surface of the base material 2, the portion of the dark cell where the black infrared light absorbing ink is solidly printed becomes black, and the light color where the infrared light absorbing ink is not printed. The cell portion is white due to the background color of the base material 2 and is visually recognized as shown in FIG. 3(A). However, in this embodiment, since the QR code 7 is formed over the camouflage pattern 8, the visibility of the QR code 7 is hindered under visible light illumination.

The camouflage pattern 8 is a checkered pattern in which white squares (bright color portions) and black squares (dark color portions) are alternately arranged, as shown in FIG. 3(B). The size of the white squares and black squares forming the camouflage pattern 8 is the same size as the cells of the QR code 7 . The camouflage pattern 8 is formed in a square area that is one size larger than the QR code 7 . Specifically, the camouflage pattern 8 is formed in a size that can just accommodate the QR code 7 and the surrounding blank portion 11 . The camouflage pattern 8 is formed with black infrared light transmissive ink. Specifically, black infrared light transmitting ink is printed solidly on the dark color portions (black square portions), and infrared light transmitting ink is printed on the bright color portions (white square portions) of the camouflage pattern 8. The surface of the white substrate 2 is exposed.

As shown in FIG. 3C, the QR code 7 is formed in the central portion of the camouflage pattern 8 so that the QR code 7 and the blank portion 11 all overlap the camouflage pattern 8 . In addition, although the dark color portion of the camouflage pattern 8 is black as shown in FIG. 3B, in FIG. Of the dark portions of the pattern 8, the portions that do not overlap the dark cells are shown in gray (actually, they are visually recognized as shown in FIG. 1). As described above, in this embodiment, the QR code 7 overlaps the camouflage pattern 8, so that the bright color portions (light cells and blank portions 11) of the QR code 7 also overlap the dark color portions of the camouflage pattern 8. The part (gray part in FIG. 3(C)) is black. Here, in the checkered pattern that constitutes the camouflage pattern 8, since the area of the bright color part and the dark color part are equal, about 50% of the bright color part of the QR code 7 overlaps the dark color part of the camouflage pattern 8 in this embodiment. The remaining approximately 50% overlaps with the light-colored portion of the camouflage pattern 8 and exhibits white.

In the printed matter 1 of this embodiment, it is difficult to read the recorded information of the QR code 7 based on the reflection intensity of visible light. This is probably because, in this embodiment, not only the dark cells of the QR code 7 but also about 50% of the bright parts of the QR code 7 are black, as described above. Specifically, in reading the recorded information of the QR code 7, the finder pattern 10 or the like is detected and the position of the QR code 7 is detected. A light/dark determination process is required to determine whether the cell is a dark cell or not. However, in a state in which half of the bright cell and the blank portion 11 are black and the remaining half is white, the position detection process cannot be completed normally. It is difficult. Also, in the light/dark determination process, about half of the bright cells of QR Code 7 are erroneously determined to be dark cells. be. The QR code 7 can decode the recorded information within the correctable range of the error correction function even if the cell brightness or darkness is erroneously determined. It cannot fit within the correctable range of QR Code 7.

In the printed matter 1 of the present embodiment, by measuring the reflection intensity of infrared light using a dedicated device, the light and dark pattern of the QR code 7 can be accurately identified and the recorded information of the QR code 7 can be read. The brightness of the camouflage pattern 8 formed with infrared light transmitting ink is not reflected in the level of the reflection intensity of infrared light, and only the brightness of the QR code 7 formed with infrared light absorbing ink is affected by the infrared light. This is because it is reflected in the level of reflection intensity. Specifically, when the reflection intensity of the infrared light at the QR code 7 formation site is measured, the infrared light is directly reflected on the surface of the base material 2 in the white portion of FIG. In the gray part of 3 (C), infrared light passes through the infrared light transmitting ink forming the camouflage pattern 8 and is directly reflected on the surface of the base material 2, so the white part of FIG. 3 (C) and the In the gray part, the reflectance of infrared light is high. On the other hand, in the black portion of FIG. 3(C), the infrared light is absorbed by the infrared light absorbing ink forming the dark cells of the QR code 7, so the reflection intensity of the infrared light is low. Thus, in this embodiment, since the infrared light reflection intensity is low only in the dark cells of the QR code 7, the light-dark pattern of the QR code 7 can be accurately identified by measuring the infrared light reflection intensity. Then, the recorded information of the QR code 7 can be read.

As described above, the printed matter 1 of the present embodiment 1 can read the recorded information of the QR code 7 based on the reflection intensity of the infrared light. The information recorded in the QR code 7 cannot be read based on the light reflection intensity. This is because ordinary copiers do not consider the reflection characteristics of infrared light at the time of copying, so that the reflection characteristics of infrared light in the original are not replicated in the copy. That is, the printed matter 1 of this embodiment can be prevented from being copied by a copier.

As an efficient method of manufacturing the printed matter 1 (admission ticket) of the present embodiment, only common printing (fixed character information 4 and camouflage pattern 8) common to all admission tickets is printed by a printing machine at a printing company or the like. 2, and then print different unique prints (variable character information 5 and QR code 7) depending on the admission ticket one by one at the ticket issuing office. In this way, the cost of issuing the printed matter 1 can be reduced by printing the common print in advance with the printer and additionally printing the unique print with the printer. In this embodiment, the QR code 7, which is unique printing, is formed on the camouflage pattern 8, which is common printing, so such a low-cost manufacturing method can be adopted. 1 and 3, the QR code 7 is arranged so that the cell of the QR code 7 and the square shape of the checkered pattern of the camouflage pattern 8 completely overlap. Even if the code 7 cell and the camouflage pattern 8 are overlapped squarely, the same effect can be obtained. That is, in the manufacturing process of the printed matter 1 of this embodiment, accurate alignment between the QR code 7 and the camouflage pattern 8 is unnecessary.

As described above, in the printed matter 1 of the present embodiment, the QR code 7, which is easy to read based on the reflection intensity of infrared light and difficult to read based on the reflection intensity of visible light, can be produced by an inexpensive method.

Examples 2 to 7 are described below. Embodiments 2 to 7 are modified examples in which the configuration of Embodiment 1 is partially changed. For this reason, the same reference numerals are given in the text and the drawings to the same configurations as in the first embodiment, and detailed description thereof is omitted.

In this embodiment, the shape of the camouflage pattern is changed from that in the first embodiment. Specifically, in Example 1, the entire camouflage pattern 8 is composed of a checkered pattern (see FIG. 3(B)), whereas in this example, as shown in FIG. 4(B), A camouflage pattern 8 a is composed of a checkered pattern 14 and a black pattern (black filled pattern) 15 . The black pattern 15 has a rectangular frame shape formed around the square camouflage pattern 8 a , and the checkered pattern 14 is formed inside the black pattern 15 . The sizes of the white and black squares forming the checkered pattern 14 are the same as in the first embodiment. As shown in FIG. 4A, the QR code 7 is the same as in Example 1, and the checkered pattern 14 has a square shape that is one size smaller than the QR code 7 . In this embodiment, as shown in FIG. 4C, the QR code 7 is formed on the camouflage pattern 8a so that the outer peripheral portion and the blank portion 11 of the QR code 7 overlap the black pattern 15. be.

As in the present embodiment, the camouflage pattern according to the present invention may be such that the checkered pattern 14 does not overlap the entire QR code 7 . In addition, in this embodiment, since the distribution of the reflected intensity of visible light is different between the portion where the QR code 7 overlaps the checkered pattern 14 and the portion where the QR code 7 overlaps the black pattern 15, the visible light It becomes more difficult to read the QR code 7 based on the reflection intensity of . In addition, in this embodiment, since the outer periphery of the camouflage pattern 8a is the black pattern 15, even if the QR code 7 is formed at a position deviated from the center of the camouflage pattern 8a, the deviation of the formation position is conspicuous. There is an advantage that it is difficult and it is easy to maintain a beautiful appearance.

In this embodiment, the shape of the camouflage pattern is changed from that in the first embodiment. Specifically, in the first embodiment, the camouflage pattern 8 is composed of a checkered pattern consisting of white and black squares (see FIG. 3(B)), whereas in the present embodiment, the camouflage pattern 8 is shown in FIG. , the camouflage pattern 8b is composed of a checkered pattern consisting of white and black vertically long rectangles. Thus, the squares forming the checkered pattern of the camouflage pattern may be different in size and shape from the cells forming the QR code 7 .

In this embodiment, the shape of the camouflage pattern is changed from that in the first embodiment. Specifically, in the first embodiment, the camouflage pattern 8 is configured as a checkered pattern (see FIG. 3B), whereas in the present embodiment, the camouflage pattern 8 as shown in FIG. 8c is composed of a dot pattern of black dots on a white background. The dot has a circular shape and its diameter is the length of one side of the QR code 7 cell.

As described above, even when the camouflage pattern according to the present invention is a dot pattern, it becomes difficult to read the QR code 7 based on the reflection intensity of visible light. Note that the size of the dots can be appropriately changed from the sizes of the above embodiments, and the shape of the dots is not limited to circles, and may be polygons, stars, or the like. In addition, the dot pattern is not limited to dark-colored dots on a light-colored background, and a dot pattern in which bright-colored dots are arranged on a dark-colored background, such as camouflage pattern 8d shown in FIG. good. In addition, the size and shape of individual dots that make up the dot pattern may be non-uniform, and the dot arrangement is not limited to equal intervals, and the dots may be irregularly arranged. may

In this example, the printed material of Example 1 is covered with a laminate film. More specifically, in the printed matter 1 of Example 1, as shown in FIG. 6A, a QR code 7 is formed with an infrared light absorbing ink 21 on a camouflage pattern 8 formed with an infrared light transmitting ink 20. I just did it. On the other hand, as shown in FIG. 6B, the printed matter 1a of the present embodiment is obtained by laminating transparent laminate films 18 on the front and back surfaces of the printed matter 1 of the first embodiment and then pouching the printed matter 1a. In the printed matter 1 of Example 1, as shown in FIG. Since it is exposed on the surface, the difference in glossiness between the infrared light transmitting ink 20 and the infrared light absorbing ink 21 is reflected relatively strongly in the reflection intensity of visible light. On the other hand, if the printed material 1a is covered with the laminate film 18 as in the present embodiment, the glossiness of the laminate film 18 will affect the glossiness of the infrared light transmitting ink 20 and the infrared light absorbing ink 21. Since the difference is hardly reflected in the reflected intensity of visible light, it becomes even more difficult to distinguish between the QR code 7 and the camouflage pattern 8 based on the reflected intensity of visible light.

In this embodiment, the configuration of the camouflage pattern is changed from that in the first embodiment. Specifically, the camouflage pattern 8e of the present embodiment is composed of a checkered pattern similar to the camouflage pattern 8 of the first embodiment (see FIG. 3B). Here, in the printed matter 1 of Example 1, ink is not printed on the bright color portions (black portions of the checkered pattern) of the camouflage pattern 8, and the white background of the base material 2 is exposed (FIG. 6 ( A)), in the printed matter 1b of the present embodiment, as shown in FIG. 6C, the white infrared light transmitting ink 22 is formed on the bright color portions of the camouflage pattern 8e. In such a configuration, if the infrared light transmitting ink 22 in the bright color portion is formed to have the same thickness as the infrared light transmitting ink 20 in the dark color portion, the irregularities on the surface of the camouflage pattern 8e are reduced. The code 7 can be formed relatively easily on the camouflage pattern 8e, and even a printer with relatively low performance can print the QR code 7 without causing printing defects such as faintness and defects. In this embodiment, the white infrared light transmitting ink 22 is applied to the bright color portion of the camouflage pattern 8e. You may do so.

The present embodiment is obtained by partially changing the configuration of the first embodiment. Specifically, in Example 1, the QR code 7 is directly formed on the camouflage pattern 8 formed with the infrared light transmissive ink 20 (see FIG. 6A). In an example, as shown in FIG. 6(D), a transparent coating layer 25 made of transparent infrared light transmitting ink is formed so as to cover the entire camouflage pattern 8, and a black ink is applied on the transparent coating layer 25. A QR code 7 is formed with infrared light absorbing ink 21 . The camouflage pattern 8 is composed of a dark color portion where the black infrared light transmitting ink 20 is formed and a light color portion where the base material 2 is exposed, and the surface is uneven, so as in Example 1, If the QR code 7 is directly formed on the camouflage pattern 8, the fixation of the infrared light absorbing ink 21 becomes unstable between the bright color portion and the dark color portion of the camouflage pattern 8, but in this embodiment, such a configuration , the entire QR code 7 is formed on the transparent coating layer 25, so that the fixing of the infrared light absorbing ink 21 can be stabilized.

Although the embodiments of the present invention have been described above, the present invention is not limited to the configurations of the above embodiments, and can be variously modified without departing from the scope of the present invention. For example, the configurations of Examples 1 to 7 described above can be combined as appropriate. Also, the configuration of the above embodiment can be modified as follows.

Although the above embodiment is a printed matter in which a QR code is formed, the symbol according to the present invention is not limited to the QR code, and may be a matrix type symbol such as a micro QR code, DataMatrix (registered trademark), or MaxiCode. .

In the above examples, the infrared light absorbing ink and the infrared light transmitting ink correspond to the infrared light absorbing material and the infrared non-absorbing material according to the present invention. The external light non-absorbing material is not limited to ink and may be toner or the like. Further, in the above embodiment, the ink forming the QR code 7 and the camouflage pattern 8 is formed by solid printing, but the QR code 7 and the camouflage pattern 8 are formed by dot printing of ink. may

In the above embodiment, the bright color portion (bright cell and blank portion 11) of the QR code 7 is white and the dark color portion (dark cell) of the QR code 7 is black. The part may be formed in a bright color other than white, and the dark part of the QR code 7 may be formed in a dark color other than black. Similarly, in the above embodiment, the bright color portion of the camouflage pattern 8 is white and the dark color portion of the camouflage pattern 8 is black. The dark color portion of pattern 8 may be formed in a dark color other than black. Moreover, although it is desirable that the bright colors of the QR code 7 and the camouflage pattern 8 are the same or similar bright colors, they may be different. Similarly, the colors of the dark portions of the QR code 7 and the camouflage pattern 8 are preferably the same or similar dark colors, but may be different. Also, the color of the surface of the substrate according to the present invention is not limited to white, and another color may be adopted.

In the above-described embodiment, the array direction of the checkered pattern squares of the camouflage pattern 8 and the array direction of the cells of the QR code 7 were arranged to match. Both may be overlapped so that the arrangement direction is tilted. Similarly, when the camouflage pattern 8 is a dot pattern, the arrangement direction of the dots of the camouflage pattern 8 and the arrangement direction of the QR code 7 may be overlapped so that both are inclined.

Moreover, in the above embodiment, the camouflage pattern 8 is formed so as to overlap the entire QR code 7, but the present invention may be configured such that the camouflage pattern 8 overlaps only a part of the symbol. When the camouflage pattern 8 overlaps only a part of the symbol, the camouflage pattern 8 is applied to an area ratio exceeding the error correction rate of the symbol so as to reliably prevent reading of the symbol based on the reflected intensity of visible light. Overlapping is desirable.

<Test product 1>
A printed material prepared according to the configuration of Example 1 was designated as Test Item 1. Here, in the test product 1, the size of the square forming the checkered pattern of the camouflage pattern was set to 0.42 mm on each side. The QR code is version 4, error correction level is M, and the cell is a square with a side of 0.42 mm.

<Test products 2 to 4>
Test items 2 to 4 were obtained by changing the camouflage pattern of test item 1 from the checkered pattern to a dot pattern of black dots on a white background. The black dots were in the shape of a square with a side of 0.42 mm. In addition, for test samples 2 to 4, by appropriately setting the intervals between the black dots, the area ratios of the respective dark portions were 20% (test sample 2), 30% (test sample 3), and 40% (test sample 4).

<Test products 5 to 7>
Test items 5 to 7 were obtained by changing the camouflage pattern of test item 1 from the checkered pattern to a dot pattern of white dots on a black background. The white dots were in the form of a square with a side of 0.42 mm. In addition, by appropriately setting the intervals between the white dots in test samples 5 to 7, the area ratios of the respective dark portions were reduced to 60% (test sample 5), 70% (test sample 6), and 80% (test sample 7).

<Test products 8 to 12>
Specimens 5 to 7 were obtained by changing the cell size of the QR code of Specimen 1. Specifically, the length of one side of the square cell is 0.17 mm for test product 8, 0.25 mm for test product 9, 0.33 mm for test product 10, 0.51 mm for test product 11, and 0.51 mm for test product 11. 12 is 0.6 mm.

<Comparative products 1 and 2>
Comparative product 1 was obtained by changing the camouflage pattern of test product 1 from a checkered pattern to a black pattern. Comparative product 2 was obtained by removing the camouflage pattern from test product 1 above.

<Test 1>
Install multiple types of QR code reading programs on a mobile terminal (smartphone), and try to read the QR codes of test products 1 to 12 and comparative products 1 and 2 with each reading program, based on the reflection intensity of visible light , whether or not the recorded information of the QR code can be successfully read. The results are shown in FIG.

As shown in FIG. 7, the test product 1 failed to read the QR code with all reading programs, while the comparative product 1 successfully read the QR code with some reading programs. This indicates that the camouflage pattern consisting of the checkered pattern can more reliably prevent reading of the QR code based on the reflection intensity of visible light than the configuration superimposed on the black pattern.

Further, as shown in FIG. 7, the QR code reading of the test products 2 to 7 failed with all the reading programs. This indicates that the camouflage pattern consisting of a dot pattern can more reliably prevent the reading of the QR code based on the reflection intensity of visible light than the configuration superimposed on the black pattern.

Further, as shown in FIG. 7, the QR code reading of the test products 8 to 12 failed with all the reading programs. This means that even if the size of the squares that make up the camouflage pattern and the size of the cells of the QR code do not match, the readout of the QR code based on the reflected intensity of visible light is more reliable than the configuration that overlaps the black pattern. This indicates that it is possible to prevent

<Test 2>
For test products 1 to 12 and comparative products 1 and 2, reading of the QR code was attempted based on the reflection intensity of infrared light using a dedicated reader. As a result, the information recorded in the QR code could be read for all of the test products 1 to 12 and the comparative products 1 and 2. This result indicates that the camouflage pattern consisting of a checkered pattern and a dot pattern does not hinder the reading of the QR code based on the reflection intensity of infrared light.

<Test 3>
Test products 1 to 12 and comparative products 1 and 2 are copied using a general copying machine, and the QR code is recorded from the part where the QR code is copied in the same manner as in test 1 above for each copy. Attempted to read information. As a result, in the copies of Test Products 1 to 12 and Comparative Product 1, the recorded information of the QR code could not be read even once. On the other hand, the QR code was successfully read with all reading programs for the copy of the comparative product 2 on which the camouflage pattern was not formed. This result indicates that the camouflage pattern consisting of the checkered pattern and the dot pattern can also prevent copying of the QR code in the same way as the black pattern.

1 printed matter 2 base material 4 fixed character information 5 variable character information 7 QR code (symbol)
8 Camouflage pattern 10 Finder pattern 11 Blank part 14 Checker pattern 15 Black pattern 18 Laminate film 20 Infrared light absorbing ink (infrared light absorbing material)
21 infrared light transmission ink (infrared light non-absorbing material)

Claims (5)

A printed matter in which a symbol is formed so as to overlap a camouflage pattern formed on the surface of a base material,
The symbol is a matrix-type symbol composed of bright cells that do not absorb infrared light and dark cells that absorb infrared light, and is made of an infrared light absorbing material,
The camouflage pattern is a camouflage pattern consisting of a light-colored portion and a dark-colored portion formed of an infrared light non-absorbing material,
A printed material, wherein the camouflage pattern includes a dot pattern and/or a checkered pattern in a portion where the camouflage pattern and the symbol overlap. 2. The printed matter according to claim 1, wherein the camouflage pattern includes a dark fill pattern in a portion where the camouflage pattern and the symbol overlap. 3. The printed matter according to claim 1, wherein at least the symbol and the camouflage pattern forming portions are surface-covered with a transparent laminate film that transmits infrared light. A layer made of a light-colored or transparent infrared light non-absorbing material is formed in the light-colored part of the camouflage pattern,
4. The printed matter according to any one of claims 1 to 3, wherein a layer made of a dark non-absorbing material for infrared light is formed in the dark portion of the camouflage pattern. The camouflage pattern is covered with a transparent coating layer made of a transparent infrared light non-absorbing material,
5. The printed matter according to any one of claims 1 to 4, wherein the entire symbol is formed on the transparent coating layer.

Images