JP7320309B1 - A code printed with a reader-readable identifier - Google Patents

Abstract

An object of the present invention is to discriminate between genuine products and fraudulent products in the distribution process, and to deter transactions of fraudulent products. A printed code printed with an identifier that can be read by a reader includes a minute mark that cannot be recognized by the reader. As a result, the printed code can be read by a reader, while users (for example, consumers, manufacturers and distributors of genuine products) can read the product corresponding to the printed matter on which the printed code is printed as a genuine product. It is possible to identify a product corresponding to a printed matter printed with a print code on which a minute mark is not arranged as a fraudulent product. [Selection drawing] Fig. 2

Description

The present invention relates to a code printed with a reader-readable identifier.

In recent years, there has been a steady increase in transactions of illegal products (counterfeit products, imitation products) that infringe on trademarks and copyrights. The circulation of counterfeit goods such as medical supplies, auto parts, toys, food, cosmetic brands, and electrical goods can endanger the health and overall safety of consumers. However, it is difficult to take effective countermeasures against the trading of such illicit products.

JP-A-7-254037 JP 2012-96490 A

The problem to be solved by the present invention is to discriminate between genuine products and fraudulent products in the distribution process and to deter transactions of fraudulent products.

A code printed with a reader-readable identifier according to the present invention includes a minute mark that cannot be recognized by a reader. As a result, while the code can be read by a reader, users (for example, consumers, manufacturers and distributors of genuine products) cannot judge the product corresponding to the printed matter on which the code is printed as the genuine product. It is possible to identify a product corresponding to a printed matter on which a code is printed without a minute mark as a counterfeit product.

FIG. 4 is a diagram showing a two-dimensional code, which is an example of a code in which minute markers are arranged, according to the embodiment; FIG. 4 is a partially enlarged view of a two-dimensional code, which is an example of a code in which minute markers are arranged, according to the embodiment; FIG. 4 is a partially enlarged view of a two-dimensional code, which is an example of a code in which minute markers are arranged, according to the embodiment; FIG. 4 is a diagram showing a one-dimensional code, which is an example of a code in which minute markers are arranged, according to the embodiment; FIG. 4 is a partially enlarged view of a one-dimensional code, which is an example of a code in which minute markers are arranged, according to the embodiment; FIG. 4 is a diagram showing a two-dimensional code, which is an example of a code in which minute markers are arranged, according to the embodiment; FIG. 4 is a diagram showing a two-dimensional code, which is an example of a code in which minute markers are arranged, according to the embodiment; FIG. 4 is a diagram showing a two-dimensional code, which is an example of a code in which minute markers are arranged, according to the embodiment; FIG. 2 is a schematic diagram showing a printing device that prints a code on which minute markers are arranged, according to an embodiment;

Hereinafter, an embodiment of a code printed with a reader-readable identifier will be described in detail with reference to the drawings.

Fig. 1 shows a code printed with an identifier that can be read by a reader (also called a "scanner"), and a code in which minute marks are placed that cannot be recognized by the reader (hereinafter referred to as "printed code"). ) 1. FIG. 1 shows a two-dimensional code 10 that is an example of the printed code 1. As shown in FIG. Examples of the two-dimensional code 10 (two-dimensional codes 30, 40, and 50 described later are the same) include QR code (registered trademark), PDF417 (including micro PDF417, compact PDF417, etc.), DataMatrix (registered trademark) , MaxiCode, AztecCode, Code49, EAN/UPC composite (Composite), GS1DataBar (RSS) composite, and the like. QR Codes include Model 1, Model 2, Micro QR Codes, rMQR Codes, SQRC®, Frame QR®, and the like. A case where the two-dimensional code 10 (the same applies to the two-dimensional codes 30, 40, and 50 described later) is the QR code model 2 will be described below, but the present invention is not limited to this case.

The two-dimensional code 10 (the same applies to codes 20, 30, 40, and 50 described later) can be made of paper (including corrugated cardboard, paper with glue on one side (sticker), etc.), plastic (plastic film, glue on one side). (including plastic films (stickers), etc.), vinyl, or cloth (including non-woven fabrics, etc.). The printed matter constitutes, for example, the product itself, the packaging of the product, or the accessory of the product (for example, an instruction manual or a product label (including a tag)), and is distributed together with the corresponding product. In some cases, printed matter constitutes product advertisements (including flyers, etc.) or price lists, etc., and is distributed separately from the corresponding products.

The two-dimensional code 10 is composed of a central data area (symbol) S and a quiet zone Q around it. The two-dimensional code 10 is a type of identifier in which a plurality of cells constituting an identifier are two-dimensionally arranged in a symbol S and information indicated by characters is represented. The two-dimensional code 10 is obtained by converting information indicated by characters into a two-dimensional code according to certain rules. The two-dimensional code 10 can be input/output as easy-to-read digital information by a reader (for example, a two-dimensional code reader). Note that the two-dimensional code 10 may have cutout symbols, alignment patterns, and the like, which constitute identifiers, in the symbols.

In addition, in the two-dimensional code 10, a marker is arranged in at least one cell (symbol A in FIG. 1 indicates one of the cells) among a plurality of cells of the two-dimensional code 10 (see FIG. 2 (A )). The sign consists of, for example, at least one of letters (including language letters, numbers, symbols, etc.) or patterns. Language characters include characters representing a wide variety of languages, such as Japanese (including hiragana, katakana, and kanji), English (including alphabets), Chinese, Korean, French, German, It means a character that indicates a language such as Spanish, Russian, Arabic, etc. Also, for example, the sign may be composed of any one of characters and patterns, or may be composed of a combination thereof. Here, micro-characters as minute markers are also called micro-characters.

In addition, when there is a cutout symbol arranged in the symbol (symbol B in FIG. 1 indicates one of the cutout symbols), the indicator is arranged in part or all of the cutout symbol that constitutes the identifier. (Fig. 2(B), (C)). In addition, when an alignment pattern (symbol C in FIG. 1 indicates an alignment pattern) exists, the mark may be arranged partially or entirely within the alignment pattern that constitutes the identifier (FIG. 3 ( A) and (B)). In other words, the marker may be arranged only within the cut-out symbol of the two-dimensional code 10, or may be arranged only within the alignment pattern. Also, the markers may be arranged only in the cutout symbol and the alignment pattern of the two-dimensional code 10, or the markers may be arranged in the cutout symbol (or alignment pattern) and in the cell. .

2A to 2C show partially enlarged views of the two-dimensional code 10. FIG. FIG. 2A is an enlarged view of an example of the portion A of the two-dimensional code 10 shown in FIG. On the other hand, FIG. 2B is an enlarged view of a first example of portion B of the two-dimensional code 10 shown in FIG. FIG. 2C is an enlarged view of a second example of the portion B of the two-dimensional code 10 shown in FIG. FIGS. 2A to 2C are examples in which characters as signs are arranged in the two-dimensional code 10. FIG. In FIGS. 2A to 2C, the size of the characters relative to the size of the portions A and B is changed for convenience.

As shown in part A of FIG. 2(A), the two-dimensional code 10 includes, in some cells, the alphabet "R" as an example of a character as an indicator, and the color of the cell (hue, saturation and brightness). ) and a different color (for example, characters are arranged in white or a similar color in a black cell, and in black, gray, or chromatic colors in a white cell). Colors close to white include chromatic colors. The resolution of the QR code reader is not necessarily high, and the resolution that can be recognized by a general-purpose device (for example, a smartphone) is at most about 0.25 [mm]. Therefore, it is preferable to set the character size to 0.25 [mm] or less. Character sizes of 0.25 [mm] or less include 0.7 [pt], 0.6 [pt], and so on.

Assuming that the user uses a magnifying glass to read characters in a cell (for example, white characters in a black cell), if the character size is 0.25 [mm], the size is 0.25 [mm]. It is preferable that the character is arranged in a cell of 25 [mm] or more, and if the character size is 0.18 [mm], the character is arranged in a cell of 0.18 [mm] or more. It is preferred that Moreover, when the character size is larger than one cell size, the characters may be arranged across a plurality of adjacent cells. For example, when the character size is 0.25 [mm] and one cell size is 0.17 [mm], white characters are arranged across four adjacent 2×2 black cells. .

As for the characters, the product name (or its initials) of the product corresponding to the printed matter or the manufacturer name (or its initials) of the product may be printed as characters.

As shown in part B of FIG. 2(B), the two-dimensional code 10 includes a symbol “! (e.g. characters are white or close to it if they are placed in the black part of the symbol, and black, gray or chromatic if they are placed in the white part of the symbol). Colors close to white include chromatic colors. As described above, the character size is preferably 0.25 [mm] or less.

As shown in part B of FIG. 2(C), the two-dimensional code 10 includes a symbol "circle mark" and an "umbrella mark" as examples of characters in some of the cutout symbols. A color different from the color (e.g., if placed in the black part of the symbol, the letter is white or a color close to it; if placed in the white part of the symbol, the letter is black, gray, or chromatic) . Colors close to white include chromatic colors. As described above, the character size is preferably 0.25 [mm] or less.

3A and 3B show partially enlarged views of the two-dimensional code 10. FIG. FIG. 3A is an enlarged view of a first example of the portion C of the two-dimensional code 10 shown in FIG. FIG. 3B is an enlarged view of a second example of the portion C of the two-dimensional code 10 shown in FIG. 3A shows an example in which characters as indicators are arranged in the two-dimensional code 10, and FIG. 3B shows an example in which patterns as indicators are arranged in the two-dimensional code 10. FIG. In addition, in FIGS. 3A and 3B, the size of the mark with respect to the size of the portion C is changed for the sake of convenience.

As shown in part C of FIG. 3(A), the two-dimensional code 10 includes, in the alignment pattern, the kanji "bara" as an example of a character as a marker in a color different from the color of the alignment pattern (for example, the alignment pattern If placed in the black portion of the alignment pattern, the character is white or a color close to it; if placed in the white portion of the alignment pattern, the character is placed in black, gray, or a chromatic color). Colors close to white include chromatic colors. As described above, the character size is preferably 0.25 [mm] or less.

As shown in part C of FIG. 3(B), the two-dimensional code 10 has a pattern in the alignment pattern as a marker in a color different from the color of the alignment pattern (for example, a black part in the alignment pattern). If placed in white or a color close to it, the dotted line pattern is placed in black, gray, or a chromatic color if placed in a white portion within the alignment pattern. Colors close to white include chromatic colors. As described above, the pattern size is preferably 0.25 [mm] or less. That is, the pattern is arranged in each region formed in the alignment pattern and having a side of 0.25 [mm] or less. The pattern includes a striped pattern, a grid pattern, a mesh pattern, a wave pattern, a brick pattern, a checkered pattern, and the like, in addition to the dotted line pattern.

Then, the two-dimensional code 10 in which minute marks (for example, characters) shown in FIGS. 2 and 3 are arranged is printed on printed matter. On the other hand, the minute mark of the two-dimensional code 10 can only be printed by a rare printing device (for example, a printing device 60 to be described later). cannot be perfectly copied. Therefore, all products corresponding to printed matter on which two-dimensional codes without minute markings are printed can be regarded as fraudulent products. Users (for example, consumers, manufacturers and distributors of genuine products) can hardly read the marks placed on the two-dimensional code 10 with the naked eye, but can read them using a magnifying glass such as a loupe.

On the other hand, the resolution of the QR code reader that reads the two-dimensional code 10 is at most about 0.25 [mm] as described above. The mark placed on the two-dimensional code 10 has a very small size (0.25 [mm] or less), and is crushed by the periphery of the mark and recognized by the reader as a symbol S without chipping. It can be read by the reader as if the label were not present.

According to the two-dimensional code 10 described with reference to FIGS. 1 to 3, the two-dimensional code 10 can be read by a reader, while the user can purchase the product corresponding to the printed matter on which the two-dimensional code 10 is printed. It can be identified as a genuine product, and a product corresponding to a printed matter printed with a code without minute marks can be identified as a counterfeit product. Therefore, it is possible to discriminate between genuine products and fraudulent products in the distribution process, and to deter transactions of fraudulent products.

Although the two-dimensional code 10 has been described as the printed code 1, the same concept can be applied to one-dimensional codes. A one-dimensional code will be described with reference to FIGS. 4 and 5. FIG.

FIG. 4 shows a one-dimensional code 20 as an example of the printed code 1. As shown in FIG. The one-dimensional code 20 is also called a barcode.

The one-dimensional code 20 is printed on printed matter. The one-dimensional code 20 consists of a data area (bar code symbol) S in the center and quiet zones Q on the left and right. The one-dimensional code 20 is a type of identifier in which a plurality of lines (bars) forming an identifier are arranged one-dimensionally in the bar code symbol S, and the thickness of each line represents information indicating a character. The one-dimensional code 20 is obtained by converting information indicated by characters into a one-dimensional code according to certain rules. The one-dimensional code 20 can be input/output as easy-to-read digital information by a reader (for example, one-dimensional code reader).

In addition, the one-dimensional code 20 has a marker arranged within at least one of the lines of the one-dimensional code 20 . The mark is composed of, for example, at least one of characters and patterns, as described above.

5A and 5B show partially enlarged views of the one-dimensional code 20. FIG. FIG. 5A is an enlarged view of a first example of the portion D of the one-dimensional code 20 shown in FIG. On the other hand, FIG. 5B is an enlarged view of a second example of the portion D of the one-dimensional code 20 shown in FIG. FIGS. 5A and 5B are examples in which characters as signs are arranged in the one-dimensional code 20. FIG. In addition, in FIGS. 5A and 5B, the character size for the portion D is changed for the sake of convenience.

As shown in part D of FIG. 5(A), the one-dimensional code 20 has a number "1234..." as an example of characters in a part of the line as a marker in a color different from the color of the line (for example, If the line is black, the characters are placed in white or a color close to it). Colors close to white include chromatic colors. As described above, the character size is preferably 0.25 [mm] or less. Assuming that the user uses a magnifying glass to read the characters within the lines (for example, the white characters within the black lines), if the character size is 0.25 [mm], the thickness is 0.25 mm. It is preferable that the character is arranged on a line of [mm] or more, and if the character size is 0.18 [mm], the character is arranged on a line of 0.18 [mm] or more in thickness. It is preferred that

As shown in part D of FIG. 5(B), the one-dimensional code 20 has the alphabet "JPO" as an example of characters and the kanji "Japan" as an example of characters in some lines as indicators. , a color different from the line color (for example, if the line is black, the characters are white or a color close to it). Colors close to white include chromatic colors. As described above, the character size is preferably 0.25 [mm] or less.

Then, the one-dimensional code 20 in which minute marks (for example, characters) shown in FIG. 5 are arranged is printed on printed matter. On the other hand, the minute mark of the one-dimensional code 20 can only be printed by a scarce printing device (for example, a printing device 60 described later), and the one-dimensional code 20 is crushed by the periphery of the mark. cannot be perfectly copied. Therefore, all products corresponding to printed matter on which a one-dimensional code without minute markings is printed can be regarded as fraudulent products. The user can hardly read the marks placed on the one-dimensional code 20 with the naked eye, but can read them using a magnifying glass.

On the other hand, the resolution in the height direction of the barcode of the barcode reader that reads the one-dimensional code 20 is sufficiently large for the minute size (0.25 [mm] or less). The markers arranged on the line of the one-dimensional code 20 are of a very small size, and are crushed by the periphery of the marker and recognized by the reader as a straight line without chipping. can be read.

In the one-dimensional code 20, an example has been described in which characters, which are signs, are arranged within some lines, but the present invention is not limited to this case. For example, a character may be placed in a blank area sandwiched between lines and having a certain width. For example, in the one-dimensional code 20, characters are arranged as indicators in a part of the blank area in a color different from the color of the blank area (for example, if the blank area is white, the characters are black, gray, or chromatic). be done.

According to the one-dimensional code 20 described with reference to FIGS. 4 and 5, the one-dimensional code 20 can be read by a reader, while the user can select the product corresponding to the printed matter on which the one-dimensional code 20 is printed. It can be identified as a genuine product, and a product corresponding to a printed matter printed with a code without minute marks can be identified as a counterfeit product. Therefore, it is possible to discriminate between genuine products and fraudulent products in the distribution process, and to deter transactions of fraudulent products.

On the other hand, the markings may be arranged over the symbol S and the quiet zone Q of the two-dimensional code 10 shown in FIG. 1, or over the barcode symbol S and the quiet zone Q of the one-dimensional code 20 shown in FIG. may be placed. The former case will be described with reference to FIG. Incidentally, the same applies to the latter.

FIG. 6A shows a two-dimensional code 30 as an example of the printed code 1. FIG. The two-dimensional code 30 is printed on printed matter in the same manner as the two-dimensional code 10 shown in FIG. FIG. 6B is an enlarged view of an example of the portion E of the two-dimensional code 30 shown in FIG. 6A. FIG. 6B is an example of arranging characters as minute markers on the two-dimensional code 30 . In addition, in FIG. 6B, the size of the characters relative to the size of the portion E is changed for the sake of convenience.

As shown in part E of FIG. 6(B), the two-dimensional code 30 includes the symbol S (and the quiet zone Q) diagonally across the symbol S (and the quiet zone Q), and the alphabet "SAMPLE" as an example of the characters as a sign, and the background color. are arranged in different colors (eg, black, gray, or chromatic). As described above, the character size is preferably 0.25 [mm] or less. Although the characters are arranged on a diagonal straight line in FIG. 6B, the arrangement is not limited to this case. For example, the characters may be arranged on a straight line in the horizontal direction, or may be arranged on a straight line in the vertical direction. In addition, the characters may not be arranged on a straight line, may be arranged on waves, and may be arranged on a plurality of straight lines as well as on one straight line (or waves). may

Then, the two-dimensional code 30 in which minute marks (for example, characters) are arranged is printed on printed matter. On the other hand, the minute mark of the two-dimensional code 30 can only be printed by a rare printing device (for example, a printing device 60 to be described later), and is crushed by the periphery of the mark. cannot be perfectly copied. Therefore, all products corresponding to printed matter on which two-dimensional codes without minute markings are printed can be regarded as fraudulent products. A user can hardly read the signs arranged on the two-dimensional code 30 with the naked eye, but can read them using a magnifying glass.

On the other hand, the resolution of the QR code reader that reads the two-dimensional code 30 is at most about 0.25 [mm] as described above. The mark placed on the two-dimensional code 30 is of a very small size (0.25 [mm] or less), and is crushed by the periphery of the mark and recognized by the reader as a symbol S (and a plain quiet zone Q) without chipping. Therefore, the two-dimensional code 30 can be read by the reader as if the label does not exist.

According to the two-dimensional code 30 (or one-dimensional code) explained using FIG. The corresponding product can be identified as a genuine product, and the product corresponding to the printed matter on which the code with no minute mark is printed can be identified as an unauthorized product. Therefore, it is possible to discriminate between genuine products and fraudulent products in the distribution process, and to deter transactions of fraudulent products.

Also, the marker may be arranged in the quiet zone Q of the two-dimensional code 10 shown in FIG. 1 or may be arranged in the quiet zone Q of the one-dimensional code 20 shown in FIG. The former case will be described with reference to FIGS. 7 and 8. FIG. Incidentally, the same applies to the latter.

FIG. 7A shows a two-dimensional code 40 as an example of the printed code 1. FIG. The two-dimensional code 40 is printed on printed matter in the same manner as the two-dimensional code 10 shown in FIG. FIG. 7B is an enlarged view of an example of the portion F of the two-dimensional code 40 shown in FIG. 7A. FIG. 7B shows an example in which one or more, for example, two rows of characters are arranged as minute signs in the two-dimensional code 40 . In addition, in FIG. 7B, the size of the characters relative to the size of the portion F is changed for the sake of convenience.

As shown in part F of FIG. 7(B), the two-dimensional code 40 includes, over the quiet zone Q, the Kanji characters "Japan" and "Rose", which are examples of characters, as indicators, and the color of the background is different. Arranged in two rows by color (eg, black, gray, or chromatic). As described above, the character size is preferably 0.25 [mm] or less.

Further, ruled lines such as solid lines and broken lines (front ruled lines, medium thin ruled lines, star ruled lines, etc.) may be arranged over the quiet zone Q. FIG. For example, a ruled line is arranged in one line between two lines of characters in a color different from the background color (for example, black, gray, or chromatic). The thickness of the ruled line is preferably 0.25 [mm] or less in accordance with the character size.

On the other hand, FIG. 8A shows a two-dimensional code 50 as an example of the printed code 1. FIG. The two-dimensional code 50 is printed on printed matter in the same manner as the two-dimensional code 10 shown in FIG. FIG. 8B is an enlarged view of an example of the portion G of the two-dimensional code 50 shown in FIG. 8A. FIG. 8(B) shows an example in which one or more, for example, three, lines of characters as minute markers are arranged in the two-dimensional code 40 . In addition, in FIG. 8B, the size of the characters relative to the size of the portion G is changed for the sake of convenience.

As shown in part G of FIG. 8(B), the two-dimensional code 50 includes two-dimensional code 50, which includes the characters "Japan" and "Rose" as indicators over the quiet zone Q except for the four corners. are arranged in three rows with different colors (eg, black, gray, or chromatic). As described above, the character size is preferably 0.25 [mm] or less.

Then, the two-dimensional codes 40 and 50 in which minute marks (for example, characters) are arranged are printed on the printed matter. On the other hand, the minute marks of the two-dimensional codes 40 and 50 can only be printed by a rare printing device (for example, a printing device 60 to be described later), and are crushed by the periphery of the marks. Codes 40 and 50 cannot be perfectly copied. Therefore, all products corresponding to printed matter on which two-dimensional codes without minute markings are printed can be regarded as fraudulent products. A user can hardly read the marks placed on the two-dimensional codes 40 and 50 with the naked eye, but can read them using a magnifying glass. In addition, even if the user cannot read the signs placed on the two-dimensional codes 40 and 50 with the naked eye, the user can recognize the existence of the signs with the naked eye.

On the other hand, the resolution of the QR code reader that reads the two-dimensional codes 40 and 50 is at most about 0.25 [mm] as described above. The markers placed on the two-dimensional codes 40 and 50 are micro-sized (0.25 [mm] or less), and are crushed by the periphery of the marker and recognized by the reader as a plain quiet zone Q. Therefore, the two-dimensional code 40 , 50 can be read by a reader as if the label were not present.

According to the two-dimensional codes 40, 50 (or one-dimensional codes) explained using FIGS. 7 and 8, the two-dimensional codes 40, 50 can be read by a reader, while the user can The product corresponding to the printed matter on which 40 and 50 are printed can be identified as the genuine product, and the product corresponding to the printed matter on which the code with no minute mark is printed can be identified as the fraudulent product. . At that time, the user can use a magnifying glass to recognize that the two-dimensional codes 40 and 50 are legitimate. It is also possible to recognize that the dimension codes 40 and 50 are normal. Therefore, it is possible to discriminate between genuine products and fraudulent products in the distribution process, and to deter transactions of fraudulent products. The two-dimensional code 50 shown in FIG. 8 differs from the two-dimensional code 40 shown in FIG. 7 in that the four corners of the quiet zone Q have blanks (chips) in which minute signs do not exist. The presence of minute labels can be easily recognized.

Next, a printing device 60 for printing the print code 1 and a printing method using it will be described.

FIG. 9 shows a printing device 60 for printing print code 1 . The printing device 60 is a device that prints the print code 1 on a printed matter such as a sheet of paper, plastic, vinyl, or cloth. A case where the printing device 60 prints the print code 1 on paper will be described below.

The printing device 60 includes a paper feed roll 61, a continuous form 62, an endless printing plate 63, a take-up roll 64, a cutting device 65, a plate cylinder 66, an impression cylinder 67, a plate cylinder 68, and a guide. It comprises a cylinder (also called a “guide roller”) 69 and ink rolls 70 , 71 .

The printing device 60 is a rotary press type printing machine that prints the print code 1 on a continuous form 62 , which is a strip of continuous paper (roll) fed from a paper supply roll 61 , using an endless strip printing plate 63 . Note that the printing device 60 prints the entire print code 1 on the continuous paper. Alternatively, the printing device 60 may apply a mark (for example, FIG. 7 and FIG. 8) are printed. Alternatively, after a printing device (not shown) that employs a flexographic printing method prints conventional printing codes on continuous paper, the printing device 60 places a mark (for example, FIG. 2, At least one of the markers (and ruled lines) shown in FIGS. 3, 5, 6B, 7 and 8 are printed.

The printed continuous form 62 is wound on a take-up roll 64, folded in zigzags by a folding machine (not shown) and deposited, or further cut into sheets by a cutting device 65. and stored in a storage box (not shown).

The printing device 60 has a plate cylinder 66 having an endless belt-shaped printing plate 63 and an impression cylinder 67 as a receiving cylinder. The endless belt-shaped printing plate 63 is stretched between a plate cylinder 68 of a plate cylinder 66 and a free-rotating guide cylinder 69 which is a driven roller. The guide cylinder 69 is adjusted to move back and forth toward the printing cylinder 66, and the tension of the endless belt-shaped printing plate 63 is adjusted. The endless belt-shaped printing plate 63 is circumscribed by a pair of ink rolls 70 and 71 facing the printing cylinder 66, and ink is transferred onto the printing surface (plate surface) of the endless belt-shaped printing plate 63. .

The plate cylinder 68 and the impression cylinder 67a of the plate cylinder 66 are solid solid cylinders formed by cutting or the like. is used. A solid (steel) cylinder has good rotational balance, is easy to form into a perfect circle, and has a large weight (for example, 300 [kg]). Less backlash. By using a solid cylinder for the plate cylinder 68 and the impression cylinder 67a of the plate cylinder 66, it is possible to reduce the deflection due to the printing pressure, and the halftone dots are crushed or smudged even in the printing in which solids and halftone dots are mixed. It is possible to print a solid image neatly.

In addition, the endless belt-shaped printing plate 63 is appropriately selected so that the longitudinal length of one round is between several tens [cm] and several tens [m]. The endless belt-shaped printing plate 63 is formed in an endless belt shape by connecting both ends of a long, thin and flexible resin letterpress printing plate. Alternatively, a plurality of long printing plates of, for example, 400 inches may be successively connected, and finally connected at both ends to form an endless band of several meters to several tens of meters.

According to the printing device 60 shown in FIG. 9, it is possible to print the print code 1 including a minute mark on the printed matter indicating the product. Although the entire print code 1 (including minute marks) or only the minute marks of the print code 1 are printed by the printing device 60 with reference to FIG. 9, the present invention is not limited to this case. , printing apparatus and printing method. It is extremely difficult to print minute marks with precision that can be recognized with a magnifying glass by adopting a flexographic printing method or a digital printing method (for example, printing using a laser printer or an inkjet printer). . However, it is not excluded to print the entire printed code 1 or only minute marks on printed matter by flexographic printing, digital printing, or the like. In addition, even if there is a printing device that prints the entire printing code 1 or only a small mark by adopting the flexographic printing method or digital printing, it is extremely rare and versatile (widely available in the market) ), it is still a rare printing device.

According to at least one embodiment described above, it is possible to discriminate between genuine products and fraudulent products in the distribution process, and to deter transactions of fraudulent products.

While several embodiments have been described, these embodiments are provided by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, changes, and combinations of embodiments can be made without departing from the scope of the invention. These embodiments and their modifications are included in the scope and spirit of the invention, as well as the scope of the invention described in the claims and equivalents thereof.

1 ... A code (printed code) in which minute signs are arranged
10, 30, 40, 50 Two-dimensional code 20 One-dimensional code 60 Printer S Data area Q Quiet zone

Claims (6)

A two-dimensional code in which a reader-readable identifier is printed and a plurality of cells constituting the identifier are arranged two-dimensionally,
In the quiet zone of the two-dimensional code, or in the quiet zone excluding the four corners of the two-dimensional code, a row of minute marks that cannot be recognized by the reader and a line of markers that are thick enough to not be recognized by the reader Borders and are placed,
The row of signs and the ruled lines are arranged to surround the data area of the two-dimensional code,
two-dimensional code. the indicator is further arranged in at least one of the plurality of cells of the two-dimensional code;
The two-dimensional code according to claim 1. The mark is further arranged within the cut-out symbol of the two-dimensional code or within the alignment pattern,
The two-dimensional code according to claim 1. The sign is at least one of a character and a pattern,
The two-dimensional code according to any one of claims 1 to 3. The sign includes the character, and the size of the character is 0.25 [mm] or less.
The two-dimensional code according to claim 4. A two-dimensional code in which a reader-readable identifier is printed and a plurality of cells constituting the identifier are arranged two-dimensionally,
In the quiet zone of the two-dimensional code, or in the quiet zone excluding the four corners of the two-dimensional code, a ruled line with such a thickness that the reader cannot recognize its existence is arranged,
The ruled lines are arranged to surround the data area of the two-dimensional code,
two-dimensional code.