JP6798864B2 - Fraud prevention structure, labels used for it, and fraud prevention methods - Google Patents

Description

The present invention makes the machine-reading code unrecognizable when the first base material portion on which the machine-reading code is displayed is attached to the second base material portion and then peeled off from the second base material portion. Regarding the prevention structure.

Conventionally, in the label attached to the adherend, various measures have been taken to detect that the label is illegally peeled off after the attachment.

For example, when the label is attached to the adherend and then peeled off, the label is reattached to the adherend by leaving a part of the colored adhesive layer or the printing layer on the adherend side. However, a structure that leaves a trace of peeling is being considered. Further, it is conceivable that a part of the printing layer is destroyed when the label is peeled off after being attached to the adherend, so that a trace of peeling is left even when the label is reattached to the adherend. (See, for example, Patent Document 1).

Japanese Patent No. 3690673

In the above-mentioned label, a bar code or a two-dimensional code may be displayed, and the product or the like to which the label is attached may be used to manage the displayed bar code or the two-dimensional code by reading the displayed bar code or the two-dimensional code. is there. In that case, even if the product is illegally peeled off from the product as described above and then reattached to the product, the trace of the peeling can be visually confirmed, but the displayed barcode or two-dimensional code can be displayed. There is a problem that it can be read.

The present invention has been made in view of the problems of the prior art as described above, and is the first after the first base material portion on which the machine reading code is displayed is attached to the second base material portion. 2. It is an object of the present invention to provide a fraud prevention structure capable of making a machine reading code unrecognizable when peeled from a base material portion, a label used for the fraud prevention structure, and a fraud prevention method.

In order to achieve the above object, the present invention
Fraud prevention structure that makes the machine reading code unrecognizable when the first base material portion on which the machine reading code is displayed is attached to the second base material portion and then peeled off from the second base material portion. And
The machine reading code is made of infrared absorbing material
The first base material portion is
The base base material on which the machine reading code is displayed and
A metal layer laminated on the entire surface of one surface of the base base material, and at least a part of which is destroyed when the first base material portion is attached to the second base material portion and then peeled off.
It has a sticking layer laminated on the opposite side of the metal layer from the base base material.
The second base material portion has an absorption layer made of the infrared absorbing material on the entire surface of the region facing the display region of the machine reading code when the first base material portion is attached.

In the present invention configured as described above, in a state where the first base material portion and the second base material portion are firmly attached to each other, the first base material portion is used to read the machine reading code displayed on the base base material. When infrared rays are irradiated from the base material side, the irradiated infrared rays are absorbed by the machine-reading cord because the machine-reading cord is made of an infrared absorbing material, and are reflected by the metal layer in other regions. By detecting the reflected wave, the machine reading code is correctly recognized. On the other hand, when the first base material portion and the second base material portion are attached and then peeled off, at least a part of the metal layer is destroyed. After that, when the first base material portion and the second base material portion are illegally attached and infrared rays are irradiated from the first base material portion side in order to read the machine reading code, at least one of the metal layers is irradiated. Since the part is destroyed, infrared rays are transmitted through the destroyed part without being reflected, but the machine reading code of the second base material part attached to the first base material part Since an absorption layer made of an infrared absorbing material is provided on the entire surface of the region facing the display region, infrared rays transmitted through the broken portion of the metal layer are also absorbed by this absorption layer. Therefore, even if the reflected wave of the irradiated infrared rays is detected, the reflected wave is different from the reflected wave by the machine reading code, and the machine reading code cannot be recognized.

As such a fraud prevention structure, a structure in which the first base material portion and the second base material portion are integrated, or a structure in which the first base material portion and the second base material portion are configured as separate bodies. Can be considered.

Further, in the case where the first base material portion and the second base material portion are integrated, the base base material has a continuous band shape over the first base material portion and the second base material portion, and is absorbed. The layers are laminated on the same surface as the surface on which the machine-reading code of the base substrate is displayed, and the base substrate is annular so that the surface on which the machine-reading code is displayed and the absorption layer is laminated is on the outside. Then, it is conceivable that the first base material portion and the second base material portion are attached by the attachment layer in a state where the machine reading code faces the absorption layer.

According to the present invention, when the first base material portion and the second base material portion are attached and then peeled off, at least a part of the metal layer is destroyed. Therefore, after that, the first base material portion and the second base material portion and the second base material portion are destroyed. When infrared rays are irradiated from the first base material side in order to read the machine reading code while the base material is improperly attached, the irradiated infrared rays are not only the machine reading code but also the first unit. It is also absorbed by the absorption layer of the second base material that is attached to the material part, and even if the reflected wave of the irradiated infrared rays is detected, the reflected wave will be different from the reflected wave by the machine reading code. Therefore, the machine reading code can be made unrecognizable.

It is a figure which shows an example of the security band which has the 1st Embodiment of the fraud prevention structure of this invention, (a) is a surface view, (b) is the cross-sectional view of AA'shown in (a), ( c) is a figure which shows the composition of the surface of a transparent film. It is a figure which shows the usage state of the security band shown in FIG. It is sectional drawing of the vicinity of the 2D code in the use state shown in FIG. 2 of the security band shown in FIG. It is a figure for demonstrating the action when the 1st base material part and the 2nd base material part of the security band shown in FIG. 1 are attached, and then they are illegally peeled off and are attached again. It is a figure for demonstrating the operation at the time of reading the 2D code of the security band shown in FIG. It is a figure which shows an example of the security band which has the 2nd Embodiment of the fraud prevention structure of this invention, (a) is a surface view, (b) is the cross-sectional view of AA'shown in (a), ( c) is a diagram showing the structure of the surface of the transparent film 10. It is a figure which shows an example of the security band which has 3rd Embodiment of the fraud prevention structure of this invention, (a) is a surface view, (b) is a sectional view of AA'shown in (a), ( c) is a figure which shows the composition of the surface of a transparent film. It is a figure which shows the use state of the security band shown in FIG. It is a figure which shows an example of the label used in the 4th Embodiment of the fraud prevention structure of this invention, (a) is a surface view, (b) is the cross-sectional view of AA'shown in (a), ( c) is a figure which shows the composition of the surface of a transparent film. 9 is a diagram for explaining how to use the security label shown in FIG. 9, where FIG. 9A is a front view of a printed matter to which the security label shown in FIG. 9 is attached, and FIG. 9B is shown in FIG. 9A. A surface view showing a state in which the security label shown in FIG. 9 is attached to the printed matter, and (c) is a partial cross-sectional view showing a state in which the security label shown in FIG. 9 is attached to the printed matter shown in (a). Is.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(First Embodiment)
FIG. 1 is a diagram showing an example of a security band having the first embodiment of the fraud prevention structure of the present invention, in which (a) is a front view and (b) is AA'shown in (a). The cross-sectional view, (c) is a figure which shows the composition of the surface of the transparent film 10.

As shown in FIG. 1, this embodiment is a band-shaped security band 1 in which the first base material portion 2 and the second base material portion 3 are continuously integrated.

In the security band 1, a two-dimensional code 12 which is a machine reading code is displayed in a region of the first base material portion 2 on one surface of the strip-shaped transparent film 10 which is a base base material, and the second base material is displayed. A solid printing layer 13 serving as an absorption layer is laminated on the region serving as the material portion 3. The two-dimensional code 12 and the solid printing layer 13 are displayed and laminated by printing using an ink containing carbon, which is an infrared absorbing material. A printing layer 21 made of white ink that does not contain an infrared absorbing material is laminated on the surface on which the two-dimensional code 12 of the transparent film 10 is displayed and the solid printing layer 13 is laminated, and the printing thereof is further performed. The print layer 22 is laminated on the layer 21 by displaying information using an ink that does not contain an infrared absorbing material. Although the two-dimensional code 12 is hidden by these print layers 21 and 22, the code recognition unit 2a facing the two-dimensional code 12 can be recognized by the information displayed by the print layer 22.

The release layer 40 is partially laminated on the surface of the transparent film 10 opposite to the two-dimensional code 12 and the solid print layer 13 by applying a pattern coating of a release agent. Further, aluminum is vapor-deposited over the release layer 40 on the entire surface of the transparent film 10 opposite to the two-dimensional code 12 and the solid printing layer 13, so that the aluminum-deposited layer 30 as a metal layer is laminated. Has been done.

The sticking layer 50 is laminated on the surface of the aluminum vapor deposition layer 30 opposite to the laminating surface with the transparent film 10 by applying an adhesive or an adhesive on the entire surface thereof, and the sticking layer 50 is laminated through the sticking layer 50. The release paper 60 is detachably attached.

The release paper 60 is formed with slits 61 penetrating the front and back at the boundary between the first base material portion 2 and the second base material portion 3.

The usage of the security band 1 configured as described above will be described below.

First, the usage state of the security band 1 shown in FIG. 1 will be described.

FIG. 2 is a diagram showing a usage state of the security band 1 shown in FIG. FIG. 3 is a cross-sectional view of the security band 1 shown in FIG. 1 in the vicinity of the two-dimensional code 12 in the used state shown in FIG.

When the security band 1 shown in FIG. 1 is used, first, the region of the release paper 60 on the side of the first base material portion 2 is peeled off through the slit 61, and the adhesive layer 50 is peeled off in the first base material portion 2. Is expressed.

Then, as shown in FIG. 2, the release paper 60 is annularly wound around the arm 4 so as to be inside, and the surface on which the print layer 22 of the second base material portion 3 is laminated by the exposed adhesive layer 50. The first base material portion 2 is attached onto the top. It is also conceivable to attach another base material such as a film to the region of the release paper 60 on the side of the second base material portion 3 via the slit 61. In that case, by using a material that is safe to touch the skin as the base material to be bonded, abnormalities such as pain and itchiness occur on the skin when wrapped around the arm 4 as shown in FIG. You can avoid it.

In a state where the security band 1 is wrapped around the arm 4 and the first base material portion 2 is attached to the second base material portion 3, as shown in FIG. 3, the first base unit is placed on the second base material portion 3. The material parts 2 are in a laminated state. That is, in the second base material portion 3, the solid printing layer 13 is laminated on the entire surface of the region facing the display area of the two-dimensional code 12 when the first base material portion 2 is attached. Become. By holding the bar code reader over the code recognition unit 2a in this state, the two-dimensional code 12 is read and recognized by the infrared rays that are the reading light emitted from the bar code reader.

Next, the action when the first base material portion 2 is attached to the second base material portion 3 as described above, and then they are illegally peeled off and reattached will be described.

FIG. 4 illustrates the action when the first base material portion 2 and the second base material portion 3 of the security band 1 shown in FIG. 1 are attached and then illegally peeled off and reattached. It is a figure for this, and shows the cross section in the vicinity of a two-dimensional code 12.

When the first base material portion 2 and the second base material portion 3 of the security band 1 shown in FIG. 1 are attached and then peeled off, the peeling layer 40 is formed as shown in FIG. 4 (a). In the laminated region, the release layer 40 is peeled from the transparent film 10 in the first base material portion 2, and in the region where the release layer 40 is not laminated, the adhesive layer 50 of the first base material portion 2 is peeled off. Is peeled off from the printing layer 22 of the second base material portion 3.

Then, when the first base material portion 2 and the second base material portion 3 are completely peeled off, the aluminum vapor deposition layer 30 and the sticking layer 50 of the first base material portion 2 are shown as shown in FIG. 4 (b). In the region where the release layer 40 of the first base material portion 2 was laminated, the aluminum vapor deposition layer 30, the attachment layer 50 and the release layer 40 remained attached to the second base material portion 3. In the region where the release layer 40 of the first base material portion 2 is not laminated, the aluminum vapor deposition layer 30 and the sticking layer 50 are separated from the second base material portion 3 together with the first base material portion 2.

Then, on the first base material portion 2 peeled from the second base material portion 3, a portion where the aluminum vapor deposition layer 30 is still laminated and a portion where the aluminum vapor deposition layer 30 is peeled off from the first base material portion 2 are formed. It will be mixed. As a result, the color of the first base material portion 2 differs depending on the presence or absence of the aluminum vapor deposition layer 30 according to the coating pattern of the release layer 40.

After that, even if the first base material portion 2 peeled from the second base material portion 3 is to be reattached to the second base material portion 3, the coating pattern of the peeling layer 40 is fine, so that the first base unit The material portion 2 and the second base material portion 3 could not be adhered neatly, and the portion where the aluminum vapor deposition layer 30 was still laminated and the aluminum vapor deposition layer 30 were separated from the first base material portion 2. As shown in FIG. 4C, the first base material portion 2 and the second base material reattached were reattached because the boundary portion with the portion did not become clean according to the coating pattern of the release layer 40. A gap 31 is formed between the portion 3 and the aluminum vapor deposition layer 30 without intervening. As a result, it is detected that the first base material portion 2 and the second base material portion 3 are illegally peeled off and reattached after the first base material portion 2 and the second base material portion 3 are attached, particularly due to the difference in color in the gap 31. It will be.

Next, the operation when reading the two-dimensional code 12 will be described.

FIG. 5 is a diagram for explaining an operation when reading the two-dimensional code 12 of the security band 1 shown in FIG.

In the security band 1 shown in FIG. 1, in a state where the first base material portion 2 and the second base material portion 3 are firmly attached to each other, the two displayed on the first base material portion 2 of the transparent film 10 When infrared rays are irradiated from the first base material portion 2 side in order to read the dimensional code 12, as shown in FIG. 5A, the irradiated infrared rays are the infrared rays of the two-dimensional code 12 in the two-dimensional code 12. The two-dimensional code 12 is correctly recognized by being absorbed by being made of an absorbent material, being reflected by the aluminum vapor deposition layer 30 in other regions, and detecting the reflected wave.

On the other hand, when the first base material portion 2 and the second base material portion 3 are attached and then peeled off, the aluminum vapor deposition layer 30 of the first base material portion 2 is destroyed as described above, and then the aluminum vapor deposition layer 30 is destroyed. Even if the first base material portion 2 peeled off from the second base material portion 3 is reattached to the second base material portion 3, the reattached first base material portion 2 and the second base material portion 3 There is a gap 31 between which the aluminum vapor deposition layer 30 does not intervene. Therefore, as shown in FIG. 5B, when infrared rays are irradiated from the first base material portion 2 side in order to read the two-dimensional code 12, the gap 31 created by the destruction of the aluminum vapor deposition layer 30 Will allow infrared rays to pass through without being reflected. At that time, in the second base material portion 3 attached to the first base material portion 2, when the first base material portion 2 is attached, the entire surface of the region facing the display area of the two-dimensional code 12 is covered. Since the solid printing layer 13 is laminated, the infrared rays transmitted through the gap 31 generated by the destruction of the aluminum vapor deposition layer 30 are also absorbed by the solid printing layer 13. As a result, even if the reflected wave of the irradiated infrared rays is detected, the reflected wave is different from the reflected wave by the two-dimensional code 12, and the two-dimensional code 12 becomes unrecognizable.

As described above, in the security band 1 of the present embodiment, if the first base material portion 2 and the second base material portion 3 are attached and then peeled off, the aluminum vapor deposition layer 30 is destroyed. When infrared rays are emitted from the first base material portion 2 side in order to read the two-dimensional code 12 in a state where the first base material portion 2 and the second base material portion 3 are illegally attached, the irradiated infrared rays are emitted. Is absorbed not only by the two-dimensional code 12 but also by the solid printing layer 13 of the second base material portion 3, and even if the reflected infrared wave emitted is detected, the reflected wave is regarded as the reflected wave by the two-dimensional code 12. Will be different, thereby making the 2D code 12 unrecognizable.

When the aluminum vapor deposition layer 30 is peeled off from the state in which the first base material portion 2 and the second base material portion 3 are attached by pattern coating the release agent on the transparent film 10. Although it will be destroyed over the entire surface, at least a region facing the two-dimensional code 12 when the first base material portion 2 and the second base material portion 3 are peeled off from the stuck state. It suffices if it is configured so that a part of is destroyed.

Further, in the present embodiment, as the metal layer, the aluminum vapor deposition layer 30 laminated by depositing aluminum on the transparent film 10 has been described as an example, but gold or silver ink is used. May be good.

Further, as long as the solid printing layer 13 contains carbon, the color of the ink is not limited to black, and black of cyan, magenta, yellow, and black may contain carbon. Further, in the second base material portion 3, carbon-containing ink may be used as the ink constituting the print layers 21 and 22. However, it is necessary to laminate the print layers 21 and 22 using an ink that does not contain carbon only in the region facing the two-dimensional code 12.

(Second Embodiment)
6A and 6B are views showing an example of a security band having a second embodiment of the fraud prevention structure of the present invention, in which FIG. 6A is a front view and FIG. 6B is an AA'shown in FIG. 6A. The cross-sectional view, (c) is a figure which shows the composition of the surface of the transparent film 10.

In this embodiment, as shown in FIG. 6, a cushion layer 70 having an irreversible elastic change property is laminated between the aluminum vapor deposition layer 30 and the attachment layer 50 with respect to the security band 1 shown in FIG. It is a security band 101.

The security band 101 of this embodiment is used in the same manner as that shown in FIG. 1, but when the first base material portion 2 and the second base material portion 3 are attached and then peeled off, the security band 101 is used. Although the aluminum vapor deposition layer 30 is destroyed, the cushion layer 70 is laminated, so that the aluminum vapor deposition layer 30 is not kept attached to the second base material portion 3 even in the region where the release layer 40 is laminated. However, since the aluminum vapor deposition layer 30 is broken as in the case of FIG. 1, infrared rays are transmitted without being reflected in the portion where the aluminum vapor deposition layer 30 is broken, and the second base material portion 3 It is absorbed by the solid printing layer 13, and the two-dimensional code 12 can be made unrecognizable.

(Third Embodiment)
7A and 7B are views showing an example of a security band having a third embodiment of the fraud prevention structure of the present invention, in which FIG. 7A is a front view and FIG. 7B is an AA'shown in FIG. The cross-sectional view, (c) is a figure which shows the composition of the surface of the transparent film 10.

As shown in FIG. 7, this embodiment is a band-shaped security band 201 in which the first base material portion 202 and the second base material portion 203 are continuously integrated in the same manner as that shown in FIG. ..

In the security band 201, the bar code 212, which is a machine reading code, is displayed in the region of the first base material portion 202 on one surface of the strip-shaped transparent film 10 serving as the base base material, and the second base material is displayed. A solid printing layer 13 serving as an absorption layer is laminated in the region serving as the portion 203. The barcode 212 and the solid printing layer 13 are displayed and laminated by printing using an ink containing carbon, which is an infrared absorbing material. A printing layer 21 made of colored ink that does not contain an infrared absorbing material is laminated on the surface on which the bar code 212 of the transparent film 10 is displayed and the solid printing layer 13 is laminated. Although the barcode 212 is hidden by the print layer 21, the code recognition unit 202a facing the barcode 212 can be recognized by the information displayed by the print layer 21.

Similar to the one shown in FIG. 1, the release layer 40 is partially laminated on the surface of the transparent film 10 opposite to the barcode 212 and the solid print layer 13 by applying a pattern coating of the release agent. ing. Further, the aluminum vapor deposition layer 30 which is a metal layer is laminated on the entire surface of the transparent film 10 opposite to the barcode 212 and the solid printing layer 13 by depositing aluminum over the release layer 40. ing.

The sticking layer 50 is laminated on the surface of the aluminum vapor deposition layer 30 opposite to the laminating surface with the transparent film 10 by applying an adhesive or an adhesive on the entire surface thereof, and the sticking layer 50 is laminated through the sticking layer 50. The release paper 60 is detachably attached.

The release paper 60 is formed with slits 61 penetrating the front and back at the boundary between the first base material portion 2 and the second base material portion 3.

The usage of the security band 201 configured as described above will be described below.

FIG. 8 is a diagram showing a usage state of the security band 201 shown in FIG. 7.

When the security band 201 shown in FIG. 7 is used, first, the region of the release paper 60 on the side of the first base material portion 202 is peeled off through the slit 61, and the adhesive layer 50 is peeled off in the first base material portion 202. Is expressed.

Then, as shown in FIG. 8, the release paper 60 is hung around the delivered product 205 so as to be on the inside, and the exposed adhesive layer 50 is placed on the surface on which the print layer 21 of the second base material portion 203 is laminated. The first base material portion 2 is attached to the surface.

After that, when the first base material portion 202 and the second base material portion 203 are peeled off, the aluminum vapor deposition layer 30 is destroyed in the same manner as that shown in FIG. As a result, even if the first base material portion 202 peeled off from the second base material portion 203 is reattached to the second base material portion 203 in that state, the first base material is used to read the barcode 212 in that state. When infrared rays are irradiated from the portion 202 side, the irradiated infrared rays are absorbed by the barcode 212, and in the region where the aluminum vapor deposition layer 30 is destroyed, the infrared rays are transmitted without being reflected, and the second unit. It will be absorbed by the solid printing layer 13 laminated on the material portion 203. Therefore, even if the reflected wave of the irradiated infrared rays is detected, the reflected wave is different from the reflected wave by the barcode 212, and the barcode 212 cannot be recognized.

(Fourth Embodiment)
9A and 9B are views showing an example of a label used in the fourth embodiment of the fraud prevention structure of the present invention, in which FIG. 9A is a front view and FIG. 9B is an AA'shown in FIG. 9A. The cross-sectional view, (c) is a figure which shows the composition of the surface of the transparent film 10.

As shown in FIG. 9, the label in the present embodiment serves as the first base material portion in the present invention, and like the first base material portion 2 shown in FIG. 1, the transparent film 10 serving as the base base material. A two-dimensional code 12 serving as a machine-reading code is displayed on one surface, and a print layer 21 made of colored ink that does not contain an infrared absorbing material is laminated in a state of hiding the two-dimensional code 12. Further, the security label 301 is formed by laminating a release layer 40, an aluminum vapor deposition layer 30 as a metal layer, and a sticking layer 50 on the other surface of the transparent film 10, and sticking the release paper 60 so as to be peelable.

The two-dimensional code 12 is displayed and laminated on one surface of the transparent film 10 by printing using an ink containing carbon, which is an infrared absorbing material.

The release layer 40 is partially laminated on the surface of the transparent film 10 opposite to the two-dimensional code 12 by applying a pattern coating of a release agent. The aluminum vapor deposition layer 30 is laminated on the entire surface of the transparent film 10 opposite to the two-dimensional code 12 by covering the release layer 40 and depositing aluminum. The sticking layer 50 is laminated on the surface of the aluminum vapor deposition layer 30 opposite to the laminating surface with the transparent film 10 by applying an adhesive or an adhesive on the entire surface thereof. The release paper 60 is detachably attached via the 50.

The usage of the security label 301 configured as described above will be described below.

10A and 10B are views for explaining how to use the security label 301 shown in FIG. 9, FIG. 10A is a front view of a printed matter to which the security label 301 shown in FIG. 9 is attached, and FIG. A front view showing a state in which the security label 301 shown in FIG. 9 is attached to the printed matter shown in (a), and (c) shows the security label 301 shown in FIG. 9 attached to the printed matter shown in (a). It is a partial cross-sectional view which shows the state which was done.

The printed matter to which the security label 301 shown in FIG. 9 is attached is the second base material portion in the present invention, and as shown in FIG. 10A, a part of one surface of the sheet 305a. The solid printing layer 313 is laminated in this region by printing with an ink containing carbon, which is an infrared absorbing material.

When the security label 301 shown in FIG. 9 is used, the release paper 60 is peeled off to expose the adhesive layer 50, and as shown in FIG. 10 (b), the printed matter 305 shown in FIG. 10 (a). It is used by sticking it on the solid print layer 313 by the sticking layer 50. That is, in the fraud prevention structure according to this embodiment, the first base material portion and the second base material portion are configured as separate bodies.

When the security label 301 is attached on the solid print layer 313 of the printed matter 305, as shown in FIG. 10 (c), the display area of the two-dimensional code 12 of the security label 301 and the solid print layer of the printed matter 305. It will face 313. That is, in the printed matter 305, when the security label 301 is affixed, the solid print layer 13 is laminated on the entire surface of the area facing the display area of the two-dimensional code 12. By holding the barcode reader over the security label 301 in this state, the two-dimensional code 12 is read and recognized.

After that, when the security label 301 is peeled off from the printed matter 305, the aluminum vapor deposition layer 30 is formed as in the case where the first base material portion 2 and the second base material portion 3 of the security band 1 shown in FIG. 1 are peeled off. It will be destroyed. As a result, even if the security label 301 peeled off from the printed matter 305 is reattached on the solid print layer 313 of the printed matter 305, infrared rays are irradiated from the security label 301 side in order to read the two-dimensional code 12 in that state. Then, the irradiated infrared rays are absorbed by the two-dimensional code 12, and in the region where the aluminum vapor deposition layer 30 is destroyed, the infrared rays are transmitted without being reflected and absorbed by the solid print layer 313 of the printed matter 305. Will be done. Therefore, even if the reflected wave of the irradiated infrared rays is detected, the reflected wave is different from the reflected wave by the two-dimensional code 12, and the two-dimensional code 12 cannot be recognized.

In this embodiment, as the second base material portion to which the security label 301 is attached, a printed matter 305 in which 313 such as solid printing is laminated on the sheet 305a has been described as an example, but it has been described on the card base material. It is also conceivable to use a card in which solid print layers are laminated and use it as a security card.

Further, in the above-described embodiment, the two-dimensional code 12 and the bar code 212 have been described as examples as the machine reading code, but the machine reading code is not limited to these, and the optical character recognition (OCR: Optical character) is not limited to these. It may be a character or a number read by a recognition) technique.

1,101,201 Security band 2,202 First base material part 2a, 202a Code recognition part 3,203 Second base material part 4 Arms 10 Transparent film 12 Two-dimensional code 13,313 Solid print layer 21,22 Print layer 30 Aluminum vapor deposition layer 31 Gap 40 Release layer 50 Adhesive layer 60 Release paper 61 Slit 70 Cushion layer 212 Bar code 205 Transport 301 Security label 305 Printed matter 305a Sheet

Claims (6)

Fraud prevention structure that makes the machine reading code unrecognizable when the first base material portion on which the machine reading code is displayed is attached to the second base material portion and then peeled off from the second base material portion. And
The machine reading code is made of infrared absorbing material
The first base material portion is
The base base material on which the machine reading code is displayed and
A metal layer laminated on the entire surface of one surface of the base base material, and at least a part of which is destroyed when the first base material portion is attached to the second base material portion and then peeled off.
It has a sticking layer laminated on the opposite side of the metal layer from the base base material.
The second base material portion has an anti-fraud structure having an absorption layer made of the infrared absorbing material on the entire surface of a region facing the display region of the machine reading code when the first base material portion is attached. .. In the fraud prevention structure according to claim 1,
A fraud prevention structure in which the first base material portion and the second base material portion are integrated. In the fraud prevention structure according to claim 2,
The base base material has a continuous strip shape extending over the first base material portion and the second base material portion.
The absorption layer is laminated on the same surface as the surface of the base substrate on which the machine reading code is displayed.
The base base material is annular so that the machine-reading code is displayed and the surface on which the absorption layer is laminated is on the outside, and the first group is in a state where the machine-reading code faces the absorption layer. An fraud prevention structure in which a material portion and the second base material portion are attached by the attachment layer and used. In the fraud prevention structure according to claim 1,
A fraud prevention structure in which the first base material portion and the second base material portion are configured as separate bodies. The machine-reading code is displayed and configured, and the machine-reading code is unrecognizable when the absorption layer made of an infrared absorbing material is attached to an adherend laminated on the surface and then peeled off from the adherend. It is a label that becomes
The machine reading code is made of infrared absorbing material
The base base material on which the machine reading code is displayed and
A metal layer that is laminated over the entire surface of one surface of the base substrate, and at least a part of the label is destroyed when the label is attached to the adherend and then peeled off.
A label having a sticking layer laminated on the opposite side of the metal layer from the base base material. When the first base material portion on which the machine reading code made of an infrared material is displayed is attached to the second base material portion and then peeled off from the second base material portion, the machine reading code cannot be recognized. It is a fraud prevention method to do
The first base material portion is set to the second base material portion so that the display region of the machine reading code in the first base material portion faces the absorption layer made of the infrared material provided in the second base material portion. Attached to
By peeling the first base material portion from the second base material portion, a metal layer laminated on the entire surface of one surface of the base base material on which the machine reading code of the first base material portion is displayed is formed. Destroy at least part,
A fraud prevention method that recognizes a machine-reading code by irradiating the machine-reading code with infrared rays.

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