KR102378182B1 - Means Preventing Forgery and Falsification Using Light Polarizing Layer and Piezochromic Fluorescence Layer - Google Patents

Abstract

The present invention is a substrate; a design printing layer located on the upper side of the substrate and having a specific shape printed thereon; a cholesteric liquid crystal display layer positioned on the design print layer and printed with a hidden shape; and an autochromic fluorescent layer positioned on the cholesteric liquid crystal display layer. In the case of checking whether forgery or not by illuminating the smart phone screen light on the forgery prevention means of the present invention or applying pressure to the forgery prevention means, the forgery is very difficult, easy to manufacture, and inexpensive. It provides the advantage of being able to detect forgery even without a forgery checking device.

Description

Means Preventing Forgery and Falsification Using Light Polarizing Layer and Piezochromic Fluorescence Layer

The present invention relates to a forgery prevention means comprising a pressure discoloration layer and a polarizing layer, and more particularly, to a substrate, a design printed layer located above the substrate, a cholesteric liquid crystal display layer located above the design printed layer, and It relates to a forgery prevention means including a pressure-change fluorescent layer positioned on the cholesteric liquid crystal display layer.

Various technologies have been introduced to prevent counterfeiting and alteration of expensive goods or goods that require authenticity of contents. Conventionally, techniques using mainly fine patterns, braille, holograms, RFID, etc. have been used to prevent counterfeiting and falsification of products, but these prior technologies have limitations in that it is not easy for general users to distinguish whether or not products are forged or tampered with. It has or has a problem in that it takes a lot of money to manufacture counterfeit and tamper-proof means.

As for the anti-counterfeiting technology, the technology that can be easily checked by the general consumer (Overt) should be given priority, but as the technology for copying is also developed gradually, the manufacturer/supplier additionally hides the anti-counterfeiting technology (Covert) Security technology that can double check when a counterfeit product is detected by applying high

Covert technology for preventing forgery and falsification at home and abroad uses a lot of infrared and ultraviolet light emitting materials, but most of them only show one color change after coating the ink itself, so the difficulty of the technology itself is not high, so there are concerns about forgery.

Recently, interest in technology enabling fluorescence control in a solid phase is increasing. Among them, there is a piezochromic fluorescence technology. Due to pressure or physical force, secondary bonding force between molecules such as pi-pi interaction, hydrogen bonding, and van der Waals force of the chemical structure of a substance changes, resulting in changes in fluorescence color or intensity, heat treatment, etc. It is a phenomenon that returns to the original fluorescence through

In other words, there is a strong hydrogen bond in the crystal that emits red fluorescence, and when pressure is applied from the outside, the hydrogen bond is broken and the molecular packing structure is changed and the phenomenon is changed to green fluorescence. Depending on the intrinsic structural characteristics of a molecule, it may move to a short wavelength or a long wavelength after pressure is applied. Here, pressure means that a certain force is applied to a plane, line, or point.

Looking at the patent literature related to the forgery prevention means including the pressure-changeable fluorescent layer, in KR Patent Application No. 10-2015-7018809 (Title of the invention: composition for credit documents and security documents using the same), it is in the form of a liquid or paste before drying. , a composition for credit documents characterized in that it comprises a printing matrix, preferably colorless, and a reversible mechanoluminescent compound having the formula (A):

Formula A

In KR Patent Application No. 10-2012-0092319 (Title of the Invention: Optical element for security element of value certificate), a fluorescent material layer; and a photonic crystal layer laminated on the fluorescent material layer to provide an optical band gap; it discloses an optical device for a security element comprising a certificate of value.

However, in the case of the above-mentioned patent documents, although there is an advantage in that it is difficult to forge a print, there is a disadvantage in that a method of manufacturing the print is complicated and the production cost is excessively required.

Numerous papers and patent documents are referenced throughout this specification and their citations are indicated. The disclosures of the cited papers and patent documents are incorporated herein by reference in their entirety to more clearly describe the level of the technical field to which the present invention pertains and the content of the present invention.

The inventors of the present invention made intensive research efforts to develop a forgery prevention means capable of detecting forgery and falsification even without a separate forgery confirmation device as well as forgery is very difficult, manufacturing is simple, and manufacturing cost is low. As a result, the light of the smartphone screen is applied to the forgery prevention means including the substrate, the printed layer on the substrate, the cholesteric liquid crystal display layer on the printed layer, and the autochromic fluorescent layer on the cholesteric liquid crystal display layer. When checking whether forgery or not by illuminating or applying pressure to a means to prevent forgery, counterfeiting is very difficult, easy to manufacture, and inexpensive to manufacture, and it is possible to identify forgery and falsification without a separate device for checking forgery other than a smartphone. The present invention was completed by finding the facts.

Accordingly, it is an object of the present invention to provide a forgery prevention means including a pressure-changeable fluorescent layer and a polarizing layer.

Other objects and advantages of the present invention will become more apparent from the following detailed description of the invention, claims and drawings.

The present invention provides a forgery prevention means.

The inventors of the present invention made intensive research efforts to develop a forgery prevention means capable of detecting forgery and falsification even without a separate forgery confirmation device as well as forgery is very difficult, manufacturing is simple, and manufacturing cost is low. As a result, the light of the smartphone screen is applied to the forgery prevention means including the substrate, the printed layer on the substrate, the cholesteric liquid crystal display layer on the printed layer, and the autochromic fluorescent layer on the cholesteric liquid crystal display layer. When checking whether forgery or not by illuminating or applying pressure to a means to prevent forgery, counterfeiting is very difficult, easy to manufacture, and inexpensive to manufacture, and it is possible to identify forgery and falsification without a separate device for checking forgery other than a smartphone. fact confirmed.

According to one aspect of the present invention, the present invention provides a substrate; a design printing layer located on the upper side of the substrate and having a specific shape printed thereon; a cholesteric liquid crystal display layer positioned on the design print layer and printed with a hidden shape; and an autochromic fluorescent layer positioned on the cholesteric liquid crystal display layer.

As used herein, the term 'barochromic fluorescence' may refer to any material whose original fluorescence wavelength changes when a physical pressure is applied.

As used herein, the term 'polarizing material' refers to any material that can detect a specific color, shape, or change in color and shape when polarized light is irradiated to a material compared to a state in which polarized light is not irradiated. can mean

As used herein, the term 'cholesteric liquid crystal' may refer to a liquid crystal in which each layer of molecules arranged in a plane is rotating in a spiral shape.

As used herein, the term 'computer' may refer to a device that processes various types of data using an electronic circuit.

As used herein, the term 'QR code' may refer to a code of a two-dimensional (matrix) format that contains various information in various combinations of printed patterns made of various types of circular or square dots.

The term 'forgery' used in this specification may refer to any act of creating a new non-existing object for the purpose of use by an unauthorized person, or any act of making changes to an existing object without authorization.

According to a preferred aspect of the present invention, the chromosomal fluorescent layer of the present invention may preferably include a chromochromic fluorescent material.

According to a preferred aspect of the present invention, the chromosomal fluorescent layer of the present invention may include a chromosomal fluorescent material having a pi-conjugated system.

According to a preferred aspect of the present invention, the pi-conjugated fluorescent material having the pi-conjugated system of the present invention preferably has at least one benzene ring, which is a pi system, bonded to both sides of the basic skeleton, and an electron-donating group; It can have at least one group that accepts electrons.

According to a preferred aspect of the present invention, the basic skeleton of the present invention is preferably selected from the group comprising fluorene, carbazole, dithienosilole and anthracene. there is.

According to a preferred embodiment of the present invention, the electron-donating group of the present invention preferably includes an alkyl amine group, an aryl amino group, an alkyl alkoxide group, and mixtures thereof. can be selected from the group that

According to a preferred aspect of the present invention, the electron accepting group of the present invention is preferably a cyano group, a nitro group, a fluoroalkyl group having one or more carbons, and mixtures thereof. It can be selected from the group comprising.

According to a preferred aspect of the present invention, the barometric fluorescent material of the present invention may preferably contain 0.01-5.0% by weight of the barometric fluorescent layer.

When the barometric fluorescent material contains less than 0.01% by weight, the barometric fluorescence effect may be insignificant, and when the barometric fluorescent material is included in excess of 5.0% by weight, there is a problem in that transparency may be lowered.

According to a preferred aspect of the present invention, the autochromic fluorescent material of the present invention may preferably include the following characteristics: (a) average particle diameter: 10-150 nm; and (b) fluorescence wavelength: 450-650 nm.

According to a preferred aspect of the present invention, the autochromic fluorescent layer of the present invention may preferably include the following characteristics: (a) visible light transmittance: 75-95%; (b) thickness for pressure discoloration: 1-100 μm; and (c) the pressure at which the color change is observed: greater than or equal to the pressure corresponding to the 4B pencil hardness value when pressure is applied with a pencil hardness machine.

According to a preferred aspect of the present invention, the cholesteric liquid crystal display layer of the present invention preferably includes a first display layer and a second display layer, and at least one of the first display layer and the second display layer is It may be printed with ink containing cholesteric liquid crystal.

According to a preferred aspect of the present invention, the first display layer and the second display layer of the present invention may be preferably printed in the same color.

According to a preferred aspect of the present invention, the first display layer and the second display layer of the present invention are each printed with an ink containing a cholesteric liquid crystal, and each of the cholesteric liquid crystals has a different orientation. can

According to a preferred aspect of the present invention, the ink containing the cholesteric liquid crystal of the present invention may preferably contain 5-50% of the cholesteric liquid crystal based on the weight of the ink.

According to a preferred aspect of the present invention, the ink containing the cholesteric liquid crystal of the present invention may include an oil solvent and an organic polymer.

According to a preferred aspect of the present invention, the oily solvent of the present invention is preferably N-methylpyrrolidone (N-methylpyrrolidone), methylethyl ketone (Methylethyl ketone), toluene (toluene), cyclohexanone (cyclohexanone) and It may be an oily solvent selected from the group containing mixtures thereof.

According to a preferred aspect of the present invention, the organic polymer of the present invention is preferably a polyurethane-based polymer, a polyvinylalcohol-based polymer, a polyacryl-based polymer, and a group comprising a mixture thereof can be selected from

According to a preferred embodiment of the present invention, the thickness of the cholesteric liquid crystal display layer of the present invention may be preferably 1-15 μm.

According to a preferred aspect of the present invention, the cholesteric liquid crystal of the present invention may preferably be mixed with a complementary fluorescent dye or a nematic liquid crystal.

In the present invention, it is very important that the cholesteric liquid crystal is mixed with a complementary fluorescent dye or a nematic liquid crystal. Because, when a complementary fluorescent dye is added to the cholesteric liquid crystal, the color seen by the eye and the color after authentication can be different, and the color after authentication can be adjusted by mixing the nematic liquid crystal with the cholesteric liquid crystal and adjusting the polarization orientation angle. Because this can be done differently.

According to a preferred aspect of the present invention, an adhesive layer and a stretched film layer may be further included on the display layer of the present invention.

According to another aspect of the present invention, the present invention provides a forgery prevention medium including a polarizing material and a chromochromic fluorescent material, and a specific shape for determining whether forgery or not is printed on the forgery prevention medium, and whether the forgery or not is 1) polarized A method of irradiating a forgery confirmation means capable of irradiating the forgery and falsification detection means to the forgery prevention medium, 2) a method of confirming using a polarizing film, and 3) a method of applying pressure to the forgery prevention medium. provide preventive measures.

According to a preferred aspect of the present invention, the anti-counterfeiting medium of the present invention may be preferably a label, a sticker, a packaging material or a paint.

According to a preferred aspect of the present invention, the specific shape capable of discriminating whether the forgery or not of the present invention may be a barcode or QR code, and most preferably, a QR code.

In the present invention, it is a very important configuration that the most desirable specific shape for determining whether the forgery or not is the QR code. This is because, when a specific shape is a QR code, not only can the screen of a smartphone, etc. be easily converted to a dedicated screen that can identify whether or not forgery has been made, but also it is possible to check whether the first forgery or not by the QR code recognition itself.

According to a preferred aspect of the present invention, a separate identification shape that can be identified by polarized light generated on a screen of a smartphone, etc. may be preferably printed on the specific shape of the present invention.

In the present invention, it is a very important configuration that a separate identification shape that can be identified by polarized light generated on a screen such as a smartphone is printed on the specific shape. This is because, when a separate identification shape that can be identified by the polarized light generated on the screen of a smartphone, etc. is printed on a specific shape, a means for checking whether or not forgery or not separately from the QR code can be provided.

According to a preferred aspect of the present invention, the forgery checking means of the present invention may be preferably selected from the group comprising a smartphone, a tablet PC, a monitor and an LCD TV, and more preferably a smartphone or tablet PC. may be, and most preferably may be a smartphone.

It is a very important configuration that the most preferable forgery checking means in the present invention is a smartphone. This is because, when using a smartphone, the QR code can be easily photographed using the camera mounted on the smartphone, and the polarized light can be sufficiently generated on the liquid crystal screen, and the size is small, so it is only possible to check whether forgery or not. This is because it is easy to check whether forgery or not using the screen.

According to a preferred aspect of the present invention, the forgery checking means of the present invention preferably uses the screen portion of the forgery checking means selected from the group comprising the smart phone, tablet PC, monitor and LCD TV to prevent the forgery of the medium It may be confirmed by irradiating light generated from the screen portion.

In the present invention, it is a very important configuration to check by irradiating the polarized light generated from the screen portion to the forgery prevention medium using the screen portion of the smartphone, which is a forgery confirmation means. Because the polarized light generated from the screen part of the smartphone passes through or reflects the polarizing material included in the forgery prevention medium, the color and/or shape of the identification shape is changed so that the identification shape can be visually identified. because it does

According to a preferred aspect of the present invention, a monochromatic background may occupy 70% or more of an area of the screen portion in the screen portion of the present invention.

According to a preferred aspect of the present invention, the monochromatic color of the present invention may be preferably selected from the group comprising white, gray, ivory, yellow, sky blue and yellow green, more preferably white or ivory, Most preferably, it may be white.

It is very important that the most preferred solid color in the present invention is white. This is because, when polarized light is irradiated to the identification shape using a white screen, the clarity of the identification shape is significantly higher than when polarized light is irradiated using a screen of a different color.

According to a preferred aspect of the present invention, the anti-forgery medium containing the polarizing material of the present invention is preferably printed using an ink that has the same color or looks the same at a glance, but either ink is cholesteric liquid crystal ink and the other ink may include a printed layer printed using the cholesteric liquid crystal ink and the cholesteric liquid crystal ink in a different direction from the cholesteric liquid crystal ink.

According to a preferred aspect of the present invention, the specific shape of the present invention is preferably a QR code shape, and the screen part of the smart phone or tablet PC is displayed by recognizing the QR code using the smart phone or tablet PC. It may be to convert the printed layer printed using the polarizing material into a dedicated screen that can be checked.

The features and advantages of the present invention are summarized as follows:

(a) the present invention provides a substrate; a design printing layer located on the upper side of the substrate and having a specific shape printed thereon; a cholesteric liquid crystal display layer positioned on the design print layer and printed with a hidden shape; and an autochromic fluorescent layer positioned on the cholesteric liquid crystal display layer.

(b) In the case of checking whether forgery or not by illuminating the smartphone screen light on the forgery prevention means of the present invention or applying pressure to the forgery prevention means, the forgery is very difficult, easy to manufacture, and inexpensive, as well as a smartphone In addition, it provides the advantage of being able to detect forgery without a separate forgery checking device.

1 shows a cross-section of the forgery prevention means according to the present invention.
2 shows a state of checking whether forgery or not using a mobile phone screen and a polarizing film.
3 shows a cross-section of checking whether forgery or not by applying a UV lamp and pressure.
Figure 4 shows the front of the state of checking whether or not forgery by applying a UV lamp and pressure.
5 shows the structure of a pressure-change fluorescent material.
6 shows a basic backbone structure of a barometric fluorescent material.
7 shows the appearance of a QR code for preventing forgery and tampering with an identification pattern printed on the QR code using ink containing a polarizing material.
8 shows the appearance of a QR code for preventing forgery and tampering with an identification pattern (NBST) printed on the middle part of the QR code using ink containing a polarizing material.
9 shows a state in which a QR code shape is recognized through a smartphone-only application and a state in which the smartphone screen is converted into a dedicated forgery confirmation screen by the recognition of the QR code shape.
10 shows a state in which the identification pattern (NBST) printed on the middle part of the QR code is checked using the dedicated forgery confirmation screen of the smartphone.

Since the present invention can apply various transformations and can have various embodiments, specific embodiments are illustrated in the drawings and described in detail. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention. In describing the present invention, if it is determined that a detailed description of a related known technology may obscure the gist of the present invention, the detailed description thereof will be omitted.

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

1 and 2 show a cross section of a forgery prevention means including a cholesteric liquid crystal display layer and a chromosomal fluorescent layer according to an embodiment of the present invention, a state of checking whether forgery or not using a smartphone and a polarizing film is shown has been

1 and 2, the forgery prevention means 100 including a cholesteric liquid crystal display layer and a barometric fluorescent layer according to an embodiment of the present invention includes a substrate 110, a design print layer 120, It includes a display layer 130 including a first display layer 131 and a second display layer 132 , and a photochromic fluorescent layer 140 .

The base material 110 is located in the lowermost layer of the forgery prevention means 100 including a cholesteric liquid crystal display layer, and various films used in the art, such as synthetic resin, paper, metal, etc. to manufacture labels, can be used.

The design print layer 120 is located on the substrate 110 , and a shape distinct from the display layer 130 , which will be described later, is printed.

The display layer 130 has a thickness of 15 μm or less, is located on the design print layer 120 , and includes a first display layer 131 and a second display layer 132 .

The first display layer 131 and the second display layer 132 are printed using ink containing cholesteric liquid crystal on only one of the two display layers, and the remaining display layers are printed using general ink. Examples and examples in which both the first display layer 131 and the second display layer 132 are printed using ink containing cholesteric liquid crystal exist.

Here, in the case where both the first display layer 131 and the second display layer 132 are printed using ink containing cholesteric liquid crystal, the orientation of the cholesteric liquid crystal used in each display layer must be different. It is possible to identify a hidden mark for checking whether forgery or not.

In addition, the ink used for printing the display layer must use the same color or ink that appears to have the same color at first glance, both the ink containing the cholesteric liquid crystal and the ink not containing the cholesteric liquid crystal.

Referring to FIGS. 3 and 4 , the forgery prevention means 100 including a cholesteric liquid crystal display layer and a barometric fluorescent layer according to an embodiment of the present invention includes a barometric fluorescent layer 140 under UV irradiation. It is possible to check whether forgery or not by applying pressure to

Referring to FIGS. 5 and 6 , the pressure-change fluorescent material may include 0.01% or more by weight of the pressure-change fluorescent material.

The characteristics of the autochromic fluorescent material are as follows: (a) average particle diameter: 10-150 nm; and (b) fluorescence wavelength: 450-650 nm.

An organic fluorescent material is one of fluorescent materials having a pi-conjugated structure including an electron donor group and an electron acceptor group.

In general, organic fluorescent materials must have an intramolecular pi-conjugated system structure so that electrons can easily move so that fluorescence properties can appear.

In other words, as the molecular structure of the fluorescent material delocalizes electrons in the pi-conjugated system, the electrons move more easily. will have

As such, organic fluorescent materials having a planar structure have high fluorescence efficiency in a solution state, whereas in a solid or thin film state, excimers are formed and quenched by intermolecular interactions and π-π stacking. (quenching), the quantum efficiency, that is, the fluorescence intensity is weakened.

5 and 6, the barometric fluorescent material is designed to have a non-planar structure, so the fluorescence intensity in the initial state is weak, but as it becomes a solid state, the excimer induces aggregation while being stacked in a twisted structure. By inhibiting the formation, the fluorescence efficiency is increased. This principle is called Aggregation Induced Emission.

In addition, it is one of organic fluorescent materials including an electron donating group (EDG) and an electron accepting group (EAG) in a molecule to facilitate movement of pi-conjugated electrons by pressure.

Here, the chromochromic fluorescent material has a structure having a pi-conjugated system having a low HOMO-LUMO energy band gap to facilitate electron movement.

The basic skeleton is one of fluorine, carbazole, dithienosilole, or anthracene.

At least one benzene ring, which is a pi system, is bonded to both sides of the basic skeleton, and has at least one electron-donating group and one electron-receiving group.

The electron-donating group includes at least one of an alkyl amine group, an aryl amino group, or an alkyl alkoxide group.

The group that accepts electrons includes at least one of a cyano group, a nitro group, or a fluoroalkyl group having one or more carbons.

As the binder for mixing the autochromic fluorescent material, a transparent binder may be used among various binders used in the art.

The pressure-changeable fluorescent layer 140 including the photochromic fluorescent material exhibits the following characteristics: (a) visible light transmittance: 75-95%; (b) thickness for pressure discoloration: 1-100 μm; and (c) pressing pressure: the pressure at which a color change is observed: greater than or equal to the pressure corresponding to the 4B pencil hardness value when pressure is applied with a pencil hardness machine.

7 to 10, the appearance of the forgery prevention means 100 according to an embodiment of the present invention, the appearance of the smartphone 50 in which the smartphone application 30 is installed, the forgery prevention means 100 and the smartphone application ( 30) is installed using a smart phone 50 to check whether or not forgery is present, a flowchart of a forgery detection method using a forgery prevention means including a polarizing material, and a cross-sectional view of a forgery prevention means including various types of polarizing material is shown has been

7 to 10, the forgery prevention means 100 according to an embodiment of the present invention is a QR code 10, an identification shape 20, a smartphone application 30, a screen for checking forgery 40. , the smartphone 50 and the light 60 generated from the screen.

7 to 10, the forgery prevention means 100 according to an embodiment of the present invention is a QR code 10 printed with an identification shape 20 printed using ink containing a polarizing material in the middle part. ) is a QR code 10 for checking the QR code 10 using a smartphone and a smartphone application 30 to be described later in the process of forgery or not using the computer and the QR code 10 built into the smartphone. The primary judgment and the secondary judgment on whether forgery or not can be simultaneously performed using the identification shape 20 printed using a polarizing material printed on the middle part of the QR code 10 .

Here, the secondary determination as to whether the above-described forgery or falsification can be visually identified using a polarizing film (not shown) or a screen 40 for checking forgery induced by a smartphone application 30 to be described later.

The smart phone application 30 is a kind of program installed on a smart phone, etc. As described above, 1) primary forgery identification that determines whether forgery or not in the process of recognizing the QR code 10 using a camera installed on a smart phone, etc. Process, 2) Secondary to determine whether forgery or not by observing the identification shape 20 printed using a polarizing material with the naked eye through the screen 40 for checking forgery that has been selectively switched through the recognition of the QR code 10 described above Proceed to identify whether forgery or not.

Here, the secondary forgery or falsification identification process of determining whether forgery or not by visually observing the identification shape 20 through the screen 40 for checking forgery is the light 60 generated from the screen for checking forgery and falsification in the identification shape 20 It proceeds to a judgment based on the presence or absence of the light identification shape 20 or whether the shape is the same.

The forgery confirmation screen 40 is composed of a white background screen in an area of 70% or more of the screen.

In addition to white, gray, ivory, yellow, sky blue, or yellow-green color may be used as the background screen, but the identification shape 20 can be most clearly identified when a white background screen is used.

QR code 10 Identification shape 20
Smartphone application 30 Screen for checking forgery 40
Light from the smartphone 50 screen 60
Forgery prevention means 100 Description 110
Design Print Layer 120 Display Layer 130
first display layer 131 second display layer 132
chromochromic fluorescent layer 140

Claims (10)

write;
a design print layer positioned above the substrate and having a specific shape printed thereon;
a cholesteric liquid crystal display layer positioned on the design print layer and printed with a hidden shape, the cholesteric liquid crystal display layer including at least one of a complementary color fluorescent dye and a nematic liquid crystal; and
In the forgery prevention means comprising a pressure-change fluorescent layer located on the cholesteric liquid crystal display layer,
The barometric fluorescent layer includes a barometric fluorescent material having a pi-conjugated system,
The pi-conjugated fluorescent material has at least one benzene ring, which is a pi system, bonded to both sides of the basic skeleton of a non-planar structure, and has at least one electron-donating group and one electron-receiving group. Forgery prevention means, characterized in that.
delete delete The method of claim 1,
The basic skeleton is forgery prevention means, characterized in that selected from the group comprising fluorene (fluorene), carbazole (carbazole) and dithienosilole (dithienosilole).
5. The method of claim 4,
The electron-donating group is an alkylamino group, an arylamino group, an alkylamide group (alkyl alkoxide group), and forgery prevention means, characterized in that selected from the group comprising a mixture thereof.
6. The method of claim 5,
The group receiving the electron is a forgery prevention means, characterized in that selected from the group comprising a cyano group (cyano group), a nitro group (nitro group), a fluoroalkyl group (fluoroalkyl group), and mixtures thereof.
The method of claim 1,
The barometric fluorescent material is forgery prevention means, characterized in that it contains 0.01-5.0% based on the weight of the barometric fluorescent layer.
8. The method of claim 7,
Forgery prevention means, characterized in that the pressure-change fluorescent material comprises the following characteristics:
(a) Average particle diameter: 10-150 nm; and
(b) Fluorescence wavelength: 450-650 nm.
9. The method of claim 8,
The chromochromic fluorescent layer is forgery prevention means, characterized in that it includes the following characteristics:
(a) visible light transmittance: 75-95%;
(b) thickness for pressure discoloration: 1-100 μm; and
(c) Pressure at which color change is observed: more than the pressure corresponding to the 4B pencil hardness value when pressure is applied with a pencil hardness machine.
The method of claim 1,
The cholesteric liquid crystal display layer includes a first display layer and a second display layer, and at least one of the first display layer and the second display layer is printed with an ink containing a cholesteric liquid crystal. , forgery prevention means.

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