JP4323578B2 - Articles for forming laser marking - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention is a marking method of forming a infrared absorbent pattern, and articles having an infrared-absorbing pattern.
[0002]
[Prior art]
There is known a printed material having a printed layer that is difficult to recognize with visible light and can be recognized with infrared light. For example, there is a printed matter having a printing layer containing infrared absorbing copper oxide, ytterbium compound, cyanine dye, and the like. Such a printed matter is formed by printing an infrared absorption pattern or an infrared emission pattern using a paint containing the above material. For example, JP-A-9-30104 and JP-A-9-31382, JP-infrared absorption pattern prints using ytterbium salt is shown open as infrared absorbing agent.
[0003]
[Problems to be solved by the invention]
Since the printed layer of the printed matter is difficult to recognize with visible light and can be recognized with infrared light, it is considered to be used for articles that require various types of anti-counterfeiting.
However, the printing layer is performed using printing or a transfer ribbon, and the formed printing layer is swelled although it is in a micron order as compared with other portions. As a result, there is a problem that the unevenness of the printed layer can be recognized with the naked eye even though the printed layer itself is difficult to recognize with visible light.
Accordingly, an object of the present invention is to provide an infrared identifiable medium that is difficult to recognize with visible light and is not only recognizable with infrared light but also has irregularities and cannot be recognized with the naked eye. It is in.
[0005]
[Means for Solving the Problems]
The present invention is a substrate having at least a part of a layer containing a visible light non-absorbing and infrared absorbing material, or a substrate containing a visible light non-absorbing and infrared absorbing material, The infrared absorbing material is a visible light non-absorbing and infrared absorbing material of an article for forming an infrared absorbing marking, characterized in that at least part of the infrared absorbing property disappears due to external energy. The present invention relates to a marking method for forming an infrared-absorbing pattern by applying energy to a substrate having a layer to be included or a substrate having a visible-light non-absorbing and infrared-absorbing material.
[0006]
The present invention further relates to an article having an infrared absorbing pattern formed by the method of the present invention.
[0007]
DETAILED DESCRIPTION OF THE INVENTION
Infrared absorptive marking forming article Infrared absorptive marking forming article is a visible light non-absorptive base material having at least part of a layer containing an infrared absorptive material, or a visible light non-absorptive, infrared absorbing The above-mentioned “infrared absorbing material” is a material having a characteristic that at least part of the infrared absorbing property is lost by external energy. The energy from the outside can be, for example, an electromagnetic wave applied to the article, and the electromagnetic wave can be, for example, a laser beam. The laser light can be, for example, an Nd: YAG laser, a CO ₂ laser, an excimer laser, or the like. Examples of the material that is non-absorptive to visible light, has infrared absorptivity, and has a characteristic that at least part of the infrared absorptivity is lost by external energy include an infrared absorptive pigment. Examples of the infrared absorbing pigment include ytterbium oxide.
[0008]
Among the articles of the present invention, in the substrate having a layer containing an infrared absorbing material, the layer containing the infrared absorbing material can be composed of, for example, the above material and a binder. The binder is preferably non-absorbable with respect to visible light and infrared rays, and examples thereof include acrylic resin, methacrylic resin, vinyl resin, styrene resin, polypropylene resin, polyethylene resin, polyacrylonitrile resin, polyethylene terephthalate resin, and nylon resin. be able to.
The content of the infrared absorbing material in the layer is appropriately determined in consideration of the type of the infrared absorbing material and the binder, the dispersibility of the dye, the particle diameter and absorption coefficient of the pigment, the wettability of the surface, the dispersibility, and the like. However, in the case of a dye, for example, it is in the range of 0.1 to 5% by weight, and in the case of a pigment, it can be in the range of, for example, 5 to 80% by weight. Further, the thickness of the layer containing the infrared absorbing material is appropriately determined in consideration of wear resistance, scratch resistance, adhesion to the substrate, coating suitability, etc., for example, 2 to 20 μm Can be a range.
In addition, a pearl (mica) pigment can be added to the layer containing an infrared absorbing material for the purpose of improving photosensitivity.
There is no restriction | limiting in particular in the base material for providing the layer containing an infrared rays absorptive material, For example, it can be polyethylene, a polypropylene, a polycarbonate, ABS, a polyethylene terephthalate etc.
[0009]
Moreover, the base material containing the infrared absorbing material among the articles of the present invention can be composed of the infrared absorbing material and the material forming the base material. The material forming the base material is preferably non-absorbable with respect to visible light and infrared rays, for example, acrylic resin, methacrylic resin, vinyl resin, styrene resin, polypropylene resin, polyethylene resin, polyacrylonitrile resin, polyethylene terephthalate resin, Nylon resin etc. can be mentioned.
The amount of the infrared-absorbing material contained in the substrate is appropriately determined in consideration of the type of the substrate and the infrared-absorbing material, the dispersibility of the dye, the particle diameter and absorption coefficient of the pigment, the wettability of the surface, the dispersibility, etc. For example, in the case of a dye, it may be in the range of 0.01 to 2% by weight, and in the case of a pigment, it may be in the range of, for example, 2 to 50% by weight. Further, the thickness of the base material containing the infrared absorbing material is appropriately determined in consideration of the use of the article, colorability, weather resistance, bending resistance, rigidity, etc., for example, in the range of 10 to 500 μm. Can be.
[0010]
The article of the present invention can have a visible light impermeable and infrared transmissive concealing layer on at least a part of at least one surface. The visible light impermeable and infrared transmissive concealing layer can be made of, for example, a thin film such as Ge, a visible light impermeable and infrared transmissive material, and a binder. Examples of the material that does not transmit visible light and transmits infrared light include titanium oxide, zinc oxide, zinc sulfide, and barium sulfide. As the binder, the binder used in the infrared absorbing material-containing layer can be used. The content of the visible light-impermeable and infrared-transmissive material in the masking layer and the thickness of the masking layer can be appropriately determined in consideration of the masking power of the masking layer and the like.
[0011]
Marking method for forming an infrared-absorbing pattern By applying energy to the layer containing the infrared-absorbing material or the substrate containing the infrared-absorbing material of the article of the present invention, the infrared-absorbing pattern is formed. Marking can be performed by forming. Examples of the energy applied to the substrate include electromagnetic waves, and examples of the electromagnetic waves include laser light. Examples of the laser include Nd: YAG laser, CO ₂ laser, and excimer laser. The Nd: YAG laser is a laser using near infrared light of 1064 nm, and is generated by irradiating the YAG lot with the light of the arc lamp built in the apparatus. The CO ₂ laser is a 10.6 μm infrared laser and is roughly classified into a TEA laser and an RF laser depending on the laser gas excitation method.
[0012]
In addition, as a marking method, any of a scanning marking method and a mask marking method can be employed. The scanning marking method is a method in which a laser beam is scanned in the X and Y directions by two rotating mirrors, then focused by a lens, and a mark is drawn on an object. The mask marking method is a method in which laser light passes through a mask (stencil) and a condensing lens to make a mask on an object. The marking method can be appropriately selected in consideration of the marking size, marking speed, and the like.
There is no restriction | limiting in particular in the kind of infrared absorption pattern shape | molded. Characters, symbols, barcodes (one-dimensional and two-dimensional) and the like can be mentioned.
In the portion to which energy such as laser light is applied by the method of the present invention, the infrared absorbing material contained in the portion is destroyed or modified by the energy, and the infrared absorbing property is partially or completely changed. To lose. As a result, it can be identified from the non-energy-irradiated portion, and can be read using an infrared bar code reader or the like. In addition, the infrared absorbing material present in the non-energy-irradiated part is destroyed or modified in structure, but there is little or no change in volume, and it is virtually impossible to visually identify the non-energy-irradiated part. .
[0013]
Articles having an infrared-absorbing pattern The present invention also includes articles having an infrared-absorbing pattern formed by the method of the present invention. As an article having an infrared absorbing pattern, for example, a printed matter containing a barcode, a book, a package, a label, or a number or ID such as a cash voucher or a card can be cited.
[0014]
The present invention will be further described with reference to the drawings.
FIG. 1 shows an infrared-absorbing marking-forming article 11 which is a base material 1 containing an infrared-absorbing material and has a titanium oxide-containing layer as a concealing layer 2 on its surface. Further, FIG. 1 shows an article 21 having an infrared-absorbing pattern in which markings 3 are formed on a substrate 1 containing an infrared-absorbing material by irradiation with laser light on the article 11 for forming infrared-absorbing markings. The marking 3 is distinguishable from the infrared-absorbing material-containing layer 2 because the infrared-absorbing property is reduced or disappears.
[0015]
【The invention's effect】
According to the present invention, in order to provide an article that can be recognized not only with visible light, but also with infrared, which is not only recognizable with infrared but also has irregularities and cannot be recognized with the naked eye, An infrared-absorbing marking forming article and an infrared-absorbing marking method can be provided. Furthermore, according to the present invention, an infrared-absorbing pattern that is not only recognizable with visible light and is not only recognizable with infrared light but also has irregularities and cannot be recognized with the naked eye, can be identified with infrared light. Articles having the same can also be provided.
[0016]
【Example】
Hereinafter, the present invention will be further described by examples.
Reference example 1
3 parts by weight of infrared absorbing dye (CIR-1081) manufactured by Nippon Carlit Co., Ltd., 27 parts by weight of polyester resin [manufactured by Toray Industries, Inc., Byron 200], 35 parts by weight of methyl ethyl ketone, and 35 parts by weight of toluene are dispersed and stirred. Thus, a gravure ink was prepared. The obtained ink was coated on a white PET substrate having a thickness of 188 μm with a gravure coater to form an infrared absorbing coating film. The radiation wavelength absorptance at 940 nm of the obtained coating film was 90%, whereas it was 10% or less in the 500 nm band which is a visible light region. When scanning marking was performed on this infrared absorbing coating film using a Q-switch type YAG laser, the infrared absorbing property of the marking portion was remarkably lost, and the absorption rate at 940 nm was 10% or less. The marking part of the infrared-absorbing coating film was hardly visually confirmed. The infrared absorbing coating film after the marking treatment was irradiated with an infrared lamp containing a large amount of near-infrared radiation up to 1000 nm, and the reflected image was observed with an infrared camera having a lens covered with a visible light cut filter. As a result, a pattern in which only the marking portion was white as a reflected image was obtained. When the barcode was formed by this laser marking and read in the black and white reversal mode, the barcode could be read.
[0017]
Reference example 2
3 parts by weight of infrared absorbing dye (CIR-1081) manufactured by Nippon Carlit Co., Ltd., 27 parts by weight of polyester resin [manufactured by Toray Industries, Inc., Byron 200], 35 parts by weight of methyl ethyl ketone, and 35 parts by weight of toluene are dispersed and stirred. Thus, a gravure ink was prepared. The obtained ink was coated on a white PET substrate having a thickness of 188 μm with a gravure coater to form an infrared absorbing coating film. On top of this, white ink (titanium oxide white, manufactured by Inktec Ink) was applied to form a concealing layer. The radiation wavelength absorptance at 940 nm of the obtained coating film was 90%, whereas it was 10% or less in the 500 nm band which is a visible light region. When scanning marking was performed on this infrared absorbing coating film using a Q-switch type YAG laser, the infrared absorbing property of the marking portion was remarkably lost, and the absorption rate at 940 nm was 10% or less. The marking part of the infrared-absorbing coating film was hardly visually confirmed. The infrared absorbing coating film after the marking treatment was irradiated with an infrared lamp containing a large amount of near-infrared radiation up to 1000 nm, and the reflected image was observed with an infrared camera having a lens covered with a visible light cut filter. As a result, a pattern in which only the marking portion was white as a reflected image was obtained. When the barcode was formed by this laser marking and read in the black and white reversal mode, the barcode could be read.
[0018]
Reference example 3
3 parts by weight of infrared absorbing dye (CIR-1081) manufactured by Nippon Carlit Co., Ltd., 27 parts by weight of polyester resin [byron 200 manufactured by Toray Industries, Inc.], 35 parts by weight of methyl ethyl ketone, and 35 parts by weight of toluene were dispersed and stirred. A gravure ink was prepared. The obtained ink was coated on a 100 μm thick transparent PET substrate with a gravure coater to form an infrared absorbing coating film. The radiation wavelength absorptance at 940 nm of the obtained coating film was 10%, whereas it was 90% or more in the 500 nm band which is a visible light region. A pressure-sensitive adhesive (Nissetsu PE-110) was applied to the infrared-absorbing coating film, laminated with silicone paper, and then a piece was punched to form a label. When this label is process-printed in three colors, yellow and red, and affixed to the surface of a printed material that does not have an absorption region in the infrared wavelength band, dot marking is performed using a CO ₂ laser. Significantly lost, the transmittance at 940 nm decreased to over 90%. The marking portion of the infrared absorbing coating film could not be confirmed visually. The infrared absorbing coating film after the marking treatment was irradiated with an infrared lamp containing a large amount of near-infrared radiation up to 1000 nm, and the reflected image was observed with an infrared camera having a lens covered with a visible light cut filter. As a result, a pattern in which only the marking portion was white as a reflected image was obtained. When the barcode was formed by this laser marking and read in the black and white reversal mode, the barcode could be read.
[0019]
Example 1
20 parts by weight of ytterbium oxide fine powder (manufactured by Shin-Etsu Chemical Co., Ltd.) was dispersed by heat-melting 80 parts by weight of polyester pellets to obtain 100 parts by weight of a master batch. After mixing 10 parts by weight of this master batch with 90 parts by weight of polyester pellets, an infrared absorbing film (thickness: 150 μm) was obtained by film inflation molding. The resulting film had a radiation wavelength absorptivity of 10% at 940 nm, whereas it was 90% or more in the 500 nm band which is a visible light region. An adhesive (Nissetsu PE-110) was applied to this infrared absorbing film, laminated with silicone paper, and then a piece was punched to form a label. When this label is process-printed in three colors, yellow and red, and affixed to the surface of a printed material that does not have an absorption region in the infrared wavelength band, dot marking is performed using a CO ₂ laser. Significantly lost, the transmittance at 940 nm decreased to over 90%. The marking part of the infrared absorbing film could not be confirmed by visual observation. The infrared ray absorbing film after the marking treatment was irradiated with an infrared lamp containing a large amount of near infrared radiation up to 1000 nm, and the reflected image was observed with an infrared camera having a lens covered with a visible light cut filter. As a result, a pattern in which only the marking portion was white as a reflected image was obtained. When the barcode was formed by this laser marking and read in the black and white reversal mode, the barcode could be read.
[0020]
Example 2
An infrared transmitting white ink (titanium oxide white, manufactured by Inktec Ink) was applied to one surface of the infrared absorbing film obtained in Example 1 to form a concealing layer. The resulting film had a radiation wavelength absorptivity of 10% at 940 nm, whereas it was 90% or more in the 500 nm band which is a visible light region. A pressure-sensitive adhesive (Nissetsu PE-110) was applied to the infrared absorbing film, laminated with silicone paper, and then a piece was punched to form a label. When this label was process-printed in three colors, yellow and red, and affixed to the surface of a printed material that did not have an absorption region in the infrared wavelength band, dot marking was performed using a CO ₂ laser. Significantly lost, the transmittance at 940 nm decreased to over 90%. The marking part of the infrared absorbing film could not be confirmed by visual observation. The reflected image was observed with an infrared camera in which the infrared-absorbing film after the marking treatment was irradiated with an infrared lamp containing a large amount of near-infrared radiation up to 1000 nm and the lens was covered with a visible light cut filter. As a result, a pattern in which only the marking portion was white as a reflected image was obtained. When the barcode was formed by this laser marking and read in the black and white reversal mode, the barcode could be read.
[Brief description of the drawings]
FIG. 1 is a schematic explanatory diagram of an article for forming an infrared-absorbing marking according to the present invention and an article having an infrared-absorbing pattern.

Claims (5)

A substrate having at least a part of a layer containing a non-visible light-absorbing and infrared-absorbing material, or a substrate containing a visible-light non-absorbing and infrared-absorbing material, the infrared-absorbing material The material has a layer containing an infrared-absorbing material that is a visible light non-absorbing material of an infrared-absorbing marking-forming article that is ytterbium oxide and has a property that at least part of the infrared-absorbing property is lost by external energy. A marking method for forming an infrared-absorbing pattern by applying energy to a substrate or a substrate containing an infrared-absorbing material that is non-absorptive to visible light. The method according to claim 1 , wherein the energy is electromagnetic waves. The method according to claim 2 , wherein the electromagnetic wave is a laser beam. The method according to claim 1, wherein the article has a visible light impermeable and infrared transmissive concealing layer on at least a part of at least one surface . An article having an infrared-absorbing pattern formed by the method according to any one of claims 1 to 4 .

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