JP3601762B2 - Fluorescent pigment composition - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a fluorescent pigment composition, and more particularly, to a fluorescent pigment composition having both color and fluorescence, which is useful for preventing forgery when used as an ink, filler, paint or toner for printing and coating. .
[0002]
[Prior art]
It is known that by coating the surface of a powder with a film of another substance, the properties of the powder can be improved or the properties can be varied, and various methods have been proposed as conventional methods for that purpose. I have.
For example, as a coating technique for forming a film on a surface of an object for protection or decoration, many methods such as a coating method, a deposition method, a sputtering method, a vacuum deposition method, an electrodeposition method, and an anodizing method are known. . However, it is difficult to make the thickness of the film uniform by the coating method or the deposition method, and it is difficult to obtain a thick film by the sputtering or the vacuum evaporation method. Further, the electrodeposition method and the anodic oxidation method have a problem that they are not suitable for treating powder because the object to be treated is used as an electrode.
With the progress in various technical fields, there is an increasing demand for powders having unique properties, particularly metal powders or metal compound powders. There is a demand for a powder having a combined function with other properties in addition to the provided properties.
For example, in the raw magnetic powder of the color magnetic toner, the color of the magnetic metal powder, which has not been a problem in the conventional black magnetic toner, cannot be used as it is. Form a thin metal oxide film on the surface of the powder to protect the powder or to modify the surface to make it easier to mix with synthetic resin, etc. The means by which they do not meet the new demands of such an area. In this regard, it is necessary to provide a powder having a new composition not found in conventional powders.
[0003]
As a useful method of forming a metal oxide for providing a powder capable of fulfilling a composite function, particularly a metal or a metal compound powder, having a composite property meeting the new requirements as described above, On the other hand, the present inventors disperse a metal powder or a metal oxide powder in a metal alkoxide solution and hydrolyze the metal alkoxide to form a metal oxide film, thereby forming a metal or metal compound. A powder having a metal oxide film having a uniform thickness of 0.01 to 20 μm on the surface of a substrate and containing a metal different from the metal constituting the substrate has been invented (JP-A-6-228604). ).
[0004]
When a plurality of layers of the metal oxide film are provided in the powder, a special function can be given by adjusting the thickness of each layer of the film. If a coating film having a different refractive index is provided with a thickness corresponding to a quarter wavelength of light, all light is reflected. When this means is applied to a magnetic substance such as a metal powder such as iron, cobalt, nickel or the like or a metal alloy powder or an iron nitride powder, the magnetic toner for magnetic toner shines white by totally reflecting light. Powder can be obtained. Further, it discloses that a color magnetic toner can be obtained by providing a colored layer on the powder and providing a resin layer thereon (Japanese Patent Application Laid-Open No. 7-90310).
[0005]
In addition, the present inventors have found that the reflected light interference waveform of the multilayer film can be adjusted by controlling the combination and thickness of the materials of the multilayer film, and a stable color tone can be obtained for a long period of storage without using a dye or pigment. (WO96 / 28269).
[0006]
As described above, the present inventors form a coating of a metal oxide or a metal on the surface of a metal powder or a metal compound powder, and in addition to the properties of the metal or metal compound powder serving as a substrate, We have worked to develop highly functional metal or metal compound powders by imparting different properties.
In the case of color printing and color magnetic printing of gift certificates and ticket cards, which have been growing in demand in recent years, in addition to the elegance of coloring, special functions for preventing forgery are required in addition to visual and magnetic reading. ing. In response to this trend, by adjusting the reflected light interference waveform of the multilayer film described above, inks with beautiful and stable colors such as blue, green, and yellow can be obtained without using dyes or pigments, and in the visible light range. In addition, because it has an interference reflection peak, it has a function that can enhance the anti-counterfeiting performance of printed matter by a method other than visual or magnetic reading by combining with a reader using reflected light by ultraviolet light or infrared light An ink composition was provided (JP-A-10-60350).
[0007]
[Problems to be solved by the invention]
However, in the above-described color ink composition, an inspection device is required in order to determine whether the color ink composition is authentic by combining with a reader using reflected light of ultraviolet rays or infrared rays. There is a need for a function that can easily determine the authenticity and a function that can further enhance the forgery prevention performance of a printed material by a new method, and there is room for improvement.
Accordingly, an object of the present invention is to solve these problems, and to provide a beautiful and stable color print of a single color such as blue, green, and yellow, a coating ink, a filler, a paint and a high-performance color magnetic print. It is useful as an ink, and it can be used for a simple method such as irradiating a light source such as a fluorescent lamp, an ultraviolet lamp, or an infrared lamp indoors without using new inspection equipment. An object of the present invention is to provide a fluorescent pigment composition having a function capable of further improving the forgery prevention performance.
[0008]
[Means for Solving the Problems]
The present inventors have conducted intensive research and found that a multilayer thin film having a different refractive index is formed on the powder surface to adjust the reflected light interference waveform of the multilayer film, and that the color and the color of at least one layer of the multilayer film are adjusted. Beautiful and stable colors such as blue, green, and yellow when used alone, by containing the same or different fluorescent pigments or by forming a layer (film) of a fluorescent substance that does not participate in light interference The present inventors have found that it is possible to prevent forgery by the simple identification of printed matter based on the presence or absence of fluorescence, and have completed the present invention.
In addition, a substrate having various properties such as a ferroelectric substance or a conductor can be used as the base of the powder, and even when a magnetic substance is used as the base, the multi-layer coated powder does not impair magnetism. It has been found that vivid coloring and fluorescent coloring are obtained.
[0009]
That is, the present invention is as follows.
(1) have a plurality of coating films on the substrate particles, the coating film of said plurality of shows the optical interference effects, at least one layer of the coating film is mainly composed of fluorescent substance and the visible light interference A fluorescent pigment composition comprising a fluorescent multi-layer coating powder involved .
( 2 ) The fluorescent pigment composition according to (1), wherein the multilayer film exhibits a specific interference reflection peak in a region other than the visible light region.
( 3 ) The fluorescent pigment composition according to the above (1), wherein the base particles are magnetic particles.
( 4 ) The fluorescent pigment composition according to the above (1), further comprising a coloring material.
[0010]
As described above, the fluorescent pigment composition of the present invention is useful as an ink, filler or paint for color printing and coating having fluorescence. When a magnetic material is used as the base, it can be applied as a coloring material for high-performance color magnetic printing inks, and can be used for visible light, invisible light (ultraviolet and infrared), fluorescent coloring and magnetism, and electric ( (Change of electric field), and it is possible to enhance the effect of preventing forgery of printed matter.
[0011]
BEST MODE FOR CARRYING OUT THE INVENTION
The substrate of the multilayer-coated powder used in the present invention is not particularly limited, and powders having various properties such as magnetism, ferroelectricity, and conductivity can be used. As a kind of the substance, a wide range of substances such as a metal, a metal compound, an organic substance, and an inorganic substance can be used.
Examples of the metal include transition metals such as iron, nickel, chromium, titanium, cobalt, copper, and aluminum; metals such as rare earth metals such as neodymium and yttrium; and alloys thereof, for example, the aforementioned metals such as iron-nickel and iron-cobalt alloys. Alloys, iron-nickel alloy nitrides, iron-nickel-cobalt alloy nitrides, and metal oxides such as iron, nickel, chromium, titanium, aluminum, and silicon (in this case, silicon is classified as a metal. ), Alkaline earth metal oxides such as calcium, magnesium and barium, or composite oxides thereof, clays, glasses and the like.
In the present invention, one of the objects is to produce a powder that also shares magnetism, such as a color magnetic toner or a color magnetic ink, and in that case, a multilayer film-coated powder in the fluorescent pigment composition of the present invention. It is preferable to use a ferromagnetic material as the substrate. The ferromagnetic material may be a transition metal such as iron, nickel, chromium, titanium, cobalt, copper, or aluminum; a rare earth metal such as neodymium or yttrium; or a metal having a high magnetic susceptibility such as an alloy of these metals; Ferromagnetic oxides and ferromagnetic alloys such as ferrite, Sr ferrite, γ-hematite, cobalt ferrite, and mixed ferrites thereof are also used.
[0012]
Further, as the organic substance, resin particles are preferable, and specific examples thereof include cellulose powder, cellulose acetate powder, polyamide, epoxy resin, polyester, melamine resin, polyurethane, vinyl acetate resin, silicon resin, acrylate, and methacrylate. And spherical or crushed particles obtained by polymerization or copolymerization of styrene, ethylene, propylene and their derivatives. Particularly preferred resin particles are spherical acrylic resin particles obtained by polymerization of acrylic acid or methacrylic acid ester.
[0013]
Further, as inorganic substances, inorganic hollow particles such as shirasu balloon (hollow silicic acid particles), fine carbon hollow spheres (Clekasphere), fused alumina bubbles, Aerosil, white carbon, silica fine hollow spheres, calcium carbonate fine hollow spheres, Calcium carbonate, perlite, talc, bentonite, kaolin, mica, synthetic mica, glass beads and the like can be used.
The shape of the powder core particles is spherical, subspherical, isotropic such as regular polyhedron, rectangular parallelepiped, spheroid, rhombohedral, plate-like, needle-like (cylinder, prism), etc., and further pulverized. It is also possible to use completely amorphous powders such as materials.
The size of these substrates is not particularly limited, but is preferably in the range of 0.01 μm to several mm.
[0014]
In the present invention, by using a plurality of coating layers having different refractive indexes from each other and coating the base particles by appropriately selecting the refractive index and the layer thickness of each coating layer, the base particles can be colored by the interference color. .
It is desirable that the material constituting each coating layer is arbitrarily selected from inorganic metal compounds, metals or alloys, and organic substances.
Examples of the inorganic metal compound constituting the coating layer include metal oxides as typical examples thereof, and specific examples thereof include iron, nickel, chromium, titanium, aluminum, silicon, calcium, magnesium, oxides such as barium, Alternatively, these composite oxides can be mentioned. Further, examples of the metal compound other than the metal oxide include metal nitrides such as magnesium fluoride and iron nitride, and metal carbides. As the simple metal constituting the coating layer, metallic silver, metallic cobalt, metallic nickel, metallic palladium, metallic iridium, platinum, gold, metallic iron and the like are mentioned, and as the metallic alloy, silver-iridium, palladium-platinum, silver-palladium And alloys such as platinum-palladium.
[0015]
The organic substance constituting the coating layer may be the same as or different from the above-mentioned organic substance constituting the base, and is not particularly limited, but is preferably a resin. Specific examples of the resin include cellulose, cellulose acetate, polyamide, epoxy resin, polyester, melamine resin, polyurethane, resin vinyl resin, silicon resin, acrylate, methacrylate, styrene, ethylene, propylene and derivatives thereof. Polymers and copolymers are exemplified.
As described above, various materials can be used as the material constituting the coating layer. However, it is necessary to appropriately select the combination of these materials according to the application in consideration of the refractive index of each coating layer. It is.
The particle size of the multilayer-coated powder according to the present invention is not particularly limited and can be appropriately adjusted depending on the purpose, but is usually in the range of 0.01 μm to several mm.
[0016]
In the present invention, the thickness of the coating film formed at one time can be in the range of 5 nm to 10 μm, and can be made thicker than the conventional forming method.
In the case of the color powder described above, the total thickness of the coating film formed in a plurality of times is preferably in the range of 10 nm to 20 μm in order to form a coating film having a good reflectance due to the interference. And more preferably in the range of 20 nm to 5 μm. The thickness is preferably in the range of 0.02 to 2.0 μm for interference reflection of visible light with a particularly thin film thickness, for example, when the particle size is limited.
[0017]
The thickness of each unit coating layer constituting each of the plurality of coating layers is set so as to have an interference reflection peak or interference transmission bottom of a specific same wavelength. More preferably, the thickness of each unit coating layer is set by the following formula (1):
N × d = m × λ / 4 (1)
[Where N is the complex refractive index, d is the basic film thickness, m is an integer (natural number), λ is the wavelength of the interference reflection peak or the interference transmission bottom, and N is the following formula (2):
N = n + iκ (2)
(N is a refractive index of each unit coating layer, i is a complex number, and κ is an attenuation coefficient.)
The basic film thickness that satisfies the above conditions, and a phase shift due to the attenuation coefficient κ of the refractive index, a phase shift at the film interface, a dispersion of the refractive index and a peak shift depending on the particle shape, each unit coating layer has the same specific The actual film thickness of each unit coating layer is corrected so as to have an interference reflection peak or an interference transmission bottom of a wavelength.
[0018]
As a method for forming the film, the following methods can be used depending on the substance to be formed, but other methods can also be used.
(1) When an organic film (resin film) is formed a. In a liquid phase, a method of forming a resin film on the particles by dispersing particles serving as a substrate and emulsion-polymerizing the particles can be used.
b. Film forming method in gas phase (CVD) (PVD)
(2) When an inorganic metal compound film is formed a. Solid phase deposition method in liquid phase A method in which particles serving as a substrate are dispersed in a metal alkoxide solution and a metal alkoxide is hydrolyzed to form a metal oxide film on the particles is preferable. An oxide film can be formed. Further, a metal oxide film or the like can be formed on the particles by the reaction of the aqueous metal salt solution.
b. Film forming method in gas phase (CVD) (PVD)
[0019]
(3) When forming a metal film or an alloy film a. Method of Reducing Metal Salt in Liquid Phase A so-called chemical plating method is used in which a metal salt is reduced in an aqueous metal salt solution to deposit a metal to form a metal film.
b. Film forming method in gas phase (CVD) (PVD)
A metal film can be formed on the surfaces of the particles by vacuum evaporation of metal or the like.
[0020]
In the fluorescent pigment composition of the present invention, the coating layer having a fluorescent substance (hereinafter referred to as a fluorescent coloring layer) is a layer that imparts fluorescent coloring property to the multilayer-coated powder. The substance contained in the fluorescent coloring layer is not particularly limited as long as it has a fluorescent coloring property of the multilayer-coated powder, that is, a substance having a characteristic of emitting fluorescence that can be easily distinguished by irradiating ultraviolet light or visible light. However, a fluorescent substance which can maintain the fluorescent coloring property for a long time is preferable.
A fluorescent substance is a substance whose function is temporarily excited by an electromagnetic wave (light) at a specific wavelength to emit light of a specific wavelength (particularly visible light), and does not emit light without a light source.
The fluorescent substance applied to the fluorescent coloring layer is a fluorescent dye or a fluorescent pigment, which is a general term for a dye that absorbs external energy and emits fluorescence. Is added, so that it exhibits a brilliant color. For example, C.I. I. Acid Yellow 7, a red basic dye that emits yellow to orange fluorescence. I. Basic Red and the like.
[0021]
The following are specific examples of the fluorescent substance applied to the fluorescent coloring layer, but the present invention is not limited to these specific examples.
Specifically, for example, examples of the organic fluorescent pigment include uranine, eosin, diaminotilbene, thioflavin T, rhodamine B, and international orange. Examples of the inorganic fluorescent pigment include calcium tungstate, lead-containing barium silicate, and europium. Containing strontium phosphate, europium-containing yttria, cerium-containing yttria, copper or silver, tin, manganese, arsenic, aluminum, one or more of cadmium or zinc sulfide, manganese-containing magnesium gallate, magnesium fluoride, calcium fluoride, oxygen-deficient oxidation Zinc, europium-containing zinc oxide, cerium-containing zinc oxide, cesium-containing zinc oxide, manganese or arsenic-containing zinc silicate, bismuth-containing zinc cadmium, bismuth-containing calcium strontium sulfide, etc. And the like.
[0022]
In the present invention, the fluorescent coloring layer is formed on the surface of the particles serving as the substrate of the fluorescent multilayer film-coated powder, in the light interference multilayer coating film formed on the surface of the substrate, or on the surface of the multilayer film-coated powder. , Can be formed.
There are the following three methods for the configuration of the fluorescent coloring layer for that purpose.
(1) A layer containing a fluorescent substance as a main component is provided, and this fluorescent coloring layer participates in visible light interference.
(2) A layer containing a fluorescent substance as a main component is provided, and this fluorescent coloring layer does not contribute to visible light interference. (It is preferable not to reduce the effect of visible light interference).
(3) It is provided as a layer containing a fluorescent substance dispersed and contained in a coating film involved in light interference.
[0023]
As an outline of the method of forming the fluorescent coloring layer in the above (1), (2) and (3), the following method is mentioned.
(1) When a layer mainly composed of a fluorescent substance is provided, and this fluorescent coloring layer is involved in visible light interference, the layer is used for a high refractive index layer or a low refractive index layer for interference depending on the magnitude of the refractive index, and the interference condition is met. The refractive index and the film thickness are designed so that visible light interference reflection occurs and the film is colored and simultaneously emits fluorescence.
For the film formation, there is a method utilizing a deposition on a surface such as a sol-gel method or a solid phase precipitation from an aqueous solution.
It is desirable to heat-treat these obtained powders if necessary. When the film material is thermally decomposed, it is desirable to form a fluorescent coloring layer on the outermost layer.
[0024]
(2) A layer mainly composed of a fluorescent substance which does not participate in light interference is provided, and when this fluorescent coloring layer does not participate in visible light interference, a fluorescent substance film is formed sufficiently thin on the outermost layer so as not to cause interference. In this case, the fluorescent material film may be a film made of fine particles.
For the film formation, there is a method utilizing a deposition on a surface such as a sol-gel method or a solid phase precipitation from an aqueous solution.
In addition, there is a method in which fluorescent substance fine particles (fluorescent particles having a smaller particle diameter than the particles to be coated) dispersed in a solvent are mixed and adhered by heteroaggregation or the like.
In the case of the above two methods, it is desirable to heat-treat these obtained powders if necessary. When the film material is thermally decomposed, it is desirable to form a fluorescent coloring layer on the outermost layer.
[0025]
(3) One method for providing a layer containing a fluorescent substance dispersed and contained in a coating film involved in light interference is to mix or disperse the fluorescent substance in the raw material composition by dissolving or dispersing, and use this to form a coating. Perform formation.
In order to make the high refractive index layer or the low refractive index layer of the interference contain the fluorescent substance, the fluorescent substance fine particles (the fluorescent particles having a smaller particle diameter than the base particle to be coated) are contained in the solvent containing the raw material during the film formation. The particles are mixed and formed into a film, and the particles are contained in one or more layers. In this case, it is desirable that the compound be contained in an outer layer, or that it be contained in many layers. Further, it is also possible to form a film after adsorbing the fluorescent substance fine particles to the base particles by hetero-aggregation or the like.
[0026]
(4) Another method of providing a layer containing a fluorescent substance dispersed and contained in a coating film involved in light interference is to form a multilayer coating powder, heat-treat the powder, and then heat-treat the powder. Is immersed in a phosphor solution to be impregnated.
When heat-treating the outermost layer, for example, adding an additive during film formation, or increasing the temperature or the heat treatment time to make the outermost layer porous and impregnating the voids with a fluorescent material dispersed or dissolved in a solvent. Formed by
[0027]
Next, as an example, a method of forming an alternate multilayer film of a metal oxide having a high refractive index and a metal oxide containing a fluorescent material having a low refractive index will be specifically described. First, the base particles are dispersed in an alcohol solution in which an alkoxide such as titanium or zirconium is dissolved, and a mixed solution of water, an alcohol, and a catalyst is dropped with stirring, and the alkoxide is hydrolyzed, so that the surface of the base particles is highly refracted. A titanium oxide film or a zirconium oxide film is formed as a rate film. Thereafter, the powder is subjected to solid-liquid separation, dried, and then subjected to a heat treatment. The drying means may be any of vacuum heating drying, vacuum drying, and natural drying. Further, it is also possible to use a device such as a spray dryer in an inert atmosphere while adjusting the atmosphere. In the heat treatment, a coating composition that does not oxidize is in the air, and a coating composition that is easily oxidized is in an inert atmosphere at 150 to 1100 ° C (when the powder core particles are inorganic powder) or 150 to 500 ° C (powder (When the core particles are other than inorganic powder) for 1 minute to 3 hours. Subsequently, the powder on which the high refractive index film is formed is dispersed in an alcohol solution in which a metal alkoxide having a low refractive index when converted to an oxide such as a silicon alkoxide or an aluminum alkoxide and a fluorescent substance are dissolved or dispersed. Then, a mixed solution of water, alcohol and a catalyst is added dropwise while stirring, and the alkoxide is hydrolyzed to form a silicon oxide or aluminum oxide film as a low refractive index film on the high refractive index film-coated powder surface. I do. Thereafter, the powder is subjected to solid-liquid separation, dried under vacuum, and then subjected to heat treatment in the same manner as described above. By this operation, by repeating the operation of forming a two-layer, high-refractive-index metal oxide film on the surface of the powder base particles, a fluorescent multilayer film-coated powder having a multilayer metal oxide film is obtained. .
[0028]
Further, a special function can be provided by adjusting the thickness of each layer of the alternating coating film having a different refractive index formed on the surface of the base particle. For example, an alternating coating film having a different refractive index is provided on the surface of the base particles so that the following formula (3) is satisfied, the refractive index n of the material forming the coating film and an integer of a quarter of the wavelength of visible light. An alternate film having a thickness d corresponding to m times is provided with an appropriate thickness and an appropriate number of films. As a result, light having a specific wavelength λ (which utilizes interference reflection of Fresnel) is reflected or absorbed.
nd = mλ / 4 (3)
Utilizing this effect, a film having a film thickness and a refractive index that satisfies the formula (3) with respect to a target wavelength of visible light is formed on the surface of the base particles, and a film having a refractive index is further formed thereon. By alternately repeating coating of different films one or more times, a film having a reflection or absorption wavelength width specific to the visible light region is formed. At this time, the order of the materials to be formed is determined as follows. First, when the refractive index of the base particles themselves is high, it is preferable that the first layer is a film having a low refractive index, and in the opposite case, the first layer is a film having a high refractive index.
[0029]
The film thickness is measured and controlled as a reflection waveform using a spectrophotometer or the like to measure the change in the optical film thickness, which is the product of the film refractive index and the film thickness. Design the thickness. For example, when the peak position of the reflection waveform of each unit coating constituting the multilayer film is shifted, white powder is obtained, but when the peak position of the reflection waveform of each unit coating is precisely adjusted, the dye or pigment is not used. Both can be a single colored powder such as blue, green and yellow.
[0030]
However, in the case of actual powder, it is necessary to design in consideration of the particle size and shape of the powder, the phase shift at the interface between the film material and the core particle material, and the peak shift due to the wavelength dependence of the refractive index. is there. For example, when the shape of the core particle is a parallel plate, the Fresnel interference by the parallel film formed on the particle plane is designed under the condition that n in the above equation (3) is replaced by N in the following equation (4). I do. In particular, in the case where the metal film is included even when the powder has a parallel plate shape, the attenuation coefficient κ is included in the refractive index N of the metal in the equation (4). In the case of a transparent oxide (dielectric), κ is very small and can be ignored.
N = n + iκ (i represents a complex number) (4)
When this attenuation coefficient κ is large, the phase shift at the mutual interface between the film material and the nuclear particle material becomes large, and further, affects the optimum interference film thickness due to the phase shift in all the layers of the multilayer film.
[0031]
As a result, even if only the geometrical film thickness is adjusted, the peak position is shifted, so that the color becomes lighter, especially when colored in a single color. In order to prevent this, the effects of the phase shift on all the films are taken into consideration, and a computer simulation is designed so that the combination of the film thicknesses is optimized in advance.
Further, there is a phase shift due to the oxide layer on the metal surface and a peak shift due to the wavelength dependence of the refractive index. In order to correct these, it is necessary to find an optimum condition using a spectrophotometer or the like so that the reflection peak and the absorption bottom have the target wavelength in the final target film number.
[0032]
Interference of a film formed on a curved surface such as a spherical powder occurs similarly to a flat plate, and basically follows the Fresnel interference principle. Therefore, the coloring method can be designed to be a single color. However, in the case of a curved surface, light incident on and reflected by the powder causes complicated interference. These interference waveforms are almost the same as a flat plate when the number of films is small. However, as the total number of films increases, the interference inside the multilayer film becomes more complicated. Also in the case of a multilayer film, the reflection spectral curve can be designed in advance by computer simulation based on the Fresnel interference so that the combination of film thicknesses is optimized. In particular, in the case of forming a film on the surface of the substrate particles, the effect of the phase shift on the surface of the substrate particles and all the films is taken into consideration, and a computer simulation is designed so that the combination of film thicknesses is optimized in advance. Further, a peak shift due to the film layer on the surface of the base particles and a peak shift due to the wavelength dependence of the refractive index are taken into consideration. In the actual sample production, referring to the designed spectral curve, in order to correct these in the actual film, change the film thickness with a spectrophotometer etc. so that the reflection peak and absorption bottom become the target wavelength with the final target film number. Optimal conditions must be found. In the case of coloring an irregularly shaped powder, interference by the multilayer film also occurs, and a basic film design is performed with reference to the conditions of the interference multilayer film of the spherical powder. The peak position of each unit film constituting the above-mentioned multilayer film can be adjusted by the film thickness of each layer, and the film thickness can be adjusted by the solution composition and the reaction time and the number of additions of the raw materials, and can be colored in a desired color. be able to. As described above, a monochromatic powder can be obtained by finding the optimum conditions while changing the film forming conditions such as the film forming solution so that the reflection peak and the absorption bottom have the target wavelength in the final target film number. Further, by controlling the combination of the substances constituting the multilayer film and the thickness of each unit film, it is possible to adjust the color development due to the interference of the multilayer film. Thereby, the powder can be vividly colored to a desired color without using a dye or a pigment. However, if necessary, a coating layer or a colored layer using a coloring material can be provided.
[0033]
The following are specific examples of the coloring material applied as necessary, but the present invention is not limited to these specific examples.
Specifically, for example, as a blue colorant, (organic dye) phthalocyanine dye, oil dye, lake dye, etc., (cyan pigment) phthalocyanine pigment, lake pigment, etc., (inorganic pigment) Metal oxide powders such as titania, alumina, silica, zirconia, ceria, and zinc oxide; and composite oxide pigments such as cobalt aluminate. Examples of yellow colorants include (organic dyes) monoazo dyes, azomethine dyes, oil dyes, lake dyes, and the like, (pigments) benzidine yellow pigments, foron yellow, acetoacetic anilide, insoluble pigments, and the like. Green colorants include (organic dyes) phthalocyanine green dyes, lake dyes such as malachite green, oil dyes, (organic pigments) naphthol green pigments such as pigment green, and green insoluble azo pigments such as green gold. Phthalocyanine green pigments, etc. (inorganic pigments) cobalt green (CoO-Zn-MgO), viridian, emerald green, chrome green and the like. Examples of red colorants include (organic dyes) lake red dyes, oil red dyes, (organic pigments) naphthol red insoluble azo pigments, red insoluble azo pigments, red naphthol pigments, red lake pigments, and the like. Pigments) lead red, cadmium red, etc. Examples of magenta colorants include (dye) anthraquinone dyes, thioindigo, oil-based magenta dyes, and (pigment) xanthene-based magenta dyes such as phosphorus-tungsten-molybdate lake pigments, 2,9-dimethylquinacridone, and naphthol. Insoluble azo pigments, coloring materials composed of xanthene dyes and organic carboxylic acids. Examples of cyan colorants include (organic dyes) phthalocyanine dyes, oil dyes, lake dyes, (organic pigments) phthalocyanine pigments, lake pigments, (inorganic pigments) titania, alumina, silica, zirconia, ceria, Examples include metal oxide powders such as zinc oxide, and composite oxide pigments such as cobalt aluminate.
[0034]
Further, a toning material can be used if necessary. The toning material basically adjusts the color, and is used for performing color matching of a desired color using a plurality of pigments. Specific examples of the toning material to be applied include the following, but the present invention is not limited to these specific examples, and it is also possible to add another pigment or dye as needed and perform toning It is.
Specifically, for example, as the blue color toning material, (organic dyes / pigments) lake dyes such as alkali blue lake and peacock blue lake, lake pigments, phthalocyanine pigments such as metal-free phthalocyanine and copper phthalocyanine, etc. , (Inorganic pigments) oxides such as ultramarine, sulfide composite pigments, copper-based blue-blue pigments such as iron blue and miroly blue, and cobalt oxide-based composite oxides such as cobalt blue and cerulean blue. Examples of the yellow color toning material include (organic dyes) fast dyes such as fast yellow, (organic pigments) azo pigments such as Hanser yellow, naphthol yellow, pigment yellow and permanent yellow, (inorganic pigments) lead and zinc. And chromates (red mouth graphite, chromium vermillion) such as barium, sulfides such as cadmium sulfide, and complex oxide pigments such as titanium yellow. Green color toning materials include (organic dyes) lake dyes such as malachite green lake and acid green lake, (organic pigments) nitroso pigments such as pigment green and naphthol green, azo pigments such as green gold, and phthalocyanine green. Phthalocyanine pigments such as polychrome copper phthalocyanine; (inorganic pigments) chromium oxides and hydrated oxides such as chrome green, zinc green, chromium oxide, and hydrated chromium (viridian); copper-based oxides such as emerald green; Cobalt-based oxides such as green. Examples of red color toning materials include (organic dyes) lake dyes such as eosin lake and rhodamine lake, quinacridone dyes and pigments such as Cinquasia Red, (organic pigments) azo pigments such as permanent red and para red, and brilliant fast red. And sulfide pigments such as cadmium red and mercury red (inorganic pigments). Examples of orange toning materials include azo pigments such as (organic pigments) permanent orange, benzene orange and Hansa Yellow, (inorganic pigments) oxides such as lead chromate (red lead yellow), and chromic acid and lead sulfate. Examples of violet toning materials such as composites (chrome vermillion) include (organic dyes) lake dyes such as methyl violet lake, (organic pigments) azo pigments such as fast violet, (inorganic pigments) cobalt phosphate Pigments such as salts, phosphates such as manganese phosphate, and composite oxides of cobalt arsenic, and the like.
Further, as a toning material for increasing lightness, a white pigment (painting material), for example, titanium oxide, zinc oxide, tin oxide, silicon oxide, antimony oxide, lead oxide, or a composite oxide thereof, Carbonates such as calcium carbonate, magnesium carbonate and barium carbonate; or sulfates such as barium sulfate and calcium sulfate; sulfides such as zinc sulfate; or composite oxides obtained by sintering the above oxides, carbonates and sulfates. And composite hydrated oxides.
[0035]
Next, each of (1) a color ink or a paint-like composition (fluid) and (2) a color toner or a color dry ink-like composition (powder) for preparing the fluorescent pigment composition according to the present invention thus obtained. Will be described.
(1) As a medium (vehicle) of the color ink or the paint-like composition (fluid) in the present invention, a conventionally known varnish used for color printing, color magnetic printing, and color magnetic paint can be used. For example, a liquid polymer, a polymer or a monomer dissolved in an organic solvent, or the like can be appropriately selected and used depending on the type of powder, the application method of the ink, and the application.
[0036]
Examples of the liquid polymer include dienes such as polypentadiene and polybutadiene, polyethylene glycols, polyamides, polypropylenes, waxes, and knitted copolymers thereof.
Polymers soluble in organic solvents include olefin polymers, acrylic resins such as oligoester acrylates, polyesters, polyamides, polyisocyanates, amino resins, xylene resins, ketone resins, diene resins. And rosin-modified phenolic resins, diene rubbers, chloroprene resins, waxes, and modified products and copolymers thereof.
Examples of the monomer soluble in the organic solvent include styrene, ethylene, butadiene, propylene and the like.
Examples of the organic solvent include alcohols such as ethanol, isopropanol and normal propanol, ketones such as acetone, benzene, toluene, xylene, kerosene, benzene hydrocarbons, esters, ethers, and modified products and copolymers thereof. Can be mentioned.
[0037]
(2) A color toner, a color dry ink, and a color dry paint-like composition (powder) are obtained by directly kneading a fluorescent multi-layer coating powder with a resin and, if necessary, a coloring material, and pulverizing the mixture. By doing so, a powdery fluorescent pigment composition can be obtained.
Further, the powder coated with a multilayer film can be made into a powdery fluorescent pigment composition by using a polymerization method such as an emulsion polymerization method or a suspension polymerization method.
In the case of this powdery fluorescent pigment composition, (a) the resin produced by the above-mentioned pulverization method is not particularly limited, but polyamide, epoxy resin, polyester, melamine resin, polyurethane, vinyl acetate resin , A silicon resin, an acrylate, a methacrylate, a polymer or a copolymer of styrene, ethylene, butadiene, propylene and derivatives thereof.
(B) In the case of the polymerization method, polymerization is started from one or a mixture of ester, urethane, vinyl acetate, organic silicon, acrylic acid, methacrylic acid, styrene, ethylene, butadiene, propylene and the like, and the polymer or These copolymers are formed.
[0038]
As described above, the fluorescent pigment composition of the present invention takes the form of (1) a color ink or a paint-like composition (fluid) and (2) a color toner or a color dry ink-like composition (powder).
In the case of a fluid state, it is a color ink, a paint, etc., the solidifying agent, a thickener for increasing the viscosity, a fluid for decreasing the viscosity, Components such as a dispersant and the like can be included for dispersing the agent and the particles.
On the other hand, in the case of powder, (a) when the powder is produced by a pulverization method, a solidification accelerator is used for the coloring material, the toning material, and the resin that is slow to dry, in order to reduce the viscosity at the time of kneading. Can contain components such as a fluidizing agent, a dispersant for dispersing the particles, a charge control agent for fixing to paper or the like, and a wax.
(B) When a polymerization method is used, the colorant or toning material, polymerization initiator, polymerization accelerator, thickener for increasing the viscosity, dispersant for dispersing the particles, dispersant, paper, etc. And a component such as a charge control agent and wax for fixing to the toner.
The multilayer-coated powder in the fluorescent pigment composition of the present invention can be applied to wet and dry color printing and wet and dry color magnetic printing by using a single powder or a combination of a plurality of powders having different spectral characteristics. Using powders of three primary colors, it has five kinds of identification functions of visible light, invisible light (ultraviolet and infrared), fluorescence and magnetism, and requires security functions such as color magnetic ink for preventing forgery of printed matter. It can be applied to other uses.
[0039]
When the fluorescent pigment composition of the present invention is used as a color ink or a paint composition or a color toner, a color dry ink or a color dry paint composition, printing on a substrate, melt transfer or application to an object to be coated, the fluorescent pigment paint composition The relationship between the content of the powder coated with the fluorescent multilayer film and the content of the resin in the product is 1: 0.5 to 1:15 in volume ratio. If the content of the medium is too small, the applied film does not adhere to the object to be coated. On the other hand, if the amount is too large, the color of the pigment becomes too light and cannot be called a good ink or paint. In addition, the relationship between the amount of the pigment and the resin in the color ink or the coating composition and the amount of the solvent is 1: 0.5 to 1:10 by volume ratio. High viscosity and cannot be applied uniformly. On the other hand, if the amount of the solvent is too large, it takes time to dry the coating film, and the efficiency of the coating operation is extremely reduced.
[0040]
In addition, the color density of a coating film when printing, melt-transferring, or applying a coating material to an object to be coated is determined by the amount of pigment per unit area of the object to be coated. After the paint is dried, the amount of the fluorescent multilayer film-coated powder of the present invention on the object to be coated is 5 to 300 g per square meter in area density, preferably 10 to 150 g to obtain a good coating color. can get. If the area density is smaller than the above value, the ground color of the object to be coated appears, and if the area density is larger than the above value, the color density of the coating color does not change, which is uneconomical. That is, even if the pigment is placed on the object to be coated to a certain thickness or more, the light does not reach the pigment on the lower side of the coating film. It is uneconomical to make the coating film thicker than such a thickness, because the coating thickness exceeds the hiding power of the coating material, and the coating effect is not obtained. However, this is not the case when thick coating is performed because the thickness of the coating film is reduced in consideration of the abrasion of the coating film.
[0041]
【Example】
Hereinafter, the present invention will be described more specifically with reference to Examples, but it is needless to say that the scope of the present invention is not limited thereto.
[Example 1]
(Fluorescent multi-layer coated powder 1 using magnetic material; second layer titania coating containing fluorescent material)
(First layer silica coating)
10 g of carbonyl iron powder (manufactured by BASF, average particle size 1.8 μm, magnetization at 10 kOe is 203 emu / g) was dispersed in 100 ml of ethanol, and the temperature of the solution was kept at 55 ° C. by heating the container in an oil bath. 6 g of silicon ethoxide, 8 g of aqueous ammonia (29%) and 8 g of water were added thereto and reacted for 2 hours with stirring. After the reaction, the reaction solution was diluted and washed with ethanol, filtered, and dried in a vacuum drier at 110 ° C. for 3 hours. After drying, heat treatment was performed at 650 ° C. for 30 minutes using a rotary tube furnace to obtain silica-coated powder A. The thickness of the obtained silica coat film was 98 nm, and the dispersion state was very good.
[0042]
(Second layer titania coating)
After the heat treatment, 10 g of the obtained silica-coated powder A ₁ and 8 g of copper-containing zinc cadmium sulfide fine particles (average particle size: 0.01 μm) as a fluorescent substance were dispersed again in 200 ml of ethanol. The container was heated in an oil bath to maintain the temperature of the solution at 55 ° C. To this, 4.7 g of titanium ethoxide is added and stirred. Was added dropwise thereto over 60 minutes a mixed solution of ethanol 30ml of water 8.0 g, and reacted for 2 hours, titania subjected to vacuum drying and heat treatment - to obtain a silica-coated powder A _2. The resulting titania - phosphor copper-containing zinc sulfide cadmium particles / silica coated powder A ₂ has good dispersibility and was an independent particle. Titania - the thickness of the titania film of silica coated powder A ₂ was 77 nm.
The peak wavelength of the spectral reflection curve of this powder was 450 nm, the reflectance at the peak wavelength was 35%, and the powder was bright cyan.
Further, the magnetization of this powder at 10 kOe was 167 emu / g.
[0043]
(Third layer silica coating)
Titania - silica coated powder A ₂ 10 g was dispersed in ethanol 100 ml, and maintained by heating the container in an oil bath the temperature of the liquid to 55 ° C.. 6 g of silica ethoxide, 8 g of aqueous ammonia (29%) and 8 g of water were added thereto and reacted for 2 hours while stirring. After the reaction, the reaction solution was diluted and washed with ethanol, filtered, and dried in a vacuum drier at 110 ° C. for 3 hours. After drying, rotary tubular oven 30 minutes subjecting silica to a heat treatment at 650 ° C. using a - obtaining a titania-code powder A _3. Obtained silica - thickness of the titania-coated powder A ₃ is 99 nm, the dispersion state was very good.
[0044]
(4th layer titania coating)
After the heat treatment again, obtained silica - titania-coated powder A ₃ 10 g was dispersed adding ethanol 200 ml, the temperature was maintained in the liquid by heating the container in an oil bath to 55 ° C.. 5.3 g of titanium ethoxide is added thereto and stirred. Was added dropwise thereto over 60 minutes a mixed solution of ethanol 30ml of water 8.0 g, and reacted for 2 hours, titania subjected to vacuum drying and heat treatment - to obtain a silica-coated powder A _4. The resulting titania - silica coated powder A ₄ are satisfactory dispersibility and was an independent particle. Titania - the thickness of the titania film of silica-coated powder A ₄ was 75 nm.
The reflection peak of this powder was 553 nm, the reflectance was 47%, and the powder was bright green. Further, the magnetization of this powder at 10 kOe was 146 emu / g.
[0045]
(Preparation and spectral properties of color ink composition)
The powder thus obtained was mixed with 35 parts of polyester resin varnish in 65 parts of powder, and then applied to white paper with a blade coater.
The reflection peak of the coated paper was 553 nm in the visible light region, and the reflectance was 53%. Further, when a fluorescent lamp was irradiated, yellow fluorescent light was emitted.
[0046]
[Comparative Example 1]
(Multilayer film-coated powder 1 using magnetic material; when phosphor is not contained)
The same operation as in Example 1 was performed. However, the phosphor copper-containing zinc cadmium sulfide fine particles were not dispersed and mixed in the reaction solution in the second layer of titania coating.
The reflection peak of the coated paper was 553 nm in the visible light region, and the reflectance was 53%. However, even when irradiated with a fluorescent lamp, no fluorescent color was observed.
[0047]
[Example 2]
(Resin-containing dry powder fluorescent pigment composition; for toner, etc.)
100 g of a dry powder of the fourth-layer titania coating (the titania-silica-coated powder A ₄ ) obtained in the same manner as in Example 1 was subjected to a silane coupling agent surface treatment, and then rutile-type titanium oxide (silane cup). 40 g of a ring agent surface-treated product (average particle size: 0.2 μm) and 110 g of a styrene monomer were mixed to make the mixture uniform. The mixture was kept at 70 ° C. in advance, added to a solution of 25 g of sodium n-dodecyl sulfate dissolved in distilled water, emulsified with a high-speed stirrer, further added with 10 g of a 10% aqueous ammonium persulfate solution and stirred at a low speed. Allowed to react for hours.
After completion of the reaction, the reaction mixture was diluted with 2 liters of distilled water, and repeatedly subjected to slant washing while adding distilled water to remove salts. After filtration, the cake was dried at 30 ° C. for 8 hours using a vacuum drier to obtain dried powder B.
Dry powder B was spherical particles having a particle size of about 10 μm, was light green, had a reflection peak of 555 nm, had a reflectance of 53%, and had a magnetization of 58 emu / g at a magnetic field of 10 kOe. When this powder was packed in a glass holder and irradiated with an ultraviolet lamp in a dark place, a light yellow light was emitted.
[0048]
[Example 3]
(Powder 2 coated with a fluorescent multilayer film using a magnetic substance; in the case of phosphor impregnation)
(First layer silica coating)
20 g of carbonyl iron powder (manufactured by BASF (average particle size: 1.8 μm, magnetization at 10 kOe: 203 emu / g)) was dispersed in an ethanol solution in which 3.0 g of silicon ethoxide was previously dissolved in 158.6 g of ethanol, and then stirred. Meanwhile, a mixed solution of 8.0 g of ammonia water and 8.0 g of deionized water prepared in advance was added. To react for 5 hours at normal temperature after the addition, after washing with enough ethanol, dried under vacuum, further using a rotary tubular oven at 500 ° C. in a nitrogen atmosphere, and heat treated for 30 minutes to obtain a silica-coated carbon alkenyl iron powder C ₁ Was.
[0049]
(Second layer titania coating)
20 g of silica-coated carbonyl iron powder C ₁ was previously dispersed in an ethanol solution in which 3.0 g of titanium ethoxide was dissolved in 198.3 g of ethanol, and then 3.0 g of deionized water prepared in advance with stirring. A mixed solution of 23.7 g of ethanol was added dropwise over 1 hour. After the dropping, the mixture was reacted at room temperature for 5 hours, washed with sufficient ethanol, vacuum-dried, and further heat-treated at 500 ° C. for 30 minutes in a nitrogen atmosphere using a rotary tube furnace to obtain titania-silica-coated carbonyl iron powder C _2. Got.
[0050]
(Third layer silica coating)
After dispersing 20 g of titania-silica-coated carbonyl iron powder C ₂ in an ethanol solution in which 3.0 g of silicon ethoxide was previously dissolved in 158.6 g of ethanol, 8.0 g of ammonia water prepared in advance with stirring. And a mixed solution of 8.0 g of deionized water. After the addition, the mixture was reacted at room temperature for 5 hours, washed with sufficient ethanol, vacuum-dried, and further heat-treated in a nitrogen atmosphere at 500 ° C. for 30 minutes using a rotary tube furnace to obtain silica-titania-coated carbonyl iron powder C _3. Got.
[0051]
(4th layer titania coating)
After dispersing 20 g of silica-titania-coated carbonyl iron powder C ₃ in an ethanol solution in which 3.0 g of titanium ethoxide was dissolved in 198.3 g of ethanol in advance, ₃ g of deionized water prepared in advance was stirred. A mixed solution of 0 g and 23.7 g of ethanol was added dropwise over 1 hour. After the dropwise addition, the mixture was reacted at room temperature for 5 hours, washed with sufficient ethanol, dried in vacuum, and further heat-treated at 500 ° C. for 30 minutes in a nitrogen atmosphere using a rotary tube furnace to obtain titania-silica-coated carbonyl iron powder C _4. Got.
[0052]
(Fifth layer silica coating)
After dispersing 20 g of titania-silica-coated carbonyl iron powder C ₄ in an ethanol solution prepared by dissolving 3.0 g of silicon ethoxide in 158.6 g of ethanol, 8.0 g of ammonia water prepared in advance with stirring. And a mixed solution of 8.0 g of deionized water. After the addition, the mixture was reacted at room temperature for 5 hours, washed with sufficient ethanol, dried in vacuum, and further heat-treated in a nitrogen atmosphere at 500 ° C. for 30 minutes using a rotary tube furnace to obtain silica-titania-coated carbonyl iron powder C _5. Got.
[0053]
(6th layer titania coating)
After dispersing 20 g of silica-titania-coated carbonyl iron powder C ₅ in an ethanol solution in which 3.0 g of titanium ethoxide was dissolved in 198.3 g of ethanol in advance, ₃ g of deionized water prepared in advance with stirring was added. A mixed solution of 0 g and 23.7 g of ethanol was added dropwise over 1 hour. After the dropwise addition, the mixture was reacted at room temperature for 5 hours, washed with sufficient ethanol, vacuum dried, and further heat-treated at 500 ° C. for 30 minutes in a nitrogen atmosphere using a rotary tube furnace to obtain titania-silica-coated carbonyl iron powder C _6. Got.
[0054]
The thus obtained multilayer film-coated powder is immersed in a solution of a fluorescent substance, International Orange, dissolved in ethyl acetate at a concentration of 0.5 g / 100 g, solid-liquid separated, dried under vacuum, and coated with a phosphor-impregnated titania-silica coat. to obtain a carbonyl iron powder _{C 7.}
[0055]
(Preparation and spectral properties of color ink composition)
This is mixed with 10 g of polyester resin varnish, 2 g of titania-silica-coated carbonyl iron powder C72, and ₇ g of xylene as a solvent to form an ink. 5 g of this ink is uniformly coated on A4 size art paper with a blade coater. And dried.
The spectral reflectance curve of the coated paper obtained after drying was as shown in FIG. In addition, the coated paper had a vivid greenish-blue color with a reflectance of 43% at a color of 460 nm.
Further, in the ultraviolet region, light near 315 nm is reflected by about 55%, and in the infrared region, light near 1115 nm is reflected by about 60%. It is possible to make a true / false judgment with four types of infrared rays. When a fluorescent lamp was irradiated in a dark place, a pale orange color was produced (FIG. 2).
[0056]
[Example 4]
(In the case of a fluorescent multilayer film-coated powder 3 using a magnetic substance, and a phosphor single-layer coating)
(First layer silica coating)
20 g of carbonyl iron powder (manufactured by BASF (average particle size: 1.8 μm, magnetization at 10 kOe: 203 emu / g)) was dispersed in an ethanol solution in which 3.5 g of silicon ethoxide was previously dissolved in 158.6 g of ethanol, and then stirred. Meanwhile, a mixed solution of 8.0 g of ammonia water and 8.0 g of deionized water prepared in advance was added. After the addition, the mixture was reacted at room temperature for 5 hours, washed with a sufficient amount of ethanol, vacuum-dried, further heat-treated at 800 ° C. for 30 minutes in a nitrogen atmosphere using a rotary tube furnace, cooled, and cooled with silica-coated carbonyl iron powder D. ₁ was obtained.
[0057]
(Second layer zinc sulfide coating)
In a separable flask, 20 g of silica-coated carbonyl iron powder D ₁ was previously dispersed in an ethanol solution in which 5.6 g of zinc ethoxide was dissolved in 198.3 g of ethanol, and then, while stirring, hydrogen sulfide gas was added at 100 ml / min. , And 55.9 g of a 3% cuprous sulfate ethanol solution prepared in advance was added dropwise over 1 hour. After the dropping, the mixture was reacted at room temperature for 4 hours, washed with sufficient ethanol, vacuum dried, and further heat-treated at 800 ° C. for 30 minutes in a nitrogen atmosphere using a rotary tube furnace, cooled, and cooled with silica-coated carbonyl iron powder. to obtain a D _2. The thickness of this zinc sulfide was 55 nm, the reflection peak of this powder was 420 nm, and the powder was blue with a reflectivity of 30%. When a fluorescent lamp was applied to this powder, a green fluorescent color was observed.
[0058]
(Third layer silica coating)
After dispersing 20 g of silica-zinc sulfide-coated carbonyl iron powder D ₂ in an ethanol solution prepared by dissolving 3.5 g of silicon ethoxide in 158.6 g of ethanol in advance, ammonia water prepared in advance was added while stirring. A mixed solution of 0 g and 8.0 g of deionized water was added. After the addition, the mixture was reacted at room temperature for 5 hours, washed with a sufficient amount of ethanol, vacuum dried, further heat-treated at 800 ° C. for 30 minutes in a nitrogen atmosphere using a rotary tube furnace, cooled, and cooled with silica-zinc sulfide coated carbonyl. It was obtained iron powder _{D 3.}
[0059]
(4th layer zinc sulfide coating)
In a separable flask, 20 g of silica-zinc sulfide-coated carbonyl iron powder D ₃ was previously dispersed in an ethanol solution in which 5.6 g of zinc ethoxide was dissolved in 198.3 g of ethanol, and then 100 ml of hydrogen sulfide gas was stirred. / Min. , And 55.9 g of a 3% cuprous sulfate ethanol solution prepared in advance was added dropwise over 1 hour. After the dropwise addition, the mixture was reacted at room temperature for 4 hours, washed with a sufficient amount of ethanol, vacuum dried, and further heat-treated in a nitrogen atmosphere at 800 ° C. for 30 minutes using a rotary tube furnace, cooled, and coated with silica-zinc sulfide. to obtain a carbonyl iron powder _{D 4.} The thickness of this zinc sulfide was 55 nm, the reflection peak of this powder was 385 nm, and it was purple with a reflectance of 41%. When a fluorescent lamp was applied to this powder, a green fluorescent color was observed. Brighter than layer.
[0060]
【The invention's effect】
As described above, the fluorescent pigment composition of the present invention has both color and fluorescence, and blue, green, and color printing of a beautiful and stable color tone of a single color such as yellow, an ink for coating, Filler and paint. In addition, since it has an interference reflection peak in addition to visible light, detection of reflected light by ultraviolet and infrared rays and identification of printed matter based on the presence or absence of fluorescent light, which can determine authenticity without using a special reading device, forgery with high accuracy Prevention becomes possible.
Having these excellent functions and utilizing a magnetic material as the substrate, it can be applied as a coloring material for high-performance color magnetic printing inks, and can emit visible light, invisible light (ultraviolet and infrared), and fluorescent light. It has a discriminating function of six kinds of combinations of magnetism and electricity (change of electric field), and can enhance the effect of preventing forgery of printed matter, and has extremely high practicality.
[Brief description of the drawings]
FIG. 1 is a graph showing a spectral reflectance curve of the fluorescent pigment composition obtained in Example 3.
FIG. 2 is a graph showing a fluorescence spectral reflectance curve of the fluorescent pigment composition obtained in Example 3.

Claims (4)

Have a plurality of coating films on the substrate particles, the coating film of said plurality of shows the optical interference effects, at least one layer of the coating film is involved in and visible light interference as a main component a fluorescent substance Fluorescent A fluorescent pigment composition comprising a powder coated with a conductive multilayer film. The fluorescent pigment composition according to claim 1, wherein the multilayer film exhibits a specific interference reflection peak in a region other than the visible light region. The fluorescent pigment composition according to claim 1, wherein the base particles are magnetic particles. The fluorescent pigment composition according to claim 1, further comprising a coloring material.

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