JP2012037328A - Ultraviolet irradiation apparatus and inspection system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an ultraviolet irradiation apparatus capable of simultaneously or individually radiating the ultraviolet rays of two kinds of wavelengths while adjusting the strength of the respective wavelengths.SOLUTION: The ultraviolet irradiation apparatus 100 includes: a casing 101 having a first opening 111 and a second opening 121; a first lamp 112 disposed inside the casing 101, for radiating the ultraviolet rays within a first wavelength region through the first opening 111; and a second lamp 122 disposed inside the casing 101, for radiating the ultraviolet rays within a second wavelength region through the second opening 121. Also, the ultraviolet irradiation apparatus 100 includes a control part 130. The control part 130 controls ultraviolet irradiation strength from the first lamp 112 through the first opening 111 and ultraviolet irradiation strength from the second lamp 122 through the second opening 121.

Description

  The present invention relates to an ultraviolet irradiation device that irradiates ultraviolet rays in a specific wavelength region, and an inspection system that includes the ultraviolet irradiation device and a luminescent medium that has a luminescent image that appears when ultraviolet rays in a specific wavelength region are irradiated.

  In recent years, micro letters, copy check patterns, infrared absorbing inks have been used to enhance security in media that require prevention of counterfeiting, such as securities including gold vouchers and prepaid cards, and ID cards including licenses. Alternatively, fluorescent ink is used. Among them, the fluorescent ink is an ink containing a phosphor that is hardly visible under visible light but is visible when invisible light (ultraviolet rays or infrared rays) is irradiated. By using such fluorescent ink, it is possible to form a fluorescent image (light-emitting image) that appears only when invisible light within a specific wavelength region is irradiated on securities or the like. As a result, it is possible to prevent the securities from being easily forged by a general-purpose color printer or the like.

  In order to further enhance the effect of preventing forgery, it has been proposed to use fluorescent ink to form a luminescent image that cannot be seen by the naked eye on securities. For example, Patent Document 1 discloses a medium having a luminescent image formed using a first fluorescent ink and a second fluorescent ink. In this case, the first fluorescent ink and the second fluorescent ink are visually recognized as the same color under visible light and ultraviolet light when viewed with the naked eye, and are different from each other when viewed through the determination tool. The ink is visible as a color. For this reason, the luminescent image formed in the securities is not easily counterfeited, and this enhances the counterfeit prevention effect by the fluorescent ink.

Japanese Patent No. 4188881

  The procedure for determining whether the securities are counterfeited is preferably performed simply and quickly. Therefore, a medium that can easily and quickly discriminate whether securities are forged by the naked eye without using a tool such as a discriminating tool under ultraviolet light, and for such a medium, 2 There is a need for an inspection system including an apparatus capable of irradiating ultraviolet rays of various wavelengths simultaneously or individually while adjusting the intensity of each wavelength.

  An object of this invention is to provide the ultraviolet irradiation device and inspection system which can solve such a subject effectively.

  An ultraviolet irradiation device according to the present invention includes a housing having a first opening and a second opening, a first lamp disposed in the housing and irradiating ultraviolet light in a first wavelength region through the first opening. A second lamp that is disposed in the housing and irradiates ultraviolet rays in a second wavelength region through the second opening, and an intensity of ultraviolet irradiation from the first lamp through the first opening and the second lamp. And a control unit that controls the intensity of ultraviolet irradiation from the second lamp through the two openings.

  In the ultraviolet irradiation apparatus according to the present invention, the first opening is provided with a first shutter having a variable aperture ratio, the second opening is provided with a second shutter having a variable aperture ratio, and the controller Controls the aperture ratio of the first shutter and the aperture ratio of the second shutter.

  In the ultraviolet irradiation apparatus according to the present invention, the control unit controls an applied voltage to the first lamp and an applied voltage to the second lamp.

  The inspection system by this invention is an inspection system provided with the said ultraviolet irradiation device and a luminescent medium, Comprising: The said luminescent medium has a base material and the luminescent image on the said base material, The said luminescent image Has a first region containing a first phosphor and a second region containing a second phosphor, at least a portion of the second region being adjacent to the first region, When the first lamp and the second phosphor are irradiated with ultraviolet rays in the first wavelength region, the first phosphor and the second phosphor emit light having a color that is visually recognized as the same color, and the second lamp emits the first light. When the ultraviolet rays in the two-wavelength region are irradiated, the first region and the second region are visually recognized as different color regions.

  In the inspection system according to the present invention, when the first lamp is irradiated with ultraviolet rays in the first wavelength region, the first phosphor emits light of a first color, and the second phosphor is The first phosphor emits light of a color that is visually recognized as the first color or the same color as the first color, and when the second lamp is irradiated with ultraviolet rays in the second wavelength region, the first phosphor has the second color. The second phosphor emits light of a third color or emits no light, and the first region and the second region are visually recognized as different color regions.

  In the inspection system according to the present invention, when the first lamp is irradiated with ultraviolet rays in the first wavelength region, the first phosphor emits light of a first color, and the second phosphor is The first phosphor emits light of a color that is visually recognized as the first color or the same color as the first color and is irradiated with ultraviolet rays in the second wavelength region by the second lamp. The second phosphor emits light of a color visually recognized as the same color as the first color, or the third phosphor emits light of the third color, or does not emit light, and the first region and the second region are Are visually recognized as regions of different colors.

  The inspection system according to the present invention is an inspection system including the ultraviolet irradiation device and a light emitting medium, and the light emitting medium includes a base material and a light emitting image on the base material, and the light emitting image. Has a first region containing a first phosphor and a second region containing a second phosphor, at least a portion of the second region being adjacent to the first region, The first phosphor and the second phosphor when irradiated with ultraviolet rays within the first wavelength region by one lamp or when irradiated with ultraviolet rays within the second wavelength region by the second lamp Emits light of a color that is visually recognized as the same color, and when irradiated with ultraviolet rays in the first wavelength region and ultraviolet rays in the second wavelength region simultaneously by the first lamp and the second lamp, The first phosphor and the second phosphor are different from each other. The color of the light to be viewed Te light is emitted.

  In the inspection system according to the present invention, when the first lamp is irradiated with ultraviolet rays in the first wavelength region, the first phosphor emits light of a first color, and the second phosphor is The first phosphor emits light of a color that is visually recognized as the first color or the same color as the first color, and when the second lamp is irradiated with ultraviolet rays in the second wavelength region, the first phosphor has the second color. The second phosphor emits light of a color that is visually recognized as the second color or the same color as the second color.

  In the inspection system according to the present invention, when the ultraviolet ray in the first wavelength region is irradiated, the color of light emitted from the first phosphor and the color of light emitted from the second phosphor The color difference between and is 10 or less.

  The inspection system according to the present invention is an inspection system including the ultraviolet irradiation device and a light emitting medium, and the light emitting medium includes a base material and a light emitting image on the base material, and the light emitting image. Has a first region containing a first phosphor and a second region containing a second phosphor, at least a portion of the second region being adjacent to the first region, The first phosphor and the second phosphor when irradiated with ultraviolet rays in the first wavelength region by one lamp and when irradiated with ultraviolet rays in the second wavelength region by the second lamp Emits light of colors visually recognized as different colors, and when the first lamp and the second lamp are simultaneously irradiated with ultraviolet rays in the first wavelength region and ultraviolet rays in the second wavelength region, The first phosphor and the second phosphor have the same color. The color of the light to be viewed Te light is emitted.

  According to the present invention, the ultraviolet irradiation device adjusts the shutter aperture ratio or the applied voltage, thereby simultaneously adjusting the irradiation intensity of the ultraviolet light in the first wavelength region and the ultraviolet light in the second wavelength region. Or it can irradiate individually. The light-emitting medium has a light-emitting image formed using a phosphor that emits light of different colors when irradiated with ultraviolet rays in the first wavelength region and when irradiated with ultraviolet rays in the second wavelength region. The ultraviolet irradiation device irradiates the light emitting medium with ultraviolet rays in the first wavelength region and ultraviolet rays in the second wavelength region simultaneously or individually while adjusting the respective irradiation intensities. It is possible to check the luminescent image.

1 is a schematic configuration diagram of an inspection system according to an embodiment of the present invention. It is an external view of the ultraviolet irradiation device concerning the embodiment. It is an external view of the ultraviolet irradiation device concerning the embodiment. It is an external view of the ultraviolet irradiation device concerning the embodiment. It is a top view which shows an example of the securities comprised by the forgery prevention medium which consists of a light emission medium which concerns on the embodiment. It is a top view which shows the light emission image of a forgery prevention medium. It is sectional drawing along the III-III line of the light emission image shown in FIG. It is a figure which shows the fluorescence emission spectrum of 1st fluorescence ink. It is a figure which shows the fluorescence emission spectrum of 2nd fluorescence ink. It is an xy chromaticity diagram showing the chromaticity of fluorescence emitted from the first fluorescent ink and the second fluorescent ink. It is a top view which shows the light emission image when UV-A is irradiated. It is a top view which shows the light emission image when UV-C is irradiated.

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

  FIG. 1 is a schematic configuration diagram of an inspection system 1 according to an embodiment of the present invention. As shown in FIG. 1, the inspection system 1 includes an ultraviolet irradiation device 100 that irradiates ultraviolet rays in the first wavelength region and ultraviolet rays in the second wavelength region simultaneously or individually, and an anti-counterfeit medium 200 made of a light emitting medium. Prepare. The forgery prevention medium 200 is a securities such as a gift certificate. The inspection system 1 inspects (confirms) whether the securities are legitimate by observing the anti-counterfeit medium 200 irradiated with ultraviolet rays by the ultraviolet irradiation device 100 with the naked eye.

  First, the ultraviolet irradiation apparatus 100 will be described with reference to FIGS. FIG. 2 is an external view of the ultraviolet irradiation device 100. As shown in FIG. 2, the ultraviolet irradiation device 100 includes a housing 101 having a first opening 111 and a second opening 121, and a first lamp 112 and a second lamp 122 arranged in the housing 101.

  The casing 101 is an aluminum casing having a size of, for example, 80 mm × 200 mm × 80 mm.

  The first lamp 112 irradiates ultraviolet rays in the first wavelength region through the first opening 111. The first wavelength region is 315 m to 400 nm, and the first lamp 112 emits so-called UV-A. For example, the first lamp 112 can be a 6 W (100 V) high-pressure mercury UV lamp having an emission peak wavelength of 365 nm.

  The second lamp 122 irradiates ultraviolet rays in the second wavelength region through the second opening 112. The second wavelength region is 200 nm to 280 nm, and the second lamp 122 emits so-called UV-C. For example, the second lamp 122 may be a 6 W (100 V) low-pressure mercury UV lamp having an emission peak wavelength of 254 nm.

  Further, the first opening 111 is provided with a louver-type first shutter 113 having a variable aperture ratio in which, for example, plate-like wings of 50 mm × 10 mm × 2 mm are arranged. In addition, the second opening 121 is provided with a louver-type second shutter 123 in which plate-shaped wings of, for example, 50 mm × 10 mm × 2 mm are arranged and the aperture ratio is variable. The aperture ratios of the first shutter 113 and the second shutter 123 can be changed from 0% to 98%.

  Furthermore, the ultraviolet irradiation device 100 includes a control unit 130 that controls the aperture ratios of the first shutter 113 and the second shutter 123. The aperture ratio of the first shutter 113 can be adjusted by turning the rotary knob 131 provided in the control unit 130. Further, the aperture ratio of the second shutter 123 can be adjusted by turning the rotary knob 132 provided in the control unit 130. In FIG. 1, the control unit 130 is provided outside the housing 101, but may be integrated with the housing 101. Further, the adjustment of the aperture ratios of the first shutter 113 and the second shutter 123 may be performed using a button or the like other than a knob.

  By controlling the aperture ratios of the first shutter 113 and the second shutter 123, the ultraviolet (UV-A) irradiation intensity from the first lamp 112 through the first opening 111 and the second lamp through the second opening 121. The intensity of ultraviolet (UV-C) irradiation from 122 can be controlled. For example, by increasing the aperture ratio of the first shutter 113, the intensity of UV-A irradiation from the first lamp 112 through the first aperture 111 can be increased. Similarly, by increasing the aperture ratio of the second shutter 123, the UV-C irradiation intensity from the first lamp 122 through the second aperture 121 can be increased.

  As shown in FIG. 2, by opening both the first shutter 113 and the second shutter 123, the ultraviolet irradiation device 100 can irradiate UV-A and UV-C simultaneously. At this time, by adjusting the aperture ratios of the first shutter 113 and the second shutter 123, UV-A and UV-C can be irradiated with desired irradiation intensities, respectively.

  Further, as shown in FIG. 3, the ultraviolet irradiation device 100 can irradiate only UV-C by closing the first shutter 113 (with an aperture ratio of 0%) and opening the second shutter 123. it can. At this time, by adjusting the aperture ratio of the second shutter 123, only UV-C can be irradiated with a desired irradiation intensity.

  Also, as shown in FIG. 4, the ultraviolet irradiation device 100 can irradiate only UV-A by closing the second shutter 123 (with an aperture ratio of 0%) and opening the first shutter 113. it can. At this time, by adjusting the aperture ratio of the first shutter 113, only UV-A can be irradiated with a desired irradiation intensity.

By adjusting the aperture ratios of the first shutter 113 and the second shutter 123, the irradiation intensity of the first lamp 112 on the irradiation surface 70 mm away from the ultraviolet irradiation device 100 can be adjusted in the range of 0 to 1100 μW / cm ^2. The irradiation intensity of the second lamp 122 can be adjusted in the range of 0 to 1300 μW / cm ² .

  As described above, the ultraviolet irradiation device 100 adjusts the aperture ratios of the first shutter 113 and the second shutter 123, so that the ultraviolet (UV-A) in the first wavelength region and the ultraviolet (UV) in the second wavelength region (UV). -C) can be irradiated simultaneously or individually while adjusting the amount of each irradiation.

  Next, the forgery prevention medium 200 will be described with reference to FIGS. FIG. 5 is a top view of the forgery prevention medium 200. As illustrated in FIG. 5, the anti-counterfeit medium 200 includes a base material 211 and a light-emitting image 212 formed on the base material 211. In the present embodiment, as will be described later, the light emission image 212 functions as an authenticity determination image for determining the authenticity of the forgery prevention medium 200.

  As shown in FIG. 5, the light emission image 212 includes a pattern area (first area) 220 and a background area (second area) 225 formed adjacent to the pattern area 220. In the example shown in FIG. 5, the pattern area 220 is made of the letter “A” (pattern), and the background area 225 is formed so as to surround the pattern area 220. As will be described later, each of the regions 220 and 225 is formed by printing fluorescent ink that emits fluorescence when excited by ultraviolet rays.

  The material of the base material 211 used in the forgery prevention medium 200 is not particularly limited, and is appropriately selected according to the type of securities configured by the forgery prevention medium 200. For example, white polyethylene terephthalate having excellent printability and processability is used as the material of the substrate 211. The thickness of the base material 211 is appropriately set according to the type of securities constituted by the forgery prevention medium 200.

The size of the luminescent image 212 is not particularly limited, and is appropriately set according to the ease of authenticity determination and the required determination accuracy. For example, the lengths l ₁ and l ₂ of the luminescent image 212 are in the range of 1-210 mm and 1-300 mm, respectively.

  Next, the light emission image 212 will be described in more detail with reference to FIGS. 6 and 7. 6 is an enlarged plan view showing the luminescent image 212 under visible light, and FIG. 7 is a cross-sectional view taken along line III-III of the luminescent image 212 shown in FIG.

  First, the structure of the luminescent image 212 will be described with reference to FIG. As shown in FIG. 7, the pattern area 220 and the background area 225 of the luminescent image 212 are formed by solid-printing the first fluorescent ink 213 and the second fluorescent ink 214 on the base material 211.

  FIG. 7 shows an example in which the first fluorescent ink 213 in the pattern area 220 is in contact with the second fluorescent ink 214 in the background area 225. However, in the present invention, “adjacent” is not limited to this, and a gap that cannot be visually recognized by the naked eye is the first fluorescent ink 213 in the pattern region 220 and the first region in the background region 225. It may be formed between the two fluorescent inks 214. Further, the first fluorescent ink 213 and the second fluorescent ink 214 may be overlapped between the first fluorescent ink 213 in the pattern area 220 and the second fluorescent ink 214 in the background area 225.

The thicknesses t ₁ and t ₂ of the first fluorescent ink 213 and the second fluorescent ink 214 are appropriately set according to the type of securities, the printing method, etc. For example, the thickness t ₁ is 0.3 to 100 μm. It has a range of the thickness _{t 2} is in the range of 0.3～100Myuemu. Incidentally, preferably, the thickness t ₁ and the thickness t ₂ is almost the same. Accordingly, it is possible to suppress the visual recognition of the boundary between the pattern area 220 and the background area 225 due to the difference between the thickness of the first fluorescent ink 213 and the thickness of the second fluorescent ink 214.

  As will be described later, each of the first fluorescent ink 213 and the second fluorescent ink 214 does not emit light under visible light, but emits predetermined fluorescence emitted when UV-A or UV-C is irradiated by the ultraviolet irradiation device 100. Contains a body, for example, a particulate pigment. Here, the particle size of the pigment contained in the inks 213 and 214 is, for example, in the range of 0.1 to 10 μm, and preferably in the range of 0.1 to 3 μm. For this reason, when the inks 213 and 214 are irradiated with visible light, the light is scattered by the pigment particles. Therefore, when the luminescent image 212 is viewed under visible light, as shown in FIG. 6, the white picture area 221 a is visually recognized as the picture area 220 and the white background area 226 a is visually recognized as the background area 225. Further, as described above, the base material 211 in the present embodiment is formed from white polyethylene terephthalate. For this reason, under visible light, the base material 211, the pattern area 220 and the background area 225 of the luminescent image 212 are all visually recognized as white. Therefore, the pattern of the pattern area 220 of the luminescent image 212 does not appear under visible light. This prevents the forgery prevention medium 200 having the luminescent image 212 from being easily forged.

  In FIG. 6, the first boundary line 215a between the pattern area 220 and the background area 225 and the second boundary line 215b between the base material 211 and the light emission image 212 are drawn for convenience. is there. Under visible light, the first boundary line 215a or the second boundary line 215b is not actually visually recognized.

  Next, the first fluorescent ink 213 and the second fluorescent ink 214 will be described in more detail with reference to FIGS. FIG. 8 is a diagram showing a fluorescence emission spectrum of the first fluorescent ink 213, and FIG. 9 is a diagram showing a fluorescence emission spectrum of the second fluorescence ink 214. FIG. 10 is an xy chromaticity diagram showing, in the XYZ color system, the chromaticity of light emitted from the first fluorescent ink 213 and the second fluorescent ink 214 when light in a specific wavelength region is irradiated.

  First, the first fluorescent ink 213 will be described. In FIG. 8, the alternate long and short dash line indicates the fluorescence emission spectrum of the first fluorescent ink 213 when irradiated with UV-A, and the solid line indicates the fluorescence of the first fluorescent ink 213 when irradiated with UV-C. The emission spectrum is shown. Each fluorescence emission spectrum shown in FIG. 8 is standardized so that the peak intensity at the maximum peak is 1.

As shown in FIG. 8, when the first fluorescent ink 213 was irradiated with UV-A, it emitted blue (first color) light having a peak wavelength λ _1A of about 445 nm and was irradiated with UV-C. At this time, it emits red (second color) light having a peak wavelength λ _1C of about 610 nm. Thus, the 1st fluorescent ink 213 contains what is called a dichroic fluorescent substance (1st fluorescent substance) from which luminescent color differs at the time of UV-A irradiation and UV-C irradiation. Such a dichroic phosphor is configured, for example, by appropriately combining a phosphor excited by UV-A and a phosphor excited by UV-C (for example, JP-A-10-251570). Issue gazette).

During UV-A irradiation, light having a wavelength of about 610 nm is also emitted as shown in FIG. However, since light having a wavelength of about 610 nm has a lower intensity than light having a peak wavelength λ _1A of about 445 nm, the light from the first fluorescent ink 213 is visually recognized as blue light during UV-A irradiation. Similarly, at the time of UV-C irradiation, light having a wavelength of about 445 nm is also emitted as shown in FIG. 8, but since the intensity thereof is small, the light from the first fluorescent ink 213 is visually recognized as red light.

  Next, the second fluorescent ink 214 will be described. In FIG. 9, the alternate long and short dash line indicates the fluorescence emission spectrum of the second fluorescent ink 214 when irradiated with UV-A, and the solid line indicates the fluorescence of the second fluorescent ink 214 when irradiated with UV-C. The emission spectrum is shown. As in the case of FIG. 8, the fluorescence emission spectra shown in FIG. 9 are normalized so that the peak intensity at the maximum peak is 1.

As shown in FIG. 9, the second fluorescent ink 214 emits blue light having a peak wavelength λ _2A of about 445 nm when irradiated with UV-A. The blue color (third color) emitted by the second fluorescent ink 214 is visually recognized as the same color or the same color as the blue color (first color) emitted by the first fluorescent ink 213 during UV-A irradiation. The second fluorescent ink 214 emits green (fourth color) light having a peak wavelength λ _2C of about 525 nm when irradiated with UV-C. As described above, the second fluorescent ink 214 also includes a so-called dichroic phosphor (second phosphor) that emits different colors when irradiated with UV-A and when irradiated with UV-C, like the first fluorescent ink 213. It is out.

During UV-A irradiation, light having a wavelength of about 525 nm is also emitted as shown in FIG. However, since light having a wavelength of about 525 nm has a lower intensity than light having a peak wavelength λ _2A of about 445 nm, the light from the second fluorescent ink 214 is visually recognized as blue light during UV-A irradiation. Similarly, at the time of UV-C irradiation, light having a wavelength of about 445 nm is also emitted as shown in FIG. 9, but since the intensity thereof is small, the light from the second fluorescent ink 214 is visually recognized as green light.

  Next, with reference to FIG. 10, the color of light emitted from the first fluorescent ink 213 or the second fluorescent ink 214 during UV-A or UV-C irradiation will be described in more detail. In the code | symbol shown in FIG. 10, the white circle or square has shown the chromaticity of the light emitted from the 1st fluorescent ink 213 or the 2nd fluorescent ink 214 at the time of UV-A irradiation, respectively. Black circles or squares indicate the chromaticity of light emitted from the first fluorescent ink 213 or the second fluorescent ink 214 during UV-C irradiation, respectively.

  The blue color (first color) corresponds to the chromaticity indicated by a white circle in FIG. 10, and the blue color (third color) corresponds to the chromaticity indicated by a white square in FIG. is doing. Further, the red color (second color) corresponds to the chromaticity indicated by the black circle in FIG. 10, and the green color (fourth color) is indicated by the black square in FIG. It corresponds to chromaticity.

  As shown in FIG. 10, in the xy chromaticity diagram, the chromaticity of light emitted from the first fluorescent ink 213 during UV-A irradiation, and the chromaticity of light emitted from the second fluorescent ink 214 during UV-A irradiation. Are close. For this reason, as described above, the light emitted from the second fluorescent ink 214 when irradiated with UV-A is visually recognized as the same color as the light emitted from the first fluorescent ink 213 during UV-A irradiation. For this reason, the pattern area 220 formed using the first fluorescent ink 213 and the background area 225 formed using the second fluorescent ink 214 are visually recognized as the same color area during UV-A irradiation. Therefore, as described later, during UV-A irradiation, the entire light emission image 212 is visually recognized as a single color (blue) image, and thus the pattern of the pattern region 220 does not appear.

  Further, as shown in FIG. 10, in the xy chromaticity diagram, the chromaticity of light emitted from the first fluorescent ink 213 during UV-C irradiation and the chromaticity of light emitted from the second fluorescent ink 214 during UV-C irradiation. Is far away. For this reason, the light emitted from the second fluorescent ink 214 when irradiated with UV-C is visually recognized as light having a different color from the light emitted from the first fluorescent ink 213 during UV-C irradiation. For this reason, the pattern region 220 formed using the first fluorescent ink 213 and the background region 225 formed using the second fluorescent ink 214 are visually recognized as different color regions during UV-C irradiation. Therefore, as will be described later, the pattern of the pattern region 220 is visually recognized during UV-C irradiation.

In the present invention, “same color” means that the chromaticities of two colors are close to each other to the extent that the color difference cannot be determined with the naked eye. More specifically, “same color” means that the color difference ΔE ^* _ab between the two colors is 10 or less, preferably 3 or less. The “different color” means that the color difference ΔE ^* _ab between the two colors is larger than 10. Here, the color difference ΔE ^* _ab is a value calculated based on L ^* , a ^* and b ^* in the L ^* a ^* b ^* color system, and is an index relating to a color difference when observed with the naked eye. Is the value. ^{Incidentally, L} * in the L ^* a * ^{b *} color system, ^{a *} and ^{b *,} or tristimulus values X in the XYZ color system, Y and Z, is calculated based on the spectrum of light. A relationship according to a well-known conversion equation is established between L ^* , a ^*, and b ^* and the tristimulus values X, Y, and Z.

  The tristimulus values can be measured by using a measuring instrument such as a spectrophotometer, a color difference meter, a colorimeter, a color meter, a chromaticity meter, for example. Among these measuring instruments, the spectrophotometer can obtain the spectral reflectance of each wavelength, and therefore can measure the tristimulus values with high accuracy, and is therefore suitable for analyzing the color difference.

In order to calculate the color difference ΔE ^* _ab , for example, first, light from a plurality of media (inks) to be compared is measured with a spectrophotometer, and based on the result, tristimulus values X, Y, Z, or L ^* , a ^* , b ^* are calculated. Then, ^L * in a plurality of media ^(ink), a *, ^b difference ^{* (ΔL *, Δa *,} Δb *) from to calculate the color difference on the basis of the following equation.

  Examples of the first fluorescent ink 213 and the second fluorescent ink 214 include, for example, 25% by weight of a dichroic phosphor having predetermined fluorescence characteristics, 8% by weight of microsilica, 2% by weight of organic bentonite, 50% by weight of alkyd resin, and Inks made into offset inks by adding 15% by weight of an alkylbenzene solvent are used. Among these, as the dichroic phosphor (first phosphor) for the first fluorescent ink 213, for example, it is excited by ultraviolet light having a wavelength of 254 nm to emit red light, and is excited by ultraviolet light having a wavelength of 365 nm to emit blue light. A phosphor DE-RB (manufactured by Nemoto Special Chemical) that emits light is used. In addition, as the dichroic phosphor (second phosphor) for the second fluorescent ink 214, for example, green light is emitted by being excited by ultraviolet rays having a wavelength of 254 nm, and blue light is emitted by being excited by ultraviolet rays having a wavelength of 365 nm. The phosphor DE-GB (manufactured by Nemoto Special Chemical) is used.

  Next, a method for inspecting whether the securities comprising the anti-counterfeit medium 200 are genuine will be described.

  First, the anti-counterfeit medium 200 under visible light is observed. In this case, as described above, the base material 211, the pattern area 220 and the background area 225 of the light emission image 212 are visually recognized as white (see FIG. 6). For this reason, the pattern of the pattern area 220 of the luminescent image 212 does not appear under visible light.

  Next, the second shutter 123 of the ultraviolet irradiation device 100 is closed (the aperture ratio is set to 0%), the first shutter 113 is opened, and the forgery prevention medium 200 is irradiated with UV-A and observed.

  FIG. 11 is a plan view showing a light emission image 212 of the forgery prevention medium 200 at the time of UV-A irradiation. The first fluorescent ink 213 that forms the pattern region 220 emits blue light. Therefore, the pattern area 220 is visually recognized as the blue portion 221b. On the other hand, the second fluorescent ink 214 forming the background region 225 emits blue light. Therefore, the background region 225 is also visually recognized as the blue portion 226b. Thus, at the time of UV-A irradiation, the pattern area 220 and the background area 225 are visually recognized as areas of the same color. Therefore, the pattern of the pattern area 220 of the light emission image 212 does not appear at the time of UV-A irradiation.

  Subsequently, the first shutter 113 of the ultraviolet irradiation device 100 is closed (the aperture ratio is set to 0%), the second shutter 123 is opened, and the forgery prevention medium 200 is irradiated with UV-C and observed.

  FIG. 12 is a plan view showing a light emission image 212 of the forgery prevention medium 200 at the time of UV-C irradiation. The first fluorescent ink 213 that forms the pattern region 220 emits red light. Therefore, the pattern area 220 is visually recognized as the red portion 221c. On the other hand, the second fluorescent ink 14 forming the background region 225 emits green light. Therefore, the background region 225 is visually recognized as the green portion 226c. Thus, at the time of UV-C irradiation, the pattern area 220 and the background area 225 are visually recognized as areas of different colors. Therefore, at the time of UV-C irradiation, the pattern of the pattern area 220 of the light emission image 212 is visually recognized.

  At this time, the ultraviolet irradiation device 100 can irradiate the emission image 212 with UV-C while adjusting the aperture ratio of the second shutter 123, that is, while adjusting the irradiation intensity. Therefore, it is possible to irradiate UV-C with an intensity suitable for visually recognizing the pattern of the pattern region 220 of the light emitting image 212, and to improve the visibility of the pattern.

  The pattern area 220 and the background area 225 are not discriminated when irradiated with UV-A, but are discriminated only after being irradiated with UV-C. That is, the pattern of the pattern region 220 is not visually recognized when irradiated with UV-A, but is recognized only when irradiated with UV-C. By checking that the colors of the pattern area 220 and the background area 225 change as described above when irradiated with visible light, UV-A, or UV-C, the securities composed of the anti-counterfeit medium 200 are authorized. It is confirmed that it is a thing.

  As described above, the pattern region 220 and the background region 225 are formed using the ink containing the dichroic phosphor, so that the forgery prevention medium 200 is counterfeited compared to the case where the ink containing the monochromatic phosphor is used. Can be difficult. In addition, the ultraviolet irradiation device 100 irradiates the anti-counterfeit medium 200 with UV-A and UV-C while adjusting the irradiation intensity, so that the luminescent image 212 can be easily and quickly determined by the naked eye. It becomes possible to discriminate.

First Modification of Anti-Counterfeit Medium 200 In the above embodiment, ink containing phosphor DE-RB is used as first fluorescent ink 213, and ink containing phosphor DE-GB is used as second fluorescent ink 214. An example is given. That is, an example in which the ink of the combination_1 in Table 1 shown below is used is shown. However, the present invention is not limited to this, and as the first fluorescent ink 213 and the second fluorescent ink 214, inks of combinations_2 to 6 in Table 1 may be used.

In Table 1, the colors shown in the column “UV-A” or “UV-C” are the first fluorescent ink 213 and the second fluorescent ink when UV-A or UV-C is irradiated. Each color of light emitted from 214 is shown. Further, the names shown in the column of “phosphor” all represent product names in the fundamental special chemistry. In this case, in the product name “DE-X ₁ X ₂ ”, X ₁ indicates the emission color at the time of UV-C irradiation, and X ₂ indicates the emission color at the time of UV-A irradiation. For example, the phosphor DE-GR is a phosphor that emits green light when irradiated with UV-C and emits red light when irradiated with UV-A.

  In combination_2 or combination_3, as in the case of combination_1, the first fluorescent ink 213 and the second fluorescent ink 214 are inks that emit light of the same color or a color that is visually recognized as the same color when irradiated with UV-A. ing.

  In combination_4 to combination_6, in contrast to combination_1 to combination_3, the first fluorescent ink 213 and the second fluorescent ink 214 emit light that is visually recognized as the same color or the same color when irradiated with UV-C. It becomes ink to do. That is, the pattern of the pattern area 220 is not visually recognized when irradiated with UV-C, but is recognized only when irradiated with UV-A.

  Even with such a combination of inks, it is possible to prevent the pattern of the luminescent image 212 from being easily elucidated, which makes it more difficult to forge the anti-counterfeit medium 200.

  In the above embodiment, when invisible light in the second wavelength region is irradiated, the first phosphor emits light of the second color, and the second phosphor emits light of the third color. For this reason, an example has been shown in which the first region including the first phosphor and the second region including the second phosphor are visually recognized as different color regions. However, the present invention is not limited to this.

  That is, when invisible light in the first wavelength region is irradiated, the first phosphor and the second phosphor emit light of a color that is visually recognized as the same color, and invisible light in the second wavelength region. As long as the first region including the first phosphor and the second region including the second phosphor are visually recognized as differently colored regions, the emission color of the first phosphor is arbitrarily set. It is possible.

  For example, when invisible light in the first wavelength region is irradiated, the first color light is emitted, and when invisible light in the second wavelength region is irradiated, the first color or the first color is also emitted. The 1st fluorescent substance which light-emits the light of the color visually recognized as the same color may be used. In this case, when invisible light in the first wavelength region is irradiated, the first phosphor emits light of the first color, and the second phosphor is visually recognized as the same color as the first color or the first color. Emit light of a certain color. For this reason, the first region and the second region are visually recognized as regions of the same color. On the other hand, when invisible light in the second wavelength region is irradiated, the first phosphor emits light of a color that is visually recognized as the first color or the same color as the first color, and the second phosphor Emits color light or does not emit light. For this reason, the first region and the second region are visually recognized as different color regions. Therefore, the pattern of the luminescent image composed of the first region and the second region is not visible when irradiated with invisible light in the first wavelength region, but only after being irradiated with invisible light in the second wavelength region. Visible. As a result, it is possible to easily and quickly confirm the emission image.

Second Modification Example of Anti-Counterfeit Medium 200 In the above embodiment and the first modification example, the pattern of the pattern region 220 is not visually recognized when one of UV-A and UV-C is irradiated, and is visible only when the other is irradiated. However, it is not visually recognized by UV-A irradiation or UV-C irradiation, but can be recognized only by simultaneous irradiation of UV-A and UV-C.

  At this time, the first fluorescent ink 213 emits red (first color) light having a peak wavelength of about 610 nm when irradiated with UV-A, and has a peak wavelength of about 610 nm when irradiated with UV-C. Emits green (second color) light of 520 nm. The first fluorescent ink 213 emits yellow (fifth color) light when irradiated with UV-A and UV-C simultaneously. As the first fluorescent ink 213, for example, the above-described phosphor DE-GR can be used.

  The second fluorescent ink 214 emits red (third color) light having a peak wavelength (emission wavelength) of about 615 nm when irradiated with UV-A, and peaks when irradiated with UV-C. Emits green (fourth color) light having a wavelength of about 515 nm. The second fluorescent ink 214 emits yellow (sixth color) light when irradiated with UV-A and UV-C simultaneously. As the second fluorescent ink 214, a fluorescent medium DE-GR1 (manufactured by Nemoto Special Chemical) having an emission wavelength difference of 5 nm or less from the phosphor DE-GR can be used. That is, the fluorescent medium DE-GR1 has a shorter emission wavelength of about 5 nm than DE-GR and a longer emission wavelength of about 5 nm than DE-GR.

  Red (first color) having a peak wavelength of about 610 nm and red (third color) having a peak wavelength of about 615 nm are visually recognized as the same color. Further, green (second color) having a peak wavelength of about 520 nm and green (fourth color) having a peak wavelength of about 515 nm are visually recognized as the same color.

On the other hand, the color difference ΔE ^* _ab between yellow (fifth color) emitted from the first fluorescent ink 213 and yellow (sixth color) emitted from the second fluorescent ink 214 when UV-A and UV-C are simultaneously irradiated. Becomes about 12, which is visually recognized as a different color.

  Since the first fluorescent ink 213 includes the fluorescent medium DE-GR and the second fluorescent ink 214 includes the fluorescent medium DE-GR1, when the ultraviolet irradiation device 100 irradiates only UV-A, the pattern region 220 and the background region 225 Is visually recognized as a region of the same color (red), and the pattern of the pattern region 220 of the luminescent image 212 does not appear. When the ultraviolet irradiation device 100 irradiates only UV-C, the pattern region 220 and the background region 225 are visually recognized as the same color (green) region, and the pattern of the pattern region 220 of the luminescent image 212 does not appear. When the ultraviolet irradiation device 100 simultaneously irradiates UV-A and UV-C, the pattern area 220 and the background area 225 are visually recognized as different yellow areas, and the pattern of the pattern area 220 of the luminescent image 212 is visually recognized.

  That is, the pattern of the pattern region 220 is not visually recognized when UV-A is irradiated, but is not visually recognized when UV-C is irradiated, and is only recognized when UV-A and UV-C are simultaneously irradiated.

  As described above, the dichroic phosphor contained in the ink forming the pattern region 220 and the dichroic phosphor contained in the ink forming the background region 225 have an emission wavelength difference of 5 nm or less. Thus, forgery of the forgery prevention medium 200 can be made more difficult.

  Moreover, the ultraviolet irradiation device 100 can irradiate UV-A and UV-C individually or simultaneously to the emission image 212 of the anti-counterfeit medium 200 while adjusting the respective irradiation intensities. Therefore, UV-A and UV-C can be simultaneously irradiated with an intensity suitable for visual recognition of the pattern in the pattern region 220. Therefore, it is possible to easily and quickly determine whether or not the light emission image 212 is normal with the naked eye.

  The first fluorescent ink 213 uses a fluorescent medium DE-RB, and the second fluorescent ink 214 uses a fluorescent medium DE-RB1 (manufactured by Nemoto Special Chemical Co., Ltd.) whose emission wavelength difference from the phosphor DE-RB is 5 nm or less. May be. In this case, during UV-A irradiation, the pattern area 220 and the background area 225 are visually recognized as the same color (blue), and the pattern of the pattern area 220 does not appear. During UV-C irradiation, the pattern area 220 and the background area 225 are visually recognized as the same color (red), and the pattern of the pattern area 220 does not appear. During simultaneous irradiation with UV-A and UV-C, the pattern area 220 and the background area 225 are visually recognized as different magenta areas, and the pattern of the pattern area 220 is visually recognized.

  The fluorescent medium DE-BG is used for the first fluorescent ink 213, and the fluorescent medium DE-BG1 (manufactured by Nemoto Special Chemical) whose emission wavelength difference from the phosphor DE-BG is 5 nm or less is used for the second fluorescent ink 214. May be. In this case, during UV-A irradiation, the pattern area 220 and the background area 225 are visually recognized as the same color (green), and the pattern of the pattern area 220 does not appear. During UV-C irradiation, the pattern area 220 and the background area 225 are visually recognized as the same color (blue), and the pattern of the pattern area 220 does not appear. During simultaneous irradiation with UV-A and UV-C, the pattern area 220 and the background area 225 are visually recognized as different cyan areas, and the pattern of the pattern area 220 is visually recognized.

Third Modification Example of Anti-Counterfeit Medium 200 When UV-A is irradiated and when UV-C is irradiated, the pattern of the pattern region 220 is visually recognized, and the pattern region 220 is simultaneously irradiated with UV-A and UV-C. It is also possible to make the pattern disappear (not visually recognized).

  For example, the anti-counterfeit medium 200 is formed using the phosphor DE-RG described above for the first fluorescent ink 213 and the phosphor DE-GR described above for the second fluorescent ink 214. Such an anti-counterfeit medium 200 is visually recognized as white as a whole under visible light, and the pattern of the pattern region 220 does not appear.

  When the ultraviolet irradiation device 100 irradiates only the UV-A to the forgery prevention medium 200, the first fluorescent ink 213 (phosphor DE-RG) forming the pattern region 220 emits green light. On the other hand, the second fluorescent ink 214 (phosphor DE-GR) forming the background region 225 emits red light. Therefore, the pattern area 220 and the background area 225 are visually recognized as areas of different colors. Therefore, at the time of UV-A irradiation, the pattern of the pattern area 220 of the light emission image 212 is visually recognized.

  When the ultraviolet irradiation device 100 irradiates only UV-C to the anti-counterfeit medium 200, the first fluorescent ink 213 (phosphor DE-RG) forming the pattern region 220 emits red light. On the other hand, the second fluorescent ink 214 (phosphor DE-GR) forming the background region 225 emits green light. Therefore, the pattern area 220 and the background area 225 are visually recognized as areas of different colors. Therefore, at the time of UV-C irradiation, the pattern of the pattern area 220 of the light emission image 212 is visually recognized.

  When the ultraviolet irradiation device 100 simultaneously irradiates UV-A and UV-C to the forgery prevention medium 200, the first fluorescent ink 213 (phosphor DE-RG) forming the pattern region 220 emits yellow light. . On the other hand, the second fluorescent ink 214 (phosphor DE-GR) that forms the background region 225 also emits yellow light. Therefore, the pattern area 220 and the background area 225 are visually recognized as the same color area. Therefore, the pattern of the pattern area 220 of the light emission image 212 does not appear at the time of simultaneous irradiation with UV-A and UV-C.

  As described above, the emission image 212 changes in each of the three irradiation patterns at the time of UV-A irradiation, UV-C irradiation, and simultaneous irradiation of UV-A and UV-C. By preventing the pattern of the pattern area 220 from appearing at the time of simultaneous irradiation, forgery of the forgery prevention medium 200 can be made more difficult.

  Moreover, the ultraviolet irradiation device 100 can irradiate UV-A and UV-C individually or simultaneously to the emission image 212 of the anti-counterfeit medium 200 while adjusting the respective irradiation intensities. Therefore, UV-A and UV-C can be simultaneously irradiated with an intensity suitable for disappearance of the pattern in the pattern region 220. Therefore, it is possible to easily and quickly determine whether or not the light emission image 212 is normal with the naked eye.

  The fluorescent medium DE-RB may be used for the first fluorescent ink 213, and the fluorescent medium DE-BR may be used for the second fluorescent ink 214. In this case, during UV-A irradiation, the first fluorescent ink 213 (phosphor DE-RB) that forms the pattern region 220 emits blue light, and the second fluorescent ink 214 (phosphor DE that forms the background region 225). -BR) emits red light. Therefore, the pattern area 220 and the background area 225 are visually recognized as areas of different colors, and the pattern of the pattern area 220 of the luminescent image 212 is visually recognized. During UV-C irradiation, the first fluorescent ink 213 (phosphor DE-RB) forming the pattern area 220 emits red light and the second fluorescent ink 214 (phosphor DE-BR) forming the background area 225 is emitted. Emits blue light. Therefore, the pattern area 220 and the background area 225 are visually recognized as areas of different colors, and the pattern of the pattern area 220 of the luminescent image 212 is visually recognized. At the time of simultaneous UV-A and UV-C irradiation, the pattern area 220 and the background area 225 are both visually recognized as magenta color areas, and the pattern of the pattern area 220 does not appear.

  The fluorescent medium DE-BG may be used for the first fluorescent ink 213, and the fluorescent medium DE-GB may be used for the second fluorescent ink 214. In this case, during UV-A irradiation, the first fluorescent ink 213 (phosphor DE-BG) that forms the pattern area 220 emits green light, and the second fluorescent ink 214 (phosphor DE that forms the background area 225). -GB) emits blue light. Therefore, the pattern area 220 and the background area 225 are visually recognized as areas of different colors, and the pattern of the pattern area 220 of the luminescent image 212 is visually recognized. During UV-C irradiation, the first fluorescent ink 213 (phosphor DE-BG) forming the pattern area 220 emits blue light and the second fluorescent ink 214 (phosphor DE-GB) forming the background area 225. Emits green light. Therefore, the pattern area 220 and the background area 225 are visually recognized as areas of different colors, and the pattern of the pattern area 220 of the luminescent image 212 is visually recognized. During simultaneous irradiation with UV-A and UV-C, the pattern area 220 and the background area 225 are both visually recognized as the same color area of cyan, and the pattern of the pattern area 220 does not appear.

  Further, when the phosphor DE-RG is used for the first fluorescent ink 213 and the phosphor DE-GR is used for the second fluorescent ink 214, the yellow ink is offset printed on the base material 211, and the first ink is printed on the second fluorescent ink 214. The first fluorescent ink 213 and the second fluorescent ink 214 may be offset printed. Similarly, when the fluorescent medium DE-RB is used for the first fluorescent ink 213 and the fluorescent medium DE-BR is used for the second fluorescent ink 214, magenta ink is offset printed on the substrate 211, Alternatively, the first fluorescent ink 213 and the second fluorescent ink 214 may be offset printed. Similarly, when the fluorescent medium DE-BG is used for the first fluorescent ink 213 and the fluorescent medium DE-GB is used for the second fluorescent ink 214, the cyan ink is offset printed on the substrate 211, The first fluorescent ink 213 and the second fluorescent ink 214 may be offset printed thereon. By doing in this way, the whole light emission image 212 becomes easy to be visually recognized as a single color image at the time of simultaneous irradiation of UV-A and UV-C.

Other Modifications In the above embodiment, the ultraviolet irradiation device 100 is provided with the louver-type first shutter 113 and the second shutter 123 as shown in FIGS. 2 to 4, but the first shutter 113 and The second shutter 123 only needs to be capable of adjusting the aperture ratio, and may be, for example, a diaphragm type or a slide type.

In the above embodiment, the control unit 130 of the ultraviolet irradiation device 100 controls the irradiation intensity of UV-A and UV-C by adjusting the aperture ratios of the first shutter 113 and the second shutter 123. The UV-A and UV-C irradiation intensities are controlled by adjusting the applied voltages to the first lamp 112 and the second lamp 122, not the aperture ratios of the first shutter 113 and the second shutter 123. Also good. By increasing the voltage applied to the first lamp 112 and the second lamp 122, the irradiation intensity can be increased. For example, by adjusting the applied voltage, the irradiation intensity of the first lamp 112 on the irradiation surface 70 mm away from the ultraviolet irradiation apparatus 100 can be adjusted in the range of 0 to 1200 μW / cm ² , and the irradiation intensity of the second lamp 122 can be adjusted. It can be adjusted within a range of 0 to 1350 μW / cm ² . In this case, the first shutter 113 and the second shutter 123 may not be provided.

  Moreover, in the said embodiment, although the ink which has the excitation characteristic with respect to UV-A or UV-C was used as the 1st fluorescent ink 213 and the 2nd fluorescent ink 214, the 1st fluorescent ink 213 or the 2nd fluorescent ink 214 is used. On the other hand, an ink having excitation characteristics with respect to ultraviolet rays (UV-B) having a wavelength of 280 nm to 315 nm can also be used. The ultraviolet irradiation apparatus 100 is an apparatus that irradiates ultraviolet rays corresponding to the excitation characteristics of the ink used to form the light emission image 212. Therefore, when an ink having an excitation characteristic with respect to UV-B is used to form the luminescent image 212, a metal halide UV lamp that irradiates UV-B or the like is used for the first lamp 112 or the second lamp 122.

  Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. In addition, various inventions can be formed by appropriately combining a plurality of components disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined.

DESCRIPTION OF SYMBOLS 1 Inspection system 100 Ultraviolet irradiation device 101 Case 111 1st opening 112 1st lamp 113 1st shutter 121 2nd opening 122 2nd lamp 123 2nd shutter 130 Control part 131,132 Counterfeit prevention medium 211 Forgery prevention medium 211 Base material 212 Luminous image 213 First fluorescent ink 214 Second fluorescent ink 215a First boundary line 215b Second boundary line 220 Picture area 221a White part 221b Blue part 221c Red part 222b Blue part 222c Green part 225 Background area 226a White part 226b Blue part 226c Green part

Claims (10)

A housing having a first opening and a second opening;
A first lamp disposed in the housing and irradiating ultraviolet light in a first wavelength region through the first opening;
A second lamp that is disposed in the housing and irradiates ultraviolet rays in a second wavelength region through the second opening;
A control unit for controlling the ultraviolet irradiation intensity from the first lamp through the first opening and the ultraviolet irradiation intensity from the second lamp through the second opening;
An ultraviolet irradiation device comprising:   A first shutter having a variable aperture ratio is provided in the first opening, a second shutter having a variable aperture ratio is provided in the second opening, and the control unit has an aperture ratio of the first shutter. The ultraviolet irradiation device according to claim 1, wherein an aperture ratio of the second shutter is controlled.   The ultraviolet irradiation device according to claim 1, wherein the control unit controls an applied voltage to the first lamp and an applied voltage to the second lamp. An inspection system comprising the ultraviolet irradiation device according to claim 1 and a light emitting medium,
The luminescent medium is
A substrate;
A luminescent image on the substrate;
Have
The emission image is
A first region containing a first phosphor;
A second region containing a second phosphor;
Have
At least a portion of the second region is adjacent to the first region;
When the first lamp is irradiated with ultraviolet rays in the first wavelength region, the first phosphor and the second phosphor emit light of a color that is visually recognized as the same color, and the second lamp The inspection system, wherein when irradiated with ultraviolet rays in the second wavelength region, the first region and the second region are visually recognized as regions of different colors. When the first lamp is irradiated with ultraviolet rays in the first wavelength region, the first phosphor emits light of the first color, and the second phosphor emits the first color or the first color. It emits light of the color that is visible as the same color,
When the second lamp is irradiated with ultraviolet rays in the second wavelength region, the first phosphor emits light of the second color, and the second phosphor emits light of the third color. Alternatively, the inspection system according to claim 4, wherein the first region and the second region are visually recognized as different color regions without emitting light. When the first lamp is irradiated with ultraviolet rays in the first wavelength region, the first phosphor emits light of the first color, and the second phosphor emits the first color or the first color. It emits light of the color that is visible as the same color,
When the second lamp is irradiated with ultraviolet rays in the second wavelength region, the first phosphor emits light of a color that is visually recognized as the first color or the same color as the first color, and the second fluorescence. The body emits light of a third color or emits no light, and the first region and the second region are visually recognized as regions of different colors. Inspection system. An inspection system comprising the ultraviolet irradiation device according to claim 1 and a light emitting medium,
The luminescent medium is
A substrate;
A luminescent image on the substrate;
Have
The emission image is
A first region containing a first phosphor;
A second region containing a second phosphor;
Have
At least a portion of the second region is adjacent to the first region;
The first phosphor and the second phosphor when irradiated with ultraviolet rays in the first wavelength region by the first lamp, or when irradiated with ultraviolet rays in the second wavelength region by the second lamp. The phosphor emits light of a color visually recognized as the same color, and is irradiated with ultraviolet rays in the first wavelength region and ultraviolet rays in the second wavelength region simultaneously by the first lamp and the second lamp. The inspection system is characterized in that the first phosphor and the second phosphor emit light of a color visually recognized as different colors. When the first lamp is irradiated with ultraviolet rays in the first wavelength region, the first phosphor emits light of the first color, and the second phosphor emits the first color or the first color. It emits light of the color that is visible as the same color,
When the second lamp is irradiated with ultraviolet rays in the second wavelength region, the first phosphor emits light of a second color, and the second phosphor has a second color or a second color. The inspection system according to claim 7, wherein the inspection system emits light of a color visually recognized as the same color.   A color difference between the color of light emitted from the first phosphor and the color of light emitted from the second phosphor when irradiated with ultraviolet rays in the first wavelength region is 10 or less. The inspection system according to claim 4, wherein: An inspection system comprising the ultraviolet irradiation device according to claim 1 and a light emitting medium,
The luminescent medium is
A substrate;
A luminescent image on the substrate;
Have
The emission image is
A first region containing a first phosphor;
A second region containing a second phosphor;
Have
At least a portion of the second region is adjacent to the first region;
The first phosphor and the second phosphor when irradiated with ultraviolet rays in the first wavelength region by the first lamp and when irradiated with ultraviolet rays in the second wavelength region by the second lamp; The phosphor emits light of a color visually recognized as different from each other, and is irradiated with ultraviolet rays in the first wavelength region and ultraviolet rays in the second wavelength region simultaneously by the first lamp and the second lamp. The inspection system is characterized in that the first phosphor and the second phosphor emit light of a color visually recognized as the same color.

Images