JP5360725B2 - Latent image printed matter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a specific image configuration in which an image observable under normal visible light is changed to a completely different image when the image is observed under a specific condition and a latent image printed matter which can be formed by the specific image configuration, in the field of precious printed matters such as bank notes, passports, securities, identification, cards and traffic tickets which are security printed matters requiring forgery preventing effects. <P>SOLUTION: In the latent image printed matter, images are formed by complicatedly combining image elements having different area ratios. The respective image elements are observed to have the same color under diffusely-reflected light and observed not to have the same color under a specific condition. Thus, the latent image printed matter has a so-called change effect, in which a first image is visually recognized under diffusely-reflected light and the visually-recognized image is changed to a second image which is a different image having no correlation with the first image when observed under a specific condition different from diffusely-reflected light. <P>COPYRIGHT: (C)2012,JPO&amp;INPIT

Description

  INDUSTRIAL APPLICABILITY The present invention can be observed under ordinary visible light in the field of valuable printed matter such as banknotes, passports, securities, identification cards, cards, and passports, which are security printed matters that require an anti-counterfeit effect. The present invention relates to a special image configuration in which an image changes to a completely different image when observed under specific conditions, and a latent image printed material that can be formed thereby.

  Recent advances in digital equipment such as scanners, printers, and color copiers have made it possible to easily produce elaborate copies of valuable prints. Therefore, in order to prevent duplication and forgery as described above, various anti-counterfeiting techniques that are not reproducible by simple copying, such as squeezing, are required. Among such anti-counterfeiting technologies is a technology consisting of a combination of complex pixel configuration and image line configuration and various functional inks with special functions, and visible images that are normally observed under light In other words, there is a technique having a so-called image change effect in which the latent image observed under a specific condition is a different image having no correlation.

  The present applicant uses two inks as a pair ink that are observed in the same color under diffuse reflected light but are observed in different colors under regular reflected light, and are configured by a special halftone dot configuration. The printed image is an image that is viewed by observing under diffuse reflected light and an image that is viewed by observing under specular reflected light, which is a different image having no correlation at all. There has already been filed an invention relating to a latent image printed matter characterized by having (see, for example, Patent Document 1).

  In addition, the present applicant, when printed on a base material, is observed as a uniform color under reflected light, but uses two inks having different transmittances as a pair ink, and an image with a special halftone dot configuration. A latent image characterized by having a change effect, wherein an image that can be observed under reflected light and an image that can be observed under transmitted light are different images having no correlation at all. An invention relating to an image printed matter has already been filed (for example, see Patent Document 2).

Japanese Patent Application No. 2009-267329 Japanese Patent Application No. 2010-008034

  However, regarding the techniques described in Patent Document 1 and Patent Document 2, a visible image observed under visible light (more specifically, meaningful information included in the visible image, There is a problem that the visibility of either one of the information portion) or the latent image (second information portion in the present invention) appearing under specular reflection light or transmitted light is low.

  The cause of this problem is as follows. For example, when forming a latent image print described in Patent Document 2, a watermark ink and a normal ink paired with the watermark ink are used, but the watermark ink and the normal ink must be the same color. In general, watermark inks lose their effect as "watermarks" that transmit light when they are finished in dark colors, so basically they are often light colors. Must be pale. One visible image (in the description in the specification of Patent Document 2 is an information element group) is formed with normal ink. However, as described above, normal ink has to be a pale color, A large contrast cannot be obtained, and as a result, the visibility of the visible image is lowered.

  Further, in order to increase the visibility of the visible image, it is necessary to increase the pixel area ratio and the image area ratio for forming the visible image. In that case, on the contrary, the latent image (in the specification of Patent Document 2) In the description, the pixel area ratio and the image area ratio forming the second printing element) must be reduced. In this case, the visibility of the latent image is lowered. As described above, there has been a problem that visibility of either a visible image or a latent image is lowered.

  In addition, for precious printed matter that requires anti-counterfeiting effects, as in the past, there is a demand for manufacturing with a highly productive printing method, and at the same time, there is a technology that makes it difficult to make a duplicate using the latest digital equipment. It has been demanded.

  The present invention is intended to solve the above-described problems, and is a latent image printed matter that forms an image by combining image elements having different area ratios in a complicated manner, and each image element is under diffuse reflected light, Because it is observed as a uniform color and is observed as an unequal color by changing the color of any image element under certain conditions, the first image is viewed under diffuse reflection and diffuse reflection When observed under specific conditions different from under light, the printed matter has a so-called change effect that changes to a second image, which is a different image that has no correlation with the first image. The present invention relates to a printed matter that can maintain high visibility of both an image (more specifically, a first information portion) and a second image (more specifically, a second information portion).

  The latent image printed material of the present invention is formed by forming a printed image on at least a part of a substrate with a first ink and a second ink having colors different from those of the substrate, and the printed image is a first image. And the second image, the first image and the second image are arranged such that the first image element, the second image element, the third image element and the fourth image element do not overlap each other. The first image element is formed by the first ink at the first area ratio, and the second image element is formed by the second ink at the second area ratio. The third image element is formed by the second ink at the third area ratio, and the fourth image element is formed by the first ink at the first area ratio, and the second image element is formed by the second ink. The first image is formed by superimposing the fourth information on the first information portion. A first background portion, the second image has a second information portion and a second background portion, the first background portion in the first image is the first image element and the second The first information part in the first image consists of a third image element and a fourth image element, and the second information part in the second image consists of the first image element and The second background portion in the second image is composed of the fourth image element, the second image element is composed of the second image element and the third image element, the first area ratio is larger than the second area ratio, The third area ratio is equal to or greater than the fourth area ratio, and the first ink and the second ink have the same hue, and the first ink has a lower density than the second ink, and the first ink And / or the second ink, when observed under diffuse reflected light and when observed under specific conditions different from those under diffuse reflected light. When the colors have different functionalities and are observed under diffuse reflected light, the first image element, the second image element, the third image element, and the fourth image element have different reflection densities. When one image is visually recognized and observed under specific conditions different from those under diffuse reflected light, the second image is visually recognized depending on the presence or absence of functionality in the first ink and the second ink. It is characterized by that.

  In the latent image printed material according to the present invention, the first area ratio is 100%, the second area ratio is 40% to 67%, and the third area ratio is 50% to 90%. Features.

  The latent image printed material according to the present invention is characterized in that the difference between the second area ratio and the third area ratio is 10% or more and 50% or less.

  The latent image printed matter according to the invention is characterized in that the fourth area ratio is 50% or less.

  Moreover, the latent image printed matter according to the present invention is characterized in that the density difference between the first ink and the second ink is 1.5 to 5 times.

  In the latent image printed material according to the present invention, the second image element and / or the third image element is at least one of an image line and a pixel, or a combination thereof.

  In addition, observation under specific conditions in the present invention includes observation under specular reflection light, observation under transmitted light, observation with irradiation of light in the ultraviolet wavelength band, observation with light in the infrared wavelength band, It is characterized by at least one condition selected from observation with light in a limited wavelength band in the visible light region or observation under a specific temperature.

  In the latent image printed matter of the present invention, both the first image observed under diffuse reflected light and the second image observed only under a specific environment are highly visible compared to the conventional similar technique. Have sex.

  In addition, since the latent image printed matter of the present invention can be manufactured by offset printing, which is a highly productive printing method, it has excellent cost performance and realizes a change effect even if the latest digital equipment is used. Since it is impossible to do so, it has an excellent anti-counterfeit effect. Moreover, since both the first image and the second image are excellent in visibility, authenticity determination between a genuine product and a counterfeit product becomes easier, and the authenticity determination property is also excellent.

The latent image printed matter in this invention is shown. The image contained in the latent image printed material of this invention is shown, (a) shows one image, (b) shows a 2nd image. The image elements which comprise the latent image printed matter of this invention are shown, (a) is a 1st image element, (b) is a 2nd image element, (c) is a 3rd image element, (d ) Indicates a fourth image element. The structure of the 1st image in the latent image printed matter of this invention is shown, (a) is each image element which comprises a 1st information part, (b) is each image element which comprises a 1st background part. Show. The structure of the 2nd image in the latent image printed matter of this invention is shown, (a) is each image element which comprises a 2nd information part, (b) is each image element which comprises a 2nd background part. Show. The plate surface structure in the latent image printed matter of this invention is shown, (a) shows the image formed with a 1st ink, (b) shows the image formed with a 2nd ink. (A) shows an image that is visually recognized when the observer sees the latent image print under diffuse reflection light, and (b) is an image that is visible when the observer sees the latent image print under regular reflection light. The image to be displayed is shown. (A) shows an image that is visually recognized when the observer sees the latent image print under diffuse reflected light, and (b) is an image that is visible when the observer sees the latent image print under transmitted light. An image is shown. (A) shows an image that is visually recognized when the observer sees the latent image print under diffuse reflected light, and (b) is an image that is visible when the observer sees the latent image print through a filter or an IR viewer. The image to be displayed is shown. The latent image printed matter in Example 2 is shown. The image contained in the latent image printed matter in Example 2 is shown, (a) shows a 1st image, (b) shows a 2nd image. Each image element which comprises the latent image printed matter in Example 2 is shown, (a) is a 1st image element, (b) is a 2nd image element, (c) is a 3rd image element, ( d) shows a fourth image element. 2 shows a configuration of a first image element in Embodiment 2. The structure of the 2nd image element in Example 2 is shown. 8 shows a configuration of a third image element in Embodiment 2. 4 shows a configuration of a fourth image element in Embodiment 2. FIG. 6 shows a partially enlarged view of the configuration of a print image in Embodiment 2. The plate | board surface structure in the latent image printed matter of Example 2 is shown, (a) shows the image formed with a 1st ink, (b) shows the image formed with a 2nd ink. (A) shows an image that is visually recognized when the observer sees the latent image print under diffuse reflected light, and (b) is an image that is visible when the observer sees the latent image print under transmitted light. An image is shown.

  DESCRIPTION OF EMBODIMENTS Embodiments for carrying out the present invention will be described with reference to the drawings. However, the present invention is not limited to the embodiments described below, and includes various other embodiments within the scope of the technical idea described in the scope of claims.

  FIG. 1 shows a latent image printed material (1) according to the present invention. The latent image printed matter (1) is formed by forming a printed image (3) having a color different from that of the substrate on at least a part of the substrate (2). For convenience of explanation, the cherry blossom pattern included in the second image (5) in the printed image (3) is represented by a white line, but the cherry blossom pattern is actually invisible.

  FIG. 2 shows the configuration of the print image (3). The print image (3) is composed of a first image (4) shown in FIG. 2 (a) and a second image (5) shown in FIG. 2 (b). The first image (4) includes a first information part (6) composed of meaningful information such as letters, numbers or symbols, and a first background part (7) surrounding the first information part (6). ), And the second image (5) includes a second information part (8) consisting of meaningful information such as letters, numbers or symbols, and a second information part (8) surrounding the second information part (8). It consists of a background part (9).

  Next, the print image (3) will be described with respect to four image elements necessary for constituting the first image (4) and the second image (5).

  FIG. 3 shows four image elements constituting the print image (3). FIG. 3A shows the first image element (10-1), and FIG. 3B shows the second image element (10-2). ) Shows the third image element (10-3), and FIG. 3D shows the fourth image element (10-4).

  Each image element is formed with a specific area ratio by the first ink or the second ink. The first ink and the second ink have the same hue, but are a pair of inks having different densities, and the first ink needs to have a lighter density than the second ink. The “hue” in the present invention is a color aspect such as red, blue, and yellow, and specifically indicates the intensity distribution of a specific wavelength in the visible light region (400 to 700 nm). The term “same hue” as used in the present invention means that the colors of red, blue, and yellow are the same in the two colors. More specifically, the distribution of the intensity of the wavelength in the visible light region is the two colors. In which there is a correlation.

  Each image element will be described. The first image element (10-1) is formed by the first ink at the first area ratio. The second image element (10-2) is formed by the second ink at a second area ratio. The third image element (10-3) is formed by the second ink at a third area ratio. The fourth image element (10-4) is composed of two types of ink, and is formed with the first ink by the first area ratio, and is superimposed by the second ink at the fourth area ratio. It consists of

  FIG. 4 shows combinations of image elements for forming the first image (4). As shown to Fig.4 (a), the 3rd image element (10-3) and the 4th image element (10-4) are combined, and the 1st information part (1) in a 1st image (4) ( 6) is formed, and the first image element (10-1) and the second image element (10-2) are combined in the first image (4) as shown in FIG. A first background portion (7) is formed.

  On the other hand, FIG. 5 shows combinations of image elements for forming the second image (5). As shown to Fig.5 (a), the 2nd information part (2) in a 2nd image (5) (4) is combined by combining a 1st image element (10-1) and a 4th image element (10-4). 8) is formed, and the second image element (10-2) and the third image element (10-3) are combined in the second image (5) as shown in FIG. A second background portion (9) is formed. The above is the description of the four image elements necessary for including the first image (4) and the second image (5) in the print image (3).

  If there is a region where each image element overlaps, unnecessary shading is generated in the region, and therefore, a region where each image element overlaps is basically not provided. However, it is within the scope of the technical idea of the present technology to provide a slight overlap portion only at the contour portion of each image element for the purpose of providing redundancy in printing printing.

  In the present invention, in observation under diffuse reflected light, the first image element (10-1) and the second image element (10-2) are observed as the same color, and the third image element (10-3) is observed. ) And the fourth image element (10-4) must be designed so that the colors of the image elements are observed as the same color.

  From this, in order to achieve the effect of the present invention, the relationship between the first area ratio, the second area ratio, the third area ratio, and the fourth area ratio is very important. Then, next, the relationship of each area ratio is demonstrated.

  Note that “under regular reflection light” in the present invention to be described later means that the angle of light incident on the printed material from the light source is substantially equal to the angle of light reflected on the printed material, for example, the incident angle from the light source to the latent image printed material. When light is incident at −45 °, it is a region where strong reflected light is generated in a region near a light receiving angle of 45 °, and “observation under regular reflected light” in the present invention means that the viewpoint of the observer is The figure shows a situation where the printed matter is observed in the region where the above-mentioned regular reflection light is generated. This region where a large amount of specular reflection light exists is centered on an angle equal to the incident light, but the angle range varies depending on the substrate used and the pair ink used.

  In addition, “under diffuse reflection” means a region other than the region under specular reflection described above, and is a specular reflection light in which the angle of light incident on the printed matter from the light source and the angle of light reflected from the printed matter are greatly different. Is a region where there is almost no existence. “Observation under diffusely reflected light” in the present invention indicates a situation in which the observer's viewpoint is in an area where there is almost no specularly reflected light and the printed matter is observed.

Further, the “equal color” in the present invention is a relationship that allows an observer to recognize two colors as the same color in the two colors. A specific range is 3 or less in color difference ΔE in CIE L ^* a ^* b ^* . Further, the “color” in the present invention represents a color including the concepts of hue, saturation and lightness.

  Further, the area ratio in the present invention is a ratio of the printing halftone dot in a certain area, and is not limited to a so-called filled form in which uniform printing halftone dots are arranged in a certain area. Forms in which print dots are continuously arranged without any gaps in a certain direction, and images with a specific area ratio are formed by repeating image lines and non-image areas by arranging image lines at regular intervals. It is possible to express a specific area ratio in the same manner as an image line using pixels or the like that are aggregated. The image line may be a dotted line, a broken line, a straight line, a curve, or a wavy line, and any image line shape is included in the technical idea of the present invention. Similarly, the pixel may be circular, polygonal, star-shaped, etc., and includes other special characters and symbols.

  In the embodiment for carrying out the present invention, a description has been given in the form of a fill in which printing halftone dots are evenly arranged in a certain area. However, in Example 2 to be described later, an image line is partially used. Thus, a mode for expressing a specific area ratio is described.

  In addition to the image line, the second image element (10-2) and the third image element (10-3) may be formed of at least one pixel or a combination of each. With each combination, for example, the second image element (10-2) is formed with an image line, and the third image element (10-3) is formed with a pixel. Further, a combination of forming each of the second image elements (10-2) as an image line or a pixel may be used.

  In general, since the density of an image under diffuse reflection is determined by the area ratio, if the ink used is the same color, it may be formed with the same area ratio in order to make different images the same color. . However, in the present invention, the first image element (10-1) is formed of the first ink, and the second image element (10-2) is formed of the second ink that is darker than the first ink. Therefore, it is necessary to design the first area ratio to be larger than the second area ratio.

  That is, the first area ratio and the second area ratio are determined by the density difference between the first ink and the second ink. The density difference in the present invention is a difference in density value when each printed portion is measured with a color densitometer when the first ink and the second ink are printed at the same area ratio. .

  The first area ratio is basically 100%. This is to increase the visibility of the second image that appears under specific conditions as much as possible. Since the visibility of the second image is strongly influenced by the size of the first area ratio, the second image is formed at a maximum area ratio of 100% as long as there is no problem in printability.

  From this, for example, when the second ink has twice the density of the first ink, the first area ratio is 100%, so the second area ratio is 50%, and the second ink Has a density four times that of the first ink, the first area ratio is 100%, so the second area ratio is 25%.

  In the present invention, observation under specific conditions means observation under specular reflection light, observation under transmitted light, observation with irradiation of light in the ultraviolet wavelength band, observation with light in the infrared wavelength band, visible The observation is performed under at least one condition selected from observation with light in a limited wavelength band in the optical region or observation under a specific temperature.

  Further, when the second ink has a density difference of 1.5 to 2.5 times with respect to the first ink, if the first area ratio is 100%, the second area ratio is 40%. It is set within the range of 67% to 67%. In this case, in order to determine the second area ratio, six patterns (for example, 40%, 45%, 50%, 55) in which the second area ratio is cut into 5% within the range of 40% to 67%. %, 60%, 65%) in advance. The area ratio at which the first ink and the second ink are most visually recognized as the same color is defined as the second area ratio.

  In addition, the third image element (10-3) and the fourth image element (10-4) need to be formed in the same color, but the third image element (10-3) is only the second ink. The fourth image element (10-4) is formed by superimposing the first ink and the second ink. Therefore, the fourth area ratio does not exceed the third area ratio.

  In other words, the fourth area ratio depends not only on the density difference between the two inks used, but also on the trapping state when the second ink is overlaid on the first ink. The shade is different. Therefore, it is necessary to perform an overprinting of two inks in advance and adjust the area ratio to an appropriate one.

  The portion printed at the fourth area ratio in the fourth image element (10-4) is visually recognized as the first information portion (6) in the observation under diffuse reflection, and is observed under specific conditions. It must change to an almost invisible state. Therefore, when the first image element (10-1) is printed with the first ink at an area ratio of 100% and the fourth image element (10-4) is superimposed with the second ink, It is necessary to determine the fourth area ratio that can satisfy the conditions shown in FIG.

  The specific condition for determining the fourth area ratio is that the first image element (in addition to being visually recognized as the same color as the third image element (10-3) in observation under diffuse reflected light) 10-1) and the second image element (10-2) are formed in different shades and produce a certain visible contrast, and in addition, in observation under specific conditions, It is visually recognized as substantially the same color as the one image element (10-1), and is different from the second image element (10-2) and the third image element (1-3), and is visible. This is the area ratio at which a constant contrast occurs. Since the appropriate value of the area ratio is completely different depending on the ink, it is necessary to perform a test in advance according to the ink to be used.

  Under diffuse reflection, the first image element (10-1) and the second image element (10-2) have the same color and the first background portion (7) in the first image (4). The third image element (10-3) and the fourth image element (10-4) become the same color and form the first information part (6) in the first image (4). As described above, the first information portion (6) and the first background portion (7) need to have a certain density difference and should not be the same color.

  Which area ratio is larger depending on whether the first image (4) is expressed as a positive image (the information part is darker than the background part) or as a negative image (the information part is brighter than the background part). Although the design is different, at least the second area ratio and the third area ratio should not be the same, and considering the visibility of the first information section (6), at least about 10% The difference is necessary.

  In addition, when the difference between the second area ratio and the third area ratio is too large, the second information (5) that appears in the observation under a specific condition is displayed on the first information section (6). This causes a problem that a mixed image appears and a mixed image appears. Therefore, it is necessary to limit the difference to 50% or less. For the same reason, it is necessary to limit the fourth area ratio to 50% or less.

  In FIG. 6, when forming latent image printed matter (1) by printing, the design on the printing plate printed using 1st ink and 2nd ink is shown. FIG. 6A is a pattern printed using the first ink, and the first image element (10-1) and the fourth image element (10-4), which are the second information part (8). ). Moreover, FIG.6 (b) is a pattern (11) printed using a 2nd ink, and removes only the 1st image element (10-1) from the printed image (3), and the 2nd It is composed of an image element (10-2), a third image element (10-3), and a fourth image element (10-4).

  First, using the first ink, considering the area ratio described above, after printing the design shown in FIG. 6A, using the second ink, also considering the area ratio described above. The latent image printed material (1) can be formed by printing with the design shown in FIG.

  About the effect of this invention, a typical example is introduced according to the characteristic of the pair ink used.

  FIG. 7 shows an example in which the latent image print (1) is formed using a normal light gray matte ink as the first ink and a dark silver ink as the second ink. The first image (4) is visually recognized in the observation under diffuse reflection, which is in a positional relationship such as the latent image print (1), the light source (12), and the observer (13a) shown in FIG. Is done. At this observation angle, the second image (5) is completely invisible.

  This is because the first image element (10-1) and the second image element (10-2) are in the same color relationship under diffuse reflection light, and the third image element (10-3) and the fourth image element (10-2) are in the same color relationship. Since the image element (10-4) is similarly color-matched under diffuse reflected light, the second image (5) is completely hidden and the first background portion (7) is visually observed. Recognized as a flat single tone. And since the 1st information part (6) is formed in the area ratio higher in that, the difference (shading) of the reflection density by the difference in area ratio is born, the character of "Japan", the background, The first image (4) is visually recognized by forming a certain contrast between the first and second images.

  The difference in reflection density in the present invention is the darkness of an image, and when light is projected onto an image printed on a substrate, it is the amount of light reflected with respect to the amount of light projected.

  On the other hand, in the observation under specular reflection light, which is in a positional relationship such as the latent image printed matter (1), the light source (12), and the observer (13b) shown in FIG. Only visible.

  This is because the second image element (10-2), the third image element (10-3) and the fourth image element (10-4) formed with the second ink containing silver ink are By reflecting light strongly, it changes to a pale color, making it difficult to grasp the difference in area ratio between each image element. In particular, the second image element (10-2) and the third image element (10-3) are visually recognized as flat and single gradation. At the same time, the first image element (10-1) formed with the first ink does not reflect light strongly, and is observed in the same color as when observed under diffuse reflected light. The image element (10-4) changes to a pale color and is observed in the same color as the first image element (10-1). Therefore, with respect to the second image element (10-2) and the third image element (10-3), the first image element (10-1) and the fourth image element (10-4) are: It will be visually recognized as a dark color.

  As described above, in the observation under specular reflection light, the difference in ink is emphasized rather than the difference in area ratio, thereby generating a strong contrast between light and shade, and the first image element (10-1) and the fourth. Image element (10-4) is emphasized, and as a result, the second image (5) is visually recognized. A specific configuration of the latent image printed material (1) shown in FIG. 7 will be described in Example 1 to be described later.

  FIG. 8 shows an example in which the latent image print (1) is formed using a light gray transparent ink for the first ink and a normal dark gray ink for the second ink. In the observation under diffuse reflected light such as the latent image printed matter (1), the light source (12), and the observer (13c) shown in FIG. 8A, the first image (4) The characters "Japan" that make up are visible. At this observation angle, the second image (5) is completely invisible.

  On the other hand, in the observation under transmitted light in the positional relationship such as the latent image printed material (1), the light source (12), and the observer (13d) shown in FIG. 8B, the second image (5) is displayed. A gray-inverted image is visually recognized. The specific configuration of this example will be described in Example 2 described later.

  Moreover, the base material used in the present invention is not particularly limited, but only when a transmissive ink is used, a base material that does not block light is used.

  FIG. 9 shows a light-colored metameric ink A that absorbs light of a specific wavelength in the first ink, and a dark-colored metameric ink B that transmits light of a specific wavelength in the second ink. This is an example in which a latent image print (1) is formed using The first image (4) is formed in the observation under the diffuse reflected light in the positional relationship such as the latent image print (1), the light source (12), and the observer (13e) shown in FIG. The letters “Japan” are visible. At this observation angle, the second image (5) is completely invisible.

  On the other hand, a filter that transmits only specific light, such as the latent image printed material (1), the light source (12), and the observer (13f) shown in FIG. When viewed through an IR viewer or the like, only the second image (5) is visible.

  Thus, in the latent image printed matter (1), in the observation under diffuse reflected light, the first image element (10-1) and the second image element (10-2) have the same color, and the third image element (10-2) Since the image element (10-3) and the fourth image element (10-4) are visually recognized in the same color, the first image (4) is visually recognized.

  In observation under specific conditions different from those under diffuse reflection, the first image element (10-1) and the fourth image element (10-4) are of the same color, and the second image element (10-4) Since the image element (10-2) and the third image element (10-3) are visually recognized in the same color, the second image (5) is visually recognized.

  Thus, in the latent image printed material (1) of the present invention, the first image (4) is visually recognized in the observation under the diffuse reflected light, and the second image (5) is visually recognized in the observation under the specific conditions. It has a so-called image change effect.

  As described above, the present invention has various variations depending on the characteristics of the pair ink used. Other functional materials that can be used as a pair ink include thermochromic ink, photochromic ink, pearl ink, liquid crystal ink, infrared absorbing ink, and luminescent ink. For example, when thermochromic ink is used, the effect of changing an image that was visible at a specific temperature to a completely different image at a different temperature can be obtained. When the image seen below is irradiated with strong light, the effect of changing to a completely different image can be obtained. Further, when pearl ink is used, it is possible to obtain an effect of changing an image that has been seen under diffuse reflection light to a completely different image under regular reflection light. Thus, latent image prints (1) with various effects can be formed depending on the characteristics of the functional material used as the pair ink.

  Next, the two most characteristic configurations and effects of the latent image printed material (1) of the present invention, which did not exist in other configurations, will be described. With these two configurations, an image change effect having higher visibility than that of the prior art is realized. One of the structures is the use of two different inks that form the printed image (3), not inks having the same color relationship but different densities, and the other is the superposition of the two inks. And having a superimposed region (fourth print image) formed. The effects of using this structure will be described below.

  In the case of forming a printed matter having a so-called change effect that changes to an image observed under a specific condition when an image observed under visible light using two types of ink is used, such as a latent image printed matter in the present invention, Using special pixel configurations such as Patent Document 1 and Patent Document 2, in addition, a pair of inks that are visually recognized in the same color under visible light and changed to an unequal color under specific conditions In general, a printed image is formed by using them. The reason for making the pair inks the same color is to conceal the second image under diffuse reflected light and make it invisible.

  When such a pair ink is used, since it is visually recognized as the same color only when printing with the same dot area ratio using each ink, for example, the first image element (10- The first area ratio for forming 1) and the second area ratio for forming the second print image (10-2) need to be designed with the same area ratio.

  However, the first image element (10-1) also has a role of causing the second image (5) to appear by causing contrast with the other three image elements in the observation under a specific condition. Since the visibility of the second image (5) in this case is affected by the size of the area ratio of the first image element (10-1), the first image element (10- It is desirable to set the area ratio of 1) as high as possible.

  However, if the area ratio of the first image element (10-1) increases, the area ratio of the second image element (10-2) also needs to be increased, and as a result, the first background portion (7) The overall area ratio increases. In this case, since the difference in area ratio between the first background part (7) and the paired first information part (6) becomes small, the first background part (7) The contrast of the first information part (6) becomes small, and the visibility of characters, symbols, etc. constituting the first information part (6) in the first image (4) decreases. .

  In addition, functional inks having special functionalities often have extremely low concentrations that can be formed by printing, or are limited in color. When such a functional ink is used, as a matter of course, the other ink in the pair is also limited to the same density and color.

  For example, the ink that forms a pair in the present invention is often the second ink, but when the second ink has a light density, the first background portion (7), as in the problem described above, Even if the difference in the area ratio of the first information portion (6) is increased, the difference in shading is not relatively increased as compared with the case where dark ink is used, and the information portion in the first image (4) ( It is difficult to improve the visibility of characters, symbols, etc. constituting 6).

  In order to avoid such a problem, in the present invention, inks having different densities are used as paired inks instead of inks having the same color relationship. For example, even if a functional ink that can only be printed at a light density is used as the first ink as in the prior art, the paired second ink is not the same color as the first ink. The design is darker than the first ink. This eliminates the need to form the second image element (10-2) with the same area ratio as the first image element (10-1) formed with the first ink, which has been a problem in the prior art. It was.

  Therefore, the first image element (10-1) is formed with a high area ratio, and the second background (5) appearing under specific conditions is kept highly visible while the first background portion ( 7) can be formed at a low concentration.

  Further, since the second ink has a high density, the first information portion (6) formed by the third image element (10-3) and the fourth image element (10-4) is formed deeply. can do. From the above, the first image element (10-1) can form the first image (4) with high visibility while being formed with a high area ratio. This is one of the reasons why the image change effect of the present invention is high.

  In addition, another effect of the present invention will be described, which is an effect generated by forming an overlapping region in which two inks are overlapped.

  When an overlapping region in which two inks overlap each other is formed, the color of the overlapping region (fourth image element (10-4) in the present invention) becomes darker and the non-overlapping region (third image in the present invention). It becomes difficult to make the same color as the element (10-3)).

  Therefore, conventionally, when forming a special printed matter having a second image using a pair of inks as in the present invention, emphasis is placed on the concealment of the second image, and halftone dots formed with different inks. There was almost no overlap. For this reason, if the image lines and pixels for expressing the first image and the second image are arranged so as not to overlap in the limited area of the print image, the first image is displayed. When expressed with a high area ratio, the other second image can be expressed only with a low area ratio, and it is difficult to achieve both the visibility of the two images.

  In the present invention, the region where the first information portion (6) and the second information portion (8) overlap is defined as the overlapping region (fourth image element (10-4) in the present invention) and the first ink. When the dot area ratios formed by the second ink and the second ink are simply summed, by providing an area exceeding 100%, the two images can be viewed at the same time.

  Further, the increase in density caused by superimposing the halftone dots formed with two different inks is performed in advance in anticipation of the increase in density, and the overlapping area (fourth image element (10-4) in the present invention) and the overlapping area. A density difference is provided between the region (third image element (10-3) in the present invention) that must be the same color as this and is eliminated.

  Further, by forming the overlapping region, the area ratio of the second information portion (8) can be configured with 100%, and the performance of the ink containing the functional material can be maximized. became.

  The above are the two largest characteristic configurations and effects of the latent image printed material (1) of the present invention. With these two configurations, the visibility of the first image (4) and the second image (5) can be kept high compared to the prior art, and the excellent change effect of the two images can be achieved. It is generated.

  In addition, the relationship between the first ink and the second ink needs to be the same in hue, but with respect to the density, one needs to be light and the other needs to be a dark relationship. However, the density difference between the first ink and the second ink is preferably larger than 1.5 times and within 5 times.

  This is because when the density difference between the inks is too small, the visibility of the first image (4) is lowered as in the conventional technique. When the density difference is too large, the observation is performed under specific conditions. In this case, the first image (4) formed with the second ink does not completely disappear but is mixed with the second image (5) and visually recognized.

  In addition, at least one of the first ink and the second ink needs to be a so-called functional ink having a function of changing color under a specific condition. Ink may be used, the second ink may be a functional ink, and both the first ink and the second ink may be a functional ink. However, when both the first ink and the second ink are functional inks, their functions need to be different. This is because with the same function, the second image cannot be visually recognized, and only the first image can be observed under any condition. Moreover, it is desirable that the functionality of the first ink and the second ink are mutually contradictory characteristics. For example, when the second image appears by irradiating and irradiating infrared rays, the first ink is an infrared absorbing ink, and the second ink is an infrared transmitting ink. This is because a strong contrast can be generated by the second ink, and the visibility of the second image can be further enhanced.

  The second information part (8) formed with the first ink needs to be formed by filling. Moreover, the most desirable among the forms of filling is a form of so-called solid that is 100% filling. Since this is one of the objects and effects of the present invention to maximize the performance of the functional ink, it is formed at 100% unless a printing trouble due to solid printing is assumed. Because it is better to do. However, it is within the scope of the technical scope of the present invention to form the second information part (8) between 100% and 80% for the purpose of avoiding printing trouble.

  The printing method of the latent image printed material in the present invention can be formed by any printing method such as offset printing, flexographic printing, letterpress printing, gravure printing, screen printing, and intaglio printing. Further, if functional ink can be used, it can be formed by IJP or the like. In this case, so-called variable printing can be performed in which information of one output item is changed.

  Hereinafter, examples of the latent image printed matter produced in detail will be described in accordance with the above-described mode for carrying out the invention, but the present invention is not limited to these examples.

  Example 1 of the present invention will be described with reference to FIGS. 1 to 7 used in the embodiment. In the first embodiment, an example will be described in which a latent image printed material that is different from an image observed under diffuse reflected light and an image observed under regular reflected light is formed. As the base material (2), white fine paper (manufactured by Nippon Paper Industries Co., Ltd.) was used.

  FIG. 1 shows a latent image printed material (1) according to the present invention. In the latent image print (1), a gray print image (3) is formed on a part of the substrate (2), and the print image (3) is the first image (4) shown in FIG. ) And the second image (5) shown in FIG. 2 (b). Furthermore, the first image (4) includes a first information part (6) and a first background part (7), and the second image (5) includes a second information part (8) and a first information part (8). It consists of two background parts (9).

  FIG. 3 shows each image element forming the print image (3). FIG. 3A shows the first image element (10-1), and FIG. 3B shows the second image element (10-2). ) Shows the third image element (10-3), and FIG. 3D shows the fourth image element (10-4).

  FIG. 4 shows combinations of image elements for forming the first image (4). As shown to Fig.4 (a), the 3rd image element (10-3) and the 4th image element (10-4) are combined, and the 1st information part (1) in a 1st image (4) ( 6) is formed, and the first image element (10-1) and the second image element (10-2) are combined in the first image (4) as shown in FIG. A first background portion (7) is formed.

  On the other hand, FIG. 5 shows combinations of image elements for forming the second image (5). As shown to Fig.5 (a), the 2nd information part (2) in a 2nd image (5) (4) is combined by combining a 1st image element (10-1) and a 4th image element (10-4). 8) is formed, and the second image element (10-2) and the third image element (10-3) are combined in the second image (5) as shown in FIG. A second background portion (9) is formed.

  Each image element will be described. The first image element (10-1) is formed with the first area ratio using the first ink, and the second image element (10-2) is formed with the second ink using the second ink. The third image element (10-3) is formed with a third area ratio using the second ink, and the fourth image element (10-4) is formed with the first ink. Are formed at the first area ratio, and then overlapped at the fourth area ratio using the second ink.

  First, the first ink and the second ink were determined. The offset ink produced with the formulation shown in Table 1 was used as the first ink. Moreover, the metallic ink for silver offsets (UV NO3 silver made from T & K TOKA) was used as the 2nd ink. The image shown in FIG. 6A is formed by the first ink, and the image shown in FIG. 6B is formed by the second ink.

  In the first embodiment, the second ink is a functional ink, and has a characteristic that the lightness increases and lightly changes when light enters. On the contrary, the first ink is a normal ink whose color hardly changes even when light is incident.

  In observation under diffuse reflection, the first ink is light gray, the second ink is dark gray, and both inks have the same gray hue. Moreover, when printing on a base material (2), the 2nd ink is the density which can obtain the density | concentration of about 1.5 to 2 times with respect to a 1st ink.

  The area ratio of each image element was determined in the following order.

  First, the area ratio (first area ratio) of the first image element (10-1) formed only with the first ink was determined. Since the printability of the first ink had no problem, the first area ratio was set to 100%.

  Subsequently, the area ratio (second area ratio) of the second image element (10-2) was determined. When the first ink has an area ratio of 100% by the previous printing test, the first ink and the second ink are visually recognized as the same color if the second ink has an area ratio of 40%. It was confirmed that the second area ratio was 40%.

  Subsequently, the area ratio (fourth area ratio) of the second ink of the fourth image element (10-4) was determined. When the second ink is overlapped with the first ink having an area ratio of more than 30% and an area ratio of 100%, the first information part (6) disappears during regular reflection according to a prior printing test. The fourth area ratio was set to 30% because it was confirmed that the image was mixed with the second image and visually recognized.

  Finally, the area ratio (third area ratio) of the third image element (10-3) was determined. According to a prior printing test, a fourth image element (10−) formed by overlapping the first ink with a 100% area ratio and then overlaying the second ink with a 30% area ratio. It was confirmed that when the second ink was formed with an area ratio of 65%, it could be visually recognized as the same color. Therefore, the third area ratio was determined to be 65%. Since these area ratios have different appropriate values depending on the ink to be used, a preliminary printing test for confirming the relationship between the area ratio of each ink and the color is indispensable.

  By the above procedure, the first image element (10-1) is formed using the first ink at an area ratio of 100%, and the second image element (10-2) is formed using the second ink. And a third image element (10-3) is formed with a second ink using a 65% area ratio, and a fourth image element (10-4) is formed. The first ink was used to form an area ratio of 100%, and then the second ink was used to superimpose an area ratio of 30%. First, after printing the image shown in FIG. 6A with the first ink, it was printed with the second ink that forms the image shown in FIG. 6B.

  The effect in Example 1 of this invention is demonstrated using FIG. As shown in FIG. 7A, when the latent image printed material (1) of the present invention is observed under diffuse reflected light, the first image element (10-1) and the second image element (10). -2) is visually recognized in the same color, and the third image element (10-3) and the fourth image element (10-4) are also visually recognized in the same color, and in addition, the third image element (10- 3) and the fourth image element (10-4) are viewed darker than the first image element (10-1) and the second image element (10-2), so that the observer (13a) The 1st image (4) shown to Fig.7 (a) was visually recognized.

  Further, as shown in FIG. 7B, when the latent image printed material (1) of the present invention is observed at an observation angle where specular reflection light is dominant, a second ink formed with the second ink is used. The image element (10-2), the third image element (10-3), and the fourth image element (10-4) of the image lightly change by strongly reflecting light, and the area ratio between the image elements Difficult to catch the difference. In particular, the second image element (10-2) and the third image element (10-3) are visually recognized as flat and single gradation. In addition, the first image element (10-1) formed with only the first ink does not change in color, and the fourth image formed with two inks, the first ink and the second ink. The element (10-4) changes lightly and becomes the same color as the first image element (10-1), and the first image element (10-1) and the fourth image element (10-4) Since the second image element (10-2) and the third image element (10-3) are viewed darker than the second image element (10-2) and the third image element (10-3), as shown in FIG. Only the second image (5) is visible.

  As described above, when the latent image printed material (1) according to the present invention is observed under diffuse reflected light, the density produced by the difference in area ratio is emphasized rather than the difference in reflectance between the paired inks. When the image (4) is viewed in gray and observed under specular reflection light, the second ink strongly reflects the light, and the shade produced by the difference in area ratio disappears visually and is constant. And the second image (5) is visually recognized by enhancing the difference in reflectance between inks. In this way, it was possible to confirm the effect of changing to a different image having no correlation in observation under diffuse reflection light and regular reflection light.

  A second embodiment of the present invention will be described with reference to FIGS. In the second embodiment, an example of forming a latent image printed material in which an image observed under diffuse reflected light and an image observed with transmitted light are different will be described. Further, in Example 2, the elements other than the first image element (10′-1) were formed by image lines instead of the painted configuration as described in the embodiment and Example 1. As the base material (2 ′), white fine paper (manufactured by Nippon Paper Industries Co., Ltd.) was used in the same manner as in Example 1.

  FIG. 10 shows a latent image print (1 ′) according to the present invention. In the latent image printed matter (1 ′), a gray printed image (3 ′) is formed on a part of the substrate (2 ′), and the printed image (3 ′) is the first image shown in FIG. It consists of one image (4 ′) and a second image (5 ′) shown in FIG. Further, the first image (4 ′) is composed of a first information part (6 ′) and a first background part (7 ′), and the second image (5 ′) is a second information part ( 8 ′) and a second background portion (9 ′).

  FIG. 12 shows each image element forming the print image (3 ′). FIG. 12A shows the first image element (10′-1), and FIG. 12B shows the second image element (10′-2). FIG. 12C shows the third image element (10′-3), and FIG. 12D shows the fourth image element (10′-4). The basic configuration of the image elements is the same as that described in the mode for carrying out the invention and Example 1, and the first image (4 ′) and A second image (5 ′) is formed.

  Each image element will be described. The first image element (10′-1) is formed with the first area ratio using the first ink, and the second image element (10′-2) is formed with the second ink. The third image element (10′-3) is formed at the third area ratio using the second ink, and the fourth image element (10′-4) is formed at the second area ratio. After the first ink is used to form the first area ratio, the second ink is used to overlap the fourth area ratio.

  First, the first ink and the second ink were determined. A transmissive ink (Teikoku Unimark) was used as the first ink for forming the image shown in FIG. Further, the offset ink having the composition shown in Table 2 was used as the second ink for forming the image shown in FIG. The image shown in FIG. 18A is formed by the first ink, and the image shown in FIG. 18B is formed by the second ink.

  In the second embodiment, the first ink is a functional ink, and has a characteristic that it looks white by strongly transmitting light when observed under transmitted light. On the contrary, the second ink does not contain any special functional material, and the color hardly changes even when light is transmitted. However, since the reflection density is extremely light, it is the same color as the base material under transmitted light. It has a feature that it is visible and visually recognized as if the image has disappeared.

  In observation under diffuse reflection, the first ink is light gray, the second ink is dark gray, and both inks have the same gray hue. Moreover, when printing on a base material (2 '), the 2nd ink is the density | concentration which can obtain the density | concentration of about 1.5 to 2 times with respect to a 1st ink.

  The area ratio of each image element was determined in the following order.

  First, the area ratio (first area ratio) of the first image element (10′-1) formed only with the first ink was determined. Since the printability of the first ink was satisfactory, the first area ratio was set to 100%.

  Subsequently, the area ratio (second area ratio) of the second image element (10′-2) was determined. When the first ink has an area ratio of 100% by the previous printing test, the first ink and the second ink are visually recognized as the same color if the second ink has an area ratio of 40%. It was confirmed that the second area ratio was 40%.

  Subsequently, the area ratio (fourth area ratio) of the second ink of the fourth image element (10′-4) was determined. When the second ink is overlapped with the first ink having an area ratio of more than 50% and an area ratio of 100% according to the previous printing test, the first information portion (when observed under transmitted light) Since it was confirmed that 6) did not completely disappear and mixed with the second image, the fourth area ratio was set to 50%.

  Finally, the area ratio (third area ratio) of the third image element (10′-3) was determined. According to a preliminary printing test, a fourth image element (10'-10) formed by superimposing a 100% area ratio using the first ink and then overlapping a second ink using a 50% area ratio. It was confirmed that when the second ink had an area ratio of 80%, it could be visually recognized as the same color when it was visually recognized as the same color as 4). Therefore, the third area ratio was determined to be 80%. Since these area ratios have different appropriate values depending on the ink to be used, a preliminary printing test for confirming the relationship between the area ratio of each ink and the color is indispensable.

  In the second embodiment, since the configuration other than the first image element (10′-1) is not the fill configuration as described in the embodiment or the first embodiment, the configuration of each image element is specifically described. To do.

  FIG. 13 shows the first image element (10′-1). The first ink is used to form a filled region (14 ') formed at the first area ratio. Only the first image element (10′-1) has a solid printing configuration filled with an area ratio of 100%, and has the same configuration as the mode for carrying out the invention and the first embodiment.

  FIG. 14 shows the second image element (10′-2). By arranging a plurality of image lines (15 ′) having a line width of 0.12 mm formed by the second ink in the S1 direction at a pitch of 0.3 mm, a second area ratio, that is, an area ratio of 40% Two image elements (10'-2) were constructed.

  FIG. 15 shows a third image element (10′-3). The third image element is an image line (15 ') that forms the second image element described above with the second ink, and an image line (15') adjacent to the image line (15 '). 16 ′) are arranged in the S1 direction at a pitch of 0.3 mm, and the image width is 0.12 mm on the non-image area of the image line (16 ′) so as not to overlap with the image line (16 ′). An image line (16 ″) is formed. Therefore, an image line (16 ′) having an image line width of 0.12 mm and an image line (16 ″) having an image line width of 0.12 mm are formed within a pitch of 0.3 mm. A third image element (10′-3) having an area ratio of 80% was configured.

  Specifically, each image line (16 ′) having an image line width of 0.12 mm in the third image element (10′-3) has an image line width of 0 in the second image element (10′-2) described above. The area ratio of this portion is 40% because it is connected to each image line (15 ') of 12 mm. Then, in order to make the area ratio of the third image element (10′-3) 80%, the image line (16 ″) having an image line width of 0.12 mm is not overlapped with the image line (16 ′). Are arranged at a pitch of 0.3 mm.

  As another example, if the area ratio of the third image element (10′-3) is 70%, first, a plurality of image lines (16 ′) having an image line width of 0.12 mm are arranged at a pitch of 0.3 mm. By doing so, the area ratio becomes 40%. In order to make the third image element (10′-3) have an area ratio of 70%, a plurality of image lines (16 ″) are arranged as an image line that forms the remaining area ratio of 30%. To do. The image line width of the image line (16 ″) at that time is appropriately determined according to the area ratio (30% in this case).

  FIG. 16 shows a fourth image element (10′-4). An image line (17 ′) formed by the second ink and having a line width of 0.15 mm is formed on the filled area (14 ′) formed by the first ink and having an area ratio of 100%. The fourth image element (10′-4) having a fourth area ratio, that is, an area ratio of 50% is configured by arranging a plurality of elements in the S1 direction.

  FIG. 17 shows a partially enlarged view of the configuration of the print image (3 ′). As described above, the print image (3 ′) includes the first image element (10′-1) illustrated in FIG. 13, the second image element (10′-2) illustrated in FIG. The third image element (10′-3) and the fourth image element (10′-4) shown in FIG. 16 are included. Each image element is shown in a partially enlarged view of FIG. Thus, they are formed so as not to overlap each other.

  The second image element (10'-2) shown in FIG. 14, the third image element (10'-3) shown in FIG. 15, and the fourth image element (10'-) shown in FIG. 4) has a configuration in which a plurality of image lines in all image elements are arranged in the S1 direction. However, the image lines need not be limited to the S1 direction. There are no particular restrictions on the direction in which it is to be detected. In other words, a plurality of image lines in all image elements may be arranged in a direction orthogonal to the S1 direction, and image lines constituting the second image element (10′-2) are arranged in the S1 direction. The direction of each image element is combined, such as forming the image lines constituting the third image element (10'-3) and the fourth image element (10'-4) in a direction orthogonal to the S1 direction. May be.

  FIG. 18 shows a plate surface configuration of the latent image printed material in the second embodiment. FIG. 18A shows an image formed with the first ink, and FIG. 18B shows an image formed with the second ink. When printing, first, the image shown in FIG. 18A was printed with the first ink, and then the image shown in FIG. 18B was printed with the second ink.

  In the present Example 2, each area ratio was comprised by the area of the drawing line contained in a fixed area. In this way, by controlling the ratio of the image line and the non-image line, a specific area ratio is configured using the image line, or the pixel and non-pixel closing ratio is controlled by using the pixel. Thus, a specific area ratio can also be configured.

  As described above, the reason why the image elements other than the first image element (10′-1) are configured by the image lines and pixels is that when the latent image printed material is copied using a copying machine, This is because a so-called copy check function is added, in which an image in which the second image is mixed appears to inform that the printed material is not a genuine product but a copy, and to check unauthorized copying.

  As described above, the first image element (10′-1), which is one of the features of the latent image printed material (1 ′) in the present invention, and other regions can be expressed with greatly different area ratios. By using a special image configuration, it is possible to give such a high copy restraining effect.

  The effect in the present Example 2 is demonstrated using FIG. As shown in FIG. 19A, when the latent image print (1) of the present invention is observed under diffuse reflected light, the first image element (10'-1) and the second image element ( 10′-2) is visually recognized in the same color, and the third image element (10′-3) and the fourth image element (10′-4) are also visually recognized in the same color. The element (10′-3) and the fourth image element (10′-4) are viewed darker than the first image element (10′-1) and the second image element (10′-2). Therefore, the first image (4 ′) shown in FIG. 19A is visually recognized by the observer (13c ′).

  In addition, as shown in FIG. 19B, when the latent image print (1 ′) of the present invention is observed under transmitted light, the second image element (10) formed with the second ink is used. '-2) and the third image element (10'-3) appear to be the same color as the base material, making it difficult to grasp the difference in area ratio between each image element, and visually flat as a single gradation Be recognized. Further, the first image element (10′-1) formed of the first ink transmits light strongly, and the fourth image element (10−1) formed of the first ink and the second ink. Since 4) is observed in the same color as the first image element (10-1), the observer (13d ') has an image in which the second image is inverted as shown in FIG. 19B. (18 ') is visually recognized.

  As described above, when the latent image printed material (1 ′) in the present invention is observed under diffuse reflected light, the density produced by the difference in area ratio is emphasized rather than the difference in transmittance between the paired inks. When the first image (4 ') consisting of the letters "Japan" is viewed in gray and observed with transmitted light, the second ink and the base material do not transmit light particularly strongly, resulting in a difference in area ratio. The shades that have disappeared disappear and converge to a certain gradation, and only the second image (5 ′) in which the cherry blossom petals are formed by the first ink is visible brightly. Thus, it was possible to confirm the effect of changing to a different image having no correlation at all in observation of diffused light and transmitted light.

1, 1 'latent image printed matter 2, 2' base material 3, 3 'printed image 4, 4' first image 5, 5 'second image 6, 6' first information section 7, 7 'first Background portion 8, 8 'second information portion 9, 9' second background portion 10-1, 10'-1 first image element 10-2, 10'-2 second image element 10-3 10'-3 3rd image element 10-4, 10'-4 4th image element 11, 11 'The pattern 12 formed with 2nd ink Light source 13a, 13b, 13c, 13c', 13d, 13d ' 13e, 13f Viewer's viewpoint 14 'Filled area 15' forming the first image element Image line 16 ', 16 "forming the second image element Image line 17' forming the third image element Image line 18 ′ forming the fourth image element Image obtained by reversing light and shade of the second image

Claims (7)

A printed image is formed on at least a part of the base material by the first ink and the second ink having different colors from the base material, and the printed image includes the first image and the second image. Prepared,
The first image and the second image are formed such that the first image element, the second image element, the third image element, and the fourth image element do not overlap each other.
The first image element is formed by the first ink at a first area ratio, and the second image element is formed by the second ink at a second area ratio, The third image element is formed by the second ink at a third area ratio, and the fourth image element is formed by the first ink at a first area ratio. The second ink is superimposed at a fourth area ratio,
The first image has a first information part and a first background part, and the second image has a second information part and a second background part,
The first information part in the first image is composed of the third image element and the fourth image element, and the first background part in the first image is the first image element. And the second image element, the second information part in the second image is composed of the first image element and the fourth image element, and the second image element in the second image. The background portion is composed of the second image element and the third image element,
The first area ratio is greater than the second area ratio, the third area ratio is greater than or equal to the fourth area ratio,
The first ink and the second ink have the same hue, the first ink has a lower density than the second ink, and the first ink and / or the second ink is , When observed under diffuse reflected light and when observed under specific conditions different from the diffuse reflected light has a different color functionality,
When observed under diffuse reflected light, the first image is caused by a difference in reflection density in the first image element, the second image element, the third image element, and the fourth image element. When the second image is visually recognized and observed under the specific condition different from that under the diffusely reflected light, the second image has a difference in functionality between the first ink and the second ink. A latent image printed matter characterized in that is visually recognized. The latent image printed matter according to claim 1, wherein the first area ratio is 100%. The latent image printed matter according to claim 1 or 2, wherein a difference between the second area ratio and the third area ratio is 10% or more and 50% or less. The latent image printed matter according to any one of claims 1 to 3, wherein the fourth area ratio is 50% or less. The latent image print according to any one of claims 1 to 4, wherein the density difference between the first ink and the second ink is 1.5 to 5 times. The latent image according to any one of claims 1 to 5, wherein the second image element and / or the third image element is at least one of an image line and a pixel, or a combination of each. Printed image. The observation under the specific conditions includes observation under specular reflection light, observation under transmitted light, observation with irradiation of light in the ultraviolet wavelength band, observation with light in the infrared wavelength band, limitation of the visible light range. The latent image printed matter according to any one of claims 1 to 6, wherein the latent image printed matter is observation with light in a specified wavelength band or observation under a specific temperature.

Images