JP2016055480A - Special latent image body - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a printed matter capable of exposing kinetic change without requiring brilliant ink formed by blending in ink, a special functional material such as a metal pigment or a pearl pigment with a semicylindrical element, and without depending on the thickness of a lens.SOLUTION: There is provided a latent image formation body 1 capable of viewing a latent image 5 clearly and kinetically by a light reflection function carried by a light reflection region, at a specific observation angle under regularly reflected light, by laminating a semicylindrical image group 6 having optical transparency on the light reflection region 4 including a latent image group 5.SELECTED DRAWING: Figure 1

Description

  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 provides images under specular reflection. The present invention relates to a changing special latent image body.

  In recent years, the effect of changing images that switch multiple images and the effect of moving images that appear to move are easily attracted to people and are difficult to forge. is there. A typical technique having this change effect is a hologram, which is widely used by being affixed to a security printed matter requiring the highest security such as a banknote or a passport.

  On the other hand, in addition to holograms, using known technologies such as parallax barriers and lenticulars, these technologies provide the ability to change images with a slight change in angle, making it possible to change images by switching between multiple images. There is already a true / false discrimination element with

  However, although holograms are used for various security printed materials such as banknotes, there are significant problems in the complexity of the manufacturing process and high manufacturing costs compared to general printed materials. Since the authenticity determination element using a parallax barrier or lenticular requires a clear layer or a lens, the base material is almost limited to plastic, and the printed material has a certain thickness (about 150 μm). It is necessary, and considering the distribution suitability in the market and the loading form, it exceeds the thickness allowed for generally printed materials, so it cannot be used for printed materials with limited thickness, and it is made of plastic that allows a certain thickness. There is a tendency not to be adopted other than cards.

  In view of the above-mentioned problems, the present applicant uses a general and relatively inexpensive material and simple printing means, and at a specific observation angle under specular reflection light at a specific part in the printed matter. We have already invented an invention related to an optical change technology in which information recognized by the human eye changes to completely different information by changing the observation angle under specular reflection light, or the image that appears appears to move. Applications have been filed (see, for example, Patent Document 1, Patent Document 2, Patent Document 3, Patent Document 4, and Patent Document 5).

Japanese Patent No. 4682283 Japanese Patent No. 4660775 Japanese Patent No. 4844894 Japanese Patent No. 5131789 Japanese Patent No. 5200284

  In the conventional techniques from Patent Document 1 to Patent Document 5, a plurality of images formed by arranging latent image elements on an image formed by arranging a plurality of bowl-shaped elements each having a bowl-shaped swell. A technology that overlays and forms a latent image that contains multiple images that appear in the latent image under specular reflection, and changes to different images by changing the observation angle. This is an excellent technology that has a moving image effect in which a captured image appears to move. However, these technologies require optical characteristics required for each bowl-shaped element to produce strong specularly reflected light when light is incident and change brightness or hue, so-called light / dark flip-flops. Or color flip-flop was essential. As a method for obtaining high light / dark flip-flop properties and color flip-flop properties, a method in which special functional materials such as metal pigments and pearl pigments having these properties are mixed in ink is generally used. However, in the case of a thick bowl-shaped element having a bulge as in the prior art, when such special ink is used, the functional material is oriented in a random direction within the thick ink film. However, since incident light is irregularly reflected in various directions, there is a problem that it is technically difficult to obtain high light-dark flip-flop properties and color flip-flop properties. When these optical characteristics cannot be satisfied, there is a problem that the latent image does not appear or the visibility of the appearing latent image is greatly reduced. As described above, there is a problem that it is difficult to impart desired brightness / darkness flip-flop property and color flip-flop property to the bowl-shaped element.

  In addition, in the conventional techniques from Patent Document 1 to Patent Document 5, if high brightness / darkness flip-flop property or color flip-flop property can be imparted to the bowl-shaped element, the visibility of the latent image is improved. This reduces the image change effect (such as the appearance of a mixture of latent images, or the number of latent images that appear) is reduced, and the moving image effect (width of motion) of the appearing latent image is small. There was a problem of becoming. This is because functional materials that are generally excellent in light and dark flip-flops or color flip-flops tend to diffuse and reflect incident light over a wide angle, resulting in a bowl-like shape against the incident light. This results in an area of the element surface that reflects the light of the element being too large. Under this condition, although the amount of reflected light itself becomes large, the latent image superimposed on the surface of the bowl-shaped element is also sampled in a wide area. Therefore, a plurality of latent image images are sampled at the same time. The latent image that should have appeared at another position is synthesized and reproduced as a blurred image at an intermediate position between A and B. From the above, the conventional technique has a problem that it is difficult to simultaneously satisfy the visibility of the latent image, the change effect, the moving image effect, and the like.

  In addition, in the conventional techniques from Patent Document 1 to Patent Document 5, a latent image formed by arranging a plurality of latent image elements on an image in which a plurality of bowl-shaped elements having a bowl-shaped swell is arranged. This is a technique of superimposing and forming a saddle-like element with a screen printer, and a latent image is generally formed with an offset printer or a flexographic printer. For this reason, in forming each printed matter, it is necessary to perform screen printing and then offset printing, which is the opposite of the flow of manufacturing common sense printed matter in the general printing process. However, in the production of the prior art, a normal printing line cannot be applied as it is, and it is necessary to design a special printing line for exclusive use. In addition, when considering manufacturing with a single printer without going through multiple printing processes, a combination printer equipped with different printing units such as screen printing and offset printing in one printer In general, offset printing and flexographic printing units are provided as pre-printing units, and screen printing is installed as a post-printing unit on the final cylinder. In order to manufacture with this printing machine, there is a problem that a special combination printing machine having an offset printing unit after the screen printing unit is required.

  The present invention aims to solve the above-mentioned problems, and, as in the prior art, the glitter property obtained by blending special functional materials such as metal pigments and pearl pigments in the ink when forming the hook-shaped elements. Without the need for ink, it is possible to achieve both the visibility of the latent image, the change effect, and the moving image effect (including moire). It is characterized in that it does not require a thickness like a printed matter using a lenticular, and can be easily manufactured at a lower cost than a hologram.

  The present invention comprises a printed image area on at least a part of a substrate, the printed image area having a light reflective area having at least one of light / dark flip-flop property and color flip-flop property, and light. It consists of a group of saddle-like elements laminated on a reflective region. The light reflective region is specularly reflected on i) a substrate having optical properties or a reflective layer having optical properties formed on the substrate. A latent image formed by aligning latent image elements having a color different from that of the base material itself or the reflective layer in a line at a predetermined pitch under light, or a latent image formed by removing a part of the reflective layer A latent image formed by arranging elements in a line at a predetermined pitch, or ii) a latent image formed by arranging latent image elements having optical characteristics on a substrate in a line at a predetermined pitch Consists of images, the saddle-like elements are light transmissive, In other words, the ridge-like elements having a raised shape are arranged in a line with the same or different pitch as the predetermined pitch, and reflect the light of the light-reflecting region at a specific observation angle under specular reflection light. The special latent image object is characterized in that the latent image is clearly and dynamically visually recognized by the function of

  The present invention is a special latent image body in which the latent image element is formed by compressing an image obtained by dividing a plurality of base images at a predetermined reduction ratio.

  In the present invention, the latent image has a latent image element group expressing two significant information, and the latent image element group includes a first latent image element arranged in a line at a predetermined pitch. The first latent image element group representing the significant information of the first latent image element and the second latent image element are arranged in a line at a predetermined pitch so as not to overlap the first latent image element. A second latent image element group representing the first latent information and the second significant information independently appearing according to the angle at which the substrate is tilted. It is an image image body.

  The special latent image body of the present invention also requires light and dark flip-flops and color flip-flops as in the prior art, but this characteristic is due to the structure of the reflective layer and the latent image. This characteristic is not necessary for the saddle-like element formed by screen printing. The hook-like element only needs to be transmissive, and it is not necessary for the screen ink to have special optical properties as in the prior art, and is easy to manufacture.

  In the prior art, the saddle-shaped element has two functions of reflecting light strongly and sampling the latent image. However, in the special latent image body of the present invention, the function of reflecting light strongly is reflected. It is a configuration in which the saddle-shaped element bears only the function of the layer and sampling the latent image. As described above, since the reflective layer and the bowl-shaped element are responsible for the two functions required individually, the reflection layer and the bowl-shaped element are specialized in structure and optical characteristics in order to realize each function. be able to. For this reason, it has become possible to simultaneously satisfy the visibility of the latent image, the change effect, the moving image effect, and the like, which were difficult with the prior art.

  Since the special latent image body of the present invention can be manufactured in the manufacturing process of a general printed matter in which screen printing is performed after offset printing, it can be manufactured using a normal printing line. It was.

  The special latent image body of the present invention can be formed with a thickness of 1/10 or less as compared with a general technique that uses a lens effect such as a lenticular or microlens array to achieve an image change effect. In addition, it does not require a dedicated production device or machine like a hologram, and can be produced by using a general printing ink and an existing printing machine with paper as a base material. Is expensive.

(A) shows the front view of the special latent image body in this invention, (b) shows a side view. The outline | summary of a structure of the special latent image body in this invention is shown. The layer structure of the special latent image body in this invention is shown. The detail of the latent image of this invention is shown. The saddle-like element group in this invention is shown. The positional relationship of the overlap of the latent image and the bowl-shaped element group in the present invention is shown. The effect of the special latent image body in this invention is shown. FIG. 3 is an explanatory diagram of a principle that produces the effect of the special latent image body of the present invention. (A) shows the front view of the special latent image body in this invention, (b) shows a side view. The outline | summary of a structure of the special latent image body in this invention is shown. The detail of the latent image in this invention is shown. The effect of the special latent image object of the present invention is shown. (A) shows the front view of the special latent image body in this invention, (b) shows a side view. The outline | summary of a structure of the special latent image body in this invention is shown. The detail of the latent image in this invention is shown. The detail of the bowl-shaped element group in this invention is shown. The effect of the special latent image object of the present invention is shown. (A) shows the front view of the special latent image body in this invention, (b) shows a side view. The outline | summary of a structure of the special latent image body in this invention is shown. The layer structure of the special latent image body in this invention is shown. The effect of the special latent image object of the present invention is shown. (A) shows the front view of the special latent image body in this invention, (b) shows a side view. The outline | summary of a structure of the special latent image body in this invention is shown. The detail of the latent image of this invention is shown. The saddle-like element group in this invention is shown. The effect of the special latent image body in this invention 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.

(First embodiment)
FIG. 1 shows a special latent image body (1) according to the present invention. FIG. 1A shows a front view of the special latent image body (1), and FIG. 1B shows a cross-sectional view of the special latent image body (1) along the line AA ′. is there. The special latent image body (1) is formed by forming a print image area (3) on a substrate (2). The substrate (2) may be paper, plastic, metal or the like as long as the print image region (3) can be formed, and the material is not limited. The print image area (3) may have any color, and there is no problem even if it is transparent or translucent. Moreover, there is no restriction | limiting in particular also about the magnitude | size of a base material (2).

  An outline of the configuration of the print image area (3) of the present invention is shown in FIG. FIG. 2 shows an example in which a light reflective region (not shown) is formed of a reflective layer (4). The light reflective region (not shown) is not only the reflective layer (4) but also a substrate. The case (2) itself or the latent image (5) may be used, and the case where the substrate (2) itself or the latent image (5) has a light reflective region (not shown) will be described later. . The print image area (3) includes a reflective layer (4), a first latent image element group (5A) representing first significant information, and a second latent image element group (second latent information element group (2A) representing second significant information). 5B) and a saddle-like element group (6). FIG. 3 shows the stacking order of the images in the print image area (3) in the first embodiment. In the print image area (3), the latent image (5) is superimposed on the reflective layer (4), and the saddle-like element group (6) is superimposed thereon. In the first embodiment, the special latent image body (1) having a three-layer structure will be described. However, the reflective layer (4) is not present, and the latent image (5) itself is the reflective layer (4). There is also a special latent image body (1) which is a part and has a two-layer structure in which the latent image (5) and the reflective layer (4) are integrated. The form of this two-layer structure will be described in a fourth embodiment. In addition, even if the base material (2) itself has the characteristics required for the reflective layer (4), that is, a form provided with a light-dark flip-flop property and a color flip-flop property, the reflective layer (4) is not necessary, so two layers It becomes a form of structure. In this case, the base material is desirably a metal or plastic.

  In the case of the three-layered special latent image body (1), the laminated structure of the three images always includes the reflective layer (4) on the bottom layer (base (2) side) and the latent image (5) in the middle. However, it is necessary to form the ridge-like element group (6) on top of each other in the overlapping order. In addition, the latent image (5) may have at least one latent image element group representing significant information, but a form having a plurality of significant information is more preferable. An example in which the image (5) includes two latent image element groups (5A, 5B) will be described. In the first embodiment, the latent image (5) includes a first latent image element group (5A) and a second latent image element group (5B), and the first latent image element group (5A). The significant information represented by is the letter “A” of the alphabet, and the significant information represented by the second latent image element group (5B) is the letter “B” of the alphabet.

  The shape of the reflective layer (4) can take any shape. Basically, it is desirable that the shape is the same as the shape of the bowl-shaped element group (6). However, different shapes may be used. In the present invention, the overlapping region where the reflective layer (4) and the saddle-like element group (6) overlap is regarded as the print image region (3), and the region not overlapping is regarded as an accessory for simple modification. The reflection layer (4) has at least one of optical characteristics of so-called light / dark flip-flop property in which light is strongly reflected during regular reflection to increase brightness, or so-called color flip-flop property in which hue changes during regular reflection. It is necessary to have. Bright and dark color flip-flops are provided in metal foil, transparent film, metal film, metal tape, resin, plastic, metal ink, gloss ink, and the like.

  On the other hand, as a material having color flip-flop properties, there are an interference film, a hologram film, and the like. As inks used for printing, there are pearl ink, liquid crystal ink, OVI, CSI (Color Shifting Ink), and the like. Many inks have an object color, while iris pearl ink is colorless and transparent. For example, a red iris pearl ink is colorless and transparent under diffuse reflection light, but emits a red interference color under regular reflection light. Thus, the hue itself of the reflective layer (4) having “color flip-flop” changes under specularly reflected light. Further, it is desirable that the reflective layer (4) has an optical characteristic that reflects light only in a very narrow angle range near the same angle opposite to the angle of the incident light without diffusing the light.

  FIG. 4 shows a specific configuration of the latent image (5). The latent image (5) includes a first latent image element group (5A) and a second latent image element group (5B). The first latent image element group (5A) includes a plurality of first latent image elements (7A) having a fixed image line width (W1) at a specific pitch (P1) in the first direction (S1 direction in the figure). It is arranged to represent the letter “A” of the alphabet. On the other hand, in the second latent image element group (5B), the second latent image element (7B) having a constant image line width (W2) has a specific pitch (P1) in the first direction (S1 direction in the figure). The letter “B” of the alphabet is represented by being arranged in multiple numbers. The first latent image element group (5A) and the second latent image element group (5B) are arranged out of phase in the first direction, so that each latent image element (7A, 7B) is arranged. The latent image (5) is configured so as not to overlap.

  In the special latent image body (1) of the first embodiment, the pitches of the latent image elements (7A, 7B) constituting the respective latent image element groups (5A, 5B) must be the same. . On the other hand, the element widths (W1, W2) in the first direction (S1) of the latent image elements (7A, 7B) may be the same or different. From the relationship between the element width and pitch of the latent image element (7), it is preferable that both the element width and pitch of the latent image element (7) are in the range of 0.01 mm to 5 mm.

  Each of the latent image elements (7) is not necessarily raised, and therefore may be formed by any printing method. In view of productivity, it is most preferable to form by offset printing. In order to visualize part of the information in the latent image (5) under specular reflection light, the latent image element (7) needs to produce a color difference with the reflective layer (4) during specular reflection. At least the color at the time of reflection needs to be different from the color at the time of regular reflection of the reflection layer (4). Further, since the latent image element (7) is formed so as to overlap the reflective layer (4), the light incident on the reflective layer (4) under the latent image element (7) is blocked and regular reflection is performed. In the case where the color change of the reflective layer (4) that occurs under light is suppressed, the color difference from the reflective layer (4) on which the latent image element (7) does not overlap increases. The visibility of significant information expressed by the latent image element group (5) becomes higher. As described above, when it is desired to further improve the visibility of the latent image, high light blocking properties may be imparted to the latent image element (7). When a functional material having a high light blocking property such as titanium dioxide or aluminum oxide is blended in the printing ink for printing the latent image (5), a higher effect can be obtained.

  If the latent image (5) is to be invisible under diffuse reflected light, the latent image (5) has the same color as the underlying reflective layer (4) or the base material (2), is colorless and transparent, What is necessary is just to form transparently. When forming with transparent or semi-transparent ink, in order to facilitate quality control, color the ink by slightly coloring pigment, or use a UV lamp with fluorescent pigment in transparent ink. It is also possible to manage abnormalities such as reprinting and printing defects.

  In the present invention, `` color '' represents a color including the concept of hue, saturation, and brightness, and `` different color '' is different from any of hue, brightness, or saturation, Or, the combination is different. The color difference in the present invention is defined by ΔE in the CIE 1976 L * a * b * color system. The CIE 1976 L * a * b * color system is a color space recommended by the CIE (International Lighting Commission) in 1976, and is defined in JIS Z 8729 in the Japanese Industrial Standards. The color difference is a distance in a color space of two colors, and the color difference in the CIE 1976 L * a * b * color system is a difference between L *, a *, and b * of two colors. It can be obtained by adding each squared and taking the square root.

  The latent image (5) may be formed not only with ink but also with a printer. It can also be formed by cutting and applying an image corresponding to the latent image element (7) to the reflective layer (4) or the substrate (2). Such cutting can be easily performed by using a laser processing machine. In many cases, the reflection layer (4) and the base material (2) irradiated with the laser lose or greatly deteriorate the light / dark flip-flop property and the color flip-flop property. ) Can be imparted with the characteristics required to constitute. When these printers and laser processing machines are used, there is a feature that variable information that gives different information one by one can be easily given.

  FIG. 5 shows a specific configuration of the bowl-shaped element group (6). The saddle-shaped element group (6) has a fixed line width (W3), and the saddle-shaped element (8) having a raised height in a bowl-like shape is specified in the first direction (S1 direction in the figure). A plurality of pitches (P1) are arranged. The bowl-shaped element (8) in the first embodiment is an image line and has a bowl-shaped cross section, but is not limited to this shape. The shape of the bowl-shaped element (8) is not limited to the image line, and may be a pixel. More specifically, any shape can be used as long as it is a three-dimensional curved surface shape, that is, a structure having a bulge and is symmetrical to at least the first direction (the S1 direction in the figure). Also good. Not only circular pixels having the swell of the third embodiment described later, but also a semi-elliptical sphere, a symmetrical shape with a certain curvature such as a bowl shape, a polygonal column such as a triangular prism, pentagonal prism, hexagonal prism, etc. The planar shape may be a shape having a curved shape such as a circle or an ellipse, or a polygon such as a triangle, pentagon, or hexagon.

  The saddle-like element group (6) needs to have a property of transmitting light and may be colored, but it should not have a structure that absorbs at least all of the light. That is, the bowl-shaped element group (6) needs to be transparent or translucent. Further, it is desirable that the image surface is smooth. The saddle-like element group (6) having the above-described configuration is formed by a printing method capable of forming a swell in a printed image line. In order to ensure a certain level of visibility in the latent image appearing under specular reflection light, the raised height of the saddle-like element (8) needs to be at least 3 μm, so it is formed by screen printing or intaglio printing. However, it is possible to form such a height of the image line even in the case of gravure printing, flexographic printing, letterpress printing, IJP, or the like. The upper limit of the height of the rise is not particularly limited, but is set to 1 mm or less in consideration of stability, friction resistance, distribution suitability, etc. when a large amount is loaded.

  FIG. 6 shows the positional relationship of the overlapping of each latent image element (7A, 7B) constituting the latent image (5) and the bowl-shaped element (8). In FIG. 6, two latent image elements (7A, 7B) are arranged so as to completely overlap the bowl-shaped element (8). This is the most desirable form, but the effect of the present invention is exhibited as long as the latent image elements (7A, 7B) and the bowl-shaped element (8) overlap at least partially.

  The effect of the special latent image body (1) of the present invention having the above structure will be described with reference to FIG. As shown in FIG. 7 (a), when the special latent image body (1) of the present invention is observed under diffuse reflected light, is the latent image (5) visually recognized in a specific color? Or invisible. As shown in FIG. 7B, when the special latent image body (1) of the present invention is observed under specular reflection light, a specific observation angle (in the first embodiment, a slightly shallow observation angle). ), The letter “A” of the alphabet represented by the first latent image element group (5A) appears. As shown in FIG. 7 (c), when the special latent image body (1) of the present invention is observed under specular reflection light, a specific observation angle (first view) is different from that in FIG. 7 (b). In the embodiment, the letter “B” of the alphabet represented by the second latent image element group (5B) appears at a slightly deeper observation angle.

  Significant information represented by each latent image element group (5A, 5B) cannot be viewed from any angle as long as it is under specular reflection light, and the angle range in which each information can be viewed is limited. Even if the special latent image body (1) is observed within the observation angle area where specular reflection light is generated from the special latent image body (1) when the observation angle is out of the specific angle range, the print image area (3) No significant information appears in it.

  The principle that produces the above effect will be described. First, the principle that the latent image (5) is visually recognized or invisible under diffuse reflection will be described. Since the printed image area (3) does not emit strong specular reflection light under diffuse reflection light, if the latent image (5) is formed of ink having a solid color, the color of the ink remains as it is. It is invisible if it is visible and is formed of transparent or translucent ink. Therefore, the latent image (5) under diffuse reflected light is visually recognized in a specific color or invisible.

  Next, the first latent image element group (5A) alone appears at a specific observation angle under specular reflection light, and the second latent image element group (5B) alone appears at a different observation angle. The principle that appears in FIG. 8 will be described with reference to FIG.

  FIG. 8A shows a state in which incident light is regularly reflected by the reflective layer (4), and FIG. 8B shows a state in which incident light is regularly reflected by the latent image element (7). . As shown in FIG. 8A, among the light emitted from the light source (9), the light (9A) having an incident angle close to the right angle with the surface angle of the bowl-shaped element (8) is the bowl-shaped element ( 8) The light (9B, 9C) entering the inside and having other incident angles is reflected on the surface of the bowl-shaped element (8) and cannot enter the bowl-shaped element (8). Thus, the light which can penetrate | invade inside the bowl-shaped element (8) among the lights irradiated from the light source (9) is restrict | limited to the light of a specific incident angle.

  In addition, although the light which has penetrated into the inside of the hook-shaped element (8) is slightly refracted and changes its angle, the thickness of the hook-shaped element (8) is originally about several μm. The effect of light reflectivity is slight. As shown in FIG. 8A, when the incident light is reflected by the reflection layer (4), extremely strong regular reflection light (11S) is generated for the same angle opposite to the angle of the incident light. For the angle, weak diffuse reflected light (11D) is generated. On the other hand, as shown in FIG. 8B, when the incident light is reflected not by the reflective layer (4) but by the latent image element (7), the regular reflected light with respect to the same angle opposite to the angle of the incident light. (11S ′) is generated, and weak diffuse reflected light (11D ′) is generated for other angles. Since the diffuse reflected light (11D) and the diffuse reflected light (11D ′) are both diffuse reflected light, there is no significant difference in the amount of light or the color of the light, but the regular reflected light (11S) and the regular reflected light (11S) are not. The reflected light (11S ′) has a large difference in light quantity and light color. The difference in the amount of light between the specularly reflected light (11S) and the specularly reflected light (11S ′) and the color of the light vary depending on the characteristics of the material forming the latent image element (7), but basically the latent image element (7 ) Causes light attenuation, so that (11S ′) is weaker than (11S) (however, it is much larger than diffusely reflected light (11D) and diffusely reflected light (11D ′)). As described above, in the diffuse reflected light region, the amount of diffuse reflected light (11D, 11D ′) and the color of the light do not change greatly depending on the presence or absence of the latent image element (7). Depending on the presence / absence of the image element (7), the amount of light of the regularly reflected light (11S, 11S ′) and the color of the light vary greatly. By this phenomenon, the latent image element (7) is visualized by the difference in light quantity and light color, and as a result, significant information represented by the latent image element group (5) is visualized.

  Further, when the angle of the special latent image body (1) with respect to the light source (9) is changed, the angle between the light source (9) and the surface of the image line of the bowl-shaped element (8) also changes, so that the bowl-shaped element (8 ) Also changes the incident angle of the light entering the inside, and accordingly, the reflection position of the light on the reflective layer (4) changes. This changes whether the first latent image element (7A) arranged on the reflective layer (4) is sampled or the second latent image element (7B) is sampled. Based on the above principle, the first latent image element group (5A) appears at a specific observation angle under specular reflection light, and the second latent image element group (5B) appears at a different observation angle. The effect of appearing alone occurs.

  In addition, specular reflection in this specification refers to a phenomenon in which strong reflected light is generated at an angle substantially equal to the angle of incident light when light is incident on a substance at an incident angle. Diffuse reflection is This refers to a phenomenon in which weak reflected light is generated at an angle different from the angle of incident light when light is incident on a substance at an incident angle. For example, when an iris pearl ink is taken as an example, it appears colorless and transparent in the diffuse reflection state, but emits a specific interference color in the regular reflection state. Observing under specularly reflected light means observing from a viewpoint at a reflection angle that is substantially equal to the angle of light incident on the printed material, and observing under diffusely reflected light means a larger angle than the angle of light incident on the printed material. It refers to the state of observation at different angles.

  In the first embodiment, the number of latent image elements included in the latent image (5) is two. However, the number of latent images (5) is not limited to two. Instead, n latent image element groups can be provided according to the user's wishes. That is, if n latent image element groups are provided, the first latent image element group (5A) is constituted by the first latent image element (7A), and the second latent image element group (5B) is The second latent image element (7B) is configured, the nth latent image element group is configured by the nth latent image element, and the latent image elements (7A, 7B) are configured so as not to overlap each other. The latent image (5) may be formed by shifting the phase in one direction (S1). The saddle-shaped element (8) and the latent image element (7) are not limited to the image line, and may be pixels. Regarding specific configurations of these elements, configurations described in Japanese Patent No. 468283, Japanese Patent No. 4660775, and the like can be used.

  Next, as a second embodiment, an effect in which a specific image looks moving under specular reflection light, that is, a so-called moving image effect will be described with reference to FIGS. 9 to 12.

(Second embodiment)
FIG. 9 shows a special latent image body (1 ′) in the second embodiment. FIG. 9A shows a front view of the special latent image body (1 ′), and FIG. 9B shows a cross section along the line AA ′ of the special latent image body (1 ′). FIG. The special latent image body (1 ′) is formed by forming a print image area (3 ′) on a base material (2 ′). In addition, about the characteristic calculated | required by a base material (2 ') and a printing image area | region (3'), since it is the same as 1st embodiment, it abbreviate | omits.

  FIG. 10 shows an outline of the configuration of the print image area (3 ′) in the second embodiment. In the print image area (3 ′), as in the first embodiment, the reflective layer (4 ′) is superimposed on the base material (2 ′), and the latent image (5 ′) is superimposed thereon. A saddle-like element group (6 ') is overlaid on top. The characteristics required for the reflective layer (4 ′) and the bowl-shaped element group (6 ′) are the same as those in the first embodiment, and are therefore omitted.

  The latent image (5 ′) shown in FIG. 11 is greatly different from the latent image (5) of the first embodiment. The latent image (5 ′) of the second embodiment is a base image (12 ′) representing specific significant information, and a frame (13 ′) having a specific height (H) and width (W4). ), The base image (12 ′) included in the frame (13 ′) is taken out, and in the first direction (S1 direction in the figure), a specific line width (W1) with a specific compression rate is obtained. It consists of a set of latent image elements (7 ') compressed into The image line width and arrangement pitch of each latent image element (7 ') are the same, but the images inside are different. Each latent image element (7 ′) is continuously arranged in a first direction (S1 direction in the figure) at a specific pitch (P1), thereby forming a latent image (5 ′). A certain latent image element (7 ′) and an adjacent latent image element (7 ′) have a phase of the frame (13 ′) fitted to the base image (12 ′) by one pitch (P1). Since the image is shifted in the first direction (S1), the extracted base image (12 ′) is also shifted in the first direction (S1) by one pitch, and the images are slightly different. Note that the base image (12 ′) in the second embodiment is a “cherry blossom”.

  For a more specific method for producing the latent image (5 ′), the method described in Japanese Patent No. 5200284 may be used. The color, required characteristics, printing method, and the like of the latent image (5 ′) are the same as those in the first embodiment, and are therefore omitted. Further, the positional relationship of superposition of the latent image (5 ′) and the bowl-shaped element group (6 ′) is the same as in the first embodiment, and at least one of the latent image elements (7 ′). The part needs to overlap the bowl-shaped element (8 ').

  The effect of the special latent image body (1 ′) of the present invention having the above structure will be described with reference to FIG. When the special latent image body (1 ′) of the present invention is observed under diffuse reflected light, the entire latent image (5 ′) is visible in a specific color or invisible (not shown). ) As shown in FIG. 12A, when the special latent image body (1 ′) of the present invention is observed under specular reflection light, a certain observation angle (a slightly shallow observation angle in the first embodiment) ), “Sakura Petal” that is the base image (12 ′) formed in the latent image (5 ′) appears. As shown in FIGS. 12B and 12C, the special latent image body (1) of the present invention is observed under specular reflection light, and the observation angle is changed to change the base image ( 12 ′), the so-called moving image effect appears in which the phase of “Sakura Petal” changes in the first direction (direction S1 in the figure).

  The principle of changing the sampling position of the latent image (5 ′) and the principle of causing a difference in light quantity and color between the latent image (5 ′) and the reflective layer (4 ′) are the same as those in the first embodiment. The description is omitted because it is similar. In addition, regarding the principle that the base image (12 ′) is reproduced when a part of the latent image (5 ′) is sampled and the base image (12 ′) appears to move when the sampling position changes, Since it is the same as the principle described in Japanese Patent No. 5200284, it will be omitted.

  In the second embodiment, the latent image element (7 ′) and the saddle-shaped element (8 ′) are both formed in a straight line to produce a moving image effect. Etc., specifically, the concentric circles described in Japanese Patent Application No. 2013-023228 filed by the present applicant, or all of the image line directions continuously change, A configuration with curved lines forming various angles of view may be used, and the configuration is not limited to a straight line. In addition, each element group may be formed using a pixel shape instead of an image line shape, and not only a linear shape but also various curves such as a curved shape or a concentric shape may be used. Good. As a specific configuration, the configuration described in Japanese Patent No. 5200284 may be used. Therefore, the effect of the present invention is realized by the layer configuration of the light-reflective region and the bowl-shaped element group without being particular about the shape of either the latent image element or the bowl-shaped element. In the present invention, “line-like” means a state in which a plurality of elements are regularly arranged at a predetermined pitch.

  In the first embodiment and the second embodiment, the description has been given of the form in which each element is formed in a line shape and the pitch of each element is the same, but the third embodiment. In FIGS. 13 to 17, a description will be given of a mode in which each element has a pixel shape, each element has a different pitch, and an appearing image has a moire pattern.

(Third embodiment)
FIG. 13 shows a special latent image body (1 ″) in the third embodiment. FIG. 13A shows a front view of the special latent image body (1 ″), and FIG. 13B shows an AA ′ line of the special latent image body (1 ″). FIG. The special latent image body (1 ″) is formed by forming a print image region (3 ″) on a base material (2 ″). In addition, about the characteristic calculated | required by a base material (2 '') and a printing image area | region (3 ''), since it is the same as 1st embodiment, it abbreviate | omits.

  FIG. 14 shows an outline of the configuration of the print image area (3 ″) in the third embodiment. In the print image area (3 ″), the reflective layer (4 ″) is superimposed on the base material (2 ″) as in the first embodiment, and the latent image (5 ″) is formed thereon. Overlapping, and a saddle-like element group (6 ″) is superimposed on it. Since the characteristics required for the reflective layer (4 ″) are the same as those in the first embodiment, the description thereof is omitted.

  The latent image (5 ″) illustrated in FIG. 15 is significantly different from the latent image (5, 5 ′) of the first embodiment or the second embodiment. The latent image (5 ″) of the third embodiment has a circular latent image element (7 ″) having a constant width (W5) and a constant height (W6). It is continuously arranged at a specific pitch (P2) in the direction (S1 direction in the figure) and at a specific pitch (P3) in the second direction (S2 direction in the figure). The color of the latent image (5 ″), the required characteristics, the printing method, and the like are the same as those in the first embodiment, and are therefore omitted.

  FIG. 16 shows a bowl-shaped element group (6 ″) according to the third embodiment. The saddle-shaped element group (6 ″) has a circular-shaped saddle-shaped element (8 ″) having a constant width (W7) and a constant height (W8) in the first direction (direction S1 in the figure). ) At a specific pitch (P4) and continuously arranged at a specific pitch (P5) in the second direction (direction S2 in the figure). Since the color, required characteristics, printing method, and the like of the saddle-like element group (6 ″) are the same as those in the first embodiment, the description thereof is omitted.

  In the third embodiment, since the image appearing under the specular reflection light is a moire pattern, the pitch (P2, P3) in either direction of the latent image (5 ″) and the saddle-shaped element The pitch (P4, P5) in any direction of the group (6 ″) needs to be different in at least one set of pitches in the same direction of the respective images. That is, the values of pitch (P2) and pitch (P4) are different, or the values of pitch (P3) and pitch (P5) are different, but pitch (P2), pitch (P4) and pitch (P3) are different. Both values of pitch (P5) need to be different. Also, the value must not be a numerical value that allows one value to be divisible by the other value. When one value is a numerical value of about 80% to 120% (excluding 100%) of the other value, a moire pattern with high visibility and high moving image effect appears.

  Further, the positional relationship of the superposition of the latent image (5 ″) and the bowl-shaped element group (6 ″) is the same as in the first embodiment, and each latent image element (7 ″). At least part of it must overlap the bowl-like element (8 ″).

  The effect of the special latent image body (1 ″) of the present invention having the above structure will be described with reference to FIG. When the special latent image body (1 ″) of the present invention is observed under diffuse reflected light, the entire latent image (5 ″) is visible in a specific color or invisible ( Not shown). As shown in FIG. 17A, when the special latent image body (1 ″) of the present invention is observed under specular reflection light, a certain observation angle (slightly shallow observation in the first embodiment) At the angle, a moire pattern generated by the interference between the latent image (5 ″) and the saddle-shaped element group (6 ″) appears. As shown in FIGS. 17 (b) and 17 (c), the special latent image body (1) of the present invention is observed under specular reflection light, and the observed moire pattern is changed by changing the observation angle. There is a so-called moving image effect that appears to change in the first direction (S1 direction in the figure) and the second direction (S2 direction in the figure).

  For the principle that the sampling position of the latent image (5 ″) changes and the principle that a difference in light quantity and color occurs between the latent image (5 ″) and the reflective layer (4 ″), the first implementation Since it is the same as that of form, description is abbreviate | omitted. In addition, the principle that moire is generated by interference of simple lines or pixels is known, and the principle that moire patterns appear to move when the sampling position changes is described in Japanese Patent No. 4844894. Since it is the same as the principle, it is omitted.

  In the third embodiment, the latent image element (7 ″) and the saddle-shaped element (8 ″) are both formed in a pixel shape to produce a moving image effect. The shape may be used to form various lines. In the third embodiment, a simple moire pattern caused by interference between simple circular pixels has been described. However, the moire enlargement phenomenon described in Japanese Patent No. 4844894 and Japanese Patent No. 5131789 has been described. Significant information itself such as characteristic symbols, characters, and numbers may be moire using a phenomenon called (Moire Magication).

  In the first embodiment, the second embodiment, and the third embodiment, the book has a three-layer structure of a reflective layer (4), a latent image (5), and a bowl-shaped element group (6), respectively. Although the embodiment in which the special latent image body (1) of the invention is formed has been described, in the fourth embodiment, the special latent image has a two-layer structure of the latent image (5) and the bowl-shaped element group (6). A form for forming the image body (1) will be described with reference to FIGS.

(Fourth embodiment)
FIG. 18 shows a special latent image body (1 ″ ″) according to the fourth embodiment. FIG. 18A shows a front view of the special latent image body (1 ′ ″), and FIG. 18B shows an AA of the special latent image body (1 ′ ″). It is sectional drawing in a 'line. The special latent image body (1 ″ ″) is formed by forming a print image region (3 ″ ″) on a base material (2 ″ ″). In addition, about the characteristic calculated | required by the base material (2 "') or a printing image area | region (3"'), since it is the same as 1st embodiment, it abbreviate | omits.

  FIG. 19 shows an outline of the configuration of the print image area (3 ′ ″) according to the fourth embodiment. FIG. 20 shows the stacking order of each image in the print image area (3 ′ ″) in the fourth embodiment. In the print image area (3 ″ ″), the latent image (5 ″ ″) is superimposed on the base material (2 ″ ″), and the saddle-shaped element group (6 ″ ″) is superimposed thereon. It consists of In the fourth embodiment, unlike the previous embodiments, the reflection layer (4) is not present, and the latent image (5 ′ ″) itself is light / dark flip-flop or color flip-flop. Is provided. That is, the latent image (5 ′ ″) bears the light / dark flip-flop property or the color flip-flop property, which is the optical characteristic required for the reflective layer (4).

  Since the image line configuration of the latent image (5 ′ ″) and the image line configuration of the bowl-shaped element group (6 ′ ″) are the same as those in the first embodiment, description thereof will be omitted. The difference from the previous embodiments is an example in which the light-reflective region (not shown) is a latent image (5 ′ ″), and ink that forms the latent image (5 ′ ″). The material has optical characteristics of at least one of light / dark flip-flop and color flip-flop. In the fourth embodiment, a latent image (on a substrate having no light / dark flip-flop property or color flip-flop property, i.e., an area having no light / dark flip-flop property or color flip-flop property). 5 ″ ′) has excellent light / dark flip-flop properties or color flip-flop properties. When forming with printing ink, an image can be formed using a metallic pigment, a pearl pigment, or the like. However, in the case of forming with a general printing ink, compared to the reflective layer (4) formed with a film or the like, the reflected light tends to diffuse and the regular reflection angle tends to be widened to a wide angle. In some cases, since the effects of the present invention are reduced, the optical properties of the ink used must be selected with particular care. In this way, by providing the latent image (5 ′ ″) with the bright / dark flip-flop property and the color flip-flop property, the special latent image body (1 ′) of the present invention is formed without forming the reflective layer (4). ″ ′) Can be formed. Since the color, required characteristics, printing method, and the like of one saddle-shaped element group (6 ′ ″) are the same as those in the first embodiment, a description thereof will be omitted.

  Further, the positional relationship of the superposition of the latent image (5 ′ ″) and the bowl-shaped element group (6 ′ ″) is the same as that in the first embodiment, and each latent image element (7 ′ It is necessary that at least a part of "") overlaps with the bowl-shaped element (8 "").

  The effect of the special latent image body (1 ′ ″) of the present invention having the above structure will be described with reference to FIG. As shown in FIG. 21A, when the special latent image body (1 ″ ″) of the present invention is observed under diffuse reflection light, the entire latent image (5 ″ ″) is a specific image. Visible in color or invisible. As shown in FIG. 21B, when the special latent image body (1 ″ ″) of the present invention is observed under specular reflection light, a specific observation angle (slightly shallow in the first embodiment) At the (observation angle), the letter “A” of the alphabet which is the first significant information represented by the first latent image element group (5A ″ ″) in the latent image (5 ″ ″) appears. Further, as shown in FIG. 21B, the second latent image element group in the latent image (5 ′ ″) is obtained by changing the observation angle of the special latent image body (1 ″ ″). The letter “B” of the alphabet, which is the second significant information represented by (5B ′ ″), appears. Note that, in the special latent image body (1 ″ ″) of the fourth embodiment, the amount of light and color of the latent image (5 ″ ″) vary greatly, so that in the first embodiment. The effect is different in the density and color relationship of the appearing latent image (the density is inverted compared to the image appearing in the first form). That is, each significant information represented by the latent image (5 ′ ″) is bright and other areas are dark, or the color of each significant information represented by the latent image (5 ′ ″) is changed. The color of the area is visually recognized without change. As described above, the latent image (5 ′ ″) has a light / dark flip-flop property or a color flip-flop property, thereby having a two-layer structure without the reflective layer (4). Also, the image change effect appears.

  In the fourth embodiment, the latent image (5 ′ ″) has a light / dark flip-flop property or a color flip-flop property, and has a two-layer structure without the reflective layer (4). However, it is also possible to realize a two-layer structure in which the base material (2 ′ ″) has a light / dark flip-flop property or a color flip-flop property and does not have the reflective layer (4).

  In the fourth embodiment, the effect of changing the image based on the first embodiment is realized with a two-layer structure, but based on the second embodiment and the third embodiment. Needless to say, the latent image (5) and the base material (2) can be provided with bright and dark flip-flops or color flip-flops to produce a moving image effect with a two-layer structure.

  Hereinafter, examples of the special latent image body specifically produced in accordance with the above-described mode for carrying out the invention will be described in detail with reference to FIGS. 22 to 26. The present invention is not limited to this example. It is not limited to.

  FIG. 22 shows a special latent image body (1-1). FIG. 22A shows a front view of the special latent image body (1-1), and FIG. 22B shows an AA ′ line of the special latent image body (1-1). FIG. The special latent image body (1-1) is formed by forming a print image area (3-1) on a substrate (2-1). As the base material (2-1), general white coated paper (Esprit Coat FM manufactured by Nippon Paper Industries Co., Ltd.) was used.

  An outline of the configuration of the print image area (3-1) of the present invention is shown in FIG. The print image area (3-1) is formed by superimposing the latent image (5-1) on the reflective layer (4-1) and superimposing the saddle-like element group (6-1) thereon. The latent image (5-1) includes a first latent image element group (5A-1) and a second latent image element group (5B-1).

  FIG. 24 shows a latent image (5-1). A first latent image element (7A-1) having an image line width of 0.15 mm is arranged in a first direction (S1) at a pitch of 0.4 mm. A first latent image element group (5A-1) configured by being continuously arranged and a second latent image element (7B-1) having an image line width of 0.15 mm are arranged at a pitch of 0.4 mm. And a second latent image element group (5B-1) configured to be continuously arranged in the direction (S1). The first latent image element group (5A-1) and the second latent image element group (5B-1) are alternately arranged with a phase shift of 0.2 mm in the first direction (S1). They do not overlap each other. The first significant information represented by the first latent image element group (5A-1) is the letter “A” of the alphabet, and the second significant information represented by the second latent image element group (5B-1). Is the letter “B” of the alphabet.

  FIG. 25 shows a bowl-shaped element group (6-1). In the saddle-like element group (6-1), saddle-like elements (8-1) having an image line width of 0.35 mm are continuously arranged at a pitch of 0.4 mm in the first direction (direction S1 in the drawing). Become.

  First, a plain silver hologram is pasted on the substrate (2-1) to form a reflective layer (4-1), and then a white offset ink (best one white) is formed on the reflective layer (4-1). The latent image (5-1) is printed by a wet offset printing method using a gray ink obtained by adding a slight black pigment to GIGA T & K TOKA, followed by a transparent UV drying screen ink (UV TUB-000). The saddle-shaped element group (6-1) was printed by a screen printing method using Teikoku Ink Manufacturing Co., Ltd. The raised height of the bowl-shaped element (8-1) was about 15 μm.

  The effect of the special latent image body (1-1) of the present invention formed with the above configuration will be described with reference to FIG. When the special latent image body (1-1) of the present invention is observed under diffuse reflected light, as shown in FIG. 26 (a), the two latent image element groups (5A-1, 5B-1) It was almost invisible because it was gray that was substantially the same color as the reflective layer (4-1), and the entire printed image area (3-1) was visually recognized as gray that was the color of the reflective layer (4-1). As shown in FIG. 26B, when the special latent image body (1-1) of the present invention is observed at a specific angle under specular reflection light, the first latent image element group (5A-1) The letter “A” represented was black, and the other print image area (3-1) was visually recognized as white. Subsequently, as shown in FIG. 26 (c), when the special latent image body (1-1) of the present invention is observed at different angles under specular reflection light, the second latent image element group (5B-1) is observed. The letter “B” represented by () was black, and the other print image area (3 ′ ″ ″) was visually recognized as white.

  As described above, the two latent image element groups (5A-1, 5B-1) are invisible under diffuse reflection light, and the first latent image element group at a specific observation angle under regular reflection light. It was confirmed that the effect of independently appearing (5A-1) and the second latent image element group (5B-1) can be obtained.

1, 1 ′, 1 ″, 1 ″ ″, 1-1 Special latent image body 2, 2 ′, 2 ″, 2 ″ ″, 2-1 Substrate 3, 3 ′, 3 ″, 3 "", 3-1 Print image area 4, 4 ', 4 ", 4-1 Reflective layer 5, 5', 5", 5 "", 5-1 Latent image 5A, 5A " ′, 5A-1 First latent image element group 5B, 5B ″ ′, 5B-1 Second latent image element group 6, 6 ′, 6 ″, 6 ″ ″, 6-1 Box-shaped element group 7, 7 ', 7 ", 7"', 7-1 Latent image elements 7A, 7A "", 7A-1 First latent image elements 7B, 7B "", 7B-1 Second latent Image elements 8, 8 ′, 8 ″, 8 ″ ″, 8-1 Haze-shaped elements 9, 9 ′, 9 ″, 9 ″ ″, 9-1 Light sources 9 A, 9 B, 9 C Incident light 10, 10 ′, 10 ″, 10 ″ ″, 10-1 observer 11D, 11D ′ diffuse reflection light 11S, 11S ′ regular reflection light 12 ′ base image 13 ′ frame

Claims (3)

A printed image area is provided on at least a part of the substrate,
The printed image area is composed of a light reflective area having optical characteristics of at least one of light and dark flip-flops and color flip-flops, and a saddle-like element group stacked on the light reflective area,
The light reflective region is
i) On the base material itself having the optical characteristics or on the reflective layer having the optical characteristics formed on the base material,
A latent image formed by arranging a plurality of latent image elements having a different color from the base material itself or the reflective layer under regular reflection light at a predetermined pitch;
Or a latent image formed by arranging a plurality of latent image elements formed by removing a part of the reflective layer at a predetermined pitch, or
ii) a latent image formed by arranging the latent image elements having the optical characteristics on the base material in a line with a predetermined pitch;
The saddle-like element group is formed by arranging light-transmitting and saddle-like elements having bulges in the same line shape with the same or different pitch as the predetermined pitch,
At a specific viewing angle under specular reflection,
A special latent image body characterized in that the latent image is clearly and dynamically visually recognized by the light reflecting function of the light reflective region.   2. The special latent image body according to claim 1, wherein the latent image element is formed by compressing an image obtained by dividing a plurality of base images at a predetermined reduction ratio. The latent image has a latent image element group representing two significant information,
The latent image element group includes a first latent image element group in which first latent image elements are arranged in a line at the predetermined pitch to represent first significant information, and the first latent image. A second latent image element is arranged in a line at the predetermined pitch so as not to overlap with the element, and consists of a second latent image element group representing second significant information,
2. The special latent image body according to claim 1, wherein the first significant information and the second significant information appear independently and can be visually recognized according to an angle at which the substrate is tilted.

Images