JP6120082B2 - Latent image printed matter - Google Patents

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 has a moving image effect under specular reflection light. The present invention relates to a technique in which a latent image having a color appears.

  Security printed matter typified by banknotes, passports, securities, identification cards, and the like requires anti-counterfeiting technology in order to prevent duplication and forgery. In addition, among anti-counterfeiting technologies, as represented by watermarks and holograms, anti-counterfeiting technologies that do not require tools and can be used for authenticity discrimination by all persons who have printed materials are required. Yes.

  Among these, anti-counterfeiting technology having a so-called “moving visual effect” in which an image appears to move is particularly attracting attention. The visual effect of moving images that appear to move (hereinafter referred to as “moving image effects”) is easy to attract attention and difficult to counterfeit. It tends to be.

  There are technologies that use parallax barriers, lenticular lenses, holograms, etc. as well-known technologies that can realize the moving image effect. Taking advantage of the feature that these technologies can change the image with a slight angle change, There are already a wide range of security prints that have a three-dimensional visual effect and a moving image effect.

  However, when a moving effect is realized using a general parallax barrier or lenticular lens, a clear layer or lens is required, so the base material is almost limited to plastic, and the printed material has a certain thickness. (At least about 150 μm) is required, and it exceeds the thickness allowed for printed materials that are generally distributed. Therefore, it cannot be used for printed materials with limited thickness, and is used for other than plastic cards that allow a certain thickness. There is a tendency not to be.

  In addition, holograms can be finished very thin and are used for various security prints such as banknotes. However, compared with general prints, there are major problems in the complexity of the manufacturing process and high manufacturing costs. .

  In order to solve the above problems, the present applicant, when light is incident on a bowl-shaped image line having high gloss and swell, determines the incident light and normal line of the ridge-shaped image line having a bulge. An application has already been filed for a printing technique capable of forming a three-dimensional effect and a moving image effect using a phenomenon in which only a formed surface reflects light strongly (see, for example, Patent Document 1).

  The technology described in Patent Document 1 is a technology that can realize an excellent moving image effect by forming an image obtained by a stereoscopic image capturing method called integral photography by image processing. This technology can be formed with a thickness of about one-tenth of that of a parallax barrier or lenticular lens, and the manufacturing technology also makes use of conventional platemaking technology and printing technology to produce relatively complex images. It has an excellent characteristic that it can be expressed and a printed image having a moving image effect can be formed at the same cost as a general printed matter.

JP 2011-126028 A

  The technique described in Patent Document 1 has an image line type in which a latent image image line having an image line-shaped configuration is superimposed on an image line having a bulge, and a pixel-shaped structure on a pixel having a bulge. There are pixel types in which latent image pixels are superimposed. In the line type, the moving direction of the base image that appears as a latent image is limited to a direction that is almost perpendicular to the line direction of the rising line, so there are few variations in the movement of the latent image, and video effects It was a design constraint. In one pixel type, the direction of movement of the latent image is not limited, but the visibility of the latent image that appears due to pixel-pixel interference is greatly reduced compared to the image type. There was a problem to do.

  In addition, the conventional technique of Patent Document 1 also has a predetermined predetermined shape on a group of ridge-like image lines formed by arranging a plurality of brilliant image lines and luminescent pixels with a predetermined pitch. In this technique, latent image line groups and latent image pixel groups formed by arranging latent image lines and latent image pixels at a pitch are overlapped. In the latent image line group and latent image pixel group, the image information of the base image is compressed and applied, and the latent image formed on the saddle-like line group and the saddle-like pixel group is overlaid. Image information contained in the line group and latent image pixel group is reproduced under specular reflection light. In this technique, the compressed image information of the latent image group and the latent image pixel group is synonymous with image information indicating that the base image exists on a different phase in a specific direction. There is an effect that the base image that appears as a latent image below appears to move. However, the technique of Patent Document 1 always forms a non-image portion (region where the base material is exposed) penetrating the print image region in a specific direction between the respective glitter image lines and pixels. The Since the latent image line group and the latent image pixel group overlapping the non-image line part are not visualized at any angle under specular reflection light, the base image included in the latent image line group and the latent image pixel group is not visible. The specific position information of the image is not reproduced, that is, the movement width of the reproduced latent image relative to the movement width of the original latent image included as image information in the latent image line group. Will get smaller. For this reason, the saddle-like image line group and the latent-image image line group need to be accurately aligned and printed at appropriate positions so that they do not overlap with each other. Most of the groups consist of different processes using different printing presses with different printing methods, and part of the latent image line group overlaps the non-image area, and the latent image line group There is a problem that at least a part of the position information of the included base image is lost, and as a result, the width of the motion of the appearing base image is reduced.

  The present invention aims to solve the above-mentioned problems, and there is no restriction on the direction of movement of the appearing latent image, the visibility is good, and the latent image is obtained even when the alignment is shifted from the proper position. Latent image printed matter that has the effect of reproducing all the information contained in the image line group and its manufacturing method, which does not require high printing accuracy and special printing method, such as offset printing method and screen printing It is formed by a combination of general techniques, and can be manufactured more easily.

  The present invention has a print image region composed of a first image and a second image arranged on the first image at least partially on the substrate, and the first image is a specular reflection light. A pixel-like first element having a three-dimensional curved surface shape having at least one of a light-dark flip-flop property and a color flip-flop property that emits a first color under the first direction and the first A plurality of first elements adjacent to each other in the first direction are arranged in a checkered pattern in the second direction intersecting the direction, and the first elements adjacent to each other in the first direction are in the first direction. The center between the adjacent first elements coincides with the center of the first element adjacent in the oblique direction, and the first element adjacent to the first element is adjacent to the first element adjacent in the oblique direction. The first elements that are diagonally adjacent to each other are arranged in the first direction. The first pitch is less than or equal to the length of the first element in the first direction, and the second image is the first image during regular reflection of the first image. A first latent image line having a second color different from the color and formed by compressing an image obtained by dividing the first base image with a predetermined compression rate is formed at a first pitch. When there are a plurality of first latent images arranged in the first direction and observed under diffuse reflected light, the second image is invisible and light is reflected at a specific angle under specularly reflected light. A latent image printed matter latent image printed matter characterized in that a first base image appears when incident, and the first base image appears to move in a first direction by changing an observation angle.

  In the present invention, the first elements diagonally adjacent to each other are arranged with a second pitch shift in the second direction, and the second pitch is equal to or less than the length of the first element in the second direction. The second image is a second latent image having a different shape, which is produced by compressing an image obtained by dividing the second base image having the same shape as or different from the first base image at a predetermined compression rate. When the second latent image is further arranged in the second direction at a second pitch, and the second latent image is incident at a specific angle under specular reflection light, the second base image Appears, and the second basic image appears to move in the second direction by changing the observation angle.

  The present invention is the latent image print, wherein the first element has a circular shape.

  The latent image printed matter of the present invention is different from both the image type and pixel type of the prior art, the first element having a bulge is a pixel shape, the first image is constituted by a set of pixels, The second element overlying it is an object line shape, and the second image is formed by a set of object lines. Unlike the image line type, the first image does not have a specific image line direction, so there is no restriction on the direction of movement of the latent image, and the direction of movement can be designed in an arbitrary direction. Further, since the pixel and the image line are overlapped with each other, the visibility is not extremely lowered as in the conventional pixel type.

  Since the latent image printed material of the present invention is formed by arranging the first elements having bulges in a checkered pattern according to a specific rule, there is no non-image portion that penetrates the print image region in a specific direction. For this reason, even when the first image and the second image are formed so as to be deviated from the normal positions and overlapped due to manufacturing irregularity or the like, all the latent image lines always overlap the first element. As a result, the effect that all the latent image information included in the second image is reproduced under regular reflection light can be ensured, and the width of the movement of the latent image is not reduced.

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

(A) shows the front view of the latent image printed material in this invention, (b) shows a side view. The outline | summary of a structure of the latent image printed matter in this invention is shown. The 1st image in this invention is shown. The details of the arrangement of pixels in the first image of the present invention are shown. A part of image which comprises the 2nd image in this invention is shown. The enlarged view of a part of image which comprises the 2nd image in this invention is shown. A part of image which comprises the 2nd image in this invention is shown. The enlarged view of a part of image which comprises the 2nd image in this invention is shown. The positional relationship of the overlap of the 1st image and 2nd image in this invention is shown. (A) shows the image visually recognized by an observer when the latent image printed material in the present invention is observed under diffuse reflected light, and (b) shows a specific angle of the latent image printed material in the present invention under specularly reflected light. (C) shows an image visually recognized by the observer when the latent image printed material according to the present invention is observed at a specific angle different from (b). Show. (A) shows the front view of the latent image printed material in this invention, (b) shows a side view. The outline | summary of a structure of the latent image printed matter in this invention is shown. The 1st image in this invention is shown. The details of the arrangement of pixels in the first image of the present invention are shown. A part of image which comprises the 2nd image in this invention is shown. The positional relationship of the overlap of the 1st image and 2nd image in this invention is shown. The positional relationship of the overlap of the 1st image and 2nd image in this invention is shown. (A) shows the image visually recognized by the observer when the latent image printed material in the present invention is observed under diffuse reflected light, and (b) to (e) show the latent image printed material in the present invention under regular reflected light. When observed at a specific angle, an image visually recognized by an observer when observed at different specific angles is shown. (A) shows the front view of the latent image printed material in this invention, (b) shows a side view. The outline | summary of a structure of the latent image printed matter in this invention is shown. The 1st image in this invention is shown. A part of image which comprises the 2nd image in this invention is shown. A part of image which comprises the 2nd image in this invention is shown. The positional relationship of the overlap of the 1st image and 2nd image in this invention is shown. The positional relationship of the overlap of the 1st image and 2nd image in this invention is shown. (A) shows the image visually recognized by the observer when the latent image printed material in the present invention is observed under diffuse reflected light, and (b) to (e) show the latent image printed material in the present invention under regular reflected light. When observed at a specific angle, an image visually recognized by an observer when observed at different specific angles 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 latent image printed material (1) according to the present invention. FIG. 1A shows a front view of the latent image printed matter (1), and FIG. 1B shows a cross-sectional view of the latent image printed matter (1) along the line AA ′. The latent image print (1) is formed by forming a print image region (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. The print image area (3) is formed by superimposing the second image (5) on the first image (4). The laminated structure of the two images must be a layer structure in which the second image (5) overlaps the first image (4). In the first embodiment, the second image (5) will be described in a form having two latent image images, the first latent image (5A) and the second latent image (5B). Basically, the second image (5) may have at least one latent image. The first latent image (5A) and the second latent image (5B) included in the second image (5) are latent image images that appear under specular reflection light.

  First, the first image (4) will be specifically described. FIG. 3 shows a first image (4). The first image (4) includes a plurality of pixel-like first elements (6) having a bulge in a predetermined direction at a predetermined pitch. It is arranged. The first element (6) in the first embodiment has a hook-like cross section and a square shape in plan view. However, the first element (6) is not limited to this shape. The shape of (6) may be any shape as long as it is a three-dimensional curved surface shape, that is, a structure having a bulge and is symmetric with respect to at least one specific direction. It has not only a hemispherical shape with a raised center but also a three-dimensional curved surface shape such as a semi-elliptical sphere, a symmetrical shape with a certain curvature such as a bowl shape, and a polygonal column such as a triangular prism, pentagonal prism, hexagonal prism, etc. However, the planar shape as shown in the second embodiment to be described later may be a shape having a curve such as a circle or an ellipse, a polygon such as a triangle, a pentagon, or a hexagon. Note that the three-dimensional structures of all the first elements (6) constituting the first image (4) need to be the same.

  The first image (4) is formed by “arraying in a checkered pattern” in which the first element (6) has a shape conforming to the checkered pattern. The “arranged in a checkered pattern” referred to in this specification is a state in which the elements are arranged in a pattern similar to a general checkered pattern, but is different from a state in which the elements are arranged in a complete checkered pattern. Specifically, “arranged in a checkered pattern” means that “the first elements (6) having the same shape are alternately arranged at a predetermined pitch like a checkered pattern, and in a specific direction (in the embodiment, , First elements adjacent to each other diagonally up and diagonally at an intermediate position in a specific direction between the first element (6) and the first element (6) adjacent to each other in the first direction (S1)) (6) refers to a state in which the center of a specific direction is located and the side and end of each first element (6) are arranged so as not to contact each other. Other conditions that must be satisfied in the arrangement of the first element (6) constituting the first image (4) will be described later. In the description of the specific configuration in the embodiment, the specific direction is the first direction (horizontal direction: S1 direction in the drawing), and the direction intersecting the specific direction is the second direction (vertical direction: drawing). Middle S2 direction). In this example, the first direction (S1) is the horizontal direction, and the second direction (S2) is the vertical direction, but the first direction (S1) and the second direction (S2) intersect. Any direction is acceptable as long as it is a relationship.

  The first image (4) is a quadrangle whose element length in the first direction (direction S1 in the figure) is W1 and whose element length in the second direction (direction S2 in the figure) is W2. The first elements (6) are arranged in a checkered pattern at a specific pitch (P1) in the first direction (S1) and at a specific pitch (P2) in the second direction (S2). Further, the first image (4) may have any color, and may be transparent or translucent. The pitch (P1) and the pitch (P2) may be the same value or different values. In consideration of image line reproducibility in printing, image resolution required for the latent image, etc., the length and each pitch (P1, P2) of the first element (6) in the first direction (S1). ) Both in the range of 0.05 mm to 5 mm.

  In the arrangement of the first elements (6) constituting the first image (4), conditions that must be satisfied in addition to the checkerboard arrangement will be specifically described. First, in addition to arranging the first elements (6) in a checkered pattern, the following positional relationship with respect to at least one specific direction must be satisfied. The positional relationship that the element length (W1) of the first element (6) and the arrangement pitch (P1) in the first direction (S1) must be satisfied will be specifically described with reference to FIG. FIG. 4B is an enlarged view of three first elements (6A, 6B, 6C) adjacent to each other in an oblique direction, which are basic repeating structures in a checkered pattern arrangement. It can be considered that the first image (4) in the first embodiment is formed by repeatedly arranging the basic structure shown in FIG. 4B vertically and horizontally. Of the three first elements (6A, 6B, 6C), the first element (6A) at the left end and the first element (6C) at the right end are the same as the pitch (P1) × 2 (twice). The phase is shifted in one direction (S1), and there is no shift in the second direction (S2). This positional relationship between the first element (6A) at the left end and the first element (6C) at the right end is referred to as a positional relationship “adjacent in the first direction (S1)” in this specification. On the other hand, the center in the first direction (S1) of the first element (6B) located at the top is the center in the first direction (S1) of the first element (6A) at the left end and the center in the first direction (S1). It lies on an extension of a straight line extending in the second direction (S2) through a point equidistant from the center in the first direction (S1) of one element (6C). That is, the center of the first element (6B) positioned at the top is shifted by the pitch (P1) in the first direction (S1) with reference to the center of the first element (6A) at the left end. In the second direction (S2), the phase is shifted by the pitch (P2). The positional relationship between the first element (6B) and the first element (6A) and the positional relationship between the first element (6B) and the first element (6C) are referred to as “diagonally adjacent to each other” in this specification. Is called a positional relationship.

  In constructing the first image (4), at least one direction (in the first embodiment, the first direction (in the first embodiment) in the positional relationship between the three adjacent first elements (6A, 6B, 6C)). Positions at which the phases of the respective ends in the first direction (S1) of the three adjacent first elements (6A, 6B, 6C) are in complete contact with or overlap with S1)) It is essential to have a relationship. Specifically, the phase in the first direction (S1) of the right side (6AR) of the leftmost first element (6A) is the same as that of the left side (6BL) of the first element (6B) located at the top. The phase in the first direction (S1) of the right side (6BR) of the upper first element (6B) that is present at the same position or on the right side is the first element (6C) located on the rightmost side. Must be located at the same position as the left side (6CL) or on the right side. In the case of complete contact, the phases of 6AR and 6BL and 6BR and 6CL with respect to the first direction (S1) coincide with each other, and as shown in FIG. Is located on the left side of 6AR (in the direction of the first element (6A) having the 6AR side), and has a region overlapping each of 6BL and 6AR, and 6CL is on the left side of 6BR (6BR 6CL has a region overlapping each part of 6BR by being positioned in a certain direction of the first element (6B) having the sides. In order to satisfy this positional relationship, the phase difference in the first direction (S1) between the first elements diagonally adjacent (for example, the first element (6A) and the first element (6B)). (Pitch (P1)) needs to be less than or equal to the length (element length (W1)) in the first direction (S1) of the first element (6). This is an essential condition in the arrangement of the first element (6) forming the first image (4) other than arranging in a checkered pattern. Furthermore, the overlapping area in the present invention is meant to include not only a partially overlapping area but also a contact area.

  In summary, the requirement for the arrangement of the first element (6) in the first image (4) is that the first element (6) is arranged in a checkered pattern, that is, “the same shape. The first elements (6) are alternately arranged vertically and horizontally like a checkerboard pattern, diagonally above and diagonally below the intermediate phase in a specific direction between the first elements (6) adjacent to the left and right Are arranged in such a configuration that the center of the first element (6) adjacent to each other is positioned, and any side or end of each first element (6) does not contact each other. " And “the phase difference (pitch (P1)) in the specific direction between the first elements diagonally adjacent to each other is the length (element length (W1) of the first element (6) in the specific direction. )) The following conditions should be satisfied.

  The first image (4) needs to have a specific color under diffuse reflected light, or be transparent or translucent, and have light and dark flip-flop properties and / or color flip-flop properties. In the present invention, “light / dark flip-flop property” refers to a property in which only the brightness of a material changes when light is incident on the material, and “color flip-flop property” refers to a property in which light is incident on a material. It refers to the property of changing the hue of a substance. Examples of inks used in printing having light and dark flip-flop properties include metallic metallic inks such as gold and silver, and glossy colored inks. Substances that are generally felt glossy have bright and dark flip-flop properties. For example, silver ink looks only dark gray under diffusely reflected light that does not strongly reflect light, but appears lighter gray or white under specularly reflected light that strongly reflects light. As described above, the ink having the “light / dark flip-flop property” changes only in lightness under specular reflection light.

  Examples of inks used for printing that have one color flip-flop property include pearl ink, liquid crystal ink, OVI, and CSI (Color Shifting Ink). Many inks have an object color, but the 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. As described above, the ink having the “color flip-flop property” changes in hue under specular reflection light.

  The first image (4) having the above-described configuration is formed by a printing method capable of forming a raised portion on the print image line. In order to ensure a certain level of visibility in the appearing latent image, the raised height of the first element (6) needs to be 3 μm or more, so it is desirable to form it by screen printing or intaglio printing. Even in the case of gravure printing, flexographic printing, letterpress printing, IJP, etc., it is possible to form such a raised height of the image line. Moreover, there is no restriction | limiting in particular about the upper limit of the height of swell, but it considers stability, friction resistance, distribution | circulation appropriateness, etc. when loading in large quantities, and shall be 1 mm or less.

  Next, the second image (5) will be specifically described. FIG. 5 shows a first latent image (5A) that is one of the two latent images included in the second image (5). In the first latent image (5A), the first latent image line (7A) having the line width W3 is the same as the arrangement pitch in the first direction (S1) of the first element (6). A plurality of pitches (P1) are arranged in the first direction (S1).

  Here, the configuration of the second image (5) will be described while explaining the production method. The basic configuration and manufacturing method are the same as those described in Japanese Patent Application Laid-Open No. 2011-126028. FIG. 6 shows a first base image (8) representing “cherry blossom petals” which is an image that is the basis of the first latent image line (7A) of the first latent image (5A). Each of the first latent image lines (7A) has a different shape, but the base image is the first base image (8) that represents the same “sakura petal”. Each first latent image line (7A) is obtained by applying a first frame (9A) having a width W4 and a height H1 to the base image (8), and in the first frame (9A). The first base image (8) included in the image is compressed in the first direction (S1), and the width in the first direction (S1) is set to W3. The width W4 in the first direction (S1) of the first frame (9A) is smaller than the width in the first direction (S1) of the first base image (8), and the second direction ( The height H1 of S2) needs to be larger than the height in the second direction (S2) of the first base image (8). The first latent image lines (7A) adjacent to each other shift the position of the first frame (9A) with respect to the first base image (8) by a constant pitch (P1) in the first direction (S1). Images compressed at the same rate. In this specification, the ratio of W3 / W4 is referred to as the compression ratio of the first latent image (5A). By changing this compression ratio, the size of the movement of the latent image and the intensity of the perspective are controlled. can do. The method for controlling the magnitude of movement and the perspective according to the compression rate is the same as the method described in Japanese Patent Application Laid-Open No. 2011-126028.

  FIG. 7 shows a second latent image (5B) which is one of the two latent images included in the second image (5). In the second latent image (5B), the second latent image line (7B) having the line width W5 is the same as the arrangement pitch in the first direction (S1) of the first element (6). A plurality of pitches (P1) are arranged in the first direction (S1).

  The configuration and production method of the first latent image (5A) and the second latent image (5B) are different. Here, the structure of the second latent image (5B) will be described while explaining the production method. FIG. 8 shows a first basic image (8) representing “cherry blossom petals” which is an image that is the basis of the second latent image line (7B) of the second latent image (5B). The first base image (8) of the second latent image (5B) in the present embodiment has the same shape as the first base image (8) of the first latent image (5A). They can be the same or different. Each second latent image line (7B) is obtained by applying a second frame (9B) having a width W6 and a height H2 to the first base image (8), so that the second frame ( 9B) the first basic image (8) included in the mirror is once mirror-reversed in the first direction (S1). The presence of this mirror reversal step is the difference between the construction and manufacturing method of the first latent image (5A) and the second latent image (5B). The mirror-inverted image is compressed in the first direction (S1) and the width in the first direction (S1) is set to W5, thereby creating the second latent image line (7B). The width W6 in the first direction (S1) of the second frame (9B) is smaller than the width in the first direction (S1) of the first base image (8), and the second direction ( The height H2 of S2) needs to be larger than the height of the first base image (8) in the second direction (S2). The adjacent second latent image line (7B) shifts the position of the second frame (9B) with respect to the first base image (8) by a constant pitch (P1) in the first direction (S1). Images compressed at the same rate. The size of the first frame (9A) and the size of the second frame (9B) may be the same or different. In this specification, the ratio of W5 / W6 is referred to as a second compression rate. The first compression rate and the second compression rate may be the same or different.

  In the latent image printed matter (1) of the present invention, the arrangement pitch of the first element (6) and the arrangement pitch of the latent image line (7) need to coincide with the compression direction of the latent image. That is, in the first embodiment, since the latent image line (7) is produced by compressing in the first direction (S1), each element in the first direction (S1). The pitch of P1 is P1 and all have the same value. The element lengths (W3, W5) in the first direction (S1) of each latent image line may be the same or different. Further, from the viewpoint of production stability, it is preferable to form both the image line width and the pitch of the latent image line in the range of 0.01 mm to 5 mm.

  For each latent image line (7), the raised height is not essential, and therefore, it may be formed by any printing method. In view of productivity, it is most preferable to form by offset printing. In order to visualize the latent image under the specular reflection light, the latent image line (7) needs to have a color difference with the first element (6) at the time of regular reflection, and at least the color at the time of reflection is It must be different from the color at the time of regular reflection of the first element (6). Further, since the latent image line (7) is formed so as to overlap the first element (6), light incident on the first element (6) below the latent image line (7) is formed. And the color change of the first element (6) that occurs under specular reflection light is suppressed. For this reason, since the color at the time of regular reflection of the first element (6) is more greatly different depending on whether or not the latent image lines (7) overlap, in order to further improve the visibility of the latent image. It is desirable that the latent image line (7) has a high light blocking property.

  Therefore, when the latent image line (7), that is, the second image (5) is formed by printing, it is desirable to use a matte ink with low gloss. Further, when a functional material having a high light blocking property such as titanium is blended with these inks, a higher effect can be obtained. Moreover, since it is desirable that the latent image line (7) is invisible under diffuse reflection light, it is desirable that the latent image line (7) has a colorless and translucent color. However, in order to facilitate quality control, the ink is colored by adding a slightly colored pigment, or a fluorescent pigment is added to the transparent ink to manage abnormalities such as reprinting and printing defects using a UV lamp. You can also.

  The latent image line (7) may be formed not only with ink but also with a printer. It can also be formed by cutting and applying the image corresponding to the latent image line (7) to the first element (6). Such cutting can be easily performed by using a laser processing machine. The first element (6) irradiated with the laser is often required for the latent image line (7) in the present invention because the light-dark flip-flop property and the color flip-flop property are lost or greatly deteriorated. The characteristic to do can be provided. 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.

  The second image (5) is formed on the first image (4) having the above configuration. The positional relationship between the two images at this time will be described with reference to FIG. Preferably, the first image (4) and the second image (5) may be overlapped in parallel with the first direction (S1). At this time, the latent image included in the second image (5) is always visualized if there is no angle shift between the first image (4) and the second image (5). Since it has a structure, there is no problem even if a displacement occurs in the first direction (S1) and / or the second direction (S2).

  Each latent image line (7) always overlaps the slope of a specific angle on the surface of each first element (6). Since the first image (4) is formed by arranging the first elements (6) in a checkered pattern, the first image (4) does not overlap the first element (6) as shown in the side view of FIG. The latent image line (7) that overlaps the substrate (2) is also present in part, but a situation in which one entire latent image line does not overlap the first element (6) does not occur. The latent image included in the second image (5) is ensured to be visualized at any observation angle under regular reflection light.

  The effect of the latent image printed material (1) of the present invention having the above structure will be described with reference to FIG. As shown in FIG. 10 (a), when the latent image print (1) of the present invention is observed under diffuse reflected light, none of the latent image included in the second image (5) is invisible. Thus, the entire print image area (3) is observed in a specific color, or cannot be observed because it is transparent or translucent. As shown in FIG. 10B, when the latent image print (1) of the present invention is observed under specular reflection light, at a specific observation angle (slightly shallow observation angle in the first embodiment), Two cherry blossom petal images, which are latent images, appear. As shown in FIG. 10 (c), when the latent image print (1) of the present invention is observed under specular reflection light, a different observation angle (in the first embodiment) from the observation angle in FIG. 10 (b). When the inclination is changed to a slightly deep observation angle), the petals of the cherry blossoms appearing in parallel with the first direction (S1) move, and the direction of movement of each petal moves in the opposite direction.

  The principle that produces the above effect will be described. First, the principle of the effect that the first latent image (5A) and the second latent image (5B) become invisible under the diffusely reflected light shown in FIG. 10 (a) will be described. Under diffuse reflection light, the second image (5) is transparent or translucent because there is no light directly incident on the second image (5) and no strong specular reflection light is emitted. . Therefore, the first latent image (5A) and the second latent image (5B) are completely invisible or almost invisible under diffuse reflection light.

  Next, the principle that the latent image (5) appears at a specific observation angle under specular reflection light and each image appears to move by changing the observation angle will be described below. Since the first element (6) constituting the first image (4) has at least one of color flip-flop property and light-dark flip-flop property, light is emitted to the print image region (3). When incident, the first element (6) reflects light strongly and regularly. Since the first element (6) has a three-dimensional rise, when light enters, only the surface of the image line that forms a normal line with the incident light strongly reflects the light. In addition, a latent image line (7) obtained by compressing the first base image (8) in the first direction (S1) is superimposed on the surface of the line of each first element (6). Unlike the first element (6), the latent image line (7) constituting the image (5) has no characteristic of strongly reflecting light, so that the first line that is normal to the incident light is formed. While the very narrow surface of the element (6) reflects the light, the latent image line (7) superimposed on the surface suppresses the reflection of the light, so that the intensity of the reflected light is generated. As a result, only the information of the latent image line (7) overlying the first element (6) in a very narrow range that is normal to the incident light is sampled and visualized by the intensity of the light. . In the first image (4), the first elements (6) having swells are continuously arranged at the pitch P1, and the surface of the image line that is normal to the incident light exists for each pitch P1. As a result, the latent image line (7) superimposed on the first element (6) is sampled with a period of the pitch P1 and visualized by the intensity of the reflected light.

  Since the latent image line (7) is formed by compressing the entire first base image (8) in the first direction (S1), only a part of each latent image line (7) is extracted. Part of the first base image (8) is reproduced. In addition, a latent image line (7) formed by compressing the information of the first base image (8) by shifting the information by the pitch P1 is overlaid on each first element (6). When all the latent image lines (7) superimposed on the first element (6) are sampled at the pitch P1, the first base image (8) is reproduced. Based on the above principle, the latent image (5) is visualized as the first base image (8) under regular reflection light.

  Further, when the observation angle is changed under specular reflection light, the angle of light incident on the latent image printed material (1) changes. In this case, the image surface of the first element (6) that is normal to the incident light changes with the change in the angle of the incident light, and the phase of the latent image image (7) that is sampled is shifted accordingly. The latent image line (7) consists of information obtained by compressing the entire first base image (8) in the first direction (S1). This corresponds to the image information moved in the direction (S1) by the width of the frame. Therefore, when the sampling phase is shifted with respect to the latent image line (7) of the first base image (8), The phase of one basic image (8) changes in the first direction (S1). For this reason, there is an effect that the latent image that appears when the observation angle is changed under specular reflection light moves in the first direction (S1).

  The first latent image (5A) and the second latent image (5B) have opposite directions of movement because the second latent image line (7B) is the first base image (7B). This is due to the fact that 8) is mirror-inverted and then compressed.

  The arrangement structure of the first elements (6) in the first image (4) of the latent image print (1) of the present invention is at least one direction (in the first embodiment, the second direction ( This structure is intended to prevent non-image lines that completely penetrate the print image area (3) from being formed in S2)). When the first image (4) is configured in such an arrangement, even when the second image (5) is overlapped and shifted in the first direction (S1), the entire latent image line (7) is displayed. It is included in the second image (5) because it does not overlap the non-image area and any latent image line (7) always overlaps any of the first elements (6). Thus, it is possible to ensure that all the information of the first basic image (8) is always reproduced at any observation angle under regular reflection.

  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, and 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.

(Second embodiment)
Subsequently, as a second embodiment, the configuration of the first element (6) and the configuration of the latent image line (7) are different examples, and the direction of movement of the first base image (8) is changed. An example in which each is different will be described.

  FIG. 11 shows a latent image print (1 ') according to the present invention. FIG. 11A is a front view of the latent image printed material (1 ′), and FIG. 11B is a cross-sectional view of the latent image printed material (1 ′) taken along the line AA ′. The latent image print (1 ') is formed by forming a print image region (3') on a substrate (2 ').

  An outline of the configuration of the print image area (3 ') of the present invention is shown in FIG. The print image area (3 ') is formed by superposing the second image (5') on the first image (4 ') having a three-dimensional curved surface structure as in the first embodiment. In the second embodiment, the second image (5 ') has two latent image images, a first latent image (5A') and a second latent image (5B ').

  The first image (4 ′) shown in FIG. 13 and FIG. 14 is a checkered pattern of the first element (6 ′) having a bulge, similar to the first image (4) of the first embodiment. Although arranged, the planar shape of each first element (6 ′) is not a quadrangle, but a circle having a width W1 and a height W2. The planar shape of the first element (6 ') is preferably circular, but may be a polygon such as a pentagon, hexagon, or octagon.

  Even when the shape of the first element (6 ′) is a circle, the length (W1) of the first element (6 ′) in the first direction (S1) (corresponds to the diameter in the case of a perfect circle) If the phase difference (pitch (P1)) in the first direction (S1) between the first element (6A ′) and the first element (6B ′) obliquely adjacent to each other is smaller than A first image (4 ′) can be formed. Even in such a configuration, the phase of the right end (6AR ′) of the first element (6A ′) located on the left is in phase with the phase of the left end (6BL ′) of the first element (6B ′) that is diagonally adjacent. The first phase (S1) has the same phase or exists on the right side, and the phase of the right end (6BR ') of one first element (6B') It is the same phase with respect to the first direction (S1) with respect to the phase of the right end (6CL ′) of (6C ′), or is present on the right side, and a specific direction (second direction (S2)) ) Does not have a non-image line that completely penetrates the print image area (3 ′).

  In the example shown in the second embodiment, not only the first direction (S1) but also the second direction between the first elements diagonally adjacent to the second direction (S2). The phase difference (pitch (P2)) in (S2) is set to be equal to or less than the length (element length (W2)) in the second direction (S2) of the first element (6 ′), and adjacent to each other diagonally. The first element (6) has a region that partially overlaps in the second direction (S2). For this reason, in the first image (4 ′) of the present embodiment, not only the second direction (S2) direction but also the print image region (3 ′) in the first direction (S1) direction. The configuration has no non-drawing line that completely passes through.

  Next, the second image (5 ′) will be specifically described. FIG. 15 shows the second latent image (5B ′). The first latent image (5A ′), which is another latent image included in the second image (5 ′), is the same as the image described in the first embodiment. Omitted.

  The second latent image line (7B ′) constituting the second latent image (5B ′) shown in FIG. 15 is the second base having the same shape as the first base image (8 ′). An image in which a second frame (not shown) having a height W6 and a width H2 is applied to the image is compressed in the second direction (S2). Basically, it has a configuration in which the compression direction of the first latent image (5A ') is changed. The width of each second latent image line (7B ′) (the length in the second direction (S2)) is W5, and the arrangement pitch is the first element in the first image (4 ′). (6 ′) is the arrangement pitch P2 in the second direction (S2), and is arranged continuously in the second direction (S2). As described above, the second image (5 ′) in the second embodiment includes the first latent image line (7A ′) and the first latent image line (7A ′). And a second latent image line (7B ′) having a different compression direction of one base image (8 ′).

  A second image (5 ') is superimposed on the first image (4') having the above-described configuration. The positional relationship of the two images at this time is as shown in FIGS. 16 and 17, and the second image (5 ′) is superimposed on the first image (4 ′). Become. As in the first embodiment, if there is no angular shift (final) between the first image (4 ′) and the second image (5 ′), the second image (5 ′) is always displayed. Since the included latent image is visualized, there is no problem even if a positional shift occurs in the first direction (S1) and the second direction (S2). In this example, the first latent image line (7A ′) and the second latent image line (7B ′) are arranged so as not to overlap, but the first latent image line (7A ′) and the second latent image line (7A ′) are not overlapped. The two latent image lines (7B ′) may overlap, and even if they overlap, the visibility of the latent image is not affected (not shown).

  The effect of the latent image printed material (1 ') of the present invention having the above structure will be described with reference to FIG. As shown in FIG. 18 (a), when the latent image print (1 ′) of the present invention is observed under diffuse reflected light, any of the latent image contained in the second image (5 ′) is invisible. Thus, the entire print image area (3 ′) is observed in a specific color, or cannot be observed because it is transparent or translucent. When the latent image print (1 ′) of the present invention is observed under specular reflection light, the latent image represented by the first latent image (5A ′) and the latent image represented by the second latent image (5B ′) are displayed. When two cherry petals of the image image appear (not shown) and the side B is tilted in the depth direction as shown in FIG. 18B, the latent image represented by the first latent image (5A ′) Does not move, and the latent image represented by the second latent image (5B ′) appears to move toward the B ′ side. Further, as shown in FIG. 18C, when the latent image print (1 ′ ″) of the present invention is tilted in the back direction with the A ′ side under specular reflection light, the second latent image (5B ′) The latent image represented by () does not move, and the latent image represented by the first latent image (5A ′) appears to move toward the A ′ side. Further, as shown in FIG. 18D, when the latent image printed matter (1 ′ ″) of the present invention is tilted B ′ side in the back direction under specular reflection light, the first latent image (5A ′) The latent image represented by () does not move, and the latent image represented by the second latent image (5B ′) appears to move toward the B side. Further, as shown in FIG. 18E, when the latent image printed material (1 ′) of the present invention is tilted in the back direction under the specularly reflected light, the second latent image (5B ′) is represented. The latent image does not move, and the latent image represented by the first latent image (5A ′) appears to move toward the A side.

  As described above, the direction of movement of each latent image can be freely designed by changing the compression direction of the latent image line (7). In the second embodiment, the movement direction of the latent image is designed in the two directions of the first direction (S1) and the second direction (S2), but the first direction (S1), Not only the two directions of the second direction (S2) but also the third direction and the fourth direction, which are arbitrary directions, are set, and a latent image that moves in the third direction and the fourth direction is formed. May be. In order to make the phase difference in the specific direction between the first elements obliquely adjacent to the plurality of directions equal to or less than the length of the first element (6) in the specific direction, the first element The shape of (6) is preferably a polygon such as a circle, rhombus, triangle, pentagon, hexagon, or octagon. Further, in this example, as an example in which the visibility of the latent image is preferable, the arrangement direction of the respective latent image lines forming the first latent image (5A ′) and the second latent image (5B ′). In the above example, two latent image images are formed by changing the above, but three or more latent image images can be formed by arranging a plurality of latent image lines in different directions. Note that, as described in paragraph (0057), the plurality of latent image images may overlap each other, or a plurality of latent image images may overlap.

  The image line in the present invention refers to a dotted line, a broken line, a straight line, a curved line, a broken line, or the like in which halftone dots, which are small dots forming a printed image, are continuously arranged in a specific direction at a certain distance. A pixel is formed by collecting at least one printing halftone dot or a plurality of printing halftone dots into a lump, various shapes such as a circle, a triangle, a polygon including a quadrangle, and a star, or a character, a symbol, a number, or the like.

  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.

  FIG. 19 shows a latent image print (1-1). FIG. 19A shows a front view of the latent image print (1-1), and FIG. 19B shows a cross-sectional view of the latent image print (1-1) along the line AA ′. is there. The latent image print (1-1) is formed by forming a print image region (3-1) on a base material (2-1). As the substrate (2-1), a general white coated paper (Espricoat 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 second image (5-1) on the first image (4-1). The second image (5-1) includes a first latent image (5A-1) and a second latent image (5B-1).

  FIG. 21 shows the first image (4-1). In the first image (4-1), the element length in the first direction (S1 direction in the figure) is 0.5 mm, and the element length in the second direction (S2 direction in the figure) is 0.5 mm (diameter). The first element (6-1), which is a 0.5 mm circle, has a pitch of 0.4 mm in the first direction (S1) with respect to the diagonally adjacent first element (6-1). It is arranged in a checkered pattern with a pitch of 0.4 mm in the second direction (S2) with respect to the diagonally adjacent first elements (6-1).

  FIG. 22 shows a first latent image (5A-1) that is one of two latent images included in the second image (5-1), and the first direction ( The first latent image line (7A-1) having an image line width of 0.35 mm in the (S1 direction) was continuously arranged in the first direction (S1) at a pitch of 0.4 mm. As in the first embodiment, each latent image line (7A-1) has a height of 10 mm and a width of 3.5 mm with respect to the first base image (8-1) representing the cherry blossom petals. The frame (9A-1) was applied and compressed to 0.35 mm in the first direction (S1). The first compression rate in the present embodiment is 0.1.

  FIG. 23 shows the second latent image (5B-1), and the second latent image line (7B-1) having a line width of 0.35 mm in the second direction (S2). Were arranged continuously in the second direction (S2) at a pitch of 0.4 mm. Each latent image line (7A-1) is a second base image having a height of 3.5 mm and a width of 10 mm with respect to a second base image having the same shape as the first base image (8-1) representing the petals of cherry blossoms. A frame (not shown) was applied and formed by compressing to 0.35 mm in the second direction (S2). The second compression rate in the present embodiment is 0.1.

  First, the two images having the above-described configuration were printed on the substrate (2-1) by using the screen ink shown in Table 1 and the first image (4-1) by the UV drying type screen printing method. Subsequently, the second image (5-1) was printed by the wet offset printing method. In the second image (5-1), a matte transparent ink (made by Matte Medium T & K TOKA) was used. The UV screen ink shown in Table 1 is an ink having color flip-flop properties, and is black under diffuse reflection light and emits a gold interference color under regular reflection light. The raised height of the first element (6-1) in this example was about 10 μm.

  As shown in FIGS. 24 and 25, the positional relationship of the overlapping of the two images was formed so that the respective images overlapped in parallel in the first direction (S1) and the second direction (S2).

  The effect of the latent image printed matter (1-1) of the present invention formed with the above configuration will be described with reference to FIG. As shown in FIG. 26 (a), when the latent image print (1-1) of the present invention is observed under diffuse reflected light, the latent image included in the second image (5-) is any It was invisible and the entire printed image area (3-1) was observed in black. When the latent image printed material (1-1) of the present invention is observed under specular reflection light, the latent image represented by the first latent image (5A-1) and the second latent image (5B-1) Appears in black in a golden background, two cherry blossom petals appear (not shown), and when the side B is tilted in the back direction as shown in FIG. 26 (b), the first latent image The latent image represented by (5A-1) did not move, and only the latent image represented by the second latent image (5B-1) appeared to move toward the B ′ side. In addition, as shown in FIG. 26C, when the latent image printed material (1-1) of the present invention is tilted in the back direction with the A 'side under specular reflection light, the second latent image (5B-1) is obtained. ) Did not move, and only the latent image represented by the first latent image (5A-1) appeared to move toward the A ′ side. In addition, as shown in FIG. 26D, when the latent image printed material (1-1) of the present invention is tilted in the back direction with the B 'side under specular reflection light, the first latent image (5A-1) is obtained. ) Did not move, and only the latent image represented by the second latent image (5B-1) appeared to move toward the B side. In addition, as shown in FIG. 26E, when the latent image printed material (1-1) of the present invention is tilted in the back direction with the A side under specular reflection light, the second latent image (5B-1) The latent image represented by was not moved, and only the latent image represented by the first latent image (5A-1) appeared to move toward the A side.

  As described above, the two latent image images (5A-1, 5B-1) are invisible under diffuse reflection light, and the first latent image (5A-) at a specific observation angle under specular reflection light. It was confirmed that the effects of 1) and the second latent image (5B-1) moving in different directions can be obtained.

1, 1 ', 1-1 Latent image printed matter 2, 2', 2-1 substrate 3, 3 ', 3-1 print image area 4, 4', 4-1 first image 5, 5 ', 5 -1 Second image 5A, 5A ', 5A-1 First latent image 5B, 5B', 5B-2 Second latent image 6, 6 ', 6-1 First element 7A, 7A' 7A-1 First latent image lines 7B, 7B ′, 7B-2 Second latent image lines 8, 8 ′, 8-1 First base images 9A, 9A ′, 9A-1 First Frame 9B, 9B ′, 9B-1 Second frame 10 Light source 11 Observer's viewpoint

Claims (3)

At least part of the substrate has a first image and a print image region composed of a second image arranged on the first image,
The first image is a pixel-shaped first pixel having a three-dimensional curved surface shape having at least one of a light-dark flip-flop property and a color flip-flop property that emits a first color under specular reflection light. A plurality of elements are arranged in a checkered pattern in a first direction and a second direction intersecting the first direction,
With respect to the first elements adjacent to each other in the first direction, the first elements adjacent to each other in the oblique direction are oblique to the center between the first elements adjacent to each other in the first direction. The center of the first element adjacent in the direction coincides, and further, the adjacent first element and the partial region of the first element adjacent in the oblique direction are arranged at the overlapping position, The first elements obliquely adjacent to each other are arranged with a first pitch shift in the first direction,
The first pitch is less than or equal to the length of the first element in the first direction;
The second image has a second color different from the first color at the time of regular reflection of the first image, and the image obtained by dividing the first base image is compressed at a predetermined compression rate. A plurality of first latent image lines each having a different shape formed at the first pitch and arranged in the first direction,
When observed under diffusely reflected light, the second image is invisible, and when light is incident at a specific angle under specularly reflected light, the first base image appears, and the observation angle is The latent image printed matter, wherein the first basic image appears to move in the first direction by being changed. The first elements diagonally adjacent to each other are arranged with a second pitch shift in the second direction,
The second pitch is less than or equal to the length of the first element in the second direction;
The second image is a second latent image having a different shape produced by compressing an image obtained by dividing a second base image having the same shape or a different shape from the first base image at a predetermined compression rate. A second latent image in which a plurality of image lines are arranged in the second direction at the second pitch;
When light is incident at a specific angle under specular reflection light, the second base image appears, and the second base image appears to move in the second direction by changing the observation angle. The latent image printed matter according to claim 1.   The latent image printed matter according to claim 1, wherein the first element has a circular shape.

Images