JP6060830B2 - Special latent image pattern former - Google Patents

Description

The present invention relates to a special latent image pattern forming body applied to banknotes, passports, securities, product tags, various certificates, etc. for preventing counterfeiting and copying.

  Due to the nature of valuable printed matter such as banknotes, passports, and securities, they are required to be difficult to forge or tamper. As a preventive measure, a technique is known in which a fine image line, minute characters, or the like is given by printing on a precious printed matter, and authenticity determination is performed based on the presence or absence thereof. However, in recent years, due to the high functionality and widespread use of copiers, counterfeit printed products that have been reproduced with fine lines that were difficult to reproduce have become a serious problem. In view of such a technical background, a lot of printed materials having not only a fine image line but also an uneven-shaped image line that cannot be reproduced by copying are disclosed in the valuable printed material. .

  For example, in Patent Document 1 filed earlier by the present applicant, a convex line that is the same color as or transparent to the base material is formed on the base material, and a plurality of color fine lines are formed on the convex line. A printed matter is disclosed in which a moiré pattern of rainbow-colored interference fringes appears when the substrate is tilted by printing so as to intersect with.

  Further, Patent Document 2 filed earlier by the present applicant discloses a printed matter formed by combining convex and convex lines formed on a base material and fine lines. The printed matter is provided with fine image lines that form the first latent image or the second latent image on both sides of each convex image line of the convex lines formed on the substrate. Thus, when the substrate is tilted, the first latent image formed of the fine image line applied to one side is visually recognized, and when tilted in the opposite direction, the second latent image formed of the fine image line applied to the other side is viewed. When the image image is visually recognized and the base material is further observed from the front, the third latent image composed of fine image lines given to both sides can be visually recognized.

Japanese Patent No. 4682280 JP 2012-6168

  With the printed matter disclosed in Patent Document 1, it is possible to create a printed matter in which iridescent moire occurs when the substrate is tilted by combining convex lines and fine lines. Compared to the case of adding only the forgery, the anti-counterfeiting effect is extremely high because it is difficult to create simply. However, since it has a configuration in which convex lines and monochromatic linear fine lines are combined, the pattern appearing at an inclination is only a simple moire pattern. For this reason, there is room for further improvement so that a printed material having a better effect, for example, a printed image in which a latent image appears due to a change in the observation angle in addition to a moire pattern, and further, the latent image appears. is there.

  Further, in Patent Document 2, a latent image divided into a latent image portion and a background portion appears when a fine image line is shaded by a convex line when the substrate is tilted. However, the appearing latent image has a latent image portion and a background portion separated by color, and is formed by applying fine image lines to both sides of the fine convex image lines. Therefore, since high printing accuracy is required, the latent image may be unclear when the image line is not arranged on the side of the convex image line due to misalignment or depending on the color that separates the latent image portion and the background portion. There is a problem that it cannot be visually recognized.

  The present invention aims to solve the above-described problems, and specifically, it appears due to a change in the observation angle formed using convex lines formed on a substrate and fine printed lines. An object of the present invention is to provide a printed matter that allows a latent image to be visually recognized as a clear image without requiring high printing accuracy.

  In order to achieve the above-mentioned object, the invention described in claim 1 is characterized in that the first line-shaped first element and the first color of the color different from the base material are formed on the convex line formed on at least a part of the base material. 2 is a special latent image pattern forming body in which a latent image composed of a pattern portion and a background portion appears as a result of a change in the observation angle. The first element is divided into a first pattern element part and a first background element part because the first element is partially different in shape, and the first pattern element part is The first color material is arranged on one side of the convex line to form the first pattern portion, and the second element is partially different in shape, so that the second pattern element portion And the second background element part, and the second pattern element part is formed by the second color material having the same color as or different from the first color material, The first pattern element portion and the first background element portion, or the first background element portion and the second background element portion are one of the convex lines. The first pattern element portion arranged at least on one side of the convex image line and the second arranged on the other side of the convex image line. The background element portion is arranged so as not to overlap, and the first background element portion arranged on one side of the convex line and the second background element arranged on the other side of the convex line The pattern element portions are arranged so as not to overlap, and when the substrate is tilted and observed, a plurality of elements should be arranged at least over one side and the other side of the image line of the latent image. A special latent image pattern formed body that is visually recognized as a moire pattern.

  The invention according to claim 2 is the special latent image pattern forming body according to claim 1, wherein the first pattern element portion and the first color are formed in each convex image line constituting the convex line. The second pattern element portion formed of the second color material having a color different from that of the first pattern element portion has the same shape and size, and the first pattern element portion and the second pattern element portion in the convex line Are all arranged correspondingly at the same position.

  The invention according to claim 3 is the special latent image pattern formed body according to claim 2, wherein the first background element portion is formed of the second color material, and the second background element portion is the first background element portion. It is formed of a color material.

  According to a fourth aspect of the present invention, in the special latent image pattern formed body according to the third aspect of the present invention, the first background element portion and the second background element in each convex image line constituting the convex line. The parts have the same shape and size, and in the convex line, the first background element part and the second background element part are all arranged correspondingly at the same position.

  The invention of claim 5 is the special latent image pattern formed body according to any one of claims 1 to 4, wherein the uneven shape of the substrate formed by the convex lines is the height of the convex portion, It is characterized in that a third latent image is formed as a watermark pattern in which at least one of the width, the depth of the concave portion, and the width is different, and the transmittance with the substrate is different.

  Further, the invention according to claim 6 is the special latent image pattern formed body according to any one of claims 1 to 5, wherein the first element or the second element has an image line and a plurality of points in the same direction. The arranged point group or the plurality of pixels is composed of at least one of the pixel groups arranged in the same direction.

  The printed matter according to the present invention having the above-described configuration prints a fine image line having a partially different shape on a convex line, so that when the substrate is tilted, the latent image and the surrounding background Any one of these is visually recognized as a moire pattern, so that the latent image can be clearly visually recognized due to the difference in color tone. The moire pattern has a characteristic that appears even when the fine lines formed on the convex lines are slightly shifted. Therefore, a moiré pattern is generated even when a misalignment occurs during manufacturing, so that it is possible to visually recognize the latent image as a clear image without requiring a high alignment accuracy.

  In addition, among a part of the fine image lines that are partially different in shape, the fine image lines constituting the background or latent image that is visually recognized as a moire pattern are provided across a plurality of sides of the convex image lines. ing. When the observation angle is changed, a moire pattern is generated around the latent image in addition to the effect that the latent image is changed by the fine image line being a shadow of the convex line. Therefore, the latent image that the printed matter of the present invention has not only appears clearly due to the difference in color tone from the moire pattern, but can also be visually recognized as the color tone of the moire pattern changes as the observation angle changes. Become.

An example of the top view which shows the special latent image pattern formation body (1) concerning this invention. The top view which shows the 1st latent image image (3a) and the 2nd latent image image (4a). The other top view which shows the 1st latent image (3a) and the 2nd latent image (4a). The top view and sectional drawing which show a convex line (5). The top view and sectional drawing which show the other form which has arrange | positioned the convex line (6) in the 1st direction (X1). The top view which shows an example of the planar shape of a convex parallel line (5). Sectional drawing which shows an example of the cross-sectional shape of a convex line (6). The top view and enlarged view of the formation body (1) shown in FIG. The top view and enlarged view of the formation body (1) shown in FIG. The top view and enlarged view which show a 1st latent image (3a). The figure which shows an example of the element concerning this invention. The enlarged view which shows a 1st element (7). The top view which shows an example of the division by the difference in the shape of a 1st pattern element part (7a) and a 1st background element part (7b). The other schematic diagram which shows the division of a 1st pattern element part (7a) and a 1st background element part (7b). The top view and enlarged view which show a 2nd latent image element (4a). The enlarged view which shows a 2nd element (8). The figure which shows the viewpoint (E1, E2, E3) at the time of observing the base material (2) to which the formation body (1) was provided. The top view at the time of observing a formation body (1) from the 1st observation angle (E1). The top view at the time of observing a formation body (1) from the 2nd observation angle (E2). The top view at the time of observing a formation body (1) from the 3rd observation angle (E3). The schematic diagram which shows a visible image (9 '). The enlarged view of the one part area | region (Z4) shown in FIG. The top view of each latent-image image (3a, 4a) visually recognized when the formation body (1) of a 1st modification is inclined and observed. The schematic diagram which shows the positional relationship of each element (7, 8) and convex image line (6). The top view at the time of observing the formation body (1) of a 1st modification from each observation angle (E1, E2, E3). The top view and enlarged view of the formation body (1) of a 2nd modification. The top view and sectional drawing which show the convex line (5) of a 3rd modification.

  Embodiments of the present invention will be described with reference to the drawings. However, the present invention is not limited to the embodiments to be described below, and various other embodiments can be implemented within the scope of the technical idea described in the claims.

  FIG. 1 is a plan view showing a special latent image pattern formed body (hereinafter referred to as “formed body”) in the present invention, and an example of an anti-counterfeit printed matter (S) provided with the formed body (1) of the present invention. It is a top view which shows a gift certificate.

  The printed material (S) is a commonly used color material such as cyan or magenta on the printable base material (2) such as paper or plastic card, and the information on the printed material (S) such as store name and ticket type. Is given by. The printed matter (S) includes a latent image forming region (Z) (hereinafter referred to as “region”) at least partially on the substrate (2). In the region (Z), the formed body (1) is disposed, and the formed body (1) has a plurality of latent image images that can be visually recognized by changing the observation angle.

  The formed body (1) has a first latent image (3) shown in FIG. 2 (a) and a second latent image (4) shown in FIG. 2 (b). The first latent image (3) is an image that can be viewed when the substrate (2) is tilted and observed, and the second latent image (4) is the first image of the substrate (2). This is an image that can be viewed when tilted to the opposite side to the time when the latent image (3) is viewed.

  The first latent image (3) includes a first pattern portion (3a) and a first background portion (3b), and the second latent image (4) includes a second pattern portion (4a). And a second background portion (4b).

  Each latent image (3, 4) is configured by providing a plurality of print lines on the convex line formed on the substrate (2).

  When the formed body (1) thus configured is observed with the substrate (1) tilted, as shown in FIG. 2, the pattern portions (3a, 4a) in the latent image (3, 4) are observed. The surrounding background portions (3b, 4b) can be visually recognized as a moire pattern, or, as shown in FIG. 3, only the pattern portions (3a ′, 4a ′) in each latent image (3 ′, 4 ′). However, it can be visually recognized as a moire pattern. This makes it possible to clearly see the pattern portions (3a, 4a) in each latent image (3, 4). Hereinafter, each element which comprises a formation body (1) is demonstrated in detail.

  FIG. 4 is a plan view and a cross-sectional view showing the convex line (5), and FIG. 4 (a) is a plan view showing the convex line (5). As shown to Fig.4 (a), the convex line | wire (5) provided to the base material (2) consists of a several convex image line (6).

  FIG. 4B is a cross-sectional view taken along the line A-A ′ of FIG. As shown in FIG. 4B, a plurality of convex image lines (6) are formed at the first pitch (P1) in the first direction (X1). Each of the plurality of convex lines (6) is arranged to have two side portions, a first side portion (6L) and a second side portion (6R), with the vertex (6T) as a boundary. The first pitch (P1) for arranging the convex image line (6) takes into consideration the printing method, the substrate (2) to be used, and the image line width of the printed image line to be printed on the convex image line (6) described later. However, it can be appropriately set within a range of 400 to 1800 μm.

  When the first pitch (P1) is less than 400 μm, the area necessary for printing the print image line on the convex image line (6) is not sufficiently obtained, and thus the image line of the print image line is not obtained. By reducing the width, the visibility of each latent image (3, 4) is lowered, which is not preferable.

  On the other hand, when the first pitch (P1) is wider than 1800 μm, a plurality of print image lines to be printed on the convex image line (6) are identified one by one, and each latent image ( 3, 4) cannot be clearly seen, which is not preferable. In FIG. 4 (a), the first pitch (P1) is shown as a constant pitch. However, if the pitch is within the range of 400 to 1800 μm, it may be partially different.

  FIG. 5 is a plan view and a cross-sectional view showing another embodiment in which the convex line (6) is arranged in the first direction (X1). As shown in FIG. 5A, the convex image lines (6) are arranged at a random pitch (PL) in the first direction (X1). FIG. 5B is a cross-sectional view taken along the line B-B ′ in FIG. In the case of arranging at a random pitch (PL), each of the pitches can be appropriately set within the same range as the first pitch (P1) described above.

  The reason why the pitch (PL) is in the range of 400 to 1800 μm is the same as that of the first pitch (P1) described above, and thus the description thereof is omitted. Hereinafter, in the present embodiment, the pitch of the convex line (6) will be described as the first pitch (P1) that is a constant pitch.

  The width (W1) of the convex image line (6) is appropriately set within a range of 0.1 to 1.0 mm in consideration of the first pitch (P1) and the width of the print image line described later. When the width (W1) of the convex image line (6) is less than 0.1 mm, it is not preferable because it is difficult to print the printed image line on the convex image line (6).

  When the width (W1) of the convex image line (6) is wider than 1.0 mm, it is difficult to clearly see each latent image (3, 4) when the printed material (S) is tilted. This is not preferable.

  The height (h1) of the convex image line (6) can be appropriately set within the range of 30 μm to 70 μm in consideration of the first pitch (P1) and the width of the print image line. When the height (h1) is less than 30 μm, it is difficult to clearly see each latent image (3, 4) when the printed matter (S) is tilted, which is not preferable.

  Further, when the height (h1) of the convex image line (6) is higher than 70 μm, it is difficult to print the printed image line on the convex image line (6), which is not preferable.

  Although the convex image line (6) is linear, it is not limited to a linear shape, and if it can be printed on the convex image line (6), it can be a wavy line, a broken line, or the like. is there. Needless to say, the shape formed by assembling a plurality of convex lines (6) can be various shapes shown in FIG. 6 as long as it can be formed in the region (Z).

  Furthermore, the cross-sectional shape of the convex image line (6) is not limited to the shape shown in the AA ′ cross-sectional view of FIG. 4 described above, and if a print image line can be formed on the convex image line (6), Various cross-sectional shapes shown in FIG. 7 are possible.

  The convex line (5) is formed on the base material (2) by intaglio printing, screen printing, embossing, penetration, laser processing, or the like. Convex lines (5) formed by intaglio printing, screen printing, etc. are printed on the base material (2) using a printing plate and ink suitable for the desired printing method such as intaglio printing or screen printing. A convex shape is formed by the heap of ink, and the convex shape is defined as a convex line (5).

  The embossed convex line (5) is formed by sandwiching the base material (2) between the concave and convex molds using a concave mold and a convex mold that match the size of the desired convex parallel line (5). By applying pressure, on the base material (2), a concave shape (indented with respect to the base material (2)) or a convex shape (protruded with respect to the base material (2)) is formed. A concave shape or a convex shape is defined as a convex line (5). In the concave shape, as described above, a convex line (5) is formed by denting a part of the substrate (2). However, in the present invention, the convex line ( 5).

  The formation of the convex lines (5) by squeezing is performed by using the raw materials of paper (dandy roll part, circular net part, press part part, etc.) on the paper machine when the base material (2) is made of paper. It is formed by removing (concave part) or increasing (convex part) the (paper material). In addition, in a recessed part, although a convex line (5) will be formed by eliminating paper stock as above-mentioned, in this invention, it calls generically a convex line (5).

  The convex line (5) is formed by laser processing or the like by removing a part of the substrate (2) with a laser using a desired laser processing apparatus. That is, the convex line (5) is formed by forming a concave portion in a part of the substrate (2). However, in the present invention, the convex line ( 5).

  In the case where the convex lines (5) are formed on the substrate (2) by printing, it is not preferable to use a transparent ink. When transparent ink is used, as will be described later, when the base material (2) is tilted, each of the latent image (3, 4) appears when the convex line (5) shields the print line. The effect will no longer occur. However, some colored transparent inks in which pigments, dyes and the like are mixed have an effect of shielding each printed image line. Therefore, such a colored transparent ink can be appropriately selected in the present invention.

  Next, a print image line that forms a latent image that can be viewed by tilting will be described. FIG. 8A is a plan view of the formed body (1) in which the background portion (3b) is visually recognized as a moire pattern as described above in FIG. 2, and FIG. 8B is a plan view of FIG. It is the schematic diagram which expanded this area | region (V1). Further, FIG. 9A is a plan view of the formed body (1) in which the pattern portion (3a ′) is visually recognized as a moire pattern, and FIG. 9B is a plan view of FIG. ) Is an enlarged schematic view of the region (V1 ′).

As shown in FIG. 8B and FIG. 9B, the streak-like first element (7) and the second element (8) are formed on the substrate (2), not shown. A plurality of lines are arranged on the convex line.

  The first element (7) is an element constituting the first latent image (3, 3 ′) shown in FIG. 2 (a) or FIG. 3 (a), and the second element (8). ) Is an element constituting the second latent image (4, 4 ') shown in FIG. 2 (b) or FIG. 3 (b).

  First, the first element (7) constituting the first latent image (3) will be described. FIG. 10A is a plan view showing a first latent image (3) that can be viewed by tilting the base material (2), and FIG. 10B is a region of FIG. 10A. It is the schematic diagram which expanded (V2). In FIG. 10B, actually, the convex line (6) and the second element (8) constituting the second latent image (4) are also arranged but omitted.

  As described above, among the pattern portion (3a) and the background portion (3b) constituting the formed body (1), in FIG. 2 (a), the background portion (3b) can be visually recognized as a moire pattern. In (a), the pattern part (3a ′) was visible as a moire pattern. This is because, in FIGS. 2 (a) and 3 (a), the elements constituting the pattern part (3a) and the elements constituting the background part (4a) surrounding the pattern part (3a) have opposite structures. It is.

  Specifically, the background portion (3b) is visible as a moire pattern. In FIG. 10 (b), the pattern portion (3a) is composed of linear elements, and the background portion (3b) is wavy. Consists of elements. On the other hand, as shown in FIG. 3B, when the pattern portion (3a ′) can be visually recognized as a moire pattern, the pattern portion (3a) is composed of wavy elements and the background portion (4b). Is composed of linear elements. Thereby, although a detailed principle will be described later, among the pattern portions (3a, 3a ′) and the background portions (3b, 3b ′) constituting the formed body (1), in FIG. 3b) can be visually recognized as a moire pattern, and in FIG. 3A, the pattern portion (3a ′) can be visually recognized as a moire pattern.

  Hereinafter, in the present embodiment, as shown in FIGS. 2 and 10, the formed body (1) is described as a configuration in which the background portion (3b) around the pattern portion (3a) can be visually recognized as a moire pattern. .

  As shown in FIG. 10 (b), an image-lined first element (7) is arranged on a convex image line (not shown) formed on the substrate (2).

  In the present invention, the first element (7) is an image line, a halftone dot group in which a plurality of points are arranged in the same direction, or a pixel group in which a plurality of pixels are arranged in the same direction. FIG. 11 is a diagram showing an example of the first element (7) in the present invention. The image line is a straight line shown in FIG. 11A and a broken line shown in FIG. The line width is generally 60 to 200 μm. A halftone dot is a point formed on a printed material by a mesh screen, a contact screen, or the like.

  A pixel is a minimum unit obtained by dividing a two-dimensional image such as a figure or a character by vertical and horizontal lines. A plurality of halftone dots and pixels are arranged in a straight line or a wavy line, and are configured in an image line. The pixel has a circular shape shown in FIG. 11C, an elliptical shape shown in FIG. 11D, and a triangular shape shown in FIG. In addition, the pixels may be rotated and arranged as shown in FIG. 11 (e), or may have a character shape as shown in FIG. 11 (f).

  Furthermore, as shown in FIG. 11G, in one element, at least two kinds of image lines, halftone dots, or pixels may be combined and arranged in the same direction. Hereinafter, in this embodiment, it demonstrates as a straight line shown to Fig.11 (a).

  FIG. 12 is an enlarged view showing one first element (7) among the plurality of first elements (7) shown in FIG. As shown in FIG. 12, the first element (7) is divided into a first pattern element part (7a) and a first background element part (7b) by partially different shapes.

  The first pattern element portion (7a) is an element constituting the first pattern portion (3a) in the first latent image (3), and is a first color different from the base material (2). The material is arranged on the first side (6L). By arranging a plurality of first pattern element portions (7a), a first pattern portion (3a) shown in FIG. 10 (a) is formed.

  The first background element portion (7b) is an element constituting the first background portion (3b) in the first latent image (3), and by a color material having a color different from that of the base material (2), One side of the convex line (6) so as not to overlap the first pattern element (7a) and the second pattern element (8a) constituting the second latent image (4) described later And the second side part (6R), which is the other side part, are disposed at least across the first side part (6L). By arranging a plurality of first background element portions (7b), a part of the first background portion (3b) shown in FIG. 10 (a) is formed.

  In FIG. 10 (b), it is arranged across both side portions (6L, 6R) of one convex image line (6), but not limited to this, one convex image line (6) has one convex image line (6). It may be arranged across the first side (6L) of the image line (6) and the second side (6R) of the adjacent convex image line (6). Further, the plurality of convex image lines (6) arranged may be arranged over two or more adjacent convex image lines (6).

  When the first pattern element part (7a) and the first background element part (7b) are the same color as the base material (2), the first element (7) printed on the base material (2) It cannot be distinguished with the naked eye. Therefore, the first pattern element portion (7a) and the first background element portion (7b) are formed of a color material having a color different from that of the base material (2).

  Different colors in the present invention may be colors having the same hue and different densities. For example, the color material forming the first pattern element portion (7a) is light red, and the first background element portion (7b) is The color material to be formed can be dark red.

  In the present invention, for the color material forming the second latent image (4) described later, the definition when the colors of the respective color materials are visually recognized as the same color or different colors is as follows. Since the relationship between the color of the pattern element portion (7a) and the first background element portion (7b) is the same, the description thereof will be omitted.

  As described above, the first element (7) is divided into a first pattern element part (7a) and a first background element part (7b) by being partially different in shape. Therefore, the colors of the color materials of the first pattern element part (7a) and the first background element part (7b) may be the same or different. Since the configuration of different colors will be described later, it will be described below as the same color.

  FIG. 13 is a plan view showing an example of division based on the difference in shape between the first pattern element portion (7a) and the first background element portion (7b). In FIG. 12, the first element (7) is divided into a straight first pattern element part (7a) and a wavy first background element part (7b). 7a) is disposed on the first side (6L), and the first background element (7b) is disposed at least across the first side (6L) and the second side (6R). Other shapes are possible as long as they are.

  For example, as shown in FIG. 13A, it is possible to divide into a wavy first pattern element portion (7a) and a first background element portion (7b). Furthermore, the first pattern element portion (7a) and the first background element portion (7b) can both be straight lines and can be classified by varying the angles. In the present invention, the division based on the change in angle is also the division based on the change in shape.

  Moreover, as shown in FIG.13 (c), it is also possible to divide into the 1st pattern element part (7a) of a rectangular wave shape, and the 1st background element part (7b) of a rectangular wave shape. As shown in FIGS. 13 (a) and 13 (c), if the image line has a shape having an arbitrary period and amplitude, the first pattern element portion (7a) can be obtained by varying the period or amplitude. And the first background element portion (7b) can be divided by a change in the shape of the drawing line.

  FIG. 14 is another schematic diagram showing the division of the first pattern element part (7a) and the first background element part (7b). In FIG. 12 described above, the first pattern element portion (7a) and the first background element portion (7b) are arranged adjacent to each other. However, as shown in FIG. The part (7a) and the first background element part (7b) may have a separate area.

  Moreover, as shown in FIG.14 (b), the form which has the area | region with which the 1st pattern element part (7a) and the 1st background element part (7b) overlapped partially may be sufficient. In addition, in the case where either form of FIG. 14 (a) and FIG. 14 (b) is adopted, it is within a range in which the concealability of each latent image (3, 4) is not lowered when viewed from the front. It is necessary to appropriately set the size of the separated area or partially overlapped area.

  The first element (7) is formed on the substrate (2) by a known printing method. The printing method of the first element (7) is not particularly limited as long as it can be printed on the substrate (2), such as an offset printing method, a gravure printing method, a screen printing method, a flexographic printing method, an ink jet printer, a laser printer, or the like. It is not something. When producing the formed body (1), in most printing methods, an increase in the line area ratio or the dot area ratio due to dot gain is expected between the substrate (2) and the printing plate surface. Needless to say, it is necessary to set the image area ratio or the halftone dot area ratio in advance.

  For the first color material forming the first pattern element portion (7a) and the second color material forming the first background element portion (7b), various inks suitable for the printing method described above are used. For example, an offset ink, a gravure ink, a screen ink, a flexo ink, a toner, etc. can be used.

  Further, the ink is not limited to a single color ink, and it is also possible to prepare inks of respective colors by mixing a plurality of inks and use the inks. In the second element (8) constituting the second latent image (4a) described later, the printing method to be formed and the ink that can be used are the same as those in the first element (7). Since there is, explanation is omitted.

  Next, the second element (8) constituting the second latent image (4) will be described. Fig.15 (a) is a top view which shows the 2nd latent image image (4) which can be visually recognized by inclining a base material (2), FIG.15 (b) is an area | region of Fig.15 (a). It is the schematic diagram which expanded (V3). In FIG. 15B, the convex line (6) and the first element (7) constituting the first latent image (3) are also actually arranged, but are omitted.

  As shown in FIG. 15 (b), the image-shaped second element (8) is arranged on a convex image line (not shown) formed on the substrate (2). As for the second element (8), similarly to the first element (7) described above, an image line, a halftone dot group in which a plurality of points are arranged in the same direction, or a plurality of pixels in the same direction. Since it is a pixel group arranged in, the description is omitted.

  FIG. 16 is an enlarged view showing one second element (8) among the plurality of second elements (8) shown in FIG. As shown in FIG. 16, the second element (8) is divided into a second pattern element part (8a) and a second background element part (8b) by partially different shapes.

  The second pattern element portion (8a) is an element constituting the second pattern portion (4a) in the second latent image (4), and the base material (2) and the first pattern element portion (7a). ) Is arranged on the second side portion (6R) by a second color material having a color different from that of the first color material forming the first color material. By arranging a plurality of second pattern element portions (8a), a second pattern portion (4a) shown in FIG. 15 (a) is formed.

  The second background element portion (8b) is not colored with the first pattern element portion (7a) and the second pattern element portion (8a) by a color material having a color different from that of the base material (2). The first side part (6L) which is one side part of the convex image line (6) and the second side part (6R) which is the other side part are disposed at least across the first image part (6R). By arranging a plurality of second background element portions (8b), a part of the second background portion (4b) shown in FIG. 15 (a) is formed.

  In FIG. 15 (b), it is arranged across both side portions (6L, 6R) of one convex image line (6). However, the present invention is not limited to this. You may arrange | position across the 1st side part (6L) of one convex image line (6), and the 2nd side part (6R) of an adjacent convex image line (6). Further, in the same manner as the first background element portion (7b) described above, the plurality of convex image lines (6) are arranged over two or more adjacent convex image lines (6). Also good.

  When the second pattern element portion (8a) and the second background element portion (8b) are the same color as the base material (2), the second element (8) printed on the base material (2) It cannot be distinguished with the naked eye. Therefore, the second pattern element portion (8a) and the second background element portion (8b) are formed of a color material having a color different from that of the base material (2).

  Similar to the first element (7) described above, the second element (8) is partially different in shape so that the second pattern element part (8a) and the second background element part (8b) It is divided into. Therefore, the colors of the second pattern element portion (8a) and the second background element portion (8b) may be the same or different, and will be described below as the same color.

  In addition, about the division by the difference in the shape of the second pattern element portion (8a) and the second background element portion (8b), it is the same as the division of the first element (7) described above. Omitted.

  Next, the observation angle for visually recognizing each latent image (3, 4) described above will be described. FIG. 17 is a diagram showing viewpoints (E1, E2, E3) when the base material (2) to which the formed body (1) is applied is observed. The convex line (6) is arranged in the first direction (X1) on the base material (2).

  In the present invention, the viewpoint is in the positional relationship shown in (E1) with respect to the base material (2), and the apex (6T) and both side portions (6L, 6R) of the convex image line (6) are visible. Suppose that it observed from the 1st observation angle (E1). Further, when the viewpoint is in the positional relationship shown in (E2) and the first side (6L) of the convex line (6) is visible, it is assumed that the observation is made from the second observation angle (E2). The viewpoint (E2a) and the viewpoint (E2b) indicate changes in the viewpoint within the second observation angle (E2).

  Furthermore, when the viewpoint is in the positional relationship shown in (E3) and the second side (6R) of the convex image line (6) is visible, it is assumed that the observation is made from the third observation angle (E3). Note that the viewpoint (E3a) and the viewpoint (E3b) indicate changes in the viewpoint within the third observation angle (E3).

  Next, the visual recognition principle when the formed body (1) is observed from each observation angle (E1, E2, E3) will be described. First, the visual recognition principle when observed from the first observation angle (E1) will be described. FIG. 18 is a plan view when the formed body (1) is observed from the first observation angle (E1).

  As shown in FIG. 18, when the base material (2) is observed from the first observation angle (E1), both side portions (6L, 6R) of the convex line (6) are adjacent to each other. It becomes visible without becoming a shadow of the line (6), and a plurality of first elements (7) and second elements (8) are all visible.

  However, since each element (7, 8) cannot be distinguished and visually recognized with the naked eye, the first latent image (3) and the second latent image (4) composed of each element (7, 8). However, each shape cannot be identified. Therefore, the visible image (9) is visually recognized as an image having a uniform density from the first observation angle (E1).

  Next, the visual recognition principle when observed from the second observation angle (E2) will be described. FIG. 19 is a plan view when the formed body (1) is observed from the second observation angle (E2). As shown in FIG. 19, when the substrate (2) is observed from the second observation angle (E2), the first pattern portion (3a) in the first latent image (3) is monochromatic. The first color that is a color is visually recognized, and the first background portion (3b) around the first color is visually recognized as a moire pattern.

  Next, the principle by which the first pattern portion (3a) is visually recognized with the first color will be described. When the substrate (2) is observed from the second observation angle (E2), the first side portion (6L) in the convex image line (6) becomes a shadow of the adjacent convex image line (6). It is visible without any problem. On the other hand, the second side portion (6R) becomes a shadow of the adjacent convex image line (6) and cannot be visually recognized.

  Therefore, when the base material (2) is observed from the second observation angle (E2), the first pattern element portion made of the color material of the first color disposed on the first side portion (6L). (7a) becomes visible, and the first pattern portion (3a) including the plurality of first pattern element portions (7a) is visually recognized in the first color.

Next, the principle that the first background portion (3b) is visually recognized as a moire pattern will be described.
As described above, when the base material (2) is observed from the second observation angle (E2), the first side portion (6L) in the convex image line (6) is adjacent to the convex image line (6). It can be seen without shadows. On the other hand, the second side portion (6R) becomes a shadow of the adjacent convex image line (6) and cannot be visually recognized.

  When the substrate (2) is observed from the second observation angle (E2), the first (6L) and the second side (6R) of the convex line (6) are arranged across the first side (6R). The part located in the 2nd side part (6R) among the 1 background element part (7b) and the 2nd background element part (8b) cannot be visually recognized.

  Therefore, when each background element part (7b, 8b) and the convex line (6) are overlapped, in each background element part (7b, 8b), along the long side direction (X2) of the convex line (6). Thus, a blind spot is formed in a linear shape at a portion located on the second side part (6R), and interference occurs along the linear blind spot part and the arrangement direction (X1) of each background element part (7b, 8b). As a result, a moire pattern is generated and is visually recognized as the first background portion (3b).

  Furthermore, when the observation angle with respect to the base material (2) is gradually changed and observed, an action of changing a portion of the convex line (6) that becomes a blind spot works, and accordingly, the first visible becomes visible. As the area and shape of the background element portion (7b) and the second background element portion (8b) change, the moire pattern of the first background portion (3b) also changes.

  As described above, when the base material (2) is observed from the second observation angle (E2), the first pattern portion (3a) in the first latent image (3) is a single color. The first latent image (3) is clearly visually recognized due to the difference in color tone between the moire pattern and the first color because the first background portion (3b) is visually recognized as a moire pattern. Furthermore, when the observation angle with respect to the base material (2) is changed, the color tone of the moire pattern is changed and visually recognized with the change in the observation angle.

  In addition, in the formed body (3) in which the pattern portions (3a, 4a) are visually recognized as a moire pattern shown in FIG. 2 described above, the pattern element portions (7a, 8a) constituting the pattern portions (3a, 4a). Is disposed over at least one side and the other side of the convex image line (6).

  Thereby, when each pattern element part (7a, 8a) and convex image line (6) are overlapped, in each pattern element part (7a, 8a), in the long side direction (X2) of the convex image line (6). Along the second side portion (6R), a blind spot is formed linearly, and interference occurs along the linear blind spot portion and the arrangement direction (X1) of each pattern element portion (7a, 8a). As a result, a moire pattern is generated and is visually recognized as the first pattern portion (3a).

  The formed body (1) has a configuration in which each element (7, 8), which is a fine printed image line, is arranged on a fine convex image line (6) formed on the substrate (2). Conventionally, each element (7, 8), which is a single printed image line, is divided into a pattern element part and a background element part not by a change in shape but by a color. Are required to be arranged only on one or the other side of the convex image line (6).

  Therefore, when printing misalignment occurs during printing, each element (7, 8) is not arranged only on one or the other side of the convex image line (6), and each latent image (3, 4). ) Does not appear due to a change in the observation angle, or even if it appears, the image line is cut off due to misalignment of printing, and the latent image (3, 4) is partially missing in some places. .

  However, in the formed body (1) of the present invention, each pattern element portion (7a, 8a) constituting each pattern portion (3a, 4a) in each latent image (3, 4) is projected to the projected image line (6). The background element parts (7b, 8b) constituting the background parts (3b, 4b) are arranged over a plurality of side parts.

  With this configuration, misalignment occurs during printing, and the pattern element portions (7a, 8a) constituting the pattern portions (3a, 4a) in the latent image (3, 4) are projected images. Even when it is not arranged only on one or the other side of the line (6), a moire pattern composed of the background element parts (7b, 8b) is observed. Therefore, even when printing misalignment occurs, the latent image (3, 4) can be clearly visually recognized due to the difference from the background portion of the moire pattern.

  Next, the visual recognition principle when observed from the third observation angle (E3) will be described. FIG. 20 is a plan view when the formed body (1) is observed from the third observation angle (E3). As shown in FIG. 20, when the base material (2) is observed from the third observation angle (E3), the second pattern portion (4a) in the second latent image (4) is the second And the second background portion (4b) around it is visually recognized as a moire pattern.

  Next, the principle that the second pattern portion (4a) is visually recognized with the second color will be described. When the substrate (2) is observed from the third observation angle (E3), the second side portion (6R) of the convex image line (6) becomes a shadow of the adjacent convex image line (6). It is visible without any problem. On the other hand, the 1st side part (6L) becomes a shadow of an adjacent convex image line (6), and cannot be visually recognized.

  Therefore, when the base material (2) is observed from the third observation angle (E3), the second pattern element portion made of the color material of the second color disposed on the second side portion (6R). (8a) becomes visible, and the second pattern portion (4a) including the plurality of second pattern element portions (8a) is visually recognized in the second color.

Next, the principle that the second background portion (4b) is visually recognized as a moire pattern will be described.
As described above, when the base material (2) is observed from the third observation angle (E3), the second side portion (6R) in the convex image line (6) is adjacent to the convex image line (6). It can be seen without shadows. On the other hand, the 1st side part (6L) becomes a shadow of an adjacent convex image line (6), and cannot be visually recognized.

  When the substrate (2) is observed from the third observation angle (E3), the first (6L) and the second side (6R) of the convex line (6) are arranged across the first side (6R). Of the first background element part (7b) and the second background element part (8b), the part located on the first side part (6L) cannot be visually recognized.

  Therefore, when each background element part (7b, 8b) and the convex line (6) are overlapped, in each background element part (7b, 8b), along the long side direction (X2) of the convex line (6). Thus, a blind spot is formed in a linear shape at a portion located on the first side (6L), and interference occurs along the linear blind spot and the arrangement direction (X1) of each background element (7b, 8b). As a result, a moire pattern is generated and is visually recognized as the second background portion (4b).

  Furthermore, when the observation angle with respect to the base material (2) is gradually changed from the viewpoint (E3a) to the viewpoint (E3b) and observed, the effect of changing the portion of the convex line (6) that becomes the blind spot works. Accordingly, the moire pattern of the second background portion (4b) also changes as the area and shape of the first background element portion (7b) and the second background element portion (8b) that can be visually recognized change. To do.

  As described above, when the base material (2) is observed from the third observation angle (E3), the second pattern portion (4a) in the second latent image (4) is a single color. The second background portion (4b) is visually recognized as a moire pattern. Furthermore, when the observation angle with respect to the base material (2) is changed, the color tone of the moire pattern is changed and visually recognized as the observation angle changes.

  In FIG. 18, the visible image (9) visible from the first observation angle (E1) is an image having a uniform density, but can also be a meaningful image. In FIG. 21 (a), a visible visible portion (9a) having a circular shape is formed in the visible image (9).

  FIG. 21B is an enlarged view of the region (V1 ′) constituting the visible image (9). As shown in FIG. 21 (b), the first background element portion (7b) and the second background element portion (8b) are shown in FIG. 21 (c) with a line having a shape having an arbitrary period and amplitude. In some cases, by arranging the upper part (11a) and the lower part (11b) of the amplitude adjacent to each other, the density is visually recognized only at the adjacent part with the naked eye. Thereby, when observed from the first observation angle (E1), a density difference occurs in the visible image (9), and the visible pattern portion (9a) becomes visible.

  FIG. 22A is an enlarged view of a part of the region (Z4) shown in FIG. 8, and FIG. 22B is an enlarged view of a part of the region shown in FIG. As described above, the formed body (1) is formed by arranging a plurality of the elements (7, 8) partially different in shape. For example, in FIG. 8, each pattern element part (7a, 8a) of a straight line and each background element part (7b, 8b) of a wavy line are arranged.

  However, as shown in the enlarged view of FIG. 22B, the line area ratio of the straight line and the wavy line in the predetermined region is larger in the case of the wavy line. The image area ratio in the present invention is the ratio of the area of the image line (the portion where ink is applied) to the unit area. When the image area ratio is larger, the image area (the portion to which ink is applied) becomes larger in the unit area. Therefore, since the density is visually recognized with the naked eye, when observed from the first observation angle (E1), there is a density difference between the pattern portions (3a, 4a) and the background portions (3b, 4b). The latent image may be visually recognized.

  Therefore, in the first element (7) and the second element (8) arranged alternately, when the straight line and the wavy line are arranged adjacent to each other in the first direction (X1), It is preferable to increase the line width of the straight line element or to decrease the line width of the wavy line element so that the line area ratios of the straight line and the wavy line are equal.

  Next, a modified example of the formed body (1) will be described. FIG. 23 is a plan view of the latent image (3, 4) visually recognized when the formed body (1) of the first modified example is tilted and observed. The above-described formed body (1) changes the observation angle with respect to the base material (2), so that the second latent image (3) has a second shape different from the first latent image (3). It was visually recognized as a latent image (4). In the formed body of the first modified example, as shown in FIG. 23, the observation angle is changed from the second observation angle (E2) to the third observation angle (E3) with respect to the base material (2). When observed, the color of the latent image having the same shape is changed and visually recognized.

  Hereinafter, the configuration of the formed body (1) of the first modification will be described. FIG. 24 is a schematic diagram showing the positional relationship between each element (7, 8) and the convex line (6). FIG. 24A is a schematic diagram showing the elements (7, 8) constituting the above-described formed body (1), and FIG. 24B shows the formed body (1) of the first modified example. It is a schematic diagram which shows each element (7, 8) to do. In each of FIGS. 24 (a) and 24 (b), each element (7, 8) arranged on one convex image line (6) constituting the formed body (1) is first observed. The state visually recognized from the angle (E1) is shown.

  As shown in FIG. 2, the formed body (1) described above has the first pattern portion (3a) and the second pattern portion (4a) arranged in different regions without overlapping in the region (Z). ing. In that case, as shown to Fig.24 (a), the 1st pattern element part (7a) which comprises the 1st pattern part (3a), and the 2nd pattern which comprises the 2nd pattern part (4a) The element part (8a) is arranged without corresponding to one convex image line (6).

  On the other hand, as shown in FIG. 23, in the formed body (1) of the first modified example, the first pattern portion (3a) and the second pattern portion (4a) are all overlapped in the region (Z). Is arranged. In that case, as shown in FIG. 24 (b), the first pattern element portion (7a) constituting the first pattern portion (3a) and the second pattern constituting the second pattern portion (4a). The element part (8a) is arranged corresponding to one convex image line (6).

  Corresponding arrangement in the present invention means that, as shown in FIG. 24 (b), each pattern element portion and / or each background element portion are arranged on one convex image line (6). ) Is disposed so as to face the center in the longitudinal direction.

  As an example, when the first pattern element portion (7a) and the second pattern element portion (8a) correspond to each other, as shown in FIG. 24 (b), the first arranged on the convex line (6). The pattern element portion (7a) and the second pattern element portion (8a) are arranged so as to face the center in the longitudinal direction of the convex image line (6).

  The first pattern element portion (7a) and the second pattern element portion (8a) have the same shape and size in the plurality of convex image lines (6), and are all arranged correspondingly at the same position. Thus, as shown in FIG. 23 described above, the first pattern portion (3a) and the second pattern portion (4a) are all formed in an overlapping region. Thereby, the first pattern portion (3a) and the second pattern portion (4a) are images having the same shape and size.

  When the first pattern element portion (7a) and the second pattern element portion (8a) are all arranged corresponding to each other in the plurality of convex image lines (6), the first pattern element portion (7a) The first color material for forming the second color material and the second color material for forming the second pattern element portion (8a) are different colors. By using different colors, when the observation angle is changed from the second observation angle (E2) to the third observation angle (E3) with respect to the base material (2), the same shape is obtained. There is an effect that the color of the latent image changes and is visually recognized.

  When the first color material forming the first pattern element portion (7a) and the second color material forming the second pattern element portion (8a) have the same color, the base material ( When the observation angle is changed from the second observation angle (E2) to the third observation angle (E3) with respect to 2), the latent image having the same shape is always visually recognized in the same color. However, it goes without saying that the background portions (3b, 4b) around it have the effect that the moire pattern changes and is visually recognized.

  Further, for the formed body (1) shown in FIGS. 1 to 20 described above, the first color material constituting the first pattern element portion (7a) and the second pattern element portion (8a) are similarly formed. It is possible to make the 2nd color material to comprise into a different color. At that time, when the observation angle is changed from the second observation angle (E2) to the third observation angle (E3) with respect to the base material (2), each pattern portion (3a 4a,) is visually recognized with a color change effect in addition to the shape change.

  Next, the visual recognition principle when the formed body (1) of the first modified example is observed from each observation angle (E1, E2, E3) will be described with reference to FIG.

  FIG. 25A is a plan view when the formed body (1) of the first modified example including the elements (7, 8) of FIG. 24B is observed from the first observation angle (E1) described above. FIG. As shown in FIG. 25A, the visible image (9) including the visible pattern portion (9a) and the visible background portion (9b) is visually recognized from the first observation angle (E1).

  The visible pattern portion (9a) is composed of a first pattern element portion (7a) and a second pattern element portion (8a), and the first color material and the second color element forming each pattern element portion (7a, 8a). It is visually recognized as a solid image by a color obtained by mixing the colors of the color materials. The visible background portion (9b) is composed of the second background element portion (7b) and the second background element portion (8b), and is a color obtained by mixing the color materials forming the background element portions (7b, 8b). Is visually recognized as a solid image.

  Next, when the formed body (1) of the first modified example is observed from the second observation angle (E2) described above, as shown in FIG. 25 (b), it is the same as the visible pattern portion (9a). The first pattern portion (3a) having the same shape and size is visually recognized by the first color, and the first background portion (3b) around the first pattern portion (3a) is visually recognized as a moire pattern. The principle that the first background portion (3b) and the second background portion (4b) of the first modified example to be described later are visually recognized as a moire pattern is the same as that of the above-described formed body (1). The description is omitted.

  Furthermore, when the formed body (1) of the first modification is observed from the third observation angle (E3), the same shape as the visible pattern portion (9a) and the first pattern portion (3a), And the 2nd pattern part (4a) of the same magnitude | size is visually recognized by the 2nd color, and the 2nd background part (4b) which is the circumference | surroundings is visually recognized as a moire pattern.

  As described above, by using the formed body (1) of the first modified example, the color of the pattern portion in the latent image and the surrounding moire pattern are visually recognized by changing the observation angle.

  Note that the formed body (1) of the first modified example shown in FIG. 23 has the observation angle with respect to the substrate (2), the first observation angle (E1), the second observation angle (E2), and the By changing the observation angle to 3 (E3), the color of the latent image having the same shape is changed and visually recognized. At that time, the visible pattern portion (9a) visually recognized from the first observation angle (E1) was an image having the same shape as each of the pattern portions (3a, 4a) that can be visually recognized by a change in the observation angle.

  Therefore, as a second modified example, regarding the formed body (1), the pattern portions (3a, 4a) are not visually recognized at the first observation angle (E1), and can be visually recognized by the change in the observation angle. explain.

  FIG. 26A is a plan view of the formed body (1) of the second modification, and FIG. 26B is an enlarged schematic view of the region (V5) of FIG. (C) is a schematic diagram which shows one convex image line (6) which comprises the formation body (1) of Fig.26 (a).

  As shown in FIG. 26 (b), the first pattern element portion (7a) constituting the first pattern portion (3a) and the second pattern element portion (2a) constituting the second pattern portion (4a) 8a) are the same in shape and size on the convex image line (6), and are all arranged corresponding to the same position.

  Also, the first background element portion (7b) and the second background element portion (8b) have the same shape and size on the convex line (6), and all correspond to the same position. Be placed.

  Further, the first pattern element portion (7a) and the second background element portion (8b) are formed of the first color material having the same color, and the first background element portion (7b) and the second pattern are formed. The element part (8a) is formed of the second color material having the same color.

  Each pattern element part (7a, 8a) and each background element part (7b, 8b) have the same shape and size, are arranged corresponding to the same position, and one pattern element part and the other background. By forming the element portion with the same color material, when the formed body (1) shown in FIG. 26A is observed from the first observation angle (E1), the first pattern portion is formed. Both (3a) and the first background portion (3b) are visually recognized as a solid image in which the first color material and the second color material are mixed.

  Therefore, at the first observation angle (E1), the first pattern portion (3a) and the first background portion (3b) cannot be separated and visually recognized. The first latent image (3) is visually recognized as a solid print image in which the color material and the second color material are mixed.

  Each formation body (1) mentioned above had the effect that the background part of a moire pattern was visually recognized by changing a viewing angle with respect to a base material (2). For the formed body (1) of the present invention, by changing the shape of the convex line (5) formed on the base material (2), in addition to the change in the observation angle, the latent image visible by transmission An image can be applied. Next, as a third modified example, a formed body (1) to which a latent image that is a watermark pattern is given will be described.

  FIG. 27A is a plan view showing a convex line (5) of the third modified example, and FIG. 27B is a cross-sectional view taken along line A-A ′ of FIG. As shown in FIG. 27 (b), in the concavo-convex shape of the base material (2) formed by the convex line (5), the height, width, and depth of the concave portion of the convex line (6) that is the convex portion. By changing at least one of the widths, the transmittance with the base material (2) is made different. As a result, a third latent image (10) which is a watermark pattern that is visible under transmitted light is formed.

  The width (W6b) of the concave portion is defined by the first pitch (P1) in which the above-described convex line (6) is arranged, and the first element (7) and the second element provided on the convex line (6). In consideration of the width of (8), it can be appropriately set in the range of 200 μm to 800 μm. When the width (W6b) is less than 200 μm, it is difficult to print the first element (7) and the second element (8) on the convex line (6), which is not preferable.

  Further, when the width of the recess (W6b) is wider than 800 μm, it is difficult to clearly see each latent image that can be visually recognized by changing the observation angle, which is not preferable.

  The convex line (6) width (W6a) constituting the third latent image (10) can be appropriately set within the range of the width of the convex line (6) described above.

  As shown in FIG. 27 (b), the third latent image (10) formed by gradually varying the height, width, depth, and width of the convex portion is shown in FIG. ) As shown. It is visually recognized as a latent image having a gradation with changed transmittance.

  Note that the convex line (6) and the bottom (6U) constituting the third latent image (10) have a high transmittance as long as the transmittance is different from that of the other convex line (6) and the bottom (6U). It is also possible to form by varying a certain amount of width, width and depth. When the height, width, and depth of the convex image line (6) and the bottom portion (6u) are varied by a certain amount, the convex image line (6) and the bottom portion (6U) constituting the third latent image (10). Each has the same transmittance. Therefore, the formed third latent image (10) is visually recognized as a watermark pattern with a constant transmittance.

DESCRIPTION OF SYMBOLS 1 Forming body 2 Base material 3 1st latent image 3a 1st pattern part 3b 1st background part 4 2nd latent image 4a 3rd pattern part 4b 2nd background part 5 Convex line 6 Convex line 6T Vertex 6L First side 6R Second side 6U Bottom 7 First element 7a First pattern element part 7b First background element part 8 Second element 8a Second pattern element part 8b 2nd background element part 9 Visible image 9a Visible pattern part 9b Visible background part 10 3rd latent image S S Anti-counterfeit printed matter X1 1st direction X2 2nd direction E1 1st observation angle E2 2nd observation Angle E3 Third observation angle Z region

Claims (6)

A plurality of first and second image-shaped elements different in color from the base material are arranged on a convex line formed on at least a part of the base material, and a pattern is formed by changing the observation angle. A special latent image pattern forming body in which a latent image composed of a portion and a background portion appears,
The convex lines are arranged with each convex line having two sides,
The first element is divided into a first pattern element part and a first background element part by partially different shapes,
The first pattern element portion is arranged on one side portion of the convex image line by the first color material to form the first pattern portion,
The second element is divided into a second pattern element part and a second background element part by partially different shapes,
The second pattern element portion is arranged on the other side portion of the convex line by a second color material having the same color as or different from the first color material to form a second pattern portion,
The first pattern element portion and the second pattern element portion , or the first background element portion and the second background element portion are on one side and the other side of the convex line. At least several
The first pattern element portion arranged on one side of the convex image line and the second background element portion arranged on the other side of the convex image line are arranged so as not to overlap, and ,
The first background element portion arranged on one side of the convex line and the second pattern element portion arranged on the other side of the convex line are arranged so as not to overlap,
When the substrate is tilted and observed, a plurality of the elements arranged at least on one side and the other side of the image line of the latent image is visually recognized as a moire pattern. Special latent image pattern formed body characterized by
In each of the convex lines forming the convex line, the second pattern element is formed by the second color material having a color different from the first color. The pattern element part has the same shape and size,
2. The special latent image pattern forming body according to claim 1, wherein, in the convex line, the first pattern element portion and the second pattern element portion are all arranged correspondingly at the same position. .   3. The special latent image according to claim 2, wherein the first background element portion is formed of the second color material, and the second background element portion is formed of the first color material. Image pattern forming body. In each of the convex lines constituting the convex line,
The first background element part and the second background element part have the same shape and size,
4. The special latent image pattern formed body according to claim 3, wherein the first background element portion and the second background element portion are all arranged at the same position in the convex line. 5. . In the concavo-convex shape of the substrate formed by the convex lines,
The third latent image, which is a watermark pattern having different transmittances with respect to the base material, is formed by changing at least one of the height, width, depth of the recess, and width of the recess. The special latent image pattern formed body according to any one of claims 1 to 4, wherein the special latent image pattern formed body is provided.   The first element or the second element includes at least one of an image line, a point group in which a plurality of points are arranged in the same direction, or a pixel group in which a plurality of pixels are arranged in the same direction. The special latent image pattern formed body according to any one of claims 1 to 5.

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