JP2013240963A - Special latent image formed body - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a special latent image formed body applied to valuable prints such as bank notes and passports for preventing forgery and duplication.SOLUTION: In a special latent image formed body, a parallel line having an uneven shape is arranged on a base material, and on the parallel line, a colored printing parallel line is arranged. The parallel line having the uneven shape is partially deformed to have a transmission factor different from that of the base material. Thus, when observation is performed from a first observation angle immediately above the base material, a visible image is visually recognized. When observation is performed from a second observation angle formed by tilting the base material, a first latent image is visually recognized. When observation is performed from a third observation angle formed by tilting the base material to a side opposite to that of the second observation angle, a second latent image is visually recognized. When the base material is observed under transmitted light, a second latent image is visually recognized.

Description

  The present invention relates to a special latent image forming body that is applied to valuable printed matter such as banknotes, passports, and securities for the purpose of preventing counterfeiting and duplication.

  Precious printed matter such as banknotes, passports, and securities is required to be difficult to forge or duplicate due to its nature. As measures against this, there are known ones in which fine lines are printed on a precious printed matter, and ones that have been subjected to a squeeze due to the thickness of the paper layer.

  Patent Document 1 discloses a watermark pattern having continuous gradation. It is possible to form a watermark pattern with continuously changing thickness by forming a paper pattern after placing a pattern mold with a stepwise change in thickness on a known paper machine. It becomes. When the prepared interleaving paper is observed under transmitted light, a watermark pattern having continuous gradation is visually recognized.

  Further, Patent Document 2 previously filed by the present applicant discloses a printed matter formed by combining a convex line and a fine image line. The printed material is provided with a convex line on the substrate, and a fine image line that forms the first latent image or the second latent image on each side of the convex line. One latent image is formed. In the produced printed matter, when the substrate is tilted, the first latent image composed of the fine image lines given to one side is visually recognized, and when the substrate is tilted in the opposite direction, the fine image lines given to the other side are displayed. When the substrate is viewed from the front, the first latent image is a composite pattern of the first latent image and the second latent image composed of fine lines applied to both sides. 3 latent image can be visually recognized.

Japanese Patent No. 3,19848 JP 2012-006168 A

  The interleaving paper disclosed in Patent Document 1 is manufactured using a paper machine and a special pattern mold, so that it is difficult to easily manufacture and the forgery prevention effect is extremely high. However, since the watermark pattern is formed by the thickness of the paper, it is basically visible under transmitted light, but in reality it is recognized even under reflected light.

  Moreover, in patent document 2, when a base material is tilted, a fine image line becomes the shadow of a convex line, and a several latent image image appears. However, the convex lines wear out in the process of distributing precious printed materials to the market, so that when the image is tilted, the fine lines do not become shadows of the convex lines, and the latent image is visible. There is a problem that the performance is lowered. Therefore, there is a demand for a printed matter to which an anti-counterfeit technology that can be discriminated by another method is provided in the same area.

  Accordingly, an object of the present invention is to provide a latent image that is concealed by a watermark pattern during observation under reflected light and that can be visually recognized by a plurality of determination methods in the same region on the substrate. To provide printed matter.

  In order to achieve the above-mentioned object, the invention according to claim 1 is provided with a latent image forming region having a plurality of images composed of uneven lines and colored lines on at least a part of a base material. In the image image forming area, a convex first element formed in a line shape in the first direction and a second material having a transmittance different from that of each of the plurality of first elements The element and the third element formed on one side of the first element have a third element formed of a colored coloring material on both sides of the convex shape of the first element. A first image element having a first color different from the first element, and a first background element having a second color different from the first element and the first color, and arranged in a first The third element arranged on the other side of the one element is divided into a second image element of the second color and a second background element of the first color, A first latent image is formed by arranging a plurality of third elements on the side, and a second latent image is formed by arranging a plurality of third elements on the other side. When a third latent image that is a watermark pattern is formed by a plurality of second elements having transmittance different from that of the base material, and observed from a first observation angle that is directly above the base material, When a visible image composed of a plurality of third elements is visually recognized and observed from a second observation angle with the substrate tilted, the first latent image is visually recognized, and the substrate is directed to the side opposite to the second observation angle. The second latent image is visually recognized when observed from a third observation angle inclined, and the third latent image is visually recognized when the substrate is observed under transmitted light. An image forming body.

  According to a second aspect of the present invention, in the special latent image forming body according to the first aspect, a plurality of the first elements are arranged at the first pitch.

  The invention according to claim 3 is the special latent image forming body according to claim 1 or 2, wherein at least one second element among the plurality of arranged second elements has a depth and / or A third latent image having a gradation is formed by a difference in transmittance between the second element having a different width and / or a different depth and / or width and the other second element. It is characterized by that.

  According to a fourth aspect of the present invention, in the special latent image forming body according to the first or second aspect, the depth and / or depth of at least one second element among the plurality of second elements arranged. Or the width is different.

  According to a fifth aspect of the present invention, in the special latent image image-forming body according to the fourth aspect, the depth and / or width is increased by changing the transmittance at two or more locations in at least one second element. A third latent image having a watermark pattern having gradation is formed by making the difference.

  Further, in the invention according to claim 6, in the special latent image forming body according to any one of claims 1 to 5, at least one first element among the plurality of arranged first elements is: In order to make the transmittance different from that of the other first elements, the third latent image is generated by the second element and the first element having a different height and / or width. It is formed.

  The invention according to claim 7 is the special latent image forming body according to claim 6, wherein the height and / or width is within at least one of the plurality of first elements arranged. Are different.

  Furthermore, the invention according to claim 8 is the special latent image forming body according to claim 7, wherein the transmittance and the width are different in at least one first element so that the height and / or the width are different. Due to the difference, a third latent image having a watermark pattern having gradation is formed.

  The special latent image forming body in the configuration of the present invention as described above is provided with a latent image that can be viewed under transmitted light in addition to a latent image that can be viewed by tilting the substrate. . Therefore, even when the convex line is worn during the distribution process, it is possible to determine whether the image is latent or not by observing the presence or absence of a latent image under transmitted light. In addition, the latent image that is visually recognized under transmitted light is formed by changing the cross-sectional shape of the convex line. Therefore, the printed matter of the present invention can form a latent image that can be observed while being tilted in the same region and a latent image that can be viewed under transmitted light.

  Furthermore, since the latent image that is visually recognized under transmitted light is formed by partially deforming the shape of the convex line, the watermark pattern is less under reflected light than a single formed body. It becomes possible to improve the concealment of the watermark pattern.

The top view which shows the special latent image image forming body (1) concerning this invention. The top view which shows the some image which a formation body (1) has. The top view and sectional drawing which show a 1st element (7). The top view and sectional drawing which show the other form of a 1st element (7). The top view which shows an example of a some 1st element (7). The figure which shows the cross-sectional shape of a 1st element (7). The top view and sectional drawing which show the 2nd element (8a). Sectional drawing which shows a 2nd element (8a). Sectional drawing which shows a 2nd element (8a). Sectional drawing which shows a 2nd element (8a). The top view and sectional drawing which show a 1st element (7). Sectional drawing which shows the 1a element (7a). The top view and sectional drawing which show a 3rd latent image image (6 '). The top view and enlarged view which show a 1st latent image (4). The top view and enlarged view which show a 2nd latent image (5). The top view and enlarged view which show a visible image (3). The figure which shows an example of an element. The figure which shows the viewpoint (E1, E2, E3, E4) at the time of observing a base material (2). The top view and sectional drawing at the time of observing a formation body (1) from the 1st observation angle (E1). The top view and sectional drawing at the time of observing a formation body (1) from the 2nd observation angle (E2). The top view and sectional drawing at the time of observing a formation body (1) from the 3rd observation angle (E3). The top view and sectional drawing at the time of observing the formed body (1) from the fourth observation angle (E4).

  FIG. 1 is a plan view showing an anti-counterfeit printed matter (S) (hereinafter referred to as “printed matter”) provided with a special latent image forming body (1) (hereinafter referred to as “formed product”) according to the present invention. is there. The printed matter (S) is a gift certificate as an example.

  The printed matter (S) is printed on a printable base material (2) such as paper, plastic card, etc., and information on the printed matter (S) such as store name and ticket type is based on commonly used inks such as cyan and magenta. Has been granted. 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 arranged, and the formed body (1) has a plurality of images.

  FIG. 2 is a plan view showing a plurality of images of the formed body (1). The formed body (1) includes a visible image (3) shown in FIG. 2 (a), a first latent image (4) shown in FIG. 2 (b), and a second latent image shown in FIG. 2 (c). It has an image image (5) and a third latent image (6) shown in FIG.

  The visible image (3) is an image that is visible when observed from directly above the substrate (2), and the first latent image (4) is observed with the substrate (2) tilted. This is an image that can be visually recognized. The second latent image (5) is an image that is visible when the substrate (2) is tilted to the opposite side to the time when the first latent image (4) is viewed. The third latent image (6) is a watermark pattern that is visible when the substrate (2) is observed under transmitted light.

  Each image (3, 4, 5, 6) of the formed body (1) is composed of different elements such as a printing element and an element formed by imparting an uneven shape to the substrate (2). Yes. Hereinafter, each element which comprises a formation body (1) is demonstrated in detail.

  FIG. 3 is a plan view and a sectional view showing the first element (7) which is a convex element, and FIG. 3 (a) is a plan view showing the first element (7). As shown to Fig.3 (a), the 1st element (7) is formed in multiple numbers in the area | region (Z) with which at least one part of the base material (2) was equipped.

  FIG. 3B is a cross-sectional view taken along the line A-A ′ of FIG. As shown in FIG. 3B, a plurality of convex first elements (7) are formed at a first pitch (P1) in the first direction (X1). Each of the plurality of first elements (7) has a first side (7L), a second side (7R), and a top (7T). The 1st pitch (P1) which arranges the 1st element (7) is the printing system, the substrate (2) to be used, and the 3rd element (9) printed on the 1st element (7) mentioned below. In consideration of the line width, 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 required for printing the third element (9) on the first element (7) cannot be sufficiently obtained, The line width of the third element (9) becomes narrow, and the visibility of the visible image (3), the first latent image (4), and the second latent image (5) decreases, which is not preferable.

  On the other hand, when the first pitch (P1) is larger than 800 μm, it is possible to identify each third element (9) printed on the first element (7) with the naked eye. When each image (3, 4, 5, 6) is visually recognized, noise is generated, which is not preferable. In FIG. 3 (a), the first pitch (P1) is shown as a constant pitch, but a part of the pitch may be different within the range of 400 to 1800 μm.

  Although the case where the first elements (7) are all arranged at the first regular pitch (P1), which is the same regular pitch, has been described, a random pitch is used for the plurality of first elements (7). It is also possible.

  FIG. 4 is a plan view and a sectional view showing another embodiment in which the first element (7) is arranged in the first direction (X1). As shown in FIG. 4A, the first elements (7) are arranged at a random pitch (PL) in the first direction (X1). FIG. 4B is a cross-sectional view taken along the line A-A ′ in FIG. In the case of arranging at a random pitch (PL), each of the pitches can be appropriately set within a range of 400 to 1800 μm, similarly to the range of the first pitch (P1) described above. is there. 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 first element (7) is described as being formed with the first pitch (P1).

  The width (W1) of the first element (7) 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 third element (9) described later. Is done. When the width (W1) of the first element (7) is less than 0.1 mm, it is not preferable because it is difficult to print the third element (9) on the first element (7).

  When the width (W1) of the first element (7) is wider than 1.0 mm, the first latent image (4) and the second latent image are formed when the printed matter (S) is tilted. It becomes difficult to clearly see (5), which is not preferable.

  The height (h1) of the first element (7) is appropriately set within the range of 30 to 70 μm in consideration of the first pitch (P1) and the width of the third element (9) described later. Is possible. When the height (h1) is less than 30 μm, it is difficult to clearly see the first latent image (4) and the second latent image (5) when the printed matter (S) is tilted. Absent.

  Further, when the height (h1) of the first element (7) is higher than 70 μm, it is difficult to print the third element (9) on the first element (7), which is not preferable.

  The first element (7) is linear, but not limited to a straight line, and if the third element (9) can be printed on the first element (7), the wavy line, the broken line, etc. Is possible.

  Further, it goes without saying that the shape formed by assembling a plurality of first elements (7) can be various shapes shown in FIG. 5 as long as it can be formed in the region (Z). There is no.

  Furthermore, the cross-sectional shape of the first element (7) is not limited to the shape shown in the AA ′ cross-sectional view of FIG. 3 described above, and a third print element, which will be described later, is formed on the first element (7). If it is possible to form the element (9), various cross-sectional shapes shown in FIG. 6 are possible. FIG. 6 is a cross-sectional view of the base material (2) cut in parallel to the first direction (X1), as in FIG. 3 described above.

  Next, the second element (8a), which is one of the elements constituting the formed body (1), will be described. FIG. 7 is a plan view and a cross-sectional view showing the second element (8a), and FIG. 7 (a) is a plan view showing the second element (8a). As shown to Fig.7 (a), the 2nd element (8a) is formed between each element of a some 1st element (7).

  FIG. 7B is a B-B ′ cross-sectional view in FIG. The 2nd element (8a) in this invention is an area | region where the transmittance | permeability is higher than the base material (2) formed between two adjacent 1st elements (7). The width (W2) of the second element (8a) is 200 μm in consideration of the first pitch (P1) where the first element (7) described above is arranged and the width of the third element (9) described later. It can be set as appropriate within a range of ˜800 μm. When the width (W2) is less than 200 μm, it is difficult to print the third element (9) on the first element (7), which is not preferable.

  Further, when the width (W2) of the second element (8a) is set to 800 μm or more, the first latent image (4) and the second latent image (5) when the printed material (S) is tilted. ) Is difficult to see clearly, which is not preferable.

  As described above, the formed body (1) of the present invention can be visually recognized under transmitted light in addition to the latent image (4, 5) that can be viewed by tilting the base material (2). The latent image (6) is given. The first element (7) and the second element (8a) described above change the transmittance with the base material (2) by making the cross-sectional shapes partially different. Therefore, by arranging a plurality of first elements (7) and / or second elements (8a) having partially different cross-sectional shapes, a third latent image that is a watermark pattern that is visible under transmitted light. The image (6) can be applied to the formed body (1).

  First, the second element (8a) will be described. The first element (7) having a partially different cross-sectional shape will be described later. As shown in FIG. 7A, a third latent image (6) having a character shape of “NPB” is formed on the base material (2). As shown in the enlarged view of FIG. 7A, the second element (8a) is disposed between the plurality of first elements (7).

  FIG. 7B is a B-B ′ cross-sectional view in FIG. The bottom (8b), which is a part of the substrate (2), has the same cross-sectional shape, but the second element (8a) has a cross-section corresponding to the third latent image (6). The shape changes.

  As shown in FIG. 7B, the second element (8a) and the bottom (8b) have different depths. In the present invention, the width (W2) and depth (h1) of the bottom portion (8b) are used as references, and the depth (h2) of the second element (8a) is the reference of the bottom portion (8b) serving as a reference. The depth from the position (M) will be described below. By making the second element (8a) deeper than the bottom (8b), the transmittance of the second element (8a) and the bottom (8b) is different, and when observed under transmitted light, the bottom (8b) The deep second element (8a) is visible brighter (whiter) than the bottom (8b). Therefore, the third latent image (6) visible under the transmitted light described above is formed by appropriately forming the plurality of second elements (8a) according to the shape of the third latent image (6). Is formed.

  In FIG. 7B, the depth (h2) of the second element (8a) forming the third latent image (6) is constant. When the depth (h2) and the width (W2) of the second element (8a) are constant, the third latent image (6) that is visible under transmitted light is a solid image having no gradation. Visible as a watermark pattern. When the depth (h2) and width (W2) of the second element (8a) forming the third latent image (6) are changed, the third latent image that can be visually recognized under transmitted light. The image (6) is visually recognized as a watermark pattern having gradation, which will be described later.

  The depth (h2) of the second element (8a) is 30 μm to 70 μm. When the thickness is 30 μm or less, the transmittance with the bottom (8b) does not change so much, and the third latent image (6) is not clearly seen under transmitted light.

  When the thickness is 70 μm or more, it is difficult to print the third element (9), which is a print image line, on the first element (7), which is not preferable. Furthermore, the durability of the printed matter (S) is lowered because the second element (8a) becomes thin, which is not preferable.

  In FIG. 7 described above, the width (W2) of the second element (8a) and the bottom (8b) is constant, but by changing the depth, the transmittance with the base material (2) is changed, A third latent image (6) was formed. However, as long as the transmittance of the base material (2) and the second element (8a) can be changed, the cross-sectional shape is not limited to that shown in FIG. It is.

  FIG. 8 is a diagram illustrating another cross-sectional shape of the second element (8a) forming the third latent image (6). 8 (a), 8 (b), 8 (c), and 8 (d) show the substrate (2) in the first direction (X1) in the same manner as the sectional view of FIG. 7 (b). It is sectional drawing cut | disconnected in parallel with respect to]. The second element (8a) described above is not limited to a cross-sectional shape in which the depth of the second element (8a) is deeper than the bottom (8b), and various shapes can be employed.

  As shown in FIG. 8A, FIG. 8B, FIG. 8C, and FIG. 8D, the width (W2) of the second element (8a) is smaller than that of the bottom (8b). Alternatively, the transmittance of the second element (8a) and the bottom part (8b) can be increased by making the depth (h2) of the second element (8a) deeper or shallower than the bottom part (8b). Can be changed. In any shape, the second element (8a) is viewed brighter than the bottom (8b) when the transmittance is higher than the bottom (8b), and conversely from the bottom (8b) when the transmittance is low. Visible dark.

  In FIG. 8, the second element (8a) is formed by changing both the width (W2) and the depth (h2), but the width (W2) and the depth (h2) Even when only one of them is changed, since there is a change in transmittance, it is possible to form the third latent image (6).

  Furthermore, it is also possible to vary the width and depth in one second element (8a). FIG. 9A is a diagram for explaining another cross-sectional shape of the second element (8a), and FIGS. 9B and 9C are cross-sectional views taken along line AA ′ in FIG. 9A. It is a figure and BB 'sectional drawing. As shown in FIG. 9B and FIG. 9C, by changing the width and depth in one second element (8a), the second element at the AA ′ cross-sectional position ( It is also possible to change the transmittance between 8a) and the second element (8a) at the BB ′ cross-sectional position.

  Furthermore, as another cross-sectional shape, the depth (h2) can be changed in one second element (8a). Fig.10 (a) is a figure explaining the other cross-sectional shape of a 2nd element (8a). FIG. 10B is a cross-sectional view taken along the line B-B ′ in FIG. As shown in FIG. 10B, the bottom (8b) has a constant depth with respect to the second direction (X2).

  FIG. 10C, FIG. 10D, and FIG. 10E are cross-sectional views taken along the line C-C ′ in FIG. As shown in FIG. 10C, FIG. 10D, and FIG. 10E, the second element (8a) is obtained by changing the depth in the second direction (X2) in multiple steps or gradually. It is also possible to change the transmittance with the bottom (8b).

  Next, the first element (7) having a partially different cross-sectional shape will be described. FIG. 11 is a plan view and a cross-sectional view showing a first element (7) having a partially different cross-sectional shape. In FIG. 11A, as an example, three first elements (7) are arranged in the first direction (X1). The first element (7) consists of a 1a element (7a) and / or a 1b element (7b).

  FIGS. 11B, 11C, and 11D are cross-sectional views taken along line A-A ′ in FIG. In the plurality of first elements (7), the first b elements (7b) all have the same cross-sectional shape. On the other hand, the cross-sectional shape of the 1a element (7a) changes corresponding to the third latent image (6). Hereinafter, in the present embodiment, when the first element (7) does not have the first a element (7a) having a different cross-sectional shape, the first element (7) is formed only from the first b element (7b). Will be described.

  As shown in FIG. 11B, the width (W1) of the 1a element (7a) is different from the 1b element (7b). In the present invention, the width (W1) and the height (h1) of the 1b element (7b) are used as a reference, and the height (h1) of the 1a element (7a) is the reference of the first 1b element (7b). The height of the element (7b) from the reference position (M) will be described below.

  As shown in FIGS. 11 (b), 11 (c) and 11 (d), the height (h1) of the 1a element (7a) is set to the height (h1) of the 1b element (7b). Or by making the width (W1) of the 1a element (7a) different from the width (W1) of the 1b element (7b), the 1a element (7a) and the 1b element (7b) If the transmittance of 7b) is different and the transmittance is higher than that of the 1b element (7b) when observed under transmitted light, the 1a element (7a) becomes the same as the first element (7b). It is brighter (whiter) than normal.

  On the other hand, when the transmittance is lower than that of the 1b element (7b), the 1a element (7a) is seen darker (black) than the 1b element (7b). Therefore, the third latent image (6) that is visible under the transmitted light described above is formed by appropriately forming the plurality of first a elements (7a) according to the shape of the third latent image (6). Is formed.

  Furthermore, as another cross-sectional shape, the first element (7a) can be formed by changing the height (h1) in one first element (7). 12A and 12B are a plan view and a cross-sectional view illustrating another cross-sectional shape of the 1a element (7a), and FIG. 12A is a plan view of the first element (7). The height of the 1b element (7b) shown in FIG. 12B is constant in the second direction (X2).

  FIGS. 12C, 12D, 12E, and 12F are cross-sectional views taken along the line C-C ′ in FIG. As shown in FIG. 12C, FIG. 12D, FIG. 12E, and FIG. 12F, the 1a element (7a) has a plurality of heights in the second direction (X2). It is also possible to change the transmittance with the 1b element (7b) by changing it gently.

  As with the second element (8a) described above, also in the first a element (7a), the width of the first a element (7a) is gradually increased within one first element (7). Alternatively, a narrowed shape is possible.

  Further, although not shown in the drawing, it is needless to say that the first element (7a) and the second element (8a) can be configured by variously combining the shapes described above. The third latent image (6) can also be formed by combining the above-described first element (7a) and second element (8a).

  Next, a method for forming the first element (7) and the second element (8a) will be described. Each element (7, 8a) is formed on the substrate (2) by embossing, intaglio printing, screen printing, squeezing or laser processing.

  The formation of each element (7, 8a) by embossing is performed by a known embossing machine using a concave mold and a convex mold that match the shape of each element (7, 8a).

  The formation of the first element (7) by intaglio printing or screen printing is performed by printing on the base material (2) using a known intaglio printing method or a printing plate and ink suitable for the known screen printing method. It is formed by the ink pile. When the first element (7) is formed by intaglio printing, screen printing and embossing, the formed first element (7) has a convex shape with respect to the base material (2). It is formed. Thereby, a 2nd element (8a) is formed between two adjacent 1st elements (7) with formation of a 1st element (7).

  The formation of each element (7, 8a) by squeezing is performed using a known paper machine capable of squeezing when the base material (2) is paper.

  Each element (7, 8a) is formed by laser processing by removing a part of the substrate (2) using a known laser processing apparatus. When formed by removing the periphery of the first element (7) by laser processing with respect to the base material (2), the removed region is thinner (concave shape) than the first element (7). )Become. Accordingly, the second element (8a) is formed between the two adjacent first elements (7) with the formation of the first element (7). Further, after the first element (7) is formed in advance by intaglio printing, screen printing, embossing, squeezing and laser processing, the space between the two adjacent first elements (7) is removed by laser processing. Thus, the second element (8a) can be formed.

  In addition, it is not preferable to form the first element (7a) and the second element (8a) forming the third latent image (6) by embossing. When the base (2) is paper and the 1a element (7a) and the second element (8a) are formed by embossing, the 1a element (7a) and the second element (8a) The fiber density is the same as that of the base material (2), and both have the same transmittance. Therefore, even when observed under transmitted light, the first (a) element (7a) and the second element (8a) and the base material (2) do not produce a difference in brightness, and can be visually recognized under transmitted light. 3 latent image (6) cannot be formed.

  However, in the case where the base material (2) is made of plastic or sheet-like resin, the embossing is performed in the manufacturing process, so that the first element (7a) and the second element (8a) The thickness changes from (2), and a difference in brightness occurs when observed under transmitted light. Therefore, the forming method of the first element (7a) and the second element (8a) for forming the third latent image (6) is appropriately set depending on the substrate (2) to be used.

  The depth (h2) and height (h1) and the width (W1, W2) of the 1a element (7a) and / or the second element (8a) forming the third latent image (6). If, for example, the height (h1) of the 2a element (7a) is all formed at the same height, the transmittance of the 1a element (7a) is all the same. Therefore, the third latent image (6) that is visible under transmitted light is visually recognized as a solid image having no gradation.

  On the other hand, the depth (h2) and the height (h1) and the width (W1, W2) of the first element (7a) and / or the second element (8a) forming the third latent image (6). Is changed, for example, when the height (h1) of the first 1a element (7a) is made different from each other, the first 1a element (7a) corresponding to the changed height is formed. ) Have different transmittances. Therefore, the third latent image (6) visible under transmitted light is visually recognized as an image having gradation.

  FIG. 13A is a plan view showing a third latent image (6 ′) that is a watermark pattern having gradation. A third latent image with a rich gradation can be obtained by varying the transmittance of the first element (7a) and / or the second element (8a) forming the third latent image (6 ′). (6 ′) is formed.

  FIG. 13A is a plan view and an enlarged view of the third latent image (6 '). The third latent image (6 ') is composed of a 1a element (7a) and a second element (8a).

  FIG. 13B is a B-B ′ cross-sectional view of the third latent image (6 ′) shown in FIG. The height of the 1a element (7a) forming the third latent image (6 ′) is gradually lowered in the first direction (X1), whereby the transmittance is increased and the brightness having gradation. Visible at. Further, the second element (8a) forming the third latent image (6 ′) gradually becomes shallower in the first direction (X1), so that the transmittance is lowered and the darkness having gradation is obtained. Visible. In this way, the third latent image (6 ′) having gradation is made different by changing the height of the plurality of first element (7a) and the depth of the second element (8a). It is formed.

  The cross-sectional shapes of the first-a element (7a) and the second element (8a) that form the third latent image (6 ′) are not limited to the cross-sectional shape shown in FIG. If the transmittance of the first element (7a) and the second element (8a) arranged in a plurality can be made different, the aforementioned FIGS. 7, 8, 9, 10, and 11 are used. 12 and the shape shown in FIG. 12, and can be formed by combining the shapes described above.

  In addition, in the element (7, 8a) whose height, depth, and width are changed in one element (7, 8a) shown in FIG. 9, FIG. 10, and FIG. In one element (7, 8a) corresponding to the change of the shape, the transmittance is different and light and shade are generated and visually recognized. As a result, it is possible to form the third latent image (6 ') having gradation.

  In order to make the third latent image (6 ′) a gradation image, at least the first element a in the first element (7) and the second element (8a) on the base material (2). A plurality of places where the transmittance of the element (7a) and / or the second element (8a) is different are necessary. Since there are a plurality of portions having different transmittances, when observed under transmitted light, light and shade are generated in one third latent image (6 '), which is visually recognized as a transmitted image having gradation.

  The third latent image (6, 6 ') is formed by partially varying the cross-sectional shape such as the width and depth of the first element (7) and / or the second element (8a). Thereby, the formed body (1) is applied to the printed material (S) distributed in the market, and the transmitted light is transmitted even when the first element (7) and / or the second element (8a) are worn in the distribution process. By observing the presence / absence of the third latent image (6, 6 ′) below, it is possible to determine authenticity. In addition, as other effects, since the cross-sectional shape is partially different, the latent image can be viewed in a tilted manner in the same region, and the latent image can be viewed under transmitted light. Can be formed.

  As described above, the formed body (1) of the present embodiment forms a plurality of 1a elements (7a) and / or second elements (8a) having different transmittances from the base material (2), thereby transmitting transmitted light. A third latent image (6, 6 ′) that can be visually recognized below can be provided.

  Next, the third element (9) that forms a latent image that can be viewed by tilting will be described. FIG. 14A is a plan view showing a first latent image (4) that can be viewed by tilting the base material (2), and FIG. 14B is a black frame in FIG. 14A. It is the schematic diagram which expanded the area | region shown by. In FIG. 14B, the third element (9) is actually disposed on both side portions (7L, 7R), but is omitted.

  As shown in FIG. 14 (b), the third element (9) arranged on the first side (7L) includes a first image element (9a1) and a first background element (9b1). . The first image element (9a1) is a first color different from the base material (2), and the first background element (9b1) is different from the base material (2) and the first color. The second color. The first image element (9a1) is composed of a first color material having a first color, and the first background element (9b1) is composed of a second color material having a second color. As described above, the third element (9) forming the first latent image (4) has the first image element (9a1) having the first color and the second color different from those of the substrate (2). ) And the first background element (9b1).

  When the first image element (9a1) and the first background element (9b1) are the same color as the substrate (2), the third element (9) printed on the substrate (2) is visually observed. It cannot be distinguished and visually recognized. Therefore, the first image element (9a1) and the first background element (9b1) 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 image element (9a1) is light red to form the first background element (9b1). It is also possible to make the color material dark red.

  In the present invention, for the color material forming the second latent image (5) 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 it is the same as the color relationship between the image element (9a1) and the first background element (9b1), a description thereof will be omitted.

  By arranging a plurality of first image elements (9a1), a first pattern portion (4a) in the first latent image (4) shown in FIG. 14 (a) is formed. Further, by arranging a plurality of the first background elements (9b1), the first background portion (4b) in the first latent image (4) shown in FIG. 14A is formed.

  Next, the second latent image (5) will be described. FIG. 15A is a plan view showing a second latent image (5) that is visible by tilting the substrate (2), and FIG. 15 (b) is a black frame in FIG. 15 (a). It is the schematic diagram which expanded the area | region shown by. FIG. 15B and FIG. 14B described above are enlarged schematic views of one of the same first elements (7). In FIG. 15 (b), the third element (9) is actually arranged on both sides (7L, 7R), but is omitted.

  As shown in FIG.15 (b), the 3rd element (9) arrange | positioned at a 2nd side part (7R) consists of a 2nd image element (9a2) and a 2nd background element (9b2). . The second image element (9a2) is the second color, and the second background element (9b2) is the first color. The second image element (9a2) is made of the second color material, and the second background element (9b2) is made of the first color material. As described above, the third element (9) forming the second latent image (5) has the second image element (9a2) with the first color and the second color different from those of the substrate (2). ) And the second background element (9b2).

  By arranging a plurality of second image elements (9a2), the second pattern portion (5a) in the second latent image (5) shown in FIG. 15 (a) is formed. Further, by arranging a plurality of second background elements (9b2), a second background portion (5b) in the second latent image (5) shown in FIG. 15 (a) is formed.

  Next, the visible image (3) will be described. FIG. 16A is a plan view showing the visible image (3), and FIG. 16B is a schematic diagram in which the area is enlarged by the black frame shown in FIG. FIG. 16B and the above-described FIGS. 14B and 15B are enlarged schematic views of one of the same first elements (7). The visible image (3) consists of all the third elements (9) arranged on the first side (7L) and the second side (7R). That is, the visible image (3) is arranged on the first latent image (4) composed of the third element (9) arranged on the first side (7L) and on the second side (7R). This is a composite image of the second latent image (5) composed of the third element (9).

  In addition, about another structure and arrangement | positioning of the 3rd element (9) arrange | positioned on the 1st element (7), Unexamined-Japanese-Patent No. 2012-006168 and Unexamined-Japanese-Patent No. 2012-006169 which the applicant applied previously. The configurations and arrangements described in Japanese Patent Application Nos. 2010-267219 and 2010-267219 may be employed. Therefore, the description here is omitted.

  In the present invention, the third element (9) 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. 17 is a diagram showing an example of the third element (9) in the present invention. The image line is a straight line shown in FIG. 17A, a broken line shown in FIG. 17B, a wavy line shown in FIG. 17C, and a broken wavy 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. 17 (e), an elliptical shape shown in FIG. 17 (f), and a triangular shape shown in FIG. 17 (g). Further, the pixels may be rotated and arranged as shown in FIG. 17 (g), or may be formed in a character shape as shown in FIG. 17 (h). Furthermore, as shown in FIGS. 17 (i) and 17 (j), in one element, at least two types of image lines, halftone dots, or pixels may be combined and arranged in the same direction.

  Next, the observation angle for visually recognizing each image described above will be described. FIG. 18 is a diagram showing viewpoints (E1, E2, E3, E4) when observing the base material (2) provided with the formed body (1). In addition, the 1st element (7) is arrange | positioned in the 1st direction (X1) on a base material (2).

  In the present invention, when the viewpoint is in the positional relationship shown in (E1) with respect to the base material (2), it is assumed that the observation is made from the first observation angle (E1), and the viewpoint is in the positional relationship shown in (E2). It is assumed that the observation was made from the second observation angle (E2), and the viewpoint was observed from the third observation angle (E3) when the viewpoint was in the positional relationship shown in (E3). On the other hand, it is the positional relationship shown in (E4), and when observed under transmitted light, it is assumed that the observation is made at the fourth observation angle (E4).

  Next, the visual recognition principle when the formed body (1) is observed from each observation angle (E1, E2, E3, E4) will be described. FIG. 19 is a plan view and a cross-sectional view of the formed body (1) when observed from the first observation angle (E1). In FIG. 19, it is assumed that the third latent image (6) composed of the plurality of second elements (8a) shown in FIG. 7 is given. Therefore, the 1st element (7) formed in the base material (2) is the 1b element (7b) of all the same shapes.

  As shown in FIG. 19, when the base material (2) is observed from the first observation angle (E1), both side portions (7L, 7R) of the first element (7) are adjacent to each other. It is visible without being a shadow of the element 1b (7b). Therefore, the visible image (3) which consists of a some 3rd element (9) is visually recognized.

  FIG. 20 is a plan view and a cross-sectional view of the formed body (1) when observed from the second observation angle (E2). As shown in FIG. 20, when the base material (2) is observed from the second observation angle (E2), the first side portion (7L) of the 1b element (7b) is adjacent to the adjacent first 1b. It can be visually recognized without being a shadow of the element (7b). On the other hand, the second side portion (7R) becomes a shadow of the adjacent 1b element (7b) and cannot be visually recognized.

  Therefore, when the substrate (2) is observed from the second observation angle (E2), only the third element (9) arranged on the first side (7L) is visible, and a plurality of A first latent image composed of a first pattern portion (4a) composed of a first image element (9a1) and a first background portion (4b) composed of a plurality of first background elements (9b1) The image (4) is visually recognized. In the first latent image (4), the first pattern portion (4a) is visually recognized in the first color, and the first background portion (4b) is visually recognized in the second color.

  FIG. 21 is a plan view and a cross-sectional view of the formed body (1) when observed from the third observation angle (E3). As shown in FIG. 12, when the substrate (2) is observed from the third observation angle (E3), the second side portion (7R) of the first b element (7b) is adjacent to the adjacent first 1b. It can be visually recognized without being a shadow of the element (7b). On the other hand, the first side part (7L) becomes a shadow of the adjacent 1b element (7b) and cannot be visually recognized.

  Therefore, when the base material (2) is observed from the third observation angle (E3), only the third element (9) disposed on the second side portion (7R) is visible, and a plurality of A second latent image composed of a second pattern portion (5a) composed of the second image element (9a2) and a second background portion (5b) composed of a plurality of second background elements (9b2). Image (5) is visually recognized. In the second latent image (5), the second pattern portion (5a) is visually recognized in the second color, and the second background portion (5b) is visually recognized in the first color.

  Note that a third latent image (6), which is a transmission image, is formed on the formed body (1), but the first observation angle (E1) and the second observation angle (E2) under reflected light. ) And the third observation angle (E3), the visible image (3), the first latent image (4), and the second latent image (5) are mainly visually recognized. Therefore, the presence of the third latent image (3 ′) is not recognized.

  FIG. 22 is a plan view and a cross-sectional view of the formed body (1) when observed from the fourth observation angle (E4). As described above, the third latent image (6) in FIG. 22 is formed by a plurality of second elements (8a). As shown in FIG. 22, the second element (8a) and the bottom (8b) have different depths. Therefore, when the substrate (2) is observed from the fourth observation angle (E4), the second element (8a) has a higher transmittance than the substrate (2) and the bottom (8b), and the base Compared with the material (2), the 1b element (7b) and the bottom (8b), it is visible brightly. Therefore, the third latent image (6) formed by the plurality of second elements (8a) is visually recognized as a transmission image.

  In addition, when the 1b element (7b) and the bottom part (8b) are formed by embossing, the 1b element (7b) and the bottom part (8b) have the same transmittance. Therefore, when observed from the fourth observation angle (E4), the base material (2), the 1b element (7b), and the bottom (8b) are visually recognized with the same brightness, and the third latent image ( 6) is visible brighter than the substrate (2), the 1b element (7b) and the bottom (8b).

  On the other hand, when the 1b element (7b) and the bottom (8b) are formed by sweeping or laser processing, the 1b element (7b) and the bottom (8b) have different transmittances. Therefore, when observed from the fourth observation angle (E4), the substrate (2), the 1b element (7b), and the bottom (8b) are visually recognized with different brightness. For example, in the formed body (1) shown in FIG. 22, when the 1b element (7b) and the bottom part (8b) are formed by scavenging, the bottom part (8b) is compared with the 1b element (7b). Since the substrate (2) is thin, the transmittance is increased. Therefore, the 1b element (7b) is visually recognized as dark and the bottom (8b) is visually recognized as bright.

  For the sake of brevity, although not shown in the plurality of third elements (9), when actually observed under transmitted light at the fourth observation angle (E4), the aforementioned visible image ( The third latent image (6) is visually recognized within 3).

Hereinafter, the present invention will be described more specifically with reference to Example 1, but the present invention is not limited thereto. As Example 1, the formed body (1) shown in FIG. The substrate (2) had a basis weight of 83 g / m ₂ and a paper thickness of 85 μm, and was formed using a known paper machine. The color of the base material (2) was changed to egg yolk by appropriately adding a pigment and an additive amount in order to set the opacity to 80% (JIS-P8149).

  In Example 1, the third latent image (6) was formed only by the second element (8a). Therefore, all the 1st elements (7) were formed only with the 1b element (7b).

  The 1b element (7b) was linear with a width (W1) of 300 μm and a height (h1) of 50 μm, and the first pitch (P1) was 500 μm.

  The widths (W2) of the second element (8a) and the bottom (8b) were both 200 μm linear. The thickness of the second element (8a) is 20 μm (digital linear gauge DG-925, manufactured by Ono Sokki), and the thickness of the bottom (8b) is 40 μm (digital linear gauge DG-925, manufactured by Ono Sokki). did.

  The second element (8a) had an opacity of 60% (JIS-P8149), and formed a higher transmittance than the base material (2), the first b element (7b), and the bottom (8b).

  The element (7b), the second element (8a), and the bottom part (8b) of the 1b are formed by a known sweeping method in the step of manufacturing the substrate (2) using a known long paper machine. did.

  The third element (9) was formed as an image line having a constant width of 130 μm shown in FIGS. 14 (b) and 14 (b). The first image element (9a1) and the second background element (9b2) are printed using offset ink (best cure indigo made by T & K TOKA), and the first background element (9b1) and the second image are printed. Element (9a2) was printed using an offset ink (Best Cure Red from T & K TOKA). The third element (9) was formed by printing on the 1b element (7b) with an offset printing machine (EP-60 manufactured by Shimogaki Iron Works).

  When the formed body (1) produced in Example 1 was observed with the naked eye from the first observation angle (E1), a visible image (3) was visible. Next, when the formed body (1) was observed from the second observation angle (E2), the first pattern portion (4a) in the first latent image (4) was visually recognized in cyan, 1 background portion (4b) was visible in magenta. Next, when the formed body (1) was observed from the third observation angle (E3), the second pattern portion (5a) in the second latent image (5) can be visually recognized in magenta color. The background portion (5b) was visible in cyan. Furthermore, when the formed body (1) was observed under transmitted light at the fourth observation angle (E4), the third latent image (6) having a character shape of “NPB” was visually recognized as a transmitted image. .

DESCRIPTION OF SYMBOLS 1 Special latent image formation body 2 Base material 3 Visible image 4 1st latent image 4a 1st pattern part 4b 1st background part 5 2nd latent image image 5a 2nd pattern part 5b 2nd background Part 6, 6 ′ third latent image 7 first element 7a 1a element 7b 1b element 7L first side part 7R second side part 7T top part 8a second element 8b bottom part 9 first 3 elements (printed lines)
9a1 1st image element 9b1 1st background element 9a2 2nd image element 9b2 2nd background element S Anti-counterfeit printed matter Z Latent image image forming area E1 1st observation angle E2 2nd observation angle E3 3rd Observation angle E4 Fourth observation angle h1, h2 Height W1, W2 Width

Claims (8)

A latent image forming region having a plurality of images composed of uneven lines and colored lines on at least a part of the substrate,
In the latent image forming region, a convex first element formed in a line shape in a first direction;
A second element having a transmittance different from that of the base material between the elements of the plurality of first elements;
On both sides of the convex shape of the first element, there is a third element formed of a colored color material,
The third element disposed on one side of the first element includes a first image element having a first color different from the first element, the first element, and the first element. Is divided into a first background element of the second color different from the color of
The third element arranged on the other side of the first element is divided into a second image element of the second color and a second background element of the first color. Arranged,
By arranging a plurality of the third elements on the one side, a first latent image is formed,
By arranging a plurality of the third elements on the other side, a second latent image is formed,
A third latent image having a watermark pattern is formed by the plurality of second elements having different transmittances from the base material,
When observing from the first observation angle that is directly above the substrate, a visible image consisting of a plurality of third elements is visually recognized,
When observing from the second observation angle tilted the substrate, the first latent image is visually recognized,
When observing from a third observation angle in which the substrate is tilted to the side opposite to the second observation angle, the second latent image is visually recognized.
When the substrate is observed under transmitted light, the third latent image is visually recognized.   2. The special latent image forming body according to claim 1, wherein a plurality of the first elements are arranged at a first pitch. Among the plurality of second elements arranged, at least one second element is different in depth and / or width from other second elements,
The third latent image having gradation is formed by a difference in transmittance between the second element having the different depth and / or width and the other second element. Item 3. The special latent image forming body according to Item 1 or 2.   3. The special latent image forming body according to claim 1, wherein a depth and / or a width are different in at least one second element among the plurality of second elements arranged. 5.   In the at least one second element, the third latent image is a watermark pattern having a gradation by varying the depth and / or the width by changing the transmittance at two or more places. The special latent image forming body according to claim 4, wherein: Among the plurality of arranged first elements, at least one first element has a different height and / or width in order to make the transmittance different from that of the other first elements,
6. The special as claimed in claim 1, wherein the third latent image is formed by the second element and the first element having a different height and / or width. Latent image forming body.   The special latent image forming body according to claim 6, wherein the height and / or the width are different in at least one of the plurality of arranged first elements.   In the at least one first element, the transmittance is different at two or more places, and the third latent image having a gradation pattern is formed by different height and / or width. 8. The special latent image forming body according to claim 7, wherein the special latent image forming body is formed.

Images