JP2014140984A - Special latent image form - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a special latent image form designed not to visibly recognize a latent image only under a limited observation condition but to vary latent images between observation under reflected light and observation under transmitted light, and thus having high true-false determination and forgery prevention effects.SOLUTION: The special latent image form is constructed in such a manner that a convex streak is disposed on a base material, colored parallel lines are arranged thereon, a transmittance is varied between the base material and the convex shape by changing a width and/or a depth between convex shapes, thus when observation is made from a first observation point directly above the base material, a visible image is viewed, when observation is made from a second observation point oblique to the base material, a first latent image is viewed, when observation is made from a third observation point under transmitted light with respect to the base material, a second latent image is viewed.

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 precious printed matter, and ones that have been subjected to squeezing due to the thickness of the paper layer.

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

  In addition, Patent Document 2 previously filed by the applicant of the present application includes a technique that allows a latent image to be visually recognized by inclining and observing under reflected light. Various line strokes or halftone dots with a certain interval on a material having an uneven shape formed by embossing at least one of various line patterns or relief patterns representing patterns by different angles A latent image pattern formed body is disclosed in which at least one of the lines is printed parallel to or inclined with respect to a portion constituting a portion other than the above-described concavo-convex pattern.

Japanese Patent No. 3198488 Japanese Patent No. 2615401

  Since the interleaving paper disclosed in Patent Document 1 is produced using a paper machine, it is difficult to produce easily and the effect of preventing forgery 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.

  Further, in Patent Document 2, a latent image formed of a concavo-convex shape is visually recognized when a printed image line is formed on a material having a concavo-convex shape formed by printing or the shape of a base material and is tilted and observed under reflected light. However, there is a problem in that the visibility of the latent image is deteriorated due to wear of the convex portion and the printed image line in the process of distributing as the above-mentioned valuable printed matter. Therefore, there is a demand for a printed matter provided with a forgery prevention technique that enables another authenticity determination method in the same area as the forgery prevention technique using the uneven shape.

  Therefore, the present invention aims to solve the above-described problems, and it is not possible to visually recognize a latent image only under limited observation conditions. The latent image can be visually recognized when observing the image, and the latent image that can be visually recognized is different between observation under transmitted light and reflected light. The purpose is to propose a body.

  In order to achieve the above-mentioned object, the invention according to claim 1 is provided with a latent image forming area comprising a latent image portion and a background portion arranged behind the latent image portion on at least a part of the substrate, A plurality of first elements having a convex shape are arranged in the first direction at the first pitch in the latent image portion, and the first elements are arranged in the first direction at the first pitch in the background portion, A plurality of first elements in the latent image portion are arranged at a phase different from that of the first element, and a second element having a transmittance different from that of the substrate is arranged between each of the plurality of first elements, and the latent image portion and the background portion Includes a plurality of third elements each having a different color from the first element at the second pitch, and the third element overlaps the first element in the latent image portion and / or the background portion. A first latent image is formed, and a second latent image that is a watermark pattern is formed by a plurality of second elements having transmittance different from that of the substrate. The first latent image is visually recognized when the substrate is tilted and observed, and the second latent image is visually recognized when the substrate is observed under transmitted light. Is the body.

  According to a second aspect of the present invention, in the special latent image forming body according to the first aspect, at least one of the plurality of second elements arranged has a depth and / or a width. Unlike the other second elements, a second latent image having a gradation is formed by the difference in transmittance between the second element having a different depth and / or width and the other second element. It is characterized by that.

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

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

  Further, the invention according to claim 5 is the special latent image forming body according to any one of claims 1 to 4, wherein at least one first element among the plurality of arranged first elements is: In order to make the transmittance different from the other first elements, the second latent image is formed by the second element having a different height and / or width and the second element and the first element having a different height and / or width. It is formed.

  The invention according to claim 6 is the special latent image forming body according to claim 5, wherein the height and / or the width are set in at least one of the plurality of arranged first elements. Are different.

  Furthermore, the invention according to claim 7 is the special latent image forming body according to claim 6, wherein the transmittance and the width are different in at least one first element so that the height and / or the width is different. Due to the difference, a second 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 newly provided with a latent image that can be visually recognized under transmitted light, in addition to a latent image that can be viewed with inclination under reflected light. Yes. Therefore, by observing the presence or absence of the latent image under the transmitted light, even if the latent image that can be viewed with tilting under the reflected light becomes invisible due to wear of the convex lines in the distribution process, Authenticity discrimination can be performed.

  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 special latent image forming body of the present invention is camouflaged by the convex line and the printed image line so that the presence of the latent image is a cracked pattern. Compared to a single printed matter, it is possible to improve the concealment property of the latent image that is a crease pattern.

The top view which shows an example of the special latent image image formation body (1) concerning this invention. The schematic diagram which shows a formation area (3). The figure which shows the observation point (L1, L2, L3) at the time of observing a formation area (3). The top view which shows a 1st pattern (4). The figure which shows the cross-sectional shape of a 1st element (5). The figure which shows an example of a pixel shape. The top view which shows the 1st element (5) which is a linear drawing line shape. The top view which shows a latent-image part (12) and a background part (13). The top view which shows a latent-image part (12) and a background part (13). The top view and sectional drawing which show a 2nd pattern (6). The figure explaining other cross-sectional shapes of a 2nd element (7). The top view and sectional drawing of one 2nd element (7) from which width differs. The top view and sectional drawing of one 2nd element (7) from which depth differs. The top view and sectional drawing of the 1st element (5) from which partial cross-sectional shape differs. The top view and sectional drawing which show the other cross-sectional shape of the 1a element (5a). The top view and sectional drawing of the 2nd latent image image (11 ') which has a gradation. The top view which shows a 3rd pattern (8). The figure which shows the visual recognition principle of a 3rd element (9). Sectional drawing of arrangement | positioning with which the 3rd element (9) overlaps with the base material (2) in which the 1st element (5) of the shape shown in FIG.5 (b) was formed. The schematic diagram which shows the state with which the 3rd element (9) overlaps about half of the observation part (V) of a 1st element (5), and the remainder overlaps with the flat part of a base material (2). The figure explaining 1st arrangement | positioning. The figure explaining 2nd arrangement | positioning. The figure explaining 3rd arrangement | positioning. The figure which shows an example of arrangement | positioning which a 3rd element (9) does not overlap with a 2nd element (7). The figure which shows an example of the arrangement | positioning which all the 3rd elements (9) overlap with a 2nd element (7). The figure which shows an example of arrangement | positioning with which a 3rd element (9) partially overlaps with a 2nd element (7).

  FIG. 1 is a plan view showing an example of a special latent image forming body (1) (hereinafter referred to as “formed body”) in the present invention. The formed body (1) has a latent image formation region (3) (hereinafter referred to as “formation region”) in which the latent image of the present invention is formed on at least a part of the substrate (2). Yes. As shown in FIG. 1, necessary information such as fees, characters, and other patterns are applied to areas other than the formation area (3) by a known printing method (for example, offset printing, intaglio printing, etc.). May be.

  As the substrate (2) in the present invention, paper sheets such as high-quality paper, coated paper, and art paper can be used. However, since a convex shape is necessary to form the two latent image images that are the feature of the present invention in the same region, the thickness of the substrate (2) is preferably 20 μm to 1000 μm, and preferably 50 μm to 300 μm is preferable. Moreover, a film, a plastic, those composite materials, etc. can also be used.

  FIG. 2A shows a formation region (3) of the formed body (1) of the present invention. As shown in FIG. 2B, the formation region (3) is adjacent to the first pattern (4) composed of a plurality of convex first elements (5) on the substrate (2). A second pattern (6) consisting of a plurality of concave second elements (7) formed between one element (5) is formed, and a substrate as shown in FIG. 2 (c) A third pattern (8) composed of a plurality of third elements (9) having a different color from (2) is formed in combination.

  When the formation region (3) is observed from directly above (hereinafter referred to as “first observation point (L1)”), as shown in FIG. The third pattern (8) can be visually recognized as a visible image, but when viewed from an oblique direction (hereinafter referred to as “second observation point (L2)”), as shown in FIG. The arrangement of the first element (5) and the third element (9) results in a portion where the color of the third pattern (8) can be visually recognized and a portion where the color of the third pattern (8) cannot be visually recognized. One latent image (10) “A” is visible.

  Further, when the formation region (3) of the present invention is observed with transmitted light (hereinafter referred to as “third observation point (L3)”), the thickness of the base material (2) is about the second pattern (6). Since it is thin, it can be visually recognized as a penetration image because of its high light transmittance, so that “10” as the second latent image (11) can be visually recognized as shown in FIG. That is, the formed body (1) includes a formation region (3) in which three different images can be visually recognized by an observation method. Details of the visual recognition principle of each latent image will be described later. Next, the first pattern (4), the second pattern (6), and the third pattern (8) formed in the formation region (3) will be described.

(First pattern)
The first pattern (4) will be described. As shown in FIG. 4A, the first pattern (4) is formed by arranging a plurality of _first elements (5) at a first pitch (P ₁ ) in the first direction (S ₁ ). . In the present invention, the “first direction” is a direction in which the first element (5) is disposed on the base material (2).

  As shown in FIG. 4B, which is a cross-sectional view taken along the line A-A 'of FIG. 4A, the first element (5) is composed of a convex image line. The first element (5) is not limited to the semicircular cross-sectional shape, and may have a cross-sectional shape shown in FIGS. 5 (a) and 5 (b).

  As a method for forming the first element (5) having a convex shape, there are known printing methods (for example, intaglio printing and screen printing) that can obtain embossing and a printed image line having a bulge. Also, the first element (5) can be formed by removing the others to form a convex shape and leaving the convex shape. For example, it can be formed by removing a part of the substrate or the base material (2) in the paper making process.

  The configuration of the first element (5) is not limited to the shape shown in FIGS. 4 and 5, and the entire surface of the convex shape can be observed when observed from the first observation point (L1). In the case of a convex shape when observed from the second observation point (L2), any shape may be used as long as the surface on the near side can be observed and the surface on the back side cannot be observed. The appearance of the convex surface when observed from the second observation point (L2) will be described later.

  In FIG. 4, the first element (5) is composed only of an image line, but is not limited thereto, and may be composed of an image line, at least one of a plurality of pixels, or a combination thereof. In the present invention, “image line” means a straight line, a broken line, a wavy line, etc., and “pixel” means a character, number, symbol, figure, mark, or the like having a predetermined shape.

  FIG. 6 is an example showing the shapes of the pixels, but is not limited to these shapes. However, when the first element (5) is formed using a plurality of pixels, it is necessary to arrange the plurality of pixels so as to be visually recognized as an image line by the naked eye. Hereinafter, the present embodiment will be described using an example in which the first element (5) configured by a straight line shown in FIG. 7 is arranged.

The first pitch (P ₁ ) shown in FIG. 7 is not limited, but the formed body (1) of the present invention is formed on the precious printed matter as described above, and from the second observation point (L2). When observing the first latent image (10), the first pitch (P ₁ ) is preferably formed in the range of 80 μm to 1000 μm. Within the above range, the first elements (5) are regularly arranged at a constant pitch.

Even if the first pitch (P ₁ ) is wider than 1000 μm, the first latent image (10) can be visually recognized, but the first latent image (10) for forming the first latent image (10) can be viewed. Since the pattern (4) of 1 becomes large and is restricted by the design constituting the precious printed matter, for example, other printed designs, it is not preferable.

Although it is possible to make the first pitch (P ₁ ) narrower than 80 μm, there is a problem of processing accuracy of the first element (5), and the first element (5) and the third element described later. The arrangement (9) is not preferable because high accuracy is required for alignment.

The width of the first element (5) in the first direction (S ₁ ) is defined as the width (W ₁ ) of the first element (5). The width (W ₁ ) of the first element (5) can be divided into a later-described latent image portion (12) and a background portion (13), and the first latent image (10) can be clearly seen. Thus, it is formed corresponding to the _first pitch (P ₁ ).

In order to form the first latent image (10) with good visibility, the range of the width (W ₁ ) of the first element (5) is _{1 with} respect to the first pitch (P ₁ ). A width range of / 5 to 4/5 is preferable. For example, when the first pitch (P ₁ ) is 80 μm, the width (W ₁ ) of the first element (5) is 16 μm to 64 μm, When the first pitch (P ₁ ) is 1000 μm, the width (W ₁ ) of the first element (5) is 200 μm to 800 μm, so that the first element with respect to the first pitch (P ₁ ) The width (W ₁ ) of (5) may be appropriately adjusted in view of the visibility of the first latent image (10) after printing a third element (9) described later.

The height (h ₁ ) of the convex first element (5) is formed in the range of 10 to 100 μm.

Even if the height (h ₁ ) of the first element (5) is lower than 10 μm, the first latent image (10) can be formed, but the first latent image (10) can be visually recognized. This is not preferable because the range becomes narrow. Further, the height (h ₁ ) of the first element (5) can be made higher than 100 μm, but the base material (2) becomes thicker than necessary, resulting in a problem that the processing efficiency is deteriorated. It is not preferable.

  The first pattern (4) composed of the first element (5) described above has a latent image portion because the phase of the regularly arranged first elements (5) is partially different. It is divided into (12) and background part (13).

  FIG. 8A is a plan view showing the latent image portion (12) and the background portion (13). In the present invention, the latent image portion (12) is a first pattern (4) configured by partially different phases of the regularly arranged first elements (5). The background portion (13) is a portion that becomes the background with respect to the latent image portion (12). Note that the first latent image is not limited to the letter “A” shown in FIG. 8A, and may be formed of numbers, symbols, figures, marks, and the like.

  FIG. 8B is an enlarged view of a portion surrounded by a dotted line in FIG. 8A, and the first element (5) constituting the latent image portion (12) is called a latent image element (12A). The first element (5) constituting the background part (13) is referred to as a background element (13A).

As shown in FIG. 8B, the latent image element (12A) may have a phase different from the background element (13A) on the upper side, which is the opposite direction to the first direction (S ₁ ). Well, contrary to FIG. 8B, the phase of the latent image element (12A) is made different from the background element (13A) in the lower direction, which is the same direction as the _first direction (S ₁ ). Also good.

  The latent image element (12A) and the background element (13A) may be separated as shown in FIG. 8 (b), or may be connected as shown in FIG. 9 (a) or FIG. 9 (b). good.

(Second pattern)
Next, the second pattern (6) will be described. FIG. 10 is a plan view and a sectional view showing the second pattern (6). As shown in FIG. 10A, the second pattern (6) is formed from a plurality of second elements (7) formed between the respective elements of the plurality of convex first elements (5). Become.

  As described above, the formed body (1) of the present invention is newly added to the third observation point (L2) in addition to the first latent image (10) that can be viewed at an angle. A second latent image (11) that is visible under the transmitted light of L1) is given. The transmittance | permeability with a base material (2) changes by making the 1st element (5) and the 2nd element (7) mentioned above partly differ in cross-sectional shape. Therefore, by arranging a plurality of first elements (5) and / or second elements (7) having partially different cross-sectional shapes, a second latent image that is a watermark pattern that is visible under transmitted light. The image (11) can be applied to the formed body (1).

  First, the second element (7) will be described. The first element (5) having a partially different cross-sectional shape will be described later. As shown in FIG. 10A, a second latent image (11) having a character shape of “10” is formed on the substrate (2). As shown in the enlarged view of FIG. 10A, the second element (7) is disposed between the plurality of first elements (5).

  FIG. 10B is a cross-sectional view taken along the line B-B ′ in FIG. The bottom (7b), which is a part of the substrate (2), has the same cross-sectional shape, but the second element (7) corresponds to the shape of the second latent image (11), The cross-sectional shape changes.

As shown in FIG. 10 (b), the second element (7) and the bottom (7b) have different depths. In the present invention, the width (W ₂ ) and depth (h ₁ ) of the bottom portion (7b) is used as a reference, and the depth (h ₂ ) of the second element (7) is the reference bottom portion (7b ) Will be described below as the depth from the reference position (M).

  By making the second element (7) deeper than the bottom (7b), the transmittance of the second element (7) and the bottom (7b) is different, and when observed under transmitted light, the bottom (7b) The deep second element (7) is visible brighter (whiter) than the bottom (7b). Therefore, the second latent image (11) visible under the transmitted light described above is formed by appropriately forming the plurality of second elements (7) according to the shape of the second latent image (11). Is formed.

In FIG. 10B, the depth (h ₂ ) of the second element (7) forming the second latent image (11) is constant. When the depth (h ₂ ) and width (W ₂ ) of the second element (7) are constant, the second latent image (11) visible under transmitted light has gradation. Not visible as a solid watermark pattern. When the depth (h ₂ ) and the width (W ₂ ) of the second element (7) forming the second latent image (11) are changed, the second element that can be visually recognized under transmitted light. The latent image (11) is visually recognized as a watermark pattern having gradation, which will be described later.

The depth (h ₂ ) of the second element (7) is 30 μm to 70 μm. When the thickness is 30 μm or less, the transmittance with the bottom (7b) does not change so much, and the second latent image (11) 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 (5), which is not preferable. Furthermore, the durability of the formed body (1) is lowered because the thickness of the second element (7) is not preferable.

In FIG. 10B described above, the width (W ₂ ) of the second element (7) and the bottom (7b) is constant, but the transmittance with the substrate (2) can be increased by changing the depth. Differently, the second latent image (11) was formed. However, as long as the transmittance of the base material (2) and the second element (7) can be changed, the cross-sectional shape is not limited to that shown in FIG. It is also possible.

FIG. 11 is a cross-sectional view showing another cross-sectional shape of the second element (7) forming the second latent image (11). 11 (a), FIG. 11 (b), FIG. 11 (c), and FIG. 11 (d) show the substrate (2) in the first direction (S) as in the cross-sectional view of FIG. 10 (b) described above. It is sectional drawing cut | disconnected in parallel with respect to ₁ ). The second element (7) described above is not limited to the cross-sectional shape in which the depth of the second element (7) is deeper than the bottom (7b), and various shapes are possible.

As shown in FIGS. 11 (a), 11 (b), 11 (c) and 11 (d), the width (W ₂ ) of the second element (7) is compared with the bottom (7b). The second element (7) and the bottom (7b) can be narrowed or widened, or the depth (h ₂ ) of the second element (7) can be made deeper or shallower than the bottom (7b). ) Can be changed. In any shape, when the transmittance is higher than that of the bottom portion (7b), it is viewed brighter than the bottom portion (7b), and conversely, when the transmittance is low, it is viewed darker than the bottom portion (7b).

In FIG. 11, the second element (7) is formed by changing both the width (W ₂ ) and the depth (h ₂ ), but the width (W ₂ ) and the depth ( Even when only one of h ₂ ) is changed, the second latent image (11) can be formed because of the change in transmittance.

  Furthermore, it is also possible to vary the width and depth in one second element (7). 12 (a) is a plan view of one second element (7) having a different width, and FIGS. 12 (b) and 12 (c) are cross-sectional views along CC ′ in FIG. 12 (a). And DD ′ sectional view. As shown in FIG. 12B and FIG. 12C, by changing the width in one second element (7), the second element (7) in the CC ′ cross-sectional position can be changed. It is also possible to change the transmittance with the second element (7) at the DD ′ cross-sectional position.

FIG. 13A is a plan view of one second element (7) having a different depth. FIG.13 (b) is EE 'sectional drawing in Fig.13 (a), and is a figure which shows the cross-sectional shape of a bottom part (7b). As shown in FIG. 13B, the bottom (7b) has a constant depth with respect to the X direction (X ₁ ), which is the length direction perpendicular to the width direction of the second element (7).

FIG.13 (c), FIG.13 (d), and FIG.13 (e) are FF 'sectional drawing in Fig.13 (a). As shown in FIGS. 13 (c), 13 (d) and 13 (e), the second element (7) is configured by changing the depth in the X direction (X ₁ ) in multiple steps or gradually. It is also possible to change the transmittance with the bottom (7b).

Next, the first element (5) having a partially different cross-sectional shape will be described. FIG. 14 is a plan view and a cross-sectional view showing a first element (5) having a partially different cross-sectional shape. In FIG. 14A, three first elements (5) are arranged in the _first direction (S ₁ ) as an example. The first element (5) consists of a 1a element (5a) and / or a 1b element (5b).

  FIGS. 14B, 14C, and 14D are cross-sectional views taken along line G-G ′ in FIG. In the plurality of first elements (5), the first b elements (5b) all have the same cross-sectional shape. On the other hand, the first-a element (5a) corresponds to the second latent image (11), and the cross-sectional shape changes. Hereinafter, in the present embodiment, when the first element (5) does not have the 1a element (5a) having a different cross-sectional shape, the first element (5) is formed only from the 1b element (5b). Will be described.

As shown in FIG. 14B, the width (W ₁ ) of the 1a element (5a) is different from the 1b element (5b). In the present invention, the width of the element of the 1b (5b) _{(W 1)} and height _{(h 1)} as a reference, the height of the element of the 1a (5a) _{(h 1)} is a reference Hereinafter, the height from the reference position (M) of the 1b element (5b) will be described.

As shown in FIGS. 14B, 14C, and 14D, the height (h ₁ ) of the 1a element (5a) is set to the height (h) of the 1b element (5b). or made different from _1), the width of the element of the 1a (5a) and _{(W 1),} by or be different from the width of the element of the 1b (5b) _{(W 1),} 1a-th element (5a) And the 1b element (5b) have different transmittances. When the transmittance is higher than that of the 1b element (5b) when observed under transmitted light, the 1a element (5a) Is brighter (whiter) than the element (5b).

  On the other hand, when the transmittance is lower than that of the 1b element (5b), the 1a element (5a) is seen darker (black) than the 1b element (5b). Therefore, the second latent image (11) visible under the transmitted light described above is formed by appropriately forming a plurality of first element (5a) according to the shape of the second latent image (11). Is formed.

Furthermore, as another cross-sectional shape, it is also possible to form the 1a element (5a) by changing the height (h ₁ ) in _{one first} element (5). FIG. 15 is a plan view and a cross-sectional view showing another cross-sectional shape of the 1a-th element (5a). Fig.15 (a) is a top view of the 1b element (5b), FIG.15 (b) is HH 'sectional drawing of Fig.15 (a). The 1b element (5b) shown in FIG. 15B has a constant height in the X direction (X ₁ ).

FIGS. 15C, 15D, 15E, and 15F are cross-sectional views taken along the line II ′ in FIG. As shown in FIGS. 15 (c), 15 (d), 15 (e), and 15 (f), the element 1a (5a) has a multi-stage or moderate height in the X direction (X ₁ ). It is also possible to change the transmittance with the element (5b) of the first b by changing to.

  Similarly to the second element (7) described above, also in the first a element (5a), the width of the first a element (5a) is gradually widened in one first element (5), Alternatively, a narrowed shape is possible.

  Furthermore, although not shown in a figure, it cannot be overemphasized that the 1a element (5a) and the 2nd element (7) can be comprised by combining the shape mentioned above variously. The second latent image (11) can also be formed by combining the above-described first element (5a) and second element (7).

  Next, a method for forming the first element (5) and the second element (7) will be described. Each element (5, 5a, 5b, 7, 7b) is formed on the substrate (2) by embossing, intaglio printing, screen printing, penetration or laser processing.

  The formation of each element (5, 5a, 5b, 7, 7b) by embossing is performed by using a concave shape and a convex shape that match the shape of each element (5, 5a, 5b, 7, 7b). Formed by machine.

  The formation of the first element (5) by intaglio printing or screen printing is performed by printing on the substrate (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 (5) is formed by intaglio printing, screen printing and embossing, the formed first element (5) is formed as a raised convex shape with respect to the substrate (2). Is done. Thereby, with formation of the first element (5), the second element (7) is formed between the two adjacent first elements (5).

  The formation of each element (5, 5a, 5b, 7, 7b) by squeezing is performed by using a known paper machine capable of squeezing when the base material (2) is paper. .

  Each element (5, 5a, 5b, 7, 7b) is formed by laser processing by removing a part of the substrate (2) using a known laser processing apparatus. When the substrate (2) is formed by removing the periphery of the first element (5) by laser processing, the removed region is thinner (concave shape) than the first element (5). Become.

  Therefore, with the formation of the first element (5), the second element (7) is formed between the two adjacent first elements (5). In addition, after the first element (5) is previously formed by intaglio printing, screen printing, embossing, squeezing and laser processing, the space between the two adjacent first elements (5) is removed by laser processing. Thus, the second element (7) can also be formed.

  Note that it is not preferable to form the first element a (5a) and the second element (7) forming the second latent image (11) by embossing. When the base (2) is paper and the 1a element (5a) and the second element (7) are formed by embossing, the 1a element (5a) and the second element (7) 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 element (5a) and the second element (7) and the base material (2) do not produce a difference in brightness, and are visible under transmitted light. The second latent image (11) 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 (5a) and the second element (7) The thickness changes from (2), and a difference in brightness occurs when observed under transmitted light. Therefore, the formation method of the first element (5a) and the second element (7) for forming the second latent image (11) is appropriately set depending on the substrate (2) to be used.

The depth (h ₂ ) and height (h ₁ ) and width (W ₁ ) of the 1a element (5a) and / or the second element (7) forming the second latent image (11). , W ₂ ) is constant, for example, when the height (h ₁ ) of the 1a element (5a) is all formed at the same height, the transmittance of the 1a element (5a) is all It will be the same. Therefore, the second latent image (11) that is visible under transmitted light is viewed as a solid image having no gradation.

On the other hand, the depth (h ₂ ), height (h ₁ ), and width (W ₁ ) of the 1a element (5a) and / or the second element (7) forming the second latent image (11). , W ₂ ) are changed, for example, when the height (h ₁ ) of the _first 1a element (5a) is made different, the first 1a corresponds to the changed height. The transmittance of the element (5a) is different. Since the transmittance is different at two or more locations, the second latent image (11) that is visible under transmitted light is visually recognized as an image having gradation.

  FIG. 16A is a plan view showing a second latent image (11 ') that is a watermark pattern having gradation. The second latent image image rich in gradation by making the transmittance of the first element (5a) and / or the second element (7) forming the second latent image (11 ′) different from each other. (11 ′) is formed, and in FIG. 16A, the second latent image (11 ′) is composed of a first a element (5a) and a second element (7).

FIG. 16B is a JJ ′ cross-sectional view of the second latent image (11 ′) shown in FIG. The height of the 1a element (5a) forming the second latent image (11 ′) gradually decreases in the first direction (S ₁ ), whereby the transmittance increases, and the brightness having gradation. It is visually recognized. Further, the second element (7) forming the second latent image (11 ′) gradually becomes shallower in the first direction (S ₁ ), so that the transmittance is lowered, and the darkness having gradation. Visible at. In this way, the second latent image (11 ′) having gradation is made different by making the heights of the first element (5a) and the depth of the second element (7) arranged differently. It is formed.

  The cross-sectional shapes of the first-a element (5a) and the second element (7) that form the second latent image (11 ′) are not limited to the cross-sectional shape shown in FIG. As long as the transmittance of the first element (5a) and the second element (7) arranged in a plurality can be made different, the above-described various shapes can be used. It is also possible to form by combining shapes.

  When the height, depth, and width are changed in one element described above, the transmittance is different in one element corresponding to the change in the shape, and light and shade are generated. As a result, the second latent image (11 ') having gradation can be formed.

  In order to make the second latent image (11 ′) a gradation image, at least the first a in the first element (5) and the second element (7) on the substrate (2). Two or more places where the transmittance of the element (5a) and / or the second element (7) is different are necessary. Since there are two or more places where the transmittance is different, when observed under transmitted light, light and shade are generated in one second latent image (11 ′), which is visually recognized as a transmission image having gradation. .

  The second latent image (11, 11 ') is formed by partially varying the cross-sectional shape such as the width and depth of the first element (5) and / or the second element (7). Thereby, the formed body (1) is applied to printed matter distributed in the market, and even if the first element (5) and / or the second element (7) are worn in the distribution process, By observing the presence or absence of two latent image images (11, 11 ′), it is possible to determine whether the image is true or false. 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 the first element (5a) and / or the second element (7) having a transmittance different from that of the base material (2), thereby transmitting the transmitted light. A second latent image (11, 11 ′) that can be visually recognized below can be provided.

(Third pattern)
Next, the 3rd pattern (8) which is a visible image is demonstrated. As shown in FIG. 17A, the third pattern (8) is formed by arranging a plurality of third elements (9) in the second direction (S ₂ ) at the second pitch (P ₂ ). . In the present invention, the “second direction” is a direction in which the third element (9) is arranged. The width of the third element (9) in the second direction (S ₂ ) is defined as the width (W ₃ ) of the third element (9).

  The third element (9) may be formed of an image line, a plurality of pixels, or a combination thereof, similarly to the first element (5) described above. The description of the configuration of the first element (5) is omitted. The third element (9) may be formed of an image line or a pixel having a shape different from that of the first element (5), or a combination thereof.

The second pitch (P ₂ ) is formed with substantially the same width as the first pitch (P ₁ ). The substantially same width is a range of 4/5 to 6/5 with respect to the first pitch (P ₁ ). Preferably, the same pitch is used. This is because when the first pitch (P ₁ ) and the second pitch (P ₂ ) are the same, the first element (5) and the third element (9) always overlap at a constant interval. This is because it is easy to visually recognize the latent image (10).

The width (W ₃ ) of the third element (9) is wider than at least 10 μm, and the upper limit is formed in a range of 9/10 with respect to the _first pitch (P ₁ ). If the width (W ₃ ) of the _third element (9) is larger than 9/10 with respect to the first pitch (P ₁ ), the latent image element (12A) and the background element (13A) This is because since the third element (9) overlaps, the contrast cannot be obtained and the first latent image (10) cannot be visually recognized. If the width (W ₃ ) of the third element (9) is narrower than 10 μm, the overlapping area between the first element (5) and the third element (9) is small, so the first latent image (10). Visibility is lowered, which is not preferable.

In the present invention, the “first direction” refers to the direction in which the first element (5) is disposed, and the “second direction” refers to the third element (9). It is a direction. In the formed body (1) of the present invention, the first direction (S ₁ ) and the second direction (S ₂ ) may be the same direction, or the second direction (S ₂ ) is the first direction. The direction may be different from the direction (S ₁ ).

FIG. 17B shows a third pattern (8) composed of a plurality of third elements (9) arranged such that the second direction (S ₂ ) is different from the _first direction (S ₁ ). It is a top view which shows an example.

  As shown in the enlarged view of FIG. 17C, the third element (9) is formed to be inclined with respect to the E-E ′ line indicating the direction in which the first element (5) is arranged. At this time, the inclination angle (α) of the first element (5) and the third element (9) is formed in a range of ± 0.5 degrees to ± 3 degrees. A preferable range of the inclination angle (α) of the first element (5) and the third element (9) is ± 0.5 degrees to ± 1.5 degrees. This is because the first latent image (10) is easier to visually recognize when the inclination angle (α) of the first element (5) and the third element (9) is smaller.

  The third pattern (8) is formed to be larger than the area of the first latent image (10) including the latent image portion (12) and the background portion (13), and the latent image portion (12) and the background portion ( 13) is arranged to cover. This is because if there is a portion where the third pattern (8) does not overlap the latent image portion (12) and the background portion (13), the entire first latent image (10) cannot be visually recognized.

  The color of the 3rd element (9) which forms the 3rd pattern (8) should just be a color different from the color of a base material (2), and is not specifically limited.

  As a method for forming the third element (9), a known printing method such as offset printing, gravure printing, inkjet printing, or laser processing can be used. When the third pattern (8) is formed by printing, the third element (9) is made of ink, and when the third pattern (8) is formed by laser processing, the third pattern (8) is formed. Element (9) consists of substrate (2) discolored by a laser.

(Arrangement of the first pattern and the third pattern)
Next, the arrangement of the first pattern (4) and the third pattern (8) and the visible first latent image (10) will be described. First, the second element (7) is excluded. The visual recognition principle of the first latent image (10) of the present invention will be described.

  First, the visual recognition principle of the 3rd element (9) arrange | positioned on the convex-shaped 1st element (5) is demonstrated using FIGS.

  FIG. 18 (a) is a plan view showing an example of a state in which the arc-shaped convex first element (5) and third element (9) shown in FIG. , An enlarged part of it. The LL ′ line indicates the position of the vertex (Q) of the first element (5) having a convex shape. In the present invention, the “convex vertex” means the base material (2). It is the highest portion of the surface on the near side of the convex first element (5) when observed from the second observation point (L2).

  In the arrangement shown in FIG. 18A, the third element (9) overlaps half of the surface of the first element (5) with the vertex (Q) of the first element (5) as a boundary. Show. At this time, when observed from the first observation point (L1), the third element (9) can be visually recognized, and the color of the third element (9) can be visually recognized.

  On the other hand, when observed from the second observation point (L2), it should be visually recognized on the surface of the first element (5) on the near side, with the vertex (Q) of the first element (5) as a boundary. However, the inner surface is behind the first element (5) and cannot be seen because it is a blind spot.

Further, the flat part of the base material (2) becomes a blind spot of the first element (5) and cannot be visually recognized basically, but the vertex (Q) of the first element (5) is the boundary. The portion near the surface of the first element (5) on the near side depends on the shape of the first element (5), the first pitch (P ₁ ), and the width of the image line (W ₁ ). It may be visible.

Further, the range that can be visually recognized on the surface of the first element (5) on the near side with the vertex (Q) of the first element (5) as a boundary is also the shape of the first element (5), the first Although there is a slight difference depending on the pitch (P ₁ ) and the width (W ₁ ) of the first element (5), hereinafter, the first element (5) becomes the front side with the vertex (Q) as the boundary. It is assumed that only the surface of the first element (5) is visible, and when the substrate (2) is observed from the second observation point (L2), the vertex (Q) of the first element (5) is used as a boundary. The surface of the first element (5) on the near side is "observation part (V)", the surface of the first element (5) on the back side and the flat part of the base material (2) Is described as “non-observation part (V ′)”.

  In addition, although the observation part (V) and non-observation part (V ') shown in FIG.18 (b) are on the KK' line, as shown in FIG. In the first element (5), the line connecting the vertices (Q) of the first element (5) over the whole at a predetermined position, that is, the LL ′ line as a boundary, and the non-observing part (V) It is divided into observation parts (V ′).

  When the first element (5) having the shape shown in FIG. 5B is formed, the range of the observation part (V) and the non-observation part (V ′) is different.

FIG. 19 is a cross-sectional view of an arrangement in which the third element (9) overlaps the base material (2) on which the first element (5) having the shape shown in FIG. 5 (b) is formed. At this time, when the base material (2) is observed from the second observation point (L2), the surface (V ₁ ) of the first element (5) on the near side and the upper surface (V) of the first element (5). The third element (9) formed in ₂ ) can be visually recognized.

However, the third element (9) formed on the upper surface (V ₂ ) of the first element (5) is the first element formed on the surface (V ₁ ) of the first element (5) on the near side. Since the visibility of the first element (9) is weak and the influence on the visibility of the first latent image (10) is small, the surface of the first element (5) on the near side is actually The first latent image (10) is visually recognized by the third element (9) overlapping (V ₁ ).

Accordingly, the first element (5) shown in FIG. 19 can observe the surface (V ₁ ) of the first element (5) on the near side when observed from the second observation point (L2). . Further, the range of the non-observation part (V ′) of the first element (5) shown in FIG. 19 is the first element (5) on the back side, the first, The upper surface (V ₂ ) of the element (5) and the flat part of the substrate (2).

  Thus, when the third element (9) overlaps with the observation part (V) of the first element (5), the third element (9) is observed when observed from the second observation point (L2). 9) can be visually recognized, and the third element (9) does not overlap the observation part (V) of the first element (5), that is, the third element (9) When it overlaps with the surface (V ′) on the back side of the first element (5) or the flat part of the substrate (2), the color of the third element (9) cannot be visually recognized.

  Next, the arrangement of the first element (5) and the third element (9) different from the arrangement shown in FIG. FIG. 20 is a diagram showing an example of the arrangement of the first element (5) and the third element (9), which is different from the arrangement shown in FIG.

  In the arrangement shown in FIG. 20 (a), the third element (9) overlaps about half of the observation part (V) of the first element (5), and the rest is on the flat part of the substrate (2). The overlapping state is shown.

  FIG. 20B is a cross-sectional view taken along line M-M ′ shown in FIG. At this time, only the part where the third element (9) overlaps the observation part (V) of the first element (5) can be visually recognized. However, since the area where the third element (9) overlaps the observation part (V) of the first element (5) is small with respect to the arrangement shown in FIG. Moreover, the 3rd element (9) which overlaps with the flat part of a base material (2) becomes a blind spot of a 1st element (5), and cannot be visually recognized.

  The present invention utilizes the above visual principle, and the first image element (5) is obtained by arranging the latent image element (12A) and the background element (13A) of the first pattern (4) in different phases. ) And the third element (9) overlap each other, and as a result, the visibility of the third element (9) when observed from the second observation point (L2) is different. One latent image (10) is visible.

Next, a specific arrangement of the first element (5) and the third element (9) and a visible latent image will be described. In addition, the arrangement of the first pattern (4) and the third pattern (8) in which the first pitch (P ₁ ) and the second pitch (P ₂ ) are arranged at the same pitch, and a latent image that can be visually recognized. Will be described.

  Further, in the case of observation from the first observation point (L1), the third element (9) can be observed in any case, so that the description is omitted, and the substrate (2) is not illustrated. A latent image that becomes visible when viewed from below and from the second observation point (L2) will be described. Moreover, in the figure which shows arrangement | positioning of the 1st element (5) demonstrated below and the 3rd element (9), an observation part (V) is made into the lower side from the half of each element shown to drawing, and a non-observation part ( V ′) is from half to upper side of each element shown in the drawing.

  The first arrangement will be described with reference to FIG. FIG. 21A shows a state in which the third element (9), which is the first arrangement, overlaps the entire latent image element (12A) and a part of the observation part (V) of the background element (13A). Show. Further, the area ratio of the third element (9) overlapping the observation part (V) of the background element (13A) is equal to the area of the third element (9) overlapping the observation part (V) of the latent image element (12A). The state is smaller than the rate.

  When the formed body (1) of the first arrangement is observed from the second observation point (L2), the observation part (V) of the latent image element (12A) and the observation part (V) of the background element (13A) Since the third element (9) overlaps, the latent image portion (12) and the background portion (13) can be visually recognized by the color of the third element (9). At this time, the area ratio of the third element (9) overlapping the observation part (V) of the background element (13A) is equal to that of the third element (9) overlapping the observation part (V) of the latent image element (12A). Since it is smaller than the area ratio, as shown in FIG. 21B, the background portion (13) can be visually recognized as a first latent image (10) at a lower density than the latent image portion (12).

  Next, the second arrangement will be described with reference to FIG. FIG. 22A shows the second arrangement, in which the third element (9) overlaps at least part of the observation part (V) of the latent image element (12A), and the observation part of the background element (13A). (V) shows an arrangement that does not overlap.

  When the formation body (1) of the second arrangement is observed from the second observation point (L2), the third element (9) overlaps the observation part (V) of the latent image element (12A). The latent image portion (12) can be visually recognized by the color of the third element (9). As a result, as shown in FIG. 22 (b), only the latent image portion (12) is visible as the first latent image (10) in the color of the third element (9).

  Next, the third arrangement will be described with reference to FIG. FIG. 23A shows a third arrangement, in which the third element (9) overlaps at least a part of the observation part (V) of the background element (13A), and the observation part (12A) of the latent image element (12A). V) shows an arrangement that does not overlap.

  When the formed body (1) of the third arrangement is observed from the second observation point (L2), the observation part (V) of the background element (13A) and the third element (9) overlap with each other. The part (13) is visible with the color of the third element (9). As a result, as shown in FIG. 23B, only the background portion (13) can be visually recognized by the color of the third element (9) as the first latent image (10).

  That is, the first element (5) and the third element (9) have the first positional relationship, the second positional relationship, and the third positional relationship, regardless of the positional relationship. It is possible to visually recognize the latent image (10). For this reason, since high accuracy is not required for the alignment of the first element (5) and the third element (9) at the time of manufacture, the productivity is excellent.

  Next, the arrangement of the second element (7) and the third element (9) and the second latent image (11) that can be visually recognized will be described with reference to FIGS.

  Further, in the case of observation from the third observation point (L3), since the third element (9) can be visually recognized in any case, the description is omitted, and the transmitted light that is the third observation point (L3) is used. The second latent image (11) that can be viewed will be described.

  An example of an arrangement in which the third element (9) does not overlap the second element (7) is shown in FIG. When this formed body (1) is observed from the third observation point (L3), the second element (7) is the thinnest in the base material (2) and is not covered with the third element (9). Therefore, the second latent image (11) can be visually recognized by simply looking bright.

  Next, FIG. 25 shows an example of an arrangement in which the third element (9) entirely overlaps the second element (7). When this formed body (1) is observed with transmitted light from the third observation point (L3), the second element (7) is completely covered with the third element (9), so the second element (7) The element (7) can be visually recognized by the color of the third element (9), or the transmitted light is blocked by the third element (9) and cannot be visually recognized.

  If the second element (7) is visible in the color of the third element (9), it is necessary that the ink constituting the third element (9) does not completely block the light. About the ink to be used, it is necessary to adjust so that the amount of transmitted light when forming the formed body (1) is at least such that the second element (7) can be visually recognized.

  As the printing method, offset printing or gravure printing in which the film thickness of the formed body (1) does not increase is preferable. When screen printing or intaglio printing in which the film thickness is increased is used, light transmission is not hindered. It is preferable to use an ink containing a dye as a component. In such a case, the portion where the second element (7) and the third element (9) overlap appears light and bright in the color of the third element (9). However, the entire formation area (3) can be visually recognized as the second latent image (11).

  FIG. 26 shows an example of an arrangement in which the third element (9) partially overlaps the second element (7). When this formed body (1) is observed with transmitted light from the third observation point (L3), the second element (7) is partially covered with the third element (9). The uncovered portion is simply bright and visible.

  In the covered part, when the ink which comprises a 3rd element (9) does not block light completely, it can visually recognize with the color of a 3rd element (9).

  Even when the ink constituting the third element (9) of the covered part completely blocks the light, the transmitted light can be seen from the part not covered by the third element (9). The image image (11) can be visually recognized.

  That is, the second latent image (11) can be visually recognized regardless of the positional relationship between the second element (7) and the third element (9). . Further, the first latent image (10) can be visually recognized regardless of the positional relationship between the first element (5) and the third element (9). Since high accuracy is not required for alignment between the base material (2) on which the first element (5) and the second element (7) are formed in advance and the third element (9), the productivity is high. Is excellent.

  The order of producing the formed body (1) has been described by taking the case where the third element (9) is arranged after the second element (7) as an example. Alternatively, the third element (9) may be arranged first, followed by the second element (7).

DESCRIPTION OF SYMBOLS 1 Special latent image image forming body 2 Base material 3 Latent image image formation area 4 1st pattern 5 1st element 6 2nd pattern 7 2nd element 8 3rd pattern 9 3rd element 10 1st Latent image 11, 11 ′ Second latent image 12 Latent image portion 12A Latent image element 13 Background portion 13A Background element L1 First observation point L2 Second observation point L3 Third observation point

Claims (7)

At least a part of the substrate includes a latent image portion formed of a latent image portion and a background portion arranged in the background of the latent image portion,
In the latent image portion, a plurality of first elements having a convex shape are arranged at a first pitch in a first direction,
In the background portion, a plurality of the first elements are arranged at the first pitch in the first direction with a phase different from that of the first element in the latent image portion,
Between each of the plurality of first elements, a second element having a transmittance different from that of the base material is disposed,
In the latent image portion and the background portion, a plurality of third elements each having a different color from the first element are arranged at a second pitch,
A first latent image is formed by overlapping the third element with the first element in the latent image portion and / or the background portion,
A second latent image that is a watermark pattern is formed by the plurality of second elements having different transmittances from the base material,
When the substrate is tilted and observed, the first latent image is visually recognized,
The special latent image forming body, wherein the second latent image is visually recognized when the substrate is observed under transmitted light. Among the plurality of second elements arranged, at least one second element is different in depth and / or width from other second elements,
The second 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 2. The special latent image forming body according to Item 1.   2. 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.   In the at least one second element, the second latent image, which is a watermark pattern having gradations, is obtained by varying the depth and / or width by varying the transmittance at two or more locations. The special latent image forming body according to claim 3, which is formed. 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,
5. The special as claimed in claim 1, wherein the second latent image is formed by the second element and the first element having a different height and / or width. Latent image forming body.   6. The special latent image forming body according to claim 5, wherein a height and / or a width are different in at least one of the plurality of arranged first elements.   In the at least one first element, the second latent image, which is a watermark pattern having a gradation, is formed by having different transmittances at two or more locations and having different heights and / or widths. The special latent image forming body according to claim 6, wherein:

Images