JP2012045742A - Transmissive latent-image pattern forming body - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a forming body that can visually recognize glossiness of a light reflecting layer under reflected light, in particular, in the case when the light reflecting layer is an OVD, an OVD image can be visually recognized, on the other hand, under transmissive light, another latent-image pattern can be visually recognized.SOLUTION: The transmissive latent-image pattern forming body includes a latent image pattern area on at least a part of a base material. The light reflecting layer in which fine elements where at least light reflectivity is not present at least at a part are formed in the form of a line pattern, is formed in the latent image pattern area. The fine elements include a plurality of latent image pattern elements, at least the one end of each of which is broken off. Each of the latent image pattern elements is configured to include at least one of a first end portion having the broken one end and a second end portion having the other broken end different from the one end, and the transmissive latent image pattern is formed by the overlapping area where the first and second end portions of different latent image pattern elements overlap each other, in the latent image pattern elements.

Description

  The present invention relates to a transparent latent image pattern formed body in which a latent image is applied to banknotes, passports, securities, gift certificates, various certificates, etc. and cards to prevent counterfeiting and duplication.

  In order to prevent counterfeiting and alteration on card media such as magnetic cards, especially cash cards, and paper media such as banknotes and various securities, measures such as strengthening the security function by attaching a hologram to the surface of each media Has been made. However, in the case of simple holograms, with the rapid development of personal computers in recent years, sophisticated counterfeit products that are difficult to distinguish from genuine products have been leaked to the market.

  Therefore, a hologram having a new anti-counterfeit effect added to the conventional hologram function has been invented. For example, a light transmission / reflection layer having a light transmission part that forms a predetermined pattern by transmitting light and a light reflection part that can reflect light, and light diffraction that can reproduce an image by light reflected by the light reflection part It is a pattern appearance object provided with the layer (for example, refer patent document 1).

  The pattern appearing body in Patent Document 1 can visually recognize an image formed by the light diffraction layer under reflected light, and can visually recognize the pattern formed by the light transmitting portion under transmitted light. As a method of forming a pattern by this light transmission part, when forming the light reflection part of the light transmission reflection layer, a pattern is formed by providing a pattern-like shielding object such as a mask, or a uniform reflection layer is formed. After the formation, a method of removing a part of the reflective layer in a pattern using a photonograph process or a laser marking device is used.

  Further, the present applicant forms a light transmissive member by removing the light reflective member in a line shape with respect to the hologram forming layer, and changes the line width of a part of the latent image region. A hologram sheet is disclosed in which a latent image is formed by dividing into background image regions (see, for example, Patent Document 2).

  In the hologram sheet described in Patent Document 2, the hologram image formed by the diffraction grating constituting the hologram forming layer can be visually recognized under reflected light, and the light reflective member and the light can be viewed under transmitted light. It is possible to visually recognize the latent image formed by changing the line width in the line formed by the transparent member.

  In the hologram sheet described in Patent Document 2, in addition to forming the latent image by changing the above-described line width, as a division between the latent image area and the background image area, the line direction is changed, It can also be formed by changing the phase of the lines or the number of lines.

  The method for forming a light transmissive member in the hologram sheet of Patent Document 2 is that the light reflective member is vacuum-deposited or sputtered, and then a mask layer is formed by a gravure printing machine or the like and immersed in an alkaline solution. The unprotected portion is dissolved and removed to form a light transmissive member.

Japanese Patent No. 4060080 JP 2007-240785 A

  However, the pattern appearing body disclosed in Patent Document 1 can cause another pattern to appear under transmitted light in addition to the conventional visual effect of the hologram image. The light reflection part is removed in a line shape within the outline of the pattern to form a light transmission part, and the actual pattern shape is not subjected to the process of forming the light transmission part on the light reflection part It is formed by the boundary between the outside of the pattern and the inside where the light transmitting portions are alternately arranged in a line, that is, the presence or absence of a so-called light reflecting portion.

  Therefore, for authentic products, fine lines formed by the light reflecting portion and the light transmitting portion have an effect of preventing peeling, but the pattern does not have a light reflecting portion, so-called a light reflecting portion and a light transmitting portion. Even with a hologram on which a pattern is formed depending on the presence or absence of a portion, there is a problem that it is difficult for the naked eye to clarify the difference and there is a possibility of being forged.

  In addition, the hologram sheet described in Patent Document 2 has a light reflecting member and a light transmitting member arranged in a single line over the entire hologram forming layer as compared with Patent Document 1, so that a simple light Image formation with or without a reflective member can be distinguished with the naked eye and has improved anti-counterfeiting effects, but the image line structure for separating the latent image area from the background image area is fine. Therefore, it takes time in the design stage of a mask image, and when forming a mask with a gravure printing machine or the like, it is possible to form a clear latent image image instead of a desired image line thickness due to quality deviation or the like. The manufacturing problem of becoming difficult remained.

  The present invention is intended to solve such a conventional problem, and in addition to the conventional visual effect of hologram image, it is possible to visually recognize another latent image pattern under transmitted light. The structure of the latent image pattern is not the contour formation of the pattern depending on the presence or absence of a reflecting member, but the formation of the latent image image by lines having the same line width, thus providing further anti-counterfeiting effects and forming the latent image pattern An object of the present invention is to propose a transparent latent image pattern formed body that can simplify the design and stabilize the quality even in the mask generation stage used for the purpose.

  The present invention has a latent image pattern region on at least a part of a substrate, a light reflective light reflection layer is formed in the latent image pattern region, and a light reflection layer is formed on at least a part of the light reflection layer. Fine elements formed by the absence of a part of the layers are arranged in a line, and a plurality of fine elements arranged in a line form a plurality of latent image pattern elements having at least one end cut off. The plurality of latent image pattern elements have at least one of a first end where one end is interrupted and a second end where the other end different from one end is interrupted. In this latent image pattern element, a transmission latent image pattern is formed by the overlapping region of the first end and the second end in different latent image pattern elements. When the latent image pattern region is viewed under transmitted light, The difference in light transmission between the overlapping area and other areas within the fine elements Ri, it is a transmission latent image pattern formed body, characterized in that transmission latent image pattern is formed.

  In the transmission latent image pattern formed body of the present invention, in a plurality of latent image pattern elements, an overlapping region is formed by a latent image pattern element having only a first end and a latent image pattern element having only a second end. It is characterized by being.

  The transmission latent image pattern formed body of the present invention is characterized in that a latent image pattern element having a first end and a latent image pattern element having a second end are arranged alternately next to each other. .

  The transmission latent image pattern formed body of the present invention includes, in a plurality of latent image pattern elements, a latent image pattern element having only a first end and a second end portion arranged on the same line. And an overlap region is formed by the latent image pattern element having both the first end and the second end.

  The transmission latent image pattern formed body of the present invention includes a latent image pattern element having only a first end and a latent image pattern element having only a second end, which are arranged on the same line, a first end, The latent image pattern elements having both of the second ends are alternately arranged adjacent to each other.

  The transmission latent image pattern formed body of the present invention has an end portion between the latent image pattern element having the first end portion forming the overlapping region and the latent image pattern element having the second end portion. It is characterized in that no fine elements are arranged.

  The transmission latent image pattern formed body of the present invention is characterized in that the element widths of the plurality of fine elements are all the same or at least one different.

  The transmission latent image pattern formed body of the present invention is characterized in that the fine element has an element width of 50 to 500 μm and a pitch of 100 to 1000 μm.

  The transparent latent image pattern formed body of the present invention is characterized in that the pitch of the fine elements in the overlapping region is ½ of the pitch of the fine elements other than the overlapping region.

  The transmission latent image pattern formed body of the present invention is characterized in that the light reflection layer is made of a light reflective metal material, and the fine element is formed by removing the metal material.

  The transmission latent image pattern formed body of the present invention is characterized in that the light reflection layer is OVD.

  The transparent latent image pattern formed body of the present invention is characterized in that the fine element is composed of at least one of an image line or a group of minute elements, or a combination thereof.

  When the transmission latent image pattern formed body of the present invention is observed under reflected light, the metallic luster due to the light reflecting layer can be visually recognized. In particular, when the light reflecting layer is an OVD having a metal material, it is formed by a diffraction grating. The observed image can be visually recognized, and when viewed under transmitted light, the transmitted latent image pattern formed by the light reflecting layer can be visually recognized.

  In the transmission latent image pattern formed body of the present invention, the transmission latent image pattern is formed while a plurality of elements formed in a line shape by the light reflection layer are applied over almost the entire area of the light reflection layer. Therefore, unlike the pattern in which the contour is expressed depending on the presence or absence of the light reflecting member, it is easy to distinguish from simple counterfeiting, so that the anti-counterfeiting effect is high.

  Further, the transmission latent image pattern formed body of the present invention uses the same line width in the step of removing a part of the light reflection layer by laser processing or mask processing in order to form a transmission latent image pattern. Therefore, simplification and stabilization of quality can be achieved in the manufacturing process such as design, processing or printing.

It is a figure which shows an example of the transmission latent image pattern formation body of this invention. It is a figure for demonstrating the aspect of a light reflection layer. It is a figure which shows the permeation | transmission latent image pattern formed in the light reflection layer. It is a figure for demonstrating the shape of an element (a latent image pattern element is included). It is a figure for demonstrating the structure of a microelement group. It is a figure which shows the structural example of an element. It is a figure for demonstrating an example of a structure of a permeation | transmission latent image pattern. It is a figure for demonstrating another example of a structure of a transmission latent image pattern. It is a figure for demonstrating an example of arrangement | positioning of an element (a latent image pattern element is included). It is a figure for demonstrating the visual recognition state of a transmission latent image pattern. FIG. 10 is a diagram for explaining a configuration of a transmission latent image pattern in Example 3.

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

  FIG. 1 is a view showing an example of a transmission latent image pattern formed body (1) according to the present invention. As shown in FIG. 1, the transmission latent image pattern formed body (1) has a latent image pattern region (3) in which the transmission latent image pattern of the present invention is formed on at least a part of the substrate (2). Have. As shown in FIG. 1, in areas other than the latent image pattern area (3), necessary information such as fees, characters or other patterns is printed in a known printing method (for example, offset printing, intaglio printing, etc.) It may be given by.

  As the base material (2) in the present invention, paper such as high-quality paper, coated paper or art paper, and films or plastics can be used, and a light reflecting layer (3) formed in the latent image pattern region (3) described later ( 4) is not particularly limited as long as it can be attached or printed.

  FIG. 2 shows a latent image pattern region (3), and a light reflecting layer (4) capable of reflecting light is attached or printed on the latent image pattern region (3). The light reflecting layer (4) is formed by affixing a metal foil made of a metal material such as gold, silver, copper, aluminum or titanium, or by printing a metal ink containing a metal material such as aluminum. In the present embodiment, the latent image pattern region (3) is formed in an elliptical shape, but is not limited to this, and may be any shape such as a triangle, a perfect circle, or a polygon.

  When the light reflecting layer (4) is formed of a metal foil, a plain metal foil as shown in FIG. 2 (a) may be stuck on the substrate (2), but as shown in FIG. 2 (b). Furthermore, it may be an OVD (optical variable device) such as a diffraction grating such as a hologram capable of expressing a stereoscopic image or a special decoration image using light interference, or a multilayer thin film in which a plurality of thin films having different optical characteristics are stacked. . In addition, when OVD shown in FIG.2 (b) is used for the light reflection layer (4), the image which can be confirmed in a fixed angle is hereafter called OVD image (5). By using OVD for the light reflection layer (4), the OVD image (5) can be confirmed under reflected light, and the transmission latent image pattern of the present invention described later can be confirmed under transmitted light. Therefore, it becomes possible to produce a further effect.

  As shown in FIG. 3, the light reflecting layer (4) affixed to the latent image pattern region (3) is a fine element (6) formed by the absence of a part of the light reflecting layer (4). ) Are arranged in a line. In the present invention, “line-like” means a state in which a plurality of elements are regularly arranged at a predetermined pitch. In FIG. 3, a plurality of elements (6) formed in a line shape can be confirmed for the sake of explanation. Actually, since the region other than the element (6) is the light reflecting layer (4), It cannot be confirmed under reflected light. Further, in FIG. 3, the elements (6) are formed in the horizontal direction, but the present invention is not limited to this, and it may be in the vertical direction or in the oblique direction, and may be arranged in a line in a certain direction.

  Further, the element (6) in the present invention is not particularly limited as long as it can be arranged in a line shape, and can be formed in various shapes as shown in FIG. For example, FIGS. 4A to 4C are image lines, in particular, FIG. 4A is a straight line, FIG. 4B is a broken line, and FIG. 4C is a wavy line. 4D is a point group that is an aggregate of a plurality of points, FIG. 4E is a pixel group that is an aggregate of a plurality of pixels, and FIG. It is a character group that is a collection of various characters.

In the present invention, in order to form a transmission latent image pattern, it is necessary to overlap a part of the elements (6) (the overlapping of these elements will be described later). Preferably it is formed. Therefore, the dotted lines or dots in FIG. 4D, the pixels in FIG. 4E, and the characters in FIG. 4F are formed on the same line so as to form one image line. It will be necessary. For example, FIG. 5 shows an example in which the element (6) is formed by a point group that is an aggregate of a plurality of points. In this respect, the height or diameter h ₁ is the same as the element width (W ₁ ) described later. In addition, the pitch (p ₁ ) between the points is set to a range of 50 to 1000 μm so as to be an interval that can be visually recognized as one image line with the naked eye.

The minute characters shown in FIG. 4 (f) are not limited to characters, but may be symbols, numbers, other figures, marks, or the like. Furthermore, when forming a line-shaped element by a group of dots, pixels, characters, etc., as shown in FIG. 4G, various shapes may be arranged in one element. In any case, the shape is not limited as long as the conditions of the height or diameter (h ₁ ) and pitch (p ₁ ) described above are satisfied. In the present invention, a point group that is a set of a plurality of points, a pixel group that is a set of a plurality of pixels, and a set of a plurality of minute characters, symbols, numbers, figures, marks, etc. It is called “element group”. Therefore, in FIG. 4D to FIG. 4G, the element (6) is formed by the microelement group.

  Although it has been explained that a plurality of “small element groups” may be formed in one element, as shown in FIGS. 6A to 6C, a plurality of shapes are formed in one element. You may form by the drawn line. Naturally, it may be formed by a line and a “small element group” within one element.

  Further, as shown in FIGS. 6D and 6E, the elements (6) having different shapes may be formed between the plurality of elements (6). In any case, the element (6) may be formed in any shape shown in FIG. 4 in one element and in each of a plurality of elements.

  In the forms of the various elements (6) shown in FIG. 4, as described above, when any of the forms is viewed, it is visually recognized as an image line, and at least one of the image lines is visible. It is necessary that the end is cut off. The meaning that at least one end of the image line is interrupted will be described later. In the following description, it is assumed that the element (6) is formed by a straight line.

  In this light reflection layer (4), a transmission latent image pattern (7) is formed by the aforementioned element (6). In FIG. 3, the transmission latent image pattern (7) will be described as a crescent moon pattern. As for the transmission latent image pattern (7) shaped like a crescent moon, the light reflection layer (4) is composed of a plurality of elements (6) arranged in a line like the fine element (6) described above. Since the metal material that is used has a higher power to reflect light, it cannot be confirmed under reflected light.

  Next, an enlarged view of a portion surrounded by a dotted line in FIG. 3 is shown in FIG. As shown in FIG. 7A, the line-shaped element (6) formed on the light reflecting layer (4) is a latent element in which at least one of the elements (6) arranged is interrupted. It has an image pattern element (6a). The arrangement of the latent image pattern element (6a) is appropriately set depending on the size of the transmission latent image pattern (7) desired to be formed on the light reflection layer (4), and is formed on the light reflection layer (4). All the elements (6) may be latent image pattern elements (6a).

  This latent image pattern element (6a) will be described in more detail. FIG. 7B is an enlarged view of two adjacent latent image pattern elements (6a) in the latent image pattern elements (6a) in FIG. One of the two latent image pattern elements (6a) has an end portion on the right side of the drawing, and the other has an end portion on the left side of the drawing. The end on the right side is the first end (9), and the end on the left is the second end (10).

  Therefore, the first end portion (9) and the second end portion (10) are disconnected from each other in opposite directions. As shown in FIG. 7 (b), the latent image pattern element (6a) having the first end (9) and the latent image pattern element (6a) having the second end (10) It is formed so as to have an overlapping region (8) on the end side of the latent image pattern element (6a). The overlapping region (8) forms the crescent moon transmission latent image pattern (7) shown in FIG. 7 (a) and further shown in FIG.

  As shown in FIG. 7C, the term “overlap” in the present invention means a first end (9) of the latent image pattern element (6a) and a latent image pattern element having the first end (9). In the second end portion (10) of the latent image pattern element (6a) different from (6a), the first end portion (9) and the second end portion (10) are arranged in parallel at the same position. It ’s good that you do n’t have to be overlaid. Accordingly, as shown in FIG. 7 (d), the first end (9) of the latent image pattern element (6a) and the latent image pattern element (6a) having the first end (9) are In the second end (10) of the different latent image pattern elements (6a), the first end (9) and the second end (10) are not arranged in parallel at the same position. In this case, the overlapping region (8) according to the present invention is not formed, so-called overlapping region (8) is not formed.

  Further, as shown in FIG. 7D, for example, the latent image pattern element (6a) having the second end (10) and the element (6) having no end are arranged in parallel. However, since the transmission latent image pattern (7) is not formed, there is no overlap. However, a latent image pattern element (6a) having a first end (9) forming a transmission latent image pattern (7) described later and a latent image pattern element (2) having a second end (10). If an element (6) that does not have an end is placed between 6a), it shall be an overlap.

As described above, the line-shaped element (6) including the latent image pattern element (6a) needs to be incapable of being confirmed under reflected light, and therefore the element width (W ₁ ) is 50 to It is formed with a pitch of 500 μm and a pitch (P ₁ ) of 100 to 1000 μm. The elements width (W _1), as long as it is within the range of 50 to 500 [mu] m, not necessarily all the same width for each element (6) which is more disposed, may be different, If the difference between the element widths (W ₁ ) is too large, the transmitted light quantity also varies between elements other than the overlapping region (8), so that the transmitted latent image pattern (7) can be clearly seen. Therefore, it is preferable to set the same element width (W ₁ ).

It should be noted that the line-shaped element (6) formed in the present invention allows the transmission latent image pattern (7) to be confirmed while being visually recognized as a regular line without any sense of incompatibility under transmitted light. In the area where the image pattern (7) is not formed, it is necessary to make the elements regularly arranged. Accordingly, the pitch of the present invention _{(P 1)} refers to a spacing between elements other than the overlap region (8), and that of _{P 1} in FIG. 7 (a) and 7 (b). Since the interval between the elements (6) other than the overlapping region (8) is the pitch (P ₁ ), the pitch in the overlapping region (8) is P _1/2 as shown in FIG. Become.

  When the transmission latent image pattern (7) is formed by the overlapping region (8) as shown in FIG. 7A, the extent to which the latent image pattern element (6a) is overlapped depends on the transmission latent image pattern (7) to be formed. It can set suitably according to the shape.

  Further, it is also possible to form a transmission latent image pattern (7) as shown in FIG. 8A by arranging the latent image pattern element (6a). FIG. 8A shows a case where a contour is formed by the overlapping region (8) to form a transmission latent image pattern (7). The latent image pattern element (6a), the first end (9), and the second end (10) for forming the transmission latent image pattern (7) will be described.

  In the latent image pattern element (6a) shown in FIGS. 7A and 7B, since one end of one image line is interrupted, one end portion always exists in one element. An element having one end (for example, the first end (9)) has an end of another element (for example, the second end (10)) that interrupts the element in the opposite direction. There is one end in one element. Further, on the end side of the latent image pattern element (6a), no other element exists on the extension line to the latent image pattern element (6a).

  However, with regard to the latent image pattern element (6a) shown in FIG. 8 (a), on the end side of the latent image pattern element (6a-1), there is another line on the extension line to the latent image pattern element (6a-1). There is a latent image pattern element (6a-2) having an edge. Therefore, two latent image pattern elements (6a-1 and 6a-2) are formed on the same line. One latent image pattern element (6a-3) has a first end (9) and a second end (10).

  FIG. 8B illustrates this in detail. FIG. 8B shows two latent image pattern elements (6a) adjacent to each other in order to explain the latent image pattern element (6a), the first end (9), and the second end (10) in detail. ) Is an enlarged view.

  As shown in FIG. 8B, the latent image pattern element (6a-1) has a first end (9), and is collinear with the latent image pattern element (6a-1) (x). A latent image pattern element (6a-2) having a second end (10) is formed thereon. In addition, the latent image pattern element (6a-3) has a first end (9) and a second end (10) which are interrupted on both sides in one element.

The second end of the latent image pattern elements (6a-3) with respect to (10), a first end portion of the latent image pattern elements (6a-1) to (9) by overlapping region _(8-1) formed, the latent image pattern elements (6a-3) a first end of the relative (9), overlapping region by a second end of the latent image pattern elements (6a-2) (10) (8- ₂ ) To form the outline of the transmission latent image pattern (7).

As shown in FIG. 8 (a), the latent image pattern element having only the first end (9) is used for the pitch when forming the transmission latent image pattern (7) by forming the contour in this way. (6a-1) element spacing, element spacing between latent image pattern elements (6a-2) having only the second end (10), and the first end (9 ) And the latent image pattern element (6a-3) having the second end portion (10), and both have the same pitch (P ₁ ). Thus, the pitch in the overlap region _(8-1) and (8 ₂₎ becomes _P 1/2 as shown in Figure 8 (b).

  As described above, when the transparent latent image pattern (7) is formed by forming the contour by the overlapping region (8), the extent of overlap may be set as appropriate depending on the extent of the contour. However, if the overlapping range is too narrow, it cannot be confirmed as a contour, and if the overlapping range is too wide, the contour or contour is not uncomfortable, so it may be 500 to 5000 μm. preferable.

  7 and 8, the latent image pattern elements (6a, 6a-1, 6a-2) are arranged adjacent to each other as shown in FIG. In addition, an element (6) having no end may be arranged between the latent image pattern element (6a) having the first end (9) and the second end (10). Even with such an arrangement, it is not possible to form a transparent transmission latent image pattern (7) that is as clear as the form in which the latent image pattern elements (6a) are arranged adjacent to each other, but an element having no end ( Since the overlapping region (8) is formed with 6) in between, the transmission latent image pattern (7) can be formed.

In the case where such an element (6) having no end portion is arranged between the latent image pattern elements (6a), if the number of the elements (6) to be arranged between them is too large, the overlapping region The interval between the latent image pattern elements (6a) for forming (8) becomes too large, and it becomes difficult to form the transmission latent image pattern (7). The transmission latent image pattern (7) to be formed may be appropriately set according to the shape, element width (W ₁ ) and pitch (P ₁ ).

  As described above, the transmission latent image pattern (7) is formed by the overlapping region (8) formed by the first end (9) and the second end (10) of the plurality of arranged line-like elements (6). Thus, the formed overlapping region (8) has a higher density of the elements (6) than the region where the other line-shaped elements (6) are arranged, and the light reflecting layer (4) Since the element (6) is formed by being deleted, the amount of transmitted light is increased when observing under transmitted light, so that it can be confirmed as a transmitted latent image pattern (7).

  Next, a method for producing the element (6) will be described. As described above, the element (6) is formed so that a part of the light reflection layer (4) transmits light in a line shape. Therefore, when the light reflecting layer (4) is made of a single layer of a metal material such as plain gold, silver, copper, aluminum, titanium, etc. shown in FIG. 2 (a), a known vacuum such as laser processing or sputtering is used. It can be formed by vapor deposition. Moreover, about the method of forming an element (6) with respect to OVD which has the light reflection layer (4) shown in FIG.2 (b), it is possible to form by well-known laser processing or demetalization processing. For example, a processing method described in JP 2007-240785 A, which has already been disclosed by the present applicant, may be used. Furthermore, about the method of forming a light reflection layer (4) with a metal ink, an element (6) part is made into a non-image area part by well-known printing systems, such as an offset printing system and an inkjet printing system, using a metal ink. It is sufficient to print as follows. In addition, the metal ink which can be used can use offset ink (UV No.3 silver made from T & K TOKA) which is silver ink, for example. As described above, whether or not a metallic material is specifically removed as a fine element (6) formed by the absence of a part of the light reflecting layer in at least a part of the light reflecting layer (4)? Alternatively, it can be formed by a region where printing ink containing a metal material is printed (applied) and a region where printing ink is not applied.

  For the light reflecting layer (4), as described with reference to FIG. 2, using the OVD having the light reflecting layer (4) and the OVD image (5) under the reflected light and the transmission under the transmitted light. The effect that two images of the latent image pattern (7) can be confirmed and the OVD image (5) camouflages the line-shaped element (6) including the latent image pattern element (6a) under reflected light. Therefore, the effect of the present invention is further exhibited. Therefore, it is preferable to form the transmission latent image pattern (7) using OVD.

  As described above, the transmission latent image pattern formed body (1) in the present invention in which the latent image pattern region (3) is formed using the OVD having the light reflection layer (4) is as shown in FIG. The OVD image (5) “plurality of stars” formed on the OVD can be visually recognized at a certain angle under reflected light, and the base on which the OVD is attached as shown in FIG. When viewed from the surface side of the substrate on which the OVD is applied by irradiating with an arbitrary light source from the opposite side of the material surface, the transmission latent image pattern (7) “moon” can be visually recognized. In addition, in FIG.10 (b), although the example which irradiated arbitrary light sources was shown, even if a base material is watermarked with sunlight, a transmission latent image pattern (7) can be visually recognized similarly.

  Hereinafter, the transmission latent image pattern formed body in the present invention will be described in detail using examples. However, the present invention is not limited to the following examples, and may be a technical category described in the claims. If necessary, it can be changed as appropriate.

  In Example 1, the light reflection layer (4) is a transmission latent image pattern formed body (1) produced using the plain metal foil shown in FIG. 2 (a). The transmission latent image pattern formed body (1) of Example 1 will be described with reference to the drawings described in the embodiment.

  As shown in FIG. 1, the transmission latent image pattern formed body (1) (specifically, a gift certificate) of Example 1 is formed on a part of the latent image pattern area (3) on the substrate (2). A plain light reflecting layer (4) shown in FIG. 2A is affixed, and in other areas, a product name, a fee character of 1000 yen, and a colored pattern are formed by offset printing.

The base material (2) shown in FIG. 1 was a brown paper material having a basis weight of 85 g / m ² , a paper thickness of 87 μm, and an opacity of 75% (JIS-P8149). Moreover, the aluminum foil was used for the light reflection layer (4).

  In the light reflection layer (4), the fine elements (6) (including the latent image pattern element (6a)) shown in FIG. 3 are arranged in a line, and a transmission latent image pattern (7) is partially formed. Is formed. As a specific configuration of the transmission latent image pattern (7), a latent image pattern element (6a) having a first end portion (9) and a second end portion (10) as shown in FIG. ) Alternately arranged, the latent image pattern element (6a) on the first end (9) side and the latent image pattern on the second end (10) side are arranged. An overlapping region (8) is formed by the element (6a).

The fine element (6) and the latent image pattern element (6a) were formed as a straight line having a line width (W ₁ ) of 200 μm and a pitch (P ₁ ) of 500 μm. Since the pitch _{(P 1)} are all equal, the latent image pattern elements in the overlap region (8) (6a) to each other _has a _P 1/2 pitches.

  Since the transmission latent image pattern (7) formed by the overlapping region (8) has a crescent moon shape as shown in FIG. 7, the range of the overlapping region (8) is 1 mm at the shortest and the longest at the longest. However, it is 5 mm.

  The fine element (6) including the latent image pattern element (6a) is formed by applying an acrylic adhesive (spray paste 55 manufactured by 3M) to the base material (2) and pasting it on the aluminum foil. Using a laser beam machine (Laser Marker MD-V, manufactured by Keyence), the fine elements (6) including the latent image pattern element (6a) were removed linearly.

  When the gift certificate which is the transmission latent image pattern formed body (1) of Example 1 thus produced is observed under reflected light from the side where the light reflecting layer (4) is applied, FIG. The solid aluminum luster shown in Fig. 1 was confirmed. When the transmission latent image pattern formed body (1) of Example 1 is observed under transmitted light from the side where the light reflection layer (4) is attached, the transmission latent image pattern having a crescent moon pattern shown in FIG. (7) was confirmed.

  In the second embodiment, only differences from the first embodiment will be described. In Example 2, an OVD foil having the OVD image (6) shown in FIG. 2B is used for the light reflecting layer (4), and the minute element (6) including the latent image pattern element (6a) is a minute element. It is the transmission latent image pattern formation body (1) comprised by the group.

  The OVD foil used for the light reflection layer (4) uses an aluminum layer as a base material, and a diffraction grating for forming an OVD image (6) is formed thereon. The aluminum layer was formed by linearly removing the fine elements (6) including the latent image pattern element (6a) using a laser processing machine (Laser Marker MD-V, manufactured by Keyence).

The microelement group constituting the fine element (6) including the latent image pattern element (6a) is configured by arranging a plurality of points shown in FIG. In addition, the microelement group was formed with a constant pitch with a diameter (h ₁ ) of one point, a so-called element width (W ₁ ) of 250 μm, and a pitch (p ₁ ) between the points of 300 μm. Then, the pitch (P ₁ ) of the fine elements (6) including the latent image pattern element (6a) was set to 500 μm, and the transparent latent image pattern (8) was formed by arranging in a line. In addition, the hot-melt agent was provided to the back surface of OVD foil, and it affixed on the base material (2) by thermocompression bonding.

  When the gift certificate which is the transmission latent image pattern formed body (1) of Example 2 thus produced is observed under reflected light from the side where the OVD foil (4) is applied, the optical change of the OVD is observed. The OVD image (6) consisting of a plurality of stars shown in FIG. 2 (b) was confirmed. Then, when observed under transmitted light from the side where the OVD foil (4) was applied, the transmitted latent image pattern (7) having a crescent moon pattern shown in FIG. 3 was confirmed.

  As described above, the configuration of Example 2 complicates the configuration of the transmission latent image pattern formed body (1), and further uses the OVD foil for the light reflection layer (4). As a result, it was possible to obtain a transmission latent image pattern formation corps (1) that also had the effect of hiding the fine elements (6).

  The third embodiment will be described only with respect to differences from the first embodiment. In the third embodiment, the configuration of the fine element (6) including the latent image pattern element (6a) forms a pattern contour as shown in FIG. 8, and the light reflection layer (4) 2 is a transmission latent image pattern formed body (1) having the same OVD foil as in FIG. The transmission latent image pattern (7) in Example 3 is a star pattern formed by the contour shown in FIG.

  FIG. 11B is an enlarged view of a region surrounded by a dotted line with respect to the transmission latent image pattern (7) shown in FIG. The fine element (6) including the latent image pattern element (6a) formed on the aluminum layer constituting the OVD foil is regarded as a straight line in FIG. 11 (a), but as shown in FIG. 11 (b). In addition, the overlapping region (8) is formed by a straight line, and the others are formed by a group of minute elements of pixels. This is because the configuration of such an element has an effect that the amount of light in the overlapping region (8) is higher than in other regions.

Each pixel constituting the microelement group has a square shape with a height (h ₁ ) of 200 μm, a so-called straight line width (W ₁ ) of 200 μm, and a pitch (p ₁ ) between the pixels of 250 μm. The pitch was constant. Then, the pitch (P ₁ ) of the fine elements (6) including the latent image pattern element (6a) is set to 500 μm, and the latent image pattern element (6a-1) having only the first end (9), A latent image pattern element (6a-2) having only two end portions (10) is formed on the same line, and next to the first end portion (9) and the second end portion (10). The latent image pattern element (6a-3) is formed, the arrangement is alternately arranged in a line, and arranged so that the overlapping area (8) comes to the star-shaped contour portion. (7) was formed.

The overlapping range of the latent image pattern elements (6a) in the overlapping region (8) is 400 μm. This overlapping range is the outline of the so-called transmission latent image pattern (7). Further, since the pitches (P ₁ ) between the latent image pattern elements (6a) are formed to be equal, the adjacent latent image pattern elements (6a) in the overlapping region (8) are 250 μm of P _1/2. It has become.

  When the gift certificate which is the transmission latent image pattern formed body (1) of Example 3 thus produced is observed under reflected light from the side where the OVD foil (4) is applied, the optical change of the OVD is observed. The OVD image (6) consisting of a plurality of stars shown in FIG. 2 (b) was confirmed. When observed under transmitted light from the side on which the OVD foil (4) was applied, the transmission latent image pattern (7) having a star-shaped outline shown in FIG. 11 (a) was confirmed.

  Thus, by setting it as the structure of Example 3, the structure of a latent image pattern element (6a) becomes more complicated, and the forgery prevention effect can be improved further.

DESCRIPTION OF SYMBOLS 1 Transmission latent image pattern formation body 2 Base material 3 Latent image pattern area | region 4 Light reflection layer 5 OVD image 6 Element 6a, 6a-1, 6a-2, 6a-3 Latent image pattern element 7 Transmission latent image pattern 8, 8- _1, 8 ₂ overlap region 9 pitch X collinear pitch _{p 1} minute elements of the first end 10 second end _W 1, _{h 1} element width _{P 1} elements

Claims (12)

A latent image pattern region is formed on at least a part of the substrate, and a light reflective layer is formed in the latent image pattern region.
At least a part of the light reflection layer, fine elements formed by the absence of a part of the light reflection layer are arranged in a line,
The plurality of fine elements arranged in a line shape has a plurality of latent image pattern elements having at least one end cut off,
The plurality of latent image pattern elements include at least one of a first end where one end is interrupted and a second end where the other end different from the one end is interrupted,
In the plurality of latent image pattern elements, a transmission latent image pattern is formed by an overlapping region of the first end portion and the second end portion in different latent image pattern elements,
When the latent image pattern region is viewed under transmitted light, the transmitted latent image pattern is formed in the fine elements formed in a line shape due to a difference in light transmission amount between the overlapping region and other regions. A transmission latent image pattern formed body characterized by being formed.   In the plurality of latent image pattern elements, the overlapping region is formed by a latent image pattern element having only the first end portion and a latent image pattern element having only the second end portion. The transmission latent image pattern formed body according to claim 1.   The latent image pattern element having only the first end portion and the latent image pattern element having only the second end portion are alternately arranged adjacent to each other. Transmission latent image pattern formed body.   In the plurality of latent image pattern elements, the latent image pattern element having only the first end and the latent image pattern element having only the second end disposed on the same line, and the first end. 2. The transmission latent image pattern forming body according to claim 1, wherein the overlapping region is formed by a latent image pattern element having both of the second end portion and the second end portion.   A latent image pattern element having only the first end and the latent image pattern element having only the second end, and the first end and the second end disposed on the same line; 5. The transmission latent image pattern forming body according to claim 1, wherein the latent image pattern elements having both are alternately arranged adjacent to each other.   The fine element having no end portion is disposed between the latent image pattern element having the first end portion forming the overlapping region and the latent image pattern element having the second end portion. The transmission latent image pattern formed body according to any one of claims 1 to 5, wherein:   The transmission latent image pattern formed body according to any one of claims 1 to 6, wherein element widths of the plurality of fine elements are all the same or at least one different.   8. The transmission latent image pattern formed body according to claim 1, wherein the fine element has an element width of 50 to 500 μm and a pitch of 100 to 1000 μm. 9.   9. The transmission latent image pattern according to claim 1, wherein a pitch of the fine elements in the overlapping region is ½ of a pitch of the fine elements other than the overlapping region. Formed body.   10. The transmission latent image pattern according to claim 1, wherein the light reflection layer is made of a light reflective metal material, and the fine element is formed by removing the metal material. Formed body.   The transmissive latent image pattern formed body according to any one of claims 1 to 10, wherein the light reflection layer is OVD.   The transparent latent image pattern formed body according to any one of claims 1 to 11, wherein the fine element is composed of at least one of an image line or a group of fine elements, or a combination thereof.

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