JP2007240787A - Hologram sheet and printing medium - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide media of high value, requiring forgery prevention and duplication prevention, such as bank notes, passports, brand protection. <P>SOLUTION: A hologram sheet has a hologram image region, comprising a latent-image image region and a latent image background region on the surface of a diffraction grating formed on one surface of a hologram forming layer, has a latent-image image line or a latent-image image pixel, comprising an optical transmission member and an optical reflecting region, comprising an optical reflecting member formed on the background of the latent-image image line or the latent-image image pixel on the latent-image image region, and has an optical reflecting region, comprising the optical reflecting member on the latent image background region. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a hologram sheet and a print medium in which the hologram sheet is attached to a substrate such as paper. In particular, the present invention is used for a highly valuable medium such as banknotes, passports, and brand protection, and can be applied to a medium that requires anti-counterfeiting or authenticity determination.

  As a method for enhancing a security function for preventing forgery by attaching a hologram on the surface of a card medium such as a magnetic card or a paper medium such as a banknote or various securities, it is known. However, with the rapid improvement in accuracy of electronic devices such as copiers and personal computers, simple holograms have not been able to obtain sufficient functions for preventing counterfeiting. Accordingly, it has been disclosed as in the following prior inventions to form a transparent layer or a transparent portion by providing a non-metal region in a metal layer or a metal vapor deposition layer constituting a hologram.

  For example, by washing away the hologram masking print layer, a metal reflective layer with a desired pattern (diamond, heart, clover, spade, etc.) is provided, and the degree of freedom in design is increased, and fine patterns and complex patterns are formed. A technique is disclosed (for example, see Patent Document 1).

As a method for removing the metal vapor deposition layer of the hologram, for example, a technique is disclosed in which the metal vapor deposition layer is melted in a non-contact manner by irradiation with a laser beam such as YAG or CO ₂ to form a print pattern as fixed information ( For example, see Patent Document 2).

  Further, a technique is disclosed in which a metal vapor deposition type thermal transfer hologram sheet is partially irradiated with a laser to evaporate a metal vapor deposition layer at the irradiated portion into a slit shape or a mesh shape (for example, see Patent Document 3).

  Furthermore, a technique is disclosed in which a print design forming unit and a watermark design forming unit are formed on a hologram by laser processing or etching processing of a metal vapor deposition film of the hologram (see, for example, Patent Document 4).

JP 11-286194 A JP-A-10-333574 JP 2003-150027 A JP 2005-14492 A

  By the way, according to Japanese Patent Application Laid-Open No. 11-286194, which is a prior invention, a non-metal region is provided in a metal vapor deposition layer of a hologram to form a desired pattern (diamond heart clover spade is disclosed). In creating a design, there is an advantage that an arbitrary pattern can be freely formed. However, from the viewpoint of security regarding forgery prevention, the desired pattern to be formed in the non-metal region in the metal vapor deposition layer by the hologram is a simple pattern, and the entire pattern pattern is formed with or without the metal vapor deposition layer. Therefore, there is a problem in terms of security because it is easy to imitate when copying and copying. Therefore, it has been desired to increase the forgery resistance by making the non-metal region in the metal vapor deposition layer more effective.

Japanese Patent Laid-Open No. 10-333574 of the prior invention forms a print pattern as fixed information by melting a metal vapor deposition layer of a hologram in a non-contact manner by irradiation with a laser beam such as YAG or CO ₂ . As specific print patterns, management numbers, characters, and the like are disclosed, and the object and use of the present invention are achieved by recording fixed information having a size that can be visually recognized. However, when fixed information is made into a fine structure (for example, a fine line or dot aggregate), since the lines and dots are very small, variations in the output of the laser beam occur and the laser output decreases. In this case, it is not formed as a line or a point, and conversely, when the laser output is increased, it may be larger than the line or point of the set width, so that it is not suitable to form a fine body. Therefore, when fixed information is processed with a laser beam, characters and the like that are not easily affected by variations in the output of the laser beam are suitable, and there is a problem when the fixed information has a fine structure.

  In addition, Japanese Patent Application Laid-Open No. 2003-150027 of the prior invention partially irradiates a metal layer deposition layer of a hologram sheet with a laser and evaporates the metal deposition layer of the irradiated portion into a slit shape or a mesh shape. A pseudo-transparent or translucent hologram sheet is left to form. Although the present invention is suitable for low-volume production of various types in terms of cost, the mass-produced product is affected by variations in the output of the laser beam. (Accuracy to be removed) also causes variation, and is not suitable when the same machining accuracy and machining quality are always required. On the other hand, an apparatus having a laser beam capable of precise processing requires a function and space for controlling heating by a laser, and the apparatus itself becomes large and the price of the apparatus becomes high, which cannot be realized at low cost.

  Further, the metal vapor deposition layer of the hologram is evaporated by laser processing, and when viewed through the slit shape or mesh shape, it looks as if it is transparent (or translucent), thereby functioning as a pseudo-transparent hologram. The purpose of making the slit shape and the mesh shape is to form a transparent (or translucent) hologram when viewed with the naked eye by repeatedly forming a removed portion and a non-removed portion on the metal deposition layer by laser processing. It gives the light and shade of. However, in terms of security regarding forgery prevention, when determining the authenticity of the hologram, the density of “transparent (or translucent)” or “not transparent (or translucent)” is used as a reference. Since standards differ depending on individual differences and objective judgment cannot be made, there is a problem that it is not suitable as a true / false discrimination means, and a true / false discrimination means that anyone can objectively judge has been desired.

  On the other hand, as information that can be seen through the metal deposition layer of the hologram by laser processing, characters and numbers are specifically disclosed. Although it is visible, there is a disadvantage that letters and numbers can be visually recognized in a reflective state even if it is not transparent, and as a latent image effect on security, a configuration in which the information is not visible when viewed in a more reflective state has been desired. .

  Further, Japanese Patent Application Laid-Open No. 2005-14492, which is a prior invention, includes a print design forming unit on a hologram and a watermark design forming unit by laser processing or etching processing of a metal vapor deposition film of the hologram. The watermark design forming part is letters and numbers, and there is no specific description in the size of the letters, and it can be seen even if it is watermarked, but on the other hand, letters and numbers can be seen in a reflected state even if it is not transparent As a latent image effect in terms of security, a configuration in which information cannot be seen in a more reflective state has been desired.

  The present invention provides a hologram sheet having a hologram forming layer, wherein a hologram image region comprising a latent image region and a latent image background region is formed on the surface of a diffraction grating formed on one surface of the hologram forming layer. And the latent image area includes a latent image line or latent image pixel made of a light transmissive member and a light reflective member formed on the background of the latent image line or latent image pixel. A hologram sheet, wherein the latent image background area includes a light reflection area made of a light reflective member.

  A hologram sheet having a hologram forming layer, the hologram sheet having a hologram image region composed of a latent image region and a latent image background region on the surface of the diffraction grating formed on one surface of the hologram forming layer. The latent image area has a light reflecting area made of a light reflecting member, and the latent image background area has a latent image background line or a latent image background pixel made of a light transmissive member, and the latent image. A hologram sheet comprising a light reflecting region made of a light reflecting member formed on the background of a background line or a latent image background pixel.

  Further, the present invention is the hologram sheet, wherein the latent image line or the latent image background line is formed in a lattice shape.

  Further, the present invention is the hologram sheet, wherein the latent image line or the latent image background line is formed with a line width of 0.08 mm to 0.16 mm.

  In the latent image area, the latent image line is formed by shrinking n times (an integer equal to or greater than 1) n times at an equal pitch along the contour line. It is.

  Further, the present invention is the hologram sheet, wherein the latent image line is based on the center of the contour line.

  In addition, the present invention provides the hologram sheet, wherein the latent image image pixels or the latent image background pixels are regularly formed in a matrix.

  The present invention is also the hologram sheet characterized in that the latent image pixel or the latent image background pixel is formed of any one of a circle, a polygon, a character, or a mark.

  Further, the present invention is the hologram sheet characterized in that the latent image area is formed with any one of a color pattern, a pattern, a pattern, a mark, and a character.

  Further, the present invention is the hologram sheet, wherein a transparent region made of a light transmissive member is formed around the hologram image region in the hologram forming layer.

  In addition, the present invention is a printing medium in which a hologram forming layer is bonded to a base material through an adhesive layer.

  The present invention is the print medium, wherein the print medium is a bank note.

  The hologram image area of the printing substrate to which the hologram sheet and the hologram forming layer of the present invention are attached with an adhesive is a light reflection area of a latent image image area and a latent image background area made of a light reflective member when viewed in a reflective state. Thus, the hologram effect can be visually observed with the diffracted light or the reflected light, but the latent image line (or latent image image pixel) formed with the light transmitting member in the hologram image region cannot be visually observed. On the other hand, when the hologram image region is viewed in a transparent state, the hologram effect cannot be visually observed, but the transmitted light of a plurality of latent image lines (or latent image image pixels) formed transparently by the light transmitting member in the hologram image region. Thus, the latent image area can be visually confirmed as characters, marks, and patterns. At this time, the latent image line (or latent image pixel) is difficult to see because it is fine as one line, but a plurality of latent image lines (or latent images) are formed in the latent image area. When the latent image area is viewed as an area (or area), information or patterns (for example, characters, marks, designs, etc.) formed in the area can be easily recognized. Therefore, it has the merit that two kinds of effects, that is, the hologram effect in the reflection state and the latent image effect in the transmission state can be visually discriminated without using a true / false discrimination tool. The same effect can be obtained even if the hologram forming layer of the present invention is attached to a base material such as paper, film or card with an adhesive, and is suitable for banknotes and securities. However, the substrate must be a material or material that transmits light above a certain level. In the above description, the latent image area is provided with a latent image line (or latent image pixel), but the latent image background area is provided with a latent image background line or latent image background pixel. It doesn't matter.

  Further, the light reflecting member in the hologram image region of the hologram sheet is formed of a highly glossy metal material such as aluminum, and therefore has high resistance to copying and duplication. The reason for this is that devices such as color copiers and scanners apply strong dropped light to the object to be copied or the object to be copied to obtain an input image. Aluminum, which has high light reflectivity, has a high reflectance of the light to be dropped. Therefore, it is difficult to reproduce accurately. In addition, in the present invention, since the latent image image lines (or latent image image pixels) formed of a light transmissive member (for example, a transparent thermoplastic resin) in the hologram image region are fine, each one of them. The latent image line (or latent image pixel) makes copying and duplication more difficult due to light reflected by a light reflecting region (for example, aluminum) that is a light reflecting member or diffracted light by a diffraction grating. . Therefore, since the hologram sheet of the present invention has two different types of prevention functions against copying and duplication, double security can be provided.

  Moreover, even if the hologram forming layer of the hologram sheet of the present invention is affixed to a substrate, a latent image effect due to the transmission state can be obtained. For example, a technique is disclosed in which holes are made in a base material such as paper and a latent image can be visually observed in a transmission state. However, in this technique, a hole is made in the base material itself. However, when the hologram forming layer of the hologram sheet of the present invention is directly attached to the base material, the durability of the base material itself does not decrease, and the ATM or ticket machine It does not have an adverse effect on the transport. Here, the “pixel” is an element formed by a light transmissive member of the latent image area or the latent image background area, and when the area of the pixel is changed, the pixel is observed in a transmissive state. The amount of transmitted light also changes. The “pixel” is the same as a halftone dot in the printing industry.

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

(Form of hologram sheet)
FIG. 1 is a schematic view of a hologram sheet 1 of the present invention. The hologram sheet 1 is wound in a roll shape and includes a hologram image area 6, a transparent area 6 e, and a positioning mark 9. The hologram image area 6 includes a light reflecting area 6a and a light reflecting area 6c made of a light reflecting member, and a latent image line 6b (or a latent image image pixel 6b) made of a light transmissive member. The light reflection area 6a and the light reflection area 6c have a hologram effect when viewed in a reflected state, and the latent image line 6b (or latent image image pixel 6b) is visually observed when viewed in a reflected state. Although it is not possible (or a latent image is formed), a line can be visually observed (or a building image is formed) when viewed in a transmissive state. The transparent region 6e is made of a light transmissive member and does not require the hologram effect. Therefore, the transparent region 6e is preferably transparent or semi-transparent, and is similar to the latent image line 6b (or latent image image pixel 6b). Of the hologram processing layer 4. On the other hand, the positioning mark 9 is made of a light-reflective member. When the positioning mark 9 is continuously pasted on a base material 10 such as paper or plastic, the positioning mark 9 in the pasting machine is read by an optical sensor or the like, and the hologram sheet 1 The adhesive layer 8 laminated on the lowermost part is bonded to the substrate 10 at a certain position by thermocompression bonding. Therefore, when the hologram sheet 1 of the present invention is affixed to the substrate 10, the positioning mark 9 is not affixed to the substrate 10, and the hologram image region 6 and the transparent region 6e around the hologram image region 6 can be affixed. desirable. The hologram sheet 1 shown in FIG. 1 is described in a roll shape because it is continuously stuck by a sticking machine. However, the hologram sheet 1 does not have to have a positioning mark 9 and the hologram image region 6 is arranged in a matrix. A plurality of sheet-like forms may be used, or the hologram sheet may be constituted by a light reflecting member alone without the transparent region 6e. Further, the shape of the positioning mark 9 is not limited, and the shape may be appropriately selected depending on the model of the sticking machine.

  The “hologram effect” described in the present invention means that when the hologram image region 6 of the present invention is viewed in the “reflected state”, the color of the design changes to rainbow colors due to the diffracted light or reflected light of the diffraction grating. The hologram has the effect that the image is switched to another image, either in the state of the hologram sheet 1 or in the state where the hologram forming layer 3 of the hologram sheet 1 is attached to the base material 10 using the adhesive layer 8 or the like. An effect is obtained. The hologram forming layer 3 is formed by forming fine irregularities to be a diffraction grating or a diffraction grating pattern on the hologram processing layer 4, and attaching a highly glossy light reflecting member such as aluminum to the irregular surface by vapor deposition or the like. Can be made. A specific hologram effect refers to an effect such that a plurality of symbols and colors change depending on the viewing angle, such as a hologram attached to a bank note such as Japan or the euro. Further, the hologram effect is not limited to the effect seen in the banknote hologram, but may be the effect of a hologram attached to a known card, gift certificate, or certificate. The “latent image effect” described here means that when the hologram image region 6 of the present invention is viewed in a “reflective state”, information such as characters, symbols and marks cannot be viewed (or becomes a latent image). However, when viewed in the “transparent state” (or when viewed through a watermark), the latent image area can be viewed as information on characters, designs, marks, and the like.

  2A and 2B are diagrams in which the hologram forming layer 3 of the hologram sheet 1 is attached to the base material 10. FIG. The specific predetermined area is the hologram image area 6 and the surrounding transparent area 6e. Further, it is desirable that the base material 10 is paper, and necessary information such as a fee, a human image, and a background pattern is applied by offset printing, intaglio printing, or screen printing. As shown in FIG. 2A, the hologram image area 6 is divided into a latent image area and a latent image background area. As shown in FIG. 2B, the latent image area includes a latent image line 6b (or latent image pixel 6b) made of a light transmissive member and the latent image line 6b (or latent image). It is composed of a light reflecting region 6a made of a light reflecting member formed on the background of the image image pixel 6b). On the other hand, the latent image background area is composed of a light reflecting area 6c made of a light reflecting member. The configurations of the latent image area and the latent image background area may be reversed.

(Configuration of hologram forming layer)
FIG. 3A is a configuration diagram of the hologram sheet 1 of the present invention, and the hologram sheet 1 is formed of a hologram sheet substrate 2, a hologram forming layer 3, and an adhesive layer 8. The hologram sheet substrate 2 is composed of a sheet substrate 2a and a release layer 2b, and is transparent or translucent on one surface of the sheet substrate 2a using a coating machine, a gravure coater, a gravure printing machine, a screen printing machine, or the like. The release layer 2b is laminated. The hologram forming layer 3 is formed by the hologram processing layer 4, the diffraction grating 5 (more precisely, the unevenness 5 a in close contact with the light reflecting member and the unevenness 5 b made of the light transmitting member), and the mask layer 7. In the case of pasting, the hologram forming layer 3 is bonded and formed on the base material 10 via the adhesive layer 8. The hologram forming layer 3 is manufactured by laminating a transparent or translucent hologram processing layer 4 as a light transmitting member on the surface of the release layer 2b, and diffracting with a fine unevenness or unevenness pattern in order to exhibit the hologram effect. A lattice 5 is formed. The diffraction grating 5 is formed by thermally transferring the unevenness of the diffraction grating 5 formed on one surface of a metal stamper (not shown) to the surface layer of the hologram forming layer 4. Precisely, the unevenness formed on the stamper becomes the diffraction grating 5 because the unevenness is reversed in the hologram processing layer 4. Next, after a light reflective member such as aluminum is vacuum-deposited or sputtered on the surface of the hologram processing layer 4, the mask layer 7 is formed by a gravure printing machine or the like and immersed in an alkaline solution to be protected by the mask layer 7. The aluminum formed on the diffraction grating 5 that has not been dissolved is dissolved and removed to form transparent irregularities 5b made of a light transmitting member. Accordingly, the light transmissive member becomes the hologram processing layer 4. On the other hand, aluminum (thick line portion in the figure) remains only in the region covered with the mask layer 7 to form the unevenness 5a in close contact with the aluminum. Specifically, of the hologram image region 6, the latent image region is composed of a light reflection region 6a (thick line portion in the figure) in which aluminum remains and a light transmission region 6b in which aluminum is dissolved. 6b is formed as a transparent or semi-transparent line or pixel and becomes a latent image line 6b (or latent image pixel 6b). On the other hand, the latent image background region is composed of a light reflection region 6c (thick line portion in the figure) where aluminum remains. Further, the transparent area 6e around the hologram image area 6 includes the diffraction grating 5 and / or the flat surface of the hologram forming layer 4, and is preferably a light transmissive member and transparent or semitransparent. Further, an adhesive layer 8 is laminated below the mask layer 7, the latent image line 6b (or latent image pixel 6b), and the transparent region 6e so that the thickness of the entire hologram sheet 1 is substantially uniform. As a method of forming a transparent or translucent region made of a light transmissive member on the hologram sheet 1, a mask layer is formed on the diffraction grating 5 of the hologram processing layer 4 with water-soluble ink, and then vacuum deposition or the like is used. A method may be used in which a light reflecting member is closely attached, the mask layer is removed, and a transparent or translucent layer is formed. It should be noted that the hologram forming layer 3 in FIG. 3A is shown to have a considerable thickness for convenience of explanation, but in an actual configuration, it is an extremely thin layer, as shown in FIGS. 3B and 3C. The thickness of the hologram forming layer 3 is the same in the actual configuration.

  The sheet base material 2a of the hologram sheet base material 2 is preferably a transparent plastic. For example, a known resin such as PET may be used. The release layer 2b, the hologram processing layer 4, and the adhesive layer 8 may be appropriately selected from known resins such as thermoplasticity and thermosetting, but the hologram processing layer 4 is a transparent or translucent material that is a light-transmitting member. Resin is desirable. The light reflecting member includes aluminum, copper, nickel, tin, etc., but aluminum having high luminance and advantageous in terms of economy is suitable, and may be formed using vacuum deposition or sputtering. Moreover, when aluminum is used for the light reflective member, a thickness of 100 to 2000 mm is desirable.

(Attaching method of hologram forming layer)
FIG. 3B is a schematic view in which the forming layer 3 which is a part of the hologram sheet 1 is attached to the base material 10 by pressing the hologram sheet 1 against the base material 10 using the high temperature heated stamp S. It is. The adhesive layer 8 is melted by heat and fixed to the substrate 10, but a hot melt material is desirable. At the time of pasting, the positioning mark 9 shown in FIG. 1 may be read and pasted with an optical sensor. FIG. 3C is a diagram in which the hologram forming layer 3 is stuck on the base material 10 after being pressed with the marking S. Therefore, the hologram forming layer 3 attached to the substrate 10 is a region pressed by the marking S and is a portion laminated below the hologram forming layer 4 and is higher than the hologram forming layer 3. The formed hologram sheet base 2 (sheet base 2a and release layer 2b) is peeled off and is not attached to the base 10. However, if the release layer 2b is transparent or translucent, even if it remains on the surface layer of the hologram forming layer 3, the hologram effect is not hindered, and therefore the release layer 2b may remain somewhat. The substrate 10 is preferably paper, plastic, cloth, film or the like.

(Thickness of hologram sheet)
3A to 3C are schematic diagrams. In an actual hologram sheet 1, the sheet base material 2a has a thickness of 0.015 mm to 0.025 mm, and a hologram forming layer to be attached to the base material 10 The thickness of No. 3 is desirably 0.005 mm to 0.030 mm, and it is effective to prevent forgery if the thickness of the hologram forming layer 3 is extremely thin.

(Configuration of diffraction grating)
The structure of the diffraction grating 5 of the hologram forming layer 3 is not particularly limited as long as it uses a well-known hologram having a fine concavo-convex pattern such as a well-known relief hologram or rainbow hologram.

(Configuration of latent image line)
4 to 8 are enlarged views of the hologram forming layer 3 attached to the substrate 10 shown in FIG. 4, 6, 7, and 8 are embodiments including the latent image line 6 b (or latent image image pixel 6 b) by the light transmissive member that is a feature of the present invention. A hologram forming layer 3 which is a part is attached to the base material 10 with an attaching machine or the like, and a hologram image region 6 which is a part of the hologram forming layer 3 and a transparent region 6e in the periphery thereof are attached to the base material 10. Yes. In addition, the hologram sheet 1 according to the present invention divides the hologram image area 6 of the hologram sheet 1 into a latent image area and a latent image background area, and the latent image area includes a plurality of latent image images made of a light transmissive member. A line 6b (or latent image pixel 6b) and a light reflecting area 6a made of a light reflecting member are provided, and a light reflecting area 6c made of a light reflecting member is provided in the latent image background area. 4, 6, 7, and 8, the layer configuration of the hologram sheet is the same, but the configuration of the latent image line 6 b (or latent image pixel 6 b) made of a light transmitting member is different. However, in FIG. 5, the latent image area is a light reflecting area 6a made of a light reflecting member, and the latent image background area is a latent image background line 6d made of a light transmitting member and a light reflecting area 6c made of a light reflecting member. The structure is the reverse of that shown in FIGS.

  FIG. 4 shows an embodiment of the present invention, in which a hologram patch (latently, the hologram forming layer 3 is formed) in which a latent image line 6b made of a light transmitting member is formed in the latent image area of the hologram image area 6. The character “5” is formed in the latent image area.

  FIG. 5 shows an embodiment of the present invention, which is a hologram patch in which a latent image background line 6d made of a light-transmitting member is formed on a latent image background area of the hologram image area 6. "Is formed.

  FIG. 6 shows an embodiment of the present invention, which is a hologram patch in which a latent image line 6b made of a light transmitting member is formed in a latent image area of the hologram image area 6. "Crest" is formed. Note that the “color pattern” here refers to a geometric pattern combining straight lines, curved lines, wavy lines, arcs, circles, and the like.

  FIG. 7 shows an embodiment of the present invention, which is a hologram patch in which a latent image line 6b made of a light transmitting member is formed in a latent image area of the hologram image area 6. "Crest" is formed.

  FIG. 8 shows an embodiment of the present invention, which is a hologram patch in which a latent image pixel 6b made of a light transmitting member is formed in the latent image area of the hologram image area 6. "Is formed.

(Hologram effect)
When the hologram forming layer 3 shown in FIGS. 4 to 8 is used, the unique effect of the present invention can be obtained. That is, as shown in FIG. 9, when viewed from the surface of the base material 10 to which the hologram forming layer 3 is attached (the surface on which the hologram forming layer 3 is attached to the base material 10) in the “reflected state”, As described above, the diffracted light from the diffraction grating 5 allows visual observation of various hologram effects depending on the observation angle. Specifically, the appearance of a plurality of symbols and the color change of the symbols can be confirmed depending on the observation angle. For example, in FIG. 10, (a) is a letter and color “A” when observed at a predetermined angle in the X direction, and (b) is a pattern and color of “sun” when observed at a predetermined angle in the X direction. (C) shows a “star” design and color when observed at a predetermined angle in the Y direction, and (d) shows a hologram effect in which a “square” design and color appears when observed at a predetermined angle in the Y direction. ing. However, the number of hologram images that appear according to the observation angle and the method of changing the image (switching, movement, expansion, contraction, etc.) of the hologram image are not particularly limited, and there is no problem with a single hologram effect. On the other hand, the latent image line 6b (or the latent image pixel 6b) made of a light transmissive member in the hologram image region 6 is finely structured and therefore has high concealability (or latent image formation) and is reflected. The latent image line 6b (or the latent image pixel 6b) does not obstruct the hologram effect when the hologram effect is visually observed.

(Latent image effect)
FIG. 11 shows a case where the substrate 10 on which the hologram forming layer 3 in FIGS. 4 to 8 is attached is viewed in a “transmission state” from the back surface (the opposite surface on which the hologram 1a is attached to the substrate 10). is there. At this time, the hologram effect is not visible, but the latent image line 6b (or the latent image pixel 6b) in the latent image area described with reference to FIGS. 4, 6, 7, and 8 has a light reflecting member. Since it is transparent, light is transmitted through the substrate 10. On the other hand, the light reflection region 6c in the latent image background region has a light reflective member (for example, a metal material), and therefore does not transmit light through the base material 10. Accordingly, when viewed in a transmissive state, the latent image area and the latent image background area have different light transmission amounts and can be visually recognized as a density difference. As a result, the latent image line 6b (or the latent image pixel 6b) in the latent image area can be viewed in the transmitted state, so that the latent image information in the latent image area can be viewed. The latent image line 6b (or the latent image pixel 6b) is so fine that it is difficult to see one by one. However, by forming a plurality of lines (or pixels) in the latent image area, transmission is possible. The amount of light becomes prominent, and latent image information and the like can be easily viewed in the latent image area. At this time, the substrate 10 needs to be made of a material or material that transmits light. In addition, when viewing in the transmission state, the same latent image effect can be obtained even when viewing from the surface (hologram forming layer 3 side). Information in the latent image area may be selected as appropriate, such as letters, numbers, designs or marks. As shown in FIG. 5, a latent image background line (or latent image background pixel) made of a light transmissive member and a light reflection region are formed in the latent image background region, and only the light reflection region is formed in the latent image region. Even in the configuration, since the amount of transmitted light is different between the latent image background area and the latent image area when visually observed in the transmissive state, and can be visually recognized as a density difference, the latent image effect similar to that described above is obtained in the reverse configuration. can get.

  A hologram forming layer 3 which is a part of the hologram sheet 1 shown in FIG. FIG. 4 is an enlarged view of the hologram forming layer 3 of FIG. 2, and is also a schematic view visually observed in a transmission state. For example, the hologram forming layer 3 having a hologram image region 6 and a transparent region 6e around the hologram image region 6 is attached to a base material 10 such as paper. The hologram image area 6 has a latent image area and a latent image background area. As shown in the enlarged view, the latent image line 6b made of a light transmissive member is obliquely formed in the latent image area. It is formed in a lattice shape. The latent image line 6b is transparent or translucent and has a fine shape so that the latent image line 6b cannot be seen in the reflected state. For example, the line width W of the latent image line 6b is 0.10 mm, but a range of 0.05 mm to 0.15 mm is preferable. The line pitch P of the latent image line 6b is regularly arranged at 1.00 mm, but is preferably in the range of 0.60 mm to 2.00 mm. Further, a light reflection region 6a made of a light reflective member is formed in the background of the latent image line 6b. On the other hand, a light reflection area 6c made of a light reflective member is formed in the latent image background area. Further, the boundary line between the latent image region and the latent image background region (or the contour line “5” shown in FIG. 4) is the character “5” when the hologram forming layer 3 is viewed in the reflected state. The outline of the image may be emphasized and the latent image “5” may be easily visible. Therefore, when the character or mark is formed as the latent image, the boundary line is not formed. It is desirable. However, the line width W and the line pitch P of the latent image line 6b are not limited to the above-described numerical values, and may be appropriately selected.

  When the hologram forming layer 3 shown in FIG. 4 is viewed in a reflective state, a hologram effect appears due to the diffraction grating 5 including the light reflection region 6a and the light reflection region 6c. Specifically, it is the same as the hologram effect shown in FIG. 9 and FIG. However, the latent image line 6b is not visible in the reflected state. In FIG. 4, when the hologram forming layer 3 is viewed in a transmission state, the plurality of latent image lines 6 b in the latent image area can be viewed, and as a result, the character “5” can be viewed. Specifically, it is the same as the latent image effect shown in FIG. 11 described above. Therefore, the hologram forming layer 3 shown in FIG. 4 can be visually discriminated by two methods: a reflection state and a transmission state. Further, the latent image line 6b is not necessarily regular and continuous. In addition, it is desirable to use aluminum as the light reflecting member, and the hologram processing layer 4 serving as the light transmitting member to use a transparent or translucent thermoplastic resin, a thermosetting resin, or a combination thereof.

  In Examples 2 to 5, the configuration of the latent image line 6b in the hologram forming layer 3 attached to the substrate 10 of Example 1 is different, but the layer configuration of the hologram is the same. Therefore, description of the same structure is abbreviate | omitted and only a different structure is demonstrated.

  As shown in FIG. 5, a light reflection region 6a made of a light reflective member such as aluminum is formed in the latent image region. On the other hand, a latent image background line 6d made of a light transmissive member is formed in a lattice shape in an oblique direction in the latent image background region. For example, the line width W of the latent image background line 6d is 0.10 mm, but a range of 0.05 mm to 0.15 mm is preferable. The line pitch P of the latent image background line 6d is regularly arranged at 1.00 mm, but is preferably in the range of 0.60 mm to 2.00 mm. However, the line width W and the line pitch P of the latent image background line 6d are not limited to the above-mentioned numerical values, and may be appropriately selected. According to the configuration of the second embodiment, the same hologram effect and latent image effect as in the first embodiment can be obtained. However, the latent image effect of Example 1 is that the latent image line 6b having no light reflecting member and the light reflecting region 6a having the light reflecting member are formed in the latent image region, and the latent image background region is formed. Since the light reflecting region 6c having the light reflecting member is formed on the surface, the latent image region looks bright by transmitting light when viewed in a transmissive state, and the latent image background region looks dark because it does not transmit light. Therefore, the number “5” can be recognized. In the present invention, such a configuration is referred to as “positive system”. On the other hand, in the second embodiment, the latent image area and the latent image background area are formed in the opposite configurations to those of the first embodiment. Therefore, when viewed in the transmissive state, the latent image area is dark because it does not transmit light. The latent image background area looks bright because it transmits light, so that the number “5” can be recognized. In the present invention, such a configuration is called “negative system”. Therefore, the latent image forming method (or how it looks in the transmissive state) is different from that of the “positive method” in the first embodiment and the “negative method” in the second embodiment. In addition, Examples 3 to 5 are formed by a positive method.

  As shown in FIG. 6, the latent image area includes a latent image line 6b made of a light transmitting member and a light reflecting area 6a made of a light reflecting member. At this time, the latent image line 6b is formed as a line constituting a chromatic pattern. Precisely, the latent image line 6b of the chromatic pattern is formed by shrinking twice along the outermost contour line of the chromatic pattern with the line pitch P being equal pitch. On the other hand, a light reflection area 6c made of a light reflective member is formed in the latent image background area. For example, the line width W of the latent image line 6b is 0.10 mm, but a range of 0.05 mm to 0.15 mm is preferable. The line pitch P of the latent image line 6b is regularly arranged at 1.00 mm, but is preferably in the range of 0.60 mm to 2.00 mm. According to the configuration of the third embodiment, the same hologram effect and latent image effect as in the first embodiment can be obtained. However, the pattern, line pitch, or number of contractions of the chromatic pattern is not limited to this embodiment, and the pattern may be selected as appropriate, and the line pitch may be variable.

  As shown in FIG. 7, the latent image area includes a latent image line 6b made of a light transmissive member and a light reflective area 6a made of a light reflective member. At this time, the latent image line 6b is formed as a line constituting a chromatic pattern. Precisely, the latent image line 6b of the chromatic pattern is contracted five times along the outermost contour line of the chromatic pattern, with the central portion of the chromatic pattern as the base point, the line pitch P being equal pitch, and so on. Formed. On the other hand, a light reflection area 6c made of a light reflective member is formed in the latent image background area. For example, the line width W of the latent image line 6b is 0.10 mm, but a range of 0.05 mm to 0.15 mm is preferable. The line pitch P of the latent image line 6b is regularly arranged at 1.00 mm, but is preferably in the range of 0.60 mm to 2.00 mm. However, the pattern, line pitch, or number of contractions of the chromatic pattern is not limited to this embodiment, and the pattern may be selected as appropriate, and the line pitch may be variable.

  As shown in FIG. 8, the latent image area includes a latent image pixel 6b made of a light transmissive member and a light reflective area 6a made of a light reflective member. At this time, the latent image pixel 6b is formed in a diamond shape. On the other hand, a light reflection area 6c made of a light reflective member is formed in the latent image background area. For example, the length W of the diagonal line of the latent image pixel 6b is 0.15 mm, but a range of 0.10 mm to 0.20 mm is preferable. The pixel pitch P in the vertical and horizontal directions of the latent image pixels 6b is set to 1.00 mm and arranged in a matrix, but a range of 0.60 mm to 2.00 mm is preferable. When implemented in such a configuration, the same hologram effect and latent image effect as in Example 1 can be obtained. However, the shape, the pixel size, and the pixel pitch of the latent image pixel 6b are not limited to the present embodiment. As the latent image pixel 6b, a circle, a polygon, a character, a mark, or the like may be selected as appropriate, and the configuration of the latent image area and the latent image background area may be reversed as in the second embodiment. FIG. 5 shows a positive type configuration, but a negative type configuration may also be used.

  In the first to fifth embodiments, the configuration of the latent image area is described as “5”, “color pattern”, or “鳳凰”, but is not limited to this embodiment. Further, although the latent image line 6b and the latent image background line 6d are described as one continuous straight line, they are parting lines (or parting lines) such as double lines, triple lines, dotted lines, and broken lines. Any line shape such as a wavy line, a curved line or the like is included in the technical idea of the present invention, and the effect is the same. The latent image line 6b and the latent image background line 6d are described as lines in the present invention. However, the latent image line 6b and the latent image background line 6d may be replaced with lines as a collection of lines.

  Furthermore, when the hologram forming layer 3 is viewed in a reflected state, in order to form a latent image (or camouflage), the light reflecting member has high luminance and high gloss, and higher diffracted light is emitted. It is desirable to use the material obtained, for example, aluminum is suitable. Further, as the color of the base material 10 to which the hologram forming layer 3 is attached, the formation of a latent image is improved by using a base material of an intermediate color excluding white or the primary color or printing the intermediate color on the base material.

  In the examples, the base material is described as paper, but the same effect can be obtained by using a transparent plastic card, plastic film, glass, nonwoven fabric, cloth, or the like. FIGS. 4 to 8 for explaining the first to fifth embodiments show the latent image line, the latent image background line, or the latent image pixel in an enlarged manner for convenience, and the actual configuration is fine. . In addition, it is desirable that the latent image line, the latent image background line, or the latent image pixel is not visible in the reflection state as described above, but even if a part of the line or pixel is slightly visible in the reflection state, Information consisting of a latent image area that can be seen in a transparent state (for example, “5” in the first and second embodiments, “color pattern” in the third and fourth embodiments, “鳳凰” in the fifth embodiment) cannot be recognized (or And not noticed) and the visibility of the hologram effect is not significantly impaired, it is within the scope of the technical idea of the present invention.

It is a perspective view of the hologram sheet of the present invention. It is a schematic diagram when the hologram formation layer of this invention is stuck on the base material. It is a block diagram of the hologram sheet of this invention. It is the schematic diagram of one Example when the hologram formation layer in this invention is affixed on the base material, and the schematic diagram visually observed in the permeation | transmission state. It is the schematic diagram of one Example when the hologram formation layer in this invention is affixed on the base material, and the schematic diagram visually observed in the permeation | transmission state. It is the schematic diagram of one Example when the hologram formation layer in this invention is affixed on the base material, and the schematic diagram visually observed in the permeation | transmission state. It is the schematic diagram of one Example when the hologram formation layer in this invention is affixed on the base material, and the schematic diagram visually observed in the permeation | transmission state. It is the schematic diagram of one Example when the hologram formation layer in this invention is affixed on the base material, and the schematic diagram visually observed in the permeation | transmission state. It is the schematic which looks at the hologram sheet in this invention in a reflective state. It is the schematic which shows the hologram sheet latent image effect in this invention. It is the schematic which visually observes the hologram sheet in this invention in a permeation | transmission state.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Hologram sheet 2 Hologram sheet base material 2a Sheet base material 2b Peeling layer 3 Hologram formation layer 4 Hologram processing layer 5 Diffraction grating 5a Concavity and convexity 5b in close contact with light reflecting member Transparent concavity and convexity 6 made of light transmitting member 6 Hologram image region 6a 6c If the light-reflective member is used, the light-reflective region 6b, 6d Line or pixel 6e made of the light-transmissive member 7e Transparent region 7 made of the light-transmissive member 7 Mask layer 8 Adhesive layer 9 Positioning mark 10 Base material S Mark W line or Pixel width P Line or pixel pitch

Claims (12)

A hologram sheet having a hologram forming layer,
On the surface of the diffraction grating formed on one surface of the hologram forming layer, there is a hologram image region composed of a latent image region and a latent image background region,
The latent image area includes a latent image line or latent image pixel composed of a light transmissive member, and a light reflective area composed of a light reflective member formed on the background of the latent image line or latent image pixel. And
A hologram sheet characterized in that the latent image background region has a light reflecting region made of a light reflecting member. A hologram sheet having a hologram forming layer,
On the surface of the diffraction grating formed on one surface of the hologram forming layer, there is a hologram image region composed of a latent image region and a latent image background region,
The latent image area has a light reflection area made of a light reflective member,
The latent image background region includes a latent image background line or latent image background pixel made of a light transmissive member, and a light reflective region made of a light reflective member formed on the background of the latent image background line or latent image background pixel. A hologram sheet characterized by comprising: The hologram sheet according to claim 1 or 2, wherein the latent image line or the latent image background line is formed in a lattice shape. 4. The hologram sheet according to claim 1, wherein a line width of the latent image line or the latent image background line is 0.08 mm to 0.16 mm. In the latent image area, the latent image line is formed by shrinking n times (an integer equal to or larger than 1) at an equal pitch along the contour line. 4. The hologram sheet according to 4. 6. The hologram sheet according to claim 5, wherein the latent image line is based on a center portion of the contour line. The hologram sheet according to claim 1 or 2, wherein the latent image image pixels or the latent image background pixels are regularly formed in a matrix. 8. The shape of the latent image image pixel or the latent image background pixel is formed by any one of a circle, a polygon, a character, or a mark. Hologram sheet. The hologram sheet according to any one of claims 1 to 8, wherein the latent image area is formed with any one of a color pattern, a pattern, a pattern, a mark, and a character. 10. The hologram sheet according to claim 1, wherein a transparent region made of a light-transmitting member is formed around the hologram image region in the hologram forming layer. . A printing medium, wherein the hologram forming layer according to any one of claims 1 to 10 is bonded to a base material via an adhesive layer. 12. The print medium according to claim 11, wherein the print medium is a bank note.

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