• 专利附录
  • 专利说明
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    • 专利摘要:
    A method of making a first security document, the security document comprising a first periodic array of imaging elements applied to a first surface of a transparent substrate and extending in a first direction; and a first periodic array of visualizing elements deposited on an opposite surface of the substrate and extending in a second direction, wherein the first periodic array of visualizing elements superimposes the first periodic array of image elements such that between at least a first viewing angle and a second viewing angle, an optical variable effect can be observed. The method comprises the steps of: (a) assessing one or more features of moire bands that would be observed passing over the first periodic array of image elements while the security document is being moved relative to an observer between at least the first viewing angle and the second viewing angle; as a result of the first direction being different from the second direction; (b) limiting at least one dimension of the first periodic array of pixels and / or the first periodic array of visualizing elements to be smaller than the width of at least one of the Mair bands; and (c) causing the first periodic array of image elements and the first periodic array of visualizing elements bounded as shown for step (b) to be fabricated as part of the security document.
    公开号:AT519828A2
    申请号:T9480/2016
    申请日:2016-12-14
    公开日:2018-10-15
    发明作者:Jolic Karlo;Fairless Power Gary
    申请人:Ccl Secure Pty Ltd;
    IPC主号:
    专利说明:

    [1] The invention relates generally to security documents in which security elements are used as a counterfeit protection measure, and in particular to the production of such security documents.
    Background of the Invention [2] It is known to provide optically variable devices wherein an array of lenticular lenses (partially cylindrical lenses) focuses on an object plane that contains multiple sets of nested picture elements. Each set of picture elements (stripes) belongs to a certain picture, so that a different picture becomes visible when the viewing angle is changed. The effect caused by optically variable devices that contain multiple sets of interleaved picture elements is sometimes referred to as a “flipping image effect”. Two sets of nested picture elements are then required to generate a two-channel alternating picture.
    [3] Lenticular lenses can be applied to a substrate using a continuous lens embossing process, i.e. roll-to-roll. After this process is completed, rolls of the material that has embossed lenses are cut into rectangular sheets and sent to a banknote printer. The banknote printer then uses a sheet-fed printing process to apply lenticular images on the back of the lenticular lenses, which are to realize the alternating image effect. Eventually they will
    2/49 • ······ • · · · • · · · ·
    Printing sheets cut into individual banknotes at the output of the banknote printer.
    [4] With a banknote produced in this way, a specific lens-to-pressure skew is typically introduced. Since banknote sheets are very thin, the lenticular lenses used must be very small, which in turn means that the lens-to-printing skew introduced during production is far more critical than would be the case with conventional lenticular sheet printing.
    [5] The lens-to-printing skewness introduced during production can introduce a moiré strip into the alternating image effect. In a two-channel alternating image, under ideal conditions, only one of the two images is seen through the lenticular lens under a first viewing angle, and the other of the two images is seen under another
    Viewing angle seen through the lenticular lens. However, if there is skewness between the printed images and the lenticular lenses, a moiré pattern or streaks may result. In this case, there is no “hard change between the two images when the banknote is pivoted, but diagonal moiré bands roll over the viewed image and reveal one image in the moiré band and the other image outside the moiré band.
    [6] There is a need for a method of making a banknote or other security document that minimizes the effects of undesirable moiré stripes or patterns on the image or images projected by a security device that is an integral part of these security documents.
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    Summary of the Invention [7] One aspect of the present invention adjusts
    A method for producing a first security document, the security document comprising:
    a transparent substrate;
    a first periodic array of picture elements applied to a first surface of the substrate and extending in a first direction; and a first periodic array of visualizing elements applied to an opposite surface of the substrate and extending in a second direction, the first periodic array of visualizing elements overlaying the picture elements such that between at least a first viewing angle and a second Viewing angle an optically variable effect can be observed, the method comprising the steps:
    a. Determining one or more features of moiré bands whose passage over the image elements would or will be observed as the security document is moved relative to an observer between at least the first viewing angle and the second viewing angle as a result of the first direction of the second direction is different;
    b. Restricting at least one dimension of the first periodic arrangement of picture elements and / or the first periodic arrangement of visualizing elements in such a way,
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    that it is smaller than the width of at least one of the moiré bands; and
    c. Cause the first periodic array of picture elements and the first periodic array of visualizing elements, which are limited as shown for step (b), to be made as part of the security document.
    It is advantageous that as a result of such a restriction of the extent of the arrangement of picture elements and / or the arrangement of visualizing elements when the banknote or other security document is moved between different viewing angles, one or more moiré bands do not occur on the enlarged ones Picture elements comes.
    [9] In one or more embodiments of the invention, one or more features of moiré bands can be determined in one step by:
    Producing a calibration security document with a second periodic array of visualizing elements and a second periodic array of picture elements, the second periodic array of visualizing elements and the second periodic array of picture elements of the first periodic array of picture elements and the second periodic array of Image elements are the same, except that they extend over an area large enough to allow the movement of the
    Let the security document observe moiré bands that cross the picture elements, · and
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    Measure the one or more features of the observed moiré bands.
    [10] In such embodiments, a test production run is performed using an array of pixels large enough to ensure that when the security document is moved between the first and second viewing angles, one or more moiré bands pass over the enlarged pixels. Features of the moiré bands, such as moiré period, moiré half period, angular misalignment or skew of the moiré bands with respect to the direction in which the arrangement of picture elements extends and the width of the moiré band itself, can be analyzed to design an arrangement of picture elements that has at least one dimension that is smaller than the width of at least one of the moiré bands.
    [11] In other embodiments of the invention, one or more features of the moiré bands can be determined in one step by:
    Determining a maximum skew between the first periodic arrangement of image elements and the first periodic arrangement of visualizing elements, which can be introduced by one or more production steps during the production of the first security document; and
    Deriving the one or more features of moiré bands from the maximum skew.
    For example, the maximum lens-to-pressure skew can be determined by using the roll-to-roll skew
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    Lens embossing, sheet skewing, skewing when moving into a sheetfed printer and / or the skewness introduced by a security document printer are offset by pressure distortion, the maximum permissible size of one or more dimensions of the arrangement of picture elements then being derived from this total skewness.
    [13] In one or more embodiments, the
    Moiré band features one or more of the following: the moiré period or some other value representative of the width of the narrowest moiré bands; and the moiré angle, which describes the angular offset of the moiré bands with respect to the first direction.
    [14] In one or more embodiments, the periodic arrangement of visualizing elements makes a first image channel visible under the first viewing angle and a second image channel visible under the second viewing angle; and the or each periodic array of picture elements comprises a first group of picture elements that form a first image that is visible in the first image channel.
    [15] The or each periodic array of picture elements may further comprise a second group of picture elements forming a second image that is visible in the second image channel.
    [16] In one or more embodiments, the first periodic arrangement of visualizing elements makes a third image channel visible from a third viewing angle; and the or each periodic array of picture elements comprises a third group of picture elements
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    form a third image that is visible in the third image channel.
    [17] In one or more embodiments, the visualizing elements are lens elements that cause the image elements to be enlarged.
    [18] In one or more embodiments, the visualizing elements are lines.
    Definitions
    Security document or trademark [19] As used herein, the term security document and trademark includes all types of documents and printed matter of value and identity documents, including but not limited to the following:
    Objects of money such as banknotes and coins, credit cards, checks, passports, identity cards, securities and share certificates, driver's licenses, title deeds, travel documents such as flight and train tickets, entrance tickets and tickets, birth, death and marriage certificates as well as study books.
    [20] The invention is particularly, but not exclusively, applicable to security documents or tokens, such as banknotes or identification documents, such as identity cards or passports, which are formed from a substrate to which one or more printing layers are applied. The diffraction gratings and the optically variable devices described here can also be used in other products, such as packaging.
    Security device or feature
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    [21] As used here, the term includes
    Security device or feature any of a large number of security devices, elements or features designed to protect the security document or security mark from forgery, duplication, alteration or tampering. Security devices or features may be in or on the substrate of the
    Security document or in or on one or more of the layers applied to the base substrate and can take many different forms, such as security threads, which are in layers of the
    Security document are embedded; Security printing inks, such as fluorescent, luminescent and phosphorescent printing inks, metallic printing inks, iridescent printing inks, photochromic, thermochromic, hydrochromic or piezochromic
    Printing inks; printed and embossed features, including relief structures; Interference layers;
    Liquid crystal devices; Lenses and lenticular structures; optically variable devices (OVDs) such as diffractive devices, including diffraction gratings, holograms and diffractive optical elements (DOEs).
    Substrate [22] As used herein, the term substrate refers to the base material from which the security document or security tag is made. The base material can be paper or other fiber material such as cellulose; a plastic or polymeric material including, but not limited to, polypropylene (PP), polyethylene (PE), polycarbonate (PC), polyvinyl chloride (PVC), polyethylene terephthalate (PET), biaxially oriented polypropylene (BOPP), or a composite material
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    two or more materials, such as a laminate of paper and at least one plastic, or of two or more polymer materials.
    Transparent windows and half-windows [23] As used here, the term window refers to a transparent or translucent area in the security document, compared to the essentially opaque area that is printed on. The window can be fully transparent, so that it allows an essentially uninfluenced light passage, or it can be partially transparent or translucent, so that it allows the light passage partially, but without allowing objects to be clearly visible through the window surface.
    [24] In the case of a polymer security document that has at least one layer of a transparent polymer material and one or more opacifying layers that have been applied to at least one side of a transparent polymeric substrate, a window surface can be formed by in the area that the window surface forms, at least one opacifying layer was omitted. If opacifying layers are applied to both sides of a transparent substrate, a fully transparent window can be formed by omitting the opacifying layers on both sides of the transparent substrate in the window area.
    [25] In the case of a polymeric security document which has opacifying layers on both sides, a partially transparent or translucent surface, hereinafter referred to as “half window,” can be formed by using the
    10/49 ·· ·· »* ·«> · · • · «• ·« «opacifying layers only on one side of the
    Security document in the window area are omitted, so that the "half window is not fully transparent, but allows the passage of some light, but without allowing objects to be clearly visible through the half window.
    [26] Alternatively, it is possible to form the substrates from a substantially opaque material, such as paper or fiber material, with an aperture of transparent
    Plastic material that is embedded in a cutout or recess in the paper or fiber substrate to form a transparent window or a translucent half-window surface.
    Opacifying layers [27] One or more opacifying layers can be applied to a transparent substrate in order to increase the opacity of the security document. An opacifying layer is such that L T <Lo, where Lo is the amount of light falling on the document and L T is the amount of light falling through the document. An opacifying layer can comprise any one or more of a wide variety of opacifying coatings. The opacifying coatings can be, for example, a pigment such as
    Contain titanium dioxide, which is dispersed in a binder or carrier of the heat-activated cross-linked polymer material. Alternatively, a substrate made of transparent plastic material could be arranged between opacifying layers of paper or other partially or essentially opaque material, to which characters can subsequently be printed or otherwise applied.
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    Brief Description of the Drawing [28] Hereinafter, embodiments of the invention will be described with reference to the accompanying drawing. It is understood that the embodiments are for illustration only and the invention is not limited by this illustration. In the drawing [29] Figure 1 is a side view of a partial section
    Embodiment of a safety device, the one
    Lenticular lens comprising a substrate and imaging elements for use in a security document;
    [30] Figure 2 is a top view of selected ones
    Lens elements and picture elements of the security device shown in FIG. 1;
    [31] FIG. 3 shows two groups of picture elements that form a separate image that can be observed when the security device shown in FIG. 1 is viewed from separate viewing angles;
    [32] FIG. 4 is a schematic illustration of a first one
    Device for use in the manufacture of a
    Security document that shown in Figure 1
    Security device comprises, and in particular comprises a lens embossing device;
    [33] FIG. 5 is a partial section of a side view of the partially produced security document, produced by means of the device from FIG. 4;
    [34] FIG. 6 is a top view of a foiling process carried out during the production of a security document
    12/49 ·· ······ · · ·· • · · · · ·· ·· · • · · · · · ·· · »·· ·· ··· ·· * ··· · · is comprised of the security device shown in Figure 1;
    [35] FIG. 7 is a schematic illustration of a
    Sheet printer during the manufacture of a
    Security document that shown in Figure 1
    Security device includes;
    [36] Figures 8 to 10 are graphical representations of
    Moire patterns or stripes across the enlarged
    Image elements of the safety device shown in FIG. 1 can go away if they are observed by a user from different viewing angles;
    [37] FIGS. 11 and 12 each show different images which are formed from groups of image elements and are nested in the security device of FIG. 1;
    [38] FIG. 13 is a graphical representation of a moiré pattern or streak passing over the magnified picture elements that can be observed by a user;
    FIG. 14 is a graphical representation of features of moiré tapes used in accordance with one or more embodiments of the invention to limit the size of the picture elements of the security device shown in FIG. 1;
    FIG. 15 is a graphical representation of the application of these restrictions to one or more dimensions of the imaging elements of the safety device of FIG. 1;
    [41] FIG. 16 is a schematic illustration of a
    Safety device with a periodic arrangement of
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    Lens elements and 5 nested images, each consisting of a series of image elements; and [42] Figure 17 is a sectional view of another
    An embodiment of a security device comprising printed lines, substrate and picture elements for use in a security document.
    Detailed Description [43] In Figure 1, what is now referred to is one
    Embodiment of a security device 10 shown that is part of a banknote or other
    Security document is. The security device 10 comprises a periodic arrangement 12 of lens elements 14. Furthermore, the device 10 comprises a substrate 16 which has an upper surface 18 and a lower surface 20. The array 12 of lens elements 14 is applied to the upper surface 18, while the lower surface 20 is one
    Object level, which is a periodic arrangement 22 of
    Carries picture elements. In this case, the periodic arrangement 22 of picture elements comprises a first group of elements 24, which form a first picture, interleaved with a second group of picture elements 26, which form a second picture.
    [44] The periodic array 12 of lens elements 14 and the periodic array 22 of picture elements form a lenticular imaging device in which the lens elements are lenticular lenses (partially cylindrical lenses) which, at least in part, focus on an object plane of several sets of nested picture elements , Although the lenticular lenses are shown in FIG. 1 as somewhat blurred, as described in WO 2010 099 571, in
    14/49 • · · • · · • * ·
    In this context, sharp imaging lenses can also be used. In the cross-sectional view of FIG. 1, for the sake of clarity, the group of picture elements 24 is shown slightly offset from the group of picture elements 26.
    [45] The left edges of adjacent picture elements 24 of the first group of picture elements are aligned with the left edges of lens elements 14, through which the picture elements 24 are to be viewed. The left edges of the picture elements of the second group of picture elements are aligned with the optical axes belonging to the lens elements 14. The picture elements 24 and 26 are interleaved in the object plane 20 to form a first and a second channel of an alternating picture.
    [46] In FIG. 2, the lens elements 14 have a focus area 28 such that each of the lens elements 14 causes an enlargement of a section or sections of one or more picture elements within this focus area. The exact positioning of the focus area 28 in relation to the picture elements 24, 26 in the object plane 20 will depend on the viewing angle of a user. For example, at the viewing angle shown in Figure 2, the focus area 28 overlaps one of the picture elements 24 almost completely and comprises only a very small portion of an imaging element 26. In this case, the picture elements 24 of the first group of picture elements should be visible around the first Display channel of the alternating image, while the picture elements 26 of the second group should not be visible. Accordingly, the arrangement of lens elements and the arrangement 22 of picture elements, when viewed from the viewing angle shown in Figure 2, produce a perceptible intensity
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    "· ·· ···· · • ·· • · • · • • · ftft • · • · • • • • • • · • · • • • • • • • ft · * · • • • · • • ft
    of the picture elements 24, while they produce only a reduced intensity 32 for the picture elements 26.
    [47] As shown in Figure 3, the overall impression that the
    Viewer when viewed under that shown in Figure 2
    Viewing angle wins that of a first image 40, which corresponds to a foreground area 42 in the form of the character “5, which is generated by the first group of image elements 24. Due to the existing crosstalk from the second group of picture elements 26 (i.e. the picture 32 reduced
    Intensity, which depends on the slight overlap of the
    Focus area 28 is generated with the picture elements 26)
    A shadow 44 of the character “A can be seen in the background.
    [48] If the device is tilted, the character "A moves further into the foreground, since a larger portion of the width of the focus area 28 overlaps the picture elements 26, and the character" 5 gradually fades into the background until the two characters "5 and "A become indistinguishable. With further tilting, the character "A 46 becomes a more prominent part of an image 48, with crosstalk 50 from the picture elements 24 of the character" 5, which forms the background 52.
    [49] An exemplary facility 80 for part of a
    The production line for producing a security document, which has the security device 10 shown in FIG. 1, is shown in FIG. A continuous web 82 of translucent or transparent material, such as polypropylene or PET, is at a first processing station 84, the one
    Roll assembly includes subjected to an adhesion promoting process. Suitable adhesion-promoting processes are flame treatment, treatment with corona discharge, treatment with plasma or the like.
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    · " ·· • • 99 9 • · • · % 9 • · 9 • • • · • • • 9 " • • · • • • 99 • · • 9 • · 9 •
    [50] At a second processing station 88, the one
    Includes roller assembly, an adhesion promoting layer 86 is applied. A suitable adhesion-promoting layer is one that is specifically designed to promote the adhesion of UV-curable coatings to polymeric surfaces. The adhesion promoting layer can comprise a UV-curable layer, a solvent-based layer, a water-based layer or any combination thereof. The adhesion-promoting layer preferably comprises a primer layer which contains a polyethylene iodine. The undercoat layer may also contain a crosslinking agent, for example a multifunctional isocyanate.
    At a third processing station 90, which likewise comprises a roller arrangement, the radiation-sensitive coating is applied to the dried surface of the adhesion-promoting layer 86. The radiation-sensitive coating can be applied by flexographic printing, gravure printing or a screen printing process.
    The radiation-sensitive coating is only applied to the security element area 92 on a first surface 94, where a lens structure 96, comprising a periodic arrangement of lens elements that are the same as the elements 14 shown in FIG. 1, is to be arranged. The security element area 92 may take the form of a strip, a separate patch in the form of a simple geometric figure, or in the form of a more complex graphic design.
    [53] While the radiation-sensitive coating is still liquid, it is processed at a fourth processing station 98 in order to close the lens elements shown in FIG
    17/49 ·· ······ · · ·· • · · · ··· ··· · ···· · · ··· In one embodiment, the processing station comprises an embossing roller 100 for embossing one
    Security element structure, such as the lens structure 96, in a radiation-sensitive coating in the form of a UV-curable printing ink. The cylindrical embossing surface 102 has surface relief configurations which correspond to the shape of the security element structure 96 to be molded. In one embodiment, the surface relief configurations can align the arrangement of lens elements in the machine direction, transverse to the machine direction, or in multiple directions at an angle to the machine direction. Although the device can shape 80 microlenses in a wide variety of shapes, the lens elements in the embodiments described herein form an array of lenticular lenses.
    [54] The cylindrical embossing surface 102 of the embossing roller 100 can have a repeating pattern of surface relief configurations or the relief structure configurations can be spatially restricted to individual shapes that match the shape of the
    Correspond to security element area 92 on the substrate 82. The embossing roller 100 may have the surface relief formations that have been formed by means of a diamond stylus with a suitable cross section, or that
    Surface relief configurations can be provided by at least one metal insert that is provided on the embossing roller 100. At least one metal insert can be attached using adhesive tape, magnetic tape, clips or other suitable fastening techniques.
    At the processing station 98, the UV-curable printing ink on the substrate is narrowed by a UV roller 104 with the cylindrical embossing surface 102 of the embossing roller 100
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    Contacted so that the liquid UV-curable printing ink flows into the surface relief formations of the cylindrical embossing surface 102. At this stage, the UV curable ink is exposed to the UV radiation that is passed through the substrate layer 82. The UV radiation can be passed through the surface of the UV roller 104. The UV roller 104 could preferably have built-in UV lamps or a roller surface that is UV-transparent at least in some areas.
    [56] If the security element structure 96 is on the
    Document substrate 82 is applied, one or more additional layer (s) is or are applied to a downstream processing station which has further roller arrangements 106 and 108. The additional layers can be clear or pigmented coatings and can be applied as a partial coating, as a coherent coating or an adaptation of both. In a preferred method, the additional layers are opacifying layers that are applied to one or both surfaces of substrate 82, except for the area of the security element structure.
    [57] FIG. 5 shows a semi-finished security document, shaped with an embossed security element structure 96 in the form of a lens structure 96, which has an arrangement of microlenses. This security document comprises a transparent substrate made of polymer material, preferably biaxially stretched polypropylene (BOPP), which has a first surface 94 and a second surface 110. Opacifying layers 112, 114 and 116 are applied to the first surface 94, with the exception of a window area 118 where the
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    Security element structure 96 is applied to the first surface 94.
    [58] - On the second surface 110, except one
    Window area 124, opacifying layers 120 and 122 are applied. The window surface 124 and the window surface 118 on the first surface 94 are essentially congruent.
    The window area 124 shown in Figure 5 is smaller than the window area 118, although it is understood that in other embodiments the relative sizes and locations of the
    Window areas 118 and 124 can be changed. A print layer 126 can be applied to the second surface 110, on the opposite side of the substrate, in the window area 124. The print layer 126 can form an image or images that are visible through the lens structure 96. For example, the printing layer 126 can comprise the arrangement 22 of picture elements shown in FIG. 1.
    [59] Now again with reference to FIG. 2: It can be seen that the periodic arrangement of picture elements 14 extends in a first direction, which is indicated by the arrow labeled 54, while the arrangement of picture elements 14 and 16 extends in a second direction, which is indicated by the arrow denoted by 56. Ideally, these two directions are the same, and the “detection of the arrangement of picture elements with the lens elements takes place completely. The process of making
    However, security documents introduce skewness between the lens elements and the image elements so that the first and second directions 54 and 56 differ from one another.
    [60] The lens-to-pressure skew in the finished
    Security document is the result of an inclination or
    20/49 of a skew in different stages of the
    Manufacturing process. The device 80 shown in FIG. 4 introduces an oblique roll-to-roll into the lens embossing, namely the portion of the obliqueness that is embossed during the continuous process, ie roll-to-roll
    Lens elements are introduced into the lens elements. This is usually the smallest contribution to the final lens-to-print skew. The lens elements are applied to the security substrate 82 with a slight skew in relation to the sheet reference marks 140 to 146 shown in FIG. 6. The reference marks 140 to 146 are then used to cut the roll into sheets for further processing. This skew can typically be up to +/- 0.2 mm above the width of the web 148 of the security substrate 82 processed by the device 80. With a typical web width of around 800 mm, the skew of the lens embossing is typically roll-to-roll
    0.2 / 800 = 0.00025 rad, however, it should be understood that this is only a non-limiting example.
    [61] A further contribution to the total lens-to-print skew in the finished security document is provided by the curved run. Arc skew is introduced because the sheets cut from the roll and processed by the device 80 are not exactly rectangular. The sheets are cut according to the sheet reference marks 140 to 146 which were applied to the web 148 during the aforementioned continuous lens embossing process, that is to say roll-to-roll. This skew 150 can typically be +/- 0.5 mm over the width of the web 148. With a usual web width of around 800 mm, the curved run can therefore
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    0.5 / 800 = 0.000625 rad, but again it is understood that this is only a non-limiting example.
    [62] Sheets cut from the security substrate web are then fed to an offset printing machine 160, in FIG. 7. The offset printing machine 160 comprises two blanket cylinders (or printing cylinders) 162, 164 which rotate in the direction indicated by the arrows and between which the sheets are fed in order to obtain multicolor prints. The blanket cylinders 162, 164 take different
    Ink samples in their respective colors from the
    Plate plate cylinders 166 and 168 (four on each side), which are distributed over part of the circumference of the blanket cylinders 162, 164, and bring them together. These printing plate cylinders 166 and 168, each carrying a corresponding printing plate, are themselves inked by corresponding inking units 170 and 172, respectively. The two inking unit groups 170 and 172 are accommodated in two ink carriages 174, 176 which can be moved toward or away from the centrally arranged printing plate cylinders 166, 168 and the blanket cylinders 162, 164. The printing plate cylinder 164 is equipped with a plurality of engraved printing plates which are evenly distributed. The ink collecting cylinder 166 has an elastic surface with the same diameter as the plate cylinder 164 and in this example, like the printing cylinder 162, is equipped with three rubber blankets. Selective ink cylinders 168 are mounted along the circumference of and in contact with the ink collecting cylinder 166, each of which is inked by means of its own inking unit 170.
    [63] The sheets are fed from a feed station 178, which is adjacent to the print group (i.e., to the right in Figure 7)
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    Feed table 180 and then a sequence of transfer cylinders 182, 184 and 186 (in this example three cylinders), which are upstream of the blanket cylinders 162, 164, supplied.
    In the example of FIG. 7, the sheets are transferred to the surface of the blanket cylinder 164, where the front edge of each sheet is held by suitable gripping means, which are located in cylinder pits between the individual segments of the blanket cylinder. Thus, each sheet is transported by means of the blanket cylinder 164 to the printing nip between the blanket cylinders 162 and 164, where simultaneous printing takes place. After double-sided printing, the printed sheets are transferred to a chain gripper system 188 for delivery to one, as is generally known
    Deliver sheet delivery station (not shown) with multiple stacks of delivery.
    [65] The printing ink applied by the offset printing machine 160 results in an applied printing layer 126 in the window area 124 on the second surface 110, on the side of the substrate opposite the first surface 94 (FIG. 5). The printing layer 126 forms the periodic arrangement of picture elements which are visible through the periodic arrangement of lens elements 96.
    [66] Contributions to lens-to-print skewness in the finished
    Security documents are provided both by feeding the sheets into the offset printing machine 160 and by printing distortion when the printing ink is applied to the security substrate by the device 160.
    [67] The one caused by offset press 160
    Entry skew is the proportion of skewness that is introduced
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    while the sheet is fed into the offset printing machine 160. This is because a sheet is usually not inserted into the press at an absolutely right angle. This skew can typically be up to +/- 0.3 mm across the width of the sheet. With a typical sheet width of around 800 mm, the run-in skew is
    0.3 / 800 = 0.000375 rad, however, it should be understood that this is only a non-limiting example.
    [68] Finally, skewness is due to pressure distortion
    Proportion of skewness that is introduced by offset printing machine 160 when printing on the sheet. When printing the array of image elements, the sheet is between a printing surface, usually the aforementioned blankets with ink in the image areas, and another surface (usually the aforementioned printing roller or other blanket that simultaneously prints ink on an opposite side of the sheet) crushed. This leads to an uneven distribution of tensions over the arch and a corresponding uneven distribution of additional skewness over the arch. With a typical sheet width of around 800 mm, this skew can typically be up to +/- 0.6 mm above the width of the sheet.
    Accordingly, the skew due to pressure distortion, as a non-limiting example, can be up to 0.6 / 800 or 0.00075 rad.
    [69] Adding up the above-mentioned maximum skewness of the roll-to-roll lens embossing, the skewed run, the skewed run-in and the skew due to pressure distortion results overall
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    0.00025 + 0.000625 + 0.000375 + 0.00075 = 0.002 rad as the maximum lens-to-pressure skew.
    FIG. 8 shows an optical effect 200 which is produced in an idealized security device in which a first periodic arrangement of picture elements, which extends in a first direction, is applied to one side of a transparent security substrate, while a periodic arrangement of Lens elements that extend in the same direction on the opposite side of the
    Security substrate is applied so that it overlaps the first periodic arrangement of picture elements and causes it to be enlarged. In this case, there is no skew between the lens elements and the picture elements.
    [71] A more realistic optical effect 202 is shown in FIG. 9. When producing a security element, a slight lens-to-pressure skew is inevitably introduced, which leads to a moiré stripe being visible in an alternating image. Optical effect 202 shows a simple moiré streak caused by the crossing of two sets of parallel lines, in this case the first periodic arrangement of picture elements, which is skewed or oblique with respect to the periodic arrangement of lens elements, at an oblique angle 204 FIG. 9 shows the moiré strips or the moiré pattern shown comprises a periodic pattern of alternating light and dark moiré bands 206 to 212. The moiré strip has one
    Moire period 214, which indicates the period with which the moiré band is repeated, and a moiré half period 216 can also be derived from this moiré period 214.
    25/49
    [72] Under certain circumstances, the moiré strip shows itself as a “rolling belt, ie. H. when the banknote is flipped, the user sees a gradual transition from one image to another (in the case of changing lenticular images) as the moiré stripe moves across the image area. The greater the degree of skewness, the smaller the period of the moiré stripe and the slower the moiré stripes move when the banknote is tilted. This is shown in Figure 10, which shows the optical effect 218 that is produced when the helix angle * 220 between the parallel picture elements and the parallel lens elements is larger from the helix angle 204 shown in Figure 9 to the helix angle 220 shown in Figure 10. It can be seen from FIG. 10 that increasing the oblique angle results in moiré bands 222 that have a smaller width and a shorter period and half period than the corresponding moiré bands, period and half period that are shown in FIG. 9.
    [73] FIGS. 11 and 12 each show two individual images of the “alternating image individual images 230 and 232 of an alternating image for use, in this exemplary embodiment, in the security device shown in FIG. 1, which is part of the security document that relates to those with reference to FIG Figures 4 to 7 described manner is made. As explained with reference to FIGS. 1 and 2, each of these images consists of a series of parallel picture elements which are nested and printed on one side of the substrate 16 - shown in FIG. A lenticular lens is located on the opposite side of the substrate. Image 230 is seen from a first viewing angle, whereas image 232 is viewed from a different viewing angle
    26/49
    is seen. If there is a skew between the arrangement of
    Introduced image elements and the arrangement of lens elements, moiré stripes can occur, such as the moiré bands 234 and 236, which are generated by the security device in the optical effect 238 shown in FIG. Instead of a “hard alternation between the two images 230 and 232 shown in FIGS. 11 and 12, this optical effect, when the device is tilted, results in a diagonal moireband which rolls over the image under consideration and an image in the Moireband 324 and the other image that is visible outside of this Moireband reveals.
    [74] It is desirable for a particular
    Viewing angle to show only one image (except for a transition viewing angle where both images can be viewed as very weak images at the same time). Ideally, regardless of the viewing angle, the optical effect produced by the security elements should not have any moiré stripes. As already mentioned, however, a skew is inevitably introduced during the production process of security documents, and the greater the skew between the images and the lenses, the narrower or thinner the moiré bands.
    [75] To address this issue of the Moire Strip, which is beyond the
    As a security element, the security document can be prepared by performing a series of steps that limit the design area or the extent of the arrangement of picture elements and / or the arrangement of lens elements or other visualizing elements. First, these steps include determining one or more features or moiré bands that are going away
    27/49 about the picture elements, while the security document is being moved relative to an observer between at least a first viewing angle and a second viewing angle, would or will be observed as a result of the visualizing elements and the picture elements moving in different directions extend.
    Second, at least one of the dimensions, such as the height or width, of the first periodic arrangement of picture elements and / or the periodic arrangement of visualizing elements is restricted such that it is smaller than the width of at least one of the moiré bands. To minimize the problem of the moiré stripes crossing the security element, it is preferred that all dimensions of the first periodic array of picture elements and / or the periodic array of visualizing elements be limited to be less than the width of at least one and preferably the narrowest of the moiré bands.
    [77] Finally, the arrangement of picture elements and the arrangement of lens elements, which are limited as shown above, are produced as part of the security document.
    In other words, once one or more of the
    Features of the moiré bands are / are known, either from a test run before production or from an estimate of the maximum skew that is likely to be introduced during the production of the security document, the moiré bandwidth of the moiré bands that are introduced by such a skew can be derived , As soon as the smallest moiré bandwidth is known, at least one dimension and preferably the maximum design area or the maximum extent of the arrangement can
    28/49 ·· ·· ·· ♦ · · · · · · · · · · · · · · · · · · · · · · · · of picture elements and / or the arrangement of lenses or other visualizing elements smaller than these smallest bandwidth can be used so that in the finished
    Security document for a viewer will no longer have moiré tapes.
    [79] It is understood that the design area of the subject
    Security image coincides with the area of the first picture elements when they are nested with the second picture elements.
    [80] According to a first embodiment, the one or more features of moiré bands can be determined, namely by producing a calibration security document with a second periodic arrangement of visualizing elements and a second periodic arrangement of picture elements, the second periodic arrangement of visible making elements and the second periodic array of picture elements are the same as the first periodic array of picture elements and the second periodic array of picture elements, except that they extend over an area large enough to allow movement of the security document Have moire bands observed that go beyond the picture elements; and measuring the one or more features of the observed
    Moirebänder.
    [81] In other words, no attempt is made to initially narrow the display area or one or more dimensions of the security image. In one or more embodiments, a periodic arrangement of picture elements is produced which is identical in area to the periodic arrangement of lens elements or the same
    29/49
    • 9 ·· ···· • * ·· • • • * · • · • · • · • · • · · • • • · • • • · · • • ·· · • • • · · • • •
    Display area as the periodic arrangement of lens elements occupies and is overlaid by it. On the basis of this calibration security document, one or more features of moiré bands, the passage of which is observed via the enlarged picture elements, are then measured.
    [82] In one embodiment, a representative
    Pattern of a lenticular image alternating between two different representations printed on the back of representative substrates with lenses using a simple design, such as a rectangle, that spans the entire area of the lenses and is designed to be “on and off” go if the security document produced, such as a banknote, is tipped over. After going through the manufacturing process described with reference to FIGS. 4 to 7, the finished samples are analyzed to determine the maximum design area or the maximum extent of at least one dimension of the two-channel alternating image as the area corresponding to the narrowest moiré strip, in this case of the width of at least one, preferably the narrowest, dark band in the moiré band is spanned. The narrowest moiré band has a repetition period and is inclined or inclined at a certain angle. The maximum design area of the two-channel alternating image should span half of the smallest moiré period and be inclined at a certain oblique angle. An example using this approach is described below.
    [83] As can be seen in Figure 14, the
    A rectangular area 260 of such a size is printed on the side of the security substrate opposite the lens elements,
    30/49
    4 · * · • * · • • · • ·· • • • • • • • • • • • • • 4 • · • • • • · • •
    that the surface - in this case the surface has a size of mm x 42 mm - and the superimposed arrangement of
    Lens elements consisting of parallel lines in one
    Pitch, which is equal to the pitch of the arrangement of
    Is lens elements, are coextensive. At the time of printing, there is a skew between the arrangement of the picture elements and the arrangement of the lens elements, which creates moiré bands (however, if the skewness were small enough, no moiré bands would be visible). In FIG. 14 the period of the moiré stripes is indicated by the double arrow 262 and the half period by the double arrow 264. The skew angle of the moiré strips is indicated by the double arrow 266. An exemplary method of determining the maximum design area for the security image is to select a square that will fit in half a period of the moiré pattern. This can be achieved by first selecting a square that is in full
    Moire period fits, such as a large square, labeled 268 in Figure 14.
    [84] This large square can then be divided into four smaller squares of the same size, such as the square labeled 270. These smaller squares should then fit in exactly half of a period of the moiré pattern.
    [85] It is understood that the smaller the side length of the square that is chosen to determine the maximum security image design area, the cleaner the change (“flip”), since fewer moire stripes will be visible in the alternate image design. Conversely, with increasing
    Side length of the square more moiré stripes in alternating image design visible. If the design area of the alternating image is set in such a way that it corresponds to the size of 270 in FIG
    31/49
    corresponds to the designated square, the visibility of the moiré strips in the final design will be greatly reduced.
    [86] The intensity profile of the moiré stripes is sinusoidal perpendicular to their axes. If the dark part of the stripe is centered in the middle of the blue square, those are
    Intensity values within the area of the square 272 are strongly positive (dark) on average, which means that the visibility of the moiré strips will be very low. This is desirable in order to obtain a clean two-channel alternating picture.
    [87] The geometric relationship between the side length of the large square 268 and the small square 272 as well as the angle and the period of the moiré strips result from the equations below, when applied to the geometric arrangement shown in FIG. 14.
    T = a + b =
    Sx sin θ -I- Sx cos θ a
    Sln0 = sb cos Θ = kJ [88] In the example shown in FIG. 14, the moiré period was measured on the basis of the printed sample and given as approximately 16 mm, while the moiré angle was also measured and stated as approximately 21 degrees. Using the aforementioned equations, the side length of the larger square is 268
    16 / (sin (21) + cos (21)) = 12 mm calculated. In other words, to minimize the visibility of moiré strips in the final design of the security document would be
    32/49
    Design area of the arrangement of picture elements a square, not larger than 0.5 x 12 = 6 mm x 6 mm.
    Another approach to determining one or more features or moiré bands is to determine the maximum skew between the first periodic arrangement of image elements and a periodic arrangement of lens elements in one or more production steps during the production of the first security document and then from the maximum skewness to derive one of the several features or moiré bands.
    [90] It is understood that the one or more features or moiré bands may include the moiré period or another value that is representative of the width of the narrowest moiré bands, and the moiré angle that describes the angular offset of the moiré bands with respect to the first direction ,
    [91] Accordingly, the maximum lens-to-pressure skew can be determined, and then this information along with the frequency of the array of lens elements and the frequency of the array of picture elements contained therein
    Embodiment forming the two-channel alternating image can be used to calculate the corresponding period and the angle of the moiré strips. The maximum design area of the lenticular image alternating between two different representations should again correspond to half a moiré period and should be inclined at a calculated angle. An exemplary contribution to skewness that is introduced through a series of manufacturing steps has been described with reference to FIGS. 4 to 7. In this example
    33/49 was the total lens-to-pressure skew through this
    Processes were introduced, maximum 0.002 rad.
    [92] In one embodiment, the lens period may be 157.5
    Lens elements per cm (400 per inch) and the grid size of the alternating image can be 157.5 lines per cm (400 per inch).
    [93] These values can then be used in the following equation (Source: Isaac Amidror, The Theory of the Moire Phenomenon (2000), Vol. 15 Computational Imaging and Vision, ISBN 0-79235950-X) to calculate the angle of the to calculate the resulting moires:
    T b sin α Γ - T r sin a b a m = arc tan, T b cos α Γ - T r cos a b where T b = T r = 400, a r = 0.002 rad, a b = 0 rad
    This results in a moiré angle = a m = 90.057 degrees (relative to the vertical).
    To calculate the period of the resulting moire, the above values can then be used in the following equation (source: Isaac Amidror, The Theory of the Moire Phenomenon):
    where T b = T r = 400, a r = 0.002 rad, a b = 0 rad, a m = 90.057 degrees. This results in a moiré period = T m = 32 mm.
    34/49 [94] The side length of the maximum design area for the
    Security pixel (the smaller one shown in Figure 14
    Square 270/272 accordingly) can then be calculated using the previous calculations. The calculated side lengths of the smaller square 270/272 and the larger square 268 are then determined as follows:
    Side length of the larger square 266 = 32 / (sin (90-90,057) + cos (90-90,057)) = 32 mm
    Side length of the smaller square 268 = 0.5 * 32 = 16 mm = max. Design size with minimal visibility of the stripes.
    Using exemplary samples, the applicant has found that typical maximum design areas for a two-channel alternating image with a banknote substrate sheet
    157.5 lenses per cm (400 LPI) 10 mm x 10 mm. By limiting the design of the two-channel alternating image so that it fits into this area, clean image-changing effects of two-channel alternating images can be realized consistently above the sheet or, in other words, at any location on the banknote. The one shown in Figures 1 and 2
    Security device 10 comprises a periodic arrangement 12 of lens elements 14, which form a lenticular lens for viewing a first image from a first viewing angle and a second image from a second viewing angle. In this embodiment, the groups of picture elements 24 comprise a first picture channel and the group of picture elements 26 forms a second picture channel. The first image channel is seen via the lenticular lens at the first viewing angle, and the second image channel is viewed via
    35/49
    the lenticular lens seen from the second viewing angle.
    [96] In other embodiments of the invention, however, picture elements from the first or second picture channel may be missing. In such embodiments, the picture elements from the first or second picture channel will be visible from one of the first or second viewing angles, but no picture elements would be seen from the other viewing angle. Instead of switching from one image to another when the security document is moved relative to an observer between the two viewing angles, the image channel that contains the image elements either appears or disappears.
    [97] The present invention is also applicable to security documents that have security devices that produce optical, variable effects other than the flipping effect described above, and to security devices with more than two image channels. FIG. 16 schematically shows, as an example, an arrangement 300 of lens elements 302 to 306, which overlaps a periodic arrangement 308 of picture elements. In this example, the periodic arrangement 308 comprises 5 groups of nested picture elements, each of which forms a separate picture that is visible in a separate picture channel. The picture elements from the first to fifth picture channels are correspondingly labeled “1 to“ 5. While the security document is being moved relative to an observer, namely from a first through a second, third and fourth to a fifth viewing angle, five image channels are successively seen by an observer. The
    36/49 optically variable effect, which results from this succession of observable image channels, is known as animation effect.
    [98] The present invention is also applicable to the production of a security document having a multi-channel security device, as shown in FIG. 16.
    [99] Also include those described above
    Embodiments Security devices in which the periodic arrangement of picture elements that is applied to a surface of the substrate of the security document is made visible by a periodic arrangement of lens elements that are attached to the opposite side of the substrate in such a way that the picture elements are enlarged and visible become. However, it should be understandable that the periodic arrangement of lens elements in these
    Embodiments is just one example of a periodic arrangement of visualizing elements that can be applied to such security devices.
    [100] For example, visualizing elements such as a family of parallel lines can also be used. Such an alternative arrangement is shown in FIG. 17, which shows a security device 320 that is part of a banknote or other security document. The
    Security device 320 includes a periodic array 322 of parallel lines 324 through 328 applied to an upper surface 330 of a transparent substrate 332. As with that shown in Figure 1
    Security device 10, the lower surface 334 of the substrate 332 is an object plane that carries a periodic array 336 of picture elements.
    37/49
    [101] Such an arrangement enables a similar range of optically variable effects that are produced as those described with reference to FIGS. 1 to 16
    Embodiments, namely image change or animation effects. The lines 324 to 328 have the same effect as the lens elements 14 in that they effectively break down the arrangement of picture elements 336. In the embodiment shown in Figure 17, the resulting image seen by an observer is generated with a contrast that is lower than that achieved with lens elements. The lines repeat with the same grid dimension as the lens elements. The width of each line and the corresponding gap between them determine the contrast that the observer can perceive. The wider these lines are, the smaller the gap, the smaller the width of the image that is patterned and the lower the resulting image contrast.
    [102] If in this patent specification (including the
    Claims) that include "includes," "includes," "comprehensive, etc., are to be interpreted to indicate the presence of the specified features, integers, steps, or components, but not the presence of one or more other features, integers, steps or exclude components or a group thereof.
    [103] It is understood that the invention is not limited to the particular embodiments described here, which are only given as examples. The scope of the invention is defined by the appended claims.
    38/49
    权利要求:
    Claims (9)
    [1]
    1. A method for producing a first security document, the security document comprising:
    a transparent substrate;
    a first periodic array of picture elements applied to a first surface of the substrate and extending in a first direction; and a first periodic array of visualizing elements applied to an opposite surface of the substrate and extending in a second direction, the first periodic array of visualizing elements overlaying the first periodic array of picture elements such that between at least a first one Viewing angle and a second viewing angle, an optically variable effect can be observed, the method comprising the steps:
    a. Determine one or more characteristics of
    Moire bands, their passing over the first periodic
    Arrangement of picture elements during the
    Security document is moved relative to an observer between at least the first viewing angle and the second viewing angle, would or will be observed as a result of the first direction being different from the second direction;
    b. Restrict at least one dimension of the first periodic array of picture elements and / or the first periodic array of visualizing elements to be smaller than the width
    39/49 is at least one of the moiré bands; and
    c. Cause the first periodic arrangement of
    Image elements and the first periodic arrangement of visualizing elements, which are limited as shown for step (b), are produced as part of the security document.
    [2]
    2. The method of claim 1, wherein determining the one or more features of moiré bands in step a. done by:
    Producing a calibration security document with a second periodic array of visualizing elements and a second periodic array of picture elements, the second periodic array of visualizing elements and the second periodic array of picture elements of the first periodic array of picture elements and the second periodic array of Image elements are the same, only that they extend over an area that is large enough to move the security document
    Observation of the movement of the moiré bands over the
    Enable picture elements; and
    Measure the one or more features of the observed moiré bands.
    [3]
    3. The method of claim 1, wherein determining the one or more features of moiré bands in step a. done by:
    Determining a maximum skew between the first periodic array of picture elements and the first
    40/49 periodic arrangement of visualizing elements, which can be introduced by one or more production steps during the production of the first security document, and
    Deriving the one or more features of moiré bands from the maximum skew.
    [4]
    4. The method of claim 2 or 3, wherein the one or more features of moiré bands comprise one or more of the following:
    the moire period or any other value representative of the width of the narrowest moiré bands; and the moiré angle, which describes the angular offset of the moiré bands with respect to the first direction.
    [5]
    5. The method according to any one of the preceding claims, wherein the periodic arrangement of visualizing elements makes a first image channel visible under the first viewing angle and a second image channel visible under the second viewing angle; and the or each periodic array of picture elements comprises a first group of picture elements forming a first image that is visible in the first image channel.
    [6]
    6. The method of claim 5, wherein the or each periodic array of image elements further comprises a second group of image elements that form a second image that is visible in the second image channel.
    41/49 • · «fr • fr • fr • fr ··· · fr fr fr
    [7]
    7. The method according to any one of claims 5 or 6, wherein the first periodic arrangement of visualizing elements from a third viewing angle makes a third image channel visible; and the or each periodic array of picture elements comprises a third group of picture elements forming a third image that is visible in the third image channel.
    [8]
    8. The method according to any one of the preceding claims, wherein the visualizing elements are lens elements which cause the image elements to be enlarged.
    [9]
    9. The method according to any one of claims 1 to 8, wherein the visualizing elements are lines.
    Vienna, applicant on June 12, 2018
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    同族专利:
    公开号 | 公开日
    AU2015101793A4|2016-01-28|
    BR112018011510A2|2018-12-11|
    GB201807684D0|2018-06-27|
    GB2559076A|2018-07-25|
    WO2017100838A1|2017-06-22|
    AU2015101793B4|2016-03-24|
    US20180345714A1|2018-12-06|
    MX2018007006A|2018-08-15|
    AU2016371234A1|2018-06-07|
    CN108367585A|2018-08-03|
    RU2018125934A|2020-01-16|
    DE112016005305T5|2018-08-02|
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    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    AU2015101793A|AU2015101793B4|2015-12-14|2015-12-14|Method of manufacturing a security document|
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