瑞士专利CH704944B1 <TITLE> Security document with integrated safety device and manufacturing process.

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专利摘要:
A security document (1) is provided, comprising a substrate (4) on which is formed a security device (10) comprising an image layer (12) and a focusing layer (11), each formed of a radiation-curable ink layer with relief formations (13; 15) is embossed. The first radiation-curable layer embossed with image relief formations (13) to form the image layer (12) is provided on a first surface of the substrate, and the second radiation-curable layer (11) embossed with focus-element relief formations (15) is provided on a second surface of the substrate. The first and second surfaces are separated by a predetermined distance (D) to produce a visible optical effect when the image layer (12) is viewed through the focusing layer (11). In preferred embodiments, at least one of the first and second radiation curable layers having diffractive relief structures is embossed, and high refractive index coatings or reflective coatings can be applied to the embossed image reliefs in the image layer (12) and / or the embossed focus element relief formations (15) of the focus layer (15). 11) are applied. The invention enables integration of security devices into a security document, such as a bill, in a cost-effective manner, without substantially increasing the thickness of the document.
公开号:CH704944B1
申请号:CH01717/12
申请日:2011-03-24
公开日:2017-03-15
发明作者:Fairless Power Gary；Batistatos Odisea；Swift Patrick；Karlo Jolic Ivan
申请人:Innovia Security Pty Ltd；
IPC主号:

专利说明:

Field of the invention
This invention relates to security documents and marks, and more particularly relates to the provision of a security document having an integrated security device or feature and also to an improved method of making such a security document.
definitions
The security document
As used herein, the term security document herein includes, but is not limited to, all types of value documents and marks and identification documents including currency units such as banknotes and coins; Credit cards, checks, passports, identity cards, security and stock certificates, driving licenses, certificates, travel documents, such as air and rail tickets, tickets and tickets, birth, death and marriage certificates and academic transcripts.
The invention is particularly applicable to security documents, such as banknotes or identification documents, such as identity cards or passports, formed from a substrate to which one or more print layers are applied.
substratum
As used herein, the term substrate refers to the base material from which the security document or security mark is formed. The base material may be paper or other fibrous 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); or a composite of two or more materials, such as a laminate of paper and at least one plastic material, or of two or more polymeric materials.
The use of plastic or polymeric materials in the manufacture of security documents, in which Australia plays a pioneering role, has been successful because polymer banknotes are more durable than their paper counterparts and may also include new security devices and features. A particularly successful security feature in polymer banknotes made for Australia and other countries has been a transparent panel or "window".
Transparent windows and half windows
As used herein, the term window refers herein to a transparent or translucent surface in the security document as compared to the substantially opaque region to which a print is applied. The window may be fully transparent, so as to allow the transmission of light substantially unaffected, or it may be partially transparent or translucent, which allows the transmission of light, but does not allow clear perception of objects through the window area.
A window surface may be formed in a polymeric security document having at least one layer of transparent polymeric material and one or more opacifying layers coated on at least one side of a transparent polymeric substrate by omitting at least one opacifying layer in the area forming the window area , When opacifying layers are applied on 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 surface.
A partially transparent or translucent surface, hereinafter referred to as a "half-window" may be formed in a polymer safety document having opacifying layers on both sides by omitting the opacifying layers only on one side of the security document in the window surface, so that the "half-window" is not fully transparent, but at least allows a passage of some light, without a clear perception of objects through the half-window is possible.
Alternatively, it is possible for the substrates to be formed from a substantially opaque material, such as paper or fibrous material, with an insertion ("insert") of transparent plastic material, in an eruption or a recess in the paper or embedded in the fiber substrate to form a transparent window or a translucent half-window surface.
Opacifying layers
One or more opacifying layers may be applied to a transparent substrate to increase the opacity of the security document. An opacifying layer is such that LT <L0, where L0 is the amount of light incident on the document and LT is the amount of light transmitted through the document. An opacifying layer may comprise any one or more of a variety of opacifying coatings. For example, the opacifying coatings may comprise a pigment, such as titanium dioxide, dispersed within a binder or carrier of the heat-activated crosslinked polymeric material. Alternatively, a substrate of transparent plastic material may be interposed between opacifying layers of paper or other partially or substantially opaque material onto which indicia may subsequently be printed or otherwise applied.
Safety device or feature
As used herein, the term security device or feature herein includes any of a wide variety of security devices, elements, or features that are intended to protect the security document or security mark from counterfeiting, copying, alteration, or tampering. Security devices or features may be provided in or on the substrate of the security document or in or on one or more layers coated on the base substrate and may take a wide variety of forms, such as security threads embedded in layers of the security document; Security inks, such as fluorescent, luminescent and phosphorescent inks, metallic inks, rainbow inks, photochromatic, thermochromatic, hydrochromatic or piezochromatic inks, printed and embossed features including relief structures; Interference layers; Liquid crystal devices; Lens and lens-like structures; optically variable devices (OVDs) such as diffractive devices including diffraction gratings, holograms and diffractive optical elements (DOEs).
Fokalpunktgrösse
As used herein, the term focal spot size refers to the dimensions, typically an effective diameter or effective width of the geometric distribution of points at which rays diffracted by a lens intersect an object plane at a particular viewing angle. The focal point size can be derived from theoretical calculations, ray-tracing simulations or from actual measurements.
Focal length f
In the present specification, focal length, when used with reference to a microlens in a lens array, means the distance from the vertex of the microlens to the position of the focus, which is indicated by locating the maximum of the energy density distribution when parallel directed radiation from the lens side is incident on the array (see T. Miyashita, "Standardization for microlenses and microlens arrays" (2007), Japanese Journal of Applied Physics, 46, p.5991).
Sag height s
The sag height or surface sag s of a lens base is the distance from a tip point to a point on the axis intersected by the shortest line from the edge of a lens base extending perpendicularly through the axis.
beam angle
The lobe angle of a lens is the entire angle of view formed by the lens.
Background of the invention
One type of security device previously proposed for use in security documents is disclosed in US Pat. No. 5,712,731 (Drinkwater), which includes a combination of microlenses and microimages for producing optically variable effects. In US Pat. No. 5,712,731, the microimages are formed by printing on a surface of a substrate, and the microlenses can be formed in a separate component or in a transparent plastic sheet bonded to the microimages. A slight mismatch between the pitch or rotation of the microimages and microlenses can produce optically variable effects, such as an enlarged image (known as moiré magnifiers, as described in M. Hutley et al., The moiré magnifier, Pure and Applied Optics , Issue 3, pp. 133 to 142 (1994)). These known security devices can generate images that appear to be moving and / or seem to float above or below the plane of the device as the viewing angle changes.
A disadvantage of these known security devices is that they are less suitable for insertion into a thin, flexible security document, such as a banknote or the like. Likewise, the generated optically variable effects are monochromatic, and the size of microimages that can be produced by traditional printing techniques such as engraving, flexure and gravure printing is limited.
It has also been proposed to form microimages in an optically variable security device using laser technology, e.g. by directing a laser beam through microlenses onto a laser-absorbing layer. However, such a technique produces only monochromatic images.
The document US 2008/0160226 discloses a security element having a first authentication feature and a second authentication feature. The first feature comprises a plurality of focusing elements in a first grid and a plurality of microscopic structures in a second grid. The microscopic structures are enlarged when viewed through the focusing elements. The second authentication element is machine and / or visually verifiable, and thus is not affected by the focusing elements of the first authentication feature. Many of the various embodiments of the security elements in US 2008/0160226 include an adhesive layer for transferring the security element to a document. Other embodiments include two carrier substrates, one for the focussing elements and the other for the microstructures. In some embodiments, the microstructures are embossed, and in other embodiments, they are printed. The security element disclosed in the publication 2008/0160226 shows a total thickness of less than 50 microns in order to make it particularly suitable for attachment to a security paper, document of value or the like. However, this can create obstacles to the size and focal length of the focusing elements and the size and resolution of the microstructures.
It is therefore desirable to provide a security document and method of manufacture in which at least some of the disadvantages of the prior art are eliminated. It is also desirable to provide a security document that includes a device that can produce optically variable effects similar to those of a combination of microlenses and microimages with an enhanced visual effect. It is further desirable to provide an improved manufacturing method of such a security document comprising such a security device.
According to the invention there is provided a security document comprising a substrate on which a security device is formed, the security device comprising an image layer and a focusing layer, the image layer comprising a plurality of embossed image relief features in a first radiation-curable ink layer on a first surface of the first Substrate, wherein the plurality of embossed image relief features in the image layer are embossed, diffractive image relief formations<tb> i. <SEP> the embossed image relief formations in the image layer form a diffractive background and wherein an image in the image layer is formed by non-diffractive regions on the diffractive background or<RTIgt; </ RTI> the embossed image relief form an image in the image layer on a non-diffractive background, wherein, for each alternative, the focus layer has a plurality of embossed focus element reliefs in a second radiation curable ink layer on a second surface of the substrate wherein the total thickness of the document substantially falls in the range of 60 to 140 microns and the first and second surfaces are separated by a predetermined distance greater than 50 microns to produce a visible optical effect when the image layer viewed through the focusing layer becomes.According to the invention, a method for producing a security document with a substrate on which a security device is formed, comprising the steps:Applying a first highly radiation-curable ink layer to a surface on one side of the substrate;Embossing the first radiation-curable ink layer with a plurality of image relief formations and curing with radiation to form an image layer, the plurality of image relief formations in the image layer being embossed diffractive image relief formations<tb> i. <SEP> the embossed image relief formations in the image layer form a diffractive background and wherein an image in the image layer is formed by non-diffractive regions on the diffractive background or<tb> ii. <SEP> the embossed reliefs form an image in the image layer on a non-diffractive background;Applying a second highly radiation-curable ink layer to a second surface of the substrate;Embossing the second radiation-curable layer with embossed focus-element relief formations and radiation curing to form a focusing layer,wherein the total thickness of the document substantially falls in the range of 60 to 140 microns and the first and second surfaces are separated by a predetermined distance greater than 50 microns to produce a visible optical effect when the image layer is viewed through the focusing layer.
The total thickness of the security document substantially falls preferably in the range of 70 to 120 microns, and more preferably from 80 to 100 microns, which is the preferred thickness range for a banknote. The first and second surfaces on which the image layer and the focusing layer are respectively provided are preferably separated by a distance substantially falling within the range of 60 to 100 μm, and more preferably between 65 and 90 μm.
Forming the image relief images in the image layer by embossing a radiation-curable ink is particularly advantageous in that it enables high-resolution pixels to be integrally formed in a security document, such as a banknote. For example, embossments of nanometer (nm) size can be formed by the "soft emboss" technique of embossing in a radiation curable ink layer and substantially simultaneously curing the radiation curable ink with radiation such as UV, X-rays or electron beams ,
A security device provided in the security document of the invention comprising an image layer comprising a plurality of pixels formed as embossed diffractive structures having a focusing layer separated from the image layer by a predetermined distance, e.g. The thickness of a transparent substrate of a security document allows the creation of a variety of optically variable effects. In particular, a visible optical effect can be produced in the form of a colored image which can be combined with other effects, such as an enlarged moiré effect, three-dimensional effects and moving or floating images.
According to another embodiment of the invention, there is provided a security document including a security device comprising an image layer comprising a plurality of relief formations applied to a first surface of the device and a focusing layer comprising a plurality of Diffraction structures formed on a second surface of the device, wherein the first and second surfaces are separated by a predetermined distance, whereby a visible optical effect in the form of a colored image is generated when the image layer is viewed through the focusing layer.
In an alternative, the image layer diffraction structures are used to form picture elements on a non-diffractive background. The non-diffractive background can take a variety of different forms. It is, for example, a transparent background, an opaque and diffusely diffusing (matt) background, or a specularly reflective background.
Alternatively, the diffractive structures form the background, while the pixels are formed by non-diffractive surfaces on the background, i. Surfaces that are free of diffraction structures.
In one embodiment, the plurality of relief element formations in the focusing layer and / or image layer comprises microlens structures and / or micromirror elements. Instead, or in addition, the plurality of relief element formations comprises formations that form at least one of a Fresnel lens, a zone plate, or a photon screen.
The use of a diffractive focusing structure, such as a Fresnel lens or zone plate, may be particularly advantageous when integrated into a security document, since such structures comprising devices are considerably thinner than their refractive counterparts. A diffractive magnification structure in the form of a photon screen offers a further advantage in that it provides substantially the same functionality as a zone plate, but has smaller continuous areas, thereby allowing for easier fabrication when using embossing techniques.
The visible optical effect that is produced when the relief formations of the image layer are viewed through the focusing layer may include an enlarged moiré effect, a three-dimensional effect, a moving image or floating image effect, or a combination thereof. Since the relief formations are applied to the device by a high-embossing process, it is possible to apply a large variety of structures (which produce a correspondingly large variety of optical effects) in a single step to the device in close spatial relationship, for example as mutually adjacent ones or nested structures.
In preferred embodiments, the substrate of the security document can be formed of a transparent material, wherein the relief formations of the image layer are embossed into a radiation-curable layer which is applied to one side of the substrate. The relief formations of the focusing layer may then be embossed into a radiation curable layer coated on the opposite side of the substrate.
In one embodiment, the thicknesses of the transparent material and the radiation-curable layers on opposite sides of the substrate determine the predetermined separation of the image layer and the focusing layer.
In an alternative embodiment, the relief formations of the image layer and the focusing layer are embossed into radiation-curable layers applied to surfaces on the same side of the substrate forming the security document, the surfaces being separated by a substantially transparent intermediate layer.
In one embodiment, at least one metallic coating or a high refractive index (HRI) coating is applied to the embossed relief formations of the image layer and / or the focusing layer. A reflective coating of this nature enhances the visibility of the optical effect produced by the device when viewed in reflection mode by the focusing layer.
In this embodiment, the substrate of the security document is transparent, translucent or opaque. The thicknesses of the substantially transparent intermediate layer, the radiation-curable layers, and any high-refractive-index coating may determine the predetermined separation of the image layer and / or the focusing layer.
Opaque substrates suitable for use with certain of the embodiments described above include paper and paper / polymer hybrid substrates.
It is particularly preferred that the security device can be integrated into a substantially transparent window of the security document to provide a further security layer above and above the security device itself.
Highly distinctive radiation-curable ink
As used herein, the term highly-applicable radiation-curable ink refers to any ink, paint, or other coating that can be applied to a substrate in a printing operation and that can be embossed in the soft state to form a relief structure. and can be cured by radiation to fix the embossed relief structure. The curing process does not take place before the radiation-curable ink is embossed, but it is possible for the curing process to take place either after the embossing or substantially simultaneously with the embossing step. The radiation-curable ink is preferably curable by ultraviolet (UV) radiation. Alternatively, the radiation-curable ink may be cured by other types of radiation, such as electron beam or X-ray.
The radiation-curable ink is preferably a transparent or translucent ink formed of a clear resin material. Such a transparent or translucent ink is particularly suitable for printing translucent security elements, such as numerical-type DOEs and lens structures.
In a particularly preferred embodiment, the transparent or translucent ink preferably comprises an acrylic-based, UV-curable, clear-coatable lacquer or coating.
Such UV-curable varnishes can be obtained from various manufacturers, including Kingfisher Ink Limited, Ultraviolet Type UVF-203 or the like. Alternatively, the radiation curable, highly impressionable coatings may be based on other composites, e.g. Nitrocellulose.
The radiation-curable inks and lacquers used according to the invention have been found to be particularly suitable for embossing microstructures, including diffractive structures such as DOEs, diffraction gratings and holograms, and microlenses and lens arrays. However, they can also be embossed with larger relief structures, such as non-diffractive optically variable devices.
The ink is preferably embossed and cured by ultraviolet (UV) radiation at substantially the same time. In a particularly preferred embodiment, the radiation-curable ink is applied and embossed at substantially the same time in a gravure printing process.
In order to be suitable for gravure printing, the radiation-curable ink preferably has a viscosity substantially falling in the range of 20 to 175 centipoise, and more preferably 30 to 150 centipoise. Viscosity can be determined by measuring the time required to drain the varnish from a Zahn Cup # 2. A sample that drains in 20 seconds has a viscosity of 30 centipoise, and a sample that drains in 63 seconds has a viscosity of 150 centipoise.
For some polymer substrates, it is necessary to apply an intermediate layer to the substrate before the radiation-curable ink is applied to improve the adhesion of the inked, embossed structure to the substrate. The intermediate layer preferably comprises a primer layer, and more preferably the primer layer comprises a polyethyleneimine. The primer layer may also comprise a crosslinker, for example a multifunctional isocyanate. Examples of other primers suitable for use in accordance with the invention include: hydroxyl-terminated polymers; Hydroxyl-terminated, polyester-based copolymers; cross-linked or uncrosslinked hydroxylated acrylates; polyurethanes; and UV-curing anionic or cationic acrylates. Examples of suitable crosslinkers include: isocyanates; polyaziridines; zirconium; aluminum acetylacetone; Melamine; and carbodiimides.
The type of primer can vary for different substrates and embossed ink structures. It is preferable to select a primer which has substantially no influence on the optical properties of the embossed ink structure.
In another possible embodiment, the radiation-curable ink may comprise metal particles to form a metallic ink composition that is both printable and highly embossable. Such a metallic ink composition may be used to print a reflective security element, such as a diffraction grating or a hologram. Alternatively, a transparent ink, e.g. is formed of a clear resin, coated on one side of the substrate with or without an intermediate primer layer, the transparent ink is then embossed and cured with radiation, and a metallic ink composition following the embossed transparent ink in a printing operation is applied if it is desired to form a reflective security element as a part of the security device.
It is also possible for the metallic ink composition to be applied in a layer which is sufficiently thin to allow the transmission of light.
When a metallic ink is used, it preferably comprises a composition containing metal pigment particles and a binder. The metal pigment particles are preferably selected from the group consisting of aluminum, gold, silver, platinum, copper, a metal alloy, stainless steel, Ni-chromium and brass. The metallic ink preferably has a low binder content and a high pigment to binder ratio. Examples of metallic ink compositions suitable for use in accordance with the present invention are described in WO 2005/049745 to Wolstenholme International Limited, which describes coating compositions suitable for use in coating a diffraction grating comprising metal pigment particles and a binder , wherein the ratio of pigment to binder is sufficiently high to allow the arrangement of the pigment particles on the contours of the diffraction grating. Suitable binders may include any one or more selected from the group consisting of: nitrocellulose, ethylcellulose, cellulose acetate, cellulose acetate propionate (CAP), cellulose acetate butyrate (CAB), alcohol soluble propionate (ASP), vinyl chloride, vinyl acetate copolymers, vinyl acetate, vinyl, Acrylic, polyurethane, polyamide, rosin ester, hydrocarbon, aldehyde, ketone, urethane, polyethylene terephthalate, terpene phenol, polyolefin, silicone, cellulose, polyamide and rosin ester resin. In a particularly preferred metallic ink composition, the binder comprises nitrocellulose and polyurethane.
The pigment to binder ratio preferably falls substantially in the range of 5: 1 to 0.5: 1 weight ratio, and more preferably substantially in the range of 4: 1 to 1: 1 weight ratio.
The metal pigment content in the weight ratio of the composition is preferably less than 10%, and more preferably less than 6%. In particularly preferred embodiments, the pigment content in the weight ratio of the composition substantially falls in the range of 0.2% to 6%, and especially from 0.2% to 2%.
The average particle diameter may be in the range of 2 μm to 20 μm, preferably in the range of 5 μm to 20 μm, and more preferably in the range of 8 μm to 15 μm.
The thickness of the pigment particles is preferably less than 100 nm and more preferably less than 50 nm. In one embodiment, the thickness of the pigment particles falls substantially in the range of 10 to 50 nm. In a further embodiment, the thickness of the pigment particles falls within Substantially in the range of 5 to 35 nm, and in another embodiment, the mean thickness of the pigment particles falls substantially in the range of 5 to 18 nm.
Highly curable, UV-curable ink compositions such as those described above have been found to be particularly suitable for embossing to form optically diffractive security devices such as diffraction gratings, holograms and diffractive optical elements.
In the case of a half-window in which the transparent area on one side is covered by at least one opacifying layer, a security device formed of a highly embossed metallic ink may be a reflecting device which is only in the half-window of the visible on the opposite side of the substrate, which is not covered by an opacifying layer in the half-window area.
It is also possible for the opacifying layer covering the half-window area on one side of the substrates to allow the partial transmission of light, so that the safety device formed by the embossed ink is partially visible in the transmission from the side, which is covered by the opacifying layer in the half-window area.
In the case of a flexible security document, such as a banknote, which is foldable, if the focusing layer is provided on a first surface of the document in a full window area, the image layer may be provided on another part of the document which is substantially spaced laterally from the focusing layer and located on the opposite surface of the document, whereby, when the lens layer is superimposed over the image layer, eg by folding, the image layer can be viewed through the focusing layer and the visible optical effect becomes apparent.
Brief description of the drawings
Some preferred embodiments of the invention will now be described, by way of example only, with reference to the accompanying drawings. Show it:<Tb> FIG. 1 <SEP> is a schematic section through a security document with an integrated security device according to an embodiment of the invention;<Tb> FIG. 2 <SEP> is a schematic section through a security document similar to FIG. 1 with a modified security device;<Tb> FIG. 3 <SEP> is a schematic section through a security document similar to FIG. 1 with a further security device;<Tb> FIG. Fig. 4 is a schematic section through a security document with a security device formed from embossed ink in a half-window area;<Tb> FIG. 5 <SEP> is a plan view of a security document showing an example of an optically variable effect produced by an integrated security device;<Tb> FIG. 6 <SEP> Top views of the focusing layer and image layer of the security document according to FIG. 5;<Tb> FIG. Fig. 7 is a plan view of a modification of the security document of Fig. 5;<Tb> FIG. 8 is a plan view and a close-up of an example of an image relief formation for use with some embodiments of the invention;<Tb> FIG. 9 <SEP> an alternative image layer for use with the configuration shown in FIG. 6;<Tb> FIG. FIG. 10 shows a schematic cross section through a modified security document in which the security device is formed on an opaque substrate; FIG.<Tb> FIG. Fig. 11 is a schematic cross-sectional view of another security document in which the security device is formed on an opacified transparent substrate; and<Tb> FIG. 12 shows a schematic cross section through a further exemplary embodiment of a security document in which the lens layer does not permanently superimpose the image layer.
Detailed description of the drawings
Referring to Figure 1, there is shown a security document 1 comprising a substrate 4 of transparent plastic material and one or more opacifying layers 5, 6 on each side of the substrate. The transparent substrate 4 is preferably formed of a transparent polymer material, such as a laminate structure of two or more layers of biaxially oriented polypropylene. However, it will be appreciated that other transparent or translucent polymer substrates may be used in the invention, such as polyethylene and polyethylene terephthalate (PET). The opacifying layers 5, 6 may comprise one or more coatings of opacifying ink applied to opposite sides of the substrate 4. Alternatively, the opacifying layers 5, 6 may be formed from layers of paper or other opaque material laminated on opposite sides of the substrate 4 to form a hybrid substrate.
As shown in Fig. 1, the opacifying layers 5, 6 are omitted in a region of the security document 1 to form a transparent surface or window 7. The security document is provided with an integral security device 10 in the window 7, as described below.
The security device 10 comprises a focusing layer 11 and an image layer 12. A first or upper surface 4a of the transparent substrate 4 comprises a plurality of embossed focusing lens relief formations in the form of diffractive microlenses 15 embossed in a first layer of radiation-curable ink were to form the focusing layer 11. On the second or lower surface 4b of the device is a second layer of radiation-curable ink into which has been embossed a plurality of diffractive image relief features, generally indicated by reference numeral 13. The diffractive image relief formations 13 form the image layer 12.
The microlenses 15 and the diffractive image reliefs 13 may be formed of a radiation-curable ink of the type described above, for example UV-acrylate with a refractive index n of 1.47.
The thickness of the transparent substrate 4 preferably falls substantially in the range of about 50 to about 120 μm. The thickness of the radiation-curable inks preferably does not exceed about 10 microns, and more preferably 5 microns. Thus, the focusing layer 11 and the image layer 12 are separated by a predetermined distance D which is larger than 50 μm, preferably between about 60 and 100 μm, and more preferably between 65 and 90 μm.
The total thickness of the security document enclosing the security device preferably falls substantially in the range of about 60 to 140 μm. In the case of a transparent substrate covered by opacifying inks, the opacifying ink layers preferably have a total thickness substantially falling in the range of about 5 to 20 microns on each side of the substrate. When a hybrid paper / polymer substrate is used, the thickness (s) of the opacifying paper layer (s) may substantially fall within the range of about 10 μm to 45 μm.
The invention enables the use of relatively wide focusing elements and picture elements. The spacing of the focusing elements and / or picture elements is preferably at least about 50 μm.
The embossed diffractive image reliefs 13 may have various two-dimensional shapes in the plane of the image layer. For example, each image relief formation can form part of a larger overall image that is visible when it is. is viewed through the focusing layer 11. Alternatively, each diffractive image relief formation 13 may be a complete image, such as a letter, a number, or a geometric shape.
The non-diffracting surfaces 18 of the image layer 12 form a background for the diffractive image relief formations 13. The radiation curable ink of the image layer may be a partially transparent ink composition, for example, containing gold or silver metal pigments as described above. In this case, an observer observing the device through the focusing layer 11 will observe a color diffraction image formed by the diffractive image relief formations 13 on a reflective gold or silver background formed by non-image areas 18.
Another layer 16 of a protective coating may be applied over the image layer 12. This serves to protect the diffractive image relief formations from physical damage and to prevent forgery by contact copying the relief structure. The further layer 16 may be a substantially transparent material, such as a high refractive index (HRI) coating, or it may be a reflective material, such as a metallic coating. An HRI or metallic coating may serve to increase the optical effect produced by the device, depending on the difference in refractive index between the coating and the image layer 12. The optical effect may, for example, be completely visible in the transmission, but only partially visible in the reflection, or vice versa.
Alternatively, the image layer 12 may be printed in a substantially transparent ink onto which another layer 16 of ink having a different index of refraction is applied such that the ink fills the diffractive image relief formations 13 and the background regions 18 fill the appearance of the material assume the further layer 16. The further layer 16 thus functions as a background layer in this embodiment.
For example, when using a highly reflective material, such as one of gold or silver metallic ink compositions described above, the viewer perceives a colored diffraction image created by the diffractive image relief features 13 against a specularly reflective gold image. or silver background, where the specular reflection of background areas 18 occurs.
The use of a non-metallic ink comprising a dye or a colored pigment causes a diffracted, colored and optically variable image to become visible against an optically invariable background with the color of the dye or pigment.
It is also possible to pattern the background regions 18, for example with a non-diffractive and non-periodic relief having a high degree of surface roughness, so that if a reflective layer of ink 16 is applied to the image layer 12, light incident on the background surfaces is not reflected specularly, ie diffuse, and the background assumes a substantially achromatic or dull appearance.
A protective coating 17, for example of an HRI material, may also be applied to the focusing layer 11.
The diffractive image relief formations 13 may have a constant spatial frequency f (= 1 / d, where d is the lattice constant) across the image layer. By means of the grating equation d (sinθm + sinθi) = mλ, where θm is the angular position of the mth diffraction order, θ is the incident angle and λ is the wavelength of the incident light, the color of the image changes when viewed under polychromatic light as the viewing angle changes , and different first-order diffraction maxima corresponding to different wavelengths become visible.
The spatial frequency and / or high definition depth may also be modulated across the image layer to produce more pronounced visual effects, such as full-tone, multi-color moiré magnified images.
It is also possible to form diffractive image reliefs 13 as subwavelength gratings to serve as 0 th order gratings for a particular wavelength of light. For example, a grating with a grating period d of about 300 nm has a strong reflection peak around 550 nm, i. it appears essentially green. This type of structure also produces another interesting effect in that it indicates a color shift with a rotation of about 90 ° in its own plane.
When sub-wavelength image reliefs 13 are formed, their spatial frequencies may also be modulated across the image layer to produce pixels of different colors. For example, some of the diffractive image relief features 13 may have a first spatial frequency such that they produce green colored light in the 0th diffraction order, while the remaining pixels may have a second spatial frequency to produce red-colored light in the 0th diffraction order. It will be appreciated that any number of different colors may be employed so that multi-color enlarged images indicative of color shift upon 90 ° rotation may be formed.
The focusing layer 11 and image layer 12 are separated by a predetermined distance D, which is usually similar or substantially equal to the focal length of the focusing elements 15, so that the focusing elements are substantially "in focus" with the pixels. The distance D may also be reduced to the size of the diffractive image relief features 13 by shaping the focal spot size of the image layer 12 such that the focal spot size is approximately equal to or within a narrow range (eg, ± 20%) of the pixel size, as in FIG Provisional US Application 61/157309.
It is also possible to use "out of focus" focusing elements that have a focal length that is substantially greater than the distance D. For example, the focal length may be about twice the distance D, e.g. When D is about 80 to 85 μm, focusing elements having a focal length of about 150 to 160 μm can be used.
If each image relief formation is a microimage in the form of a pattern or a sign and the microimages are substantially identical and repeat over the image layer at a particular repetition period or spatial frequency, they are viewed through lenses 15 having a similar repetition period , then the observer perceives an integral image consisting of moiré rings, each ring being an enlarged version of the individual microimages. The degree of magnification depends on the difference in the repetition period between the lens array in the focusing layer 11 and the array of microimages in the image layer 12, as well as the relative angular orientation of the lens and image array.
The microimages may be formed as non-diffractive structures, e.g. as structures with a spatial extent in the order of several micrometers in one or both dimensions in the plane of the image layer. This is a much higher resolution than can be achieved by printing. Alternatively, they may be diffraction structures having a similar overall expansion as the non-diffractive structures described above, but which are diffractively substructured, i. each microimage is a diffraction grating or a sub-wavelength grating.
It is also possible for the image relief formations to be more complex diffractive, reflective or refractive structures.
In one embodiment, each diffractive image rendering formation 13 may be patterned to produce, upon reflection under diffuse illumination by polychromatic light, an image of a portion of a real or fictitious object, the object appearing three-dimensional and achromatic to the viewer.
An example of such a structure is a relief formation comprising reflective facets (micromirrors) in which the slopes (angles) of the facets are modulated to reflect incident light in a manner that reflects from the surface of the surface Object as described in PCT application WO 90/08 338. Another example of a relief structure capable of producing a pseudo-3D effect, as described in PCT application WO 2006/013 215, is a relief structure comprising a series of diffractive zones, the spatial frequency and curvature the diffractive exploits in each zone are arranged such that incident light is deflected in a manner that simulates reflection from the surface of the object.
Viewing diffractive image reliefs 13 of this nature under an array of lenses 15 can give the user a pseudo-3D impression that also varies as the viewing angle is changed.
In another embodiment, each of the diffractive image relief formations 13 may be of the type described above but produce a pseudo-3D image of the entire object. If the diffractive image reliefs 13 are substantially identical to one another and are each below a lens 15, then the device can produce a visual optical effect that is a rotated and magnified version of the pseudo 3D image according to the moiré magnification principle described above.
In another embodiment, each diffractive image relief formation 13 may be structured as an array of micromirrors in which the angle between each micromirror and the substrate is modulated to produce a highly reflective optical effect. For example, the micro-mirror angles within a diffractive image relief formation 13 can be modulated to reflect incident light in a manner that simulates reflection from the surface of a real or fictional three-dimensional object, giving the observer a pseudo-3D effect.
In general, any focusing element of the focusing layer over a picture element 13 is in use of the device, but complex optical variable effects, such as animation, can be generated by applying diffractive image relief formations 13 consisting of a plurality of entangled (spatially multiplexed) images ) Images are obtained. For example, a "jumping image" effect can be provided by interlacing two images. The diffractive image reliefs 13 in this case would be the segments of the interlaced images, and each focussing element 15 would overlay a pair of diffractive image reliefs 13, one from each image.
In another example, the diffractive image relief formations 13 may include more than one type of effect-generating relief element, such that the image layer 12 may, for example, be an array of sub-wavelength grating microimages that produce a 0 th order diffraction image that shifts the color upon rotation , and includes an array of diffractive microimages that shift the color as the device inclines but not as the device rotates. Two or more different types of optical effect can thus be generated by a single image layer 12.
It is also possible to use diffraction lens structures as the focusing elements to provide an enlargement effect, for example the Fresnel microlenses 25 according to FIG. 2. FIG. 2 shows a security document 2 similar to that according to FIG. 1, but with a modified security device 20. The security document 2 and the device 20 according to FIG. 2 are in all other respects substantially identical to the security document 1 and the device 10 according to FIG . 1 . The Fresnel microlenses 25 may be formed as structures having a continuous profile, as shown in FIG. 2, or may be approximated by structures having a binary or multi-plane profile, as known in the art.
Fig. 3 shows a security document 3 similar to Fig. 1, but with another modified security device 30. The security document 3 and the device 30 according to Fig. 3 are in all other respects substantially identical to the security document 1 and the device 10 according to FIG. 1. The security device 30 differs from that according to FIG. 1 in that the embossed diffractive structures 33 in the image layer 12 form a diffractive background, and the focusing elements 35 of the focusing layer 14 lie over non-diffracting surfaces 36 in the image layer.
Referring now to Figure 4, a security document 40 is shown that includes the security device 20 of Figure 2. The security document 40 includes a first opacifying layer 42 covering the side of the substrate 4 on which the image layer 12 is provided, and optionally may include a second opacifying layer 44 covering the first opacifying layer. On the opposite side of the substrate on which the focusing layer 14 is provided, a first opacifying layer 46 (and optionally a second opacifying layer 48) covers the substrate 4 with the exception of the surface of the device 20. The uncovered surface 45 to which the opacifying Layers 46, 48 are not applied, thus forming in the upper surface of the document, as shown, a half-window surface 47 comprising the device 20.
The opacifying layers 42 and 44 may comprise any one or more of a variety of opacifying coatings. For example, the opacifying coatings may comprise a pigment, such as titanium dioxide, dispersed in a binder or carrier of a heat-activated, crosslinkable polymeric material. Alternatively, the substrate 4 of transparent plastic material may be disposed between opacifying layers of paper on which indicia may subsequently be printed or otherwise applied. It is also possible for the security documents to be formed from a paper or fibrous substrate having a surface relief with a transparent plastic inlet recessed in the breakout surface to form a transparent window onto which the ink composition is applied and embossed to form the transparent Focusing layer 11 and image layer 12 form.
Referring to Figures 5, 6 and 8, a security document 120 is shown that includes a window or half window area 130 through which a moiré magnifying effect is visible. Fig. 5 shows the security document in plan view. The security document 120 has a similar structure to that shown in FIG. 1, but the diffractive image relief formations 13 are highly embossed diffractive microstructures in the form of letters "A" 113 in an image layer 112, as shown in the enlarged view of FIG also shows an enlarged view of the microlenses 115 of the focusing layer 114. A greatly enlarged version of one of the diffractive microstructures 113 is shown at reference numeral 150 in FIG. Surfaces 118 that are not occupied by letter "A" 113 may be unstructured areas, or may be patterned non-periodically to diffuse incident light.
In Fig. 8, each diffractive microstructure 113 comprises a series of highly embossed diffractive utilizations in which dark lines 113a indicate embossed portions (utilizations) and white lines 113b indicate non-embossed portions (tableaux). Such a formation may provide a transition between light and dark images when viewed in transmission at various angles or if the security document is tilted.
The background layer (not shown) applied on the embossed image layer 112 is preferably a translucent ink including a dye so that when the diffraction microstructures 113 are viewed through the focusing layer 114, the microlenses 115 include and a (n ) has similar (but not identical) pitch and rotation arrangement as the image layer 112, enlarged and rotated letters 113 showing a diffractive, optically variable effect are visible against a non-diffracting colored background 118, FIG the background color corresponds to the color of the dye.
FIG. 7 shows a modified version 220 of the security document 120 according to FIG. 5, in which the roles of foreground and background have been reversed. In this case, the image layer is embossed everywhere, except for areas corresponding to the letter "A", so that enlarged and rotated versions 213 with the color of the dye in the window area 230 are visible against a colored diffractive background 218, which is the embossed Corresponds to areas.
If the distance between adjacent embossed 113a and non-embossed 113b surfaces is made small enough, then the pixel may form a sub-wavelength grating, which preferably reflects light of a particular color, as described above.
It should also be noted that the spatial frequency of the utilizations 113a within a pixel 113 may be modulated to produce different color effects. The depth of the embossed exploits can be modulated as well or instead.
Diffraction microstructures 113 in different regions of the image layer 112 may also have different spatial frequencies and / or high-definition depths to produce different colors and / or brightness across the image layer 112.
FIG. 9 shows an alternative image layer 312 (without scale) for the image layer 112 according to FIGS. 5 and 7. In this embodiment, diffractive image reliefs 313 (delimited by dashed lines) are generally not identical. The diffractive image relief features 313 include embossed exploits (dark lines) 313a and non-embossed surfaces 313b, and the spacing and curvature of the embossed effects can be modulated across the image layer 312. Using a device employing the image layer 312, each diffractive image relief image 313 is viewed through a single lens in a superimposed lens array 114, giving the viewer the impression of a diffracted image 350 that changes color, and that also seems to be moving and / or floating when the viewpoint is changed.
Referring now to FIG. 10, a modified security document 50 is shown that includes an opaque substrate 51 provided with an integral security device 510. The security device 510 is similar to the security device 10 of FIG. 1 and includes an image layer 52 and a focusing layer 54. The image layer 52 is formed of a layer of radiation-curable ink applied to one surface of a first surface 59 of the opaque substrate 51, whereupon diffractive image relief features 53 are embossed in the ink layer and the ink is cured. An optical spacer layer 56, preferably a layer of HRI material, is applied to the image layer 52. A layer of radiation-curable ink is then applied to the spacer layer 56 and the microlenses 55, which are simultaneously embossed and cured in the ink layer to form the focusing layer 54. Another layer 57, preferably of an HRI material, may be applied to protect the focusing layer 54. The non-embossed, non-diffractive surfaces 58 of the image layer form a background for the embossed pixels 53, but it will be appreciated that the arrangement can be reversed with the embossed areas forming a background for unembossed areas forming the pixels as described with reference to FIG.
The surface of the opaque substrate 51 on the side on which the security device 510 is provided may be defined by one or more other opaque layers, e.g. Print layers 511 and 512 are covered except for the area where the security device is located. Thus, a half window 517 is formed in the security document to produce a similar effect as in FIG. 4.
In the embodiment of Fig. 10, the image layer 52 and the focusing layer 54 are on the same side of the substrate, and this may be advantageous in some manufacturing constructions.
FIG. 11 shows a modified security document 60 having a security device 610 that is similar to the device 20 of FIGS. 2 and 4. The document 60 comprises a transparent substrate 61 to which an opacifying coating 70 has been applied on a surface 71. A radiation-curable ink image layer 62 is applied to the surface 72 of the substrate 61 opposite to the opacifying coating 70, and image relief formations 63 are formed by embossing and curing the radiation-curable ink. Then an HRI coating 66 is applied to the image layer 62, and another layer 67 of a substantially transparent optical spacer is still applied to the HRI coating 66. A second layer of radiation-curable ink may then be applied to the outer surface 73 of the optical spacer layer 67, and focussing element relief formations 65 are embossed and cured in the radiation-curable ink to form the focussing layer 64. Another layer of HRI material 67, which may be the same or different than the HRI coating 66, is then applied to the focusing layer 64 to protect the lenses.
As shown in Fig. 10, the surface of the transparent substrate 61 on the side on which the security device 610 is provided may be covered by one or more other opaque layers, for example, print layers 610 and 612 except for the surface in which the safety device is located. Thus, a half window 617 is formed in the security document to produce a similar effect as in FIG. 4.
In each of Figs. 10 and 11, the total thickness of the optical spacer and the HRI coating, if provided, is preferably such that the image layer and the focusing layer are separated by a distance D larger than 50 μm. The total thickness of the security document preferably falls substantially in the range of about 60 to 140 microns, and more preferably is less than about 85 microns to allow the thickness of the opaque substrate or opacified transparent substrate.
FIG. 12 shows another modified security document 410 that includes a transparent substrate 411 with opacified coatings 422, 424 applied thereto, except for the regions 430, 431, each of which forms a window area in the security document 410. In the first window 430, a focusing layer 414 of radiation-curable ink is applied, in which focusing element relief formations 415 have been embossed and hardened. An HRI material 417 is applied to the focussing element relief formations 415 as a protective coating. In the second window area 431, on the opposite side of the substrate with respect to the focusing layer 414, a second layer of radiation-curable ink is applied, in which image relief formations 413 are embossed and hardened to form the image layer 412. Image reliefs 413 are protected by a second HRI protection layer 416.
By folding the security document 410 and aligning the two window areas 430, 431 so that the focusing layer 414 overlaps with the image layer 412, a visible optical effect may appear, for example, a diffractive or non-diffracting moiré magnification effect as described above, or a moving and / or floating colored image. This "self-verifying" security document configuration adds another recognizable security feature for authenticating the document.
It can also be seen that the focusing layer 414 and the image layer 412 may be located on the same side of the substrate 411, instead of the opposite sides as shown in Fig. 11, assuming the substrate thickness and / or the focal length of the focusing elements 415 are / will be set accordingly.
In some applications, an intermediate primer layer (not shown) may be applied to the surface of the substrate 11, 51, 61, 411 before the highly impressionable ink composition of layers 12, 14, 52, 54, 62, 64, 112 , 114, 412, 414 to improve the adhesion of the resulting embossed structure to the substrate.
The device for embossing the UV-curable ink to form the embossed structure may include a shim or a seamless roller. The balance or roller may be made of any suitable material, such as nickel or polyester.
The nickel balances are preferably prepared via a nickel sulfamate electroplating process. The surface of a photoresist glass plate carrying a microscopic structure used to form a diffractive relief structure or an array of microlenses may be vacuum metallized or sprayed with pure silver. The plate may then be placed in a nickel sulfamate solution and over a period of time nickel molecules are deposited on the surface of the silver-coated photoresist resulting in a pristine copy. Subsequent copies can be used when transferring the image for reproduction or transfer to ultraviolet polyester balances or to create a seamless roll.
Polyester stabilizers can be prepared by coating polyester with an ultraviolet curable lacquer and by contact copying the original image and curing the transferred image with ultraviolet light.
Seamless cylinders can be made by using a metallized transfer film having a submicroscopic diffraction pattern or a microscopic lens pattern for microlenses thereon, which can be fixed and transferred onto a cylinder coated with an adhesive. The metallized transfer film may then be adhered to the roll via a nip. The adhesive is then cured, preferably by heat. Upon curing, the transfer film is removed, leaving the metallized layer with the sub-microscopic or microscopic pattern on the surface of the cylinder, i. the roller. This is repeated until the cylinder is completely covered. This cylinder can be placed in an injection tube and injected with silicone to make a mold. The submicroscopic or microscopic pattern can then be cast on the inner surface of the silicone.
When the silicone is cured, the mold is removed and placed in a second injection tube. An injection molding roll can then be placed in the mold and filled with a hard resin, which is preferably cured with heat. After the cure, the roller may be removed from the mold in which the pattern in the interior surface of the silicone has transferred to the exterior surface of the resin cylinder and is ready for use to transfer the submicroscopic diffraction pattern or lens pattern on the surface of the cylinder to the surface of a printed surface to transfer ultraviolet-curable varnishes on the first surface of a substrate.
In another embodiment, a cylinder is coated with an ultraviolet curable resin with a clear transfer film having a submicroscopic diffraction pattern or lens pattern placed on the surface of the ultraviolet resin over a nip and with ultraviolet radiation is hardened. The cylinder may then subsequently be injection molded as described above and used to transfer the pattern directly into the surface of a printed ultraviolet-cured resist on the first surface of a substrate.
The top surface of the substrate may be printed with the highly visible UV curable ink in discrete halftone screen or half window area so that subsequent further printing on non-screened areas may take place as images / patterns outside the window or half window area , The substrate may then be passed through a lip roll to a cylinder carrying a submicroscopic diffraction pattern or lens pattern or image in the form of a nickel or polyester balance attached to the surface of a cylinder. In a preferred embodiment, the patterns are held on a seamless cylinder, so that the accuracy of the transfer can be improved. The submicroscopic diffraction pattern or lens pattern may then be transferred from the balance or seamless roll into the surface of the exposed ultraviolet curable lacquer by contacting the surface of the balance or seamless roll with the surface of the exposed ultraviolet curable lacquer. An ultraviolet light source can expose through the upper surface of the film substrate and directly cures the paint by exposure to ultraviolet light. The ultraviolet light sources may be the lamps in the range of 200 watts to 450 watts applied within the cylinder, which cure through the printed ultraviolet lacquer and fix the transferred submicroscopic diffraction pattern or lens pattern.
The above-described method, in which embossed relief structure security devices are formed by printing a transparent radiation-curable ink on a sheet, wherein the ink is embossed in its soft state and at the same time the ink is cured with radiation, enables a plurality of security features that on a Sheets of banknotes or other security documents in which the security features are more accurate in tinting with the window or half-window areas of the individual documents of the sheet as compared to other methods of applying high-impact security devices such as diffraction gratings or holograms by transferring the security devices of a transfer sheet on the security documents. This is according to the present invention based, at least in part, on the alignment of the security device, which is generated as an integral step of the printing process and does not suffer from the problems of sheet feeding scanning in which the tolerances are usually greater than 1 mm.
Another advantage of the invention is that it allows security devices to consist of a focusing layer and a picture layer to be integrated into a security document, such as a banknote, in a cost-effective manner, without the thickness of the document being essential to increase. In some cases, the additional height of the safety device is not noticeable. The invention therefore enables the use of relatively wide focusing elements and picture elements without adversely affecting the further printing or use of the device. The device, which is formed of a focusing layer and an image layer, is an obvious security feature that allows for increased visibility by the public and provides a greater degree of difficulty in copying by the counterfeiter.
It will be understood that various modifications and variations can be made in the embodiments of the present invention described above:For example, the various focus layers and image layers in the various embodiments may be interchanged, and while the example embodiments have been described with particular reference to a security document in the form of a bill, it will be appreciated that the various embodiments and embodiments of the invention have application in other types Security and identification documents comprising the following:Credit cards, checks, passports, identity cards, security and stock certificates, driving licenses, certificates, travel documents, such as air and rail tickets, tickets and tickets, birth, death and marriage certificates, and academic transcriptions.

权利要求:
Claims (11)
[1]
A security document having a substrate on which a security device is formed, the security device comprising an image layer and a focusing layer, the image layer comprising a plurality of embossed image relief features in a first radiation-curable ink layer on a first surface of the substrate, the plurality of embossed ones Image Relief Formations in the picture layer are highly embossed diffractive image relief formations, beingi. the highly embossed diffractive image relief formations in the image layer form a diffractive background and wherein an image in the image layer is formed by non-diffractive regions on the diffractive background orii. the highly embossed diffractive image relief form an image in the image layer on a non-diffractive background,wherein, for each alternative, the focusing layer comprises a plurality of embossed focusing element relief formations in a second radiation-curable ink layer on a second surface of the substrate, the total thickness of the document falling within the range of 60 to 140 μm, and the first and second surfaces being around separated by a predetermined distance greater than 50 microns to produce a visible optical effect when the image layer is viewed through the focusing layer.
[2]
A security document according to claim 1, wherein the embossed focus element relief formations are diffractive structures.
[3]
A security document according to any one of the preceding claims, wherein the visible optical effect produced by the focusing layer when viewing the embossed relief image in the image layer is a color image.
[4]
A security document according to any one of the preceding claims, wherein the visible optical effect produced when viewing the image relief formations of the image layer by the focusing layer has at least the following effects: an enlarged moiré effect; a three-dimensional effect; and includes a floating or floating image.
[5]
5. Security document according to one of the preceding claims, wherein the security device is contained in a window or half window of the security document.
[6]
6. A method for producing a security document with a substrate on which a security device is formed, comprising the steps:a) applying a first high-impact, radiation-curable ink layer to a surface on one side of the substrate;b) embossing the first radiation-curable ink layer with a plurality of image relief formations and curing with radiation to form an image layer, wherein the plurality of image relief formations in the image layer are embossed diffractive image relief formationsi. the highly embossed diffractive image relief formations in the image layer form a diffractive background and wherein an image in the image layer is formed by non-diffractive regions on the diffractive background orii. the highly embossed diffractive image relief form an image in the image layer on a non-diffractive background;c) applying a second highly-curable, radiation-curable ink layer to a second surface of the substrate;d) embossing the second radiation-curable layer with highly embossed focus-element relief formations and curing with radiation to form a focusing layer,e) wherein the total thickness of the document falls in the range of 60 to 140 microns and the first and second surfaces are separated by a predetermined distance greater than 50 microns to produce a visible optical effect when the image layer is viewed through the focusing layer ,
[7]
7. A method according to claim 6, wherein the embossed focusing element relief formations are diffractive structures.
[8]
The method according to claim 6 or 7, wherein the substrate is formed of a transparent material, the image reliefs of the image layer are embossed into a radiation-curable layer coated on one side of the substrate, and the focusing element reliefs of the focusing layer are formed into a radiation-curable layer embossed on the opposite side of the substrate.
[9]
A method according to any of claims 6 to 8, wherein the image relief image formations and focusing element relief formations of the focusing layer are embossed into radiation-curable layers applied to surfaces on the same side of the substrate, the surfaces being formed by a substantially transparent intermediate layer are separated.
[10]
10. The method according to any one of claims 6 to 9, wherein at least one reflective coating or coating with high refractive index is applied to the embossed image relief reliefs of the image layer and / or the embossed focusing element relief formations of the focusing layer.
[11]
A method according to any one of claims 6 to 10, wherein at least one of the first and second radiation-curable ink layers is embossed to form the relief formations and cured with radiation at substantially the same time as the embossing step to fix the embossed relief formations.

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同族专利:

公开号 | 公开日

DE112011100983T5|2013-04-11|

CN102958705B|2016-08-31|

GB201216429D0|2012-10-31|

US20130069360A1|2013-03-21|

WO2011116425A1|2011-09-29|

MX2012010975A|2012-11-23|

AU2011232310A1|2012-10-18|

AU2011232310B2|2014-04-10|

HK1182997A1|2013-12-13|

BR112012024191A2|2019-09-24|

GB2505724B|2015-10-14|

CN102958705A|2013-03-06|

GB2505724A|2014-03-12|

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AU2016101590B4|2016-09-08|2017-05-18|Ccl Secure Pty Ltd|A 3d micromirror device|

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法律状态:
2016-08-31| PFA| Name/firm changed|Owner name: INNOVIA SECURITY PTY LTD., AU Free format text: FORMER OWNER: SECURENCY INTERNATIONAL PTY LTD, AU |

2017-08-15| PFA| Name/firm changed|Owner name: CCL SECURE PTY LTD, AU Free format text: FORMER OWNER: INNOVIA SECURITY PTY LTD., AU |

优先权:

申请号 | 申请日 | 专利标题

AU2010901243A|AU2010901243A0|2010-03-24|Security device and method of manufacture|

PCT/AU2011/000337|WO2011116425A1|2010-03-24|2011-03-24|Security document with integrated security device and method of manufacture|

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