The present invention relates generally to optically variable devices and, more particularly, to aligning or orienting magnetic flakes in a painting or printing process in order to obtain a dynamic optical effect.
Optically variable devices are used in a wide variety of applications, both decorative and utilitarian; for example, such devices are used as security devices on commercial products. Optically variable devices can be made in numerous ways and achieve a variety of effects. Examples of optically variable devices include holograms imprinted on credit cards and authentic software documentation, color-shifting images printed on banknotes and enhancing the surface appearance of items such as motorcycle helmets and wheel covers.
Optically variable devices can be made as a film or foil that is pressed, stamped, glued, or otherwise attached to an object, and can also be made using optically variable pigments. One type of optically variable pigments is commonly called color-shifting pigments because the apparent color of images appropriately printed with such pigments changes with the change of the angle of view and/or illumination. A common example is the numeral “20” printed with color-shifting pigments in the lower right-hand corner of a U.S. twenty-dollar bill, which serves as an anti-counterfeiting device.
Optically variable devices can also be made with magnetic pigments that are aligned with a magnetic field. After coating a product with a liquid ink or paint composition, a magnet with a magnetic field having a desirable configuration is placed on the underside of the substrate. Magnetically alignable flakes dispersed in a liquid organic medium orient themselves parallel to the magnetic field lines, tilting from the original orientation. This tilt varies from normal to the surface of a substrate to the original orientation, which included flakes essentially parallel to the surface of the product. The planar oriented flakes reflect incident light back to the viewer, while the reoriented flakes do not, providing the appearance of a three dimensional pattern in the coating.
Some anti-counterfeiting devices are covert, while others are intended to be noticed. Unfortunately, some optically variable devices that are intended to be noticed are not widely known because the optically variable aspect of the device is not sufficiently dramatic. For example, the color shift of an image printed with color-shifting pigments might not be noticed under uniform fluorescent ceiling lights, but is more noticeable in direct sunlight or under single-point illumination. This can make it easier for a counterfeiter to pass counterfeit notes without the optically variable feature because the recipient might not be aware of the optically variable feature, or because the counterfeit note might look substantially similar to the authentic note under certain conditions.
Accordingly, there is a need to mitigate the disadvantages of existing optical security devices. It is an object of the present invention to provide highly noticeable security devices where illusive optical effects are produced by magnetically aligned pigments, and which may be formed within high speed printing processes.
An article includes a substrate and a coating which contains pigment flakes in a binder and is supported by the substrate. Each of the pigment flakes includes a magnetic or magnetizable material for magnetic alignment of the pigment flakes, and the pigment flakes are aligned so as to form an aligned pattern wherein a portion of the pigment flakes have their substantially planar major surfaces parallel to the substrate along a continuous imaginary line on a surface of the substrate between first and second points thereof, and the pigment flakes form curved patterns in a plurality of cross-sections normal the continuous imaginary line so that radii of the curved patterns increase along the imaginary line from the first point to the second point. When light is incident upon the pigment flakes from a light source, light reflected from the aligned pattern forms a bright image which appears to gradually change its shape and move from one side of the continuous imaginary line to another side of the continuous imaginary line when the substrate is tilted with respect to the light source.
In one aspect of the invention, the article includes an image printed with a non-magnetic ink, under the coating comprising pigment flakes as described above. The radii of the curved patterns initially increase and then decrease along the continuous imaginary line, so that the bright image moves from one side to another side of the image.
In another aspect of the invention, an article includes a substrate and a coating which contains pigment flakes in a binder and is supported by the substrate. Each of the pigment flakes includes a magnetic or magnetizable material for magnetic alignment of the pigment flakes, and the pigment flakes are aligned so as to form an aligned pattern wherein a portion of the pigment flakes have their substantially planar major surfaces parallel to the substrate along a continuous imaginary line on a surface of the substrate between first and second points thereof, and the pigment flakes form curved patterns in a plurality of cross-sections normal the continuous imaginary line, and wherein the continuous imaginary line is a zigzag or wavy line between the first and second points. When light is incident upon the pigment flakes from a light source, light reflected from the image region forms a bright zigzag or wave which appears to move when the substrate is tilted with respect to the light source.
The invention will be described in greater detail with reference to the accompanying drawings which represent preferred embodiments thereof, wherein:
A previously unknown effect has been discovered by the inventors in their search for new printed devices which would provide highly noticeable dynamic optical effects. It has been found that a square magnet magnetized through its diagonal may align magnetically alignable pigment flakes to produce a “boomerang” optical effect visible to a naked human eye and illustrated in
With reference to
When an ink or paint containing magnetically alignable flakes is applied to a surface of a substrate, and the flakes are aligned using the magnet shown in
In general, in cross-sections normal to a continuous imaginary line 130 between points A and B, the magnetically alignable flakes form a curved patterns wherein radii of the curved patterns increase along the imaginary line when moving from A to B, wherein a radius of a curved pattern formed by flakes in a cross-section of a coating is understood as an average radius of a curve formed by head-to-tail connection of the flakes. Preferably, the radii of the curved patterns decrease further along the imaginary line, i.e. beyond the point B (
The concentration of the magnetically alignable flakes in the ink or paint may be between 4 and 25% by weight, preferably between 4 and 14 wt % so that the underlying graphical pattern or solid background is visible in the regions adjacent to the bright image, i.e. to minimize shading outside of the bright image. It has been found that, counter intuitively, bright dynamic images printed with a diluted ink have better defined shapes and are more distinct from the background than frames printed with high-concentration inks. Apparently, a diluted magnetic ink allows removal of unwanted effects and shadows. In particular, the background overprinted with a low-concentration magnetic ink is visible through the magnetic ink practically everywhere, with the exception of a region where the magnetically alignable flakes are aligned in a predetermined manner so as to focus reflected light to form a bright image.
For focusing, or concentrating the reflected light, the magnetic reflective flakes are aligned in a curved pattern such that a cross-section of the pattern includes flakes aligned parallel to the substrate in the central part of the pattern defined by the imaginary line 130, and also includes flakes tilted so that the angles between the flakes and the substrate gradually increases in the direction from the imaginary line 130 to the outer edge of the pattern. The flakes may be thought of as forming a Fresnel reflector which focuses reflected light into a bright image visible to an observer. It turned out that the diluted ink with the concentration in the range of between 4 and 14 wt % provides an adequately noticeable image formed by the focusing pattern of aligned reflective flakes.
The continuous imaginary line 130 on the surface of the substrate is defined by the underlying magnet and is orthogonal to the magnetic lines on the surface of the magnet used for aligning the flakes. A portion of the magnetically alignable flakes which are directly above the continuous imaginary line 130 are parallel to the substrate along the segments AB and BC.
In order for the boomerang optical effect to be visible to a naked human eye, the pattern of the pigment flakes should have a sufficient size. For example, the width of the curved pattern in the maximal cross-section 200 between the two points with the 80 degrees tilt is preferably within the range of from 8 to 25 mm.
Optionally, the article includes at least a background printed or painted so at to provide a coating containing non-magnetic pigments, so that the bright image would appear to move relative to the background. Preferably, the underlying non-magnetic coating provides an image and the radii of the curved patterns initially increase and then decrease along the continuous imaginary line, so that the bright image moves from one side to another side of the image as shown in
In the particular example discussed above, the curved patterns formed by the flakes in the cross-sections of the coating are convex patterns; however, other magnetic arrangements or printing techniques may result in concave patterns. By way of example, the magnetic ink or paint may be provided onto a transparent plastic support; the magnetically aligned flakes may be aligned with the magnet shown in
Additionally, a variety of magnets may be used in place of the square magnet, including magnets with a planar surface (e.g. circle or diamond) parallel to the magnetic axis of the magnet. In case of a symmetric magnet or magnetic assembly, the imaginary line is a straight line with serves as an axis of symmetry for the moving image. In case of an asymmetric magnet, the imaginary line where the flakes are aligned parallel to the substrate is a curve.
A combination of several magnets, assembled together, allows producing more complicated optical effects based on the aforediscussed alignment of magnetically alignable flakes. With reference to
With reference to
The characteristic feature of reflective surfaces in
With reference to
The photographs in
With reference to
With reference to
The ink was cured with UV light completion of the alignment of the flakes. As a result, aligned magnetic flakes have formed a convex reflective surface. The diverter deflected the field around the edges of the square cut, differently aligning the flakes in the margins of the cut. With reference to
It has been shown above that a variety of magnets and magnetic assemblies may be used for producing a boomerang effect defined by an imaginary line on a surface of the substrate, wherein light incident upon magnetically alignable flakes from a light source, is reflected from the article to form a curved bright region which appears to gradually change its shape and move from one side of the imaginary line to another side of the imaginary line when the substrate is tilted with respect to the light source. The magnetically alignable flakes are aligned so as to form an image defined by the imaginary line so that, in each of a plurality of cross-sections normal the imaginary line between first and second points thereof, the magnetically alignable flakes form a concave or convex pattern wherein a radius of the concave or convex pattern increases along the imaginary line from the first point to the second point. Preferably, the radius decreases beyond the second point so as to form an entire boomerang which appear to be a bent bright contoured frame with a wider middle portion and tapered ends. However, by way of example, one can print magnetic ink over only the lower half (with respect to the drawing in
With reference to
The resulting image may be thought of as a zigzag or wavy rolling bar. When light is incident upon the magnetically alignable flakes from a light source, light reflected from the article forms a bright zigzag or wave which appears to move when the substrate is tilted with respect to the light source. The bright zigzag may include at least three sections. The flakes may be aligned so that in most, or at least in one of the plurality cross-sections, angles that the magnetically aligned flakes form with the substrate increase from zero at the imaginary line to 80 degrees on both sides of the imaginary line. In order for the dynamic zigzag or curve optical effect to be visible to a naked human eye, the aligned pattern of the pigment flakes should have a sufficient size. For example, the width of the curved pattern in the cross-sections between the two points with the 80 degrees tilt is preferably within the range of from 3 to 20 mm.
With reference to
A stack of thin flexible magnets allows making the rolling bar effect with many odd shapes of the same rolling bar radius. Furthermore, using flexible magnets in a variety of sizes, clamped and bended between brackets may result in a curved rolling bar wherein a radius of flake alignment changes along the curve defining the rolling bar.
The following comments and particular details relate to all the embodiments described herein.
The substrate may be a paper, plastic, or cardboard substrate, etc., and the resulting article may be a banknote, a credit card, or any other object thereto magnetically alignable flakes are applied as described herein.
In the embodiments where a magnetic ink is printed onto a plastic substrate (e.g. transparent polyester), the substrate may have a transparent hologram, bearing a symbol or a pattern, which may graphically match the pattern of the substrate. The hologram is preferably coated with a material with high index of refraction. Including a hologram provides an additional security feature to the device, because manufacturing of the device involves not only skills in security printing and magnetic alignment, but also skills in making of holograms.
The aforedescribed articles may be used as optical security devices, and may have two components: graphical and optical with optical component, possibly on the top of the graphical component, and be integrated into a banknote or a security label. The graphical component can include one of security patterns used in the document security industry and/or a picture or a symbol. The optical component can be made with color-shifting interference pigments or reflective metallic pigment flakes. The optical component enhances appearance of the graphical component. The optical component reflects light from a concave, convex, convexo-convex, or convexo-concave, etc. arrangement of magnetic pigments (flakes) dispersed in a binder and aligned along the lines of applied magnetic field. The binder is a light transmissive, preferably clear, UV-curable binder. The concentration of the particles in the binder is preferably in the range of 4 wt %-14 wt % so that the most of the coating containing magnetically alignable flakes is transparent and the underlying graphic component is visible. The low concentration coating provides a bright image, e.g. the boomerang or zigzag, only in the regions where the flakes are aligned in a curved pattern and may focus reflected light in a predetermined direction. The low concentration (4 wt %-14 wt %) of the flakes is useful to eliminate or at least minimize shadows of the bright boomerang, zigzag, or wavy image.
Both components may be printed using conventional techniques. Graphics and the optical effect produced by the optical component should complement each other. The optical component may be provided either on the top of the graphics or underneath of it. The optical component can be coated in patterns or can be coated as a continuous layer. The optical component can be in the form of a convex reflector (when the substrate printed with wet magnetic ink is placed on the top of the magnet) or concave reflector (when a thin transparent polymer sheet printed with wet magnetic ink is placed on the top of the magnet, flakes aligned in the field, ink cured and transparent sheet laminated with printed side to the graphical image) or a combination of concave and convex reflectors.
The graphical and optical components can be printed with pigments of the same color. Preferably, the optical effect generated by the optical component obscures only a small portion of entire region leaving the rest of the printed image available for observation.
Magnetically alignable pigment flakes may be formed of one or more thin film layers, including a layer of magnetic or magnetizable material such as Nickel, Cobalt, and their alloys so as to enable magnetic alignment of the flakes while in a liquid binder under the influence of a magnetic field. Such flakes are referred to sometimes as magnetic flakes which is understood to include magnetizable pigment flakes. The magnetic layer may be hidden between two reflector layers, preferably made of Aluminum. Additionally, a dielectric layer may be provided on each reflector layer, and an absorber layer—on each dielectric layer, thus forming color-shifting flakes. By way of example, the pigment flakes have the reflector/magnetic/reflector structure, or the absorber/dielectric/reflector/magnetic/reflector/dielectric/absorber structure, wherein the absorber layers are preferably Cr layers, the dielectric layers are preferably MgF2 layers, and the reflector layers are preferably Al layers; of course, other materials may be used as known in the art. Various thin-film flakes and methods of their manufacturing are disclosed e.g. in U.S. Pat. Nos. 5,571,624, 4,838,648, 7,258,915, 6,838,166, 6,586,098, 6,815,065, 6,376,018, 7,550,197, 4,705,356 incorporated herein by reference. The magnetically alignable flakes are essentially planar, however may include symbols or gratings. The flakes have a thickness of between 50 nm and 2,000 nm, and a length of between 2 microns and 200 microns. The flakes may have an irregular shape. Alternatively, shaped flakes such as square, hexagonal, or other selectively-shaped flakes may be used to promote coverage and enhanced optical performance.
Preferably, the magnetically alignable flakes are highly reflective flakes having at least 50%, and preferably 70%, reflectivity in the visible spectrum.
The pigment flakes are conventionally manufactured using a layered thin film structure formed on a flexible web, also referred to as a deposition substrate. The various layers are deposited on the web by methods well known in the art of forming thin coating structures, such as Physical and Chemical vapor deposition and the like. The thin film structure is then removed from the web material and broken into thin film flakes, which can be added to a polymeric medium such as various pigment vehicles (binders) for use as ink, paint, or lacquer which are collectively referred herein as “ink,” and may be provided to a surface of a substrate by any conventional process referred herein as “printing.” The binder is preferably a clear binder, but may be tinted with a low amount or conventional dye, and may include a low amount of admixtures, e.g. taggant non-magnetic flakes having a symbol thereon.
Within the ink or paint, the magnetically alignable flakes may be oriented with application of a magnetic field produced by one or more permanent magnets or electromagnets. Advantageously, the magnetic alignment of the flakes as described in this application may be performed as part of a high-speed printing process, wherein a substrate with a printed or painted image moves at a speed of from 20 ft/min to 300 ft/min on a support, e.g. a belt or a plate, in proximity of a magnetic assembly, one described above. The magnetic assembly may be placed under the support, or embedded into a roller used in a rotational printing apparatus. Generally, the flakes tend to align along the magnetic lines of the applied field while the ink is still wet. Preferably, the ink is solidified when the printed image is still in the magnetic field. Various methods of aligning magnetically alignable flakes are disclosed e.g. in U.S. Pat. No. 7,047,883 and U.S. Patent Application No. 20060198998, now U.S. Pat. No. 8,343,615 both incorporated herein by reference.
In general, in the concave and convex patterns of reflective flakes, a cross-section of the pattern includes flakes aligned parallel to the substrate in the central part of the pattern, and tilted flakes with the angle between the flakes and the substrate gradually increasing in the direction from the center to the outer edge of the pattern. Preferably, flakes at the outer edges of the pattern are oriented almost normally, at least at 80 degrees, and preferably at 85 degrees to the substrate, so as to reduce shadows of the dynamic image by minimizing the disadvantageous “shallowing” effect. For clarity, an angle between a flake and a substrate is understood as an angle between a first plane parallel to the flake and a second plane parallel to the substrate.
Advantageously, a bright boomerang which gradually flips from one side to another side of an image, a bright rolling zigzag or wave may be used as security features as well as decorative elements.
The incorporation of sheet metal between the top of the magnet and the bottom of printed substrate with the layer of wet ink containing magnetic flakes allows tuning of the field direction and its magnetic flux magnitude. Magnetic fields can be re-routed around objects. By surrounding an object with a material which can “conduct” magnetic flux better than the materials around it, the magnetic field will tend to flow along this material and avoid the objects inside.
When ferromagnetic sheet or plate is placed into a magnetic field, it draws the field into itself providing a path for the magnetic field lines through it. The field on the other side of the plate is almost nil because the plate has diverted the field causing a lot of it to flow within the plate itself instead of in the air.
Magnetic properties of metals define how these metals divert magnetic field when they in the sheet form are placed in the field. Metals or alloys with high magnetic permeability are usually used got this purpose. Mu-metal or permalloy are broadly used for shielding purposes; they typically have relative permeability values of 80,000-100,000 compared to several thousand for ordinary steel.
Mu-metal and permalloy also have very low saturation, the state where an increase in magnetizing force produces no further increase in magnetic induction in a magnetic material. So while it is extremely good as a conduit for very weak fields, it is essentially not much better than air when it comes to very strong magnetic fields. The field is diverted toward the magnetic pole located in the center of their print with magnetic ink reducing radius of magnetically aligned ring that looked as if the field was focused. However, the reality is that such shielding of the field almost twice reduces its flux magnitude.
As demonstrated in the pictures, the Mumetal sheet dissipates the field along its volume. The steel sheet, having a lower permeability, attracts a lot of field near the magnet.
The distance between the magnet and the sheet has also effect the field propagation through the metal and the field magnitude above the shield. A good demonstration of it can be seen in cartoons at http://www.coolmagnetman.com/motion10.htm.
The purpose of the diverters was in the deflection of the field in a predetermined direction from its original to change alignment of particles in predictable way.
Two materials have been used as diverters in two different methods of alignment. They were Mumetal sheets and cold rolled steel sheets (cold rolling makes sheets with a larger grain size that improves magnetic permeability). The thickness of the sheets varied in the range from 0.004″ to 0.1″.
Mumetal sheets, used in the first method, have been selected with the thickness that allowed the field penetrated up through the sheet. The diverters had a cut in the middle of it. The cuts had different shapes for different magnets. The field curved around the edges of the cut correspondingly aligning magnetic pigment in addition to the flakes aligned in the field penetrated through the magnets as illustrated in
For more unusual optical effects, the diverters were cut in different pieces and put on the top of the magnet to drive the field around the edges allowing it also penetrate through the plane of the diverter. Examples of such effects with corresponding magnets are demonstrated in
The optical effect in
Magnetic assembly schematically illustrated in
The magnetic assembly in
The second method included steel diverters completely blocking magnetic field.
These diverters, also cut in pieced and put in particular places on the top of the magnet, blocked the field in these places and allowed the field to emerge from non-blocked places.
The same assembly as shown in
The thickness and material selection for a diverter depend on the strength of the magnet and its configuration. For example, neodymium boron iron sintered magnets are very strong. Placing thick steel plate on the top of the magnet in
The present invention is a Division of U.S. patent application Ser. No. 16/224,575, filed Dec. 18, 2018, now U.S. Pat. No. 10,562,333, issued Feb. 18, 2020, which is a Continuation of U.S. patent application Ser. No. 14/797,864, filed Jul. 13, 2015, now U.S. Pat. No. 10,232,660, issued Mar. 19, 2019, which is a Divisional of U.S. patent application Ser. No. 13/737,811 filed Jan. 9, 2013, now U.S. Pat. No. 9,102,195, issued Aug. 11, 2015, which claims priority from U.S. Provisional Patent Application No. 61/585,954 filed Jan. 12, 2012, the disclosures of which are hereby incorporated by reference in their entireties.
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