ES2443046T5 - A two-stage method for coating an article for secure printing - Google Patents

Description

5

10

fifteen

twenty

25

30

35

40

Four. Five

fifty

55

DESCRIPTION

A two-stage method for coating an article for secure printing Field of the invention

The present invention relates generally to a two-stage method for preparing a printed image with security and more particularly, to a method for forming the image by coating the surface of the substrate with an ink containing flake material that can be align and expose the coated surface to a magnetic or electric field in order to align at least a portion of the flaked material, and subsequently coat the substrate with a second printed image above or below the first image.

Background of the invention

The present invention relates to coating a substrate with an ink or paint or other similar means to form an image that has optically illusory effects. Many surfaces painted or printed with particles similar to flat platelets show greater reflectance and brighter colors than surfaces coated with a paint or ink containing conventional pigments. Painted or printed substrates with pigments in scales that shift color show color changes when viewed from different angles. Flake pigments may contain a material that is magnetically sensitive, so that they can be aligned or oriented in an applied magnetic field. Said particles can be prepared from a combination of magnetic and non-magnetic materials and mixed with a paint or ink vehicle in the production of magnetic paints or inks. A feature of these products is the ability of the scales to become oriented along the lines of an applied field within the paint or liquid ink layer while remaining basically in this position after drying or curing of the paint or ink vehicle. The relative orientation of the scale and its main dimension with respect to the coated surface determines the level of reflectance or its direction and / or can determine the chroma of the paint or ink. Alternatively, the dielectric material can be aligned in an electric field.

The alignment of magnetic particles along applied magnetic field lines has been known for centuries and is described in basic physics textbooks. This description is found in a book by Halliday, Resnick, Walker, with the title, Fundamentals of physics. Sixth Edition, page 662. It is also known how to align dielectric particles in an electric field, and this form of alignment can be applied to the present invention.

US Patent No. 3,371,854 in the name of Steingroever describes that an effect of geometric figures can be produced in coatings applied to any surface by using a preliminary coating that includes a liquid vehicle in which particles of particles are suspended. permanent magnets; the coating being applied and then hardened, after which the particles are magnetized under the influence of magnetic lines of force placed in a predetermined model, and another coating containing magnetically orientable particles is applied, whose particles become oriented by the product of the magnetic field with the particles applied first.

U.S. Patent No. 3,853,676 in the name of Graves et al. describes the painting of a substrate with a film comprising material that forms films and magnetically orientable pigment that is oriented in curved configurations and located in the vicinity of the film, and that can be seen with the naked eye to provide awareness to the viewer of the location of the movie.

US Patent No. 5,079,058 to Tomiyama discloses a film with geometric figures forming a laminated sheet comprising a multilayer structure prepared by successively laminating a separable sheet layer, a pressure sensitive adhesive layer, a base sheet layer, and a sheet layer with geometric figures, or additionally lamination of a pigmented printing layer. The film layer with geometric figures is prepared by a process comprising coating a fluid coating composition containing a magnetic powder material on a face of the base sheet layer to form a fluid film, and acting a magnetic force on the Magnetic powder material contained in the fluid film, in a fluid state, to form a geometric figure.

US Patent No. 5,364,689 in the name of Kashiwagi discloses a method and apparatus for producing a product having a magnetically formed geometric figure. The magnetically formed geometric figure becomes visible on the surface of the painted product while the light rays incident on the paint layer are reflected or absorbed differently with magnetic particles placed in a way that corresponds to that of the figure desired geometric. More particularly, Kashiwagi describes how various geometric figures, caused by the magnetic alignment of nickel scales, can be formed on the surface of a wheel cover.

U.S. Patent No. 6,808,806 to Phillips in the name of Flex Products Inc. discloses methods and devices for producing images on coated articles. The methods generally include the application of ES 2 443 046 T3 3 a layer of magnetizable pigment coating in liquid form on a substrate, magnetizable pigment coating containing a plurality of particles or scales

5

10

fifteen

twenty

25

30

35

40

Four. Five

fifty

55

non spherical magnetic Subsequently, a magnetic field is applied to selected regions of the pigment coating while the coating is in liquid form, with the magnetic field altering the orientation of the selected magnetic particles or scales. Finally, the pigment coating solidifies, fixing the reoriented particles or scales in a position not parallel to the surface of the pigment coating to produce an image such as a three-dimensional image on the surface of the coating. The pigment coating may contain various particles or magnetic interference or non-interference scales, such as magnetic color displacement pigments.

US Patent No. 6,103,361 discloses substrates with geometric figures useful in the production of decorative kitchen utensils formed by coating a base with a mixture of fluoropolymer and magnetic flakes that magnetically induce an image in the coating composition of polymer. The baked fluoropolymer release coating contains magnetizable scales. A part of the scales 15 are oriented in the plane of the substrate and a part of said scales are magnetically reoriented to form a geometric figure in the coating that is observed in the reflected light, the scales having a longer dimension that is larger than the thickness of said coating. The substrate with geometric figures is formed by applying magnetic force through the edges of a magnetizable die placed under a coated base to induce an effect or pattern of imaging.

A common feature of the prior art references mentioned above is a formation of different types of geometric figures in a painted or printed layer. Most geometric figures exist in the form of signs such as symbols, shapes, signs, or letters; and these geometric figures reproduce the shape of a magnet often placed below the substrate and are formed with the shading contour lines that appear in the paint or ink layer resulting in particular alignments of magnetic scales. The desired geometric figure becomes visible on the surface of the painted product as the light rays incident on the paint layer are reflected or absorbed differently by the subgroup of non-spherical magnetic particles.

Although these prior art references provide some useful and interesting optical effects, there is a need for geometric figures that have a higher degree of optical illusiveness, and that are more difficult to falsify. U.S. patent application No. 20050106367, filed on December 22, 2004, on behalf of Raksha et al. Titled "Method and Apparatus for Orienting Magnetic Flakes" describes several interesting embodiments that provide optical illusiveness, such as "rolling-bar" and "flip-flop" that can serve as the basis for the embodiments of this invention. However, there is a need to provide different geometric figures on a single substrate where two coatings provide images that appear to move independently of each other while the direction of light changes or while the image rotates or tilts.

It is an object of this invention to provide a more complex image having at least two distinct characteristics where each characteristic is realized in a separately applied coating.

It is an object of this invention to provide a more complex image that has at least two distinct characteristics where each characteristic is realized in a separate coating and where the at least two coatings provide the appearance of two images that move synergistically together even looking different. each other while the image moves in one direction.

Invention Statement

In accordance with one aspect of the invention, a method of coating an article comprising the steps of:

apply a first magnetic coating to a substrate using a magnetic or electric field to orient scales within the coating along the magnetic field lines; and, after the first coating has cured, subsequently apply a second magnetic coating on the first coating and use a magnetic or electric field to orient the scales within the second coating along the magnetic field lines.

In accordance with one aspect of the invention, a method of coating an article comprising the steps of:

apply a first magnetic coating to a substrate;

use a magnetic field to orient the scales within the coating depending on the magnetic field lines; Y,

after the first coating has cured, subsequently apply a second magnetic coating on the first coating and use a second magnetic field to orient the scales within the second coating depending on the second magnetic field; and allow the second magnetic coating to cure.

5

10

fifteen

twenty

25

30

35

40

Four. Five

In accordance with another aspect of the invention, an image formed by magnetic particles aligned by a magnetic field is provided, where two distinct elements within the image appear to be moving simultaneously, and where the movement is relative movement, when the image moves or when the light source on the image moves.

According to another aspect of the invention, an image formed by magnetic particles is provided where two distinct elements within the image appear to be moving, where one is stationary while the other moves, and vice versa, when the image moves in two different directions or when the light source on the image moves in two different directions.

In a broad aspect of the present invention, a method is provided for providing an optically illusory image comprising the steps of applying a pigment having scales that can be magnetically aligned thereon above or below an already formed image, and magnetically align the scales that can be magnetically aligned within the pigment and allow the scales to heal.

It should be understood, apart from the broad aspects of the present invention, which have been mentioned above, that scales that can be magnetically aligned are preferably used, and a magnetic field is provided to align scales that can be magnetically aligned; however, other forces are fields that can align a plurality of scales at the same time, in a predetermined orientation, and are also within the scope of the present application.

Indicated more broadly, the present invention provides a method for forming an image by application of a first coating of optical effect to a first face of the substrate and using a magnetic or electric field to orient the scales within the coating depending on the field; Y,

apply a second coating of optical effect on the first coating or on the second face of the substrate, where the effects of both coatings, or the combined effects from at least one face of the substrate can be observed.

In an alternative embodiment of the invention, the first and second coatings include diffractive scales, which have a geometric surface relief figure formed thereon or on them, and the scales in the first coating are oriented along their geometric figure. of surface relief with an orientation different from that of the diffractive scales in the second coating.

According to one aspect of the invention, a method of coating an article according to claim 1 is provided.

According to another aspect of the invention, a method of creating an image according to claim 7 is provided.

In accordance with another aspect of the invention, an image according to claim 9 is provided.

According to another aspect of the invention, a substrate is provided that supports an image according to claim 10.

Brief description of the drawings

Exemplary embodiments of the invention will be described below in accordance with the drawings in which:

Figure 1 is a drawing of a gemstone that shows asterism caused by small rutile needles (titanium oxide) that have six rays.

Figures 2a to 2d represent the stages of preparing an image that has two cross-rotating bars that appear to move with a change in the viewing angle.

Figures 3a to 3d show a series of stages and images that form a final image in Figure 3d where a balloon having a text therein provides an optical flip-flop effect.

Figures 4a to 4d represent the stages of the preparation of a flip-flop and a rotating bar created in the same substrate.

Figures 5a to 5d illustrate the stages in several printing images of two rotating bars that seem to move closer to each other to form a single rotating bar and that the vascular image seems to be separated into two rotating bars.

Figures 6a and 6b illustrate a container with the rotating rod element of Figure 5d.

5

10

fifteen

twenty

25

30

35

40

Four. Five

fifty

55

The photomicrographs of Figures 7a and 7b show an area of an image obtained with a two-stage printing process, where the two photographs correspond to the same area of the image.

Detailed description

The orientation of magnetic scales scattered in a paint or ink vehicle along the lines of an applied magnetic field can produce a plurality of illusory optical effects. Many of these effects, which are described in other patents and patent applications assigned to Flex Products Inc., have a dynamic animation-like appearance similar to holographic kinograms or a tiger's eye effect on precious stones. When a graphic image, printed on the surface of a substrate in the presence of a magnetic field, tilts or bends with respect to the light source and the viewer, the illusory optical effect moves towards or outside the viewer, or towards the left or right.

However, according to the present invention it is possible to manufacture very different and more complex kinds of optical effects with two-stage printing or painting of an article with ink or magnetic paint containing magnetic particles, in the presence of different magnetic fields. In the first stage, the vehicle of ink or transparent or dyed paint, mixed with reflection or displacement of the color of diffractive pigment or any other platelet type magnetic pigment of a concentration (preferably 15-50% by weight), is Prints / paints on the surface of an item in any predetermined graphic geometric figure, is exposed to the magnetic field to form a predetermined optical effect, and is cured to fix the magnetic scales on the solid ink / paint vehicle layer. In the second stage, the lower concentration ink or paint (preferably in the range of 0.1-15% by weight) is printed on top of the first printed image 20, exposed to the magnetic field, and cured . The ink or paint vehicle for the second layer is preferably transparent, however it may be dyed. The magnetic pigments for the second printed / painted layer may be the same as for the first layer or they may be different. The pigment size for the second layer may be the same or different. The color of the pigment for the second layer may be the same or different as for the first layer. The shape and intensity of the field, applied to the second layer, may be the same or preferably may be different so that the viewer experiences two different effects. The graphic geometric figure for the second layer can be the same or different. The color combination of inks or pigments can increase or decrease a particular color in the final printed image.

In the printing process complex geometric figures of lines, dots, arcs and other shapes, augmented with optically illusory effects of the present invention can be used to make it difficult for counterfeiters to reproduce visually encrypted documents.

The substrate for two-stage printing according to the present invention may be transparent or opaque; This is usually determined with the graphics of the image and the desired optical effect. In the case where an opaque substrate is used, the first and second applied coating layers are printed or painted on the same face of the opaque substrate with the most transparent image applied as the second coating on the top of the first coating layer For transparent substrates, the application for the first and second coatings may be as described for opaque substrates, or alternatively and preferably, the first coating layer may be printed with an ink concentrated on a first face of the substrate and the second Coating layer can be printed with diluted ink on the opposite side of the substrate. For some purposes, the first coating layer may be a layer printed with diluted ink and the layer with concentrated ink may be printed the second. The observation of a final image can be done through the substrate.

A first example of an article printed in accordance with an embodiment of the present invention, with two cross-rotating bars produces an optical effect similar to asterism. US Patent Applications No. 2004/0051297, and No. 2005/0106367 in the name of Raksha et al, describe a single rotating bar and a method for preparing a rotating bar, where the effect is formed by a Convex or concave cylindrical reflection of light rays from magnetic particles dispersed in the ink or paint vehicle and line up in the magnetic field.

The asterism in the gemstones is caused by dense inclusions of tiny thin, parallel fibers in the mineral that make the light reflect a star-like, undulating formation of concentrated light that moves around when the mineral is rotated. Normally this is caused by small rutile needles (titanium oxide) in the case of ruby and sapphire as is done by way of example in Figure 1. Stars can have four, six, or more rays.

A flexographic printed image of a box with a four-star star, or two rotating bars, is shown in Figures 2c and 2d. The image in Figure 2a of a single rotating bar 202 is printed in a first stage with ink containing 25% by weight of a pigment that shifts the color from green to gold on the surface of transparent, translucent or opaque substrate and The convex rotating bar 202 is formed in applied magnetic field.

5

10

fifteen

twenty

25

30

35

40

Four. Five

fifty

55

60

The second image shown in Figure 2b is printed with an ink containing 10% by weight of the same green to gold pigment dispersed in a transparent ink vehicle (which makes it translucent) on the top of the first image 202 and the convex rotating bar 204 is formed in the field when its direction is at 90 ° with respect to the direction of the rotating bar 202 in the first printed image of Figure 2a. The resulting printed image of Figure 2c shows a four-ray star. The star moves to the bottom of the printed image shown in Figure 2d, when it is rotated or tilted horizontally with its highest edge away from the viewer, or to the top of the image if it was tilted toward the viewer. By tilting the image over and over again in the direction shown in Figure 2d, both rotating bars seem to move simultaneously towards and away from each other. By coating the substrate with two rotating bars in this manner, the functionality of each rotating bar to provide the perception of rotation through the sheet while rotating, is provided so that both bars appear to move synergistically. , in seemingly different directions even with a slight rotation in one direction. In this embodiment it is not necessary to bite or tilt the sheet in three different directions to see both bars moving. A single movement in one direction will provide perception of two bars that move differently.

Referring now to Figure 3a, an image of a balloon 301 is shown, which was printed by screen printing with a ribbon 30% thick by weight, which contained pigment of color shift from magenta to gold with the scores with an average size of 22 micrometers, and was exposed to a magnetic field to form the V-shaped flip-flop optical effect. The flip-flop effect is described in US Patent Applications No. 2004/0051297, and N ° 2005/0106367, in the man of Raksha et al. In this effect, the lower part below the equator line of the globe has a bright magenta color and the upper part has a dark golden color at a normal viewing angle . The magnetic scales in the lower part of the image obtain such orientation in an applied magnetic field; These scales send reflected directly towards the eye of the observer, which makes them appear bright. In contrast, particles in the upper part of the globe send light reflected in the direction of the observer's chest. The color of the scales, in this angle of observation and in this orientation of the particles in particular, is golden. When the balloon, printed on the substrate, tilts with its upper edge towards the observer, the scales at the bottom reflect the rays of light in the direction of the observer's hat, which makes them appear dark golden. Simultaneously, the scales on the top of the globe reflect the rays of light incident in the eye of the observer, which makes them visible as bright magenta. The inclination of the sample in the opposite direction again exchanges the colors of the image.

The second image 302 "Test Text" shown in Figure 3b is printed with 10% by weight of diluted ink on top of the balloon 301 and is exposed to another magnetic field that produces a roof-shaped orientation of magnetic particles An optical effect on the image, printed with these oriented particles, has an "exchange" of color opposite to the color changes of the first printed image. The pigment in the second ink is the same magenta to gold as in the first image but its size is close to 10 micrometers. The hue of this pigment has the same value as the largest 22 micrometer pigment but its chromaticity is less than the chromaticity of the largest pigment in the first layer that makes it slightly darker. At a normal viewing angle, the resulting image 303 in Figure 3c shows the light magenta "Text" translucent on a dark gold background and the translucent "Essay" dark gold on a background of the magenta globe sparkly. When the printed image 303 tilts 40 with its upper edge away from the observer, as shown in 304, two parts of the globe and the text exchange or "permute" their colors. The upper part of the globe is made of bright magenta color with translucent TEXT of dark golden color and the lower part of the globe is made of dark gold color with TEST of bright magenta color.

The "Text Essay" logo 401, shown in Figure 4a, was printed on top of image 402 containing a flip-flop element that has been described in the patents mentioned above. Image 402 was printed with a concentrated ink containing Al / M / Al magnetic pigment (in which Al is aluminum. M is any material that can be magnetically aligned). The flip flop can be formed with alignment of V-shaped or roof-shaped magnetic scales in organic solid media. At the normal viewing angle 50 and in the V-shaped alignment of the particles in the resin, the lower part 403 of the image 402 is bright and the upper part 404 is dark. A second image 405 was printed on top of image 402. In Figure 4b, image 405 was printed with diluted ink, containing 5% by weight of gold-colored magnetic non-displacement pigment, and placed in the field to form a rotating rod optical element. The rotating bar 406 is formed near the top of the image. The ink was cured after finishing the alignment of the particles. The flip flop and the text are very visible through the top lining layer in the double printed image 407 in Figure 4d at a normal viewing angle.

However, at the inclination of the printed image with its upper edge away from the observer, the rotating bar rotates the printed image 407 and occupies a place in the middle part 408 of the box that conceals the logo 401 and the flip flop such as shown in Figure 4d. An image 501, shown in Figure 4a, was an image printed by flexography on a transparent substrate 500 with the ink containing 20% by weight magnetic pigment, placed in the field to form the optical effect of convex rotating bar 502 and cured to fix the magnetic particles aligned. Flexography or flexographic printing is a machine printing process that uses rollers or cylinders with a flexible rubber type surface that prints with the raised area, at 65

5

10

fifteen

twenty

25

30

35

40

same as the printing surface, but with much less ink. In this process, the ink dries quickly and allows the machine to run at high speed. The finished product has a very smooth finish with well-defined details and that often resembles rotary screen printing.

In Figure 5b, another image 503 is printed with diluted ink, placed in the field to form the concave rotating bar 504 and cured to fix the particles in this position. The final impression 505 shows at a normal angle of observation an image with the effect of individual rotating bar 506. When the sample is inclined with its upper edge than away from the observer, the individual rotating bar 506 is divided into two rotating bars 507 and 508 that move in the opposite direction. The inverted inclination of the image for the normal angle makes the rotating bars 507 and 508 together produce a single optical effect. Both printed images can have the same shape, as shown in Figure 5d, or they can have different shapes.

Referring now to Figures 6a and 6b, a very attractive image for manufacturing security labels on curved surfaces is shown. Bottles for packaging pharmaceutical products, shown in Figures 6a and 6b, are a good example of the use of rotating rotating bars. Bottle 601 has a label 602 attached to its surface. The safety element 603 with the dividing rotating bar described in the previous example is printed on the upper part of the label 602. The element 603 has a single rotating bar 604 at the normal viewing angle. The bottle has a wide line 605 created by reflection of the incident light from a cylindrical surface of the bottle. However, the rotating bar 604, which also resembles a cylindrical surface that reflects, is 90 ° with respect to line 605. The inclination of the bottle 601 with its upper part away from the observer produces a division of the bar that rotate 604 on two bars that rotate 606 and 607. 20 When the bottle tilts back, the bars that rotate 606 and 607 collapse on the individual bar that rotates 604 again.

Turning now to Figures 7a and 7b, the photomicrograph 7a shows the groove orientation of the pigments of a first applied layer of diffractive particles in a vehicle using a magnetic field oriented from top to bottom (or vice versa). After curing the first printed layer, a second print on the top of the first was applied with a magnetic field oriented from left to right (or vice versa). The camera used to capture the photomicrograph in Figure 7b was centered to show the second groove orientation of the microstructured particles. Note that the load of the second coating is less than the load of the first.

In addition, it should be understood that in the figures and in the embodiments shown below, scales oriented towards the groove may be used instead together with other types of scales that have been described so far.

Although the embodiments described so far, represent the application of two-stage coatings to the same or different face of a substrate, less preferably, but still within the scope of the present invention, is the use of a first scale coating. which can be aligned on a first substrate, laminated to a substrate that has a printed image or an image recorded on it similar or different. For example, in a first stage, a rotating bar can be printed on a first substrate, which can be subsequently laminated to a holographic image, where one of the substrates is basically a light transmitter.

In another less preferred embodiment of the present invention, two coatings are applied to different faces of a substrate, where a second of the coatings has a viscosity that changes when energy such as light of a predetermined wavelength is applied and the coating becomes fluid. The first coating is a conventional coating that can be magnetized and aligned after being applied. After the first coating is cured and the scales are permanently aligned, the second coating can be made fluid enough to align the scales, and then cure it.

Claims (11)

5 10 fifteen twenty 25 30 35 40 Four. Five 1. A method for coating an article comprising the steps of: applying a first orientable coating with a field comprising magnetic pigment scales at a first concentration to a first face of a substrate and using a magnetic or electric field to orient scales within the coating along the lines of the magnetic field; and after the first coating has cured, subsequently apply a second magnetic coating comprising magnetic pigment scales at a second concentration on the first coating or on the second face of the substrate and use a magnetic or electric field to orient the scales within the second coating along the magnetic field lines, where the second concentration is different from the first concentration. 2. A method as defined in claim 1, wherein the magnetic field to orient the scales within the first magnetic coating is a first magnetic field and where the first magnetic field is used to orient scales within the second coating. 3. A method as defined in claim 1, wherein the magnetic field to orient the scales within the first magnetic coating is a first magnetic field and where the magnetic field used to orient scales within the second coating is a second magnetic field. 4. A method as defined in claim 1, wherein the first magnetic field and the second magnetic field are generated with different magnets or with different magnet generation systems. 5. A method as defined in claim 1, wherein a two-stage manufacturing process is used. 6. A method as defined in claim 1, wherein one of the first and second coatings includes multilayer optically variable scales and wherein the other of the coatings includes diffractive scales, wherein at least a part of the diffractive scales has a figure geometric surface relief formed on it. 7. A method as defined in claim 5, wherein the first and second coatings include diffractive scales, which have a geometric surface relief figure formed thereon and thereon, and wherein the scales in the first coating they are oriented along their geometric surface relief figure with a different orientation to that of the diffractive scales in the second coating. 8. A method to create an image that comprises the stages of: applying a first coating containing magnetic pigment scales at a first concentration on a first face of a substrate; provide a magnetic field to align the scales within the first coating in a predetermined manner; allow the first coating to cure or dry; Y, applying a second coating containing magnetic pigment flakes at a second concentration different from the first concentration on the first coating or on a second face of the substrate and, provide a magnetic field before the second coating cures or dries in order to align the scales within the second coating. 9. An image that has a first optical element that changes its appearance with a change in the angle of view or with a change in the light that affects the image; and that it has a second optical element, independent of the first optical element that changes its appearance with a change in the viewing angle or with a change in the light that affects the image, where the first element includes a first coating of scales magnetically aligned at a first concentration, and where the second element includes a second coating of magnetically aligned scales on the first coating at a second concentration with a different orientation than the scales of the first coating, where the second concentration is different from the first concentration, 10 fifteen so that the viewer simultaneously experiences two different effects independent of the first element and the second element, when the first element and the second element are displayed, respectively. 10. A substrate that supports an image formed by: a first coating of optical scales aligned at a first concentration that provide a change in color, reflectance or diffraction with a change in viewing angle, where the substrate additionally supports a second coating having optically distinguishable elements thereon, the first and second coatings being visible from at least one face of the substrate, and where the characteristics of the second coating can be distinguished from a characteristic made in the first coating and where the second coating is a coating applied separately from optical scales aligned at a second concentration different from the first concentration. 11. A substrate as defined in claim 10, wherein each of the first and second coatings forms a different image, wherein each different image is formed with magnetically aligned optical scales