PT2165774E - Method for orienting magnetic flakes - Google Patents

Description

1

DESCRIPTION

" MAGNETIC FLOW ORIENTATION METHOD " BACKGROUND OF THE INVENTION

This invention relates generally to optically variable pigments, films, devices and images, and more particularly to the alignment and orientation of magnetic flakes, such as during a painting or printing process, to obtain an illusory optical effect .

Optically variable devices are used in a wide variety of applications, both decorative and utilitarian. Optically variable devices may be made in a variety of ways to achieve a variety of effects. Examples of optically variable devices include holograms printed on credit cards and authentic software documentation, color-changing images printed on banknotes, and improve the surface appearance of items such as helmets and wheel covers for motorcycles.

The optically variable devices may be made as a film or sheet which is pressed, stamped, glued or otherwise secured to an object, and may also be made using optically variable pigments. An optically variable type of pigment is commonly referred to as a color changing pigment because the apparent color of the appropriately printed images with such pigments changes as the viewing angle and / or the illumination is inclined. A common example is " 20 " printed with color-changing pigment in the lower right corner of a twenty US dollar bill, which serves as an anti-counterfeit device.

Some anti-counterfeit devices are hidden, while others are meant to be noticed. Unfortunately, some optically variable devices, which are intended to be noticed are not widely known, because the optically variable aspect of the device is not dramatic enough. For example, changing the color of a printed image with color-changing pigment may not be noticeable under uniform fluorescent ceiling lights, but may be more noticeable in direct sunlight or under single-point illumination. This may make it easier for a counterfeiter to pass fake notes without the optically variable element because the recipient may not be aware of the optically variable element, or because the fake note may appear substantially similar to the authentic note under certain conditions.

Optically variable devices may also be made with magnetic pigments which are aligned with a magnetic field after application of the pigment (usually in a vehicle such as an ink vehicle) to a surface. However, painting with magnetic pigments has been used mainly for decorative purposes. For example, the use of magnetic pigments for the production of painted cover wheels with a decorative feature which appears as a three-dimensional shape has been described. A pattern was formed on the product painted by applying a magnetic field to the product while the ink medium was still in the liquid state. The ink medium had dispersed non-spherical magnetic particles that aligned along the lines of the magnetic field. The field had two regions. The first region contained magnetic force lines which were oriented parallel to the surface and arranged in the shape of a desired pattern. The second region contained lines that were non-parallel to the surface of the painted product and arranged around the pattern. To form the pattern, magnets 3 or permanent electromagnets having the shape corresponding to the shape of the desired pattern were placed beneath the painted product to orient in the magnetic field the non-spherical magnetic particles dispersed in the paint while the paint was still wet. When the paint dries, the pattern becomes visible on the surface of the painted product as the light rays incident on the paint layer are influenced differently by the oriented magnetic particles.

In a similar manner, there has been described a process for producing a pattern of flake magnetic particles in the fluoropolymer matrix. After coating a product with a composition in liquid form, a magnet of a desirable shape was placed on the underside of the substrate. Magnetic flakes dispersed in a liquid organic medium orient themselves parallel to the lines of the magnetic field, inclining in relation to the initial planar orientation. This slope ranged from perpendicular to the surface of a substrate to the original orientation, which includes flakes essentially parallel to the surface of the product. The flakes oriented in the planar direction reflected the incident light back to the viewer while the reorientated flakes did not reflect, providing the appearance of a three-dimensional pattern in the coating.

Although these approaches describe methods and apparatus for imaging which are similar to three-dimensional images in layers of paint, they are not suitable for high-speed printing processes because they are essentially discontinuous processes. It is desirable to provide methods and apparatus for high speed in-line printing and painting that reorient the magnetic pigment flakes. In addition, it is desirable to create more notable optically variable security features in financial documents and other products. The post-published WO 02/090002 A2 discloses multilayer magnetic flakes which may be oriented using an magnet disposed adjacent a substrate, for example, a magnet in the shape of a letter. In some examples of this document, adjacent portions of the magnet appear black when viewed at a 90 degree viewing angle. EP 0 556 449 AI discloses the formation of patterns by placing magnets adjacent to substrates covered with an ink layer containing non-spherical magnetic particles, causing an alignment of the particles according to a magnetic field caused by the magnet. Some portions of the aligned particles may resemble the shape of an arc. With the method disclosed herein, characters may be formed which appear in white, while the surrounding area appears in black. US 3,853,676 A discloses the arrangement of magnetic pigments in a curved shape near reference points in close proximity to a film using curved magnetic fields to create an illusion of depth. US 6,103,361 A discloses the orientation of magnetic flakes in such a way that in a first part and a second part they are essentially parallel to a substrate, and between the first and second parts, the flakes are perpendicular to the substrate. To guide the flakes, one can use magnetizable inks. GB 1,131,038 A discloses the production of a particle pattern in a polytetrafluoroethylene matrix using magnets to create an illusion of depth. The particles may be oriented inclined to the substrate in this manner. For example, an iman may be used in the form of a star. US 2,570,856 A discloses a method in which a film containing magnetic particles is subjected to a magnetic field, for example, rotated in a magnetic field. After hardening, the film can be removed from the magnetic field. GB 1,107,395 A discloses devices and methods for printing characters on a sheet using ink containing magnetizable particles and using magnets to move ink containing particles onto the sheet. Some of the magnets used may be provided on a roll. WO 88/07214 A discloses the orientation of preferably spherical particles, preferably a hemisphere of which is coated by light reflecting material having electrical or magnetic properties. The particles may be set in a desired orientation with respect to a substrate using a magnetic or electric field, for example, such that the light reflecting material is facing the substrate, in a continuous process in which the substrate moves along a magnetic device. The magnetic device may include a series of permanent magnet rods that are disposed in the lengthwise direction and extend transversely to the substrate. EP 0 325 237 A2 discloses a method and apparatus for producing a magnetic recording medium in which a substrate moves in a direction of field lines of a magnetic field.

SUMMARY OF THE INVENTION The present invention provides a method as defined in claim 1.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. IA is a simplified cross-section of a printed image, which will be referred to as a " flip-flop ". 1B is a simplified plan view of an image printed on a document at a first selected viewing angle. 1C is a simplified plan view of an image printed at a second selected viewing angle, obtained by tilting the image with respect to the point of view. 2A is a simplified cross-section of a printed image, which will be referred to as a " rolling bar ", for discussion purposes. Fig. 2B is a simplified plan view of the scroll bar image at a chosen first viewing angle. 2C is a simplified plan view of the scroll bar image at a second selected viewing angle. Fig. 12A is a simplified schematic side view of a rolling printing apparatus not according to the claimed invention. Fig. 12B is a simplified schematic side view of a rolling printing apparatus according to the claimed invention. Fig. 12C is a simplified perspective view of a rotating drum with magnetic assemblies, according to the apparatus shown in Figs. 12A and 12B. 12D is a simplified perspective view of a part of a rotating drum with a magnetically shaped surface. 12E is a simplified side view of the magnetic assembly for printing illusive three-dimensional images. Fig. 12F is a simplified side view of a magnet for printing three-dimensional illusory images. Fig. 13B is a simplified flowchart of a method of printing an image according to another embodiment of the present invention. DETAILED DESCRIPTION OF THE INVENTION 1. Introduction The present invention in its various embodiments solves the problem of predetermined orientation of optically variable ink magnetic flakes in a high speed printing process. Typically, particles of an optically variable pigment dispersed in a liquid paint or paint vehicle generally orient themselves parallel to the surface when printed or painted on a surface. The orientation parallel to the surface provides a high reflectance of incident light from the coated surface. The magnetic flakes can be inclined while in the liquid medium by application of a magnetic field. The flakes are generally aligned such that the larger diagonal of a flake follows a line of magnetic field. Depending on the position and strength of the magnet, the magnetic field lines can penetrate the substrate at different angles by tilting the magnetic flakes to these angles of inclination. An inclined flake reflects incident light differently than a flake parallel to the surface of the printed substrate. Reflectance and hue may have different inclination angles. The inclined flakes typically appear darker and have a different color than the flakes parallel to the surface at a normal viewing angle. The orientation of magnetic flakes in printed images presupposes several problems. Many modern printing processes are high speed compared to the batch type process which applies a magnet against a static coated article (no movement) and holds the magnet in position while the ink dries. In some printers, the paper substrate moves at a speed of 100-160 meters per minute. Paper sheets are stacked after one print operation, and fed to another stack. The inks used in such operations typically dry in milliseconds. Conventional processes are not suitable for such applications.

It has been found that one way of obtaining improved optical effects in the painted / printed image is by the orientation of the magnetic flakes perpendicular to the direction of the moving substrate. In other words, the liquid paint medium painted or printed with flocs dispersed in the substrate moves perpendicular to the magnetic lines of the field to cause redirection of the flakes. This type of orientation can provide remarkable illusory optical effects in the printed image. A type of optical effect will be referred to as a kinematic optical effect for discussion purposes. An illusory kinematic optical effect generally provides an illusion of movement in the printed image as the image is tilted relative to the viewing angle, assuming a stationary source of illumination. Another illusory optical effect provides a virtual depth for a printed, two-dimensional image. Some images can provide both virtual movement and depth. Another type of illusory optical effect reverses the appearance of a printed area, such as by alternating between light and dark colors, as the image is tilted back and forth. II. Examples of Illustrated Printed Images FIG. 1A is a simplified cross-section of a printed image 20, which will be referred to as " flip-flop " optical effect, ", for discussion purposes. The flip-flop includes a first printed part 22 and a second printed part 24, separated by a transition 25. Pigment flakes 26, surrounded by the vehicle 28, such as an ink vehicle or a paint vehicle, have been aligned parallel to a first plane in the first part, and pigment flakes 26 'in the second part were aligned parallel to a second plane. The flakes are shown as short lines in cross-sectional view. The flakes are magnetic flakes, that is, pigment flakes that can be aligned using a magnetic field. They may or may not retain the remaining magnetization. Not all flakes in each part are precisely parallel to one another or the respective alignment plane, but the overall effect is essentially as shown. Figures are not drawn to scale. A typical flake may be twenty microns in diameter and about one micron thick, therefore, the figures are merely illustrative. The image is printed or painted on a substrate 29, such as paper, plastic film, laminate, paperboard, or other surface. For convenience of discussion, the term " printed " will be used to generically describe the application of pigments in a carrier to a surface, which may include other techniques, including techniques others may refer to as " paint ".

In general, the flakes seen in a position normal to the plane of the flake appear bright, when the flakes seen along the edge of the plate appear dark. For example, light from a light source 30 is reflected away from the flakes in the first region relative to a viewer 32. If the image is tilted in the direction indicated by an arrow 34, the flakes of the first region 22 will be seen perpendicular, whereas the light will be reflected in the flakes in the second region 24. In this way, in the first viewing position the first region will appear clear and the second region will appear dark, while in the second viewing position the fields will reverse, the first region becomes dark and the second region becomes clear. This provides a very striking visual effect. Likewise, if the pigment flakes are of color exchange, one part may appear to be of a first color and the other part of another color. The carrier is usually clear, clear or colored, and the flakes are usually quite reflective. For example, the carrier could be a greenish color and the flakes could include a metal layer, such as a thin film of aluminum, gold, nickel, platinum or metal alloy, or be a metal flake, such as a flake of nickel or alloy. Light reflected by a layer of metal through the green vehicle may appear bright green, while the other part with flakes seen on the perpendicular may appear dark green or other color. If the flakes are merely metallic flakes in a transparent vehicle, then one portion of the image may appear shiny metallic while another portion appears dark. Alternatively, the metal flakes may be coated with a dyed layer, or the flakes may include an optical interference structure, such as a Fabry-Perot absorber-spacer-reflector type structure. Fig. 1B is a simplified plan view of the image 20 printed on the substrate 29, which could be a document, such as a bank note or a certificate of values, in a selected first viewing angle. The printed image may act as a security function 11 and / or authentication because the illusory image can not be photocopied and can not be produced using conventional printing techniques. The first part 22 appears bright and the second part 24 appears dark. A cut line 40 indicates the cross-section shown in Fig. 1A. The transition 25 between the first and second portions is relatively sharp. The document could be, for example, a bank note, certificate of shares, or any other high-value printed material. 1C is a simplified plan view of the image 20 printed on the substrate 29 at a second selected viewing angle obtained by tilting the image with respect to the point of view. The first part 22 now appears dark, while the second part 24 appears clear. The angle of inclination at which the image is inverted depends on the angle between the planes of alignment of the flakes in the different parts of the image. In one sample, the image was inverted from light to dark when tilted by about 15 degrees. 2A is a simplified cross-section of a printed image 42 of a kinematic optical device which will be referred to as a " rolling bar " for discussion purposes. The image includes pigment flakes 26 surrounded by the transparent vehicle 28 printed on the substrate 29. The pigment flakes are aligned in a curved shape. As with the flip-flop, the scroll bar region (s) that reflect light from the faces of the pigment flakes to the viewer appear lighter than areas that do not directly reflect light to the viewer. This image provides a clear band (s) or bar (s) that appears to move (" roll ") through the image, when the image is inclined to 12 to the viewing angle (assuming a source of fixed lighting). 2B is a simplified plan view of the image of the roller bar 42 at a first selected viewing angle. A shiny bar 44 appears in a first position in the image between two contrasting fields 46, 48. Fig. 2C is a simplified plan view of the scroll bar image at a selected second viewing angle. The shiny bar 44 'appears to have been " to a second position in the image, and the sizes of the contrasting fields 46 ', 48' have changed. The alignment of the pigment flakes creates the illusion of a " roll " down the image as the image is tilted (at a fixed viewing angle and fixed lighting). Tilting the image in the other direction causes the slider bar to roll in the opposite direction (up).

It may also appear that the bar has depth, even if it is printed on a plane. The virtual depth may appear to be much larger than the physical thickness of the printed image. The inclination of the flakes in a selected pattern reflects light to create the illusion of

depth or " 3D ", as is commonly referred to. A three-dimensional effect can be obtained by placing a shaped magnet behind the paper or other substrate with magnetic pigment flakes printed on the substrate in a fluid carrier. The flakes align along the lines of the magnetic field and create the 3D image after drying (for example, drying or curing) of the vehicle. The image often seems to move when it is tilted so 3D kinematic images can be formed. Flip-flops and scroll bars can be printed with flakes of magnetic pigments, that is, pigment flakes that can be aligned with a magnetic field. 13

A printed flip-flop image provides an optically variable device with two distinct fields that can be obtained with a single printing step and use a single ink formulation. A rolling bar type image provides an optically variable device that has a contrast band that appears to move when the image is tilted, similar to the semi-precious stone known as the Tiger's Eye. These printed images are quite visible and the illusory aspects can not be photocopied. Such images may be applied to paper currency, share certificates, software documentation, security seals, and similar objects such as authentication and / or anti-counterfeit devices. These images are particularly desirable for high volume printed documents such as banknotes, packages and labels because they can be printed in a high speed printing operation. III. Figure 12A is a simplified schematic side view of a portion of a printing apparatus 200 not according to the claimed invention. The magnets 202, 204, 206, 208 are located within a print roll 210, forming a pattern that correlates with a printed image. The substrate 212, such as a web of paper, plastic film, or laminate, travels between the print cylinder 214 and the print roller 210 at high speed. The printing cylinder picks up a relatively thick layer of ink 212 or liquid paint 215 containing the magnetic pigment from a source container 216. The paint or ink is spread to the desired thickness on the printing cylinder with a blade 218. During printing of an image between the print cylinder and the printing cylinder, the printing roller magnets orient (i.e., selectively align) the magnetic pigment flakes in at least part of the printed image 220. A tensioner 222 is normally used for maintaining the desired tension of the substrate as it exits the printing roller and printing cylinder, and the image on the substrate is dried with a dryer 224. The dryer may be from a heater, for example, or the paint or paint can be curable by UV and consolidated with a UV lamp. Fig. 12B is a simplified schematic side view of a portion of a printing apparatus 200 'in accordance with the present invention. The magnets 202 ', 204', 206 ', 208' are installed in the tensioner 222 'or other roller. The magnets guide the flakes of magnetic pigments in the printed images before the fluid vehicle's paint or paint dries or consolidates. A field 219 exits the print roll 210 'and print cylinder 214 with flakes in an unselected orientation, and a wet image 220' is oriented by an imprint 206 'on the tensioner 222' before the flakes are fixed. The dryer 224 accelerates or completes the drying or curing process. 12C is a simplified perspective view of a magnetic roller 232 according to an embodiment of the present invention. The cylinder could be a printing cylinder or a tensioner, as discussed in conjunction with Figs. 12A and 12B, or other roller in a printing system contacting the substrate prior to the printing ink or paint being secured. The magnetic assemblies 234, 236, 238, 240, 241 are attached to the roll with screws 242, which allow the magnetic assemblies to be changed without removing the roll from the printer. The magnetic assemblies could be configured to produce flip-flop images 234, 236 or roller bar 238, or could be of patterned magnetic material 240, 241, which produces an image patterned on the printed substrate or other selected magnetic configuration. The magnetic structures on the roller are aligned with the sheet or roller to provide the desired magnetic field pattern for fields printed on the substrate with magnetic pigment flakes. The illustrated patterns represent smooth patterns that follow the curve of the roll circumference. Alternatively, the magnetic structure could be integrated into the cylinder, or a roll with a suitable material surface could be magnetized into selected standards. 12D is a simplified perspective cross-section of a portion of a roller 232 'with a magnetic mount 244 embedded in the roller. The magnetic assembly has a star shaped cross-section, and its surface 244 'is essentially aligned with the surface of the roller. The magnetic assembly could be of permanently magnetized molded material, as shown in Fig. 12F, or have an end section of SUPERMALLOY, MU-METAL or the like, as shown in Fig.

Fig. 12E below. The roll rotates toward the first arrow 246 and a paper or film substrate 248 moves toward the second arrow 250. A field 252 including magnetic pigment flakes has been printed on the substrate. The field was on the surface of the star-shaped magnetic assembly when the cylinder was near the substrate, and an illusory optical element 254 in the shape of a star was formed in the field. The magnetic pigment flakes are fixed while the magnetic assembly is in contact with the substrate. The illusory optical effect 254 is a star with an apparent depth much deeper than the physical thickness of the printed field. It has been found that the type of vehicle used with the magnetic pigment flakes can affect the final result. For example, a solvent (including water-based) carrier tends to reduce in volume as the solvent evaporates. This may further cause alignment, such as tilting partially inclined flakes toward the plane of the substrate. UV curable vehicles tend not to shrink and the alignment of the magnetic pigment flakes after contact with the magnetic field pattern tends to be more precisely preserved. If it is desired to maintain alignment, or improve the solvent evaporative alignment in the vehicle, it depends on the intended application. Fig. 12E is a simplified side view of a magnetic mount 256 with a permanent magnet 258 which supplies the magnetic field which is directed to the substrate 248 by a patterned tip 260 of SUPERMALLOY or other high permeability material. The patterned lines of the magnetic field 262 are shown for illustration purposes only. Some " super-magnetic " are hard, brittle, and often difficult to machine in intricate shapes. SUPERMALLOY is much easier to machine than NdFeB magnets, for example, and therefore can provide an intricate magnetic field pattern with sufficient magnetic field strength to align the magnetic pigment flakes to the desired pattern. The low magnetizing remnants of SUPERMALLOY and similar alloys make them easier to machine as well.

Fig. 12F is a simplified side view of a magnetic mount 264 with shaped permanent magnet 258 '. Fig. The total length of the magnet does not have to be molded, but only the part that produces the desired field pattern on the substrate 248. Although some materials which are commonly used to form permanent magnets are difficult to machine, simple patterns can be formed by less, in the tip section. Other permanent magnet forming materials are machinable, and may provide sufficient magnetic force to produce the desired illusory optical effect. Likewise, magnet alloys may be shaped or formed in relatively complex shapes using powder metallurgy techniques. IV. Fig. 13A is a simplified flowchart of a method 310 for printing an image onto a substrate. A substrate is moved apart from a rotary roller with built-in magnets (step 312) to align the magnetic pigment flakes (step 314) which have been applied to the substrate in a liquid carrier. The magnetic pigment flakes are then attached (step 316) to obtain an optically variable image resulting from the alignment of the pigment flakes. The magnetic pigment flakes are aligned by magnets on a tensioner. After the flakes are aligned the paint or paint is dried or cured to fix the image.

Various magnetic structures may be incorporated into the roller (s), including magnetic structures for forming flip-flops or rolling bars.

Other magnetic structures, such as magnets having a selected shape face, may be incorporated in the rollers to provide high speed printing of optically variable images. For example, a magnet having a ring shape on its face (the face of the roll) can produce a " fisheye " in a field printed with the magnetic pigment flakes. The magnets of the roll (s) could be formed into other shapes, such as a star, the $ sign, or the € sign, for example. Providing the magnets in the tensioner or other roller near the dryer can prevent the problems associated with the image in the flakes of magnetic pigments being degraded as the image leaves the trailing edge of the face of the magnet.

Lisbon,

Claims (1)

A method of forming an image on a substrate, characterized in that the method comprises: (a) printing fields (219) with magnetic pigment flakes in an unselected orientation on the substrate using a printing roll (210 ' and a print cylinder 214 while the substrate moves between the print cylinder 214 and the print roller 210 'at high speed, the substrate being tensioned by a tension roller 222' which comprises the magnets 202 ', 204', 206 ', 208', (b) orientation of a wet image (220 ') in one of the fields (219) by one of the magnets (206') installed in a tension roller (22 ' before the flakes are attached, and (c) securing the flakes using a drier (224) while the field (219) is in contact with the magnet (206 '). Lisbon,