The present invention relates to labels and methods of producing labels that may be incorporated into plastic products, rubber products, and the like by fusion to provide security information and a graphic image. The present invention is further related to labels that provide security information, and labeled articles incorporating the labels.

Plastic and rubber materials are used to form and package a wide variety of products. However, many products or packaging may be subject to fraudulent or illegal sale or distribution. Additionally, plastic or rubber products or packaging may be subject to counterfeiting. For example, injectable and oral drugs may be packaged in plastic or rubber packaging, and these drugs may be subject to fraudulent sale or distribution. Such fraudulent use of plastic and rubber products may be detrimental to the health and safety of consumers. Additionally, the fraudulent sale or distribution of plastic and rubber products may adversely affect the profitability of manufacturers and sellers of the products and packaging. There remains a need in the art for labels that provide authentication and verification of plastic and rubber products.

The present invention relates to a system for providing security information using a labeled article, a labeled article for use in such a security system, and labels for use in the labeled article. The security system includes a labeled article having a label with at least one invisible IR or UV image (or both) printed thereon to provide security information. The security system includes a verification system such as verification equipment that is programmed to verify the security information.

The label comprises a printable sheet, which may be a precipitated silica filled micro-porous material, having at least one invisible IR or UV image, (or both), printed thereon, at least one visible image printed thereon, and a coating over-coating the printable sheet. The at least one IR image is preferably printed on the printable sheet using inks selected from lithographic, gravure, flexographic, screen inks and combinations thereof, such that the at least one visible image at least partially overlies the at least one IR image. Preferably the IR image has a wavelength of between about 800 angstroms and about 3000 angstroms. A plurality of invisible IR images may be used to provide security information, such as bar codes, or a dot matrix pattern. Most preferred is an invisible IR image configured such that it exhibits an expected change in absorption and reflection in providing the security information.

The at least one invisible UV image is preferably printed on the printable sheet such that it at least partially overlies the at least one visible image. The UV image may be a plurality of invisible UV images with a small variation in wavelength, and may contain a trace molecular chemical to enhance its security feature, which may be in the form of bar codes, or dot matrix pattern, or a block print. As with the IR image, the UV image may exhibit an expected change in absorption and reflection in providing the security information. Likewise a printed sheet having one UV image printed over another UV image, which images are detected using optical spectroscopy, may be used to provide security information.

In the most preferred embodiment, both an invisible IR image(s) and an invisible UV image(s) are used to provide security information.

The label of the present invention may be used to provide a labeled article by permanently in-mold fusing the label to an article made of plastic, rubber or the combination thereof.

In accordance with an embodiment of the present invention, a label comprising a printable sheet, a visible image, and an invisible image is provided. The label may be incorporated into a variety of thermoplastic, thermoset, and rubber material based products, and the label may be fused into the surface of the thermoplastic, thermoset, or rubber material thereby making the label essentially tamper proof. The printable sheet has at least one visible image printed thereon, and the printable sheet has at least one invisible image printed thereon.

The printable sheet may have a thickness of about ten mil or less. The printable sheet is made of a material that can survive the tortuous injection molding environment and one that is in-moldable with a wide variety of thermoplastic and thermoset materials. The printable sheet may be made of any suitable material such as precipitated silica filled micro-porous sheet materials commercially available in the marketplace. Such materials exhibit varying degrees of robustness in the tortuous injection-molding environment. For example, material sold by PPG Industries, Pittsburgh, PA. under the trade name Teslin or MiST™ is, when properly coated as explained herein, found to be satisfactory for the most demanding molding environments including thermoset applications where the material will be exposed to high temperatures for extended time periods for curing. Other materials, such as Artisyn™ manufactured by Daramic, Inc. of Owensboro, KY. are generally satisfactory for thermoplastic injection molding applications if treated using layers to improve their tensile properties and stability

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in the mold. Use of surface treatment layers make ten mil thickness material suitable in all applications and makes seven mil thickness material suitable in many applications.

The visible images, i.e. graphic images, may be printed using any suitable ink. For example, the inks may be selected to produce the highest quality graphic images and survive the molding process while also exhibiting excellent flexibility and resistance to fading in UV light. With respect to said inks, there are families of satisfactory lithographic, gravure, flexographic, and screen inks available in the marketplace from a number of sources by referring to inks suitable for use with PPG Industries Teslin® printable sheet. The use of such inks helps obtain a quality print of visible images on silica- filled micro-porous sheet materials. Reference is made to the Grafusion™ series of lithographic inks and the GRA series of screen inks which have been optimized for the aforementioned silica filled micro-porous materials and which demonstrate the flexibility and robustness to provide and maintain a high quality graphic image through a tortuous injection molding process. Both of these series of inks exhibit exceptional fade resistance in prolonged UV exposure. These inks are available from Fusion Graphics of Dayton, Ohio. Such inks comprise a pigment and carrier which are formulated to withstand

temperatures of up to 600°F. The visible images may be printed in any suitable manner.

For example, the visible images may be printed utilizing lithography, screen printing, flexography, high resolution ink jet printing, and color or monochrome electrostatic laser printing.

The invisible image may be formed in any suitable manner. For example, the invisible image may be an IR image. The IR image may be printed with any suitable IR ink. Suitable IR inks are generally inks that are visible only under light that is at or near

IR in wavelength. For example, the ink may be visible under light having a wavelength of from about 800 angstroms to about 3000 angstroms. On the other hand, an invisible image, which may be a UV image, may be printed over the visible image and, then, excited by a UV light source. Preferably the label of the present invention has both an IR image and a UV image printed thereon. Flint Ink Corp. of Franklin, Ohio, Kennedy InIc Co., of Dayton, Ohio and Angstrom Technologies, Inc. of Erlanger, Kentucky provide both UV and IR inks.

The invisible image is configured to provide security information. For example, the IR image may be one image or a plurality of images, and the IR image may be any suitable image. Suitable images include, but are not limited to, a bar code or a dot matrix pattern. The bar code or dot matrix pattern may comprise the security information. Images may comprise a multiplayer logo with two wavelengths of electronically detectable and readable data, like a solid bar with a variable bar printed directly on top yet only seen with electronic detection and spectroscopy. The IR images may be printed in any suitable manner. For example, the IR images may be printed utilizing lithography, screen printing, flexography, high-resolution ink jet printing, and color or monochrome electrostatic laser printing.

It will be understood that the IR image formed from IR ink may be excited by an IR light source and read electronically to detect the presence and shape of the IR image. The same is true for UV inks. Thus, the presence of the security information may be verified, and the security information may be read to provide information such as the authenticity of the label. Additionally, the IR image may be read by electronic equipment to detect the rise and fall of the rates of absorption and reflection of the IR image. The

rates of absorption and reflection are traits that may be controlled during the manufacturing process of the label, and these traits provide information that may be provided to verification equipment. Thus, these traits may additionally comprise security information. The verification equipment may then be used to verify the identity and authenticity of the label by reading the security information provided by the IR image. The printed IR or UV image can be electronically detected by illuminating the images with an appropriate light source and reading them with a filtered CCD electronic camera. Using the camera and a computer it is possible to detect a variation less than .05% in difference. These images cannot be seen with the eye or with any other photographic technologies and since the wavelengths to be detected and the images are only a few wavelengths apart, it is extremely difficult to impossible to replicate the chemical response and print correct intensity in the blind.

The printable sheet may have a layer or layers over the printable sheet that aid the molding process and provide added permanence to the printed image in abrasive, chemical, or UV light exposure environments. The over-casting layers may be applied in any suitable manner. For example, the layers may be applied by coating the printable sheet by lithography, screen printing, application of curable silicone, and roll coating with the layers. Alternatively, the over-casting layers may be applied to the printable sheet by lamination. The layer or layers are generally applied over the visible and invisible images. The' roll coat or lamination method are preferred for cost and performance reasons.

With respect to the layers, there are families of UV energy cross-linkable layers that provide the said printed silica-filled micro-porous materials with the desirable performance enhancements. By the nature of their molecular level changes during curing

such layers enhance the tensile properties of the printed sheets reducing the tendency of the sheet to stretch as molten material flows over the sheet to its edges. Increasing the tensile properties also allows the use of thinner material such as seven mil thickness; this is important because it reduces the cross section presented at the sheet edge where an excessive thickness induces disruption of the material flow causing said sheet to lift from the mold surface. The increases in tensile properties are also of value in minimizing stretch thus making the printable sheets usable in a continuous roll fed sheet extrusion process where graphics are fused to extrudate as it is produced.

By the nature of the molecular changes that occur during curing, the layers also protect the ink during molding processes and provide the printable sheets with an increased surface coefficient of friction which significantly enhances the stability of the printed sheet within the mold during tortuous molding processes. Such sheet stability lowers the potential movement or float of the printed sheet as molten material flows over the sheet to its edges. The stability enhances high yield during tortuous molding processes.

When needed, such layers can be formulated and are commercially available which also enhance the resistance of the printed sheets from degradation by chemicals such as petroleum distillates and solvents which could contact the surface of the product in many applications. When needed such layers can also be formulated and are commercially available to enhance the resistance of any of the products to color fading from protracted exposure to UV light in outdoor or other high sunlight exposure applications. Such layers may also provide suitable dielectric performance so that printed and coated sheets can be

held in the mold cavities using electrostatic means without the degradation or dissipation of the electrostatic charge prior to mold closure and completion of the molding process.

In accordance with an embodiment of the present invention, the coating may be a UV curable clear coating material having a coefficient of friction greater than 0.5. The coating may be a UV curable clear coating having a cured gloss of greater than 55%. Additionally, the coating may impart enhanced properties to the printable sheet. For example, the coating may impart outdoor resistance to UV induced image fading for five to ten years, resistance to image degradation from contact with petroleum based materials or solvents, and/or resistance to underfoot slippage of greater than a 0.6 coefficient of friction as tested under ASTM D2047.

Satisfactory, but not optimum, UV curable layers are available from a number of sources by specifying a clear coat that will adhere to lithographic printed images and which exhibits whatever performance factors such as those cited above are needed for the specific application. A suitable series of such layers has been optimized to enhance the most important properties for the majority of product applications is the GRA series of layers, which are clear variants of the screen inks previously cited. These layers are available from Fusion Graphics of Dayton Ohio. Such layers are UV crosslinkable layers containing an may acrylate ester.

In accordance with an embodiment of the present invention, the label may have invisible ultraviolet (UV) ink printed over the visible image to produce a UV image. The UV image is configured to provide security information. The UV image may be produced by using any suitable UV ink. Examples of suitable UV inks include, but are not limited to, those available from Angstrom Technologies Inc. and Kennedy InIc Co. UV ink is

generally invisible to the human eye unless placed under a UV light. For example, the UV ink may be visible when placed under a long wave UV light. The UV image may be any suitable image. For example, the image may be a dot matrix pattern, a bar code, or the image may be a block print that covers the visible image, and the UV images may comprise security information. The UV image may be layered with the layer or layers over the UV image. The UV images may be printed in any suitable manner. For example, the UV images may be printed utilizing lithography, screen printing, flexography, high resolution ink jet printing, and color or monochrome electrostatic laser printing. It is possible to manufacture multiple UV inks and with small variations in wavelength of the same color. This allows for printing, for example, a yellow solid bar image and then over the same solid bar print a yellow custom bar code image and then use the Raman spectroscopy process to determine the forensic validity of the images, we may also add a trace molecular chemical that only can be detected using spectroscopy, further adding additional levels of security. It will be understood that the UV image may be excited by an UV light source and read electronically to detect the presence and shape of the UV image. Thus, the presence of the security information provided by the UV image may be verified, and the security information may be read to provide information such as the authenticity of the label. Additionally, the UV image may be read by electronic equipment to detect the rise and fall of the rates of absorption and reflection of the UV image and the density of the UV image. The rates of absorption and reflection and density are traits that may be controlled during the manufacturing process of the label, and these traits provide information that may be provided to verification equipment. These traits may comprise

security information. The verification equipment may then be used to verify the identity and authenticity of the label by reading the security information provided by the invisible UV image.

In accordance with an embodiment of the present invention, the labels may be incorporated into plastic or rubber articles made from any suitable materials to form labeled articles. Suitable materials for the articles include polymers such as thermoplastic polymers and thermoset polymers. Suitable polymers include, but are not limited to, Polyolefin (polypropylene, polyethylene) polycarbonate, elastomers, polyamides, polystyrene, polyphenylene oxide, polyvinyl chloride, partially devulcanized crumb rubber, crumb rubber filled polymer, and acrylonitrile-butadiene-styrene. Suitable materials also include unvulcanized rubber. Transparent polymers may be used, and the labels may have a visible and/or invisible IR image printed on the front and the back of the labels. Additionally, recycled or regrind materials may be utilized to form the products of the present invention. The recycled or regrind materials may contain non-homogenous and variegated material derived from recycled or regrind stocks.

The labels of the present invention may be incorporated into plastic or rubber articles in any suitable manner. Generally, the labels are permanently fused into the surface of the plastic or rubber material during the manufacture of the article. The labels may be fused into the surface of suitable materials by any suitable process such as molding including thermosetting, vulcanization, and thermoplastic molding and extrusion. Because the labels are permanently fused into the surface of the plastic or rubber material during the manufacture of the article, the labels are essentially tamper proof. Any attempt to remove the label will irreversibly alter the surface of the plastic or rubber material, and

such alteration of the surface will be apparent. Thus, the labels provide embedded security information that may be unique to the product.

The labels exhibit high stability in the mold during molding, and the labels may be used in a wide variety of molding techniques. The labels may introduced into a mold, contacted with the article material, and the labels may then be fused into the article during the molding process. Suitable molding processes include injection, blow, thermoforming, gas assist, structural foam, compression, and rotational molding. The labels may be permanently fused into the surface of an article during extrusion and vulcanization processes. The labels of the present invention may exhibit improved positional stability in a mold. For example, the label may have dielectric properties that permit positionally stable placement using electrostatic charging of the printable sheet in any position within a mold for over 30 seconds including during the molding process. Such dielectric properties may be imparted by the layers as discussed herein, hi another example, the label may have a coefficient of friction between the printable sheet and a mold surface sufficient to resist the force of molding material flowing over the molding side of the printable sheet. Additionally, the label may have a surface that softens sufficiently to produce adhesion to a mold surface sufficient to resist the force of molding material flowing over the molding side of the printable sheet. The labels of the present invention may be thermoformed to fit complex mold face geometries. For example, the label may be incorporated into a product have a raised area or areas. Additionally, the products may be decorated post mold using any suitable technique such as pad printing, heat transfer, foil transfer, screen printing, airbrush, and

application of an adhesive label. In a further example, the label may comprise a three dimensional printable sheet printed with visible and invisible images as discussed herein. The three dimensional label may be molded with a suitable product to produce a labeled three dimensional product. The label may be made three dimensional by a method selected from heat welding, vacuum forming, ultrasonic welding, and coining, and combinations thereof.

It will be understood that the label may be manufactured to contain graphic visible and invisible images that are unique to a labeled article. Additionally, the absorption, reflection, and density of the IR and UV images may be controlled during manufacturing, and changes in these rates may be used to identify a particular labeled article. Using the Raman spectrographic technologies allows for the fused label to be uniquely identified, i.e. as a "fingerprint" or "DNA" for that image. The ability to deposit these images as unique individually electronic printed imagery with lots code provide all the aspects to handle fraudulent and gray market distribution of products. In accordance with another aspect of the present invention, a system for providing security information is provided. The system comprises a labeled article as discussed herein having security information provided thereon. The system additionally comprises a verification system that comprises verification equipment. The verification equipment that is capable of electronically reading IR and UV images. The verification equipment may be programmed to interpret the IR and UV images in any desired manner. For example, the verification equipment may be programmed to verify the security information provided on the labeled product. Additionally, the verification equipment may be electronically provided with expected changes in the absorption or reflection of the

TR and/or UV images, and the expected changes may be used to verify the identity and authenticity of the labeled product.

It will be obvious to those skilled in the art that various changes may be made without departing from the scope of the invention, which is not to be considered limited to what is described in the specification.