This invention relates to making and securing circuits, such as identification tags, with touch fasteners.
Much effort has recently been expended to develop improved circuitry and systems for wireless tracking of objects, such as by Radio Frequency IDentification, or RFID. The cost of RFID tags has been reduced to the point that it is now commercially feasible to incorporate them even into disposable packaging.
All such tags feature antennae, typically in the form of a conductive trace arranged to be responsive to a weak, externally applied field oscillating at a given frequency. Typically they also contain a few, fairly inexpensive electronic components coupled to the antenna.
Improvements in the design and manufacturing of such identification tags are sought, as well as improvements in the manufacturing of electrical circuitry generally, and in the means of attaching such tags and/or other circuitry to a supporting surface.
According to one aspect, an identification tag includes a flexible sheet-form base having a broad surface formed of resin, electrically conductive material, and an array of fastener elements extending from the broad surface of the base. The conductive material is carried by the base, forming a conductive path and defining at least a portion of an antenna responsive to externally applied electromagnetic radiation oscillating at a predetermined frequency. The fastener elements are arranged and constructed to engage predetermined frequency. The fastener elements are arranged and constructed to engage mating fastener elements to selectively secure the tag.
In some embodiments, the fastener elements are shaped to releasably engage exposed loop fibers associated with a supporting surface to which the tag is to be secured. In some cases, the fastener elements are raised projections of the resin of the broad surface of the base, or at least each have stems molded of resin contiguous with the resin forming the broad surface of the base. The array of fastener elements is substantially coextensive with the broad surface of the base in many instances.
The identification tag preferably has an entire thickness, measured from distal ends of the fastener elements to an exposed broad surface of the base opposite the fastener elements, of less than about 0.1 inch (2.5 millimeters), more preferably less than about 0.05 inch (1.25 millimeters).
In some embodiments the fastener elements each have distal heads overhanging the base to form loop-engaging crooks.
In some examples the antenna is encased within the base. For example, the antenna may be disposed between a first layer of resin forming the broad surface and insulating one side of the antenna, and a second layer of resin insulating another side of the antenna. The first and second layers of resin may consist of a single seamless extent of a single resin material, or may be of differing material properties. In some cases the first and second layers are permanently welded to one another in a manner to encompass the antenna.
For many applications the fastener elements each have a height, measured from the broad surface of the base, of less than about 0.05 inch, and the array of fastener elements has a density of at least about 20 fastener elements per square centimeter (in some cases, at least 50, or even at least 75, fastener elements per square centimeter).
In many instances the tag also includes at least one discrete electrical component carried by the base and coupled to the antenna. In some cases the electrical component includes a circuit mounted in a sealed housing fully or at least partially embedded in the base. In some configurations the electrical component includes a circuit in electrical communication with the antenna and at least partially electrically isolated by resin of the base.
In some embodiments, an identification tag includes a wrist strap. In some cases, the tag has a head defining an aperture adjacent one end of the tag, and the fastener elements include a row of projections that cooperate with a feature of the head to prevent withdrawal of the tag from the aperture with an opposite end of the tag inserted through the aperture. In some cases, the fastener elements are configured to releasably engage other fastener elements of the tag when the tag is wrapped about an object to engage itself. For example, the other fastener elements can include loops. In some cases, the base defines a discrete frangible region spaced from longitudinal ends of the tag and spanning at least one electrically conductive member of the tag, such that breaking the base at the frangible region renders the tag inoperable.
In some embodiments, the identification tag defines a receptacle sized to receive an electronic component, the tag comprising electrically conductive connection surfaces positioned to establish electrical connectivity between the antenna and the received component. In some cases, identification tags are combined with an electronic component disposed within the receptacle, the electronic component comprising a microprocessor and containing a unique component identification code. In some cases, the receptacle is bounded by at least one wall having component retention features that extend into the receptacle and prevent removal of a received electronic component. In some cases, the receptacle includes an electronic component removal slot arranged to permit sliding a received electronic component laterally out of the receptacle.
Some other aspects of the invention feature methods of continuously forming a series of identification tags.
One method involves introducing a thermoplastic resin into a gap formed adjacent a peripheral surface of a rotating mold roll, the mold roll defining an array of cavities therein, the resin being introduced under pressure and temperature conditions selected to cause the resin to at least partially fill the cavities to form fastener element stems integrally with and extending from one broad surface of a strip of said resin, while introducing a preformed strip into the gap. The preformed strip includes a support substrate carrying a series of discrete electrical traces configured to form at least portions of antennae responsive to externally applied electromagnetic radiation oscillating at a predetermined frequency. The preformed strip is introduced so as to cause the resin to bond with the preformed strip and form a laminate material having a flexible resin base carrying both an exposed array of fastener element stems and a series of antennae.
In some applications the method also includes severing the laminate material into discrete identification tags, each tag containing an antenna and a multiplicity of exposed fastener elements.
In some cases the electrical traces each include a continuous, coiled, flexible trace of conductive material forming a conductive path of length greater than a lateral extent of the antenna.
In some instances the cavities of the mold roll are shaped to mold distal heads on the fastener element stems, the distal heads being shaped to overhang the broad surface of the strip of resin so as to be releasably engageable with exposed loop fibers. In some other instances each of the stems defines a tip portion, the method further including deforming the tip portion of a plurality of the stems to form engaging heads overhanging the broad side of the strip of resin and shaped to be engageable with exposed loop fibers.
In some cases the gap is a nip defined between the rotating mold roll and a counter-rotating pressure roll.
In some embodiments the support substrate includes a film carrying the conductive material on its surface. The resin is introduced to the gap directly adjacent the rotating mold roll, and the film is introduced to the gap under pressure and temperature conditions that cause the film to become permanently bonded to the resin to envelop and electrically isolate the antennae.
Another method features molding a continuous, flexible base of an electrically insulating thermoplastic resin, while forming a series of channels in a surface of the base; at least partially filling the formed channels with a flowable, electrically conductive composition; stabilizing the flowable composition in the channels to form a pattern of stable, electrically conductive traces within the channels; and providing a series of discrete electronic circuits carried by the flexible base. Each circuit is electrically connected to a corresponding one of the traces to form a trace-circuit pairing, and each trace-circuit pairing is responsive to externally applied electromagnetic radiation oscillating at a predetermined frequency.
In some cases, at least partially filling the formed channels includes using printing techniques to dispense conductive ink into the channels.
In some cases, at least partially filling the formed channels includes dispensing the flowable composition onto the surface of the base, and then substantially removing the flowable composition from non-channel regions of the surface.
In some examples, removing the flowable composition includes wiping the surface.
In some embodiments the flowable composition is in powder form prior to stabilization. In some cases the flowable composition comprises a liquid carrier solution containing metal ions, or a suspension of conductive particles.
The composition may be stabilized in the channels by evaporating a solvent from the composition, or by radiating the composition in the channels with radiation selected from a group consisting of heat, ultraviolet radiation, and microwave radiation, or by subjecting the composition to reducing conditions, or by releasing reducing agents from capsules contained within the flowable composition.
In some examples molding the base includes feeding the thermoplastic resin in a moldable form into a gap adjacent a mold roll. The gap may be defined between the mold roll and a counter-rotating roll, for example. The method also includes, in some cases, forming a field of loop-engageable fastener elements extending from the base by introducing the resin into the gap such that the resin fills a field of fixed cavities defined in the mold roll to form a field of molded stems; solidifying the molded stems; stripping the stems from the mold roll; and then forming loop-engageable heads on the molded stems.
For some applications the method includes, prior to filling the channels, surface-treating the channels to promote adhesion of the flowable composition.
In some cases the method also includes providing a field of loop-engageable fastener elements on the base exposed to releasably secure the base to a loop-bearing support, such as by integrally molding the fastener elements with the base such that the fastener elements extend outwards from a surface of the base. The fastener elements may be provided by attaching preformed fastener element tape to the base.
In some cases the method includes attaching an electrically insulating cover over the conductive traces, with the cover attached to the base. Attaching the insulative layer may include passing the sheet-form base through a gap adjacent a mold roll in the presence of moldable resin to encapsulate the conductive traces, or spraying an insulating composition onto the base, such that the insulating composition encapsulates the conductive traces.
Another aspect of the invention features a method of forming a flexible identification tag with integral touch fastener elements.
One method includes introducing an elongated flexible circuit strip including a substrate and a series of longitudinally spaced apart tag circuits carried by the substrate to a gap adjacent a peripheral surface of a mold roll having an array of stem forming cavities extending inwardly from the peripheral surface, while simultaneously introducing a thermoplastic resin into the gap directly adjacent the peripheral surface under temperature and pressure conditions causing the thermoplastic resin to at least partially fill the stem forming cavities and to permanently bond to the substrate. The permanently joined thermoplastic resin and substrate is then stripped the from the mold roll to expose the fastener element stems. Various embodiments can provide particularly efficient methods of making RFID tags as well as other circuits, and providing such circuits in many cases with integral touch fastener elements. Flexible circuits with integral touch fasteners may be readily releasable and repositionable, and identification tags employing such fastening means, reusable.
In some aspects, a n electronically readable wrist strap includes: an elongated and flexible strip of resin having opposite longitudinal ends and securable about a wrist of a wearer; electrically conductive material carried by the strip and forming a conductive path that defines at least a portion of an antenna responsive to externally applied electromagnetic radiation oscillating at a predetermined frequency; and electronic circuitry in electrical communication with the antenna and containing an electronically readable identification code. The strip defines a discrete frangible region spaced from the longitudinal ends and spanning at least one electrically conductive member of the strap, such that breaking the strip at the frangible region to remove the strap from the wrist renders the strap unreadable.
In some embodiments, electronically readable wrist straps further include an array of fastener elements extending from the broad surface of the base, the fastener elements arranged and constructed to engage mating fastener elements to selectively secure the tag. In some cases, the fastener elements comprise raised projections of the resin of the broad surface of the base.
In some embodiments, the antenna is disposed between a first layer of resin forming the broad surface and insulating one side of the antenna, and a second layer of resin insulating another side of the antenna. In some cases, the first and second layers of resin consist of a single, seamless extent of a single resin material. In some cases, the first and second layers are of differing material properties.
The details of one or more embodiments of the invention are set forth in the accompanying drawings and the description below. Other features, objects, and advantages of the invention will be apparent from the description and drawings, and from the claims.
Like reference symbols in the various drawings indicate like elements.
Referring to
An array of fastener elements 20 extends from the broad surface 14 of base 12, the fastener elements arranged and constructed to engage mating fastener elements (such as loop elements, not shown) associated with a supporting surface, such as a fabric garment, to selectively secure the tag to the supporting surface. As shown, the array of fastener elements 20 is substantially coextensive with the broad surface 14 of base 12, and has a density of at least about 150 fastener elements per square centimeter.
Referring next to
In the example of
In use, referring to
In the example of
For example, in the configuration of
Many methods are envisioned for forming the above-described identification tags. One such method begins with a roll 34 of carrier material 36, such as film, to which a series of RFID antennae 18 are adhered, as shown in
The formed product is cooled on the mold roll until the solidified fastener elements (e.g., hooks) are stripped from their fixed cavities by a stripper roll 108. Along with the molten resin, the continuous antennae carrier strip 36 is fed into nip 102, where it is bonded with resin 140 and becomes a permanent part of the base of the resulting product, pressure and temperature conditions in the nip causing the antennae carrier strip to become permanently bonded to the resin to envelop and electrically isolate the antennae. Thus, the product 162 that is stripped from the mold roll 104 includes both fastener elements 20 and RFID antennae 18 as illustrated, for example, in
Other forming methods are also envisioned. For example, molten resin can be injected directly into the mold roll cavities under pressure applied by a stationary molding shoe, with the antennae strip laminated to an obverse side of the resin base while the fastener elements are solidifying in their cavities. Direct mold roll injection is more fully described, for example, in U.S. Pat. No. 5,441,687, issued Aug. 15, 1999, to Murasaki et. al, also incorporated herein by reference.
In another example illustrated in
In any of the methods described herein, the mold roll cavities may be shaped to form stems only, without an undercut portion for forming an engaging head of a fastener element. In such cases the product (e.g., 162) stripped from the mold roll has only integrally molded stems protruding from its upper surface. Subsequent to the stripping operation, the product is passed between a heated roller and an anvil roller (such as at rolls 122 in
In yet another suitable technique, a thermoplastic base is extruded having continuous rails of hook fastener-shaped profile. The rails, but not the base, are subsequently slit laterally at intervals along the length of the extrusion to form separate portions of the fastener-shaped rail, each portion separated from an adjacent portion by a slit. The base is then permanently stretched longitudinally to create space between adjacent portions of the fastener-shaped rails. The resulting fastener tape has rows of spaced individual hook fastener elements. Such a technique is more fully described for example, in U.S. Pat. No. 4,894,060, issued Jan. 16, 1990 and also incorporated herein by reference. To such extruded, slit and stretched product a strip of RFID antennae may be laminated as discussed above, and then severed into individual identification tags.
Another method of forming identification tags features forming the conductive antenna directly on the tag base, rather than using preformed strips of RFID tags. Referring to
Structural features 232 are also configured to form channels 234 whose opening is narrower than the width of the base of the channel. Some other embodiments form channels 234 with different shapes. However, channels 234 with at least a portion whose width decreases with increasing distance from an opposite side of base 12 provide additional mechanical resistance to the removal of conductive material 16 from the resin base after stabilization.
Channels 234 are patterned, in shape, width and thickness, to correspond with a desired conductive material layout to form antennae in the finished product. In this embodiment, second mold roll 106′ is formed of a roller sleeve whose surface is etched to form structural features 232. Alternatively, second mold roll 106′ can be assembled from multiple rings, each ring including structural features 232 configured to shape shallow channels 234. The use of roll molding produces channels 234 in longitudinally extending repeating patterns. Multiple columns of antennae formed from respective longitudinally-extending patterns of channels 234 can be produced side-by-side on a single roll molding apparatus. As molten resin 140 enters nip 102, pressure in the nip forces the resin into the fastener element mold cavities and around structural features 232.
The system illustrated in
The capacitance of the resonant circuit may be provided by a pad of conductive ink dispensed into a molded recess on one side of the base layer with the conductive trace forming the inductor, and a second pad of conductive ink or metallic coating formed on an opposite side of the base layer in a region aligned with the first pad, on the fastening side of the product. The thickness of base layer 26 provides the separation between the capacitive ‘plates’. Such a second pad of conductive material may be formed directly on the fastener elements, such as by techniques taught in U.S. Pat. No. 6,977,055. Trimming or tuning the resonance of the circuit in such instances may be accomplished by removing portions of one or more fastener elements within the second pad. The second pad may be electrically coupled to an associated microchip carried on the ink side of the product through a via, or may be mounted on the fastening side of the base layer.
Alternatively, the second side of the capacitor can be provided by a metallic foil applied over the pad of conductive ink and secured to the base layer 26 by a non-conductive adhesive tape that electrically separates the conductive ink from the foil layer. Or the capacitor can be provided as a preformed electrical component mounted and electrically coupled to the inductor after forming of the conductive traces.
After conductive traces 16 are formed, sealing station 244 sprays a cover 28′ (e.g., an epoxy, an acrylate, or an epoxy-acrylate) on the upper surface of resin base layer 26. Cover 28′ is selected at least in part for its compatibility with and ability to bond to the resin of layer 26 and for its insulative properties. Cover 28′ and resin layer 26 cooperate to substantially insulate conductive traces 16 from each other and from the surrounding environment. Second sides of the capacitor may also be formed by a layer of conductive coating applied over the cover 28′. The resulting strip of RFID tag material is spooled for storage on storage roll 254.
Filled resin strip 210 and preformed fastener tape 272 are fed into lamination nip 224 defined between lamination rolls 268. Heater 274 heats fastener tape 272 as the fastener tape proceeds from feed roll 276 into lamination nip 224. Fastener tape 272 is selected from fastener tapes which are compatible with the resin of strip 210. Thus, when heated fastener tape 272 proceeds through lamination nip 224 with strip 210, the fastener tape and the strip 210 cooperate in sealing and insulating conductive traces 16 within the base. In other embodiments, an adhesive is applied to fastener tape 272 before it enters lamination nip 224 rather than heating the fastener tape before it enters the lamination nip.
Referring to
In another embodiment, dispenser 282 sprays a liquid silver composition (e.g., a binding agent such as ethylenediaminetetraacetic acid (EDTA) or citric acid containing silver ions) on the resin base, instead of a metallic powder. The liquid silver composition contains reducing agents (e.g., ascorbic acid or ferrous ammonium sulfate) encapsulated in micro-bubbles. After doctor blade 262 wipes accumulated silver composition from non-channel regions of resin base layer 26, energy radiated by an ultrasonic emitter (not shown) releases the reducing agents initially contained by the micro-bubbles and solidifies the silver composition. In other embodiments, other liquid compositions of similar properties, including for example compositions with other metals such as copper or aluminum, are used to fill channels 234 and to form conductive traces 16 on resin base layer 26.
In some embodiments, the system also includes an electroplating station that electroplates a second conductive material onto conductive traces 16. This can increase the uniformity of the conductivity along the surface of conductive traces 16.
A component feed roll 288 places discrete electronic components 30 into receptacles 292 on a placement roll 294, with component pins or solder pads 295 directed radially outwards. Optionally, a solder pad heater 296 is placed to heat pads 295 of components 30 as placement roll 294 rotates to bring the components into contact with resin layer 26. Pins 295 of pin-bearing components contact and pierce conductive traces 16 and resin base layer 26, while solder pads 295 of surface mount components electrically join to traces 16. This provides both electrical connection and mechanical fastening for components 30. Each component 30 or set of components, electrically connected to an associated antenna trace, forms a trace-circuit pairing.
It can be difficult to spool tape with electrical components attached. Therefore, the illustrated manufacturing system includes a cutting roll 298. As the continuous tag material is pulled between cutting roll 298 and support roll 258, ridges 300 arranged on the peripheral surface of the cutting roll cut the longitudinally extending tag material into discrete RFID tags.
Referring to
Conductive ink may alternatively be applied by other means. For example,
Another method, particularly useful for forming the fastener RFID tag of
A gear pump 336, 348, is positioned at the outlet of each extruder, to accurately control the rate of polymer delivered to the mold roll. The final thickness of the base of the product is then adjusted by roll 352, and the finished fastener RFID tape is stripped from the mold roll 340 by passing it around exit roll 354. The finished tape may then be severed to form the product of
Referring next to
Referring to
The fastener strap 605 can have various different dimensions depending on its intended use. For example, the base 625 of the fastener strap 605 can have a thickness of between about 0.005 inch and 0.030 inch. The strap 605 can have a length of between about 3 inches and 36 inches. The width of the strap can range from about 0.25 inch and 1 inch. In some cases, it is beneficial to provide a relatively wide strap in order to broadly distribute the retaining load across the fastener product. Because the relatively wide strap broadly distributes the load, the fastener product is able to withstand more stress (e.g., sheer stress) than a similar product having a thinner strap. Similarly, the strength of the strap increases as the thickness of the strap increases.
The fastener projections 630 are in the shape of wedges. More particularly, a first surface 631 of the fastener projections 630 is substantially flat and inclined at an angle α of between about 10 degrees and 45 degrees relative to the planar base 615. A second surface 633 extends from the base 615 at a steeper angle of incline φ of between about 45 degrees and 90 degrees relative to the base 615. The second surface 633 joins the first surface 631 to form an apex 632. The apex can have an angle ω ranging from about 30 to 80 degrees. The projections 630 extend to a height of between about 0.01 inch and 0.05 inch above the base 615. The fastener projections 630 are arranged such that the second surfaces 633 all face in the same direction. In this case, the second sides 633 face toward the head element 610.
The dimensions discussed above are merely used to describe particular embodiments. Straps and projections of other suitable shapes and sizes capable of providing the product with fastening ability can be used.
The head element 610 defines an aperture 645. When the fastener strap 605 is inserted through the aperture 645, the head element 610 cooperates with the fastener projections 630 to prevent the strap 605 from retreating back through the aperture 645. In other words, the head element 610 is configured such that it provides one-way movement of the strap 605 through the aperture 645.
The head element 610 includes a retaining arm 658 that extends into the aperture 645. When the strap 605 is pulled through the aperture 645 in the direction of arrow A, the first surfaces 631 of the wedge-shaped fastener projections 630 deflect the retaining arm 658 away from the projections 630 allowing the strap 605 to proceed through the head element 610. However, when the strap 605 is pulled in a direction opposite to that shown by the arrow, the second surface 633 of the projection 630 abuts and engages the retaining arm 658. This prevents the strap 605 from exiting the head element 610.
This configuration provides straps configured for one time use. For example, a hospital or amusement park can provide wrist straps assigned to a particular patient (e.g., for confirmation of identity before administering medication) or guest (e.g., for confirming what level of access to park attractions has been purchased). As described above, the strap 605 is inserted through aperture 645 to secure the fastener product 600 around a user's wrist. A nurse or attendant can verify that the strap is snugly attached such that the wrist strap cannot be slipped off over the user's hand. In some cases, removal of the wrist strap requires cutting or breaking the strap 605, thus severing the electrical connection between the RFID antenna and the microchip 607, or altering the electrical characteristics of the antenna. When the electrical connection is broken, the wrist strap is inoperative.
In other embodiments, the retaining arm 658 can be configured to allow a user of the product 610 to release the arm 658 from engagement with the projection 630 to allow the strap 605 to be removed from the head element 610 after insertion. This enables the user to reuse the fastener product 610 multiple times. Other releasable fastening configurations, such as mating hook and loop fastener arrays, are also envisioned.
In particular embodiments, the head element 610 extends to a height of between about 0.1 inch (0.254 cm) and 0.4 inch (1.016 cm) above the base 615. Depending on the width of the strap 605, the width of the head can range from about 0.3 inch (0.762 cm) to 1.25 inch (3.175 cm). Head elements of other shapes and sizes capable of receiving the strap in the aperture to allow the strap to enclose the product in a fastened position can be used.
As discussed above, the fastener product 600 includes the backing material 612 attached to a bottom surface of the strap 605 opposite the surface from which the fastener projections 630 extend. The backing material can be one of various suitable materials including, for example, non-woven materials, knit materials, foam materials, and metallized film. Depending on the material from which the backing material 612 is composed, it can provide various benefits, as discussed above.
Fastener projections having other shapes can also be employed.
Referring to
Referring to
Microchip assembly 716 includes a microchip 724 disposed in a block 726 of an electrically insulative substrate. The block 726 is sized to fit into the aperture 720 with the outer walls of the block 726 adjacent the inner surfaces of the aperture 720. Fastener elements 728A. 728B extend from side surfaces of the block 726 and are configured to engage fastener elements 722A, 722B. The fastening elements 722A, 722B are also wedge shaped fastening elements. Some of fastening elements 728A are electrically conductive and other fastening elements 728B are electrically insulative. Electrically conductive fastening elements 728A can include (e.g., be made of an electrically conductive material) or can be plated. Leads 721 (e.g., wires or traces of conductive material) electrically connect the microchip 724 with electrically conductive fastening elements 728A.
Referring to
Referring to
In use, the identification product 700 is inoperative when microchip assembly 716 is not installed in RFID module 710. When it is desired to activate the identification product 700, a user presses the microchip assembly 716 into the aperture 720 until the fastener elements 728 engage the fastener elements 722. Other embodiments are implemented using other types of fastener elements (e.g., molded hooks on the microchip assembly 716 and loop material on the antenna assembly 714). Contact between electrically conductive fasteners elements 722A and electrically conductive fastener elements 728A provides an electrical connection between the antenna assembly 714 and the microchip assembly 716. If desired, the user can render the identification device 700 inoperative by sliding the microchip assembly out the antenna assembly 714 through the side opening 721 of aperture 720. Some embodiments are implemented with an aperture 720 that does not include a side opening.
In any of the above-described RFID fastener products, the male fastener elements themselves may have a conductive surface, for providing electrical power and/or communication through a hook-loop or hook-hook interface, such as is taught in U.S. Pat. No. 6,977,055, issued Dec. 20, 2005 and incorporated by reference herein in its entirety.
Other useful features can be found in PCT Application Serial No. PCT/US01/46045, filed Oct. 25, 2001, U.S. Provisional Application Ser. No. 60/293,743, filed May 25, 2001, U.S. Provisional Application Ser. No. 60/323,244, filed Sep. 19, 2001, U.S. Provisional Application Ser. No. 60/243,353, filed Oct. 25, 2000, and U.S. application Ser. No. 10/423,816, filed Apr. 25, 2003, the entire contents of all of these earlier filings being hereby fully incorporated by reference.
A number of embodiments of the invention have been described. Nevertheless, it will be understood that various modifications may be made without departing from the spirit and scope of the invention.
In another example, referring to
Accordingly, other embodiments are within the scope of the following claims.
This application claims the benefit of U.S. Provisional Patent Application No. 60/805,454, filed Jun. 21, 2006, which is incorporated herein by reference in its entirety.
Number | Date | Country | |
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60805454 | Jun 2006 | US |