Shoe inserts have long been used to provide better fit, feel and support for the foot within a shoe. Such inserts range from simple linings, to contoured paddings, to support orthotics. They also range from inexpensive standard insoles, to very expensive custom-fit inserts. Inexpensive insole options, which often fail to provide sufficient fit and comfort, are currently produced by one of the following methods: “boil and wear” type solutions, ski-shop spray or heat form solutions. More custom-fit or personalized shoe inserts tend to be very expensive, and the fitting process sometimes involves a trip to a physician's office or to a location with specialized fitting equipment where a scan or mold of the foot can be made. The customer will often have to wait days or weeks for delivery of the final insert.
The present invention relates to an improved custom-fit, personalized footbed or insole that is inexpensive and easy to use.
In accordance with the foregoing objectives and others, one embodiment of the present invention provides a customizable footbed. The customizable footbed comprises a top layer which, when the footbed is in an operating configuration faces a bottom of a foot. The customizable footbed also comprises a bottom layer opposite the top layer which, when the footbed is the operating configuration is positioned away from the bottom of the foot. The top and bottom layers defining an intermediate space therebetween. For example, the bottom layer may comprise an elastomeric polymer. The customizable footbed further comprises a plurality of packets arranged within the intermediate space. Each packet may comprise an exterior membrane defining a chamber therein, and an interior filling within the chamber. The exterior membrane may comprise a thermoplastic polymer, in particular a low-density polyethlyene polymer. The exterior membrane may also have an average thickness from about 5 mm to about 10 mm. The interior filling may be selected from a group consisting of two or more components of a curable material that chemically react upon mixing of the components to irreversibly form a solid or semi-solid resin or a gel. The curable material may be a two-component or multi-component resin that spontaneously reacts upon mixing of the components. For example, the curable material may be selected from a group consisting of polyurethane resins, silicone resins, epoxy resins, and melamin resins. In another example, the curable material may be a quick-curing material that solidifies into a desired shape within 30 mins upon mixing of the components. The plurality of packets may be configured to burst upon application of a pressure corresponding to that of the foot being rocked back and forth on the top layer such that the interior fillings of the packets flow into and mix within the intermediate space. For example, the plurality of packets may be configured to burst upon application of a pressure from about 0.1 N/cm2 to 1 kN/cm2. In some examples, each of the plurality of packets may have a three-dimensional shape. In particular, the three-dimensional shape may be selected from a group consisting of hemis-spherical, cubic, hexagonal prism, pentagonal prism, rectangular prism, square prism, cone, and tetragonal pyramid shapes. More particularly, the each of the plurality of packets may have a square prism shape, in particular, a ratio of a width and a height of the square prism is from about 1:2 to about 2:1, specifically 1:1. In one example, the plurality of packets may be uniformly sized and shaped, and arranged in a two-dimensional array. Furthermore, the packets may be spaced apart by a distance from about 0.05″ to about 0.1″. In another example, the plurality of packets may be arranged to form at least a first two-dimensional array across a first section of the footbed corresponding to a first portion of the foot, and a second array forming a second section of the footbed corresponding to a second portion of the foot. Furthermore, the plurality of packets may be formed from a singly shaped polymeric film bonded to a flat polymeric film.
In one aspect, a self-customizing footwear is provided. The self-customizing footware may comprise an upper, an insole, and an outsole. The insole comprises a top layer which, when the insole is in an operating configuration is faces a bottom of a foot. The insole also comprises a bottom layer opposite the top layer which, when the insole is the operating configuration is positioned away from the bottom of the foot. The top and bottom layers defining an intermediate space therebetween. The insole further comprises a plurality of packets arranged within the intermediate space, each packet comprising an exterior membrane defining a chamber therein, and an interior filling within the chamber. The interior filling may be selected from a group consisting of two or more components of a curable material that chemically react upon mixing of the components to irreversibly form a solid or semi-solid resin or a gel. The plurality of packets may be configured to burst upon application of a pressure corresponding to that of the foot being rocked back and forth while wearing the footware such that the interior fillings of the packets flow into and mix within the intermediate space.
In another aspect, a method for customizing a footbed to coform to contours of a foot is provided. The method may comprise a first step of applying a pressure to burst a plurality of packets. Each packet comprising an exterior membrane defining a chamber therein, and an interior filling within the chamber. The interior filling may be selected from a group consisting of two or more components of a curable material. The method may also comprise a step of mixing the components of the curable material to initiate a chemical reaction such that the components irreversibly react to form a solid or semi-solid resin or a gel. The method may further comprise a step for holding the foot against the footbed for a period of less than 30 mins such that the curable material reacts to form a shape comforming to the courtours of the foot.
In a futher aspect, an alternative embodiment for a customizeable footbed is provided. The customizable footbed comprises a top layer and a bottom layer. The customizable footbed further comprises a plurality of blister packets arranged between the top and bottom layers. Each packet comprises an exterior membrane defining a chamber therein, and an interior filling within the chamber. The interior filling may be selected from a group consisting of two or more components of a curable material that chemically react upon mixing of the components to irreversibly form a solid or semi-solid resin or a gel. The plurality of blister packets may be configured to rupture upon application of a pressure corresponding to that of the foot being rocked back and forth on the top layer such that the interior fillings of the packets intermix.
These and other aspects of the invention will become apparent to those skilled in the art after a reading of the following detailed description of the invention, including the figures and appended claims.
This invention relates to an improved footbed technology that provides a custom-fit, mold-on-demand footbed which molds to the contours of the foot, is pliable, and has the feel of a gel. Please note that in this application, the terms “footbed”, insole”, and “insert” are used interchangeably. In particular, a customizeable footbed comprising an elastomeric bottom layer and a layer of burstable packets coupled to the bottom layer, wherein at least one of the burstable packets have a curable liquid may be provided. The footbeds of the present invention contain a top layer and bottom layer with packets, capsules, blister packets, blisters or bladders (hereinafter referred to as “packets”) arranged in between the two layers, e.g., the top layer and the bottom layer. In one embodiment, the top layer and the bottom layer may define an intermediate space therebetween. A plurality of packets may be arranged in the intermediate space and may each have an exterior membrane defining a chamber therein. The chambers may be filled with an interior filling, which may comprise a component of a two-component or multi-component curable material. The components of the curable material may chemically react, e.g., crosslink, to form a solid or semi-solid resin or a gel. The exterior membrane of the packets may be formed from a material such that the packets burst during a custom-fit molding process, thereby releasing components of the curable material and allowing the components to be mixed with each other. Packets may take different shapes, sizes, two-dimensional positioning, or wall thickness in order to tune the packet's burst strength. In some applications, it may be important that certain packets burst before others so a mixture of burst strengths may be desired.
More particularly, the packets may contain components that set or cure upon release from the bursted packets and may combine and react with contents of adjacent packets to initiate curing. Upon mixture of the components, the curable material may begin to cure or set, with or without further reaction or stimuli. In some embodiments, the components of the curable material may spontaneously react with each other upon mixing of the components. In other embodiments, a portion of the packets may contain a catalyst and/or a crosslinking reagent for inititiating a chemical reaction, in particular, a cross-linking reaction between different components of the curable material.
When in use, the footbed with the mixed components may be held against a user's foot such that the curable material cures or sets in a shape that conforms to the contours of the user's foot. The different components released from the packets may flow into each other and pool within the intermediate space, particularly in areas under the foot where voides may exist, e.g., under the arch area, or around the toes. The mixed components may begin to set and cure and solidify after a period of time, preferably a short period of time, such that the curable material surrounds and corresponds to a contour of the foot, e.g., defining a perimeter of the foot and flowing betwewn the toes, arch and metatarsal areas. For example, the curable material may flow under the midfoot or an arch area of the foot, which allows the material to cure and set to provide a cured and lasting impression of the contours of midfoot, arch or the entire foot.
In one exemplary embodiment, the top and bottom layers are both made of an elastomeric film, and the packets arranged in between the two layers are made from a thermoplastic material. These packets can contain materials that begin to set or cure upon release from the packets and mixing/reacting with contents of adjacent packets. The packets are arranged in arrays and compartments and can be configured to optimize fit upon cure. The packets are arranged in arrays, separated into sections or compartments that correspond to different parts of the foot, e.g., section for toes, section for arch, section for heel (See
As discussed above, the footbed may comprise a top layer. The top layer may be configured such that in an operating configuration, i.e., when the footbed is being worn by a user in footwear (e.g., inserted into a shoe), the top layer faces a bottom of a foot of the user. The top layer may comprise any suitable material that is wearable against a body part, in particular, that is comfortable against the bottom of the foot, for example, a fabric and/or a polymeric film. In one embodiment, the top layer may comprise a fabric. In another embodiment, the top layer may comprise an elastomeric material, in particular in the form of an elastomeric film. In an alternative embodiment, the top layer may comprise a thermoplastic material, e.g., a thermoplastic polymer. More particularly, the thermoplastic material may comprise a thermoplastic polyurethane (TPU), e.g., a TPU laminate with fabric. The top layer may have any suitable thickness. In some exemplary embodiments, the top layer may have a thickness from about 0.5 mm to about 10 mm, from about 0.5 mm to about 5 mm, or from about 1 mm to about 3 mm.
The footbed may also comprise a bottom layer, which may be configured such that in an operating configuration, i.e., when the footbed is being worn by a user in footwear (e.g., inserted into a shoe), the bottom layer is opposite the top layer away from the bottom of the foot of the user. The bottom layer may also comprise any suitable material, for example, a polymeric form former, that is comfortable for insertion into footwear (e.g., a shoe). In one embodiment, the bottom layer may comprise an elastomeric material, in particular in the form of an elastomer film. In an alternative embodiment, the bottom layer may comprise a thermoplastic material, e.g., a thermoplastic polymer. More particularly, the thermoplastic material may comprise a thermoplastic polyurethane (TPU) film. The bottom layer may have any suitable thickness. In some exemplary embodiments, the bottom layer may have a thickness from about 1 mm to about 15 mm, from about 3 mm to about 12 mm, from about 5 mm to about 10 mm, or from about 7 mm to about 9 mm.
In one exemplary embodiment, the top layer and/or the bottom layer is preferably made from a breathable, anti-bacterial, anti-fungal and/or anti-odor material. In another exemplary embodiment, the top layer and/or bottom layer may comprise anti-bacterial, anti-fungal and/or anti-order agent embedded within a polymeric film (e.g., an elastomeric film or a thermoplastic film).
In some embodiments, the interior chamber of the packets may be filled with liquids having high viscosities such that additional mixing by an external source may be necessary. Typically, such additional source for mixing may be applied by hand or by foot or feet of a user with any type of motion, typically natural motion. For example, such high viscosity fluids may have a viscosity of greater than 1000 cps, greater than 1200 cps, or greater than 1500 cps. The user may burst some or all of the packets by hand prior to putting the insert into the shoe, to aid in mixing, reduce mixing time, or otherwise aid in the custom-molding. For example, the user may apply pressure from the user's hands, such as a pressing or a twisting motion by the hands. The user may also apply additional pressure and mixing by foot, such as by rocking back and forth while standing or pressing against the footbed.
The exterior membrane of the packets may be formed from any suitable material that can discharge the interior filling therein upon application of the desired pressure, as discussed above. In one particulr embodiment, the exterior membrane comprises a thermplastic polymer, e.g., a thermoplastic film former. More particularly, the thermoplastic material may comprise a thermoplastic polyurethane (TPU) or a low density polyethylene (LDPE), which may be in the form of a polymeric film. The exterior membrane may have any suitable thickness. In some exemplary embodiments, the exterior membrane may have a thickness or an average thickness from about 1 mm to about 20 mm, from about 3 mm to about 18 mm, or from about 5 mm to about 15 mm, or from about 8 mm to about 12 mm. In one particular embodiment, the exterior membrane may have an average thickeness from about 5 mm to about 10 mm. The exterior membrane may also be formed from two or more separate sheets of polymer film that are sealed together by any suitable means, including a seal, a weld, an adhesive, etc., which are discussed further below.
As discussed above, the burstable packets 1 may contain different components of a curable material that when mixed react to form a solid or semi-solid resin or a gel. Generally, the packets may contain solid, liquid or gaseous components (or mixtures thereof or suspensions containing such) that, when mixed, result in some chemical reaction that cures the materials to become a solid in the desired shape and form. In some embodiments, the mixing or reaction may also produce some other effect or attribute such as heat, cold, light, or color change. The color change may aid in identifying whether the bursting and mixing has been performed sufficiently. Each packet may contain one or more of the solid, liquid or gaseous component. In particular, the packets can be filled with a range of two-component or multi-component reactive liquids. For example, each packet may contain one or more of the reactive liquids. Examples of reactive liquids are two-component resins, such as polyurethane resins, silicone resins, epoxy resins, melamin resins, and polyurea resins; multi-component liquid reactants to affect the production of heat, such as in the dissolution of calcium chloride into water; multi-component liquid reactants to affect the lowering of the temperature, such as the dissolution of ammonium chloride into water; and multi-component liquid reactants to affect the production of light, such as the mixing of luminol and hydrogen peroxide.
In some exemplary embodiments, the components of the curable material may chemically react, e.g., crosslink, to form a solid or semi-solid resin or a gel. Suitable curable materials may include polyurethane resins, silicone resins, epoxy resins, melamin resins, and polyurea resins. The components may further comprise additional additives that may impart a detectable change upon reaction, e.g., a color change or activating chemiluminescence (e.g., mixing of luminal and hydrogen perioxide). The reaction of the components of the curable material may be either exothermic (i.e., generate heat) or endothermic (i.e., reduces heat). However, the exothermic or endothermic changes of the reaction should be within a tolerable range of temperature changes to the human skin, for example, the exothermic reaction should not release energy that raises the temperature of the footbed to above 90° C., prefereably the temperature should be maintained below 75° C., more preferably below 50° C. Similarly, the endothermic changes of the reaction should not reduce the temperature of the footbed to below 0° C., preferably the temperature should be maintained above 10° C., more preferably above 20° C.
In particular, the components of the curable material may comprise a first component comprising monomers, and a second component comprising crosslinking reagents. Alternatively, the components of the curable materials, e.g., monomers for crosslinking, may be reactive upon exposure to air or components found within ambient air, such as moisture or oxygen. In other embodiments, a portion of the packets may contain a catalyst and/or a crosslinking reagent for initiating a chemical reaction, in particular, a cross-linking reaction between different components of the curable material. In some embodiments, the components of the curable material may spontaneously react with each other upon mixing of the components.
Suitable two-component curable materials may include a first component (which is also referred to herein after as Component A), and a second component (which is also referred to hereinafter as Component B). In one particular embodiment, the two-component curable material may be a silicone. For example, Component A and Component B may comprise a vinyl-terminated dimethylpolysiloxane and a silicon-hydride crosslinker with platinum catalyst, respectively. In particular, the two-components may comprise commerically available silicone components: Andisil® 204-37C and Andisil® 204-37D.
In a preferred embodiment, the components of the curable material may comprise different reagents for a quick-cure or quick-set curable material. For example, the components of the quick-cure or quick-set curable material may begin to cross-link upon mixing of the components with each other. The quick-cure or quick-set curable material may form a solid or semi-solid resin or a gel in the desired shape, e.g., conforming to contours of a foot, as it crosslinks within about 1 hour of initial mixing, preferably within about 45 mins of initial mixing, more preferably within about 30 mins of initial mixing, and even more preferably within about 20 mins of initial mixining. Even more preferably, the quick-cure or quick-set curable material may solidify or gel within a short period of time, e.g., less than 5 mins, or less than 3 mins.
The plurality of packets may have any suitable shape. In some embodiments, the packets may be made in different three-dimensional structures, aspect ratios, and overall dimensions, including but not limited to height, width, and wall thickness for different applications. The three-dimensional structure of the packets can be any three-dimensional closed solid compromising flat, contoured and/or curved surfaces; some examples are hemi-spherical, cubic, hexagonal prism, pentagonal prism, square prism, rectangular prism, cone, and tetragonal pyramid shapes. In some embodiments, the plurality of packets may all have a uniform size and/or shape. For example, as shown in
Alternatively, the packets may each have a regular or irregular three-dimensional shape and may have any suitable aspect ratio. For an irregular shape, the aspect ratio may be defined as a ratio of an average lateral cross sectional diameter to a height of the shape, which may range from about 1:2 to about 2:1, and preferably about 1:1. The above describe aspect ratios are not limited to irregular shapes, but may be also used for any suitable polygonal three-dimensional shape.
Furthermore, the plurality of packets may be arranged two-dimensionally on a flat or curved surface. For example, the plurality of packets may be arrange across the bottom layer of the footbed. The curvature of the two-dimensional array may be optimized to maximize the ease of packet bursting by the user. The spacing, distribution, shape, and size of the packets can also be varied to maximize the ease of bursting by the user. The spacing between the packets may vary between a nil thickness and 100 centimeters. More particularly, the spacing between packets may range from about 0.01″ to about 0.5″, from about 0.03″ to about 0.3″, or from about 0.05″ to about 0.1″. Packets may be all the same size and shape or comprise a variety of different shapes within the same footbed. In one embodiment, the packets may be arranged to form a two-dimensional arrange along the length and width of the footbed. Such an arrangement may be useful for optimizing fit against an entire contour of the foot upon mixing and curing of the components of the curable material.
The most preferable arrangement of packets is a pattern of identical shaped and sized close-packed polygonal prisms, such as cubes, rectangular prisms, or hexagonal prisms. This arrangement allows the air to be evacuated efficiently from the outside thermoplastic, elastomeric bag. In this arrangement, a two-component resin can be distributed in packets such that parts A and B (i.e., the parts to be mixed) are spaced out in separate packets an alternating fashion. Such an alternating arrangment may further allow for through mixing of components A and B upon bursting of the packets.
As shown in
In some embodiments, the plurality of packets may be arranged to form multiple arrays arranged across different sections of the foot. In one embodiment, the plurality of packets may be arranged to form at least a first two-dimensional array across a first section of the footbed corresponding to a first portion of the foot, and second array forming a second section of the footbed corresponding to a second portion of the foot. In one exemplary embodiment, each section is sealed from the next section such that no fluid communicates between the different sections. In some embodiments, each section may be compartmentalized to control the flow of the components of the curable material to different areas of the foot. For example, an area of the footbed corresponding to the toes may comprise one compartment/section of burstable packets, an area of the footbed corresponding to an arch area of the foot may comprise another compartment/section of burstable packets, and an area of the footbed corresponding to a heel portion of the foot may also comprise a futher compartment/section of burstable packets to direct curable material to desired locations to allow for improved shaping of the footbed to provide proper foot support in these desired regions.
Each section may also include packets that are sized and shaped suitable for that particular section, for example, a first section may comprise an array having a first set of uniformly sized and shaped packets that are different from a second set of uniformly sized and shaped packets that are part of a second section. Although two different sections are discussed above, it is understood that more than two sections and therefore, more than two two-dimensional arrays may be utilized in the footbed of the present invention.
As can be seen in
In one exemplary embodiment, the plurality of packets may be formed by bonding together two plastic sheets, preferably two polymeric films, more particularly two thermoplastic films. The two plastic sheets that bond together to form the packet may both be thermoformed, blow molded, or otherwise shaped to define the packet volume or only one sheet can be shaped. The preferred embodiment for the moldable footbeds is a singly shaped low-density polyethylene sheet bonded to a flat low-density polyethylene sheet. In the preferred embodiment for the moldable footbed, the polyethylene is thermally welded to the adjacent sheet to define the seams of each packet.
Packets may be formed from any materials that can be sealed to each other by some means. Methods of sealing the packet seams include thermally welding, sonically welding, mechanically folded together, using a curable adhesive, or using a hot-melt adhesive or thermoplastic). For other applications, the packets could be formed by thermal or sonic welding of thermoplastic sheets or it may be desirable to use an adhesive or other material to form a significantly stronger or weaker bond to tune the delamination of the packet seam. For example, all inner seams of the individual packets in the array may be tuned to delaminate while the outer seams remain laminated such that the packet array becomes one continuous pouch after bursting. The shaped plastic sheet could also form packets with hard non-porous surfaces, such as glass, metal, rock, or a coated surface.
In a preferred method of making the footbed of the present invention, the packet arrays are formed by vacuum forming thermoplastic sheets into bubble sheets. The thermoplastic material can survive strenuous conditions during manufacturing, shipment and handling but bursts when body weight pressure is applied. This prevents premature curing and preserves on-demand molding functionality. The arrayed packets are filled with resin and a backing layer is thermally sealed to the open back of the packets to form an arrayed sheet of packets, which can be seen in
In another embodiment, the footbed of the present invention may be enclosed in a compartment within the shoe. The footbed may be enclosed in a way that it may be slid in and out, removed and replaced, or permanently enclosed.
The footbed may be included in an item of self-customizing footwear. The item of self-customizing footware may comprising an upper, an insole, and an outsole, wherein the insole comprises an elastomeric upper layer positioned to contact with the bottom of the foot; an elastomeric bottom layer coupled to the outsole; and a middle layer enclosed between the upper layer and lower layer; and the middle layer comprising a plurality of burstable packets having a curable liquid material. Additionally. at least some of the burstable packets are configured to burst under pressure from a foot subject to a weight bearing action, and wherein upon bursting, the curable liquid material flows within the enclosed middle layer to conform to and solidify in the shape of the foot. The middle layer may also be divided into a plurality of compartments, wherein the quantity and/or composition of curable liquid material differs between each of the compartments. Furthermore, the compartments may be configured to control flow of material and compensate for different pressure applied by different portions of the foot during the weight bearing action.
The steps for producing footbeds of a preferred embodiment of the present invention are as follows: First, materials are prepared by cutting LDPE, TPU, fabric, and transfer adhesive to the proper size required. With the LDPE sheeting, custom bubble arrays are formed by vacuum thermoforming of the film. The LDPE sheeting is brought into close proximity of a high temperature heat source, kept at 275° C. Once the material begins to soften and exhibits characteristics of melting, the sheeting is then brought into contact with a custom mold that is arranged on a vacuum plate, allowing the softened material to form a net shape of the custom mold. Once this custom bubble arrangement is formed, the piece is then placed into a custom holder with rigid channels between the formed bubbles, allowing the bubbles to hang freely. In this holder, silicone components are then loaded into the bubbles in an alternating fashion. Once the bubbles are filled, a sheet of LDPE is then laid across the loaded bubbles. Using a high temperature and high pressure pneumatic thermal press, this film is pressed into the custom bubble arrays, forcing a high pressure gradient where the rigid channel below lies, allowing the LDPE to seal to itself through the silicone contamination. This completes the formation of the silicone loaded bubble arrays.
Using the prepared TPU sheeting, two films are placed directly on top of one another and a desired fabric top cover is applied to the top surface using a double sided transfer tape adhesive. With the fabric in place, the silicone loaded bubble array is aligned in proper position in between the two TPU sheets. With this array in place, three sides of the film stack are heat sealed, creating TPU-TPU bonds around the outer edge. With these seals completed, the final open side is then used to evacuate the excess air held within the films, creating a vacuum tight seal of the TPU sheeting around the custom bubble arrays. Once the air has been evacuated, the TPU sheets are then heat sealed using a custom sealing plate kept at high temperature and pressure, forming the overall shape of an insole complete with sealed partitions in specific areas of the insole to separate bubbles in certain regions of the foot. Once this seal has been created, the net shape desired for further manufacturing is then cut and the custom moldable layer of the insole is completed.
The materials used for the production of the insoles, including the commercial suppliers' information, are as follows:
In another embodiment, the packets may be formed in a square prism blisters having the following aspect dimensions. 0.25″×0.25″×0.25″ (1:1 aspect ratio). The packets may contain two different interior fillers (A and B) arranged in an alternating fashion. Each packet may be spaced apart from an adjacent packet by a gap between 0.05″-0.1″.
The materials used for the production of the insoles, including the commercial suppliers' information, are as follows:
Interior filling/silicone:
Andisil® 204-37C having a viscosity—1950 cps
Andisil® 204-37D having a viscosity—1450 cps
1:1 mixed gel time (20 sec mix)—55 sec
Properties—cure 20 minutes at RT:
Bottom TPU Layer: Product: DT 7101, polyether TPU film
Top Fabric Specs:
Product: Jump Spacer+2 mil TPU Laminate+Print
Company: Cosmo Fabrics
Packet exterior membrane: LDPE
The invention described and claimed herein is not to be limited in scope by the specific embodiments herein disclosed since these embodiments are intended as illustrations of several aspects of this invention. Any equivalent embodiments are intended to be within the scope of this invention. Indeed, various modifications of the invention in addition to those shown and described herein will become apparent to those skilled in the art from the foregoing description. Such modifications are also intended to fall within the scope of the appended claims. All publications cited herein are incorporated by reference in their entirety.
This application claims priority to U.S. Provisional Patent Application Ser. No. 62/295,863 filed Feb. 16, 2016, the entire contents of which is hereby incorporated by reference herein.
Number | Date | Country | |
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62295863 | Feb 2016 | US |