The present disclosure relates to packaging materials. More particularly, the present disclosure is directed to devices and methods for manufacturing inflatable cushions to be used as packaging material.
Shoes are produced and typically shipped in paperboard cartons for transportation and sale. Typically, to protect the shoes from being crushed or damaged during transportation and prior to sale, many producers insert paper wadding, molded pulp shapes, or other combinations of materials to maintain the form factor of the shoe. If the shoes are not filled, then during long shipping cycles the shoes will take or form memory in various shapes that will not meet the consumer esthetics when they try on the shoes. The use of molded pulp or crumpled paper not only is used as filler to retain the shape but it has no memory and can be crushed during transportation and storage. These materials also do not have the consumer appeal and marketing that shoe company's desire. They also carry extra weight and cost when used as filler. Recently, alternatives have come to maker such as blow molded shapes made to try and fill out the cavity of the shoe to maintain the shape, but they do not have the ability to cove a range of sizes without individual forms being made.
A variety of inflated cushions are known and used for sundry packaging applications. For example, inflated cushions are often used as void-fill packaging in a manner similar to or in place of foam peanuts, crumpled paper, and similar products. Also for example, inflated cushions are often used as protective packaging in place of molded or extruded packaging components. Generally, inflated cushions are formed from films having two plies that are joined together by seals. The seals can be formed simultaneously with inflation, so as to capture air therein, or prior to inflation to define a film configuration having inflatable chambers. The inflatable chambers can be inflated with air or another gas and thereafter sealed to inhibit or prevent the release of the air or gas.
In an example, an inflatable shoe insert assembly may have an elongated tubular element formed of opposing, flexible, polymeric plies that are sealed together to define a tubular inflation chamber that is narrow and elongated and is configured to seal inflation fluid therein; a shoe-upper element formed of opposing, flexible, polymeric plies that are sealed together to define a shoe-upper inflation chamber configured to seal inflation fluid therein; wherein tubular and shoe upper inflation chambers are configured and dimensioned to fit together into a shoe and support each other in an installed position to cooperatively support and maintain the shape of the shoe upper.
The present disclosure is related to inflated packaging elements, such as shoe-packaging inserts for preserving the shape of a shoe and reducing deforming during shipping. Illustrative embodiments will now be described to provide an overall understanding of the disclosed apparatus. Those of ordinary skill in the art will understand that the disclosed apparatus may be adapted and modified to provide alternative embodiments of the apparatus for other applications, and that other addition s and modifications may be made to the disclosed apparatus without departing from the scope of the present disclosure. For example, features of the illustrative embodiments may be combined, separated, interchanged and/or re-arranged to generate other embodiments. The embodiments shown can be used for a variety of inflated packaging elements, such as shoe inserts. A person of ordinary skill in the art would understand that modifications, variations, and combination are included within the scope of the present disclosure.
In accordance with various embodiments, the uninflated element is an uninflated shoe insert configured for placement in an individual shoe. For example, two individual uninflated inserts form a pair of uninflated inserts. A pair of uninflated inserts may have two individual uninflated inserts that are similarly shaped. A pair of uninflated inserts may be inflated and then assembled or packaged with a pair of shoes. One inflated insert of the pair of inserts is positioned within one shoe of the pair of shoes. For example, a first pair of uninflated inserts may have two similarly shaped uninflated inserts, one to be later inflated per individual shoe. One of uninflated insert may be differently shaped than a second uninflated insert that is also configured to be later inflated and packaged with a shoe. A later inflated insert may be positioned near the front portion or vamp region of the shoe, and another later inflated insert may be positioned in the rear portion or quarter region of the shoe. A unit of uninflated inserts may contain at least two pairs of uninflated inserts, and each pair may be dissimilarly shaped with the other pair of uninflated inserts.
In one example, the uninflated element is an uninflated shoe insert. The multi-ply structure 100 may have individual, similarly shaped uninflated inserts. In another example, the multi-ply structure 100 may have individual, dissimilarly shaped uninflated inserts. In another example, the multi-ply structure 100 may have multiple pairs of similarly shaped uninflated inserts, each pair of individual uninflated inserts being similarly shaped. In another example, the multi-ply structure 100 may have multiple pairs of dissimilarly shaped uninflated inserts, with each pair of individual uninflated inserts being similarly shaped. In another example, the multi-ply structure 100 may have multiple units of uninflated inserts, with similar and dissimilar pairs of uninflated inserts. In another example, the multi-ply structure 100 may have multiple units of individual inserts. In another example, the multi-ply structure 100 may have a combination of uninflated inserts, pairs of uninflated inserts, and units of uninflated inserts.
The individual inserts may have a single seal pattern or a variety of seal patterns to form inflation chambers of the inserts. The seal pattern may form the inflation chambers regardless if the insert is inflated and sealed using an inflating and sealing machine with continuous inflation, an inflation machine with valves, inflation and sealing machine that inflates and seals an individual insert, or an inflation machine that inflates individual inserts with valves.
With reference to
For reference, the transverse direction 104 extends generally perpendicular to the longitudinal direction. The transverse direction 104 may correspond to an overall width of the multi-ply structure 100. For example, a roll of the multi-ply structure 100 may have a width in the transverse direction that is a few inches wide up to a few feet wide.
The flexible structure 100 of
In some examples, the first and second plies 105, 111 join to define a first longitudinal edge 117 and a second longitudinal edge 119 (both extending in the longitudinal direction 102) of the film 100. The first and second plies 105, 111 can be formed from a single sheet of flexible structure material, a flattened tube of flexible structure with one edge having a slit or being open, or two sheets of flexible structure. For example, the first and second plies 105, 111 may be formed from a single sheet of flexible structure 100 that is folded to define the joined second edges 109, 115 (e.g., “c-fold film”). Alternatively, for example, the first and second plies 105, 111 can include a tube of flexible structure (e.g., a flattened tube) that is slit along the aligned first longitudinal edges 107, 113 or the second aligned longitudinal edges 109, 115. Also, for example, the first and second plies 105, 111 can include two independent sheets of flexible structure joined, sealed, or otherwise attached together along the aligned first longitudinal edges 107, 113 or the second aligned longitudinal edges 109, 115.
The flexible structure 100 can be formed from any of a variety of web materials known to those of ordinary skill in the art and as such the flexible structure 100 may also be referred to as a web or web 100 herein. Such web materials include, but are not limited to ethylene vinyl acetates (EVAs), metallocenes, polyethylene resins such as low density polyethylene (LDPE), linear low density polyethylene (LLDPE), and high density polyethylene (HDPE), and blends thereof. Other materials and constructions can be used. The disclosed flexible structure 100 may be rolled on a hollow tube, a solid core, or folded in a fan-folded box or in another desired form for storage and shipment.
In some embodiments, the web plies 105, 111 are between 10 and 100 microns thick. In some embodiments, the web plies 105, 111 are at least 20 microns thick. For example, in an embodiment, the web plies 105, 111 may be between 50 and 75 microns thick.
In some embodiments, the web plies 105, 111 are made from a co-extruded material that contains nylon. For example, the web plies 105, 111 may be made from polyethylene and nylon. Materials containing nylon serve as an air barrier and retain the air over the shipping and storage cycle of shoes. Other suitable materials and constructions can be used.
A multiply web 100 may be made of a monolayer or multilayer polymeric film material. Each ply may be made from a monolayer or multilayer film. Monolayer films are typically made of polyethylene, although other suitable polymers may be used. The one or more layers of multilayer film embodiments may include polymers of differing compositions. In some embodiments, the disclosed layers may be selected from ethylene, amide, or vinyl polymers, copolymers, and combinations thereof. The disclosed polymers can be polar or non-polar. The disclosed ethylene polymers may be substantially non-polar forms of polyethylene. In many cases the ethylene polymer may be a polyolefin made from copolymerization of ethylene and another olefin monomer, for example an alpha-olefin. The ethylene polymer may be selected from low, medium, or high density polyethylene, or a combination thereof. In some cases, the density of various polyethylenes may vary, but in many cases the density of low density polyethylene may be, for example, from about 0.905 or lower to about 0.930 g/cm3, the density of medium density polyethylene may be, for example, from about 0.930 to about 0.940 g/cm3, and high density polyethylene may be, for example, about 0.940 to about 0.965 g/cm3 or greater. Other suitable densities of various polyethylenes may be used. The ethylene polymer may be selected from linear low density polyethylene (LLDPE), metallocene linear low density polyethylene (mLLDPE), high density polyethylene (HDPE), medium density polyethylene (MDPE), and low density polyethylene (LDPE).
In some embodiments, the polar polymer may be a non-polar polyethylene which may be modified to impart a polar characteristic. In other embodiments the polar polymer is an ionomer (e.g. copolymers of ethylene and meth acrylic acid, E/MAA), a high vinyl acetate content EVA copolymer, or other polymer with polar characteristics. In one embodiment the modified polyethylene may be anhydride modified polyethylene. In some embodiments, the maleic anhydride is grafted onto the olefin polymer or copolymer. Modified polyethylene polymers may react rapidly upon coextruding with polyamide and other ethylene containing polymers (e.g., EVOH). In some cases a layer or sublayer comprising the modified polyethylene may form covalent bonds, hydrogen bonds and/or, dipole-dipole interactions with other layers or sublayers, for example sublayers or layers comprising a barrier layer. In many embodiments, modification of a polyethylene polymer may increase the number of atoms on the polyethylene that are available for bonding. For example, modification of polyethylene with maleic anhydride adds acetyl groups to the polyethylene, which may then bond with polar groups of the barrier layer, for example hydrogen atoms on a nylon backbone. Modified polyethylene may also form bonds with other groups on the nylon backbone as well as polar groups of other barrier layers, for example alcohol groups on EVOH. In some embodiments, a modified polyethylene may form chain entanglements and/or van der Waals interactions with an unmodified polyethylene.
The layers of the plies 105, 111 may be adhered or otherwise attached together, for example, by tie layers. In other embodiments, one or more of the plies 105, 111 are a single layer of material, for example, a polyethylene layer.
Mixtures of ethylene and other molecules may also be used. For example, ethylene vinyl alcohol (EVOH) is a copolymer of ethylene and vinyl alcohol. EVOH has a polar character and can aid in creating a gas barrier. EVOH may be prepared by polymerization of ethylene and vinyl acetate to give the ethylene vinyl acetate (EVA) copolymer followed by hydrolysis. EVOH can be obtained by saponification of an ethylene-vinyl acetate copolymer. The ethylene-vinyl acetate copolymer can be produced by a known polymerization, such as solution polymerization, suspension polymerization, emulsion polymerization and the like, and saponification of ethylene-vinyl acetate copolymer can be also carried out by a known method. Typically, EVA resins are produced via high pressure autoclave and tubular processes.
Polyamide is a high molecular weight polymer having amide linkages along the molecular chain structure. Polyamide is a polar polymer. Nylon polyamides, which are synthetic polyamides, have favorable physical properties of high strength, stiffness, abrasion and chemical resistance, and low permeability to gas, for example oxygen.
As shown in
In accordance with various embodiments, each insert 101 includes a series of seals 121 disposed along the longitudinal extent of the flexible structure 100. The transverse seal 121 extends in the transverse direction 104. For each insert 101, the transverse seal 121 extends across a portion of the distance between the first longitudinal edge 117, and in the embodiment shown, towards the second longitudinal edge 119 (also extending in the longitudinal direction). Each transverse seal 121 can have a first end 125 proximate the first longitudinal edge 117 and a second end 127 proximate the inflation region 123. In some embodiments, the second end 127 may be spaced a dimension d1 (extending in the transverse direction 104) away from the second longitudinal edge 119. In some embodiments, the flexible structure 100 may also include a first longitudinal seal 129 proximate the first longitudinal edge 117 (for example, when the first and second plies 105, 111 include two independent sheets of flexible structure, the sheets 105, 111 may be joined, sealed, or otherwise attached together at the first longitudinal seal 129 aligned with the first longitudinal edges 107, 113). While the longitudinal seal 129 may be located at the longitudinal edge 117, they also may be offset from the longitudinal edge 117. In some examples the transverse seals 121 may extend to the longitudinal seal 129. In other embodiments, the transverse seal 121 may have the first end 125 proximal to the longitudinal seal 129 without intersecting the longitudinal seal 129. In other embodiments, the transverse seal 121 may intersect the longitudinal seal 129 and extend past it.
A chamber 131 is defined within a boundary formed by the first longitudinal edge 117 and a pair of adjacent seals 121 for each insert 101. The chamber 131 is configured to be inflated via the inflation region 123.
The inflation region 123 may be formed along the second longitudinal edge 119. In some embodiments, such as
In some examples, the inflation opening 136 is positioned in the transverse direction 104, and allows for a nozzle to be inserted into the inflation opening 136, the nozzle polsitioned in the longitudinal direction 102. The inflation region 123 may have a width of dimension D extending in the transverse direction 104. In some examples, dimension D is similar to the dimension d1, the distance between the second end 127 of the transverse seal 121 and the second longitudinal edge 119. In other examples, specifically in embodiments having a longitudinal seal 133, the dimension D is smaller than dimension d. In some embodiments, the second longitudinal seal 133 may be proximate or collinear with the second longitudinal edge 119. In other embodiments, the second longitudinal seal 133 is proximal to but offset from the second longitudinal edge 119. The second longitudinal seal 133 may form the portion of the inflation region 123 in embodiments with an inflation channel 122. In some embodiments with the second longitudinal seal 133, the width D is smaller than d1 by a value of the thickness of the second longitudinal seal 133.
In some examples, an inflation region 123 includes the two ends of plies 105, 111 that form an inflation opening extending in the longitudinal direction 102 generally parallel with the second longitudinal side 119, such that an air nozzle outlet may be aligned in the transverse direction 104 and positioned between the second longitudinal edges 109, 115 of the plies 105, 111 (that form the second longitudinal edge 119) to inject air into the uninflated chamber to later form an inflated insert. The second longitudinal edge 119 is not sealed by the second longitudinal seal 133 in this example.
In other examples, the inflation region and opening may be positioned near the center (with respect to the transverse direction 104) of the structure 100 with uninflated inserts (extending in the transverse direction 104) positioned on either side of the inflation opening.
In accordance with some embodiments, each of the transverse seals 121 as embodied in
The seals 121 as well as the longitudinal seal 129 may be formed from any variety of techniques known to those of ordinary skill in the art. Such techniques include, but are not limited to, adhesion, friction, welding, fusion, heat sealing, laser sealing and ultrasonic welding of the two plies 105, 111.
The first and second longitudinal edges 117, 119 and seals 121 cooperatively define boundaries of inflation chambers 131 for each uninflated insert 101. As shown in
In some examples, the seals and/or edges define an inflation port for feeding fluid into the inflation chambers, and the inflation ports are sealable for sealing the fluid in the inflation chambers. In some examples, the port is oriented to be sealable by a seal oriented generally parallel to the inflation region. In some examples, the pattern of seals and/or edges form an inflation region between the opposing plies, and the inflation chamber is in fluid communication with the inflation ports for inflating a plurality of inflation chambers through the inflation region and inflation region. In some examples, the inflation region is a circumferentially closed inflation region that directs the fluid to a plurality of the inflation ports.
In some examples, the opposing plies of the uninflated element may have a seal pattern that defines multiple uninflated elements that are separated from each other by a line of weakness. In some embodiments, the lines of weakness form a perimeter around the uninflated element that enable the uninflated elements to be separated from each other. In other embodiments, the lines may traverse a portion of or all of the transverse width of the flexible structure 100. The lines of weakness may also allow excess material to be removed from the uninflated elements. For example, the various lines of weakness may allow for excess material to be removed from a part of the inflated elements or the entire perimeter. The lines of weakness may be straight, curved, or any suitable shape. The may be positioned on top of or collinear with a seal, or positioned adjacent a seal.
In accordance with various embodiments, as shown in
In accordance with various embodiments, as shown in
The lines of weakness 137, 138 can include a variety of lines of weakness known by those of ordinary skill in the art. For example, in some embodiments, the lines of weakness 137 includes rows of perforations, in which a row of perforations includes alternating lands and slits spaced along the transverse extend of the row. The lands and slits can occur at regular or irregular intervals along the transverse extent of the row. Alternatively, in some embodiments, the lines of weakness 137 include score lines or the like formed in the flexible structure. The lines of weakness 138 may include similar features.
The lines of weakness 137, 138 may be formed from a variety of techniques known to those of ordinary skill in the art. Such techniques include, but are not limited to, cutting (e.g., techniques that use a cutting or toothed element, such as a bar, blade, block, roller, wheel, punch, or the like) and/or scoring (e/g/, techniques that reduce the strength or thickness of material in the first and second plies, such as electromagnetic (e.g., laser) scoring and mechanical scoring.)
In the embodiments of
In some examples, the uninflated inserts 101 are configured to be inflated and used in kids or adult shoes, ranging from US size 1 to US size 16. For example, a size 1 shoe may correspond to a foot length of 20 cm and a size 16 shoe may correspond to a foot length of 32 cm. The insert 101 has a high aspect ratio of length to width such that the insert 101 may later be inflated and easily folded about its width. In an example, the aspect ratio is at least 4:1. In another example, the aspect ratio is at least 10:1. In another example, the aspect ratio may be as high as 20:1 or 30:1.
Generally, a shoe has an upper and a sole. The upper of the shoe contains the sections of the shoe above the sole. The upper of the shoe has a vamp (or front of the shoe) and quarter (the sides and the back of the shoe). In some examples, the vamp includes the toe and tongue (if the shoe has a tongue). In some examples, the quarter include a rear quarter section where a user's heel may be positioned, and side quarter sections that include a lateral and medial sides of the shoes up to where they connect with the vamp.
In some examples, the length L of the inserts 101 corresponds to a value that is about twice up to three times the length of a shoe the insert will be installed within. This allows for the uninflated insert to be inflated and later folded in half or in thirds to be positioned in a shoe, so that portions of the vamp area and quarter area of the shoe may be supported. In some examples, the insert 101 length is less than twice that of the length of the shoe it will be installed within, such as when the shoe has a narrow vamp portion and the folded insert will not extend fully between the front and rear of the shoe. In other examples, the length L of the insert 101 is less than the length of the shoe, the insert is not folded about its width, and the insert is configured to be positioned in the quarter region of the shoe (see
In some examples, the uninflated element may be differently shaped than that of the inserts of
As shown in
In the embodiment of
In the example of
Intermediate seals 339 may be located within the chambers 331a between the intersection of the angled seal 322a and the seal 321a and seal 321c, and within chamber 331b between the intersection of the angled seal 322b and the seal 321b and seal 321c. In some embodiments, the intermediate seals 339 connect to or intersect with the seals 321a, 321b. In some embodiments, the intermediate seals 339 connect to the seal 321c. In some embodiments, as shown in
The intermediate seals 339 may act as flexible members or joints when the flexible structure 300 is later inflated and sealed, such that the inflated insert may be manipulated about itself along the intermediate seal 339. The location of intermediate seals 339 may be at a ratio of about ⅙ to ½ of the overall length of the seals 321, with the position of the intermediate seals 339 measured from the second end 327 of the seal 321 proximate the second longitudinal edge 319.
Similar to
The overall length of the uninflated insert 301 may be similar to or longer than the length of the vamp region of a shoe. When the length of the insert is longer than the length of the vamp region of the shoe, the insert 301 may be inflated and then folded about the intermediate seals 339. The position of the intermediate seals with respect to the overall length of the insert influences how the insert may be flexibly folded upon itself to manipulate the length of the insert once installed within the shoe. This allows for customization of vamp support, such that an insert may be configured to support shoes having a variety of vamp shapes and sizes.
The inserts 801 and structure 800 of
In accordance with the embodiments of
The inflation and sealing device 1901 is configured for continuous inflation of the web 1900 as it is unraveled from the roll. The roll of web 1900 includes a plurality of inflation chambers 1914 that are arranged in series. To begin manufacturing of the inflated shoe inserts 1921 from the web 1900, the inflation opening of the web 1900 is inserted around an inflation assembly, such as an inflation nozzle in the inflation region 1942. The web 1900 is advanced over the nozzle with the inflation chambers 1914 extending transversely with respect to the inflation nozzle and an outlet of the inflation nozzle. The outlet, which can be disposed on a radial side and/or upstream tip of the nozzle, for example, directs fluid into the nozzle body into the inflation chambers 1914 as the web 1900 advances along a material path in a longitudinal direction.
The inflation nozzle inserts fluid, such as pressurized air, along a fluid path into the uninflated web material through the nozzle outlets, inflating the inflation chambers 1914. The inflation nozzle can include a nozzle inflation channel that fluidly connects a fluid source with the nozzle outlets. It is appreciated that in other configurations, the fluid can be other suitable pressurized gas, foam, or liquid. The web 1900 is advanced or driven through the inflation sealing device 1901 by a drive mechanism, such as a driver, sealing drum, or a drive roller, or between a device of belts or pressure plates that can heat and press the plies together to form a heat seal, in a downstream direction along a material path.
After being fed through a web feed area 1964, the first and second plies (for examples, the sealing mechanism then forms a seal 1917 at the sealing location 1916 of the inflated web 1900 to close the mouth 1920 of each inflation chamber 1914. The sealing mechanism may include a sealing device to heat seal the plies of film together, such as with a heating element to melt, fuse, join, bind, or unite the two plies or other types of welding or sealing elements. The web 1900 is continuously advanced through the sealing assembly along the material path and past the sealing device at a sealing area to form a continuous longitudinal seal along the web by sealing the first and second plies together at the seal location 1916. The seal location 1916 abuts the seal 1922 so that when the plies are sealed along the seal location 1916, a seal 1917 is formed to seal the mouths 1920 shut, thereby forming a continuous seal around the inflation chamber 1914.
In accordance with various embodiments, the inflation and sealing device can have more than one belt. For example, one belt may drive the various rollers and a second belt may pinch the web against the sealing drum. In various embodiments, the inflation and sealing device may have no belts. For example, the sealing drum may pinch the web against a stationary platform and drive the web thorough the inflation and sealing device at the same time.
For embodiments in which a closed perimeter inflation region is used to receive the nozzle, the inflation and sealing device further can have a cutting assembly to cut the inflation region to allow the web to come off the inflation nozzle typically downstream of where the web is inflated.
The embodiment of
In other examples, inflation and sealing device may be configured to individually inflate and seal an uninflated element when the web comprises a single uninflated element, a pair of uninflated elements, or a combination of various sized uninflated elements.
The fluid flowing through the inflation and sealing device (e.g., air) may be regulated to equal to or greater than atmospheric pressure. Some typical air pressures are regulated between about 1 psi and 14 psi. For example, the air may be regulated to be between 3 psi and 8 psi in some embodiments.
The inflated insert 902 includes a lateral-medial direction 906, a medial edge 907 and a lateral edge 909, an anterior-posterior direction 908, an anterior end 955 (similar to the first longitudinal edge 317 of
Upon inflation of the inflation chamber, the seals 321, angled seals 322, and intermediate seals 339, together with the longitudinal chamber seal 903, form the boundaries and perimeters of different regions of the inflated insert 902. In the embodiment of
An intermediate flexible region 949 has a length extending in the anterior-posterior direction 908 equal or greater to the width of the intermediate seals 339, and a lateral-medial width extending in the lateral-medial direction 906 between the seals 321a proximate the medial edge 907 and seal 321b lateral edge 909. In the embodiment of
A front region 947 has a length 963 in the anterior-posterior direction 908 that extends from the edges of the intermediate seals 339 proximate the anterior end 955 of the insert 902 up to the anterior end 955. The front region 947 has a lateral-medial width in the lateral-medial direction 906 that extends between the seals 321a and 321b. The front region 947 is inflated in an area between the angled seals 322a and 322b, forming a tapered inflation region that may be similar to portions of a vamp of a shoe. The front region is bisected by the seal 321c. The seals allow the front region to be flexed and adjusted to shape to the vamp region of the shoe.
In some examples, the inflated insert 902 may have an inflated length, such as the combination of lengths of 963, 965 and the length of intermediate flexible region 949, that is shorter than the length of a shoe the insert 902 may be installed within (see
In the embodiment of
The seals 321a, 321b, 321c, angled seals 322a, 322b, and/or intermediate seals 339 may be used to increase the flexibility of the inflated insert 902. For example, the insert 902 may be folded, bent, or manipulated in the posterior-anterior direction 908 at the intermediate flexible region 949, as the inflated regions are filled with air or other gas and have a higher stiffness than the seal areas, which are made from the flexible web material which has a lower stiffness than the inflated areas. The insert 902 may be folded, bent or manipulated in the lateral-medial direction 906 about the seal 321c. The inflated regions are still flexible, as the pressure of the air or gas inside the inflated regions may be at or slightly above atmospheric pressure. The ability of to be flexibly manipulate the insert about the seals allows the insert to be used with a variety of shoe shapes and sizes. The inflation chamber can include a plurality of inflation chamber regions with a first hinge line that allows the chamber regions to be folded with respect to each other to fit within a shoe upper, and wherein the inflated and folded insert is tapered to fit within and support a shape of the shoe upper.
In some embodiments, the shape of the front region 947 is similar to the shape of a vamp region of a shoe, and is configured to flex and at least partially fill a toe cavity of the shoe. The insert 902 is configured such that when it is inserted into a shoe cavity, the insert 902 provides support to the front portion of a shoe, such as the vamp with the tongue and toe portion. The support provided by the insert 902 may prevent sagging or dropping of portions of the shoe into the shoe cavity.
In some embodiments, the lateral-medial width of the insert 902 may be larger than that of a shoe, so that the insert 902 flexes and bends to fit into the shoe cavity and provides support to the walls forming the vamp and quarter regions of the shoe.
While reference is made to the insert 902 inflations heights and lateral-medial widths, it should be understood that these components may be referred to as diameters of the insert 902. For example, in embodiments in which the insert 902 has a portion that is a column-like configuration, the inflation height and lateral-medial width may be substantially equal to each other. For example, cross-sections taken along the lateral-medial direction may be substantially circular, having a diameter.
In another example, the configuration of the insert 902 allows the insert 902 to also be used as an inflated packaging element placed within packaging with consumer or business products to protect the products during transportation.
The insert 1002 has a posterior region 1045 with an anterior-posterior length 1065 that extends between the chamber seal 1003 and a posterior edge of intermediate seals 539 proximate the anterior end 1055. The posterior region 1045 has a lateral-medial width that extends between the seal 521a and the seal 521d, and the width is split by the seals 521b and 521c.
An intermediate flexible region 1049 has a length equal or greater to the width of the intermediate seals 539 proximate the anterior end 1055, and a lateral-medial width between the seal 521a and 521d. In the embodiment of
The insert 1002 has a front region 1047 with a length 1063 extending from the anterior edge of the intermediate seals 539 proximate the anterior end 1055 and extending to the anterior end 1055. The front region 1047 has a lateral medial width that extends from the seal 521a to the seal 521d, and is split by the seals 521b, 521c. The front region 1047 has an inflated portion formed by the anterior edge of the intermediate seals 539 proximate the anterior end 1055 and the lateral side edge of angled seals 522a, and the medial side edge of seal 522b. In some embodiments, the inflated portion of the front region 1047 may be conical or triangularly shaped.
As shown in
The seals 521a, 521b, 521c, 521d form a pattern and may act as hinges and provide flexibility and allow the inflated insert 1002 to be bent, hinged, or manipulated in the lateral-medial direction. The angled seals 522a, 522b provide flexibility and allow the front region 1047 to be manipulated, shaped, or bent into a cone shape which may coincide to support the vamp of a shoe. The posterior region 1045 has additional flexible regions 1067a, 1067b based upon the location of the intermediate seals 539. The intermediate seals 539 provide additional flexibility and allow the insert 1002 to be bent, hinged, folded, or manipulated in the anterior-posterior direction. The seals 521, 522, 539 also help control the overall height of the various regions of the inflated insert. In an example, the seal pattern includes a second hinge extending generally in an anterior-posterior direction, such that first and second hinge lines divide lateral, center, and medial chamber regions. The first and second hinge lines are positioned so that the inflated and folded lateral and medial chamber regions are oriented upright with respect to the medial chamber region to increase the thickness of the shoe upper insert at lateral and medial sides thereof.
In another example, the configuration of the insert 1002 allows the insert 1002 to also be used as an inflated packaging element placed within packaging with consumer or business products to protect the products during transportation.
In some examples, the tubular element is configured to be positioned within the shoe cavity near the sole of the shoe and support a general inner circumference of the shoe, with the shaped element positioned above the tubular element and supporting a portion of the vamp of the shoe (see
In the embodiment of
In the embodiments of
In some instances, the inflated insert assembly 1101 is configured to flex and fill the shoe cavity 1121, in order to maintain the structural form of the shoe 1103 during shipping and/or storing. The inflated insert assembly 1101 can flexibly form to the shoe 1103 to fill out the various widths and shapes of the vamp and provide stiffness through the length of the sole 1111 and to the rear quarter section 1123 to maintain a flat and formed shoe.
As shown in
In the embodiment of
For example, in
As shown in
While some of the various inserts described herein have been described with respect to being positioned with a single shoe or a pair of shoes or to protect a single shoe or a pair of shoes, the individual inserts as described herein could be used as an individual inflated packaging elements or a combination of inflated packaging elements to protect various products during shipment.
In accordance with various embodiments, these components and other components which may be utilized within an inflation and sealing device including without limitation, the nozzle, blower sealing assembly, and drive mechanisms, and their various components or related systems may be structured, positioned, and operated as disclosed in any of the various embodiments described in the incorporated references such as, for example, U.S. Pat. No. 8,061,110; U.S. Pat. No. 8,128,770; U.S. Patent Publication No. 2014/0261752; U.S. Patent Publication No. 2011/0172072; and U.S. Patent Publication No. 2017/0071292 each of which is herein incorporated by reference. Also, the various systems, materials, processes, and components described in U.S. Pat. No. 7,926,507 may be used, which is hereby incorporated by reference in its entirety. Also, the webs described herein may be formed as disclosed in U.S. Application Publication No. 2015/0033669, which is hereby incorporated by reference in its entirety. Each of the embodiments discussed herein may be incorporated and used with the various sealing devices of the incorporated references and/or other inflation and sealing devices. For example, any mechanism discussed herein or in the incorporated references may be used in the inflation and sealing of web as the web or film material described in the incorporated references.
The present application claims priority to U.S. provisional application No. 62/546,447 filed Aug. 16, 2017 entitled “Shaped Inflatable Shoe Insert,” the disclosure of which is hereby incorporated by reference in its entirety.
Number | Date | Country | |
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62546447 | Aug 2017 | US |