An article of footwear includes an upper and a sole structure that is thermoformed to the upper. The upper has a ground facing surface, and opposing medial and lateral sidewalls disposed on opposite sides of the ground facing surface. The sole structure has an inner surface adhered to the upper and an outer surface that is opposite the inner surface. The sole structure includes a thermoplastic base layer that defines the inner surface of the sole structure. The sole structure further includes a thermoplastic outer layer integrally formed with the base layer. The outer layer has a plurality of protuberances, each protuberance has an outer face that defines a portion of the outer sole surface, and the outer layer further includes a plurality of splayed sipes extending across a portion of the sole structure. Each splayed sipe generally extends between at least two adjacent protuberances.

A sole structure with an integrated cleat member includes a plate member with a protruding portion that forms a first portion of the cleat member. A second portion of the cleat member is attached to the first portion and may be made of a less rigid material than the first portion. A supporting structure can be disposed inside the protruding portion. A method of forming the sole structure can include reshaping a portion of a plate member to form a protruding portion, molding a cleat tip portion onto the protruding portion and molding a supporting structure into a concave inner portion of the protruding portion.

The present disclosure encompasses three-dimensional articles comprising flexible-composite materials and methods of manufacturing said three-dimensional articles. More particularly, the present system relates to methods for manufacturing seamless three-dimensional-shaped articles usable for such finished products as airbags/inflatable structures, bags, shoes, and similar three-dimensional products. A preferred manufacturing process combines composite molding methods with specific precursor materials to form fiber-reinforced continuous shaped articles that are flexible and collapsible.

A stitched article includes a substrate and a first strand portion formed from a bundle of fibers. The substrate has a first region and a second region. The first strand portion is attached to the substrate in the first region and in the second region via a series of stitches formed with a thread and forms a first layer on the substrate. The article has a first concentration of the stitches in the first region along a first length of the strand portion and a second concentration of the stitches different than the first concentration in the second region along a second length of the first strand portion.

A decentralized private blockchains network is provided. In some implementations, the system performs operations comprising receiving, at a client system, data having a sensitivity level, the operations further comprise splitting, at the client system, the data based on the sensitivity level, the splitting comprising splitting the data into data portions. The operations further comprise storing, at a decentralized storage system, the decentralized storage system comprising a plurality of private blockchains, each of the data portions in a separate private blockchain of the plurality of private blockchains. The operations further comprise storing, at a multi-decentralized private blockchains network (MDPBN), pointers to locations of the data portions within the decentralized storage system. Related systems, methods, and articles of manufacture are also described.

The present invention relates to a shoe sole material composition, a shoe sole material and a method for producing the same. The shoe sole material composition comprises a blending mixture and a crosslinking agent. The blending mixture includes an elastomer and a thermoplastic material. An amount of the elastomer is larger than an amount of the thermoplastic material. The crosslinking agent is subjected the elastomer to a crosslinking reaction during a heating and blending process, such that the elastomer can invert into a discontinuous phase dispersed in the thermoplastic material, thereby producing the shoe sole of the present invention. Therefore, the shoe sole material has an excellent recycling property, further improving reusability of the shoe sole.

An algae-elastomer composite including an elastomer matrix; algae; and a mixing additive sufficient to achieve a desired property. The algae can be present in a milled condition having a particle size value of between about 10 and 120 microns. The algae is mixed with the elastomer matrix in a dry condition having a moisture content of below about 10%. A method of preparing the algae-based elastomer composite is provided that includes the steps of: premixing an elastomer matrix; adding an algae filler; adding a mixing additive that includes a plasticizer; forming an elastomer-algae blend by blending the algae and elastomer to a temperature sufficient to be further mixed, wherein the temperature is about 10° C. higher than the temperature sufficient for the elastomer alone; adding and mixing a curing or vulcanizing agent for the elastomer dispersing the elastomer-algae blend; and heating and curing the elastomer-algae blend into a final form.

The present invention relates to an upper for a shoe, including an inner layer; an outer layer overlapping the inner layer at least partially; wherein the outer layer includes a plurality of cuts; wherein the inner layer includes a plurality of protrusions; wherein each cut at least partially overlaps at least one protrusion; wherein each protrusion causes an extension in width of its corresponding cut when the shoe is worn.

A component, for example, a shoe foxing, may have one or more regions with embedded particles and one or more regions without embedded particles. The one or more regions without embedded particles may comprise one or more outer surfaces of the component. The component may be formed by heating and pressing material sections in a mold. The component may be formed by extrusion. One or more of the material sections may lack embedded particles.

Beads may be stitched to a substrate layer and then fused to form structures including foam midsoles, foam pads, and other foam structures. Beads may be embroidered to multiple substrate layers and then folded or stacked together to form a preform used in a mold to form a midsole.