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.

The present disclosure relates to a method for manufacturing a shoe, in particular a sports shoe, comprising the steps of providing a plurality of individual particles for a sole element in a mold, providing an upper in the mold, and fusing the plurality of individual particles and the upper by means of an electromagnetic field to bond the plurality of individual particles with each other and with the upper.

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 technology relates generally to a footwear assembly and method of manufacturing said footwear assembly. The footwear assembly includes an outsole and an upper connected to the outsole, where the upper includes a neoprene sock, a vulcanized rubber layer, and an injection molded layer. The neoprene sock is a full-foot neoprene sock having a foot portion that is configured to receive a wearer's foot. The vulcanized rubber layer fully covers a vamp portion, heel portion, toe portion, and ankle portion of the neoprene sock while only covering some of an underfoot portion. The injection molded layer is formed over a portion of the vulcanized rubber layer and completely covers the underfoot portion of the neoprene sock.

A footwear article is formed according to a process that includes the steps of: forming a sheet including a rubber outsole material; forming an outsole component by passing the sheet through an extruder or calendar machine; applying a vulcanizing accelerant to the outsole component by dipping the outsole component in a liquid bath; forming a plurality of rubber outsoles from the outsole component by cutting the outsole component into the plurality of rubber outsoles; incorporating each of the plurality of rubber outsoles into the footwear article; and vulcanizing the footwear article. The vulcanizing accelerant includes a dithiocarbamate compound. The footwear article includes the rubber outsole, an insole and an upper. The vulcanizing accelerant allows the step of vulcanizing the footwear article to be performed substantially faster as compared to conventional footwear vulcanization methods.

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.

A molding assembly having a top mold member and a base mold member. The top mold member can include a first top mold portion and a second top mold portion that shift between a top mold open configuration and a top mold closed configuration by rotating about a top mold hinge axis. The molding assembly can shift between a molding assembly open configuration and a molding assembly closed configuration by rotating at least the top mold member about a molding assembly hinge axis.

A sports shoe includes an upper wherein a majority by weight of the upper is made from a thermoplastic base material and a sole wherein a majority by weight of the sole is made from the same thermoplastic base material. The sole and the upper are individually fabricated and joined to each other. The thermoplastic base material includes at least one of the following materials: thermoplastic polyurethane TPU, polyamide PA, polyethylene terephthalate PET, or polybutylene terephthalate PBT.

Provided is a method of manufacturing a shoe by which an outsole, a midsole, and an upper part are integrally manufactured in first- through third-stage molds without liquid primer or adhesive processing.

Disclosed herein is a process for making a shoe using a stand-alone mouldable nonwoven fabric which has the ability of self-sustaining and shape maintenance and which is heated to become softened till molten. In the process of the invention, the shoe parts are moulded by a compression moulding process and the moulded parts are then heated and welded together by a plastic welding method.