In one embodiment, a midsole for an article of footwear is described that includes a first foaming cord made of a first material and a second foaming cord made of a second material. The first material is different than the second material. The first foaming cord and the second foaming cord are embroidered into a shape of the midsole. The first foaming cord and the second foaming cord may be embroidered to a substrate material by thread. A midsole can include multiple layers of foaming cords. Customized midsoles may be formed by selective placement of one or more foaming cords in different locations or layers to provide different properties or characteristics to the midsole.

An outsole component for use in an article of footwear is manufactured using a molding process that incorporates a second polymeric material with a film component including a first layer formed of a polymeric hydrogel material. The first layer forms the external or ground-facing layer of the outsole. Methods of manufacturing the outsole component, as well as articles of footwear including outsole component and methods of manufacturing such articles of footwear are also described.

A compressible footwear that may include a compressible sole and a compressible upper part that is mechanically coupled to the compressible sole. The compressible sole consisting essentially of multiple compressible cells that are made of a flexible material and have top openings and bottom openings. The multiple compressible cells span over at least a majority of the compressible sole and are configured to undergo a compression while substantially maintaining a thickness of the compressible sole.

An article of footwear (10) that includes a liner (30), an upper (14), and an insert (50). The liner has an inward surface (31) that encloses an inner void (18) for accommodating a foot, and an outward surface (32) that defines a rear shaft portion (38), a heel portion (36), and a sole portion (35). The upper has a midsole portion (42), and surrounds the rear shaft portion, the sole portion, and the heel portion of the liner. The insert is formed as a single body of material with increased hardness and stiffness relative to the upper. This insert is arranged between the liner and the upper, and includes a protruding portion (54), a heel counter (56), and a shank (58). The protruding portion extends upwards from the heel counter and along the rear shaft portion, and provides a guiding trajectory for a heel during insertion into the inner void.

This document discloses a process for manufacturing recyclable injection molded microcellular foams for use in, footwear components, seating components, protective gear components, and watersport accessories. The process includes the steps of providing a thermoplastic polymer which comprises at least one monomer derived from depolymerized post-consumer plastic, inserting a fluid into a barrel of a molding apparatus. The fluid is introduced under temperature and pressure conditions to produce a super critical fluid. The process further includes mixing the thermoplastic polymer and super critical fluid so as to create a single phase solution, and injecting the single phase solution into a mold of an injection molding machine under gas counter pressure. The process further includes foaming the single phase solution by controlling the head and temperature conditions within the mold.

An outsole component for use in an article of footwear is manufactured using a molding process that incorporates a second polymeric material with a film component including a first layer formed of a polymeric hydrogel material. The first layer forms the external or ground-facing layer of the outsole. Methods of manufacturing the outsole component, as well as articles of footwear including outsole component and methods of manufacturing such articles of footwear are also described.

Components for articles of footwear and athletic equipment including a foam are provided. The foam portion of the components and articles include a composition which includes a thermoplastic copolyester, the composition having a foam structure. A polymer layer is provided on at least on surface of the foam portion. The polymer layer can control or reduce the water uptake of the foam portion. Methods of making the compositions, foams, and components are provided, as well as methods of making an article of footwear including one of the foam components. In some aspects, the foams and foam components can be made by injection molding, or injection molding followed by compression molding.

An upper for a shoe and a shoe including an upper and a sole that is connected to the upper may be provided. In one implementation, an upper for a shoe may be provided, the shoe including the upper and a sole connected to a lower edge of the upper via injection molding. The upper may include a first knitted area having a first stitch density, wherein a portion of the first knitted area may be located at the lower edge of the upper and may include a first meltable material having a first melting temperature. The first meltable material may be melted prior to or during the connection of the sole to the upper and may limit the flow of molding material through a melted area of the upper.

The utilization of heat in the manufacturing of footwear may be accomplished through microwave energy. The microwave energy is conveyed to the footwear components through a microwave transparent window of a tool. The microwave transparent tool window forms as least a portion of a part-contacting surface of the tool. Another surface of the tool is formed from a microwave reflecting material, such as aluminum. The footwear component(s) are exposed to microwave energy while within the tool such that the microwave energy passes through the tool window to cause a dielectric heating of one or more materials within a tool cavity of the tool.

The utilization of heat in the manufacturing of footwear may be accomplished through microwave energy. The microwave energy is conveyed to the footwear components through a microwave transparent window of a tool. The microwave transparent tool window forms as least a portion of a part-contacting surface of the tool. Another surface of the tool is formed from a microwave reflecting material, such as aluminum. The footwear component(s) are exposed to microwave energy while within the tool such that the microwave energy passes through the tool window to cause a dielectric heating of one or more materials within a tool cavity of the tool.