A mold, a molding apparatus, and a method for manufacturing articles or components is used to manufacture an article or component of the article that at least partially comprises an ultraviolet (UV) curable material. The mold and apparatus comprise at least one mold wall formed of a cyclic olefin copolymer, which is in contact with UV radiation curable material and allows the article or component of the article to be exposed to UV radiation for a period of time in order to provide for at least partial cure thereof.

The invention concerns a method of producing an article of footwear comprising: providing an upper; providing a mold and opening the mold; inserting the upper into the open mold; closing the mold; and injecting a pressurized molten resin, wherein, after the injecting, there is a gap filled with the resin between a side wall of the mold and an outer surface of at least a first portion of the upper, wherein the gap is essentially zero at a contacting point, wherein the gap increases gradually from the contacting point in at least a first region of the mold.

A molding system and a method for forming a sole structure are provided. The method includes flowing a molten polymeric material into a mold from an upstream device, receiving the molten polymeric material in a cavity of the mold, and maintaining a repeatable, uniform pressure profile as the molten polymeric material is delivered into the mold.

A fluid-filled chamber, which may be incorporated into articles of footwear and other products, may include an outer barrier, a first tensile structure, and a second tensile structure. Any of the first and second tensile structures may include one or more textile tensile members. The first and second tensile structures may be located within an interior void defined by the outer barrier and may be bonded to the outer barrier. The first and second tensile structures may be bonded to the outer barrier in different areas of the outer barrier that are in fluid communication with each other. The first tensile structure may have a height greater than a height of the second tensile structure. In turn, the relative locations and differences of height between the tensile structures may impart a contour to the chamber.

This disclosure concerns a master model for the production of a mold, comprising: (a) a first part, a second part comprising a textured surface; wherein the first part and the second part are connected.

A method is provided for making footwear utilizing a spray-on material. The method can include spraying a spray-on fabric onto surfaces of a three dimensional last. The last can be produced using additive manufacturing techniques, such as 3D printing, based on data corresponding to dimensions and contours of a consumer's foot, and/or preselected aesthetic footwear designs. The spray-on fabric is sprayed onto the surfaces of the last and allowed to cure to form a flexible, non-woven fabric upper. The upper can be removed from the last and turned inside out. With the upper turned inside out, a sole can be joined to the fabric upper to form the footwear.

An article of footwear including an outsole, a fabric upper and at least one connector including a first male member co-molded with the fabric upper and a second female member. The first member includes at least one rib and the second member includes at least one groove, where the at least one connector is secured to the outsole by inserting the second member in the outsole and engaging the at least one rib of the first member with the at least one groove of the second member.

A customizeable footbed, a self-customizing footwear having a customizable footbed, and a method for customizing a footbed to conform to contours of a foot is provided. The customizable footbed may include 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 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 such that the interior fillings of the packets flow into and mix within the intermediate space.

Cleat structures, e.g., for golf shoes, may include a flat and flexible interior surface and/or a generally disk-shaped perimeter area that includes features to promote in-molding of the cleat to a footwear sole component (e.g., to permanently engage the cleat with an outsole member). Such cleats may provide a flexible and comfortable base, including a low profile, e.g., to enable formation relatively thin and/or flexible footwear sole components. Footwear sole components and articles of footwear that include one or more in-molded cleat structures of this type also are described. Molds used for in-molding procedures and methods of using the molds to make articles with in-molded components (e.g., for making footwear sole structures including one or more in-molded cleats) also are described.

A hot-molding method using a plastic elastomer to fabricate a vamp comprises steps: fabricating a hot-molding mold according to a pattern design of a vamp; fabricating blanks of different thicknesses, shapes, sizes, colors and materials; placing the blanks in the hot-molding mold; placing the hot-molding mold in a hot-molding machine to undertake a hot-molding process; and taking the hot-molding mold out of the hot-molding machine and then taking out the vamp from the mold after cooling. The method enables a single vamp to simultaneously use blanks of different thicknesses, shapes, colors and materials and diversifies vamp designs. The method fixes blanks securely in the mold and joins blanks of different colors to an identical vamp in a single process. The blanks are hard to peel off the vamp after molding. The method features a short fabrication cycle, high efficiency and high yield.