Described are methods for the manufacture of a plastic component, in particular a cushioning element for sports apparel, a plastic component manufactured with such a method, for example a sole or a part of a sole for a shoe, and a shoe with such a sole. According to an aspect of the invention, a method for the manufacture of a plastic component, in particular a cushioning element for sports apparel, is provided which includes loading a mold with a first material which includes particles of an expanded material, and, during loading the mold, pre-heating the particles by supplying energy, wherein the energy is supplied in the form of at least one electromagnetic field.

A method of manufacturing a midsole includes placing first and second preforms into a midsole recess of a mold, with first and second portions of the mold defining a first overflow chamber connected to the first recess; closing the mold by positioning the first and second portions in contact with one another; heating the mold for a predetermined period of time at a predetermined temperature such that the first and second preforms melt and bond together to form a midsole, with a portion of each of the first and second preforms flowing into the first overflow chamber to form a first overflow portion; removing the midsole from the mold; allowing the midsole to expand; and cutting away the first overflow portion.

A method of manufacturing a non-woven fabric includes the steps of: (a.) providing a substrate, wherein the substrate is air permeable in at least a portion of its surface; (b.) providing a fiber transfer device adapted to transfer fibers onto the substrate; (c.) transferring a first plurality of fibers onto the substrate; and (d.) applying a pressure differential to the air permeable portion of the substrate, wherein the strength of the pressure differential is varied across the surface of the substrate.

A method of manufacturing an article comprises etching an etched feature on a surface of a first polymeric sheet, and forming a fluid-filled bladder element from the first polymeric sheet, with the fluid-filled bladder element having a sealable internal cavity that retains fluid. The method includes assembling the bladder element in the article so that a first portion of the bladder element having the etched feature is exposed to view, and a second portion of the bladder element is blocked from view by the article. An article includes the bladder element with the etched feature.

A shoe sole with shoe nails made of different materials includes: a base made of a first material and including a plurality of connecting portions each having at least three connecting surfaces, at least two connecting surfaces have different slopes and are connected to each other. The shoe nails are formed on the connecting portions, and the shoe nails are equal in quantity to the connecting portions. Each connecting portion has a shoe nail, each shoe nail includes: an abutting portion formed in the shape of the connecting portions, and an opposite exposed portion which is a flat surface used for stepping on a floor. The abutting portion includes at least three abutting surfaces, at least two abutting surfaces have different slopes and are connected to each other, and each abutting surface is abutted against a corresponding connecting surface with a corresponding slope.

The invention relates to systems and methods for creating a foamed part. An example method includes providing a polymer processing system, providing a mold having at least one expandable mold cavity in fluid communication with the polymer processing system, mixing polymeric material and blowing agent within the polymer processing system to produce a unfoamed mixture, injecting a volume of the mixture of polymeric material and blowing agent from the polymer processing system and into the expandable mold cavity, and expanding the mold cavity to expand the unfoamed mixture within the mold cavity and form a foamed preform. Thereafter, the foamed preform may be inserted into a compression mold to press-form the foamed preform into a finished part.

A method of manufacturing a midsole includes placing first and second preforms into a midsole recess of a mold, with first and second portions of the mold defining a first overflow chamber connected to the first recess; closing the mold by positioning the first and second portions in contact with one another; heating the mold for a predetermined period of time at a predetermined temperature such that the first and second preforms melt and bond together to form a midsole, with a portion of each of the first and second preforms flowing into the first overflow chamber to form a first overflow portion; removing the midsole from the mold; allowing the midsole to expand; and cutting away the first overflow portion.

A skate including a tridimensional skate boot shell with a sole insert embedded in or received in the skate boot shell such that at least part of a thickness of the sole portion is defined under the sole insert, and a holder under the skate boot shell configured for retaining a ground-engaging skate element. The holder is connected to the sole insert by at least one fastener extending through the at least part of the thickness of the sole portion. A method of manufacturing a skate boot is also discussed.

An upper shell panel may be placed between first and second sections of a mold. The first section may include one or more expansion cavities and the second section may include one or more pour cavities. A foam-producing chemical mixture may be delivered into the one or more pour cavities and the mold may be closed. The delivered foam-producing chemical mixture may be allowed to expand within the closed mold and to force regions of the upper shell panel into the one or more expansion cavities. The upper shell panel may then be removed from the mold subsequent to the expansion of the delivered mixture.

Methods for manufacturing cushioning elements for sports apparel are described. A method is provided for manufacturing a cushioning element for sports apparel from randomly arranged particles of an expanded material. The method includes positioning a functional element within a mold and loading the mold with the particles of the expanded material, wherein the loading occurs through at least two openings within the mold and/or wherein the loading occurs between different movable parts of the mold.