A method for forming a plate includes attaching a first strand portion to a flexible substrate to form a first layer on the substrate and positioning a second strand portion on the first layer to form a second layer on the first layer in a plurality of discrete regions on the substrate. The method also includes positioning a plurality of traction elements into corresponding cavities formed into a first mold surface and positioning the substrate on the first mold surface to change a shape of the substrate. At least one of heat and pressure is applied to the first strand portion, the second strand portion, the substrate, and the traction elements to conform the substrate to the shape of the first mold surface and form the traction elements into the substrate at each of the discrete regions. The method also includes incorporating the substrate into an article of footwear.

The manufacturing of articles relies on the bonding of two or more components to form some forms of the articles, such as a shoe sole bonded with a shoe upper. The bonding may be achieved with an adhesive particulate that is applied to a surface of a substrate. The adhesive particulate is selectively fused to the substrate with a controlled energy source, such as a laser. The selective application of laser energy allows for specific geometric structures of adhesive particulate to be formed on the substrate. The substrate having the fused adhesive particulate is mated with another component allowing the fused adhesive particulate to bond the first substrate and the second component.

The manufacturing of articles relies on the bonding of two or more components to form some forms of the articles, such as a shoe sole bonded with a shoe upper. The bonding may be achieved with an adhesive particulate that is applied to a surface of a substrate. The adhesive particulate is selectively fused to the substrate with a controlled energy source, such as a laser. The selective application of laser energy allows for specific geometric structures of adhesive particulate to be formed on the substrate. The substrate having the fused adhesive particulate is mated with another component allowing the fused adhesive particulate to bond the first substrate and the second component.

The present invention relates to a method for interconnecting components of a sporting good, in particular a sports shoe, and a sports shoe manufactured with such a method. The method may include (a.) forming a pattern element having at least one removable at least partially non-transparent or non-reflective portion, (b.) irradiating at least one of the first and the second component via the pattern element with heat radiation and (c.) interconnecting the irradiated first and second component.

An integrally-formed shoe having no machine sewing and a manufacturing method thereof are provided. A structure of the shoe includes: a lining sock body that uses a knitting manner and includes an opening; and a surface sock body that uses a knitting manner and includes an opening and a sole, where the opening of the lining sock body is nested inside the surface sock body; the two sock bodies are properly mounted on a sock machine; low melting point yarn and nylon elastic filament are mixed into knitting of the lining sock body; low melting point yarn, nylon elastic filament, and set yarn are mixed into knitting of the surface sock body; after the sock machine weaves and molds the two sock bodies into a whole, a hollow mold is nested inside the surface sock body; the whole is heated and baked to slightly damage surface tissues of the yarn, and is then cooled to make the set yarn in knitwear be reorganized and extended according to the shape of an external fixing mold, to present a predetermined pattern; and after the surface sock body presents the predetermined pattern, the sole is directly bonded to the bottom of the surface sock body so as to achieve bonding of the sole and the surface sock body, to complete the integrally-formed shoe having no machine sewing, so that a user feels more comfortable due to no machine sewing.

An integrally-formed shoe having no machine sewing and a manufacturing method thereof are provided. A structure of the shoe includes: a lining sock body that uses a knitting manner and includes an opening; and a surface sock body that uses a knitting manner and includes an opening and a sole, where the opening of the lining sock body is nested inside the surface sock body; the two sock bodies are properly mounted on a sock machine; low melting point yarn and nylon elastic filament are mixed into knitting of the lining sock body; low melting point yarn, nylon elastic filament, and set yarn are mixed into knitting of the surface sock body; after the sock machine weaves and molds the two sock bodies into a whole, a hollow mold is nested inside the surface sock body; the whole is heated and baked to slightly damage surface tissues of the yarn, and is then cooled to make the set yarn in knitwear be reorganized and extended according to the shape of an external fixing mold, to present a predetermined pattern; and after the surface sock body presents the predetermined pattern, the sole is directly bonded to the bottom of the surface sock body so as to achieve bonding of the sole and the surface sock body, to complete the integrally-formed shoe having no machine sewing, so that a user feels more comfortable due to no machine sewing.

A method for joining a sole element with an upper element includes the steps of (a) operating a positioning system to position the sole element and the upper element in a defined first position with respect to each other, (b) operating the positioning system to position the sole element and the upper element in a second position for applying a joining agent to the sole element and/or the upper element and (c) joining the sole element with the upper element by operating the positioning system to position the sole element in contact with the upper element in a third position of the positioning system, wherein the third position is defined with respect to the first position.

A method for joining a sole element with an upper element includes the steps of (a) operating a positioning system to position the sole element and the upper element in a defined first position with respect to each other, (b) operating the positioning system to position the sole element and the upper element in a second position for applying a joining agent to the sole element and/or the upper element and (c) joining the sole element with the upper element by operating the positioning system to position the sole element in contact with the upper element in a third position of the positioning system, wherein the third position is defined with respect to the first position.

Aspects of the present invention relate to systems and methods for customizing microwave energy distribution within a chamber to accommodate various load characteristics. Aspects of the present invention customized configurations of ports, deflectors, waveguides, conducting rods, and slots to shape and distribute energy.

Aspects of the present invention relate to systems and methods for customizing microwave energy distribution within a chamber to accommodate various load characteristics. Aspects of the present invention customized configurations of ports, deflectors, waveguides, conducting rods, and slots to shape and distribute energy.