The present invention relates to a fiber-containing structure comprising an interwoven and welded base material and a welded elastomer layer, and at least one part of the base material and the welded elastomer layer are welded to each other. The invention also relates to a method for manufacturing the fiber-containing structure and a shoe structure containing the fiber-containing structure.

The present disclosure relates to an insole including a lower layer, an upper layer and an intermediate layer arranged between the lower layer and the upper layer. The lower layer or base of the insole is a supporting layer designed to be placed, in use conditions of the insole, above a sole of an item of footwear. The upper layer is designed to be placed, in use conditions of the insole, in contact with a foot, with or without a sock, of a user. The intermediate layer includes natural feathers distributed uniformly and treated so as not to allow displacement thereof along the intermediate layer. The disclosure further relates to an upper of an item of footwear.

The present disclosure relates to an insole including a lower layer, an upper layer and an intermediate layer arranged between the lower layer and the upper layer. The lower layer or base of the insole is a supporting layer designed to be placed, in use conditions of the insole, above a sole of an item of footwear. The upper layer is designed to be placed, in use conditions of the insole, in contact with a foot, with or without a sock, of a user. The intermediate layer includes natural feathers distributed uniformly and treated so as not to allow displacement thereof along the intermediate layer. The disclosure further relates to an upper of an item of footwear.

A biocomposite material and methods and systems for forming a biocomposite material are provided. In one example, a biocomposite material includes a biopolymer material and an internal structure imparting zonal properties to the biocomposite material, where the biopolymer material at least partially surrounds and/or extends through the internal structure. The biopolymer material includes mycelium grown from a fungal strain.

A shoe (34) of the present invention includes a sole (32) and an upper (33). The upper (33) is composed of a fabric having a knit structure, and contains fiber reinforcement portions (23, 24, and 25) in predetermined portions of the upper (33) integrally. The fiber reinforcement portions (23, 24, and 25) are formed of a float stitch with a plurality of float stitch yarns (19). The shoe of the present invention imparts a proper fit to a wearer's foot by forming the upper composed of the fabric having the knit structure that stretches properly. Also, in the case where the direction of foot force is suddenly changed while the sole contacts the ground, the shoe can hold the foot in desired predetermined positions by the fiber reinforcement portions situated in predetermined positions of the upper integrally. Thus, the present invention provides a shoe having proper holding properties while maintaining fitting properties.

A fiber-bound engineered material is provided that imparts an intended characteristic at an intended relative location. A fiber layer is entangled with additional fibers in a manner to create a non-uniform engineered material. The lack of uniformity of a fiber-bound engineered material may be accomplished through manipulation of the fibers and/or through fiber binding a scrim. The fiber layer binds with additional fibers through entanglement such that a mechanical connection between the entangled fibers is provided. This entanglement allows the fibers to bind without supplemental adhesives, interlacing, or connections. Variations in the fibers and/or inclusion of scrim materials prior to entanglement allows for an intended characteristic (e.g., a functional characteristic) at an intended relative location (e.g., a position determined by an article to be formed therefrom).

An upper for a shoe, in particular a sports shoe, includes at least one tape covering at least 50% of the upper. At least one tape portion includes a plurality of connected tapes. A further aspect relates to an upper for a shoe, in particular a sports shoe, including at least one tape portion including a plurality of connected tapes. In some connected tapes, the tapes are zig-zag stitched to each other on their edges.

An upper for a shoe, in particular a sports shoe, includes at least one tape covering at least 50% of the upper. At least one tape portion includes a plurality of connected tapes. A further aspect relates to an upper for a shoe, in particular a sports shoe, including at least one tape portion including a plurality of connected tapes. In some connected tapes, the tapes are zig-zag stitched to each other on their edges.

A fiber bound engineered material is provided that imparts an intended characteristic at an intended relative location. A fiber layer is entangled with additional fibers in a manner to create a non-uniform engineered material. The lack of uniformity of a fiber bound engineered material may be accomplished through manipulation of the fibers and/or through fiber binding a scrim. The fiber layer binds with additional fibers through entanglement such that a mechanical connection between the entangled fibers is provided. This entanglement allows the fibers to bind without supplemental adhesives, interlacing, or connections. Variations in the fibers and/or inclusion of scrim materials prior to entanglement allows for an intended characteristic (e.g., a functional characteristic) at an intended relative location (e.g., a position determined by an article to be formed therefrom).

Provided are, among other things, systems, methods and techniques for making a shoe outsole and to shoe outsoles made using such techniques. In one such technique, a sheet of composite material is produced by extruding a base material together with a sheet of fabric material. The sheet of composite material is then cut into an outsole component, and a shoe outsole is fabricated using the outsole component.