A procedure for making a shoe with a knitted upper, including a series of steps in whichduring an upper shaping steponce the internal stocking has been placed on the shoe tree, a membrane element (3) is placed in position, which covers the portion corresponding to the sole of the shoe tree and a lateral portion. The membrane element is a single-body element formed of a polymer membrane that has adhesive material on both sides thereof and features a series of suitable shaped and positioned perforations (30). The membrane element is designed to create a support structure for the two stockings so that the shoe obtained has and maintains a structured shape. Once the upper is complete, a sole is constructed by injection moulding in order to create a shoe that is a single, homogeneous, compact, and structured body.

A method for the three-dimensional forming of an upper of a footwear, comprises: preparing a sock comprising thermoplastic yarns; fitting the sock on a reference form of an upper to be formed; placing the reference form with the sock in an oven; heating the sock in the oven up to determining the at least partial fusion of thermoplastic material of the thermoplastic yarns of the sock; cooling the sock up to determining the cross-linking of the thermoplastic material and the formation of the upper with more rigid portions and less rigid portions; removing the upper from the reference form.

Aspects of the present invention relate to a dynamic woven material that is capable of undergoing a dimensional change in response to an external stimulus. The dynamic woven material comprises a plurality of discrete woven cells, where each woven cell comprises a reactive region and a non-reactive region. The reactive region changes from a first physical state to a second physical state when the woven material is exposed to the external stimulus. The woven material may be formed with zonal stretch properties by varying the areas occupied by the reactive region and the non-reactive region in each woven cell. For example, the bigger the area occupied by the reactive region in the woven cells in a particular zone of the dynamic woven material, the higher the level of stretch in the particular zone may be. Exemplary products manufactured from the dynamic woven material include, for example, articles of footwear.

Aspects of the present invention relate to a dynamic woven material that is capable of undergoing a dimensional change in response to an external stimulus. The dynamic woven material comprises a plurality of discrete woven cells, where each woven cell comprises a reactive region and a non-reactive region. The reactive region changes from a first physical state to a second physical state when the woven material is exposed to the external stimulus. The woven material may be formed with zonal stretch properties by varying the areas occupied by the reactive region and the non-reactive region in each woven cell. For example, the bigger the area occupied by the reactive region in the woven cells in a particular zone of the dynamic woven material, the higher the level of stretch in the particular zone may be. Exemplary products manufactured from the dynamic woven material include, for example, articles of footwear.

An upper includes an upper body being a woven fabric, and the upper body includes a first bundle body in which a first linear body and a second linear body are bundled along a first direction, and a second bundle body in which the first linear body is bundled along a second direction orthogonal to the first direction.

Aspects of the present invention relate to a dynamic woven material that is capable of undergoing a dimensional change in response to an external stimulus. The dynamic woven material comprises a plurality of discrete woven cells, where each woven cell comprises a reactive region and a non-reactive region. The reactive region changes from a first physical state to a second physical state when the woven material is exposed to the external stimulus. The woven material may be formed with zonal stretch properties by varying the areas occupied by the reactive region and the non-reactive region in each woven cell. For example, the bigger the area occupied by the reactive region in the woven cells in a particular zone of the dynamic woven material, the higher the level of stretch in the particular zone may be. Exemplary products manufactured from the dynamic woven material include, for example, articles of footwear.

An insole for loose insertion into a shoe, wherein the insole has at least the following layer structure with a first layer made of carbon fiber-reinforced plastic, one or more intermediate layers and a second layer made of carbon fiber-reinforced plastic, the layers being arranged essentially one above the other at least partially.

An insole for loose insertion into a shoe, wherein the insole has at least the following layer structure with a first layer made of carbon fiber-reinforced plastic, one or more intermediate layers and a second layer made of carbon fiber-reinforced plastic, the layers being arranged essentially one above the other at least partially.

A system for forming a non-woven, yarn structure for an engineered textile includes a jig having a plurality of upstanding pins and an automatic winding system for winding a plurality of continuous strands of yarn across the jig and around the upstanding pins. The automatic winding system includes a movement mechanism and a winding head coupled with the movement mechanism. The movement mechanism includes one or more motors that are configured to translate the winding head across a central workspace area of the jig. The winding head includes a rotatable base; a plurality of yarn guides arranged in a linear array and extending from the rotatable base, each yarn guide adapted to receive a different one of the continuous strands, and a rotation motor coupled to the rotatable base and configured to selectively rotate the base to alter an orientation of the linear array.

A system for forming a non-woven, yarn structure for an engineered textile includes a jig having a plurality of upstanding pins and an automatic winding system for winding a plurality of continuous strands of yarn across the jig and around the upstanding pins. The automatic winding system includes a movement mechanism and a winding head coupled with the movement mechanism. The movement mechanism includes one or more motors that are configured to translate the winding head across a central workspace area of the jig. The winding head includes a rotatable base; a plurality of yarn guides arranged in a linear array and extending from the rotatable base, each yarn guide adapted to receive a different one of the continuous strands, and a rotation motor coupled to the rotatable base and configured to selectively rotate the base to alter an orientation of the linear array.