A method for automated manufacturing of shoe soles comprises the steps of: loading a transfer device with at least one outsole element and at least one supporting element, positioning the loaded transfer device adjacent a first part and a second part of a sole mold, transferring the at least one outsole element from the transfer device to the first part and transferring the at least one supporting element from the transfer device to the second part of the sole mold, filling the sole mold with a plurality of individual particles, and applying a medium to bond and/or fuse the particles with each other and with the at least one outsole element.

An upper of an article of footwear comprises a plurality of stretch zones each having a respective stretching capability. Suitable example stretch zones may include four-way stretch zones, two-way stretch zones, and/or lock-out zones. In some examples, an upper having a plurality of stretch zones comprises a single continuous piece of material configured to have regions of different stretching capability. The single piece of material may comprise a layered material having two stretchable outer layers, wherein a plurality of stretch zones of the piece of material are defined by corresponding intermediate layers disposed at selected locations between the outer layers. Examples of intermediate layers providing two-way stretch, four-way stretch, and little or no stretch are disclosed.

The present disclosure relates generally to three-dimensionally printed molds, and associated methods, for use in manufacturing articles such as footwear. In some embodiments, for example, a three-dimensionally printed mold may be a master mold that is used to manufacture a secondary mold. The secondary mold may be used, in certain embodiments, to provide a cured material that can be transferred to a substrate, such as a textile, thereby providing the manufactured article. The use of such arrangements can, according to certain embodiments, allow for the production of improved articles of footwear and/or customized articles of footwear.

The present disclosure relates generally to three-dimensionally printed molds, and associated methods, for use in manufacturing articles such as footwear. In some embodiments, for example, a three-dimensionally printed mold may be a master mold that is used to manufacture a secondary mold. The secondary mold may be used, in certain embodiments, to provide a cured material that can be transferred to a substrate, such as a textile, thereby providing the manufactured article. The use of such arrangements can, according to certain embodiments, allow for the production of improved articles of footwear and/or customized articles of footwear.

A wearable article, a system, and methods include a structural material configured to enable the wearable article to the worn on a body, a piezoelectric generator, positioned with respect to the structural material in a configuration to be flexed to output a voltage, a data translator, coupled to the piezoelectric generator, configured to output electronic data based on the voltage, and an electronic data storage, coupled to the data translator, configured to store the electronic data from the data translator.

A wearable article, a system, and methods include a structural material configured to enable the wearable article to the worn on a body, a piezoelectric generator, positioned with respect to the structural material in a configuration to be flexed to output a voltage, a data translator, coupled to the piezoelectric generator, configured to output electronic data based on the voltage, and an electronic data storage, coupled to the data translator, configured to store the electronic data from the data translator.

A footwear customization kit comprises a container including an article of footwear, a stand, a steaming bag and a set of instructions. The article of footwear includes one or more customizable portions that can be deformed when heated, including an upper and a customizable insert. The stand and the steaming bag can be used to heat the article of footwear and the customizable portions in a steam environment. The customizable portions can be modified by a shape of a foot inserted into the article of footwear and can permanently retain the shape upon cooling.

A footwear customization kit comprises a container including an article of footwear, a stand, a steaming bag and a set of instructions. The article of footwear includes one or more customizable portions that can be deformed when heated, including an upper and a customizable insert. The stand and the steaming bag can be used to heat the article of footwear and the customizable portions in a steam environment. The customizable portions can be modified by a shape of a foot inserted into the article of footwear and can permanently retain the shape upon cooling.

An article of apparel, a system, and methods include a structural material configured to enable the article of footwear to the worn on a body. A wireless transmission circuit is included and a piezoelectric generator is positioned with respect to the structural material in a configuration to be flexed to induce a voltage signal output. A voltage sensor is configured to sense the voltage profile and output a sensor signal indicative of the voltage profile. An electronic data storage, coupled to the voltage sensor, is configured to store voltage profile information based on the sensor data. A comparator, coupled to the electronic data storage, is configured to identify a change in the voltage profile information over time. The wireless transmission circuit is configured to transmit data indicative of a physical status of the article of footwear based on the change in the voltage profile information over time.

An article of apparel, a system, and methods include a structural material configured to enable the article of footwear to the worn on a body. A wireless transmission circuit is included and a piezoelectric generator is positioned with respect to the structural material in a configuration to be flexed to induce a voltage signal output. A voltage sensor is configured to sense the voltage profile and output a sensor signal indicative of the voltage profile. An electronic data storage, coupled to the voltage sensor, is configured to store voltage profile information based on the sensor data. A comparator, coupled to the electronic data storage, is configured to identify a change in the voltage profile information over time. The wireless transmission circuit is configured to transmit data indicative of a physical status of the article of footwear based on the change in the voltage profile information over time.