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 sole sensor system is provided. The sole sensor system that includes a sensor or sensors within insoles for use with footwear, wherein the sensors wirelessly send sensor data to a user computing device that communicates with a server to process the sensor data to determine pressure points of the user's feet during various activities of the user.

It is an object of the present invention to array and utilize piezoelectric generators. It is also an object of the invention to implement properly configured piezoelectric generators into applications that can recapture expelled kinetic energy that is otherwise wasted. Particularly, piezoelectric generators, or arrays, may be, for example, placed in shoes, clothing, tires, roads, and sidewalks in order to recapture the energy expelled in everyday human activities (e.g., walking, moving, and driving).

It is an object of the present invention to array and utilize piezoelectric generators. It is also an object of the invention to implement properly configured piezoelectric generators into applications that can recapture expelled kinetic energy that is otherwise wasted. Particularly, piezoelectric generators, or arrays, may be, for example, placed in shoes, clothing, tires, roads, and sidewalks in order to recapture the energy expelled in everyday human activities (e.g., walking, moving, and driving).

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.

The invention relates to the field of the footwear industry, namely footwear (5) with a sole (6) of variable dimensions. The proposed method of dimensional change of the footwear sole (6) and the footwear (5) include a sole (6) of variable dimensions, the height of which may increase or decrease or return to the initial position, depending on the position of the sole (6) in contact with the supporting surface. The method of changing the height of the sole (6) of the footwear (5) proposed according to the invention facilitates climbing uphill, stairs, downhill, cycling by creating an effect of upward acting escalator without jerking or an effect of downward acting escalator without jerking, respectively.

The invention relates to the field of the footwear industry, namely footwear (5) with a sole (6) of variable dimensions. The proposed method of dimensional change of the footwear sole (6) and the footwear (5) include a sole (6) of variable dimensions, the height of which may increase or decrease or return to the initial position, depending on the position of the sole (6) in contact with the supporting surface. The method of changing the height of the sole (6) of the footwear (5) proposed according to the invention facilitates climbing uphill, stairs, downhill, cycling by creating an effect of upward acting escalator without jerking or an effect of downward acting escalator without jerking, respectively.

Systems and apparatus related to footwear including a modular lacing engine are discussed. In this example, the lace guide is deformable to assist in facilitating automated lace tightening. The lace guide can include a middle section, a first extension and a second extension. In this example, the lace guide can be configured to define a first route for a lace cable, the first route including receiving the lace cable along the first incoming lace axis and expelling the lace cable along the first outgoing lace axis. In this example, the lace guide can also deflect, in response to tension on the lace cable, resulting in defining a second route for the lace cable, the second route including receiving the lace cable along a second incoming lace axis and expelling the lace cable along a second outgoing lace axis.