The present invention discloses a power-generating insole based on fabric integration, which comprises a power-generating insole body, a detachable outer layer and an electronic module; The power-generating insole comprises a first friction component, a second friction component and a fabric composite component; The first friction component is composed of a first electrode layer and a first polymer material; The first friction component and the fabric composite component are integrally formed; The second friction component is wrapped around the middle part of the fabric composite component, and is integrated with the first friction component and the fabric composite component; The detachable outer layer is wrapped on the surface of the power-generating insole body; The electronic module is connected to the power-generating insole body; The present invention has long service life, good flexibility, plasticity, is washing resistance and stability.

The present invention discloses a power-generating insole based on fabric integration, which comprises a power-generating insole body, a detachable outer layer and an electronic module; The power-generating insole comprises a first friction component, a second friction component and a fabric composite component; The first friction component is composed of a first electrode layer and a first polymer material; The first friction component and the fabric composite component are integrally formed; The second friction component is wrapped around the middle part of the fabric composite component, and is integrated with the first friction component and the fabric composite component; The detachable outer layer is wrapped on the surface of the power-generating insole body; The electronic module is connected to the power-generating insole body; The present invention has long service life, good flexibility, plasticity, is washing resistance and stability.

The present invention relates to a functional shoe configured to generate power when a user wearing the shoe walks, so that a battery there inside can be charged, and to supply the charged electricity to internal and external devices so as to be used for the purpose of user safety and device charging, and enable use of a location tracking function using a GPS device. A self-generating smart shoe according to the present invention comprises: an outsole constituting the lower portion of the shoe while having a plurality of receiving portions formed therein; a self-generation unit which, while being installed at the heel of the outsole, generates power by using a pressure generated when the user wearing the shoe walks and the restoring force due to the pressure; and a battery which, while being installed in the outsole, is charged when the self-generation unit generates power.

The present invention relates to a functional shoe configured to generate power when a user wearing the shoe walks, so that a battery there inside can be charged, and to supply the charged electricity to internal and external devices so as to be used for the purpose of user safety and device charging, and enable use of a location tracking function using a GPS device. A self-generating smart shoe according to the present invention comprises: an outsole constituting the lower portion of the shoe while having a plurality of receiving portions formed therein; a self-generation unit which, while being installed at the heel of the outsole, generates power by using a pressure generated when the user wearing the shoe walks and the restoring force due to the pressure; and a battery which, while being installed in the outsole, is charged when the self-generation unit generates power.

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.

A personal monitoring system includes one or more passive biometric sensors and a communication device. A passive biometric sensor is operable to sense a body condition of a body in accordance with a sense signal at a sense frequency to produce sensed data of a body condition. The passive biometric sensor is further operable to transmit an e-field signal via the body regarding the sensed data, wherein the e-field signal is in accordance with an e-field transmit/receive frequency. The communication device is operable to receive the e-field signal via the body. The communication device is further operable to recover the sensed data from the received e-field signal.

A kinetic energy generator, system and method of transmitting data are described. The kinetic energy generator includes a piezoelectric element that receives kinetic energy initiated by a user, a rectifier connected with the piezoelectric element that rectifies voltage from the piezoelectric element, a capacitive system of capacitors formed from different materials connected with the piezoelectric element through the rectifier, a short-range transceiver connected with the capacitive system and activated in response to energy storage in the capacitive system reaching a threshold level, and a non-volatile memory that provides at least some of the data transmitted by the transceiver in response to a request from the transceiver. Below an inflection point, the capacitive system stores more energy than one system of one capacitor type and less energy than another system of another capacitor type arranged in the same manner as the capacitive system, and the reverse above the inflection point.

A kinetic energy generator, system and method of transmitting data are described. The kinetic energy generator includes a piezoelectric element that receives kinetic energy initiated by a user, a rectifier connected with the piezoelectric element that rectifies voltage from the piezoelectric element, a capacitive system of capacitors formed from different materials connected with the piezoelectric element through the rectifier, a short-range transceiver connected with the capacitive system and activated in response to energy storage in the capacitive system reaching a threshold level, and a non-volatile memory that provides at least some of the data transmitted by the transceiver in response to a request from the transceiver. Below an inflection point, the capacitive system stores more energy than one system of one capacitor type and less energy than another system of another capacitor type arranged in the same manner as the capacitive system, and the reverse above the inflection point.

Systems methods, and structures are provided that scavenge mechanical energy to provide electrical energy to a wearable, where the mechanical energy is scavenged by a bending-strain-based transducer that includes a non-resonant energy harvester. The bending-strain-based transducer also includes a sensor and/or a haptic device. The transducer may comprise a piezoelectric layer comprising a low-K piezoelectric material, such as aluminum nitride, which enables generation of higher voltage and power/energy output and/or a thinner transducer. Transducers in accordance with the present disclosure can be included in wearables for which large transducer thickness would be problematic, such as shoe insoles, midsoles or outsoles, garments, bras, handbags, backpacks, and the like.