This work focuses on using miniature thermoelectric generators encapsulated in a polydimethylsiloxane matrix for designing a bendable, wearable prototype for self-powering a temperature sensor. Therma-Tech™ compound was chosen as the material to form the heatsink to enhance the device bendability. It was tested in real-life scenarios, in indoor and outdoor environments. When the environmental temperature exceeds 30 °C, the wearable thermoelectric energy harvester was unable to power the temperature sensor consuming approximately 5 µW. However, wearing the device on the lower leg can be an interesting approach to differentiate the execution of dynamic activities from static ones using thermoelectric generators. An automatic segmentation algorithm is presented for detecting transitions between motor activities using data only from the thermoelectric generators. Maximum value of load power generated by the prototype is 27 µW, for a difference of temperature between the thermocouples constituting the thermoelectric generator of 0.23 °C, when the environmental temperature was 20.5 °C.

Wearable device for body heat energy harvesting in real-life scenarios

Paterno G.;
2024

Abstract

This work focuses on using miniature thermoelectric generators encapsulated in a polydimethylsiloxane matrix for designing a bendable, wearable prototype for self-powering a temperature sensor. Therma-Tech™ compound was chosen as the material to form the heatsink to enhance the device bendability. It was tested in real-life scenarios, in indoor and outdoor environments. When the environmental temperature exceeds 30 °C, the wearable thermoelectric energy harvester was unable to power the temperature sensor consuming approximately 5 µW. However, wearing the device on the lower leg can be an interesting approach to differentiate the execution of dynamic activities from static ones using thermoelectric generators. An automatic segmentation algorithm is presented for detecting transitions between motor activities using data only from the thermoelectric generators. Maximum value of load power generated by the prototype is 27 µW, for a difference of temperature between the thermocouples constituting the thermoelectric generator of 0.23 °C, when the environmental temperature was 20.5 °C.
2024
Proto, A.; Schmidt, M.; Vondrak, J.; Kubicek, J.; Paterno, G.; Jargus, J.; Penhaker, M.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11392/2570511
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