Pēteris Aizpurietis, Didzis Lapsa, Niklāvs Barkovskis, Arnis Salmiņš, Rims Janeliukštis, Kaspars Ozols. Wireless induction charging station for industrial application. 2023 Workshop on Microwave Theory and Technology in Wireless Communications (MTTW), 62-66 pp. IEEE, 2023.
Bibtex citation:
Bibtex citation:
@inproceedings{15732_2023,
author = {Pēteris Aizpurietis and Didzis Lapsa and Niklāvs Barkovskis and Arnis Salmiņš and Rims Janeliukštis and Kaspars Ozols},
title = {Wireless induction charging station for industrial application},
journal = {2023 Workshop on Microwave Theory and Technology in Wireless Communications (MTTW)},
pages = {62-66},
publisher = {IEEE},
year = {2023}
}
author = {Pēteris Aizpurietis and Didzis Lapsa and Niklāvs Barkovskis and Arnis Salmiņš and Rims Janeliukštis and Kaspars Ozols},
title = {Wireless induction charging station for industrial application},
journal = {2023 Workshop on Microwave Theory and Technology in Wireless Communications (MTTW)},
pages = {62-66},
publisher = {IEEE},
year = {2023}
}
Abstract: Wiring for charging LiPo batteries poses problems due to electromagnetic interference and limitations of wire length. In this work, a method for charging wireless sensor network wirelessly using NRF52840 is developed for both transmitting and receiving side of equipment. A Qi-compliant WE760308103202 wireless charging coil receiver is used and its performance evaluated to estimate optimal parameters of wireless charging, such as load and resonance frequency detuning for receiver. By tuning the frequency of operation, it is possible to utilize generic electronic components with reduced costs.