Design of a wireless power transfer system for assisted living applications

Advances in material science and semiconductor technology have enabled a variety of inventions to be implemented in electronic systems and devices used in the medical, telecommunications, and consumer electronics sectors. In this paper, a wireless charging system is described as a wearable body heat...

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Veröffentlicht in:Wireless power transfer 2019-03, Vol.6 (1), p.41-56
Hauptverfasser: Abdullahi, Qassim S., Joshi, Rahil, Podilchak, Symon K., Khan, Sadeque R., Chen, Meixuan, Rooney, Jean, Rooney, John, Sun, Danmei, Desmulliez, Marc P.Y., Georgiadis, Apostolos, Anagnostou, Dimitris
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container_end_page 56
container_issue 1
container_start_page 41
container_title Wireless power transfer
container_volume 6
creator Abdullahi, Qassim S.
Joshi, Rahil
Podilchak, Symon K.
Khan, Sadeque R.
Chen, Meixuan
Rooney, Jean
Rooney, John
Sun, Danmei
Desmulliez, Marc P.Y.
Georgiadis, Apostolos
Anagnostou, Dimitris
description Advances in material science and semiconductor technology have enabled a variety of inventions to be implemented in electronic systems and devices used in the medical, telecommunications, and consumer electronics sectors. In this paper, a wireless charging system is described as a wearable body heater that uses a chair as a transmitter (Tx). This system incorporates the widely accepted Qi wireless charging standard. Alignment conditions of a linear three-element coil arrangement and a 3 × 3 coil matrix array are investigated using voltage induced in a coil as a performance indicator. The efficiency obtained is demonstrated to be up to 80% for a voltage of over 6.5 Volts and a power transfer of over 5 Watts. Our results and proposed approach can be useful for many applications. This is because the wireless charging system described herein can help design seating areas for the elderly and disabled, commercial systems, consumer electronics, medical devices, electronic textiles (e-textiles), and other electronic systems and devices.
doi_str_mv 10.1017/wpt.2019.2
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source Cambridge University Press Journals Complete
subjects Batteries
Charging
Coils
Consortia
Design
Efficiency
Electric potential
Electronic devices
Electronic systems
Electronics
Mathematical analysis
Matrix methods
Medical devices
Medical electronics
Smart materials
Systems design
Textiles
Transmitters
Transplants & implants
Voltage
Wireless power transmission
title Design of a wireless power transfer system for assisted living applications
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