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A wearable all printed textile based 6.78 MHz 15 W output wireless power transfer system and it's screen printed joule heater application

A wearable all printed textile based 6.78 MHz 15 W output wireless power transfer system and it's screen printed joule heater application
A wearable all printed textile based 6.78 MHz 15 W output wireless power transfer system and it's screen printed joule heater application

While research in passive flexible circuits for wireless power transfer (WPT) such as coils and resonators continues to advance, limitations in their power handling and low efficiency have hindered the realization of efficient all-printed high-power wearable WPT receivers. Here, we propose a screen-printed textile-based 6.78 MHz resonant inductive WPT system using planar inductors with concealed metal-insulator-metal tuning capacitors. A printed voltage doubler rectifier based on silicon carbide diodes is designed and integrated with the coils, showing a power conversion efficiency of 80%-90% for 2-40 W inputs over a wide load range. Compared to prior wearable WPT receivers, it offers an order of magnitude improvement in power handling along with higher efficiency (approaching 60%) while using all-printed passives and a compact rectifier. The coils exhibit a simulated specific absorption rate under 0.4 W/kg for 25 W received power, and under 21 °C increase in the coils' temperature for a 15 W DC output. Additional fabric shielding is investigated, reducing harmonics emissions by up to 17 dB. We finally demonstrate a wirelessly-powered textile-based carbon-silver Joule heater, capable of reaching up to 60 °C at 2 cm separation from the transmitter, as a wearable application, which can only be wireless-powered using the proposed system.

Antennas, Capacitors, Coils, Heating systems, Inductance, RFID, Rectifiers, Substrates, Tuning, coils, heaters, inductors, rectifiers, resistors, wireless power transfer, wireless power transfer (WPT)
0278-0046
3741-3750
Wagih, Mahmoud
7e7b16ba-0c64-4f95-bd3c-99064055f693
Komolafe, Abiodun
5e79fbab-38be-4a64-94d5-867a94690932
Ullah, Irfan
15653bbb-6bcc-4f9e-b1af-54145ad92cdb
Weddell, Alexander
3e13398e-fe50-4304-a868-00bde6217dde
Beeby, Stephen
ba565001-2812-4300-89f1-fe5a437ecb0d
Wagih, Mahmoud
7e7b16ba-0c64-4f95-bd3c-99064055f693
Komolafe, Abiodun
5e79fbab-38be-4a64-94d5-867a94690932
Ullah, Irfan
15653bbb-6bcc-4f9e-b1af-54145ad92cdb
Weddell, Alexander
3e13398e-fe50-4304-a868-00bde6217dde
Beeby, Stephen
ba565001-2812-4300-89f1-fe5a437ecb0d

Wagih, Mahmoud, Komolafe, Abiodun, Ullah, Irfan, Weddell, Alexander and Beeby, Stephen (2023) A wearable all printed textile based 6.78 MHz 15 W output wireless power transfer system and it's screen printed joule heater application. IEEE Transactions on Industrial Electronics, 71 (4), 3741-3750. (doi:10.1109/TIE.2023.3277112).

Record type: Article

Abstract

While research in passive flexible circuits for wireless power transfer (WPT) such as coils and resonators continues to advance, limitations in their power handling and low efficiency have hindered the realization of efficient all-printed high-power wearable WPT receivers. Here, we propose a screen-printed textile-based 6.78 MHz resonant inductive WPT system using planar inductors with concealed metal-insulator-metal tuning capacitors. A printed voltage doubler rectifier based on silicon carbide diodes is designed and integrated with the coils, showing a power conversion efficiency of 80%-90% for 2-40 W inputs over a wide load range. Compared to prior wearable WPT receivers, it offers an order of magnitude improvement in power handling along with higher efficiency (approaching 60%) while using all-printed passives and a compact rectifier. The coils exhibit a simulated specific absorption rate under 0.4 W/kg for 25 W received power, and under 21 °C increase in the coils' temperature for a 15 W DC output. Additional fabric shielding is investigated, reducing harmonics emissions by up to 17 dB. We finally demonstrate a wirelessly-powered textile-based carbon-silver Joule heater, capable of reaching up to 60 °C at 2 cm separation from the transmitter, as a wearable application, which can only be wireless-powered using the proposed system.

Text
A Wearable All-Printed Textile-Based 6.78 MHz 15 W-Output Wireless Power Transfer System and its Screen-Printed Joule Heater Application - Accepted Manuscript
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More information

e-pub ahead of print date: 22 May 2023
Published date: 22 May 2023
Additional Information: Publisher Copyright: © 1982-2012 IEEE.
Keywords: Antennas, Capacitors, Coils, Heating systems, Inductance, RFID, Rectifiers, Substrates, Tuning, coils, heaters, inductors, rectifiers, resistors, wireless power transfer, wireless power transfer (WPT)

Identifiers

Local EPrints ID: 479454
URI: http://eprints.soton.ac.uk/id/eprint/479454
ISSN: 0278-0046
PURE UUID: 5d164ff2-e2e2-4644-8fe9-96c46c38cd43
ORCID for Mahmoud Wagih: ORCID iD orcid.org/0000-0002-7806-4333
ORCID for Abiodun Komolafe: ORCID iD orcid.org/0000-0002-3618-2390
ORCID for Stephen Beeby: ORCID iD orcid.org/0000-0002-0800-1759

Catalogue record

Date deposited: 24 Jul 2023 17:01
Last modified: 14 Dec 2024 03:03

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Contributors

Author: Mahmoud Wagih ORCID iD
Author: Abiodun Komolafe ORCID iD
Author: Irfan Ullah
Author: Alexander Weddell
Author: Stephen Beeby ORCID iD

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