Multi-MHz inductive and capacitive power transfer systems with PCB-based self-resonators
This article presents multimegahertz (multi-MHz) wireless power transfer technology utilizing integrated printed-circuit-board (PCB) self-resonators, designed for both inductive and capacitive power transfer (IPT and CPT) systems. The PCB resonator comprises a pair of contactless PCB-coil plates inc...
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sg-ntu-dr.10356-1812282024-11-18T07:10:48Z Multi-MHz inductive and capacitive power transfer systems with PCB-based self-resonators Wang, Yao Wang, Kaiyuan Li, Kerui Yang, Yun Hui, Ron Shu Yuen School of Electrical and Electronic Engineering Engineering Capacitive power transfer Inductive power transfer This article presents multimegahertz (multi-MHz) wireless power transfer technology utilizing integrated printed-circuit-board (PCB) self-resonators, designed for both inductive and capacitive power transfer (IPT and CPT) systems. The PCB resonator comprises a pair of contactless PCB-coil plates incorporating trace inductance and integrated plate capacitance. In IPT systems, the plate capacitances between PCB coils are used to compensate the trace inductances, while the trace inductances are adopted to compensate the plate capacitances in CPT systems. 300 W multi-MHz IPT and CPT systems have been developed using 210 mm × 210 mm circular PCB resonators, showcasing stable output current and voltage across a wide range of load variations. A 3 MHz IPT system is verified to operate with the maximum efficiency of 90.5% over a relatively long distance of 10 cm with strong antimisalignment but poor antiload-variation performance. On the contrary, the CPT systems operating at 3.125 MHz, 4.68 MHz, and 6.78 MHz are demonstrated to operate with the maximum efficiencies of 93.14%, 90.56%, and 83.34% over relatively short distances of 6 mm, 15 mm, and 37 mm, respectively, with strong antiload-variation but poor antimisalignment performance. Agency for Science, Technology and Research (A*STAR) Ministry of Education (MOE) This work was supported in part by A∗STAR MTC Young Individual Research Grant under Grant M23M7c0115, in part by the Ministry of Education Academic Research Fund Tier-1 under Grant RG134/23, and in part by the Hong Kong RGC Theme-based Research Project under Grant T23-708/24-N. 2024-11-18T07:10:48Z 2024-11-18T07:10:48Z 2024 Journal Article Wang, Y., Wang, K., Li, K., Yang, Y. & Hui, R. S. Y. (2024). Multi-MHz inductive and capacitive power transfer systems with PCB-based self-resonators. IEEE Transactions On Power Electronics, 39(10), 14077-14090. https://dx.doi.org/10.1109/TPEL.2024.3431226 0885-8993 https://hdl.handle.net/10356/181228 10.1109/TPEL.2024.3431226 2-s2.0-85199089257 10 39 14077 14090 en M23M7c0115 RG134/23 IEEE Transactions on Power Electronics © 2024 IEEE. All rights reserved. |
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Engineering Capacitive power transfer Inductive power transfer |
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Engineering Capacitive power transfer Inductive power transfer Wang, Yao Wang, Kaiyuan Li, Kerui Yang, Yun Hui, Ron Shu Yuen Multi-MHz inductive and capacitive power transfer systems with PCB-based self-resonators |
| description |
This article presents multimegahertz (multi-MHz) wireless power transfer technology utilizing integrated printed-circuit-board (PCB) self-resonators, designed for both inductive and capacitive power transfer (IPT and CPT) systems. The PCB resonator comprises a pair of contactless PCB-coil plates incorporating trace inductance and integrated plate capacitance. In IPT systems, the plate capacitances between PCB coils are used to compensate the trace inductances, while the trace inductances are adopted to compensate the plate capacitances in CPT systems. 300 W multi-MHz IPT and CPT systems have been developed using 210 mm × 210 mm circular PCB resonators, showcasing stable output current and voltage across a wide range of load variations. A 3 MHz IPT system is verified to operate with the maximum efficiency of 90.5% over a relatively long distance of 10 cm with strong antimisalignment but poor antiload-variation performance. On the contrary, the CPT systems operating at 3.125 MHz, 4.68 MHz, and 6.78 MHz are demonstrated to operate with the maximum efficiencies of 93.14%, 90.56%, and 83.34% over relatively short distances of 6 mm, 15 mm, and 37 mm, respectively, with strong antiload-variation but poor antimisalignment performance. |
| author2 |
School of Electrical and Electronic Engineering |
| author_facet |
School of Electrical and Electronic Engineering Wang, Yao Wang, Kaiyuan Li, Kerui Yang, Yun Hui, Ron Shu Yuen |
| format |
Article |
| author |
Wang, Yao Wang, Kaiyuan Li, Kerui Yang, Yun Hui, Ron Shu Yuen |
| author_sort |
Wang, Yao |
| title |
Multi-MHz inductive and capacitive power transfer systems with PCB-based self-resonators |
| title_short |
Multi-MHz inductive and capacitive power transfer systems with PCB-based self-resonators |
| title_full |
Multi-MHz inductive and capacitive power transfer systems with PCB-based self-resonators |
| title_fullStr |
Multi-MHz inductive and capacitive power transfer systems with PCB-based self-resonators |
| title_full_unstemmed |
Multi-MHz inductive and capacitive power transfer systems with PCB-based self-resonators |
| title_sort |
multi-mhz inductive and capacitive power transfer systems with pcb-based self-resonators |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/181228 |
| _version_ |
1816859026687787008 |