High-Frequency, High-Power Resonant Inverter With eGaN FET for Wireless Power Transfer

被引：82

作者：

Choi, Jungwon ^{[1
]}

Tsukiyama, Daisuke ^{[2
]}

Tsuruda, Yoshinori ^{[3
]}

Davila, Juan Manuel Rivas ^{[1
]}

机构：

[1] Stanford Univ, Stanford, CA 94305 USA

[2] Daihen Corp, Osaka 5328512, Japan

[3] Kabushiki Kaisha Daihen, Osaka 230173, Japan

来源：

IEEE TRANSACTIONS ON POWER ELECTRONICS | 2018年 / 33卷 / 03期

关键词：

Enhancement mode gallium nitride (eGaN) FET; high-frequency power inverter; magnetic resonant coupling (MRC); resonant inverter;

D O I：

10.1109/TPEL.2017.2740293

中图分类号：

TM [电工技术]; TN [电子技术、通信技术];

学科分类号：

0808 ; 0809 ;

摘要：

This letter presents a high-power resonant inverter using an enhancement mode gallium nitride (eGaN) device with magnetic resonant coupling (MRC) coils at 13.56 MHz for wireless power transfer (WPT). The power inverter driving the transmitting coils is based on a class Phi(2) inverter, a single-switch topology with low switch-voltage stress, and fast transient response. The implementation utilizes a recently available eGaN device in a low-inductance package that is compatible with operation in the 10 s of MHz switching frequency. In this letter, we present experimental measurements of the inverter in a WPT application and characterize the system performance over various distances and operating conditions. Before using MRC coils, we evaluated the performance of the class Phi(2) inverter with the eGaN FET. It delivered 1.3-kW output to a 50-Omega load with an efficiency of 95% when a 280-V input voltage was applied. For WPT operation, we added the open-type four-coil unit with a diameter of 300 mm to deliver power over 270-mm distance. With the addition of MRC coils, the class Phi(2) inverter provided 823-W output power with 87% efficiency over 270-mm distance between coils.

引用

页码：1890 / 1896

页数：7

共 50 条

[31] A Voltage-Feed High-Frequency Resonant Inverter With Controlled Current Output as a High-Frequency AC Power Source
Zeng, Jun
Liu, Junfeng
Yang, Jinming
Luo, Fei
IEEE TRANSACTIONS ON POWER ELECTRONICS, 2015, 30 (09) : 4854 - 4863
[32] PCB Layout Optimization of High-Frequency Inverter for Magnetic Coupled Resonance Wireless Power Transfer System
Yang, Dongsheng
Cheng, Zixin
Li, Hua
Won, Sokhui
Zhou, Bowen
Tian, Jiangwei
IEEE ACCESS, 2019, 7 : 171395 - 171404
[33] MATERIAL CONSIDERATIONS FOR HIGH-FREQUENCY, HIGH-POWER CAPACITORS
WHITE, W
GALPERIN, I
IEEE TRANSACTIONS ON ELECTRICAL INSULATION, 1985, 20 (01): : 66 - 69
[34] HIGH-POWER HIGH-FREQUENCY BROADCAST ANTENNA SYSTEMS
PETTITT, C
COMMUNICATION & BROADCASTING, 1979, 5 (02): : 13 - 20
[35] Design Guidelines for High-Power and High-Frequency Transformers
Salinas, Guillermo
Gimenez, Alvaro
Oliver, Jesus A.
Prieto, Roberto
THIRTY-FOURTH ANNUAL IEEE APPLIED POWER ELECTRONICS CONFERENCE AND EXPOSITION (APEC 2019), 2019, : 1423 - 1429
[36] SUPERCONDUCTING RESONATOR FOR HIGH-FREQUENCY - HIGH-POWER APPLICATIONS
WEINMAN, LS
MURRAY, HD
VARDIMAN, R
IEEE TRANSACTIONS ON MAGNETICS, 1975, MA11 (02) : 411 - 412
[37] TUNABLE HIGH-FREQUENCY HIGH-POWER PIEZOCERAMIC RADIATOR
LANINA, EP
SOVIET PHYSICS ACOUSTICS-USSR, 1978, 24 (03): : 207 - 209
[38] HIGH-FREQUENCY HIGH-POWER OPERATION OF TUNNEL DIODES
KIM, CS
BRANDLI, A
IRE TRANSACTIONS ON CIRCUIT THEORY, 1961, CT 8 (04): : 416 - &
[39] HIGH-FREQUENCY HIGH-POWER STATIC INDUCTION TRANSISTOR
NISHIZAWA, JI
YAMAMOTO, K
IEEE TRANSACTIONS ON ELECTRON DEVICES, 1978, 25 (03) : 314 - 322
[40] DEVELOPMENT OF HIGH-POWER, HIGH-FREQUENCY THYRISTOR INVERTERS
FITZ, PJ
MARCONI REVIEW, 1976, 39 (203): : 173 - 188

← 1 2 3 4 5 →