台湾光子源之新型高频宽双极校正电源

2019 IEEE 60th International Scientific Conference on Power and Electrical Engineering of Riga Technical University (RTUCON) Pub Date : 2019-10-01 DOI:10.1109/RTUCON48111.2019.8982295

Y. Wong, Jhao-Cyuan Huang, K. Liu, C. Liu, Bao-sheng Wang

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引用次数: 0

摘要

2013年12月，台湾的光子源产生了第一束光。TPS已运行6年，平均无故障时间(MTBF)达到世界一流标准。NSRRC对存储环和升压环的升级需要为快速校正磁铁提供快速双极电源。对于快速校正磁铁的要求，校正电源的输出电流必须具有10kHz的高带宽。一个原型DC/DC校正电源采用MOSFET全桥电路和200kHz PWM控制信号，在最大工作电流为10安培的小参考信号下实现了高达10kHz的带宽和小于3db的衰减。最后，该原型在参考信号0.1V(等于0.lA)时实现了11 kHz的带宽，衰减小于3 dB。文中还介绍了电源电路、控制电路、MOSFET驱动电路、辅助稳压电源电路、保护电路的设计和元器件布局。实验结果表明，从增益裕度和相位裕度可以验证控制回路设计的有效性。

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A Novel High Bandwidth Bipolar Corrector Power Supply in Taiwan Photon Source

The first light of Taiwan's photon source was produced on December 2013. TPS has been in operation for 6 years and mean time between fail (MTBF) has reached world class standards. The NSRRC upgrade of a storage ring and booster ring requires fast bipolar power supplies for the fast correction magnets. For the fast correction magnets are requirement of the correction power supplies must had a high bandwidth of 10kHz for the output current. A prototype DC/DC corrector power supply using a MOSFET full bridge circuit with a 200kHz PWM control signal and achieved up of 10kHz bandwidth with less than 3-dB attenuation for a small refer signal of the maximum operation current of 10 amperes. Finally, the prototype achieved an 11 kHz bandwidth with less than 3 dB attenuation for a refer signal 0.1V (equal to 0.lA). This paper also presents the designs of the power circuit, control circuit, MOSFET driver circuit, auxiliary & regulator power circuit, protection circuit, and component layout. The experimental results, the effectiveness of the control loop design can be verified from the gain margin and phase margin.

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来源期刊

2019 IEEE 60th International Scientific Conference on Power and Electrical Engineering of Riga Technical University (RTUCON)

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