Low-voltage power supply system based on three-phase to two-phase and integrated power quality control method

Guo, Cheng; Lianghui, Yang; Zhang, Liyan

doi:10.1088/1757-899x/677/5/052089

Cited by 1 publication

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“…The main power switches are bidirectional controlled to handle the magnetizing energy of the isolation transformer [8][9][10]. The ripple frequency at the output is double the switching frequency of the main switch, and most high-powered converters are designed with this circuit structure [11][12][13].…”

Section: Introductionmentioning

confidence: 99%

Design a H-bridge low ripple and high bandwidth air core magnet corrector power supply in NSRRC

Wong¹,

Huang²,

Liu³

et al. 2021

J. Inst.

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This paper is the study of a low-current-ripple and high-bandwidth corrector power supply. The main circuit of this power supply is using a full bridge (H-bridge) structure, and the output current through the high-precision direct current current transducers (DCCT) to transfer the reference voltage to the controller. Previous TPS corrector power supply had a 4.7 kHz current bandwidth, and its output current ripple was 100 μA. Such current ripple and bandwidth do not satisfy the requirements of a rapidly orbiting feedback system of air core loading. Therefore, our research team designed a novel prototype power supply with a high bandwidth (more than 10 kHz) and low output current ripple (less than 10 μA) which was developed via a novel topology circuit. The operation frequency of the main power switch's n-type metal-oxide-semiconductor logic of this novel circuit is increased to 245 kHz. Moreover, the output results of the filter inductor and filter capacitor are modified to 80 μH and 2.46 μF, respectively. The prototype power supply bandwidth reached 10.546 kHz and increase of 124% and its output current ripple was lowered below than 5 μA. The properties of this corrector power supply are very important for the beam correction in storage rings. Finally, A circuit with an input voltage of 48 V, a maximum output current of 10 A, and an output power of 400 W is tested in a laboratory to verify the performance of the developed corrector for the National Synchrotron Radiation Research Center.

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